JAJSDP7 データシート

JAJSDP7 August 2017 AM5718-HIREL

PRODUCTION DATA.

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メカニカル・データ（パッケージ｜ピン）

ZBO|760

サーマルパッド・メカニカル・データ

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7 Timing Requirements and Switching Characteristics

7.1 Timing Test Conditions

All timing requirements and switching characteristics are valid over the recommended operating conditions unless otherwise specified.

7.2 Interface Clock Specifications

7.2.1 Interface Clock Terminology

The interface clock is used at the system level to sequence the data and/or to control transfers accordingly with the interface protocol.

7.2.2 Interface Clock Frequency

The two interface clock characteristics are:

The maximum clock frequency
The maximum operating frequency

The interface clock frequency documented in this document is the maximum clock frequency, which corresponds to the maximum frequency programmable on this output clock. This frequency defines the maximum limit supported by the Device IC and does not take into account any system consideration (PCB, peripherals).

The system designer will have to consider these system considerations and the Device IC timing characteristics as well to define properly the maximum operating frequency that corresponds to the maximum frequency supported to transfer the data on this interface.

7.3 Timing Parameters and Information

The timing parameter symbols used in the timing requirement and switching characteristic tables are created in accordance with JEDEC Standard 100. To shorten the symbols, some of pin names and other related terminologies have been abbreviated as follows:

Table 7-1 Timing Parameters

SUBSCRIPTS
SYMBOL	PARAMETER
c	Cycle time (period)
d	Delay time
dis	Disable time
en	Enable time
h	Hold time
su	Setup time
START	Start bit
t	Transition time
v	Valid time
w	Pulse duration (width)
X	Unknown, changing, or don't care level
F	Fall time
H	High
L	Low
R	Rise time
V	Valid
IV	Invalid
AE	Active Edge
FE	First Edge
LE	Last Edge
Z	High impedance

7.3.1 Parameter Information

Figure 7-1 Test Load Circuit for AC Timing Measurements

The load capacitance value stated is only for characterization and measurement of AC timing signals.

This load capacitance value does not indicate the maximum load the device is capable of driving.

7.3.1.1 1.8V and 3.3V Signal Transition Levels

All input and output timing parameters are referenced to V_ref for both "0" and "1" logic levels. V_ref = (VDD I/O)/2.

Figure 7-2 Input and Output Voltage Reference Levels for AC Timing Measurements

All rise and fall transition timing parameters are referenced to V_IL MAX and V_IH MIN for input clocks, V_OL MAX and V_OH MIN for output clocks.

Figure 7-3 Rise and Fall Transition Time Voltage Reference Levels

7.3.1.2 1.8V and 3.3V Signal Transition Rates

The default SLEWCONTROL settings in each pad configuration register must be used to guaranteed timings, unless specific instructions otherwise are given in the individual timing sub-sections of the datasheet.

All timings are tested with an input edge rate of 4 volts per nanosecond (4 V/ns).

7.3.1.3 Timing Parameters and Board Routing Analysis

The timing parameter values specified in this data manual do not include delays by board routes. As a good board design practice, such delays must always be taken into account. Timing values may be adjusted by increasing/decreasing such delays. TI recommends using the available I/O buffer information specification (IBIS) models to analyze the timing characteristics correctly. To properly use IBIS models to attain accurate timing analysis for a given system, see the Using IBIS Models for timing Analysis application report (literature number SPRA839). If needed, external logic hardware such as buffers may be used to compensate any timing differences.

7.4 Recommended Clock and Control Signal Transition Behavior

All clocks and control signals must transition between V_IH and V_IL (or between V_IL and V_IH) in a monotonic manner. Monotonic transitions are more easily guaranteed with faster switching signals. Slower input transitions are more susceptible to glitches due to noise and special care should be taken for slow input clocks.

7.5 Virtual and Manual I/O Timing Modes

Some of the timings described in the following sections require the use of Virtual or Manual I/O Timing Modes. Table 7-2 provides a summary of the Virtual and Manual I/O Timing Modes across all device interfaces. The individual interface timing sections found later in this document provide the full description of each applicable Virtual and Manual I/O Timing Mode. Refer to the "Pad Configuration" section of the TRM for the procedure on implementing the Virtual and Manual Timing Modes in a system.

Table 7-2 Modes Summary

Virtual or Manual IO Mode Name	Data Manual Timing Mode
DPI Video Output
No Virtual or Manual IO Timing Mode Required	DPI1/3 Video Output Default Timings - Rising-edge Clock Reference
DSS_VIRTUAL1	DPI1/3 Video Output Default Timings - Falling-edge Clock Reference
VOUT1_MANUAL1	DPI1 Video Output Alternate Timings
VOUT2_IOSET1_MANUAL1	DPI2 Video Output IOSET1 Alternate Timings
VOUT2_IOSET1_MANUAL2	DPI2 Video Output IOSET1 Default Timings - Rising-edge Clock Reference
VOUT2_IOSET1_MANUAL3	DPI2 Video Output IOSET1 Default Timings - Falling-edge Clock Reference
VOUT2_IOSET2_MANUAL1	DPI2 Video Output IOSET2 Alternate Timings
VOUT2_IOSET2_MANUAL2	DPI2 Video Output IOSET2 Default Timings - Rising-edge Clock Reference
VOUT2_IOSET2_MANUAL3	DPI2 Video Output IOSET2 Default Timings - Falling-edge Clock Reference
VOUT3_MANUAL1	DPI3 Video Output Alternate Timings
GPMC
No Virtual or Manual IO Timing Mode Required	GPMC Asynchronous Mode Timings and Synchronous Mode - Default Timings
GPMC_VIRTUAL1	GPMC Synchronous Mode - Alternate Timings
McASP
No Virtual or Manual IO Timing Mode Required	McASP1 Asynchronous and Synchronous Transmit Timings
MCASP1_VIRTUAL1_SYNC_RX	See Table 7-52
MCASP1_VIRTUAL2_ASYNC_RX	See Table 7-52
No Virtual or Manual IO Timing Mode Required	McASP2 Asynchronous and Synchronous Transmit Timings
MCASP2_VIRTUAL1_SYNC_RX_80M	See Table 7-53
MCASP2_VIRTUAL2_ASYNC_RX	See Table 7-53
MCASP2_VIRTUAL3_SYNC_RX	See Table 7-53
MCASP2_VIRTUAL4_ASYNC_RX_80M	See Table 7-53
No Virtual or Manual IO Timing Mode Required	McASP3 Synchronous Transmit Timings
MCASP3_VIRTUAL2_SYNC_RX	See Table 7-54
No Virtual or Manual IO Timing Mode Required	McASP4 Synchronous Transmit Timings
MCASP4_VIRTUAL1_SYNC_RX	See Table 7-55
No Virtual or Manual IO Timing Mode Required	McASP5 Synchronous Transmit Timings
MCASP5_VIRTUAL1_SYNC_RX	See Table 7-56
No Virtual or Manual IO Timing Mode Required	McASP6 Synchronous Transmit Timings
MCASP6_VIRTUAL1_SYNC_RX	See Table 7-57
No Virtual or Manual IO Timing Mode Required	McASP7 Synchronous Transmit Timings
MCASP7_VIRTUAL2_SYNC_RX	See Table 7-58
No Virtual or Manual IO Timing Mode Required	McASP8 Synchronous Transmit Timings
MCASP8_VIRTUAL1_SYNC_RX	See Table 7-59
eMMC/SD/SDIO
No Virtual or Manual IO Timing Mode Required	MMC1 DS (Pad Loopback), HS (Internal Loopback and Pad Loopback), SDR12 (Internal Loopback and Pad Loopback), and SDR25 Timings (Internal Loopback and Pad Loopback) Timings
MMC1_VIRTUAL1	MMC1 SDR50 (Pad Loopback) Timings
MMC1_VIRTUAL4	MMC1 DS (Internal Loopback) Timings
MMC1_VIRTUAL5	MMC1 SDR50 (Internal Loopback) Timings
MMC1_VIRTUAL6	MMC1 DDR50 (Internal Loopback) Timings
MMC1_MANUAL1	MMC1 DDR50 (Pad Loopback) Timings
MMC1_MANUAL2	MMC1 SDR104 Timings
No Virtual or Manual IO Timing Mode Required	MMC2 Standard (Pad Loopback), High Speed (Pad Loopback) Timings
MMC2_VIRTUAL2	MMC2 Standard (Internal Loopback), High Speed (Internal Loopback) Timings
MMC2_MANUAL1	MMC2 DDR (Pad Loopback) Timings
MMC2_MANUAL2	MMC2 DDR (Internal Loopback) Timings
MMC2_MANUAL3	MMC2 HS200 Timings
No Virtual or Manual IO Timing Mode Required	MMC3 DS, SDR12, HS, SDR25 Timings
MMC3_MANUAL1	MMC3 SDR50 Timings
No Virtual or Manual IO Timing Mode Required	MMC4 DS, SDR12, HS, SDR25 Timings
QSPI
No Virtual or Manual IO Timing Mode Required	QSPI Mode 3 Timings
QSPI1_MANUAL1	QSPI Mode 0 Timings
GMAC
No Virtual or Manual IO Timing Mode Required	GMAC MII0/1 Timings
GMAC_RGMII0_MANUAL1	GMAC RGMII0 with Transmit Clock Internal Delay Enabled
GMAC_RGMII1_MANUAL1	GMAC RGMII1 with Transmit Clock Internal Delay Enabled
GMAC_RMII0_MANUAL1	GMAC RMII0 Timings
GMAC_RMII1_MANUAL1	GMAC RMII1 Timings
VIP
VIP_MANUAL1	VIN1A (IOSET7) and VIN2A (IOSET10) Rise-Edge Capture Mode Timings
VIP_MANUAL2	VIN1A (IOSET7) and VIN2A (IOSET10) Fall-Edge Capture Mode Timings
VIP_MANUAL3	VIN2A (IOSET4/5/6) Rise-Edge Capture Mode Timings
VIP_MANUAL4	VIN2B (IOSET7/8/9) Rise-Edge Capture Mode Timings
VIP_MANUAL5	VIN2A (IOSET4/5/6) Fall-Edge Capture Mode Timings
VIP_MANUAL6	VIN2B (IOSET7/8/9) Fall-Edge Capture Mode Timings
VIP_MANUAL7	VIN1A (IOSET2/3/4) and VIN1B (IOSET4/7) and VIN2B (IOSET1/10) Rise-Edge Capture Mode Timings
VIP_MANUAL8	VIN1A (IOSET5/6) and VIN2A (IOSET7/8/9) Rise-Edge Capture Mode Timings
VIP_MANUAL9	VIN1B (IOSET6/7) Rise-Edge Capture Mode Timings
VIP_MANUAL10	VIN1B (IOSET5) and VIN2B (IOSET2/11) Rise-Edge Capture Mode Timings
VIP_MANUAL11	VIN1B (IOSET5) and VIN2B (IOSET2/11) Fall-Edge Capture Mode Timings
VIP_MANUAL12	VIN1A (IOSET2/3/4) and VIN1B (IOSET4/7) and VIN2B (IOSET1/10) Fall-Edge Capture Mode Timings
VIP_MANUAL13	VIN1A (IOSET5/6) and VIN2A (IOSET7/8/9) Fall-Edge Capture Mode Timings
VIP_MANUAL14	VIN1B (IOSET6/7) Fall-Edge Capture Mode Timings
VIP_MANUAL15	VIN1A (IOSET8/9/10) Rise-Edge Capture Mode Timings
VIP_MANUAL16	VIN1A (IOSET8/9/10) Fall-Edge Capture Mode Timings
PRU-ICSS
No Virtual or Manual IO Timing Mode Required	All PRU_ICSS Modes not covered below
PR1_PRU1_DIR_IN_MANUAL	PRU-ICSS1 PRU1 Direct Input Mode Timings
PR1_PRU1_DIR_OUT_MANUAL	PRU-ICSS1 PRU1 Direct Output Mode Timings
PR1_PRU1_PAR_CAP_MANUAL	PRU-ICSS1 PRU1 Parallel Capture Mode Timings
PR2_PRU0_DIR_IN_MANUAL1	PRU-ICSS2 PRU0 IOSET1 Direct Input Mode Timings
PR2_PRU0_DIR_IN_MANUAL2	PRU-ICSS2 PRU0 IOSET2 Direct Input Mode Timings
PR2_PRU0_DIR_OUT_MANUAL1	PRU-ICSS2 PRU0 IOSET1 Direct Output Mode Timings
PR2_PRU0_DIR_OUT_MANUAL2	PRU-ICSS2 PRU0 IOSET2 Direct Output Mode Timings
PR2_PRU1_DIR_IN_MANUAL1	PRU-ICSS2 PRU1 IOSET1 Direct Input Mode Timings
PR2_PRU1_DIR_IN_MANUAL2	PRU-ICSS2 PRU1 IOSET2 Direct Input Mode Timings
PR2_PRU1_DIR_OUT_MANUAL1	PRU-ICSS2 PRU1 IOSET1 Direct Output Mode Timings
PR2_PRU1_DIR_OUT_MANUAL2	PRU-ICSS2 PRU1 IOSET2 Direct Output Mode Timings
PR2_PRU0_PAR_CAP_MANUAL1	PRU-ICSS2 PRU0 IOSET1 Parallel Capture Mode Timings
PR2_PRU0_PAR_CAP_MANUAL2	PRU-ICSS2 PRU0 IOSET2 Parallel Capture Mode Timings
PR2_PRU1_PAR_CAP_MANUAL1	PRU-ICSS2 PRU1 IOSET1 Parallel Capture Mode Timings
PR2_PRU1_PAR_CAP_MANUAL2	PRU-ICSS2 PRU1 IOSET2 Parallel Capture Mode Timings
HDMI, EMIF, Timers, I2C, HDQ/1-Wire, UART, McSPI, USB, SATA, PCIe, DCAN, GPIO, KBD, PWM, ATL, JTAG, TPIU, RTC, SDMA, INTC, MLB
No Virtual or Manual IO Timing Mode Required	All Modes

7.6 Video Input Ports (VIP)

The Device includes 1 Video Input Ports (VIP)

Table 7-3, Figure 7-4 and Figure 7-5 present timings and switching characteristics of the VIPs.

CAUTION

The I/O timings provided in this section are valid only for VIN1 and VIN2 if signals within a single IOSET are used. The IOSETs are defined in Table 7-4.

Table 7-3 Timing Requirements for VIP ^{⁽³⁾⁽⁴⁾⁽⁵⁾}

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
V1	t_c(CLK)	Cycle time, vinx_clki ^{⁽³⁾ ⁽⁵⁾}	6.06 ^⁽²⁾	ns
V2	t_w(CLKH)	Pulse duration, vinx_clki high ^{⁽³⁾ ⁽⁵⁾}	0.45*P ^⁽²⁾	ns
V3	t_w(CLKL)	Pulse duration, vinx_clki low ^{⁽³⁾ ⁽⁵⁾}	0.45*P ^⁽²⁾	ns
V4	t_{su(CTL/DATA-CLK)}	Input setup time, Control (vinx_dei, vinx_vsynci, vinx_fldi, vinx_hsynci) and Data (vinx_dn) valid to vinx_clki transition ^{⁽³⁾ ⁽⁴⁾ ⁽⁵⁾}	3.11 ^⁽²⁾	ns
V6	t_{h(CLK-CTL/DATA)}	Input hold time, Control (vinx_dei, vinx_vsynci, vinx_fldi, vinx_hsynci) and Data (vinx_dn) valid from vinx_clki transition ^{⁽³⁾ ⁽⁴⁾ ⁽⁵⁾}	-0.05 ^⁽²⁾	ns

For maximum frequency of 165 MHz.
P = vinx_clki period.
x in vinx = 1a, 1b, 2a, 2b.
n in dn = 0 to 7 when x = 1b, 2b.
n = 0 to 23 when x = 1a, 2a.
i in clki, dei, vsynci, hsynci and fldi = 0 or 1.

Figure 7-4 Video Input Ports clock signal

Figure 7-5 Video Input Ports timings

In Table 7-4 and Table 7-5 are presented the specific groupings of signals (IOSET) for use with vin1 and vin2.

Table 7-4 VIN1 IOSETs

SIGNALS	IOSET2		IOSET3		IOSET4 ^⁽¹⁾		IOSET5^⁽¹⁾		IOSET6^⁽¹⁾		IOSET7^⁽¹⁾		IOSET8		IOSET9		IOSET10
SIGNALS	BALL	MUX	BALL	MUX	BALL	MUX	BALL	MUX	BALL	MUX	BALL	MUX	BALL	MUX	BALL	MUX	BALL	MUX
vin1a
vin1a_clk0	P1	2	B11	4	B11	3	P4	4	P4	4	B26	8	AC5	9	E17	7	E17	7
vin1a_hsync0	N7	2	C11	4	C11	3	R3	4	P7	4	E21	8	AB8	9	F12	7	F12	7
vin1a_vsync0	R4	2	E11	4	E11	3	T2	4	N1	4	F20	8	AB5	9	G12	7	G12	7
vin1a_fld0	P9	2	D11	4	D11	3	P9	4	J7	4	F21	8	C17	9	C14	7	C14	7
vin1a_de0	N9	2	B10	4	B10	3	P7	5	H6	4	C23	8	AB4	9	D14	7	D14	7
vin1a_d0	M6	2	B7	4	B7	3	R6	4	R6	4	B14	8	AD6	9	D18	7	C17	7
vin1a_d1	M2	2	B8	4	B8	3	T9	4	T9	4	J14	8	AC8	9	B19	7	B19	7
vin1a_d2	L5	2	A7	4	A7	3	T6	4	T6	4	G13	8	AC3	9	F15	7	F15	7
vin1a_d3	M1	2	A8	4	A8	3	T7	4	T7	4	J11	8	AC9	9	B18	7	B18	7
vin1a_d4	L6	2	C9	4	C9	3	P6	4	P6	4	E12	8	AC6	9	A16	7	A16	7
vin1a_d5	L4	2	A9	4	A9	3	R9	4	R9	4	F13	8	AC7	9	C15	7	C15	7
vin1a_d6	L3	2	B9	4	B9	3	R5	4	R5	4	C12	8	AC4	9	A18	7	A18	7
vin1a_d7	L2	2	A10	4	A10	3	P5	4	P5	4	D12	8	AD4	9	A19	7	A19	7
vin1a_d8	L1	2	E8	4	E8	3	U2	4	U2	4	E15	8	AA4	9	F14	7	F14	7
vin1a_d9	K2	2	D9	4	D9	3	U1	4	U1	4	A20	8	AB3	9	G14	7	G14	7
vin1a_d10	J1	2	D7	4	D7	3	P3	4	P3	4	B15	8	AB9	9	A13	7	A13	7
vin1a_d11	J2	2	D8	4	D8	3	R2	4	R2	4	A15	8	AA3	9	E14	7	E14	7
vin1a_d12	H1	2	A5	4	A5	3	K7	4	K7	4	D15	8	D17	9	A12	7	A12	7
vin1a_d13	J3	2	C6	4	C6	3	M7	4	M7	4	B16	8	G16	9	B13	7	B13	7
vin1a_d14	H2	2	C8	4	C8	3	J5	4	J5	4	B17	8	A21	9	A11	7	A11	7
vin1a_d15	H3	2	C7	4	C7	3	K6	4	K6	4	A17	8	C18	9	B12	7	B12	7
vin1a_d16	R6	2	F11	4	F11	3					C18	8
vin1a_d17	T9	2	G10	4	G10	3					A21	8
vin1a_d18	T6	2	F10	4	F10	3					G16	8
vin1a_d19	T7	2	G11	4	G11	3					D17	8
vin1a_d20	P6	2	E9	4	E9	3					AA3	8
vin1a_d21	R9	2	F9	4	F9	3					AB9	8
vin1a_d22	R5	2	F8	4	F8	3					AB3	8
vin1a_d23	P5	2	E7	4	E7	3					AA4	8
vin1b
vin1b_clk1					P7	6	M4	4	V1	5	N9	6
vin1b_hsync1					H5	6	H5	6	U7	5	N7	6
vin1b_vsync1					H6	6	H6	6	V6	5	R4	6
vin1b_fld1					M4	6			W2	5	P4	6
vin1b_de1					N6	6	N6	6	V7	5	P9	6
vin1b_d0					K7	6	K7	6	U4	5	R6	6
vin1b_d1					M7	6	M7	6	V2	5	T9	6
vin1b_d2					J5	6	J5	6	Y1	5	T6	6
vin1b_d3					K6	6	K6	6	W9	5	T7	6
vin1b_d4					J7	6	J7	6	V9	5	P6	6
vin1b_d5					J4	6	J4	6	U5	5	R9	6
vin1b_d6					J6	6	J6	6	V5	5	R5	6
vin1b_d7					H4	6	H4	6	V4	5	P5	6

The IOSET under this column is only applicable for pins with alternate functionality which allows either VIN1 or VIN2 signals to be mapped to the pins. These alternate functions are controlled via CTRL_CORE_VIP_MUX_SELECT register. For more information on how to use these options, please refer to Device TRM, chapter Control Module, section Pad Configuration Registers.

Table 7-5 VIN2 IOSETs

SIGNALS	IOSET1		IOSET2		IOSET4		IOSET5		IOSET6		IOSET7^⁽¹⁾		IOSET8^⁽¹⁾		IOSET9^⁽¹⁾		IOSET10^⁽¹⁾		IOSET11
SIGNALS	BALL	MUX	BALL	MUX	BALL	MUX	BALL	MUX	BALL	MUX	BALL	MUX	BALL	MUX	BALL	MUX	BALL	MUX	BALL	MUX
vin2a
vin2a_clk0					E1	0	E1	0	V1	4	B11	3	P4	4	P4	4	B26	8
vin2a_hsync0					G1	0	G1	0	U7	4	C11	3	R3	4	P7	4	E21	8
vin2a_vsync0					G6	0	G6	0	V6	4	E11	3	T2	4	N1	4	F20	8
vin2a_fld0					H7	0	G2	1	W2	4	D11	3	P9	4	J7	4	F21	8
vin2a_de0					G2	0			V7	4	B10	3	P7	5	H6	4	C23	8
vin2a_d0					F2	0	F2	0	U4	4	B7	3	R6	4	R6	4	B14	8
vin2a_d1					F3	0	F3	0	V2	4	B8	3	T9	4	T9	4	J14	8
vin2a_d2					D1	0	D1	0	Y1	4	A7	3	T6	4	T6	4	G13	8
vin2a_d3					E2	0	E2	0	W9	4	A8	3	T7	4	T7	4	J11	8
vin2a_d4					D2	0	D2	0	V9	4	C9	3	P6	4	P6	4	E12	8
vin2a_d5					F4	0	F4	0	U5	4	A9	3	R9	4	R9	4	F13	8
vin2a_d6					C1	0	C1	0	V5	4	B9	3	R5	4	R5	4	C12	8
vin2a_d7					E4	0	E4	0	V4	4	A10	3	P5	4	P5	4	D12	8
vin2a_d8					F5	0	F5	0	V3	4	E8	3	U2	4	U2	4	E15	8
vin2a_d9					E6	0	E6	0	Y2	4	D9	3	U1	4	U1	4	A20	8
vin2a_d10					D3	0	D3	0	U6	4	D7	3	P3	4	P3	4	B15	8
vin2a_d11					F6	0	F6	0	U3	4	D8	3	R2	4	R2	4	A15	8
vin2a_d12					D5	0	D5	0			A5	3	K7	4	K7	4	D15	8
vin2a_d13					C2	0	C2	0			C6	3	M7	4	M7	4	B16	8
vin2a_d14					C3	0	C3	0			C8	3	J5	4	J5	4	B17	8
vin2a_d15					C4	0	C4	0			C7	3	K6	4	K6	4	A17	8
vin2a_d16					B2	0	B2	0			F11	3					C18	8
vin2a_d17					D6	0	D6	0			G10	3					A21	8
vin2a_d18					C5	0	C5	0			F10	3					G16	8
vin2a_d19					A3	0	A3	0			G11	3					D17	8
vin2a_d20					B3	0	B3	0			E9	3					AA3	8
vin2a_d21					B4	0	B4	0			F9	3					AB9	8
vin2a_d22					B5	0	B5	0			F8	3					AB3	8
vin2a_d23					A4	0	A4	0			E7	3					AA4	8
vin2b
vin2b_clk1	P7	6	M4	4							H7	2	H7	2	AB5	4	P7	6	M4	4
vin2b_hsync1	H5	6	H5	6							G1	3	G1	3	AC5	4	H5	6	H5	6
vin2b_vsync1	H6	6	H6	6							G6	3	G6	3	AB4	4	H6	6	H6	6
vin2b_fld1	M4	6											G2	2			M4	6
vin2b_de1	N6	6	N6	6							G2	3			AB8	4	N6	6	N6	6
vin2b_d0	K7	6	K7	6							A4	2	A4	2	AD6	4	K7	6	K7	6
vin2b_d1	M7	6	M7	6							B5	2	B5	2	AC8	4	M7	6	M7	6
vin2b_d2	J5	6	J5	6							B4	2	B4	2	AC3	4	J5	6	J5	6
vin2b_d3	K6	6	K6	6							B3	2	B3	2	AC9	4	K6	6	K6	6
vin2b_d4	J7	6	J7	6							A3	2	A3	2	AC6	4	J7	6	J7	6
vin2b_d5	J4	6	J4	6							C5	2	C5	2	AC7	4	J4	6	J4	6
vin2b_d6	J6	6	J6	6							D6	2	D6	2	AC4	4	J6	6	J6	6
vin2b_d7	H4	6	H4	6							B2	2	B2	2	AD4	4	H4	6	H4	6

The IOSET under this column is only applicable for pins with alternate functionality which allows either VIN1 or VIN2 signals to be mapped to the pins. These alternate functions are controlled via CTRL_CORE_VIP_MUX_SELECT register. For more information on how to use these options, please refer to Device TRM, chapter Control Module, section Pad Configuration Registers.

NOTE

To configure the desired Manual IO Timing Mode the user must follow the steps described in section "Manual IO Timing Modes" of the Device TRM.

The associated registers to configure are listed in the CFG REGISTER column. For more information please see the Control Module chapter in the Device TRM.

Manual IO Timings Modes must be used to guaranteed some IO timings for VIP1. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Manual Functions Mapping for VIP1 1A IOSET7 and 2A IOSET10 for a definition of the Manual modes.

Table 7-6 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-6 Manual Functions Mapping for VIP1 1A IOSET7 and 2A IOSET10

BALL	BALL NAME	VIP_MANUAL1		VIP_MANUAL2		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	8	8^⁽¹⁾
E21	gpio6_14	1400	240	1767	0	CFG_GPIO6_14_IN	vin2a_hsync0	vin1a_hsync0
F20	gpio6_15	1170	240	1522	0	CFG_GPIO6_15_IN	vin2a_vsync0	vin1a_vsync0
F21	gpio6_16	1470	0	1600	0	CFG_GPIO6_16_IN	vin2a_fld0	vin1a_fld0
B14	mcasp1_aclkr	2145	200	2509	0	CFG_MCASP1_ACLKR_IN	vin2a_d0	vin1a_d0
G13	mcasp1_axr2	2740	900	2680	1180	CFG_MCASP1_AXR2_IN	vin2a_d2	vin1a_d2
J11	mcasp1_axr3	2933	200	2700	600	CFG_MCASP1_AXR3_IN	vin2a_d3	vin1a_d3
E12	mcasp1_axr4	2901	240	2660	700	CFG_MCASP1_AXR4_IN	vin2a_d4	vin1a_d4
F13	mcasp1_axr5	2600	840	2640	920	CFG_MCASP1_AXR5_IN	vin2a_d5	vin1a_d5
C12	mcasp1_axr6	2718	240	3081	0	CFG_MCASP1_AXR6_IN	vin2a_d6	vin1a_d6
D12	mcasp1_axr7	2983	240	2540	800	CFG_MCASP1_AXR7_IN	vin2a_d7	vin1a_d7
J14	mcasp1_fsr	2203	240	2566	0	CFG_MCASP1_FSR_IN	vin2a_d1	vin1a_d1
E15	mcasp2_aclkr	2143	240	2492	0	CFG_MCASP2_ACLKR_IN	vin2a_d8	vin1a_d8
B15	mcasp2_axr0	2543	240	2905	0	CFG_MCASP2_AXR0_IN	vin2a_d10	vin1a_d10
A15	mcasp2_axr1	2664	240	2730	400	CFG_MCASP2_AXR1_IN	vin2a_d11	vin1a_d11
D15	mcasp2_axr4	2792	240	2750	400	CFG_MCASP2_AXR4_IN	vin2a_d12	vin1a_d12
B16	mcasp2_axr5	2621	300	2983	0	CFG_MCASP2_AXR5_IN	vin2a_d13	vin1a_d13
B17	mcasp2_axr6	1903	100	2086	0	CFG_MCASP2_AXR6_IN	vin2a_d14	vin1a_d14
A17	mcasp2_axr7	2928	200	2670	700	CFG_MCASP2_AXR7_IN	vin2a_d15	vin1a_d15
A20	mcasp2_fsr	2291	200	2654	0	CFG_MCASP2_FSR_IN	vin2a_d9	vin1a_d9
C18	mcasp4_aclkx	1433	0	1540	0	CFG_MCASP4_ACLKX_IN	vin2a_d16	vin1a_d16
G16	mcasp4_axr0	2500	0	2560	0	CFG_MCASP4_AXR0_IN	vin2a_d18	vin1a_d18
D17	mcasp4_axr1	2379	100	2599	0	CFG_MCASP4_AXR1_IN	vin2a_d19	vin1a_d19
A21	mcasp4_fsx	1500	1400	1900	1040	CFG_MCASP4_FSX_IN	vin2a_d17	vin1a_d17
AA3	mcasp5_aclkx	3740	1850	3900	1700	CFG_MCASP5_ACLKX_IN	vin2a_d20	vin1a_d20
AB3	mcasp5_axr0	3800	2760	3800	2800	CFG_MCASP5_AXR0_IN	vin2a_d22	vin1a_d22
AA4	mcasp5_axr1	4099	2500	3900	2870	CFG_MCASP5_AXR1_IN	vin2a_d23	vin1a_d23
AB9	mcasp5_fsx	3740	2100	3860	2060	CFG_MCASP5_FSX_IN	vin2a_d21	vin1a_d21
B26	xref_clk2	0	0	0	0	CFG_XREF_CLK2_IN	vin2a_clk0	vin1a_clk0
C23	xref_clk3	1440	0	1623	0	CFG_XREF_CLK3_IN	vin2a_de0	vin1a_de0

Some signals listed are manual functions that present alternate multiplexing options. These manual functions are controlled via CTRL_CORE_ALT_SELECT_MUX or CTRL_CORE_VIP_MUX_SELECT registers. For more information on how to use these options, please refer to Device TRM, Chapter Control Module, Section Pad Configuration Registers.

Manual IO Timings Modes must be used to guaranteed some IO timings for VIP1. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-7 Manual Functions Mapping for VIN2A (IOSET4/5/6) for a definition of the Manual modes.

Table 7-7 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-7 Manual Functions Mapping for VIN2A (IOSET4/5/6)

BALL	BALL NAME	VIP_MANUAL3		VIP_MANUAL5		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	0	1	2	3	4
U3	RMII_MHZ_50_CLK	2616	1379	2798	1294	CFG_RMII_MHZ_50_CLK_IN	-	-	-	-	vin2a_d11
U4	mdio_d	2558	1105	2790	954	CFG_MDIO_D_IN	-	-	-	-	vin2a_d0
V1	mdio_mclk	998	463	1029	431	CFG_MDIO_MCLK_IN	-	-	-	-	vin2a_clk0
U5	rgmii0_rxc	2658	862	2896	651	CFG_RGMII0_RXC_IN	-	-	-	-	vin2a_d5
V5	rgmii0_rxctl	2658	1628	2844	1518	CFG_RGMII0_RXCTL_IN	-	-	-	-	vin2a_d6
W2	rgmii0_rxd0	2638	1123	2856	888	CFG_RGMII0_RXD0_IN	-	-	-	-	vin2a_fld0
Y2	rgmii0_rxd1	2641	1737	2804	1702	CFG_RGMII0_RXD1_IN	-	-	-	-	vin2a_d9
V3	rgmii0_rxd2	2641	1676	2801	1652	CFG_RGMII0_RXD2_IN	-	-	-	-	vin2a_d8
V4	rgmii0_rxd3	2644	1828	2807	1790	CFG_RGMII0_RXD3_IN	-	-	-	-	vin2a_d7
W9	rgmii0_txc	2638	1454	2835	1396	CFG_RGMII0_TXC_IN	-	-	-	-	vin2a_d3
V9	rgmii0_txctl	2672	1663	2831	1640	CFG_RGMII0_TXCTL_IN	-	-	-	-	vin2a_d4
U6	rgmii0_txd0	2604	1442	2764	1417	CFG_RGMII0_TXD0_IN	-	-	-	-	vin2a_d10
V6	rgmii0_txd1	2683	1598	2843	1600	CFG_RGMII0_TXD1_IN	-	-	-	-	vin2a_vsync0
U7	rgmii0_txd2	2563	1483	2816	1344	CFG_RGMII0_TXD2_IN	-	-	-	-	vin2a_hsync0
V7	rgmii0_txd3	2717	1461	2913	1310	CFG_RGMII0_TXD3_IN	-	-	-	-	vin2a_de0
V2	uart3_rxd	2445	1145	2743	923	CFG_UART3_RXD_IN	-	-	-	-	vin2a_d1
Y1	uart3_txd	2650	1197	2842	1080	CFG_UART3_TXD_IN	-	-	-	-	vin2a_d2
E1	vin2a_clk0	0	0	0	0	CFG_VIN2A_CLK0_IN	vin2a_clk0	-	-	-	-
F2	vin2a_d0	1812	102	1936	0	CFG_VIN2A_D0_IN	vin2a_d0	-	-	-	-
F3	vin2a_d1	1701	439	2229	10	CFG_VIN2A_D1_IN	vin2a_d1	-	-	-	-
D3	vin2a_d10	1720	215	2031	0	CFG_VIN2A_D10_IN	vin2a_d10	-	-	-	-
F6	vin2a_d11	1622	0	1702	0	CFG_VIN2A_D11_IN	vin2a_d11	-	-	-	-
D5	vin2a_d12	1350	412	1819	0	CFG_VIN2A_D12_IN	vin2a_d12	-	-	-	-
C2	vin2a_d13	1613	147	1476	260	CFG_VIN2A_D13_IN	vin2a_d13	-	-	-	-
C3	vin2a_d14	1149	516	1701	0	CFG_VIN2A_D14_IN	vin2a_d14	-	-	-	-
C4	vin2a_d15	1530	450	2021	0	CFG_VIN2A_D15_IN	vin2a_d15	-	-	-	-
B2	vin2a_d16	1512	449	2044	11	CFG_VIN2A_D16_IN	vin2a_d16	-	vin2b_d7	-	-
D6	vin2a_d17	1293	488	1839	5	CFG_VIN2A_D17_IN	vin2a_d17	-	vin2b_d6	-	-
C5	vin2a_d18	2140	371	2494	0	CFG_VIN2A_D18_IN	vin2a_d18	-	vin2b_d5	-	-
A3	vin2a_d19	2041	275	1699	611	CFG_VIN2A_D19_IN	vin2a_d19	-	vin2b_d4	-	-
D1	vin2a_d2	1675	35	1736	0	CFG_VIN2A_D2_IN	vin2a_d2	-	-	-	-
B3	vin2a_d20	1972	441	2412	88	CFG_VIN2A_D20_IN	vin2a_d20	-	vin2b_d3	-	-
B4	vin2a_d21	1957	556	2391	161	CFG_VIN2A_D21_IN	vin2a_d21	-	vin2b_d2	-	-
B5	vin2a_d22	2011	433	2446	102	CFG_VIN2A_D22_IN	vin2a_d22	-	vin2b_d1	-	-
A4	vin2a_d23	1962	523	2395	145	CFG_VIN2A_D23_IN	vin2a_d23	-	vin2b_d0	-	-
E2	vin2a_d3	1457	361	1943	0	CFG_VIN2A_D3_IN	vin2a_d3	-	-	-	-
D2	vin2a_d4	1535	0	1601	0	CFG_VIN2A_D4_IN	vin2a_d4	-	-	-	-
F4	vin2a_d5	1676	271	2052	0	CFG_VIN2A_D5_IN	vin2a_d5	-	-	-	-
C1	vin2a_d6	1513	0	1571	0	CFG_VIN2A_D6_IN	vin2a_d6	-	-	-	-
E4	vin2a_d7	1616	141	1855	0	CFG_VIN2A_D7_IN	vin2a_d7	-	-	-	-
F5	vin2a_d8	1286	437	1224	618	CFG_VIN2A_D8_IN	vin2a_d8	-	-	-	-
E6	vin2a_d9	1544	265	1373	509	CFG_VIN2A_D9_IN	vin2a_d9	-	-	-	-
G2	vin2a_de0	1732	208	1949	0	CFG_VIN2A_DE0_IN	vin2a_de0	vin2a_fld0	vin2b_fld1	vin2b_de1	-
H7	vin2a_fld0	1461	562	1983	151	CFG_VIN2A_FLD0_IN	vin2a_fld0	-	vin2b_clk1	-	-
G1	vin2a_hsync0	1877	0	1943	0	CFG_VIN2A_HSYNC0_IN	vin2a_hsync0	-	-	vin2b_hsync1	-
G6	vin2a_vsync0	1566	0	1612	0	CFG_VIN2A_VSYNC0_IN	vin2a_vsync0	-	-	vin2b_vsync1	-

Manual IO Timings Modes must be used to guaranteed some IO timings for VIP1. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-8 Manual Functions Mapping for VIN2B (IOSET7/8/9) for a definition of the Manual modes.

Table 7-8 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-8 Manual Functions Mapping for VIN2B (IOSET7/8/9)

BALL	BALL NAME	VIP_MANUAL4		VIP_MANUAL6		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	2	3	4
AC5	gpio6_10	2829	884	3009	892	CFG_GPIO6_10_IN	-	-	vin2b_hsync1
AB4	gpio6_11	2648	1033	2890	1096	CFG_GPIO6_11_IN	-	-	vin2b_vsync1
AD4	mmc3_clk	2794	1074	2997	1089	CFG_MMC3_CLK_IN	-	-	vin2b_d7
AC4	mmc3_cmd	2789	1162	2959	1210	CFG_MMC3_CMD_IN	-	-	vin2b_d6
AC7	mmc3_dat0	2689	1180	2897	1269	CFG_MMC3_DAT0_IN	-	-	vin2b_d5
AC6	mmc3_dat1	2605	1219	2891	1219	CFG_MMC3_DAT1_IN	-	-	vin2b_d4
AC9	mmc3_dat2	2616	703	2947	590	CFG_MMC3_DAT2_IN	-	-	vin2b_d3
AC3	mmc3_dat3	2760	1235	2931	1342	CFG_MMC3_DAT3_IN	-	-	vin2b_d2
AC8	mmc3_dat4	2757	880	2979	891	CFG_MMC3_DAT4_IN	-	-	vin2b_d1
AD6	mmc3_dat5	2688	1177	2894	1262	CFG_MMC3_DAT5_IN	-	-	vin2b_d0
AB8	mmc3_dat6	2638	1165	2894	1187	CFG_MMC3_DAT6_IN	-	-	vin2b_de1
AB5	mmc3_dat7	995	182	1202	107	CFG_MMC3_DAT7_IN	-	-	vin2b_clk1
B2	vin2a_d16	1423	0	1739	0	CFG_VIN2A_D16_IN	vin2b_d7	-	-
D6	vin2a_d17	1253	0	1568	0	CFG_VIN2A_D17_IN	vin2b_d6	-	-
C5	vin2a_d18	2080	0	2217	0	CFG_VIN2A_D18_IN	vin2b_d5	-	-
A3	vin2a_d19	1849	0	2029	0	CFG_VIN2A_D19_IN	vin2b_d4	-	-
B3	vin2a_d20	1881	50	2202	0	CFG_VIN2A_D20_IN	vin2b_d3	-	-
B4	vin2a_d21	1917	167	2313	0	CFG_VIN2A_D21_IN	vin2b_d2	-	-
B5	vin2a_d22	1955	79	2334	0	CFG_VIN2A_D22_IN	vin2b_d1	-	-
A4	vin2a_d23	1899	145	2288	0	CFG_VIN2A_D23_IN	vin2b_d0	-	-
G2	vin2a_de0	1568	261	2048	0	CFG_VIN2A_DE0_IN	vin2b_fld1	vin2b_de1	-
H7	vin2a_fld0	0	0	0	0	CFG_VIN2A_FLD0_IN	vin2b_clk1	-	-
G1	vin2a_hsync0	1793	0	2011	0	CFG_VIN2A_HSYNC0_IN	-	vin2b_hsync1	-
G6	vin2a_vsync0	1382	0	1632	0	CFG_VIN2A_VSYNC0_IN	-	vin2b_vsync1	-

Manual IO Timings Modes must be used to guaranteed some IO timings for VIP1. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-9 Manual Functions Mapping for VIN1A (IOSET2/3/4) and VIN1B (IOSET4/7) and VIN2B (IOSET1/10) for a definition of the Manual modes.

Table 7-9 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-9 Manual Functions Mapping for VIN1A (IOSET2/3/4) and VIN1B (IOSET4/7) and VIN2B (IOSET1/10)

BALL	BALL NAME	VIP_MANUAL7		VIP_MANUAL12		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	2	3^⁽¹⁾	3^⁽¹⁾	4^⁽¹⁾	4^⁽¹⁾	5	6⁽¹⁾	6⁽¹⁾
R6	gpmc_a0	3080	1792	3376	1632	CFG_GPMC_A0_IN	vin1a_d16	-	-	vin2a_d0	-	-	vin1b_d0	-
T9	gpmc_a1	2958	1890	3249	1749	CFG_GPMC_A1_IN	vin1a_d17	-	-	vin2a_d1	-	-	vin1b_d1	-
N9	gpmc_a10	3073	1653	3388	1433	CFG_GPMC_A10_IN	vin1a_de0	-	-	-	-	-	vin1b_clk1	-
P9	gpmc_a11	3014	1784	3290	1693	CFG_GPMC_A11_IN	vin1a_fld0	-	-	vin2a_fld0	vin1a_fld0	-	vin1b_de1	-
K7	gpmc_a19	1385	0	1246	0	CFG_GPMC_A19_IN	-	-	-	vin2a_d12	-	-	vin2b_d0	vin1b_d0
T6	gpmc_a2	3041	1960	3322	1850	CFG_GPMC_A2_IN	vin1a_d18	-	-	vin2a_d2	-	-	vin1b_d2	-
M7	gpmc_a20	859	0	720	0	CFG_GPMC_A20_IN	-	-	-	vin2a_d13	-	-	vin2b_d1	vin1b_d1
J5	gpmc_a21	1465	0	1334	0	CFG_GPMC_A21_IN	-	-	-	vin2a_d14	-	-	vin2b_d2	vin1b_d2
K6	gpmc_a22	1210	0	1064	0	CFG_GPMC_A22_IN	-	-	-	vin2a_d15	-	-	vin2b_d3	vin1b_d3
J7	gpmc_a23	1111	0	954	0	CFG_GPMC_A23_IN	-	-	-	vin2a_fld0	-	-	vin2b_d4	vin1b_d4
J4	gpmc_a24	1137	0	1051	0	CFG_GPMC_A24_IN	-	-	-	-	-	-	vin2b_d5	vin1b_d5
J6	gpmc_a25	1402	0	1283	0	CFG_GPMC_A25_IN	-	-	-	-	-	-	vin2b_d6	vin1b_d6
H4	gpmc_a26	1298	0	1153	0	CFG_GPMC_A26_IN	-	-	-	-	-	-	vin2b_d7	vin1b_d7
H5	gpmc_a27	934	0	870	0	CFG_GPMC_A27_IN	-	-	-	-	-	-	vin2b_hsync1	vin1b_hsync1
T7	gpmc_a3	3019	2145	3296	2050	CFG_GPMC_A3_IN	vin1a_d19	-	-	vin2a_d3	-	-	vin1b_d3	-
P6	gpmc_a4	3063	1981	3357	1829	CFG_GPMC_A4_IN	vin1a_d20	-	-	vin2a_d4	-	-	vin1b_d4	-
R9	gpmc_a5	3021	1954	3304	1840	CFG_GPMC_A5_IN	vin1a_d21	-	-	vin2a_d5	-	-	vin1b_d5	-
R5	gpmc_a6	3062	1716	3348	1592	CFG_GPMC_A6_IN	vin1a_d22	-	-	vin2a_d6	-	-	vin1b_d6	-
P5	gpmc_a7	3260	1889	3583	1631	CFG_GPMC_A7_IN	vin1a_d23	-	-	vin2a_d7	-	-	vin1b_d7	-
N7	gpmc_a8	3033	1702	3328	1547	CFG_GPMC_A8_IN	vin1a_hsync0	-	-	-	-	-	vin1b_hsync1	-
R4	gpmc_a9	2991	1905	3281	1766	CFG_GPMC_A9_IN	vin1a_vsync0	-	-	-	-	-	vin1b_vsync1	-
M6	gpmc_ad0	2907	1342	3181	1255	CFG_GPMC_AD0_IN	vin1a_d0	-	-	-	-	-	-	-
M2	gpmc_ad1	2858	1321	3132	1234	CFG_GPMC_AD1_IN	vin1a_d1	-	-	-	-	-	-	-
J1	gpmc_ad10	2920	1384	3223	1204	CFG_GPMC_AD10_IN	vin1a_d10	-	-	-	-	-	-	-
J2	gpmc_ad11	2719	1310	3019	1198	CFG_GPMC_AD11_IN	vin1a_d11	-	-	-	-	-	-	-
H1	gpmc_ad12	2845	1135	3160	917	CFG_GPMC_AD12_IN	vin1a_d12	-	-	-	-	-	-	-
J3	gpmc_ad13	2765	1225	3045	1119	CFG_GPMC_AD13_IN	vin1a_d13	-	-	-	-	-	-	-
H2	gpmc_ad14	2845	1150	3153	952	CFG_GPMC_AD14_IN	vin1a_d14	-	-	-	-	-	-	-
H3	gpmc_ad15	2766	1453	3044	1355	CFG_GPMC_AD15_IN	vin1a_d15	-	-	-	-	-	-	-
L5	gpmc_ad2	2951	1296	3226	1209	CFG_GPMC_AD2_IN	vin1a_d2	-	-	-	-	-	-	-
M1	gpmc_ad3	2825	1154	3121	997	CFG_GPMC_AD3_IN	vin1a_d3	-	-	-	-	-	-	-
L6	gpmc_ad4	2927	1245	3246	1014	CFG_GPMC_AD4_IN	vin1a_d4	-	-	-	-	-	-	-
L4	gpmc_ad5	2923	1251	3217	1098	CFG_GPMC_AD5_IN	vin1a_d5	-	-	-	-	-	-	-
L3	gpmc_ad6	2958	1342	3238	1239	CFG_GPMC_AD6_IN	vin1a_d6	-	-	-	-	-	-	-
L2	gpmc_ad7	2900	1244	3174	1157	CFG_GPMC_AD7_IN	vin1a_d7	-	-	-	-	-	-	-
L1	gpmc_ad8	2845	1585	3125	1482	CFG_GPMC_AD8_IN	vin1a_d8	-	-	-	-	-	-	-
K2	gpmc_ad9	2779	1343	3086	1223	CFG_GPMC_AD9_IN	vin1a_d9	-	-	-	-	-	-	-
N6	gpmc_ben0	1555	0	1425	0	CFG_GPMC_BEN0_IN	-	-	-	-	-	-	vin2b_de1	vin1b_de1
M4	gpmc_ben1	1501	0	1397	0	CFG_GPMC_BEN1_IN	-	-	-	vin2b_clk1	-	-	vin2b_fld1	vin1b_fld1
P7	gpmc_clk	0	0	0	0	CFG_GPMC_CLK_IN	-	-	-	vin2a_hsync0	-	vin2a_de0	vin2b_clk1	vin1b_clk1
H6	gpmc_cs1	1192	0	1102	0	CFG_GPMC_CS1_IN	-	-	-	vin2a_de0	-	-	vin2b_vsync1	vin1b_vsync1
P1	gpmc_cs3	1324	374	1466	353	CFG_GPMC_CS3_IN	vin1a_clk0	-	-	-	-	-	-	-
D11	vout1_clk	1648	885	1762	928	CFG_VOUT1_CLK_IN	-	vin2a_fld0	vin1a_fld0	vin1a_fld0	-	-	-	-
F11	vout1_d0	2197	565	2734	215	CFG_VOUT1_D0_IN	-	vin2a_d16	vin1a_d16	vin1a_d16	-	-	-	-
G10	vout1_d1	2221	576	2750	230	CFG_VOUT1_D1_IN	-	vin2a_d17	vin1a_d17	vin1a_d17	-	-	-	-
D7	vout1_d10	1800	863	1910	916	CFG_VOUT1_D10_IN	-	vin2a_d10	vin1a_d10	vin1a_d10	-	-	-	-
D8	vout1_d11	1656	931	1780	945	CFG_VOUT1_D11_IN	-	vin2a_d11	vin1a_d11	vin1a_d11	-	-	-	-
A5	vout1_d12	1719	1086	1866	1041	CFG_VOUT1_D12_IN	-	vin2a_d12	vin1a_d12	vin1a_d12	-	-	-	-
C6	vout1_d13	1757	928	1851	1022	CFG_VOUT1_D13_IN	-	vin2a_d13	vin1a_d13	vin1a_d13	-	-	-	-
C8	vout1_d14	2279	345	2788	0	CFG_VOUT1_D14_IN	-	vin2a_d14	vin1a_d14	vin1a_d14	-	-	-	-
C7	vout1_d15	1810	874	2786	69	CFG_VOUT1_D15_IN	-	vin2a_d15	vin1a_d15	vin1a_d15	-	-	-	-
B7	vout1_d16	1763	774	1880	807	CFG_VOUT1_D16_IN	-	vin2a_d0	vin1a_d0	vin1a_d0	-	-	-	-
B8	vout1_d17	1695	788	1805	838	CFG_VOUT1_D17_IN	-	vin2a_d1	vin1a_d1	vin1a_d1	-	-	-	-
A7	vout1_d18	1777	590	1871	684	CFG_VOUT1_D18_IN	-	vin2a_d2	vin1a_d2	vin1a_d2	-	-	-	-
A8	vout1_d19	2047	22	2196	0	CFG_VOUT1_D19_IN	-	vin2a_d3	vin1a_d3	vin1a_d3	-	-	-	-
F10	vout1_d2	1809	941	2759	178	CFG_VOUT1_D2_IN	-	vin2a_d18	vin1a_d18	vin1a_d18	-	-	-	-
C9	vout1_d20	1676	944	1795	973	CFG_VOUT1_D20_IN	-	vin2a_d4	vin1a_d4	vin1a_d4	-	-	-	-
A9	vout1_d21	1712	688	1848	670	CFG_VOUT1_D21_IN	-	vin2a_d5	vin1a_d5	vin1a_d5	-	-	-	-
B9	vout1_d22	1698	557	2443	0	CFG_VOUT1_D22_IN	-	vin2a_d6	vin1a_d6	vin1a_d6	-	-	-	-
A10	vout1_d23	1627	1035	1726	1116	CFG_VOUT1_D23_IN	-	vin2a_d7	vin1a_d7	vin1a_d7	-	-	-	-
G11	vout1_d3	2427	429	2853	167	CFG_VOUT1_D3_IN	-	vin2a_d19	vin1a_d19	vin1a_d19	-	-	-	-
E9	vout1_d4	2351	412	2845	85	CFG_VOUT1_D4_IN	-	vin2a_d20	vin1a_d20	vin1a_d20	-	-	-	-
F9	vout1_d5	1634	983	1729	1076	CFG_VOUT1_D5_IN	-	vin2a_d21	vin1a_d21	vin1a_d21	-	-	-	-
F8	vout1_d6	1776	880	2736	107	CFG_VOUT1_D6_IN	-	vin2a_d22	vin1a_d22	vin1a_d22	-	-	-	-
E7	vout1_d7	2272	351	2757	53	CFG_VOUT1_D7_IN	-	vin2a_d23	vin1a_d23	vin1a_d23	-	-	-	-
E8	vout1_d8	1724	898	1819	990	CFG_VOUT1_D8_IN	-	vin2a_d8	vin1a_d8	vin1a_d8	-	-	-	-
D9	vout1_d9	2281	566	2804	195	CFG_VOUT1_D9_IN	-	vin2a_d9	vin1a_d9	vin1a_d9	-	-	-	-
B10	vout1_de	1734	749	1828	842	CFG_VOUT1_DE_IN	-	vin2a_de0	vin1a_de0	vin1a_de0	-	-	-	-
B11	vout1_fld	0	0	0	0	CFG_VOUT1_FLD_IN	-	vin2a_clk0	vin1a_clk0	vin1a_clk0	-	-	-	-
C11	vout1_hsync	1634	606	2399	0	CFG_VOUT1_HSYNC_IN	-	vin2a_hsync0	vin1a_hsync0	vin1a_hsync0	-	-	-	-
E11	vout1_vsync	1887	0	2068	0	CFG_VOUT1_VSYNC_IN	-	vin2a_vsync0	vin1a_vsync0	vin1a_vsync0	-	-	-	-

Some signals listed are manual functions that present alternate multiplexing options. These manual functions are controlled via CTRL_CORE_ALT_SELECT_MUX or CTRL_CORE_VIP_MUX_SELECT registers. For more information on how to use these options, please refer to Device TRM, Chapter Control Module, Section Pad Configuration Registers.

Manual IO Timings Modes must be used to guaranteed some IO timings for VIP1. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-10 Manual Functions Mapping for VIN1A (IOSET5/6) and VIN2A (IOSET7/8/9) for a definition of the Manual modes.

Table 7-10 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-10 Manual Functions Mapping for VIN1A (IOSET5/6) and VIN2A (IOSET7/8/9)

BALL	BALL NAME	VIP_MANUAL8		VIP_MANUAL13		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	3	4^⁽¹⁾	4^⁽¹⁾	5^⁽¹⁾	5^⁽¹⁾
R6	gpmc_a0	1891	427	2176	0	CFG_GPMC_A0_IN	-	vin2a_d0	vin1a_d0	-	-
T9	gpmc_a1	1713	513	2109	0	CFG_GPMC_A1_IN	-	vin2a_d1	vin1a_d1	-	-
P9	gpmc_a11	1797	317	2036	0	CFG_GPMC_A11_IN	-	vin2a_fld0	vin1a_fld0	-	-
P4	gpmc_a12	0	0	0	0	CFG_GPMC_A12_IN	-	vin2a_clk0	vin1a_clk0	-	-
R3	gpmc_a13	1876	391	2144	0	CFG_GPMC_A13_IN	-	vin2a_hsync0	vin1a_hsync0	-	-
T2	gpmc_a14	1720	756	2384	38	CFG_GPMC_A14_IN	-	vin2a_vsync0	vin1a_vsync0	-	-
U2	gpmc_a15	1502	368	1804	0	CFG_GPMC_A15_IN	-	vin2a_d8	vin1a_d8	-	-
U1	gpmc_a16	1651	355	1902	0	CFG_GPMC_A16_IN	-	vin2a_d9	vin1a_d9	-	-
P3	gpmc_a17	1642	338	1862	0	CFG_GPMC_A17_IN	-	vin2a_d10	vin1a_d10	-	-
R2	gpmc_a18	1612	0	1406	0	CFG_GPMC_A18_IN	-	vin2a_d11	vin1a_d11	-	-
K7	gpmc_a19	1463	152	1418	0	CFG_GPMC_A19_IN	-	vin2a_d12	vin1a_d12	-	-
T6	gpmc_a2	1789	646	2310	0	CFG_GPMC_A2_IN	-	vin2a_d2	vin1a_d2	-	-
M7	gpmc_a20	1124	0	933	0	CFG_GPMC_A20_IN	-	vin2a_d13	vin1a_d13	-	-
J5	gpmc_a21	1491	206	1483	0	CFG_GPMC_A21_IN	-	vin2a_d14	vin1a_d14	-	-
K6	gpmc_a22	1218	245	1254	0	CFG_GPMC_A22_IN	-	vin2a_d15	vin1a_d15	-	-
J7	gpmc_a23	1216	0	1021	0	CFG_GPMC_A23_IN	-	vin2a_fld0	vin1a_fld0	-	-
T7	gpmc_a3	1789	766	2451	8	CFG_GPMC_A3_IN	-	vin2a_d3	vin1a_d3	-	-
P6	gpmc_a4	1842	646	2329	0	CFG_GPMC_A4_IN	-	vin2a_d4	vin1a_d4	-	-
R9	gpmc_a5	1778	556	2215	0	CFG_GPMC_A5_IN	-	vin2a_d5	vin1a_d5	-	-
R5	gpmc_a6	1783	443	2088	0	CFG_GPMC_A6_IN	-	vin2a_d6	vin1a_d6	-	-
P5	gpmc_a7	2207	370	2393	0	CFG_GPMC_A7_IN	-	vin2a_d7	vin1a_d7	-	-
N1	gpmc_advn_ale	1755	116	1745	0	CFG_GPMC_ADVN_ALE_IN	-	vin2a_vsync0	vin1a_vsync0	-	-
P7	gpmc_clk	1896	351	2152	0	CFG_GPMC_CLK_IN	-	vin2a_hsync0	vin1a_hsync0	vin2a_de0	vin1a_de0
H6	gpmc_cs1	1337	74	1288	0	CFG_GPMC_CS1_IN	-	vin2a_de0	vin1a_de0	-	-
D11	vout1_clk	1939	332	2486	0	CFG_VOUT1_CLK_IN	vin2a_fld0	-	-	-	-
F11	vout1_d0	2140	647	2617	386	CFG_VOUT1_D0_IN	vin2a_d16	-	-	-	-
G10	vout1_d1	2104	615	2620	314	CFG_VOUT1_D1_IN	vin2a_d17	-	-	-	-
D7	vout1_d10	2139	406	2675	85	CFG_VOUT1_D10_IN	vin2a_d10	-	-	-	-
D8	vout1_d11	1944	534	2569	125	CFG_VOUT1_D11_IN	vin2a_d11	-	-	-	-
A5	vout1_d12	1966	659	2646	154	CFG_VOUT1_D12_IN	vin2a_d12	-	-	-	-
C6	vout1_d13	2048	447	2624	87	CFG_VOUT1_D13_IN	vin2a_d13	-	-	-	-
C8	vout1_d14	2222	548	2700	286	CFG_VOUT1_D14_IN	vin2a_d14	-	-	-	-
C7	vout1_d15	2072	443	2664	67	CFG_VOUT1_D15_IN	vin2a_d15	-	-	-	-
B7	vout1_d16	2044	455	2634	82	CFG_VOUT1_D16_IN	vin2a_d0	-	-	-	-
B8	vout1_d17	1971	246	2433	0	CFG_VOUT1_D17_IN	vin2a_d1	-	-	-	-
A7	vout1_d18	2104	120	2440	0	CFG_VOUT1_D18_IN	vin2a_d2	-	-	-	-
A8	vout1_d19	1888	0	2105	0	CFG_VOUT1_D19_IN	vin2a_d3	-	-	-	-
F10	vout1_d2	2170	237	2624	0	CFG_VOUT1_D2_IN	vin2a_d18	-	-	-	-
C9	vout1_d20	1942	512	2579	91	CFG_VOUT1_D20_IN	vin2a_d4	-	-	-	-
A9	vout1_d21	1997	141	2324	0	CFG_VOUT1_D21_IN	vin2a_d5	-	-	-	-
B9	vout1_d22	1949	0	2165	0	CFG_VOUT1_D22_IN	vin2a_d6	-	-	-	-
A10	vout1_d23	1871	704	2522	269	CFG_VOUT1_D23_IN	vin2a_d7	-	-	-	-
G11	vout1_d3	2319	417	2740	191	CFG_VOUT1_D3_IN	vin2a_d19	-	-	-	-
E9	vout1_d4	2300	369	2739	137	CFG_VOUT1_D4_IN	vin2a_d20	-	-	-	-
F9	vout1_d5	1923	579	2527	191	CFG_VOUT1_D5_IN	vin2a_d21	-	-	-	-
F8	vout1_d6	2148	396	2622	138	CFG_VOUT1_D6_IN	vin2a_d22	-	-	-	-
E7	vout1_d7	2212	335	2653	110	CFG_VOUT1_D7_IN	vin2a_d23	-	-	-	-
E8	vout1_d8	1962	573	2573	178	CFG_VOUT1_D8_IN	vin2a_d8	-	-	-	-
D9	vout1_d9	2312	335	2725	138	CFG_VOUT1_D9_IN	vin2a_d9	-	-	-	-
B10	vout1_de	1973	414	2551	52	CFG_VOUT1_DE_IN	vin2a_de0	-	-	-	-
B11	vout1_fld	0	0	0	0	CFG_VOUT1_FLD_IN	vin2a_clk0	-	-	-	-
C11	vout1_hsync	1813	261	2277	0	CFG_VOUT1_HSYNC_IN	vin2a_hsync0	-	-	-	-
E11	vout1_vsync	1665	0	1881	0	CFG_VOUT1_VSYNC_IN	vin2a_vsync0	-	-	-	-

Some signals listed are manual functions that present alternate multiplexing options. These manual functions are controlled via CTRL_CORE_ALT_SELECT_MUX or CTRL_CORE_VIP_MUX_SELECT registers. For more information on how to use these options, please refer to Device TRM, Chapter Control Module, Section Pad Configuration Registers.

Manual IO Timings Modes must be used to guaranteed some IO timings for VIP1. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-11 Manual Functions Mapping for VIN1B (IOSET6/7) for a definition of the Manual modes.

Table 7-11 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-11 Manual Functions Mapping for VIN1B (IOSET6/7)

BALL	BALL NAME	VIP_MANUAL9		VIP_MANUAL14		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	5	6
R6	gpmc_a0	1873	702	2202	441	CFG_GPMC_A0_IN	-	vin1b_d0
T9	gpmc_a1	1629	772	2057	413	CFG_GPMC_A1_IN	-	vin1b_d1
N9	gpmc_a10	0	0	0	0	CFG_GPMC_A10_IN	-	vin1b_clk1
P9	gpmc_a11	1851	1011	2126	856	CFG_GPMC_A11_IN	-	vin1b_de1
P4	gpmc_a12	2009	601	2289	327	CFG_GPMC_A12_IN	-	vin1b_fld1
T6	gpmc_a2	1734	898	2131	573	CFG_GPMC_A2_IN	-	vin1b_d2
T7	gpmc_a3	1757	1076	2106	812	CFG_GPMC_A3_IN	-	vin1b_d3
P6	gpmc_a4	1794	893	2164	559	CFG_GPMC_A4_IN	-	vin1b_d4
R9	gpmc_a5	1726	853	2120	523	CFG_GPMC_A5_IN	-	vin1b_d5
R5	gpmc_a6	1792	612	2153	338	CFG_GPMC_A6_IN	-	vin1b_d6
P5	gpmc_a7	2117	610	2389	304	CFG_GPMC_A7_IN	-	vin1b_d7
N7	gpmc_a8	1758	653	2140	308	CFG_GPMC_A8_IN	-	vin1b_hsync1
R4	gpmc_a9	1705	899	2067	646	CFG_GPMC_A9_IN	-	vin1b_vsync1
U4	mdio_d	1945	671	2265	414	CFG_MDIO_D_IN	vin1b_d0	-
V1	mdio_mclk	255	119	337	0	CFG_MDIO_MCLK_IN	vin1b_clk1	-
U5	rgmii0_rxc	2057	909	2341	646	CFG_RGMII0_RXC_IN	vin1b_d5	-
V5	rgmii0_rxctl	2121	1139	2323	988	CFG_RGMII0_RXCTL_IN	vin1b_d6	-
W2	rgmii0_rxd0	2070	655	2336	340	CFG_RGMII0_RXD0_IN	vin1b_fld1	-
V4	rgmii0_rxd3	2092	1357	2306	1216	CFG_RGMII0_RXD3_IN	vin1b_d7	-
W9	rgmii0_txc	2088	1205	2328	1079	CFG_RGMII0_TXC_IN	vin1b_d3	-
V9	rgmii0_txctl	2143	1383	2312	1311	CFG_RGMII0_TXCTL_IN	vin1b_d4	-
V6	rgmii0_txd1	2078	1189	2324	1065	CFG_RGMII0_TXD1_IN	vin1b_vsync1	-
U7	rgmii0_txd2	1928	1125	2306	763	CFG_RGMII0_TXD2_IN	vin1b_hsync1	-
V7	rgmii0_txd3	2255	971	2401	846	CFG_RGMII0_TXD3_IN	vin1b_de1	-
V2	uart3_rxd	1829	747	2220	400	CFG_UART3_RXD_IN	vin1b_d1	-
Y1	uart3_txd	2030	837	2324	568	CFG_UART3_TXD_IN	vin1b_d2	-

Manual IO Timings Modes must be used to guaranteed some IO timings for VIP1. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-12 Manual Functions Mapping for VIN1B (IOSET5) and VIN2B (IOSET2/11) for a definition of the Manual modes.

Table 7-12 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-12 Manual Functions Mapping for VIN1B (IOSET5) and VIN2B (IOSET2/11)

BALL	BALL NAME	VIP_MANUAL10		VIP_MANUAL11		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	4^⁽¹⁾	4^⁽¹⁾	6^⁽¹⁾	6^⁽¹⁾
K7	gpmc_a19	1600	943	2023	477	CFG_GPMC_A19_IN	-	-	vin2b_d0	vin1b_d0
M7	gpmc_a20	1440	621	1875	136	CFG_GPMC_A20_IN	-	-	vin2b_d1	vin1b_d1
J5	gpmc_a21	1602	1066	2021	604	CFG_GPMC_A21_IN	-	-	vin2b_d2	vin1b_d2
K6	gpmc_a22	1395	983	1822	519	CFG_GPMC_A22_IN	-	-	vin2b_d3	vin1b_d3
J7	gpmc_a23	1571	716	2045	200	CFG_GPMC_A23_IN	-	-	vin2b_d4	vin1b_d4
J4	gpmc_a24	1463	832	1893	396	CFG_GPMC_A24_IN	-	-	vin2b_d5	vin1b_d5
J6	gpmc_a25	1426	1166	1842	732	CFG_GPMC_A25_IN	-	-	vin2b_d6	vin1b_d6
H4	gpmc_a26	1362	1094	1797	584	CFG_GPMC_A26_IN	-	-	vin2b_d7	vin1b_d7
H5	gpmc_a27	1283	809	1760	338	CFG_GPMC_A27_IN	-	-	vin2b_hsync1	vin1b_hsync1
N6	gpmc_ben0	1978	780	2327	389	CFG_GPMC_BEN0_IN	-	-	vin2b_de1	vin1b_de1
M4	gpmc_ben1	0	0	0	0	CFG_GPMC_BEN1_IN	vin2b_clk1	vin1b_clk1	vin2b_fld1	vin1b_fld1
H6	gpmc_cs1	1411	982	1857	536	CFG_GPMC_CS1_IN	-	-	vin2b_vsync1	vin1b_vsync1

Some signals listed are manual functions that present alternate multiplexing options. These manual functions are controlled via CTRL_CORE_ALT_SELECT_MUX or CTRL_CORE_VIP_MUX_SELECT registers. For more information on how to use these options, please refer to Device TRM, Chapter Control Module, Section Pad Configuration Registers.

Manual IO Timings Modes must be used to guaranteed some IO timings for VIP1. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-13 Manual Functions Mapping for VIN1A (IOSET8/9/10) for a definition of the Manual modes.

Table 7-13 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-13 Manual Functions Mapping for VIN1A (IOSET8/9/10)

BALL	BALL NAME	VIP_MANUAL15		VIP_MANUAL16		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	7	9
AC5	gpio6_10	2131	2198	2170	2180	CFG_GPIO6_10_IN	-	vin1a_clk0
AB4	gpio6_11	3720	2732	4106	2448	CFG_GPIO6_11_IN	-	vin1a_de0
C14	mcasp1_aclkx	2447	0	3042	0	CFG_MCASP1_ACLKX_IN	vin1a_fld0	-
G12	mcasp1_axr0	3061	0	3380	292	CFG_MCASP1_AXR0_IN	vin1a_vsync0	-
F12	mcasp1_axr1	3113	0	3396	304	CFG_MCASP1_AXR1_IN	vin1a_hsync0	-
B13	mcasp1_axr10	2803	0	3362	0	CFG_MCASP1_AXR10_IN	vin1a_d13	-
A12	mcasp1_axr11	3292	0	3357	546	CFG_MCASP1_AXR11_IN	vin1a_d12	-
E14	mcasp1_axr12	2854	0	3145	320	CFG_MCASP1_AXR12_IN	vin1a_d11	-
A13	mcasp1_axr13	2813	0	3229	196	CFG_MCASP1_AXR13_IN	vin1a_d10	-
G14	mcasp1_axr14	2471	0	3053	0	CFG_MCASP1_AXR14_IN	vin1a_d9	-
F14	mcasp1_axr15	2815	0	3225	201	CFG_MCASP1_AXR15_IN	vin1a_d8	-
B12	mcasp1_axr8	2965	0	3427	83	CFG_MCASP1_AXR8_IN	vin1a_d15	-
A11	mcasp1_axr9	3082	0	3253	440	CFG_MCASP1_AXR9_IN	vin1a_d14	-
D14	mcasp1_fsx	2898	0	3368	139	CFG_MCASP1_FSX_IN	vin1a_de0	-
A19	mcasp2_aclkx	2413	0	2972	0	CFG_MCASP2_ACLKX_IN	vin1a_d7	-
C15	mcasp2_axr2	2478	0	3062	0	CFG_MCASP2_AXR2_IN	vin1a_d5	-
A16	mcasp2_axr3	2806	0	3175	242	CFG_MCASP2_AXR3_IN	vin1a_d4	-
A18	mcasp2_fsx	2861	78	2936	599	CFG_MCASP2_FSX_IN	vin1a_d6	-
B18	mcasp3_aclkx	1583	0	1878	0	CFG_MCASP3_ACLKX_IN	vin1a_d3	-
B19	mcasp3_axr0	2873	0	3109	375	CFG_MCASP3_AXR0_IN	vin1a_d1	-
C17	mcasp3_axr1	1625	1400	2072	1023	CFG_MCASP3_AXR1_IN	vin1a_d0	vin1a_fld0
F15	mcasp3_fsx	2792	0	3146	257	CFG_MCASP3_FSX_IN	vin1a_d2	-
C18	mcasp4_aclkx	1547	268	1776	0	CFG_MCASP4_ACLKX_IN	-	vin1a_d15
G16	mcasp4_axr0	2362	587	2815	193	CFG_MCASP4_AXR0_IN	-	vin1a_d13
D17	mcasp4_axr1	2326	667	2769	304	CFG_MCASP4_AXR1_IN	-	vin1a_d12
A21	mcasp4_fsx	924	2573	1338	2219	CFG_MCASP4_FSX_IN	-	vin1a_d14
AA3	mcasp5_aclkx	3731	2106	4130	1708	CFG_MCASP5_ACLKX_IN	-	vin1a_d11
AB3	mcasp5_axr0	3800	3013	4159	2776	CFG_MCASP5_AXR0_IN	-	vin1a_d9
AA4	mcasp5_axr1	3828	2951	4179	2733	CFG_MCASP5_AXR1_IN	-	vin1a_d8
AB9	mcasp5_fsx	3675	2447	4074	2142	CFG_MCASP5_FSX_IN	-	vin1a_d10
AD4	mmc3_clk	3907	2744	4260	2450	CFG_MMC3_CLK_IN	-	vin1a_d7
AC4	mmc3_cmd	3892	2768	4242	2470	CFG_MMC3_CMD_IN	-	vin1a_d6
AC7	mmc3_dat0	3786	2765	4156	2522	CFG_MMC3_DAT0_IN	-	vin1a_d5
AC6	mmc3_dat1	3673	2961	4053	2667	CFG_MMC3_DAT1_IN	-	vin1a_d4
AC9	mmc3_dat2	3818	2447	4209	2096	CFG_MMC3_DAT2_IN	-	vin1a_d3
AC3	mmc3_dat3	3902	2903	4259	2672	CFG_MMC3_DAT3_IN	-	vin1a_d2
AC8	mmc3_dat4	3905	2622	4259	2342	CFG_MMC3_DAT4_IN	-	vin1a_d1
AD6	mmc3_dat5	3807	2824	4167	2595	CFG_MMC3_DAT5_IN	-	vin1a_d0
AB8	mmc3_dat6	3724	2818	4123	2491	CFG_MMC3_DAT6_IN	-	vin1a_hsync0
AB5	mmc3_dat7	3775	2481	4159	2161	CFG_MMC3_DAT7_IN	-	vin1a_vsync0
D18	xref_clk0	1971	0	2472	0	CFG_XREF_CLK0_IN	vin1a_d0	-
E17	xref_clk1	0	192	0	603	CFG_XREF_CLK1_IN	vin1a_clk0	-

7.7 Display Subsystem - Video Output Ports

Three Display Parallel Interfaces (DPI) channels are available in DSS named DPI Video Output 1, DPI Video Output 2 and DPI Video Output 3.

NOTE

The DPI Video Output i (i = 1 to 3) interface is also referred to as VOUTi.

Every VOUT interface consists of:

24-bit data bus (data[23:0])
Horizontal synchronization signal (HSYNC)
Vertical synchronization signal (VSYNC)
Data enable (DE)
Field ID (FID)
Pixel clock (CLK)

NOTE

For more information, see the Display Subsystem chapter of the Device TRM.

NOTE

VOUT1, VOUT2 and VOUT3 only qualified for use at 1.8V.

CAUTION

The I/O Timings provided in this section are valid only if signals within a single IOSET are used. The IOSETs are defined in Table 7-16.

CAUTION

The I/O Timings provided in this section are valid only for some DSS usage modes when the corresponding Virtual I/O Timings or Manual I/O Timings are configured as described in the tables found in this section.

CAUTION

All pads/balls configured as vouti_* signals must be programmed to use slow slew rate by setting the corresponding CTRL_CORE_PAD_*[SLEWCONTROL] register field to SLOW (0b1).

Table 7-14, Table 7-15 and Figure 7-6 assume testing over the recommended operating conditions and electrical characteristic conditions.

Table 7-14 DPI Video Output i (i = 1..3) Default Switching Characteristics

NO.	PARAMETER	DESCRIPTION	MODE	MIN	MAX	UNIT
D1	t_c(clk)	Cycle time, output pixel clock vouti_clk	DPI1/2/3 in 1.8V mode DPI2 in 3.3V mode	11.76^⁽³⁾		ns
D1	t_c(clk)	Cycle time, output pixel clock vouti_clk	DPI1/3 in 3.3V mode	13.33^⁽³⁾		ns
D2	t_w(clkL)	Pulse duration, output pixel clock vouti_clk low		P*0.5-1 ^⁽¹⁾		ns
D3	t_w(clkH)	Pulse duration, output pixel clock vouti_clk high		P*0.5-1 ^⁽¹⁾		ns
D5	t_d(clk-ctlV)	Delay time, output pixel clock vouti_clk transition to output data vouti_d[23:0] valid	DPI1	-2.5	2.5	ns
D6	t_d(clk-dV)	Delay time, output pixel clock vouti_clk transition to output control signals vouti_vsync, vouti_hsync, vouti_de, and vouti_fld valid	DPI1	-2.5	2.5	ns
D5	t_d(clk-ctlV)	Delay time, output pixel clock vouti_clk transition to output data vouti_d[23:0] valid	DPI2 (vin2a_fld0 clock reference)	-2.5	2.5	ns
D6	t_d(clk-dV)	Delay time, output pixel clock vouti_clk transition to output control signals vouti_vsync, vouti_hsync, vouti_de, and vouti_fld valid	DPI2 (vin2a_fld0 clock reference)	-2.5	2.5	ns
D5	t_d(clk-ctlV)	Delay time, output pixel clock vouti_clk transition to output data vouti_d[23:0] valid	DPI2 (xref_clk2 clock reference)	-2.5	2.5	ns
D6	t_d(clk-dV)	Delay time, output pixel clock vouti_clk transition to output control signals vouti_vsync, vouti_hsync, vouti_de, and vouti_fld valid	DPI2 (xref_clk2 clock reference)	-2.5	2.5	ns
D5	t_d(clk-ctlV)	Delay time, output pixel clock vouti_clk transition to output data vouti_d[23:0] valid	DPI3	-2.5	2.5	ns
D6	t_d(clk-dV)	Delay time, output pixel clock vouti_clk transition to output control signals vouti_vsync, vouti_hsync, vouti_de, and vouti_fld valid	DPI3	-2.5	2.5	ns

P = output vouti_clk period in ns.
All pads/balls configured as vouti_* signals must be programmed to use slow slew rate by setting the corresponding CTRL_CORE_PAD_*[SLEWCONTROL] register field to SLOW (0b1).
SERDES transceivers may be sensitive to the jitter profile of vouti_clk. See Application Note SPRAC62 for additional guidance.

Table 7-15 DPI Video Output i (i = 1..3) Alternate Switching Characteristics^⁽²⁾

NO.	PARAMETER	DESCRIPTION	MODE	MIN	MAX	UNIT
D1	t_c(clk)	Cycle time, output pixel clock vouti_clk	DPI1/2/3 in 1.8-V mode DPI2 in 3.3V mode	6.06^⁽³⁾		ns
D1	t_c(clk)	Cycle time, output pixel clock vouti_clk	DPI1/3 in 3.3-V mode	13.33^⁽³⁾		ns
D2	t_w(clkL)	Pulse duration, output pixel clock vouti_clk low		P * 0.5 – 1 ^⁽¹⁾		ns
D3	t_w(clkH)	Pulse duration, output pixel clock vouti_clk high		P * 0.5 – 1 ^⁽¹⁾		ns
D5	t_d(clk-ctlV)	Delay time, output pixel clock vouti_clk transition to output data vouti_d[23:0] valid	DPI1	1.02	4.55	ns
D6	t_d(clk-dV)	Delay time, output pixel clock vouti_clk transition to output control signals vouti_vsync, vouti_hsync, vouti_de, and vouti_fld valid	DPI1	1.02	4.55	ns
D5	t_d(clk-ctlV)	Delay time, output pixel clock vouti_clk transition to output data vouti_d[23:0] valid	DPI2 (vin2a_fld0 clock reference)	1.02	4.55	ns
D6	t_d(clk-dV)	Delay time, output pixel clock vouti_clk transition to output control signals vouti_vsync, vouti_hsync, vouti_de, and vouti_fld valid	DPI2 (vin2a_fld0 clock reference)	1.02	4.55	ns
D5	t_d(clk-ctlV)	Delay time, output pixel clock vouti_clk transition to output data vouti_d[23:0] valid	DPI2 (xref_clk2 clock reference)	1.02	4.55	ns
D6	t_d(clk-dV)	Delay time, output pixel clock vouti_clk transition to output control signals vouti_vsync, vouti_hsync, vouti_de, and vouti_fld valid	DPI2 (xref_clk2 clock reference)	1.02	4.55	ns
D5	t_d(clk-ctlV)	Delay time, output pixel clock vouti_clk transition to output data vouti_d[23:0] valid	DPI3	1.02	4.55	ns
D6	t_d(clk-dV)	Delay time, output pixel clock vouti_clk transition to output control signals vouti_vsync, vouti_hsync, vouti_de, and vouti_fld valid	DPI3	1.02	4.55	ns

P = output vouti_clk period in ns.
All pads/balls configured as vouti_* signals must be programmed to use slow slew rate by setting the corresponding CTRL_CORE_PAD_*[SLEWCONTROL] register field to SLOW (0b1).
SERDES transceivers may be sensitive to the jitter profile of vouti_clk. See Application Note SPRAC62 for additional guidance.

Figure 7-6 DPI Video Output^⁽¹⁾^⁽²⁾^⁽³⁾

The configuration of assertion of the data can be programmed on the falling or rising edge of the pixel clock.
The polarity and the pulse width of vouti_hsync and vouti_vsync are programmable, refer to the DSS section of the device TRM.
The vouti_clk frequency can be configured, refer to the DSS section of the device TRM.

In Table 7-16 are presented the specific groupings of signals (IOSET) for use with VOUT2.

Table 7-16 VOUT2 IOSETs

SIGNALS	IOSET1		IOSET2
SIGNALS	BALL	MUX	BALL	MUX
vout2_d23	F2	4	AA4	6
vout2_d22	F3	4	AB3	6
vout2_d21	D1	4	AB9	6
vout2_d20	E2	4	AA3	6
vout2_d19	D2	4	D17	6
vout2_d18	F4	4	G16	6
vout2_d17	C1	4	A21	6
vout2_d16	E4	4	C18	6
vout2_d15	F5	4	A17	6
vout2_d14	E6	4	B17	6
vout2_d13	D3	4	B16	6
vout2_d12	F6	4	D15	6
vout2_d11	D5	4	A15	6
vout2_d10	C2	4	B15	6
vout2_d9	C3	4	A20	6
vout2_d8	C4	4	E15	6
vout2_d7	B2	4	D12	6
vout2_d6	D6	4	C12	6
vout2_d5	C5	4	F13	6
vout2_d4	A3	4	E12	6
vout2_d3	B3	4	J11	6
vout2_d2	B4	4	G13	6
vout2_d1	B5	4	J14	6
vout2_d0	A4	4	B14	6
vout2_vsync	G6	4	F20	6
vout2_hsync	G1	4	E21	6
vout2_clk	H7	4	B26	6
vout2_fld	E1	4	F21	6
vout2_de	G2	4	C23	6

NOTE

To configure the desired virtual mode the user must set MODESELECT bit and DELAYMODE bitfield for each corresponding pad control register.

The pad control registers are presented in Table 4-3 and described in Device TRM, Control Module Chapter.

Virtual IO Timings Modes must be used to guaranteed some IO timings for VOUT1. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Virtual IO Timings Modes. See Table 7-17 Virtual Functions Mapping for VOUT1 for a definition of the Virtual modes.

Table 7-17 presents the values for DELAYMODE bitfield.

Table 7-17 Virtual Functions Mapping for DSS VOUT1

BALL	BALL NAME	Delay Mode Value	MUXMODE
BALL	BALL NAME	DSS_VIRTUAL1	0	3
H3	gpmc_ad15	14		vout3_d15
D9	vout1_d9	15	vout1_d9
N7	gpmc_a8	15		vout3_hsync
L6	gpmc_ad4	14		vout3_d4
E8	vout1_d8	15	vout1_d8
M6	gpmc_ad0	14		vout3_d0
F9	vout1_d5	15	vout1_d5
J3	gpmc_ad13	14		vout3_d13
T6	gpmc_a2	15		vout3_d18
M2	gpmc_ad1	14		vout3_d1
P6	gpmc_a4	15		vout3_d20
B10	vout1_de	15	vout1_de
B7	vout1_d16	15	vout1_d16
R5	gpmc_a6	15		vout3_d22
A9	vout1_d21	15	vout1_d21
H2	gpmc_ad14	14		vout3_d14
T9	gpmc_a1	15		vout3_d17
E7	vout1_d7	15	vout1_d7
C11	vout1_hsync	15	vout1_hsync
D11	vout1_clk	15	vout1_clk
P1	gpmc_cs3	15		vout3_clk
B9	vout1_d22	15	vout1_d22
G11	vout1_d3	15	vout1_d3
R4	gpmc_a9	15		vout3_vsync
D8	vout1_d11	15	vout1_d11
J2	gpmc_ad11	14		vout3_d11
L3	gpmc_ad6	14		vout3_d6
D7	vout1_d10	15	vout1_d10
L5	gpmc_ad2	14		vout3_d2
F10	vout1_d2	15	vout1_d2
M1	gpmc_ad3	14		vout3_d3
P5	gpmc_a7	15		vout3_d23
T7	gpmc_a3	15		vout3_d19
A7	vout1_d18	15	vout1_d18
C7	vout1_d15	15	vout1_d15
J1	gpmc_ad10	14		vout3_d10
L2	gpmc_ad7	14		vout3_d7
N9	gpmc_a10	15		vout3_de
F11	vout1_d0	15	vout1_d0
G10	vout1_d1	15	vout1_d1
R9	gpmc_a5	15		vout3_d21
L1	gpmc_ad8	14		vout3_d8
F8	vout1_d6	15	vout1_d6
L4	gpmc_ad5	14		vout3_d5
A10	vout1_d23	15	vout1_d23
E11	vout1_vsync	15	vout1_vsync
C9	vout1_d20	15	vout1_d20
R6	gpmc_a0	15		vout3_d16
A8	vout1_d19	15	vout1_d19
E9	vout1_d4	15	vout1_d4
H1	gpmc_ad12	14		vout3_d12
B11	vout1_fld	15	vout1_fld
P9	gpmc_a11	15		vout3_fld
K2	gpmc_ad9	14		vout3_d9
C6	vout1_d13	15	vout1_d13
B8	vout1_d17	15	vout1_d17
A5	vout1_d12	15	vout1_d12
C8	vout1_d14	15	vout1_d14

NOTE

To configure the desired Manual IO Timing Mode the user must follow the steps described in section "Manual IO Timing Modes" of the Device TRM.

The associated registers to configure are listed in the CFG REGISTER column. For more information please see the Control Module Chapter in the Device TRM.

Manual IO Timings Modes must be used to guaranteed some IO timings for VOUT1. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-18 Manual Functions Mapping for DSS VOUT1 for a definition of the Manual modes.

Table 7-18 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-18 Manual Functions Mapping for DSS VOUT1

BALL	BALL NAME	VOUT1_MANUAL1		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	0
D11	vout1_clk	0	212	CFG_VOUT1_CLK_OUT	vout1_clk
F11	vout1_d0	2502	0	CFG_VOUT1_D0_OUT	vout1_d0
G10	vout1_d1	2402	0	CFG_VOUT1_D1_OUT	vout1_d1
D7	vout1_d10	2147	0	CFG_VOUT1_D10_OUT	vout1_d10
D8	vout1_d11	2249	0	CFG_VOUT1_D11_OUT	vout1_d11
A5	vout1_d12	2410	0	CFG_VOUT1_D12_OUT	vout1_d12
C6	vout1_d13	2129	0	CFG_VOUT1_D13_OUT	vout1_d13
C8	vout1_d14	2279	0	CFG_VOUT1_D14_OUT	vout1_d14
C7	vout1_d15	2266	23	CFG_VOUT1_D15_OUT	vout1_d15
B7	vout1_d16	1798	0	CFG_VOUT1_D16_OUT	vout1_d16
B8	vout1_d17	2243	0	CFG_VOUT1_D17_OUT	vout1_d17
A7	vout1_d18	2127	0	CFG_VOUT1_D18_OUT	vout1_d18
A8	vout1_d19	2096	0	CFG_VOUT1_D19_OUT	vout1_d19
F10	vout1_d2	2375	0	CFG_VOUT1_D2_OUT	vout1_d2
C9	vout1_d20	2105	0	CFG_VOUT1_D20_OUT	vout1_d20
A9	vout1_d21	2120	0	CFG_VOUT1_D21_OUT	vout1_d21
B9	vout1_d22	2013	65	CFG_VOUT1_D22_OUT	vout1_d22
A10	vout1_d23	1887	0	CFG_VOUT1_D23_OUT	vout1_d23
G11	vout1_d3	2429	0	CFG_VOUT1_D3_OUT	vout1_d3
E9	vout1_d4	2639	0	CFG_VOUT1_D4_OUT	vout1_d4
F9	vout1_d5	2319	0	CFG_VOUT1_D5_OUT	vout1_d5
F8	vout1_d6	2227	0	CFG_VOUT1_D6_OUT	vout1_d6
E7	vout1_d7	2309	0	CFG_VOUT1_D7_OUT	vout1_d7
E8	vout1_d8	1999	0	CFG_VOUT1_D8_OUT	vout1_d8
D9	vout1_d9	2276	0	CFG_VOUT1_D9_OUT	vout1_d9
B10	vout1_de	1933	0	CFG_VOUT1_DE_OUT	vout1_de
B11	vout1_fld	1825	0	CFG_VOUT1_FLD_OUT	vout1_fld
C11	vout1_hsync	1741	13	CFG_VOUT1_HSYNC_OUT	vout1_hsync
E11	vout1_vsync	2338	0	CFG_VOUT1_VSYNC_OUT	vout1_vsync

Manual IO Timings Modes must be used to guaranteed some IO timings for VOUT2. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-19 Manual Functions Mapping for DSS VOUT2 IOSET1 for a definition of the Manual modes.

Table 7-19 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-19 Manual Functions Mapping for DSS VOUT2 IOSET1

BALL	BALL NAME	VOUT2_IOSET1_MANUAL1		VOUT2_IOSET1_MANUAL2		VOUT2_IOSET1_MANUAL3		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	A_DELAY (ps)	G_DELAY (ps)	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	4
E1	vin2a_clk0	2571	0	1059	0	1025	0	CFG_VIN2A_CLK0_OUT	vout2_fld
F2	vin2a_d0	2124	0	589	0	577	0	CFG_VIN2A_D0_OUT	vout2_d23
F3	vin2a_d1	2103	0	568	0	557	0	CFG_VIN2A_D1_OUT	vout2_d22
D3	vin2a_d10	2091	0	557	0	545	0	CFG_VIN2A_D10_OUT	vout2_d13
F6	vin2a_d11	2142	0	608	0	596	0	CFG_VIN2A_D11_OUT	vout2_d12
D5	vin2a_d12	2920	385	1816	255	1783	276	CFG_VIN2A_D12_OUT	vout2_d11
C2	vin2a_d13	2776	322	1872	192	1838	213	CFG_VIN2A_D13_OUT	vout2_d10
C3	vin2a_d14	2904	0	1769	0	1757	0	CFG_VIN2A_D14_OUT	vout2_d9
C4	vin2a_d15	2670	257	1665	127	1632	148	CFG_VIN2A_D15_OUT	vout2_d8
B2	vin2a_d16	2814	155	1908	31	1878	43	CFG_VIN2A_D16_OUT	vout2_d7
D6	vin2a_d17	3002	199	1897	69	1865	89	CFG_VIN2A_D17_OUT	vout2_d6
C5	vin2a_d18	1893	0	358	0	347	0	CFG_VIN2A_D18_OUT	vout2_d5
A3	vin2a_d19	1698	0	163	0	151	0	CFG_VIN2A_D19_OUT	vout2_d4
D1	vin2a_d2	2193	0	658	0	646	0	CFG_VIN2A_D2_OUT	vout2_d21
B3	vin2a_d20	1736	0	202	0	190	0	CFG_VIN2A_D20_OUT	vout2_d3
B4	vin2a_d21	1636	0	101	0	89	0	CFG_VIN2A_D21_OUT	vout2_d2
B5	vin2a_d22	1628	0	93	0	81	0	CFG_VIN2A_D22_OUT	vout2_d1
A4	vin2a_d23	1538	0	0	0	0	0	CFG_VIN2A_D23_OUT	vout2_d0
E2	vin2a_d3	1997	0	462	0	450	0	CFG_VIN2A_D3_OUT	vout2_d20
D2	vin2a_d4	2528	0	993	0	982	0	CFG_VIN2A_D4_OUT	vout2_d19
F4	vin2a_d5	2038	0	503	0	492	0	CFG_VIN2A_D5_OUT	vout2_d18
C1	vin2a_d6	1746	0	211	0	200	0	CFG_VIN2A_D6_OUT	vout2_d17
E4	vin2a_d7	2213	0	678	0	666	0	CFG_VIN2A_D7_OUT	vout2_d16
F5	vin2a_d8	2268	0	733	0	721	0	CFG_VIN2A_D8_OUT	vout2_d15
E6	vin2a_d9	2170	0	635	0	623	0	CFG_VIN2A_D9_OUT	vout2_d14
G2	vin2a_de0	2102	0	568	0	556	0	CFG_VIN2A_DE0_OUT	vout2_de
H7	vin2a_fld0	0	983	1398	1185	1385	1202	CFG_VIN2A_FLD0_OUT	vout2_clk
G1	vin2a_hsync0	2482	0	974	0	936	0	CFG_VIN2A_HSYNC0_OUT	vout2_hsync
G6	vin2a_vsync0	2296	0	784	0	750	0	CFG_VIN2A_VSYNC0_OUT	vout2_vsync

Manual IO Timings Modes must be used to guaranteed some IO timings for VOUT2. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-20 Manual Functions Mapping for DSS VOUT2 IOSET2 for a definition of the Manual modes.

Table 7-20 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-20 Manual Functions Mapping for DSS VOUT2 IOSET2

BALL	BALL NAME	VOUT2_IOSET2_MANUAL1		VOUT2_IOSET2_MANUAL2		VOUT2_IOSET2_MANUAL3		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	A_DELAY (ps)	G_DELAY (ps)	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	6
E21	gpio6_14	1983	0	79	0	68	0	CFG_GPIO6_14_OUT	vout2_hsync
F20	gpio6_15	2159	0	158	0	148	0	CFG_GPIO6_15_OUT	vout2_vsync
F21	gpio6_16	1864	0	0	0	0	0	CFG_GPIO6_16_OUT	vout2_fld
B14	mcasp1_aclkr	2614	0	1255	0	1270	0	CFG_MCASP1_ACLKR_OUT	vout2_d0
G13	mcasp1_axr2	2705	0	1350	0	1360	0	CFG_MCASP1_AXR2_OUT	vout2_d2
J11	mcasp1_axr3	2865	0	1210	0	1219	0	CFG_MCASP1_AXR3_OUT	vout2_d3
E12	mcasp1_axr4	2759	0	1404	0	1413	0	CFG_MCASP1_AXR4_OUT	vout2_d4
F13	mcasp1_axr5	2980	0	1325	0	1335	0	CFG_MCASP1_AXR5_OUT	vout2_d5
C12	mcasp1_axr6	2634	0	1275	0	1289	0	CFG_MCASP1_AXR6_OUT	vout2_d6
D12	mcasp1_axr7	2658	0	1302	0	1311	0	CFG_MCASP1_AXR7_OUT	vout2_d7
J14	mcasp1_fsr	2818	0	1163	0	1172	0	CFG_MCASP1_FSR_OUT	vout2_d1
E15	mcasp2_aclkr	2728	0	1373	0	1382	0	CFG_MCASP2_ACLKR_OUT	vout2_d8
B15	mcasp2_axr0	2513	0	319	534	308	560	CFG_MCASP2_AXR0_OUT	vout2_d10
A15	mcasp2_axr1	2712	0	1357	0	1366	0	CFG_MCASP2_AXR1_OUT	vout2_d11
D15	mcasp2_axr4	2529	0	1169	0	1184	0	CFG_MCASP2_AXR4_OUT	vout2_d12
B16	mcasp2_axr5	2376	0	543	478	1029	0	CFG_MCASP2_AXR5_OUT	vout2_d13
B17	mcasp2_axr6	2620	0	1265	0	1274	0	CFG_MCASP2_AXR6_OUT	vout2_d14
A17	mcasp2_axr7	2492	0	354	483	845	0	CFG_MCASP2_AXR7_OUT	vout2_d15
A20	mcasp2_fsr	2358	0	12	487	513	0	CFG_MCASP2_FSR_OUT	vout2_d9
C18	mcasp4_aclkx	2524	0	1165	0	1179	0	CFG_MCASP4_ACLKX_OUT	vout2_d16
G16	mcasp4_axr0	2578	0	797	0	806	0	CFG_MCASP4_AXR0_OUT	vout2_d18
D17	mcasp4_axr1	2253	0	750	0	759	0	CFG_MCASP4_AXR1_OUT	vout2_d19
A21	mcasp4_fsx	2478	0	823	0	832	0	CFG_MCASP4_FSX_OUT	vout2_d17
AA3	mcasp5_aclkx	4672	1737	3256	1798	3226	1837	CFG_MCASP5_ACLKX_OUT	vout2_d20
AB3	mcasp5_axr0	4642	1286	3226	1347	3196	1386	CFG_MCASP5_AXR0_OUT	vout2_d22
AA4	mcasp5_axr1	4625	725	3209	786	3179	825	CFG_MCASP5_AXR1_OUT	vout2_d23
AB9	mcasp5_fsx	4565	1062	3149	1123	3119	1162	CFG_MCASP5_FSX_OUT	vout2_d21
B26	xref_clk2	0	49	1359	466	1341	512	CFG_XREF_CLK2_OUT	vout2_clk
C23	xref_clk3	1947	0	36	0	45	0	CFG_XREF_CLK3_OUT	vout2_de

Manual IO Timings Modes must be used to guaranteed some IO timings for VOUT3. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-21 Manual Functions Mapping for DSS VOUT3 for a definition of the Manual modes.

Table 7-21 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-21 Manual Functions Mapping for DSS VOUT3

BALL	BALL NAME	VOUT3_MANUAL1		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	3
R6	gpmc_a0	2395	0	CFG_GPMC_A0_OUT	vout3_d16
T9	gpmc_a1	2412	0	CFG_GPMC_A1_OUT	vout3_d17
N9	gpmc_a10	2473	0	CFG_GPMC_A10_OUT	vout3_de
P9	gpmc_a11	2906	0	CFG_GPMC_A11_OUT	vout3_fld
T6	gpmc_a2	2360	0	CFG_GPMC_A2_OUT	vout3_d18
T7	gpmc_a3	2391	0	CFG_GPMC_A3_OUT	vout3_d19
P6	gpmc_a4	2626	0	CFG_GPMC_A4_OUT	vout3_d20
R9	gpmc_a5	2338	0	CFG_GPMC_A5_OUT	vout3_d21
R5	gpmc_a6	2374	0	CFG_GPMC_A6_OUT	vout3_d22
P5	gpmc_a7	2432	0	CFG_GPMC_A7_OUT	vout3_d23
N7	gpmc_a8	3155	0	CFG_GPMC_A8_OUT	vout3_hsync
R4	gpmc_a9	2309	0	CFG_GPMC_A9_OUT	vout3_vsync
M6	gpmc_ad0	2360	0	CFG_GPMC_AD0_OUT	vout3_d0
M2	gpmc_ad1	2420	0	CFG_GPMC_AD1_OUT	vout3_d1
J1	gpmc_ad10	2235	0	CFG_GPMC_AD10_OUT	vout3_d10
J2	gpmc_ad11	2253	0	CFG_GPMC_AD11_OUT	vout3_d11
H1	gpmc_ad12	1949	427	CFG_GPMC_AD12_OUT	vout3_d12
J3	gpmc_ad13	2318	0	CFG_GPMC_AD13_OUT	vout3_d13
H2	gpmc_ad14	2123	0	CFG_GPMC_AD14_OUT	vout3_d14
H3	gpmc_ad15	2195	29	CFG_GPMC_AD15_OUT	vout3_d15
L5	gpmc_ad2	2617	0	CFG_GPMC_AD2_OUT	vout3_d2
M1	gpmc_ad3	2350	0	CFG_GPMC_AD3_OUT	vout3_d3
L6	gpmc_ad4	2324	0	CFG_GPMC_AD4_OUT	vout3_d4
L4	gpmc_ad5	2371	0	CFG_GPMC_AD5_OUT	vout3_d5
L3	gpmc_ad6	2231	0	CFG_GPMC_AD6_OUT	vout3_d6
L2	gpmc_ad7	2440	0	CFG_GPMC_AD7_OUT	vout3_d7
L1	gpmc_ad8	2479	0	CFG_GPMC_AD8_OUT	vout3_d8
K2	gpmc_ad9	2355	0	CFG_GPMC_AD9_OUT	vout3_d9
P1	gpmc_cs3	0	641	CFG_GPMC_CS3_OUT	vout3_clk

7.8 Display Subsystem - High-Definition Multimedia Interface (HDMI)

The High-Definition Multimedia Interface is provided for transmitting digital television audiovisual signals from DVD players, set-top boxes and other audiovisual sources to television sets, projectors and other video displays. The HDMI interface is aligned with the HDMI TMDS single stream standard v1.4a (720p @60Hz to 1080p @24Hz) and the HDMI v1.3 (1080p @60Hz): 3 data channels, plus 1 clock channel is supported (differential).

NOTE

For more information, see the High-Definition Multimedia Interface chapter of the device TRM

7.9 Camera Serial Interface 2 CAL bridge (CSI2)

NOTE

For more information, see the Camera Serial Interface 2 CAL Bridge chapter of the device TRM

The camera adaptation layer (CAL) deals with the processing of the pixel data coming from an external image sensor, data from memory. The CAL is a key component for the following multimedia applications: camera viewfinder, video record, and still image capture. The CAL has two serial camera interfaces (primary and secondary):

The primary serial interface (CSI2 Port A) is compliant with MIPI CSI-2 protocol with four data lanes.
The secondary serial interface (CSI2 Port B) is compliant with MIPI CSI-2 protocol with two data lanes.

7.9.1 CSI-2 MIPI D-PHY-1.5 V and 1.8 V

The CSI-2 port A is compliant with the MIPI D-PHY RX specification v1.00.00 and the MIPI CSI-2 specification v1.00, with 4 data differential lanes plus 1 clock differential lane in synchronous mode, double data rate:

1.5 Gbps (750 MHz) @OPP_NOM for each lane.

The CSI-2 port B is compliant with the MIPI D-PHY RX specification v1.00.00 and the MIPI CSI-2 specification v1.00, with 2 data lanes plus 1 clock lane (differential) in synchronous mode, double data rate:

1.5 Gbps (750 MHz) @OPP_NOM for each lane, in synchronous mode.

7.10 External Memory Interface (EMIF)

The device has a dedicated interface to DDR3 and DDR3L SDRAM. It supports JEDEC standard compliant DDR3 and DDR3L SDRAM devices with the following features:

16-bit or 32-bit data path to external SDRAM memory
Memory device capacity: 128Mb, 256Mb, 512Mb, 1Gb, 2Gb, 4Gb and 8Gb devices
One interface with associated DDR3/DDR3L PHYs

NOTE

For more information, see the EMIF Controller section of the Device TRM.

7.11 General-Purpose Memory Controller (GPMC)

The GPMC is the unified memory controller that interfaces external memory devices such as:

Asynchronous SRAM-like memories and ASIC devices
Asynchronous page mode and synchronous burst NOR flash
NAND flash

NOTE

For more information, see the General-Purpose Memory Controller section of the Device TRM.

7.11.1 GPMC/NOR Flash Interface Synchronous Timing

CAUTION

The I/O Timings provided in this section are valid only for some GPMC usage modes when the corresponding Virtual I/O Timings or Manual I/O Timings are configured as described in the tables found in this section.

Table 7-22 and Table 7-23 assume testing over the recommended operating conditions and electrical characteristic conditions below (see Figure 7-7, Figure 7-8, Figure 7-9, Figure 7-10, Figure 7-11 and Figure 7-12).

Table 7-22 GPMC/NOR Flash Interface Timing Requirements - Synchronous Mode - Default

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
F12	t_su(dV-clkH)	Setup time, read gpmc_ad[15:0] valid before gpmc_clk high	3	ns
F13	t_h(clkH-dV)	Hold time, read gpmc_ad[15:0] valid after gpmc_clk high	1.1	ns
F21	t_{su(waitV-clkH)}	Setup time, gpmc_wait[1:0] valid before gpmc_clk high	2.5	ns
F22	t_{h(clkH-waitV)}	Hold Time, gpmc_wait[1:0] valid after gpmc_clk high	1.3	ns

NOTE

Wait monitoring support is limited to a WaitMonitoringTime value > 0. For a full description of wait monitoring feature, see the Device TRM.

Table 7-23 GPMC/NOR Flash Interface Switching Characteristics - Synchronous Mode - Default

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
F0	t_c(clk)	Cycle time, output clock gpmc_clk period	11.3		ns
F2	t_d(clkH-nCSV)	Delay time, gpmc_clk rising edge to gpmc_cs[7:0] transition	F – 1.7 ^⁽⁷⁾	F + 5.58 ^⁽⁷⁾	ns
F3	t_{d(clkH-nCSIV)}	Delay time, gpmc_clk rising edge to gpmc_cs[7:0] invalid	E – 1.7 ^⁽⁶⁾	E + 4.2 ^⁽⁶⁾	ns
F4	t_d(ADDV-clk)	Delay time, gpmc_a[27:0] address bus valid to gpmc_clk first edge	B – 1.8 ^⁽³⁾	B + 4.3 ^⁽³⁾	ns
F5	t_{d(clkH-ADDIV)}	Delay time, gpmc_clk rising edge to gpmc_a[27:0] gpmc address bus invalid	–1.8		ns
F6	t_d(nBEV-clk)	Delay time, gpmc_ben[1:0] valid to gpmc_clk rising edge	B – 4.3 ^⁽³⁾	B + 1.5 ^⁽³⁾	ns
F7	t_{d(clkH-nBEIV)}	Delay time, gpmc_clk rising edge to gpmc_ben[1:0] invalid	D – 1.5 ^⁽⁵⁾	D + 4.3 ^⁽⁵⁾	ns
F8	t_d(clkH-nADV)	Delay time, gpmc_clk rising edge to gpmc_advn_ale transition	G – 1.3 ^⁽⁸⁾	G + 4.2 ^⁽⁸⁾	ns
F9	t_{d(clkH-nADVIV)}	Delay time, gpmc_clk rising edge to gpmc_advn_ale invalid	D – 1.3 ^⁽⁵⁾	G + 4.2 ^⁽⁵⁾	ns
F10	t_d(clkH-nOE)	Delay time, gpmc_clk rising edge to gpmc_oen_ren transition	H – 1.0 ^⁽⁹⁾	H + 3.2 ^⁽⁹⁾	ns
F11	t_{d(clkH-nOEIV)}	Delay time, gpmc_clk rising edge to gpmc_oen_ren invalid	E – 1.0 ^⁽⁶⁾	E + 3.2 ^⁽⁶⁾	ns
F14	t_d(clkH-nWE)	Delay time, gpmc_clk rising edge to gpmc_wen transition	I – 0.9 ^⁽¹⁰⁾	I + 4.2 ^⁽¹⁰⁾	ns
F15	t_d(clkH-Data)	Delay time, gpmc_clk rising edge to gpmc_ad[15:0] data bus transition	J – 2.1 ^⁽¹¹⁾	J + 4.6 ^⁽¹¹⁾	ns
F17	t_d(clkH-nBE)	Delay time, gpmc_clk rising edge to gpmc_ben[1:0] transition	J – 1.5 ^⁽¹¹⁾	J + 4.3 ^⁽¹¹⁾	ns
F18	t_w(nCSV)	Pulse duration, gpmc_cs[7:0] low	A ^⁽²⁾		ns
F19	t_w(nBEV)	Pulse duration, gpmc_ben[1:0] low	C ^⁽⁴⁾		ns
F20	t_w(nADVV)	Pulse duration, gpmc_advn_ale low	K ^⁽¹²⁾		ns
F23	t_d(CLK-GPIO)	Delay time, gpmc_clk transition to gpio6_16 transition	0.5	7.5	ns

Table 7-24 GPMC/NOR Flash Interface Timing Requirements - Synchronous Mode - Alternate^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
F12	t_su(dV-clkH)	Setup time, read gpmc_ad[15:0] valid before gpmc_clk high	2.9	ns
F13	t_h(clkH-dV)	Hold time, read gpmc_ad[15:0] valid after gpmc_clk high	2	ns
F21	t_{su(waitV-clkH)}	Setup time, gpmc_wait[1:0] valid before gpmc_clk high	2.5	ns
F22	t_{h(clkH-waitV)}	Hold Time, gpmc_wait[1:0] valid after gpmc_clk high	2.1	ns

Total GPMC load on any signal at 3.3 V must not exceed 10 pF.

Table 7-25 GPMC/NOR Flash Interface Switching Characteristics - Synchronous Mode - Alternate^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
F0	t_c(clk)	Cycle time, output clock gpmc_clk period ^⁽¹³⁾	15.04		ns
F2	t_d(clkH-nCSV)	Delay time, gpmc_clk rising edge to gpmc_cs[7:0] transition	F + 0.6 ^⁽⁷⁾	F + 7.0 ^⁽⁷⁾	ns
F3	t_{d(clkH-nCSIV)}	Delay time, gpmc_clk rising edge to gpmc_cs[7:0] invalid	E + 0.6 ^⁽⁶⁾	E + 7.0 ^⁽⁶⁾	ns
F4	t_d(ADDV-clk)	Delay time, gpmc_a[27:0] address bus valid to gpmc_clk first edge	B – 0.6 ^⁽³⁾	B + 7.0 ^⁽³⁾	ns
F5	t_{d(clkH-ADDIV)}	Delay time, gpmc_clk rising edge to gpmc_a[27:0] gpmc address bus invalid	–0.7		ns
F6	t_d(nBEV-clk)	Delay time, gpmc_ben[1:0] valid to gpmc_clk rising edge	B – 7.0	B + 0.4	ns
F7	t_{d(clkH-nBEIV)}	Delay time, gpmc_clk rising edge to gpmc_ben[1:0] invalid	D – 0.4	D + 7.0	ns
F8	t_d(clkH-nADV)	Delay time, gpmc_clk rising edge to gpmc_advn_ale transition	G + 0.7 ^⁽⁸⁾	G + 6.1 ^⁽⁸⁾	ns
F9	t_{d(clkH-nADVIV)}	Delay time, gpmc_clk rising edge to gpmc_advn_ale invalid	D + 0.7 ^⁽⁵⁾	D + 6.1 ^⁽⁵⁾	ns
F10	t_d(clkH-nOE)	Delay time, gpmc_clk rising edge to gpmc_oen_ren transition	H + 0.7 ^⁽⁹⁾	H + 5.1 ^⁽⁹⁾	ns
F11	t_{d(clkH-nOEIV)}	Delay time, gpmc_clk rising edge to gpmc_oen_ren invalid	E + 0.7 ^⁽⁶⁾	E + 5.1 ^⁽⁶⁾	ns
F14	t_d(clkH-nWE)	Delay time, gpmc_clk rising edge to gpmc_wen transition	I + 0.7 ^⁽¹⁰⁾	I + 6.1 ^⁽¹⁰⁾	ns
F15	t_d(clkH-Data)	Delay time, gpmc_clk rising edge to gpmc_ad[15:0] data bus transition	J – 0.4 ^⁽¹¹⁾	J + 4.9 ^⁽¹¹⁾	ns
F17	t_d(clkH-nBE)	Delay time, gpmc_clk rising edge to gpmc_ben[1:0] transition	J – 0.4 ^⁽¹¹⁾	J + 4.9 ^⁽¹¹⁾	ns
F18	t_w(nCSV)	Pulse duration, gpmc_cs[7:0] low	A ^⁽²⁾		ns
F19	t_w(nBEV)	Pulse duration, gpmc_ben[1:0] low	C ^⁽⁴⁾		ns
F20	t_w(nADVV)	Pulse duration, gpmc_advn_ale low	K ^⁽¹²⁾		ns
F23	t_d(CLK-GPIO)	Delay time, gpmc_clk transition to gpio6_16.clkout1 transition ^⁽¹⁴⁾	0.5	7.5	ns

Total GPMC load on any signal at 3.3V must not exceed 10pF.
For single read: A = (CSRdOffTime - CSOnTime) * (TimeParaGranularity + 1) * GPMC_FCLK period
For burst read: A = (CSRdOffTime - CSOnTime + (n - 1) * PageBurstAccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK period
For burst write: A = (CSWrOffTime - CSOnTime + (n - 1) * PageBurstAccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK period with n the page burst access number.
B = ClkActivationTime * GPMC_FCLK
For single read: C = RdCycleTime * (TimeParaGranularity + 1) * GPMC_FCLK
For burst read: C = (RdCycleTime + (n - 1) * PageBurstAccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK
For Burst write: C = (WrCycleTime + (n - 1) * PageBurstAccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK with n the page burst access number.
For single read: D = (RdCycleTime - AccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK
For burst read: D = (RdCycleTime - AccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK
For burst write: D = (WrCycleTime - AccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK
For single read: E = (CSRdOffTime - AccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK
For burst read: E = (CSRdOffTime - AccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK
For burst write: E = (CSWrOffTime - AccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK
For nCS falling edge (CS activated):
Case GpmcFCLKDivider = 0 :
F = 0.5 * CSExtraDelay * GPMC_FCLK Case GpmcFCLKDivider = 1:
F = 0.5 * CSExtraDelay * GPMC_FCLK if (ClkActivationTime and CSOnTime are odd) or (ClkActivationTime and CSOnTime are even)
F = (1 + 0.5 * CSExtraDelay) * GPMC_FCLK otherwise
Case GpmcFCLKDivider = 2:
F = 0.5 * CSExtraDelay * GPMC_FCLK if ((CSOnTime - ClkActivationTime) is a multiple of 3)
F = (1 + 0.5 * CSExtraDelay) * GPMC_FCLK if ((CSOnTime - ClkActivationTime - 1) is a multiple of 3)
F = (2 + 0.5 * CSExtraDelay) * GPMC_FCLK if ((CSOnTime - ClkActivationTime - 2) is a multiple of 3)
Case GpmcFCLKDivider = 3:
F = 0.5 * CSExtraDelay * GPMC_FCLK if ((CSOnTime - ClkActivationTime) is a multiple of 4)
F = (1 + 0.5 * CSExtraDelay) * GPMC_FCLK if ((CSOnTime - ClkActivationTime - 1) is a multiple of 4)
F = (2 + 0.5 * CSExtraDelay) * GPMC_FCLK if ((CSOnTime - ClkActivationTime - 2) is a multiple of 4)
F = (3 + 0.5 * CSExtraDelay) * GPMC_FCLK if ((CSOnTime - ClkActivationTime - 3) is a multiple of 4)
For ADV falling edge (ADV activated):
Case GpmcFCLKDivider = 0 :
G = 0.5 * ADVExtraDelay * GPMC_FCLK
Case GpmcFCLKDivider = 1:
G = 0.5 * ADVExtraDelay * GPMC_FCLK if (ClkActivationTime and ADVOnTime are odd) or (ClkActivationTime and ADVOnTime are even)
G = (1 + 0.5 * ADVExtraDelay) * GPMC_FCLK otherwise
Case GpmcFCLKDivider = 2:
G = 0.5 * ADVExtraDelay * GPMC_FCLK if ((ADVOnTime - ClkActivationTime) is a multiple of 3)
G = (1 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVOnTime - ClkActivationTime - 1) is a multiple of 3)
G = (2 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVOnTime - ClkActivationTime - 2) is a multiple of 3)
For ADV rising edge (ADV desactivated) in Reading mode:
Case GpmcFCLKDivider = 0:
G = 0.5 * ADVExtraDelay * GPMC_FCLK
Case GpmcFCLKDivider = 1:
G = 0.5 * ADVExtraDelay * GPMC_FCLK if (ClkActivationTime and ADVRdOffTime are odd) or (ClkActivationTime and ADVRdOffTime are even)
G = (1 + 0.5 * ADVExtraDelay) * GPMC_FCLK otherwise
Case GpmcFCLKDivider = 2:
G = 0.5 * ADVExtraDelay * GPMC_FCLK if ((ADVRdOffTime - ClkActivationTime) is a multiple of 3)
G = (1 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVRdOffTime - ClkActivationTime - 1) is a multiple of 3)
G = (2 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVRdOffTime - ClkActivationTime - 2) is a multiple of 3)
Case GpmcFCLKDivider = 3:
G = 0.5 * ADVExtraDelay * GPMC_FCLK if ((ADVRdOffTime - ClkActivationTime) is a multiple of 4)
G = (1 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVRdOffTime - ClkActivationTime - 1) is a multiple of 4)
G = (2 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVRdOffTime - ClkActivationTime - 2) is a multiple of 4)
G = (3 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVRdOffTime - ClkActivationTime - 3) is a multiple of 4)
For ADV rising edge (ADV desactivated) in Writing mode:
Case GpmcFCLKDivider = 0:
G = 0.5 * ADVExtraDelay * GPMC_FCLK
Case GpmcFCLKDivider = 1:
G = 0.5 * ADVExtraDelay * GPMC_FCLK if (ClkActivationTime and ADVWrOffTime are odd) or (ClkActivationTime and ADVWrOffTime are even)
G = (1 + 0.5 * ADVExtraDelay) * GPMC_FCLK otherwise
Case GpmcFCLKDivider = 2:
G = 0.5 * ADVExtraDelay * GPMC_FCLK if ((ADVWrOffTime - ClkActivationTime) is a multiple of 3)
G = (1 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVWrOffTime - ClkActivationTime - 1) is a multiple of 3)
G = (2 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVWrOffTime - ClkActivationTime - 2) is a multiple of 3)
Case GpmcFCLKDivider = 3:
G = 0.5 * ADVExtraDelay * GPMC_FCLK if ((ADVWrOffTime - ClkActivationTime) is a multiple of 4)
G = (1 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVWrOffTime - ClkActivationTime - 1) is a multiple of 4)
G = (2 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVWrOffTime - ClkActivationTime - 2) is a multiple of 4)
G = (3 + 0.5 * ADVExtraDelay) * GPMC_FCLK if ((ADVWrOffTime - ClkActivationTime - 3) is a multiple of 4)
For OE falling edge (OE activated):
Case GpmcFCLKDivider = 0:
- H = 0.5 * OEExtraDelay * GPMC_FCLK
Case GpmcFCLKDivider = 1:
- H = 0.5 * OEExtraDelay * GPMC_FCLK if (ClkActivationTime and OEOnTime are odd) or (ClkActivationTime and OEOnTime are even)
- H = (1 + 0.5 * OEExtraDelay) * GPMC_FCLK otherwise
Case GpmcFCLKDivider = 2:
- H = 0.5 * OEExtraDelay * GPMC_FCLK if ((OEOnTime - ClkActivationTime) is a multiple of 3)
- H = (1 + 0.5 * OEExtraDelay) * GPMC_FCLK if ((OEOnTime - ClkActivationTime - 1) is a multiple of 3)
- H = (2 + 0.5 * OEExtraDelay) * GPMC_FCLK if ((OEOnTime - ClkActivationTime - 2) is a multiple of 3)
Case GpmcFCLKDivider = 3:
- H = 0.5 * OEExtraDelay * GPMC_FCLK if ((OEOnTime - ClkActivationTime) is a multiple of 4)
- H = (1 + 0.5 * OEExtraDelay) * GPMC_FCLK if ((OEOnTime - ClkActivationTime - 1) is a multiple of 4)
- H = (2 + 0.5 * OEExtraDelay) * GPMC_FCLK if ((OEOnTime - ClkActivationTime - 2) is a multiple of 4)
- H = (3 + 0.5 * OEExtraDelay)) * GPMC_FCLK if ((OEOnTime - ClkActivationTime - 3) is a multiple of 4)
For OE rising edge (OE desactivated):
Case GpmcFCLKDivider = 0:
- H = 0.5 * OEExtraDelay * GPMC_FCLK
Case GpmcFCLKDivider = 1:
- H = 0.5 * OEExtraDelay * GPMC_FCLK if (ClkActivationTime and OEOffTime are odd) or (ClkActivationTime and OEOffTime are even)
- H = (1 + 0.5 * OEExtraDelay) * GPMC_FCLK otherwise
Case GpmcFCLKDivider = 2:
- H = 0.5 * OEExtraDelay * GPMC_FCLK if ((OEOffTime - ClkActivationTime) is a multiple of 3)
- H = (1 + 0.5 * OEExtraDelay) * GPMC_FCLK if ((OEOffTime - ClkActivationTime - 1) is a multiple of 3)
- H = (2 + 0.5 * OEExtraDelay) * GPMC_FCLK if ((OEOffTime - ClkActivationTime - 2) is a multiple of 3)
Case GpmcFCLKDivider = 3:
- H = 0.5 * OEExtraDelay * GPMC_FCLK if ((OEOffTime - ClkActivationTime) is a multiple of 4)
- H = (1 + 0.5 * OEExtraDelay) * GPMC_FCLK if ((OEOffTime - ClkActivationTime - 1) is a multiple of 4)
- H = (2 + 0.5 * OEExtraDelay) * GPMC_FCLK if ((OEOffTime - ClkActivationTime - 2) is a multiple of 4)
- H = (3 + 0.5 * OEExtraDelay) * GPMC_FCLK if ((OEOffTime - ClkActivationTime - 3) is a multiple of 4)
For WE falling edge (WE activated):
Case GpmcFCLKDivider = 0:
- I = 0.5 * WEExtraDelay * GPMC_FCLK
Case GpmcFCLKDivider = 1:
- I = 0.5 * WEExtraDelay * GPMC_FCLK if (ClkActivationTime and WEOnTime are odd) or (ClkActivationTime and WEOnTime are even)
- I = (1 + 0.5 * WEExtraDelay) * GPMC_FCLK otherwise
Case GpmcFCLKDivider = 2:
- I = 0.5 * WEExtraDelay * GPMC_FCLK if ((WEOnTime - ClkActivationTime) is a multiple of 3)
- I = (1 + 0.5 * WEExtraDelay) * GPMC_FCLK if ((WEOnTime - ClkActivationTime - 1) is a multiple of 3)
- I = (2 + 0.5 * WEExtraDelay) * GPMC_FCLK if ((WEOnTime - ClkActivationTime - 2) is a multiple of 3)
Case GpmcFCLKDivider = 3:
- I = 0.5 * WEExtraDelay * GPMC_FCLK if ((WEOnTime - ClkActivationTime) is a multiple of 4)
- I = (1 + 0.5 * WEExtraDelay) * GPMC_FCLK if ((WEOnTime - ClkActivationTime - 1) is a multiple of 4)
- I = (2 + 0.5 * WEExtraDelay) * GPMC_FCLK if ((WEOnTime - ClkActivationTime - 2) is a multiple of 4)
- I = (3 + 0.5 * WEExtraDelay) * GPMC_FCLK if ((WEOnTime - ClkActivationTime - 3) is a multiple of 4)
For WE rising edge (WE desactivated):
Case GpmcFCLKDivider = 0:
- I = 0.5 * WEExtraDelay * GPMC_FCLK
Case GpmcFCLKDivider = 1:
- I = 0.5 * WEExtraDelay * GPMC_FCLK if (ClkActivationTime and WEOffTime are odd) or (ClkActivationTime and WEOffTime are even)
- I = (1 + 0.5 * WEExtraDelay) * GPMC_FCLK otherwise
Case GpmcFCLKDivider = 2:
- I = 0.5 * WEExtraDelay * GPMC_FCLK if ((WEOffTime - ClkActivationTime) is a multiple of 3)
- I = (1 + 0.5 * WEExtraDelay) * GPMC_FCLK if ((WEOffTime - ClkActivationTime - 1) is a multiple of 3)
- I = (2 + 0.5 * WEExtraDelay) * GPMC_FCLK if ((WEOffTime - ClkActivationTime - 2) is a multiple of 3)
Case GpmcFCLKDivider = 3:
- I = 0.5 * WEExtraDelay * GPMC_FCLK if ((WEOffTime - ClkActivationTime) is a multiple of 4)
- I = (1 + 0.5 * WEExtraDelay) * GPMC_FCLK if ((WEOffTime - ClkActivationTime - 1) is a multiple of 4)
- I = (2 + 0.5 * WEExtraDelay) * GPMC_FCLK if ((WEOffTime - ClkActivationTime - 2) is a multiple of 4)
- I = (3 + 0.5 * WEExtraDelay) * GPMC_FCLK if ((WEOffTime - ClkActivationTime - 3) is a multiple of 4)
J = GPMC_FCLK period, where GPMC_FCLK is the General Purpose Memory Controller internal functional clock
For read:
K = (ADVRdOffTime - ADVOnTime) * (TimeParaGranularity + 1) * GPMC_FCLK
For write: K = (ADVWrOffTime - ADVOnTime) * (TimeParaGranularity + 1) * GPMC_FCLK
The gpmc_clk output clock maximum and minimum frequency is programmable in the I/F module by setting the GPMC_CONFIG1_CSx configuration register bit fields GpmcFCLKDivider
gpio6_16 programmed to MUXMODE=9 (clkout1), CM_CLKSEL_CLKOUTMUX1 programmed to 7 (CORE_DPLL_OUT_DCLK), CM_CLKSEL_CORE_DPLL_OUT_CLK_CLKOUTMUX programmed to 1.
CSEXTRADELAY = 0, ADVEXTRADELAY = 0, WEEXTRADELAY = 0, OEEXTRADELAY = 0. Extra half-GPMC_FCLK cycle delay mode is not timed.

Figure 7-7 GPMC / Multiplexed 16bits NOR Flash - Synchronous Single Read -
(GpmcFCLKDivider = 0)^{⁽¹⁾⁽²⁾}

In gpmc_csi, i = 0 to 7.
In gpmc_waitj, j = 0 to 1.

Figure 7-8 GPMC / Nonmultiplexed 16bits NOR Flash - Synchronous Single Read -
(GpmcFCLKDivider = 0)^{⁽¹⁾⁽²⁾}

In gpmc_csi, i = 0 to 7.
In gpmc_waitj, j = 0 to 1.

Figure 7-9 GPMC / Multiplexed 16bits NOR Flash - Synchronous Burst Read 4x16 bits -
(GpmcFCLKDivider = 0)^{⁽¹⁾⁽²⁾}

In gpmc_csi, i= 0 to 7.
In gpmc_waitj, j = 0 to 1.

Figure 7-10 GPMC / Nonmultiplexed 16bits NOR Flash - Synchronous Burst Read 4x16 bits -
(GpmcFCLKDivider = 0)^{⁽¹⁾⁽²⁾}

In gpmc_csi, i = 0 to 7.
In gpmc_waitj, j = 0 to 1.

Figure 7-11 GPMC / Multiplexed 16bits NOR Flash - Synchronous Burst Write 4x16bits -
(GpmcFCLKDivider = 0)^{⁽¹⁾⁽²⁾}

In “gpmc_csi”, i = 0 to 7.
In “gpmc_waitj”, j = 0 to 1.

Figure 7-12 GPMC / Nonmultiplexed 16bits NOR Flash - Synchronous Burst Write 4x16bits - (GpmcFCLKDivider = 0)^{⁽¹⁾⁽²⁾}

In “gpmc_csi”, i = 1 to 7.
In “gpmc_waitj”, j = 0 to 1.

7.11.2 GPMC/NOR Flash Interface Asynchronous Timing

CAUTION

Table 7-26 and Table 7-27 assume testing over the recommended operating conditions and electrical characteristic conditions below (see Figure 7-13, Figure 7-14, Figure 7-15, Figure 7-16, Figure 7-17 and Figure 7-18).

Table 7-26 GPMC/NOR Flash Interface Timing Requirements - Asynchronous Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
FA5	t_acc(DAT)	Data Maximum Access Time (GPMC_FCLK cycles)		H ^⁽¹⁾	cycles
FA20	t_{acc1-pgmode(DAT)}	Page Mode Successive Data Maximum Access Time (GPMC_FCLK cycles)		P ^⁽²⁾	cycles
FA21	t_{acc2-pgmode(DAT)}	Page Mode First Data Maximum Access Time (GPMC_FCLK cycles)		H ^⁽¹⁾	cycles
-	t_su(DV-OEH)	Setup time, read gpmc_ad[15:0] valid before gpmc_oen_ren high	1.9		ns
-	t_h(OEH-DV)	Hold time, read gpmc_ad[15:0] valid after gpmc_oen_ren high	1		ns

H = Access Time * (TimeParaGranularity + 1)
P = PageBurstAccessTime * (TimeParaGranularity + 1)

Table 7-27 GPMC/NOR Flash Interface Switching Characteristics - Asynchronous Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
-	t_r(DO)	Rising time, gpmc_ad[15:0] output data	0.447	4.067	ns
-	t_f(DO)	Fallling time, gpmc_ad[15:0] output data	0.43	4.463	ns
FA0	t_w(nBEV)	Pulse duration, gpmc_ben[1:0] valid time		N ^⁽¹⁾	ns
FA1	t_w(nCSV)	Pulse duration, gpmc_cs[7:0] low		A ^⁽²⁾	ns
FA3	t_{d(nCSV-nADVIV)}	Delay time, gpmc_cs[7:0] valid to gpmc_advn_ale invalid	B - 2 ^⁽³⁾	B + 4 ^⁽³⁾	ns
FA4	t_{d(nCSV-nOEIV)}	Delay time, gpmc_cs[7:0] valid to gpmc_oen_ren invalid (Single read)	C - 2 ^⁽⁴⁾	C + 4 ^⁽⁴⁾	ns
FA9	t_d(AV-nCSV)	Delay time, address bus valid to gpmc_cs[7:0] valid	J - 2 ^⁽⁵⁾	J + 4 ^⁽⁵⁾	ns
FA10	t_d(nBEV-nCSV)	Delay time, gpmc_ben[1:0] valid to gpmc_cs[7:0] valid	J - 2 ^⁽⁵⁾	J + 4 ^⁽⁵⁾	ns
FA12	t_{d(nCSV-nADVV)}	Delay time, gpmc_cs[7:0] valid to gpmc_advn_ale valid	K - 2 ^⁽⁶⁾	K + 4 ^⁽⁶⁾	ns
FA13	t_d(nCSV-nOEV)	Delay time, gpmc_cs[7:0] valid to gpmc_oen_ren valid	L - 2 ^⁽⁷⁾	L + 4 ^⁽⁷⁾	ns
FA16	t_w(AIV)	Pulse duration, address invalid between 2 successive R/W accesses	G ^⁽⁸⁾		ns
FA18	t_{d(nCSV-nOEIV)}	Delay time, gpmc_cs[7:0] valid to gpmc_oen_ren invalid (Burst read)	I - 2 ^⁽⁹⁾	I + 4 ^⁽⁹⁾	ns
FA20	t_w(AV)	Pulse duration, address valid : 2nd, 3rd and 4th accesses	D ^⁽¹⁰⁾		ns
FA25	t_d(nCSV-nWEV)	Delay time, gpmc_cs[7:0] valid to gpmc_wen valid	E - 2 ^⁽¹¹⁾	E + 4 ^⁽¹¹⁾	ns
FA27	t_{d(nCSV-nWEIV)}	Delay time, gpmc_cs[7:0] valid to gpmc_wen invalid	F - 2 ^⁽¹²⁾	F + 4 ^⁽¹²⁾	ns
FA28	t_d(nWEV-DV)	Delay time, gpmc_ wen valid to data bus valid		2	ns
FA29	t_d(DV-nCSV)	Delay time, data bus valid to gpmc_cs[7:0] valid	J - 2 ^⁽⁵⁾	J + 4 ^⁽⁵⁾	ns
FA37	t_d(nOEV-AIV)	Delay time, gpmc_oen_ren valid to gpmc_ad[15:0] multiplexed address bus phase end		2	ns

For single read: N = RdCycleTime * (TimeParaGranularity + 1) * GPMC_FCLK
For single write: N = WrCycleTime * (TimeParaGranularity + 1) * GPMC_FCLK
For burst read: N = (RdCycleTime + (n - 1) * PageBurstAccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK
For burst write: N = (WrCycleTime + (n - 1) * PageBurstAccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK
For single read: A = (CSRdOffTime - CSOnTime) * (TimeParaGranularity + 1) * GPMC_FCLK
For single write: A = (CSWrOffTime - CSOnTime) * (TimeParaGranularity + 1) * GPMC_FCLK
For burst read: A = (CSRdOffTime - CSOnTime + (n - 1) * PageBurstAccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK
For burst write: A = (CSWrOffTime - CSOnTime + (n - 1) * PageBurstAccessTime) * (TimeParaGranularity + 1) * GPMC_FCLK
For reading: B = ((ADVRdOffTime - CSOnTime) * (TimeParaGranularity + 1) + 0.5 * (ADVExtraDelay - CSExtraDelay)) * GPMC_FCLK
For writing: B = ((ADVWrOffTime - CSOnTime) * (TimeParaGranularity + 1) + 0.5 * (ADVExtraDelay - CSExtraDelay)) * GPMC_FCLK
C = ((OEOffTime - CSOnTime) * (TimeParaGranularity + 1) + 0.5 * (OEExtraDelay - CSExtraDelay)) * GPMC_FCLK
J = (CSOnTime * (TimeParaGranularity + 1) + 0.5 * CSExtraDelay) * GPMC_FCLK
K = ((ADVOnTime - CSOnTime) * (TimeParaGranularity + 1) + 0.5 * (ADVExtraDelay - CSExtraDelay)) * GPMC_FCLK
L = ((OEOnTime - CSOnTime) * (TimeParaGranularity + 1) + 0.5 * (OEExtraDelay - CSExtraDelay)) * GPMC_FCLK
G = Cycle2CycleDelay * GPMC_FCLK * (TimeParaGranularity +1)
I = ((OEOffTime + (n - 1) * PageBurstAccessTime - CSOnTime) * (TimeParaGranularity + 1) + 0.5 * (OEExtraDelay - CSExtraDelay)) * GPMC_FCLK
D = PageBurstAccessTime * (TimeParaGranularity + 1) * GPMC_FCLK
E = ((WEOnTime - CSOnTime) * (TimeParaGranularity + 1) + 0.5 * (WEExtraDelay - CSExtraDelay)) * GPMC_FCLK
F = ((WEOffTime - CSOnTime) * (TimeParaGranularity + 1) + 0.5 * (WEExtraDelay - CSExtraDelay)) * GPMC_FCLK

Figure 7-13 GPMC / NOR Flash - Asynchronous Read - Single Word Timing^{⁽¹⁾⁽²⁾⁽³⁾}

In gpmc_csi, i = 0 to 7. In gpmc_waitj, j = 0 to 1.
FA5 parameter illustrates amount of time required to internally sample input data. It is expressed in number of GPMC functional clock cycles. From start of read cycle and after FA5 functional clock cycles, input Data will be internally sampled by active functional clock edge. FA5 value must be stored inside AccessTime register bits field.
GPMC_FCLK is an internal clock (GPMC functional clock) not provided externally.
The "DIR" (direction control) output signal is NOT pinned out on any of the device pads. It is an internal signal only representing a signal direction on the GPMC data bus.

Figure 7-14 GPMC / NOR Flash - Asynchronous Read - 32-bit Timing^{⁽¹⁾⁽²⁾⁽³⁾}

In “gpmc_csi”, i = 0 to 7. In “gpmc_waitj”, j = 0 to 1.
FA5 parameter illustrates amount of time required to internally sample input Data. It is expressed in number of GPMC functional clock cycles. From start of read cycle and after FA5 functional clock cycles, input Data will be internally sampled by active functional clock edge. FA5 value should be stored inside AccessTime register bits field
GPMC_FCLK is an internal clock (GPMC functional clock) not provided externally
The "DIR" (direction control) output signal is NOT pinned out on any of the device pads. It is an internal signal only representing a signal direction on the GPMC data bus.

Figure 7-15 GPMC / NOR Flash - Asynchronous Read - Page Mode 4x16-bit Timing^{⁽¹⁾⁽²⁾⁽³⁾⁽⁴⁾}

In “gpmc_csi”, i = 0 to 7. In “gpmc_waitj”, j = 0 to 1
FA21 parameter illustrates amount of time required to internally sample first input Page Data. It is expressed in number of GPMC functional clock cycles. From start of read cycle and after FA21 functional clock cycles, First input Page Data will be internally sampled by active functional clock edge. FA21 calculation is detailled in a separated application note and should be stored inside AccessTime register bits field.
FA20 parameter illustrates amount of time required to internally sample successive input Page Data. It is expressed in number of GPMC functional clock cycles. After each access to input Page Data, next input Page Data will be internally sampled by active functional clock edge after FA20 functional clock cycles. FA20 is also the duration of address phases for successive input Page Data (excluding first input Page Data). FA20 value should be stored in PageBurstAccessTime register bits field.
GPMC_FCLK is an internal clock (GPMC functional clock) not provided externally
The "DIR" (direction control) output signal is NOT pinned out on any of the device pads. It is an internal signal only representing a signal direction on the GPMC data bus.

Figure 7-16 GPMC / NOR Flash - Asynchronous Write - Single Word Timing^⁽¹⁾

In “gpmc_csi”, i = 0 to 7. In “gpmc_waitj”, j = 0 to 1.
The "DIR" (direction control) output signal is NOT pinned out on any of the device pads. It is an internal signal only representing a signal direction on the GPMC data bus.

Figure 7-17 GPMC / Multiplexed NOR Flash - Asynchronous Read - Single Word Timing^{⁽¹⁾⁽²⁾⁽³⁾}

In “gpmc_csi”, i = 0 to 7. In “gpmc_waitj”, j = 0 to 1
FA5 parameter illustrates amount of time required to internally sample input Data. It is expressed in number of GPMC functional clock cycles. From start of read cycle and after FA5 functional clock cycles, input Data will be internally sampled by active functional clock edge. FA5 value should be stored inside AccessTime register bits field.
GPMC_FCLK is an internal clock (GPMC functional clock) not provided externally
The "DIR" (direction control) output signal is NOT pinned out on any of the device pads. It is an internal signal only representing a signal direction on the GPMC data bus.

Figure 7-18 GPMC / Multiplexed NOR Flash - Asynchronous Write - Single Word Timing^⁽¹⁾

In “gpmc_csi”, i = 0 to 7. In “gpmc_waitj”, j = 0 to 1.
The "DIR" (direction control) output signal is NOT pinned out on any of the device pads. It is an internal signal only representing a signal direction on the GPMC data bus.

7.11.3 GPMC/NAND Flash Interface Asynchronous Timing

CAUTION

Table 7-28 and Table 7-29 assume testing over the recommended operating conditions and electrical characteristic conditions below (see Figure 7-19, Figure 7-20, Figure 7-21 and Figure 7-22).

Table 7-28 GPMC/NAND Flash Interface Timing Requirements

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
GNF12	t_acc(DAT)	Data maximum access time (GPMC_FCLK Cycles)		J ^⁽¹⁾	cycles
-	t_su(DV-OEH)	Setup time, read gpmc_ad[15:0] valid before gpmc_oen_ren high	1.9		ns
-	t_h(OEH-DV)	Hold time, read gpmc_ad[15:0] valid after gpmc_oen_ren high	1		ns

J = AccessTime * (TimeParaGranularity + 1)

Table 7-29 GPMC/NAND Flash Interface Switching Characteristics

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
-	t_r(DO)	Rising time, gpmc_ad[15:0] output data	0.447	4.067	ns
-	t_f(DO)	Fallling time, gpmc_ad[15:0] output data	0.43	4.463	ns
GNF0	t_w(nWEV)	Pulse duration, gpmc_wen valid time		A ^⁽¹⁾	ns
GNF1	t_d(nCSV-nWEV)	Delay time, gpmc_cs[7:0] valid to gpmc_wen valid	B - 2 ^⁽²⁾	B + 4 ^⁽²⁾	ns
GNF2	t_d(CLEH-nWEV)	Delay time, gpmc_ben[1:0] high to gpmc_wen valid	C - 2 ^⁽³⁾	C + 4 ^⁽³⁾	ns
GNF3	t_d(nWEV-DV)	Delay time, gpmc_ad[15:0] valid to gpmc_wen valid	D - 2 ^⁽⁴⁾	D + 4 ^⁽⁴⁾	ns
GNF4	t_d(nWEIV-DIV)	Delay time, gpmc_wen invalid to gpmc_ad[15:0] invalid	E - 2 ^⁽⁵⁾	E + 4 ^⁽⁵⁾	ns
GNF5	t_{d(nWEIV-CLEIV)}	Delay time, gpmc_wen invalid to gpmc_ben[1:0] invalid	F - 2 ^⁽⁶⁾	F + 4 ^⁽⁶⁾	ns
GNF6	t_{d(nWEIV-nCSIV)}	Delay time, gpmc_wen invalid to gpmc_cs[7:0] invalid	G - 2 ^⁽⁷⁾	G + 4 ^⁽⁷⁾	ns
GNF7	t_d(ALEH-nWEV)	Delay time, gpmc_advn_ale high to gpmc_wen valid	C - 2 ^⁽³⁾	C + 4 ^⁽³⁾	ns
GNF8	t_{d(nWEIV-ALEIV)}	Delay time, gpmc_wen invalid to gpmc_advn_ale invalid	F - 2 ^⁽⁶⁾	F + 4 ^⁽⁶⁾	ns
GNF9	t_c(nWE)	Cycle time, write cycle time		H ^⁽⁸⁾	ns
GNF10	t_d(nCSV-nOEV)	Delay time, gpmc_cs[7:0] valid to gpmc_oen_ren valid	I - 2 ^⁽⁹⁾	I + 4 ^⁽⁹⁾	ns
GNF13	t_w(nOEV)	Pulse duration, gpmc_oen_ren valid time		K ^⁽¹⁰⁾	ns
GNF14	t_c(nOE)	Cycle time, read cycle time		L ^⁽¹¹⁾	ns
GNF15	t_{d(nOEIV-nCSIV)}	Delay time, gpmc_oen_ren invalid to gpmc_cs[7:0] invalid	M - 2 ^⁽¹²⁾	M + 4 ^⁽¹²⁾	ns

A = (WEOffTime - WEOnTime) * (TimeParaGranularity + 1) * GPMC_FCLK
B = ((WEOnTime - CSOnTime) * (TimeParaGranularity + 1) + 0.5 * (WEExtraDelay - CSExtraDelay)) * GPMC_FCLK
C = ((WEOnTime - ADVOnTime) * (TimeParaGranularity + 1) + 0.5 * (WEExtraDelay - ADVExtraDelay)) * GPMC_FCLK
D = (WEOnTime * (TimeParaGranularity + 1) + 0.5 * WEExtraDelay ) * GPMC_FCLK
E = (WrCycleTime - WEOffTime * (TimeParaGranularity + 1) - 0.5 * WEExtraDelay ) * GPMC_FCLK
F = (ADVWrOffTime - WEOffTime * (TimeParaGranularity + 1) + 0.5 * (ADVExtraDelay - WEExtraDelay ) * GPMC_FCLK
G = (CSWrOffTime - WEOffTime * (TimeParaGranularity + 1) + 0.5 * (CSExtraDelay - WEExtraDelay ) * GPMC_FCLK
H = WrCycleTime * (1 + TimeParaGranularity) * GPMC_FCLK
I = ((OEOffTime + (n - 1) * PageBurstAccessTime - CSOnTime) * (TimeParaGranularity + 1) + 0.5 * (OEExtraDelay - CSExtraDelay)) * GPMC_FCLK
K = (OEOffTime - OEOnTime) * (1 + TimeParaGranularity) * GPMC_FCLK
L = RdCycleTime * (1 + TimeParaGranularity) * GPMC_FCLK
M = (CSRdOffTime - OEOffTime * (TimeParaGranularity + 1) + 0.5 * (CSExtraDelay - OEExtraDelay ) * GPMC_FCLK

Figure 7-19 GPMC / NAND Flash - Command Latch Cycle Timing^⁽¹⁾

In gpmc_csi, i = 0 to 7.

Figure 7-20 GPMC / NAND Flash - Address Latch Cycle Timing^⁽¹⁾

In gpmc_csi, i = 0 to 7.

Figure 7-21 GPMC / NAND Flash - Data Read Cycle Timing^{⁽¹⁾⁽²⁾⁽³⁾}

GNF12 parameter illustrates amount of time required to internally sample input Data. It is expressed in number of GPMC functional clock cycles. From start of read cycle and after GNF12 functional clock cycles, input data will be internally sampled by active functional clock edge. GNF12 value must be stored inside AccessTime register bits field.
GPMC_FCLK is an internal clock (GPMC functional clock) not provided externally.
In gpmc_csi, i = 0 to 7. In gpmc_waitj, j = 0 to 1.

Figure 7-22 GPMC / NAND Flash - Data Write Cycle Timing^⁽¹⁾

In gpmc_csi, i = 0 to 7.

NOTE

To configure the desired virtual mode the user must set MODESELECT bit and DELAYMODE bitfield for each corresponding pad control register.

The pad control registers are presented in Table 4-3 and described in Device TRM, Control Module Chapter.

Virtual IO Timings Modes must be used to guaranteed some IO timings for GPMC. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Virtual IO Timings Modes. See Table 7-30 Virtual Functions Mapping for GPMC for a definition of the Virtual modes.

Table 7-30 presents the values for DELAYMODE bitfield.

Table 7-30 Virtual Functions Mapping for GPMC

BALL	BALL NAME	Delay Mode Value	MUXMODE
BALL	BALL NAME	GPMC_VIRTUAL1	0	1	2	3	5	6	14^⁽¹⁾	14^⁽¹⁾
N1	gpmc_advn_ale	15	gpmc_advn_ale	gpmc_cs6		gpmc_wait1	gpmc_a2	gpmc_a23
H3	gpmc_ad15	13	gpmc_ad15
L3	gpmc_ad6	13	gpmc_ad6
L5	gpmc_ad2	13	gpmc_ad2
E6	vin2a_d9	9							gpmc_a25
M3	gpmc_wen	15	gpmc_wen
H2	gpmc_ad14	13	gpmc_ad14
R3	gpmc_a13	15	gpmc_a13
N7	gpmc_a8	14	gpmc_a8
T2	gpmc_a14	15	gpmc_a14
L6	gpmc_ad4	13	gpmc_ad4
H4	gpmc_a26	15	gpmc_a26		gpmc_a20
M6	gpmc_ad0	13	gpmc_ad0
N2	gpmc_wait0	15	gpmc_wait0
F6	vin2a_d11	9							gpmc_a23
M2	gpmc_ad1	13	gpmc_ad1
J3	gpmc_ad13	13	gpmc_ad13
T6	gpmc_a2	14	gpmc_a2
L4	gpmc_ad5	13	gpmc_ad5
F5	vin2a_d8	9							gpmc_a26
T1	gpmc_cs0	15	gpmc_cs0
G1	vin2a_hsync0	9							gpmc_a27
P6	gpmc_a4	14	gpmc_a4
N6	gpmc_ben0	15	gpmc_ben0	gpmc_cs4
R5	gpmc_a6	14	gpmc_a6
U2	gpmc_a15	15	gpmc_a15
J2	gpmc_ad11	13	gpmc_ad11
U1	gpmc_a16	15	gpmc_a16
T9	gpmc_a1	14	gpmc_a1
J4	gpmc_a24	15	gpmc_a24		gpmc_a18
J7	gpmc_a23	15	gpmc_a23		gpmc_a17
L1	gpmc_ad8	13	gpmc_ad8
J1	gpmc_ad10	13	gpmc_ad10
H1	gpmc_ad12	13	gpmc_ad12
M7	gpmc_a20	15	gpmc_a20		gpmc_a14
D3	vin2a_d10	9							gpmc_a24
P1	gpmc_cs3	14	gpmc_cs3				gpmc_a1
M5	gpmc_oen_ren	15	gpmc_oen_ren
R4	gpmc_a9	14	gpmc_a9
H6	gpmc_cs1	15	gpmc_cs1		gpmc_a22
M1	gpmc_ad3	13	gpmc_ad3
L2	gpmc_ad7	13	gpmc_ad7
P5	gpmc_a7	14	gpmc_a7
T7	gpmc_a3	14	gpmc_a3
M4	gpmc_ben1	15	gpmc_ben1	gpmc_cs5			gpmc_a3
P7	gpmc_clk	15	gpmc_clk	gpmc_cs7		gpmc_wait1
K6	gpmc_a22	15	gpmc_a22		gpmc_a16
P2	gpmc_cs2	15	gpmc_cs2
H7	vin2a_fld0	11							gpmc_a27	gpmc_a18
N9	gpmc_a10	14	gpmc_a10
P4	gpmc_a12	15	gpmc_a12				gpmc_a0
P3	gpmc_a17	15	gpmc_a17
R9	gpmc_a5	14	gpmc_a5
J5	gpmc_a21	15	gpmc_a21		gpmc_a15
H5	gpmc_a27	15	gpmc_a27		gpmc_a21
K2	gpmc_ad9	13	gpmc_ad9
K7	gpmc_a19	15	gpmc_a19		gpmc_a13
J6	gpmc_a25	15	gpmc_a25		gpmc_a19
R6	gpmc_a0	14	gpmc_a0
E1	vin2a_clk0	11							gpmc_a27	gpmc_a17
R2	gpmc_a18	15	gpmc_a18
P9	gpmc_a11	14	gpmc_a11

Some signals listed are virtual functions that present alternate multiplexing options. These virtual functions are controlled via CTRL_CORE_ALT_SELECT_MUX or CTRL_CORE_VIP_MUX_SELECT registers. For more information on how to use these options, please refer to Device TRM, Chapter Control Module, Section Pad Configuration Registers.

7.12 Timers

The device has 16 general-purpose (GP) timers (TIMER1 - TIMER16), two watchdog timers, and a 32-kHz synchronized timer (COUNTER_32K) that have the following features:

Dedicated input trigger for capture mode and dedicated output trigger/pulse width modulation (PWM) signal
Interrupts generated on overflow, compare, and capture
Free-running 32-bit upward counter
Supported modes:
- Compare and capture modes
- Auto-reload mode
- Start-stop mode
On-the-fly read/write register (while counting)

The device has two system watchdog timer (WD_TIMER1 and WD_TIMER2) that have the following features:

Free-running 32-bit upward counter
On-the-fly read/write register (while counting)
Reset upon occurrence of a timer overflow condition

The device includes one instance of the 32-bit watchdog timer: WD_TIMER2, also called the MPU watchdog timer.

The watchdog timer is used to provide a recovery mechanism for the device in the event of a fault condition, such as a non-exiting code loop.

NOTE

For additional information on the Timer Module, see the Device TRM.

7.13 Inter-Integrated Circuit Interface (I2C)

The device includes 5 inter-integrated circuit (I2C) modules which provide an interface to other devices compliant with Philips Semiconductors Inter-IC bus (I2C-bus™) specification version 2.1. External components attached to this 2-wire serial bus can transmit/receive 8-bit data to/from the device through the I2C module.

NOTE

Note that, on I2C1 and I2C2, due to characteristics of the open drain IO cells, HS mode is not supported.

NOTE

Inter-integrated circuit i (i=1 to 5) module is also referred to as I2Ci.

NOTE

For more information, see the Multimaster High-Speed I2C Controller section of the Device TRM.

Table 7-31, Table 7-32 and Figure 7-23 assume testing over the recommended operating conditions and electrical characteristic conditions below.

Table 7-31 Timing Requirements for I2C Input Timings^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	STANDARD MODE		FAST MODE		UNIT
NO.	PARAMETER	DESCRIPTION	MIN	MAX	MIN	MAX	UNIT
1	t_c(SCL)	Cycle time, SCL	10		2.5		µs
2	t_{su(SCLH-SDAL)}	Setup time, SCL high before SDA low (for a repeated START condition)	4.7		0.6		µs
3	t_h(SDAL-SCLL)	Hold time, SCL low after SDA low (for a START and a repeated START condition)	4		0.6		µs
4	t_w(SCLL)	Pulse duration, SCL low	4.7		1.3		µs
5	t_w(SCLH)	Pulse duration, SCL high	4		0.6		µs
6	t_{su(SDAV-SCLH)}	Setup time, SDA valid before SCL high	250		100^⁽²⁾		ns
7	t_h(SCLL-SDAV)	Hold time, SDA valid after SCL low	0^⁽³⁾	3.45^⁽⁴⁾	0^⁽³⁾	0.9^⁽⁴⁾	µs
8	t_w(SDAH)	Pulse duration, SDA high between STOP and START conditions	4.7		1.3		µs
9	t_r(SDA)	Rise time, SDA		1000	20 + 0.1C_b ^⁽⁵⁾	300^⁽³⁾	ns
10	t_r(SCL)	Rise time, SCL		1000	20 + 0.1C_b ^⁽⁵⁾	300^⁽³⁾	ns
11	t_f(SDA)	Fall time, SDA		300	20 + 0.1C_b ^⁽⁵⁾	300^⁽³⁾	ns
12	t_f(SCL)	Fall time, SCL		300	20 + 0.1C_b ^⁽⁵⁾	300^⁽³⁾	ns
13	t_{su(SCLH-SDAH)}	Setup time, SCL high before SDA high (for STOP condition)	4		0.6		µs
14	t_w(SP)	Pulse duration, spike (must be suppressed)			0	50	ns
15	C_b ^⁽⁵⁾	Capacitive load for each bus line		400		400	pF

The I2C pins SDA and SCL do not feature fail-safe I/O buffers. These pins could potentially draw current when the device is powered down.
A Fast-mode I²C-bus™ device can be used in a Standard-mode I²C-bus system, but the requirement t_su(SDA-SCLH)≥ 250 ns must then be met. This will automatically be the case if the device does not stretch the LOW period of the SCL signal. If such a device does stretch the LOW period of the SCL signal, it must output the next data bit to the SDA line t_r max + t_su(SDA-SCLH)= 1000 + 250 = 1250 ns (according to the Standard-mode I²C-Bus Specification) before the SCL line is released.
A device must internally provide a hold time of at least 300 ns for the SDA signal (referred to the V_IHmin of the SCL signal) to bridge the undefined region of the falling edge of SCL.
The maximum t_h(SDA-SCLL) has only to be met if the device does not stretch the low period [t_w(SCLL)] of the SCL signal.
C_b = total capacitance of one bus line in pF. If mixed with HS-mode devices, faster fall-times are allowed.

Table 7-32 Timing Requirements for I²C HS-Mode (I²C3/4/5 Only)^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	C_b = 100 pF MAX		C_b= 400 pF ^⁽²⁾		UNIT
NO.	PARAMETER	DESCRIPTION	MIN	MAX	MIN	MAX	UNIT
1	t_c(SCL)	Cycle time, SCL	0.294		0.588		µs
2	t_{su(SCLH-SDAL)}	Set-up time, SCL high before SDA low (for a repeated START condition)	160		160		ns
3	t_h(SDAL-SCLL)	Hold time, SCL low after SDA low (for a repeated START condition)	160		160		ns
4	t_w(SCLL)	LOW period of the SCLH clock	160		320		ns
5	t_w(SCLH)	HIGH period of the SCLH clock	60		120		ns
6	t_{su(SDAV-SCLH)}	Setup time, SDA valid vefore SCL high	10		10		ns
7	t_h(SCLL-SDAV)	Hold time, SDA valid after SCL low	0 ^⁽³⁾	70	0 ^⁽³⁾	150	ns
13	t_{su(SCLH-SDAH)}	Setup time, SCL high before SDA high (for a STOP condition)	160		160		ns
14	t_w(SP)	Pulse duration, spike (must be suppressed)	0	10	0	10	ns
15	C_b ^⁽²⁾	Capacitive load for SDAH and SCLH lines		100		400	pF
16	C_b	Capacitive load for SDAH + SDA line and SCLH + SCL line		400		400	pF

I²C HS-Mode is only supported on I²C3/4/5. I2C HS-Mode is not supported on I²C1/2.
For bus line loads C_b between 100 and 400 pF the timing parameters must be linearly interpolated.
A device must internally provide a Data hold time to bridge the undefined part between V_IH and V_IL of the falling edge of the SCLH signal. An input circuit with a threshold as low as possible for the falling edge of the SCLH signal minimizes this hold time.

Figure 7-23 I2C Receive Timing

Table 7-33 and Figure 7-24 assume testing over the recommended operating conditions and electrical characteristic conditions below.

Table 7-33 Switching Characteristics Over Recommended Operating Conditions for I2C Output Timings^⁽²⁾

NO.	PARAMETER	DESCRIPTION	STANDARD MODE		FAST MODE		UNIT
NO.	PARAMETER	DESCRIPTION	MIN	MAX	MIN	MAX	UNIT
16	t_c(SCL)	Cycle time, SCL	10		2.5		µs
17	t_{su(SCLH-SDAL)}	Setup time, SCL high before SDA low (for a repeated START condition)	4.7		0.6		µs
18	t_h(SDAL-SCLL)	Hold time, SCL low after SDA low (for a START and a repeated START condition)	4		0.6		µs
19	t_w(SCLL)	Pulse duration, SCL low	4.7		1.3		µs
20	t_w(SCLH)	Pulse duration, SCL high	4		0.6		µs
21	t_{su(SDAV-SCLH)}	Setup time, SDA valid before SCL high	250		100		ns
22	t_h(SCLL-SDAV)	Hold time, SDA valid after SCL low (for I2C bus devices)	0	3.45	0	0.9	µs
23	t_w(SDAH)	Pulse duration, SDA high between STOP and START conditions	4.7		1.3		µs
24	t_r(SDA)	Rise time, SDA		1000	20 + 0.1C_b ^{⁽¹⁾ ⁽³⁾}	300^⁽³⁾	ns
25	t_r(SCL)	Rise time, SCL		1000	20 + 0.1C_b ^{⁽¹⁾ ⁽³⁾}	300^⁽³⁾	ns
26	t_f(SDA)	Fall time, SDA		300	20 + 0.1C_b ^{⁽¹⁾ ⁽³⁾}	300^⁽³⁾	ns
27	t_f(SCL)	Fall time, SCL		300	20 + 0.1C_b ^{⁽¹⁾ ⁽³⁾}	300^⁽³⁾	ns
28	t_{su(SCLH-SDAH)}	Setup time, SCL high before SDA high (for STOP condition)	4		0.6		µs
29	C_p	Capacitance for each I2C pin		10		10	pF

C_b = total capacitance of one bus line in pF. If mixed with HS-mode devices, faster fall-times are allowed.
Software must properly configure the I2C module registers to achieve the timings shown in this table. See the Device TRM for details.
These timings apply only to I2C1 and I2C2. I2C3, I2C4, and I2C5 use standard LVCMOS buffers to emulate open-drain buffers and their rise/fall times should be referenced in the device IBIS model.

NOTE

I2C emulation is achieved by configuring the LVCMOS buffers to output Hi-Z instead of driving high when transmitting logic-1.

Figure 7-24 I2C Transmit Timing

7.14 HDQ / 1-Wire Interface (HDQ1W)

The module is intended to work with both HDQ and 1-Wire protocols. The protocols use a single wire to communicate between the master and the slave. The protocols employ an asynchronous return to one mechanism where, after any command, the line is pulled high.

NOTE

For more information, see the HDQ / 1-Wire section of the Device TRM.

7.14.1 HDQ / 1-Wire - HDQ Mode

Table 7-34 and Table 7-35 assume testing over the recommended operating conditions and electrical characteristic conditions below (see Figure 7-25, Figure 7-26, Figure 7-27 and Figure 7-28).

Table 7-34 HDQ/1-Wire Timing Requirements-HDQ Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
1	t_CYCH	Read bit window timing	190	250	µs
2	t_HW1	Read one data valid after HDQ low	32^⁽²⁾	66^⁽²⁾	µs
3	t_HW0	Read zero data hold after HDQ low	70^⁽²⁾	145^⁽²⁾	µs
4	t_RSPS	Response time from HDQ slave device^⁽¹⁾	190	320	µs

Defined by software.
If the HDQ slave device drives a logic-low state after tHW0 maximum, it can be interpreted as a break pulse. For more information see "HDQ / 1-Wire Switching Characteristics - HDQ Mode" and the HDQ/1-Wire chapter of the TRM.

Table 7-35 HDQ / 1-Wire Switching Characteristics - HDQ Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
5	t_B	Break timing	190		µs
6	t_BR	Break recovery time	40		µs
7	t_CYCD	Write bit windows timing	190		µs
8	t_DW1	Write one data valid after HDQ low	0.5	50	µs
9	t_DW0	Write zero data hold after HDQ low	86	145	µs

AM5718-HIREL SPRS906_TIMING_HDQ1W_01.gif

Figure 7-25 HDQ Break and Break Recovery Timing - HDQ Interface Writing to Slave

AM5718-HIREL SPRS906_TIMING_HDQ1W_02.gif

Figure 7-26 Device HDQ Interface Bit Read Timing (Data)

AM5718-HIREL SPRS906_TIMING_HDQ1W_03.gif

Figure 7-27 Device HDQ Interface Bit Write Timing (Command / Address or Data)

AM5718-HIREL SPRS906_TIMING_HDQ1W_04.gif

Figure 7-28 HDQ Communication Timing

7.14.2 HDQ/1-Wire-1-Wire Mode

Table 7-36 and Table 7-37 assume testing over the recommended operating conditions and electrical characteristic conditions below (see Figure 7-29, Figure 7-30 and Figure 7-31).

Table 7-36 HDQ / 1-Wire Timing Requirements - 1-Wire Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
10	t_PDH	Presence pulse delay high	15	60	µs
11	t_PDL	Presence pulse delay low	60	240	µs
12	t_RDV	Read data valid time	t_LOWR	15	µs
13	t_REL	Read data release time	0	45	µs

Table 7-37 HDQ / 1-Wire Switching Characteristics - 1-Wire Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
14	t_RSTL	Reset time low	480	960	µs
15	t_RSTH	Reset time high	480		µs
16	t_SLOT	Bit cycle time	60	120	µs
17	t_LOW1	Write bit-one time	1	15	µs
18	t_LOW0	Write bit-zero time^⁽²⁾	60	120	µs
19	t_REC	Recovery time	1		µs
20	t_LOWR	Read bit strobe time^⁽¹⁾	1	15	µs

t_LOWR (low pulse sent by the master) must be short as possible to maximize the master sampling window.
t_LOWR must be less than tSLOT.

AM5718-HIREL SPRS906_TIMING_HDQ1W_05.gif

Figure 7-29 1-Wire-Break (Reset)

AM5718-HIREL SPRS906_TIMING_HDQ1W_06.gif

Figure 7-30 1-Wire-Read Bit (Data)

AM5718-HIREL SPRS906_TIMING_HDQ1W_07.gif

Figure 7-31 1-Wire-Write Bit-One Timing (Command / Address or Data)

7.15 Universal Asynchronous Receiver Transmitter (UART)

The UART performs serial-to-parallel conversions on data received from a peripheral device and parallel-to-serial conversion on data received from the CPU. There are 10 UART modules in the device. Only one UART supports IrDA features. Each UART can be used for configuration and data exchange with a number of external peripheral devices or interprocessor communication between devices

The UARTi (where i = 1 to 10) include the following features:

16C750 compatibility
64-byte FIFO buffer for receiver and 64-byte FIFO for transmitter
Baud generation based on programmable divisors N (where N = 1…16 384) operating from a fixed functional clock of 48 MHz or 192 MHz

Break character detection and generation
Configurable data format:
- Data bit: 5, 6, 7, or 8 bits
- Parity bit: Even, odd, none
- Stop-bit: 1, 1.5, 2 bit(s)
Flow control: Hardware (RTS/CTS) or software (XON/XOFF)
Only UART1 module has extended modem control signals (CD, RI, DTR, DSR)
Only UART3 supports IrDA

NOTE

For more information, see the UART section of the Device TRM.

Table 7-38, Table 7-39 and Figure 7-32 assume testing over the recommended operating conditions and electrical characteristic conditions below.

Table 7-38 Timing Requirements for UART

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
4	t_w(RX)	Pulse width, receive data bit, 15/30/100pF high or low	0.96U^⁽¹⁾	1.05U^⁽¹⁾	ns
5	t_w(CTS)	Pulse width, receive start bit, 15/30/100pF high or low	0.96U^⁽¹⁾	1.05U^⁽¹⁾	ns
	t_d(RTS-TX)	Delay time, transmit start bit to transmit data	P^⁽²⁾		ns
	t_d(CTS-TX)	Delay time, receive start bit to transmit data	P^⁽²⁾		ns

U = UART baud time = 1/programmed baud rate
P = Clock period of the reference clock (FCLK, usually 48 MHz or 192MHz).

Table 7-39 Switching Characteristics Over Recommended Operating Conditions for UART

NO.	PARAMETER	DESCRIPTION		MIN	MAX	UNIT
	f_(baud)	Maximum programmable baud rate	15 pF		12	MHz
			30 pF		0.23
			100 pF		0.115
2	t_w(TX)	Pulse width, transmit data bit, 15/30/100 pF high or low		U - 2^⁽¹⁾	U + 2^⁽¹⁾	ns
3	t_w(RTS)	Pulse width, transmit start bit, 15/30/100 pF high or low		U - 2^⁽¹⁾	U + 2^⁽¹⁾	ns

U = UART baud time = 1/programmed baud rate

Figure 7-32 UART Timing

7.16 Multichannel Serial Peripheral Interface (McSPI)

The McSPI is a master/slave synchronous serial bus. There are four separate McSPI modules (SPI1, SPI2, SPI3, and SPI4) in the device. All these four modules support up to four external devices (four chip selects) and are able to work as both master and slave.

The McSPI modules include the following main features:

Serial clock with programmable frequency, polarity, and phase for each channel
Wide selection of SPI word lengths, ranging from 4 to 32 bits
Up to four master channels, or single channel in slave mode
Master multichannel mode:
- Full duplex/half duplex
- Transmit-only/receive-only/transmit-and-receive modes
- Flexible input/output (I/O) port controls per channel
- Programmable clock granularity
- SPI configuration per channel. This means, clock definition, polarity enabling and word width
Power management through wake-up capabilities
Programmable timing control between chip select and external clock generation
Built-in FIFO available for a single channel.
Each SPI module supports multiple chip select pins spim_cs[i], where i = 1 to 4.

NOTE

For more information, see the Serial Communication Interface section of the device TRM.

NOTE

The McSPIm module (m = 1 to 4) is also referred to as SPIm.

CAUTION

The I/O timings provided in this section are applicable for all combinations of signals for SPI1 and SPI2. However, the timings are valid only for SPI3 and SPI4 if signals within a single IOSET are used. The IOSETS are defined in Table 7-42.

Table 7-40, Figure 7-33 and Figure 7-34 present Timing Requirements for McSPI - Master Mode.

Table 7-40 Timing Requirements for SPI - Master Mode ^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	MODE	MIN	MAX	UNIT
SM1	t_c(SPICLK)	Cycle time, spi_sclk ^{⁽¹⁾ ⁽²⁾}	SPI1/2/3/4	20.8 ^⁽³⁾		ns
SM2	t_w(SPICLKL)	Typical Pulse duration, spi_sclk low ^⁽¹⁾		0.5*P-1 ^⁽⁴⁾		ns
SM3	t_w(SPICLKH)	Typical Pulse duration, spi_sclk high ^⁽¹⁾		0.5*P-1 ^⁽⁴⁾		ns
SM4	t_{su(MISO-SPICLK)}	Setup time, spi_d[x] valid before spi_sclk active edge ^⁽¹⁾		3.5		ns
SM5	t_{h(SPICLK-MISO)}	Hold time, spi_d[x] valid after spi_sclk active edge ^⁽¹⁾		3.7		ns
SM6	t_{d(SPICLK-SIMO)}	Delay time, spi_sclk active edge to spi_d[x] transition ^⁽¹⁾	SPI1	-3.57	4.1	ns
			SPI2	-3.9	3.6	ns
			SPI3	-4.9	4.7
			SPI4	-4.3	4.5
SM7	t_d(CS-SIMO)	Delay time, spi_cs[x] active edge to spi_d[x] transition			5	ns
SM8	t_d(CS-SPICLK)	Delay time, spi_cs[x] active to spi_sclk first edge ^⁽¹⁾	MASTER_PHA0 ^⁽⁵⁾	B-4.2 ^⁽⁶⁾		ns
SM8	t_d(CS-SPICLK)	Delay time, spi_cs[x] active to spi_sclk first edge ^⁽¹⁾	MASTER_PHA1 ^⁽⁵⁾	A-4.2 ^⁽⁷⁾		ns
SM9	t_d(SPICLK-CS)	Delay time, spi_sclk last edge to spi_cs[x] inactive ^⁽¹⁾	MASTER_PHA0 ^⁽⁵⁾	A-4.2 ^⁽⁷⁾		ns
SM9	t_d(SPICLK-CS)	Delay time, spi_sclk last edge to spi_cs[x] inactive ^⁽¹⁾	MASTER_PHA1 ^⁽⁵⁾	B-4.2 ^⁽⁶⁾		ns

This timing applies to all configurations regardless of SPI_CLK polarity and which clock edges are used to drive output data and capture input data.
Related to the SPI_CLK maximum frequency.
20.8ns cycle time = 48MHz
P = SPICLK period.
SPI_CLK phase is programmable with the PHA bit of the SPI_CH(i)CONF register.
B = (TCS + 0.5) * TSPICLKREF * Fratio, where TCS is a bit field of the SPI_CH(i)CONF register and Fratio = Even ≥2.
When P = 20.8 ns, A = (TCS + 1) * TSPICLKREF, where TCS is a bit field of the SPI_CH(i)CONF register. When P > 20.8 ns, A = (TCS + 0.5) * Fratio * TSPICLKREF, where TCS is a bit field of the SPI_CH(i)CONF register.

AM5718-HIREL SPRS906_TIMING_McSPI_01.gif

Figure 7-33 McSPI - Master Mode Transmit

AM5718-HIREL SPRS906_TIMING_McSPI_02.gif

Figure 7-34 McSPI - Master Mode Receive

Table 7-41, Figure 7-35 and Figure 7-36 present Timing Requirements for McSPI - Slave Mode.

Table 7-41 Timing Requirements for SPI - Slave Mode

NO.	PARAMETER	DESCRIPTION	MODE	MIN	MAX	UNIT
SS1 ^⁽¹⁾	t_c(SPICLK)	Cycle time, spi_sclk		62.5 ^⁽²⁾ ^⁽³⁾		ns
SS2 ^⁽¹⁾	t_w(SPICLKL)	Typical Pulse duration, spi_sclk low		0.45*P ^⁽⁴⁾		ns
SS3 ^⁽¹⁾	t_w(SPICLKH)	Typical Pulse duration, spi_sclk high		0.45*P ^⁽⁴⁾		ns
SS4 ^⁽¹⁾	t_{su(SIMO-SPICLK)}	Setup time, spi_d[x] valid before spi_sclk active edge		5		ns
SS5 ^⁽¹⁾	t_{h(SPICLK-SIMO)}	Hold time, spi_d[x] valid after spi_sclk active edge		5		ns
SS6 ^⁽¹⁾	t_{d(SPICLK-SOMI)}	Delay time, spi_sclk active edge to mcspi_somi transition	SPI1/2/3	2	26.6	ns
SS6 ^⁽¹⁾	t_{d(SPICLK-SOMI)}	Delay time, spi_sclk active edge to mcspi_somi transition	SPI4	2	20.1	ns
SS7 ^⁽⁵⁾	t_d(CS-SOMI)	Delay time, spi_cs[x] active edge to mcspi_somi transition			20.95	ns
SS8 ^⁽¹⁾	t_{su(CS-SPICLK)}	Setup time, spi_cs[x] valid before spi_sclk first edge		5		ns
SS9 ^⁽¹⁾	t_h(SPICLK-CS)	Hold time, spi_cs[x] valid after spi_sclk last edge	SPI1/2	5		ns
			SPI3	7.5		ns
			SPI4	6		ns

This timing applies to all configurations regardless of SPI_CLK polarity and which clock edges are used to drive output data and capture input data.
When operating the SPI interface in RX-only mode, the minimum Cycle time is 26ns (38.4MHz)
62.5ns Cycle time = 16 MHz
P = SPICLK period.
PHA = 0; SPI_CLK phase is programmable with the PHA bit of the SPI_CH(i)CONF register.

AM5718-HIREL SPRS906_TIMING_McSPI_03.gif

Figure 7-35 McSPI - Slave Mode Transmit

AM5718-HIREL SPRS906_TIMING_McSPI_04.gif

Figure 7-36 McSPI - Slave Mode Receive

In Table 7-42 are presented the specific groupings of signals (IOSET) for use with SPI3 and SPI4.

Table 7-42 McSPI3/4 IOSETs

SIGNALS	IOSET1		IOSET2		IOSET3		IOSET4		IOSET5
SIGNALS	BALL	MUX	BALL	MUX	BALL	MUX	BALL	MUX	BALL	MUX
McSPI3
spi3_cs0	D11	8	V9	7	A12	3	D17	2	AC9	1
spi3_cs1	B11	8	AC3	1	E14	3	B11	8	AC3	1
spi3_cs2	F11	8			F11	8	F11	8
spi3_cs3	A10	8			A10	8	A10	8
spi3_d0	C11	8	W9	7	B13	3	G16	2	AC6	1
spi3_d1	B10	8	Y1	7	A11	3	A21	2	AC7	1
spi3_sclk	E11	8	V2	7	B12	3	C18	2	AC4	1
McSPI4
spi4_cs0	P9	8	F3	8	U6	7	AA4	2	AB5	1
spi4_cs1	P4	8	P4	8	Y1	8	Y1	8	Y1	8
spi4_cs2	R3	8	R3	8	W9	8	W9	8	W9	8
spi4_cs3	T2	8	T2	8	V9	8	V9	8	V9	8
spi4_d0	N9	8	F2	8	V6	7	AB3	2	AB8	1
spi4_d1	R4	8	G6	8	U7	7	AB9	2	AD6	1
spi4_sclk	N7	8	G1	8	V7	7	AA3	2	AC8	1

7.17 Quad Serial Peripheral Interface (QSPI)

The Quad SPI (QSPI) module is a type of SPI module that allows single, dual or quad read access to external SPI devices. This module has a memory mapped register interface, which provides a direct interface for accessing data from external SPI devices and thus simplifying software requirements. It works as a master only. There is one QSPI module in the device and it is primary intended for fast booting from quad-SPI flash memories.

General SPI features:

Programmable clock divider
Six pin interface (DCLK, CS_N, DOUT, DIN, QDIN1, QDIN2)
4 external chip select signals
Support for 3-, 4- or 6-pin SPI interface
Programmable CS_N to DOUT delay from 0 to 3 DCLKs
Programmable signal polarities
Programmable active clock edge
Software controllable interface allowing for any type of SPI transfer

NOTE

For more information, see the Quad Serial Peripheral Interface section of the Device TRM.

CAUTION

The IO Timings provided in this section are only valid when all QSPI Chip Selects used in a system are configured to use the same Clock Mode (either Clock Mode 0 or Clock Mode 3).

CAUTION

The I/O Timings provided in this section are valid only for some QSPI usage modes when the corresponding Virtual I/O Timings or Manual I/O Timings are configured as described in the tables found in this section.

Table 7-43 and Table 7-44 Present Timing and Switching Characteristics for Quad SPI Interface.

Table 7-43 Switching Characteristics for QSPI

NO.	PARAMETER	DESCRIPTION	MODE	MIN	MAX	UNIT
Q1	t_c(SCLK)	Cycle time, sclk	Default Timing Mode, Clock Mode 0	11.71		ns
Q1	t_c(SCLK)	Cycle time, sclk	Default Timing Mode, Clock Mode 3	20.8		ns
Q2	t_w(SCLKL)	Pulse duration, sclk low		Y*P-1 ^⁽¹⁾		ns
Q3	t_w(SCLKH)	Pulse duration, sclk high		Y*P-1 ^⁽¹⁾		ns
Q4	t_d(CS-SCLK)	Delay time, sclk falling edge to cs active edge, CS3:0	Default Timing Mode	-M*P-1.6 ^{⁽²⁾ ⁽³⁾}	-M*P+2.6 ^{⁽²⁾ ⁽³⁾}	ns
Q5	t_d(SCLK-CS)	Delay time, sclk falling edge to cs inactive edge, CS3:0	Default Timing Mode	N*P-1.6 ^{⁽²⁾ ⁽³⁾}	N*P+2.6 ^{⁽²⁾ ⁽³⁾}	ns
Q6	t_d(SCLK-D0)	Delay time, sclk falling edge to d[0] transition	Default Timing Mode	-1.6	2.6	ns
Q7	t_ena(CS-D0LZ)	Enable time, cs active edge to d[0] driven (lo-z)		-P-3.5	-P+2.5	ns
Q8	t_dis(CS-D0Z)	Disable time, cs active edge to d[0] tri-stated (hi-z)		-P-2.5	-P+2.0	ns
Q9	t_d(SCLK-D0)	Delay time, sclk first falling edge to first d[0] transition	PHA=0 Only, Default Timing Mode	-1.6	2.6	ns

The Y parameter is defined as follows:
If DCLK_DIV is 0 or ODD then, Y equals 0.5.
If DCLK_DIV is EVEN then, Y equals (DCLK_DIV/2) / (DCLK_DIV+1).
For best performance, it is recommended to use a DCLK_DIV of 0 or ODD to minimize the duty cycle distortion. The HSDIVIDER on CLKOUTX2_H13 output of DPLL_PER can be used to achieve the desired clock divider ratio. All required details about clock division factor DCLK_DIV can be found in the device-specific Technical Reference Manual.
P = SCLK period.
M=QSPI_SPI_DC_REG.DDx + 1 when Clock Mode 0.
M=QSPI_SPI_DC_REG.DDx when Clock Mode 3.
N = 2 when Clock Mode 0.
N = 3 when Clock Mode 3.

AM5718-HIREL SPRS906_TIMING_QSPI1_01.gif

Figure 7-37 QSPI Read (Clock Mode 3)

AM5718-HIREL SPRS906_TIMING_QSPI1_02.gif

Figure 7-38 QSPI Read (Clock Mode 0)

CAUTION

Table 7-44 Timing Requirements for QSPI^⁽³⁾^⁽²⁾

NO.	PARAMETER	DESCRIPTION	MODE	MIN	UNIT
Q2	t_su(D-RTCLK)	Setup time, d[3:0] valid before falling rtclk edge	Default Timing Mode, Clock Mode 0	4.6	ns
Q2	t_su(D-SCLK)	Setup time, d[3:0] valid before falling sclk edge	Default Timing Mode, Clock Mode 3	12.3	ns
Q13	t_h(RTCLK-D)	Hold time, d[3:0] valid after falling rtclk edge	Default Timing Mode, Clock Mode 0	-0.1	ns
Q13	t_h(SCLK-D)	Hold time, d[3:0] valid after falling sclk edge	Default Timing Mode, Clock Mode 3	0.1	ns
Q14	t_su(D-SCLK)	Setup time, final d[3:0] bit valid before final falling sclk edge	Default Timing Mode, Clock Mode 3	12.3-P ^⁽¹⁾	ns
Q15	t_h(SCLK-D)	Hold time, final d[3:0] bit valid after final falling sclk edge	Default Timing Mode, Clock Mode 3	0.1+P ^⁽¹⁾	ns

P = SCLK period.
Clock Modes 1 and 2 are not supported.
The Device captures data on the falling clock edge in Clock Mode 0 and 3, as opposed to the traditional rising clock edge. Although non-standard, the falling-edge-based setup and hold time timings have been designed to be compatible with standard SPI devices that launch data on the falling edge in Clock Modes 0 and 3.

AM5718-HIREL SPRS906_TIMING_QSPI1_03.gif

Figure 7-39 QSPI Write (Clock Mode 3)

AM5718-HIREL SPRS906_TIMING_QSPI1_04.gif

Figure 7-40 QSPI Write (Clock Mode 0)

CAUTION

NOTE

To configure the desired Manual IO Timing Mode the user must follow the steps described in section Manual IO Timing Modes of the Device TRM.

The associated registers to configure are listed in the CFG REGISTER column. For more information see the Control Module chapter in the Device TRM.

Manual IO Timings Modes must be used to guaranteed some IO timings for QSPI. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-45 Manual Functions Mapping for QSPI for a definition of the Manual modes.

Table 7-45 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-45 Manual Functions Mapping for QSPI

BALL	BALL NAME	QSPI1_MANUAL1		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	1
T7	gpmc_a3	0	0	CFG_GPMC_A3_OUT	qspi1_cs2
P6	gpmc_a4	0	0	CFG_GPMC_A4_OUT	qspi1_cs3
R3	gpmc_a13	0	0	CFG_GPMC_A13_IN	qspi1_rtclk
T2	gpmc_a14	2247	1186	CFG_GPMC_A14_IN	qspi1_d3
U2	gpmc_a15	2176	1197	CFG_GPMC_A15_IN	qspi1_d2
U1	gpmc_a16	2229	1268	CFG_GPMC_A16_IN	qspi1_d0
U1	gpmc_a16	0	0	CFG_GPMC_A16_OUT	qspi1_d0
P3	gpmc_a17	2251	1217	CFG_GPMC_A17_IN	qspi1_d1
R2	gpmc_a18	0	0	CFG_GPMC_A18_OUT	qspi1_sclk
P2	gpmc_cs2	0	0	CFG_GPMC_CS2_OUT	qspi1_cs0
P1	gpmc_cs3	0	0	CFG_GPMC_CS3_OUT	qspi1_cs1

7.18 Multichannel Audio Serial Port (McASP)

The multichannel audio serial port (McASP) functions as a general-purpose audio serial port optimized for the needs of multichannel audio applications. The McASP is useful for time-division multiplexed (TDM) stream, Inter-Integrated Sound (I2S) protocols, and intercomponent digital audio interface transmission (DIT).

The device have integrated 8 McASP modules (McASP1-McASP8) with:

McASP1 and McASP2 modules supporting 16 channels with independent TX/RX clock/sync domain

McASP3 through McASP8 modules supporting 4 channels with independent TX/RX clock/sync domain

The McASP1 is instantiated in IPU power domain

McASP2 through McASP8 are part of the L4_PER2 peripheral power domain

NOTE

For more information, see the Serial Communication Interface section of the Device TRM.

CAUTION

The I/O Timings provided in this section are valid only for some McASP usage modes when the corresponding Virtual I/O Timings or Manual I/O Timings are configured as described in the tables found in this section.

Table 7-46, Table 7-47, Table 7-48 and Figure 7-41 present Timing Requirements for McASP1 to McASP8.

Table 7-46 Timing Requirements for McASP1^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	MODE	MIN	UNIT
1	t_c(AHCLKRX)	Cycle time, AHCLKR/X		20	ns
2	t_w(AHCLKRX)	Pulse duration, AHCLKR/X high or low		0.35P ^⁽²⁾	ns
3	t_c(ACLKRX)	Cycle time, ACLKR/X		20	ns
4	t_w(ACLKRX)	Pulse duration, ACLKR/X high or low		0.5R – 3 ^⁽³⁾	ns
5	t_{su(AFSRX-ACLK)}	Setup time, AFSR/X input valid before ACLKR/X	ACLKR/X int	20.5	ns
5	t_{su(AFSRX-ACLK)}	Setup time, AFSR/X input valid before ACLKR/X	ACLKR/X ext in ACLKR/X ext out	4	ns
6	t_{h(ACLK-AFSRX)}	Hold time, AFSR/X input valid after ACLKR/X	ACLKR/X int	–1	ns
6	t_{h(ACLK-AFSRX)}	Hold time, AFSR/X input valid after ACLKR/X	ACLKR/X ext in ACLKR/X ext out	1.7	ns
7	t_su(AXR-ACLK)	Setup time, AXR input valid before ACLKR/X	ACLKR/X int	21.6	ns
7	t_su(AXR-ACLK)	Setup time, AXR input valid before ACLKR/X	ACLKR/X ext in ACLKR/X ext out	11.5	ns
8	t_h(ACLK-AXR)	Hold time, AXR input valid after ACLKR/X	ACLKR/X int	–1	ns
8	t_h(ACLK-AXR)	Hold time, AXR input valid after ACLKR/X	ACLKR/X ext in ACLKR/X ext out	2.34	ns

ACLKR internal: ACLKRCTL.CLKRM=1, PDIR.ACLKR = 1
ACLKR external input: ACLKRCTL.CLKRM=0, PDIR.ACLKR=0
ACLKR external output: ACLKRCTL.CLKRM=0, PDIR.ACLKR=1
ACLKX internal: ACLKXCTL.CLKXM=1, PDIR.ACLKX = 1
ACLKX external input: ACLKXCTL.CLKXM=0, PDIR.ACLKX=0
ACLKX external output: ACLKXCTL.CLKXM=0, PDIR.ACLKX=1
P = AHCLKR/X period in ns.
R = ACLKR/X period in ns.

Table 7-47 Timing Requirements for McASP2^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	MODE	MIN	UNIT
1	t_c(AHCLKRX)	Cycle time, AHCLKR/X		20	ns
2	t_w(AHCLKRX)	Pulse duration, AHCLKR/X high or low		0.35P ^⁽²⁾	ns
3	t_c(ACLKRX)	Cycle time, ACLKR/X	Any Other Conditions	20	ns
3	t_c(ACLKRX)	Cycle time, ACLKR/X	ACLKX/AFSX (In Sync Mode), ACLKR/AFSR (In Async Mode), and AXR are all inputs "80M" Virtual IO Timing Modes	12.5	ns
4	t_w(ACLKRX)	Pulse duration, ACLKR/X high or low	Any Other Conditions	0.5R – 3 ^⁽³⁾	ns
4	t_w(ACLKRX)	Pulse duration, ACLKR/X high or low	ACLKX/AFSX (In Sync Mode), ACLKR/AFSR (In Async Mode), and AXR are all inputs "80M" Virtual IO Timing Modes	0.38R ^⁽³⁾	ns
5	t_{su(AFSRX-ACLK)}	Setup time, AFSR/X input valid before ACLKR/X	ACLKR/X int	20.3	ns
			ACLKR/X ext in ACLKR/X ext out	4.5	ns
			ACLKR/X ext in ACLKR/X ext out "80M" Virtual IO Timing Modes	3	ns
6	t_{h(ACLK-AFSRX)}	Hold time, AFSR/X input valid after ACLKR/X	ACLKR/X int	–1	ns
			ACLKR/X ext in ACLKR/X ext out	1.8	ns
			ACLKR/X ext in ACLKR/X ext out "80M" Virtual IO Timing Modes	3	ns
7	t_su(AXR-ACLK)	Setup time, AXR input valid before ACLKR/X	ACLKR/X int	21.1	ns
			ACLKR/X ext in ACLKR/X ext out	4.5	ns
			ACLKR/X ext in ACLKR/X ext out "80M" Virtual IO Timing Modes	3	ns
8	t_h(ACLK-AXR)	Hold time, AXR input valid after ACLKR/X	ACLKR/X int	–1	ns
			ACLKR/X ext in ACLKR/X ext out	1.8	ns
			ACLKR/X ext in ACLKR/X ext out "80M" Virtual IO Timing Modes	3	ns

ACLKR internal: ACLKRCTL.CLKRM=1, PDIR.ACLKR = 1
ACLKR external input: ACLKRCTL.CLKRM=0, PDIR.ACLKR=0
ACLKR external output: ACLKRCTL.CLKRM=0, PDIR.ACLKR=1
ACLKX internal: ACLKXCTL.CLKXM=1, PDIR.ACLKX = 1
ACLKX external input: ACLKXCTL.CLKXM=0, PDIR.ACLKX=0
ACLKX external output: ACLKXCTL.CLKXM=0, PDIR.ACLKX=1
P = AHCLKR/X period in ns.
R = ACLKR/X period in ns.

Table 7-48 Timing Requirements for McASP3/4/5/6/7/8^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	MODE	MIN	UNIT
1	t_c(AHCLKRX)	Cycle time, AHCLKR/X		20	ns
2	t_w(AHCLKRX)	Pulse duration, AHCLKR/X high or low		0.35P ^⁽²⁾	ns
3	t_c(ACLKRX)	Cycle time, ACLKR/X		20	ns
4	t_w(ACLKRX)	Pulse duration, ACLKR/X high or low		0.5R – 3 ^⁽³⁾	ns
5	t_{su(AFSRX-ACLK)}	Setup time, AFSR/X input valid before ACLKR/X	ACLKR/X int	19.7	ns
5	t_{su(AFSRX-ACLK)}	Setup time, AFSR/X input valid before ACLKR/X	ACLKR/X ext in ACLKR/X ext out	5.6	ns
6	t_{h(ACLK-AFSRX)}	Hold time, AFSR/X input valid after ACLKR/X	ACLKR/X int	–1.1	ns
	t_{h(ACLK-AFSRX)}	Hold time, AFSR/X input valid after ACLKR/X	ACLKR/X ext in ACLKR/X ext out	3.33	ns
	t_su(AXR-ACLK)	Setup time, AXR input valid before ACLKX	ACLKX int (ASYNC=0)	20.3	ns
	t_su(AXR-ACLK)	Setup time, AXR input valid before ACLKX	ACLKR/X ext in ACLKR/X ext out	5.1	ns
8	t_h(ACLK-AXR)	Hold time, AXR input valid after ACLKX	ACLKX int (ASYNC=0)	–0.8	ns
8	t_h(ACLK-AXR)	Hold time, AXR input valid after ACLKX	ACLKR/X ext in ACLKR/X ext out	3.33	ns

ACLKR internal: ACLKRCTL.CLKRM = 1, PDIR.ACLKR = 1 (NOT SUPPORTED)
ACLKR external input: ACLKRCTL.CLKRM = 0, PDIR.ACLKR = 0
ACLKR external output: ACLKRCTL.CLKRM = 0, PDIR.ACLKR = 1
ACLKX internal: ACLKXCTL.CLKXM = 1, PDIR.ACLKX = 1
ACLKX external input: ACLKXCTL.CLKXM = 0, PDIR.ACLKX = 0
ACLKX external output: ACLKXCTL.CLKXM = 0, PDIR.ACLKX = 1
P = AHCLKR/X period in ns.
R = ACLKR/X period in ns.

AM5718-HIREL SPRS906_TIMING_McASP_01.gif

A. For CLKRP = CLKXP = 0, the McASP transmitter is configured for rising edge (to shift data out) and the McASP receiver is configured for falling edge (to shift data in).

B. For CLKRP = CLKXP = 1, the McASP transmitter is configured for falling edge (to shift data out) and the McASP receiver is configured for rising edge (to shift data in).

Figure 7-41 McASP Input Timing

Table 7-49, Table 7-50, Table 7-51 and Figure 7-42 present Switching Characteristics Over Recommended Operating Conditions for McASP1 to McASP8.

Table 7-49 Switching Characteristics Over Recommended Operating Conditions for McASP1^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	MODE	MIN	MAX	UNIT
9	t_c(AHCLKRX)	Cycle time, AHCLKR/X		20		ns
10	t_w(AHCLKRX)	Pulse duration, AHCLKR/X high or low		0.5P - 2.5 ^⁽²⁾		ns
11	t_c(ACLKRX)	Cycle time, ACLKR/X		20		ns
12	t_w(ACLKRX)	Pulse duration, ACLKR/X high or low		0.5P - 2.5 ^⁽³⁾		ns
13	t_{d(ACLK-AFSXR)}	Delay time, ACLKR/X transmit edge to AFSX/R output valid	ACLKR/X int	-0.9	6	ns
13	t_{d(ACLK-AFSXR)}	Delay time, ACLKR/X transmit edge to AFSX/R output valid	ACLKR/X ext in ACLKR/X ext out	2	23.1	ns
14	t_d(ACLK-AXR)	Delay time, ACLKR/X transmit edge to AXR output valid	ACLKR/X int	-1.4	6	ns
14	t_d(ACLK-AXR)	Delay time, ACLKR/X transmit edge to AXR output valid	ACLKR/X ext in ACLKR/X ext out	2	24.2	ns

ACLKR internal: ACLKRCTL.CLKRM=1, PDIR.ACLKR = 1
ACLKR external input: ACLKRCTL.CLKRM=0, PDIR.ACLKR=0
ACLKR external output: ACLKRCTL.CLKRM=0, PDIR.ACLKR=1
ACLKX internal: ACLKXCTL.CLKXM=1, PDIR.ACLKX = 1
ACLKX external input: ACLKXCTL.CLKXM=0, PDIR.ACLKX=0
ACLKX external output: ACLKXCTL.CLKXM=0, PDIR.ACLKX=1
P = AHCLKR/X period in ns.
R = ACLKR/X period in ns.

Table 7-50 Switching Characteristics Over Recommended Operating Conditions for McASP2 ^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	MODE	MIN	MAX	UNIT
9	t_c(AHCLKRX)	Cycle time, AHCLKR/X		20		ns
10	t_w(AHCLKRX)	Pulse duration, AHCLKR/X high or low		0.5P - 2.5 ^⁽²⁾		ns
11	t_c(ACLKRX)	Cycle time, ACLKR/X		20		ns
12	t_w(ACLKRX)	Pulse duration, ACLKR/X high or low		0.5P - 2.5 ^⁽³⁾		ns
13	t_{d(ACLK-AFSXR)}	Delay time, ACLKR/X transmit edge to AFSX/R output valid	ACLKR/X int	-1	6	ns
13	t_{d(ACLK-AFSXR)}	Delay time, ACLKR/X transmit edge to AFSX/R output valid	ACLKR/X ext in ACLKR/X ext out	2	23.2	ns
14	t_d(ACLK-AXR)	Delay time, ACLKR/X transmit edge to AXR output valid	ACLKR/X int	-1.3	6	ns
14	t_d(ACLK-AXR)	Delay time, ACLKR/X transmit edge to AXR output valid	ACLKR/X ext in ACLKR/X ext out	2	23.7	ns

ACLKR internal: ACLKRCTL.CLKRM=1, PDIR.ACLKR = 1
ACLKR external input: ACLKRCTL.CLKRM=0, PDIR.ACLKR=0
ACLKR external output: ACLKRCTL.CLKRM=0, PDIR.ACLKR=1
ACLKX internal: ACLKXCTL.CLKXM=1, PDIR.ACLKX = 1
ACLKX external input: ACLKXCTL.CLKXM=0, PDIR.ACLKX=0
ACLKX external output: ACLKXCTL.CLKXM=0, PDIR.ACLKX=1
P = AHCLKR/X period in ns.
R = ACLKR/X period in ns.

Table 7-51 Switching Characteristics Over Recommended Operating Conditions for McASP3/4/5/6/7/8^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	MODE	MIN	MAX	UNIT
9	t_c(AHCLKRX)	Cycle time, AHCLKR/X		20		ns
10	t_w(AHCLKRX)	Pulse duration, AHCLKR/X high or low		0.5P - 2.5 ^⁽²⁾		ns
11	t_c(ACLKRX)	Cycle time, ACLKR/X		20		ns
12	t_w(ACLKRX)	Pulse duration, ACLKR/X high or low		0.5P - 2.5 ^⁽³⁾		ns
13	t_{d(ACLK-AFSXR)}	Delay time, ACLKR/X transmit edge to AFSX/R output valid	ACLKR/X int	-0.5	6	ns
13	t_{d(ACLK-AFSXR)}	Delay time, ACLKR/X transmit edge to AFSX/R output valid	ACLKR/X ext in ACLKR/X ext out	1.9	24.5	ns
14	t_d(ACLK-AXR)	Delay time, ACLKR/X transmit edge to AXR output valid	ACLKR/X int	-1.4	7.1	ns
14	t_d(ACLK-AXR)	Delay time, ACLKR/X transmit edge to AXR output valid	ACLKR/X ext in ACLKR/X ext out	1.1	24.2	ns

ACLKR internal: ACLKRCTL.CLKRM=1, PDIR.ACLKR = 1
ACLKR external input: ACLKRCTL.CLKRM=0, PDIR.ACLKR=0
ACLKR external output: ACLKRCTL.CLKRM=0, PDIR.ACLKR=1
ACLKX internal: ACLKXCTL.CLKXM=1, PDIR.ACLKX = 1
ACLKX external input: ACLKXCTL.CLKXM=0, PDIR.ACLKX=0
ACLKX external output: ACLKXCTL.CLKXM=0, PDIR.ACLKX=1
P = AHCLKR/X period in ns.
R = ACLKR/X period in ns.

AM5718-HIREL SPRS906_TIMING_McASP_02.gif

A. For CLKRP = CLKXP = 1, the McASP transmitter is configured for falling edge (to shift data out) and the McASP receiver is configured for rising edge (to shift data in).

B. For CLKRP = CLKXP = 0, the McASP transmitter is configured for rising edge (to shift data out) and the McASP receiver is configured for falling edge (to shift data in).

Figure 7-42 McASP Output Timing^AB

Table 7-52 through Table 7-59 explain all cases with Virtual Mode Details for McASP1/2/3/4/5/6/7/8 (see Figure 7-43 through Figure 7-50).

Table 7-52 Virtual Mode Case Details for McASP1

No.	CASE	CASE Description	Virtual Mode Settings		Notes
No.	CASE	CASE Description	Signals	Virtual Mode Value	Notes
IP Mode : ASYNC
1	COIFOI	CLKX / FSX: Output CLKR / FSR: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-43
1	COIFOI	CLKX / FSX: Output CLKR / FSR: Input	AXR(Inputs)/CLKR/FSR	MCASP1_VIRTUAL2_ASYNC_RX	See Figure 7-43
2	COIFIO	CLKX / FSR: Output CLKR / FSX: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-44
2	COIFIO	CLKX / FSR: Output CLKR / FSX: Input	AXR(Inputs)/CLKR/FSR	MCASP1_VIRTUAL2_ASYNC_RX	See Figure 7-44
3	CIOFIO	CLKR / FSR: Output CLKX / FSX: Input	AXR(Outputs)/CLKX/FSX	MCASP1_VIRTUAL2_ASYNC_RX	See Figure 7-45
3	CIOFIO	CLKR / FSR: Output CLKX / FSX: Input	AXR(Inputs)/CLKR/FSR	Default (No Virtual Mode)	See Figure 7-45
4	CIOFOI	CLKR / FSX: Output CLKX / FSR: Input	AXR(Outputs)/CLKX/FSX	MCASP1_VIRTUAL2_ASYNC_RX	See Figure 7-46
4	CIOFOI	CLKR / FSX: Output CLKX / FSR: Input	AXR(Inputs)/CLKR/FSR	Default (No Virtual Mode)	See Figure 7-46
IP Mode : SYNC (CLKR / FSR internally generated from CLKX / FSX)
5	CO-FO-	CLKX / FSX: Output	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-47
5	CO-FO-	CLKX / FSX: Output	AXR(Inputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-47
6	CI-FO-	FSX: Output CLKX: Input	AXR(Outputs)/CLKX/FSX	MCASP1_VIRTUAL1_SYNC_RX	See Figure 7-48
6	CI-FO-	FSX: Output CLKX: Input	AXR(Inputs)/CLKX/FSX	MCASP1_VIRTUAL1_SYNC_RX	See Figure 7-48
7	CI-FI-	CLKX / FSX: Input	AXR(Outputs)/CLKX/FSX	MCASP1_VIRTUAL1_SYNC_RX	See Figure 7-49
7	CI-FI-	CLKX / FSX: Input	AXR(Inputs)/CLKX/FSX	MCASP1_VIRTUAL1_SYNC_RX	See Figure 7-49
8	CO-FI-	CLKX: Output FSX: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-50
8	CO-FI-	CLKX: Output FSX: Input	AXR(Inputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-50

Table 7-53 Virtual Mode Case Details for McASP2

No.	CASE	CASE Description	Virtual Mode Settings		Notes
No.	CASE	CASE Description	Signals	Virtual Mode Value	Notes
IP Mode : ASYNC
1	COIFOI	CLKX / FSX: Output CLKR / FSR: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)^⁽¹⁾	See Figure 7-43
			AXR(Inputs)/CLKR/FSR	Default (No Virtual Mode)^⁽¹⁾
			AXR(Inputs)/CLKR/FSR	MCASP2_VIRTUAL4_ASYNC_RX_80M ^⁽²⁾
2	COIFIO	CLKX / FSR: Output CLKR / FSX: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-44
2	COIFIO	CLKX / FSR: Output CLKR / FSX: Input	AXR(Inputs)/CLKR/FSR	MCASP2_VIRTUAL2_ASYNC_RX	See Figure 7-44
3	CIOFIO	CLKR / FSR: Output CLKX / FSX: Input	AXR(Outputs)/CLKX/FSX	MCASP2_VIRTUAL2_ASYNC_RX	See Figure 7-45
3	CIOFIO	CLKR / FSR: Output CLKX / FSX: Input	AXR(Inputs)/CLKR/FSR	Default (No Virtual Mode)	See Figure 7-45
4	CIOFOI	CLKR / FSX: Output CLKX / FSR: Input	AXR(Outputs)/CLKX/FSX	MCASP2_VIRTUAL2_ASYNC_RX	See Figure 7-46
4	CIOFOI	CLKR / FSX: Output CLKX / FSR: Input	AXR(Inputs)/CLKR/FSR	Default (No Virtual Mode)	See Figure 7-46
IP Mode : SYNC (CLKR / FSR internally generated from CLKX / FSX)
5	CO-FO-	CLKX / FSX: Output	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-47
5	CO-FO-	CLKX / FSX: Output	AXR(Inputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-47
6	CI-FO-	FSX: Output CLKX: Input	AXR(Outputs)/CLKX/FSX	MCASP2_VIRTUAL3_SYNC_RX	See Figure 7-48
6	CI-FO-	FSX: Output CLKX: Input	AXR(Inputs)/CLKX/FSX	MCASP2_VIRTUAL3_SYNC_RX	See Figure 7-48
7	CI-FI-	CLKX / FSX: Input	AXR(Outputs)/CLKX/FSX	MCASP2_VIRTUAL3_SYNC_RX^⁽¹⁾	See Figure 7-49
			AXR(Inputs)/CLKX/FSX	MCASP2_VIRTUAL3_SYNC_RX^⁽¹⁾
			AXR(Inputs)/CLKX/FSX	MCASP2_VIRTUAL1_SYNC_RX_80M^⁽²⁾
8	CO-FI-	CLKX: Output FSX: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-50
8	CO-FI-	CLKX: Output FSX: Input	AXR(Inputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-50

Used up to 50MHz. Should also be used in a CI-FI- mixed case where AXR operate as both inputs and outputs (that is, AXR are bidirectional).
Used in 80MHz input only mode when AXR, CLKX and FSX are all inputs.

Table 7-54 Virtual Mode Case Details for McASP3

No.	CASE	CASE Description	Virtual Mode Settings		Notes
No.	CASE	CASE Description	Signals	Virtual Mode Value	Notes
IP Mode : ASYNC
1	COIFOI	CLKX / FSX: Output CLKR / FSR: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-43
1	COIFOI	CLKX / FSX: Output CLKR / FSR: Input	AXR(Inputs)/CLKR/FSR	MCASP3_VIRTUAL2_SYNC_RX	See Figure 7-43
2	COIFIO	CLKX / FSR: Output CLKR / FSX: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-44
2	COIFIO	CLKX / FSR: Output CLKR / FSX: Input	AXR(Inputs)/CLKR/FSR	MCASP3_VIRTUAL2_SYNC_RX	See Figure 7-44
3	CIOFIO	CLKR / FSR: Output CLKX / FSX: Input	AXR(Outputs)/CLKX/FSX	MCASP3_VIRTUAL2_SYNC_RX	See Figure 7-45
3	CIOFIO	CLKR / FSR: Output CLKX / FSX: Input	AXR(Inputs)/CLKR/FSR	MCASP3_VIRTUAL2_SYNC_RX	See Figure 7-45
4	CIOFOI	CLKR / FSX: Output CLKX / FSR: Input	AXR(Outputs)/CLKX/FSX	MCASP3_VIRTUAL2_SYNC_RX	See Figure 7-46
4	CIOFOI	CLKR / FSX: Output CLKX / FSR: Input	AXR(Inputs)/CLKR/FSR	MCASP3_VIRTUAL2_SYNC_RX	See Figure 7-46
IP Mode : SYNC (CLKR / FSR internally generated from CLKX / FSX)
5	CO-FO-	CLKX / FSX: Output	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-47
5	CO-FO-	CLKX / FSX: Output	AXR(Inputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-47
6	CI-FO-	FSX: Output CLKX: Input	AXR(Outputs)/CLKX/FSX	MCASP3_VIRTUAL2_SYNC_RX	See Figure 7-48
6	CI-FO-	FSX: Output CLKX: Input	AXR(Inputs)/CLKX/FSX	MCASP3_VIRTUAL2_SYNC_RX	See Figure 7-48
7	CI-FI-	CLKX / FSX: Input	AXR(Outputs)/CLKX/FSX	MCASP3_VIRTUAL2_SYNC_RX	See Figure 7-49
7	CI-FI-	CLKX / FSX: Input	AXR(Inputs)/CLKX/FSX	MCASP3_VIRTUAL2_SYNC_RX	See Figure 7-49
8	CO-FI-	CLKX: Output FSX: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-50
8	CO-FI-	CLKX: Output FSX: Input	AXR(Inputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-50

Table 7-55 Virtual Mode Case Details for McASP4

No.	CASE	CASE Description	Virtual Mode Settings		Notes
No.	CASE	CASE Description	Signals	Virtual Mode Value	Notes
IP Mode : ASYNC
1	COIFOI	CLKX / FSX: Output CLKR / FSR: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-43
1	COIFOI	CLKX / FSX: Output CLKR / FSR: Input	AXR(Inputs)/CLKR/FSR	MCASP4_VIRTUAL1_SYNC_RX	See Figure 7-43
2	COIFIO	CLKX / FSR: Output CLKR / FSX: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-44
2	COIFIO	CLKX / FSR: Output CLKR / FSX: Input	AXR(Inputs)/CLKR/FSR	MCASP4_VIRTUAL1_SYNC_RX	See Figure 7-44
3	CIOFIO	CLKR / FSR: Output CLKX / FSX: Input	AXR(Outputs)/CLKX/FSX	MCASP4_VIRTUAL1_SYNC_RX	See Figure 7-45
3	CIOFIO	CLKR / FSR: Output CLKX / FSX: Input	AXR(Inputs)/CLKR/FSR	MCASP4_VIRTUAL1_SYNC_RX	See Figure 7-45
4	CIOFOI	CLKR / FSX: Output CLKX / FSR: Input	AXR(Outputs)/CLKX/FSX	MCASP4_VIRTUAL1_SYNC_RX	See Figure 7-46
4	CIOFOI	CLKR / FSX: Output CLKX / FSR: Input	AXR(Inputs)/CLKR/FSR	MCASP4_VIRTUAL1_SYNC_RX	See Figure 7-46
IP Mode : SYNC (CLKR / FSR internally generated from CLKX / FSX)
5	CO-FO-	CLKX / FSX: Output	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-47
5	CO-FO-	CLKX / FSX: Output	AXR(Inputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-47
6	CI-FO-	FSX: Output CLKX: Input	AXR(Outputs)/CLKX/FSX	MCASP4_VIRTUAL1_SYNC_RX	See Figure 7-48
6	CI-FO-	FSX: Output CLKX: Input	AXR(Inputs)/CLKX/FSX	MCASP4_VIRTUAL1_SYNC_RX	See Figure 7-48
7	CI-FI-	CLKX / FSX: Input	AXR(Outputs)/CLKX/FSX	MCASP4_VIRTUAL1_SYNC_RX	See Figure 7-49
7	CI-FI-	CLKX / FSX: Input	AXR(Inputs)/CLKX/FSX	MCASP4_VIRTUAL1_SYNC_RX	See Figure 7-49
8	CO-FI-	CLKX: Output FSX: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-50
8	CO-FI-	CLKX: Output FSX: Input	AXR(Inputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-50

Table 7-56 Virtual Mode Case Details for McASP5

No.	CASE	CASE Description	Virtual Mode Settings		Notes
No.	CASE	CASE Description	Signals	Virtual Mode Value	Notes
IP Mode : ASYNC
1	COIFOI	CLKX / FSX: Output CLKR / FSR: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-43
1	COIFOI	CLKX / FSX: Output CLKR / FSR: Input	AXR(Inputs)/CLKR/FSR	MCASP5_VIRTUAL1_SYNC_RX	See Figure 7-43
2	COIFIO	CLKX / FSR: Output CLKR / FSX: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-44
2	COIFIO	CLKX / FSR: Output CLKR / FSX: Input	AXR(Inputs)/CLKR/FSR	MCASP5_VIRTUAL1_SYNC_RX	See Figure 7-44
3	CIOFIO	CLKR / FSR: Output CLKX / FSX: Input	AXR(Outputs)/CLKX/FSX	MCASP5_VIRTUAL1_SYNC_RX	See Figure 7-45
3	CIOFIO	CLKR / FSR: Output CLKX / FSX: Input	AXR(Inputs)/CLKR/FSR	MCASP5_VIRTUAL1_SYNC_RX	See Figure 7-45
4	CIOFOI	CLKR / FSX: Output CLKX / FSR: Input	AXR(Outputs)/CLKX/FSX	MCASP5_VIRTUAL1_SYNC_RX	See Figure 7-46
4	CIOFOI	CLKR / FSX: Output CLKX / FSR: Input	AXR(Inputs)/CLKR/FSR	MCASP5_VIRTUAL1_SYNC_RX	See Figure 7-46
IP Mode : SYNC (CLKR / FSR internally generated from CLKX / FSX)
5	CO-FO-	CLKX / FSX: Output	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-47
5	CO-FO-	CLKX / FSX: Output	AXR(Inputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-47
6	CI-FO-	FSX: Output CLKX: Input	AXR(Outputs)/CLKX/FSX	MCASP5_VIRTUAL1_SYNC_RX	See Figure 7-48
6	CI-FO-	FSX: Output CLKX: Input	AXR(Inputs)/CLKX/FSX	MCASP5_VIRTUAL1_SYNC_RX	See Figure 7-48
7	CI-FI-	CLKX / FSX: Input	AXR(Outputs)/CLKX/FSX	MCASP5_VIRTUAL1_SYNC_RX	See Figure 7-49
7	CI-FI-	CLKX / FSX: Input	AXR(Inputs)/CLKX/FSX	MCASP5_VIRTUAL1_SYNC_RX	See Figure 7-49
8	CO-FI-	CLKX: Output FSX: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-50
8	CO-FI-	CLKX: Output FSX: Input	AXR(Inputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-50

Table 7-57 Virtual Mode Case Details for McASP6

No.	CASE	CASE Description	Virtual Mode Settings		Notes
No.	CASE	CASE Description	Signals	Virtual Mode Value	Notes
IP Mode : ASYNC
1	COIFOI	CLKX / FSX: Output CLKR / FSR: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-43
1	COIFOI	CLKX / FSX: Output CLKR / FSR: Input	AXR(Inputs)/CLKR/FSR	MCASP6_VIRTUAL1_SYNC_RX	See Figure 7-43
2	COIFIO	CLKX / FSR: Output CLKR / FSX: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-44
2	COIFIO	CLKX / FSR: Output CLKR / FSX: Input	AXR(Inputs)/CLKR/FSR	MCASP6_VIRTUAL1_SYNC_RX	See Figure 7-44
3	CIOFIO	CLKR / FSR: Output CLKX / FSX: Input	AXR(Outputs)/CLKX/FSX	MCASP6_VIRTUAL1_SYNC_RX	See Figure 7-45
3	CIOFIO	CLKR / FSR: Output CLKX / FSX: Input	AXR(Inputs)/CLKR/FSR	MCASP6_VIRTUAL1_SYNC_RX	See Figure 7-45
4	CIOFOI	CLKR / FSX: Output CLKX / FSR: Input	AXR(Outputs)/CLKX/FSX	MCASP6_VIRTUAL1_SYNC_RX	See Figure 7-46
4	CIOFOI	CLKR / FSX: Output CLKX / FSR: Input	AXR(Inputs)/CLKR/FSR	MCASP6_VIRTUAL1_SYNC_RX	See Figure 7-46
IP Mode : SYNC (CLKR / FSR internally generated from CLKX / FSX)
5	CO-FO-	CLKX / FSX: Output	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-47
5	CO-FO-	CLKX / FSX: Output	AXR(Inputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-47
6	CI-FO-	FSX: Output CLKX: Input	AXR(Outputs)/CLKX/FSX	MCASP6_VIRTUAL1_SYNC_RX	See Figure 7-48
6	CI-FO-	FSX: Output CLKX: Input	AXR(Inputs)/CLKX/FSX	MCASP6_VIRTUAL1_SYNC_RX	See Figure 7-48
7	CI-FI-	CLKX / FSX: Input	AXR(Outputs)/CLKX/FSX	MCASP6_VIRTUAL1_SYNC_RX	See Figure 7-49
7	CI-FI-	CLKX / FSX: Input	AXR(Inputs)/CLKX/FSX	MCASP6_VIRTUAL1_SYNC_RX	See Figure 7-49
8	CO-FI-	CLKX: Output FSX: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-50
8	CO-FI-	CLKX: Output FSX: Input	AXR(Inputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-50

Table 7-58 Virtual Mode Case Details for McASP7

No.	CASE	CASE Description	Virtual Mode Settings		Notes
No.	CASE	CASE Description	Signals	Virtual Mode Value	Notes
IP Mode : ASYNC
1	COIFOI	CLKX / FSX: Output CLKR / FSR: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-43
1	COIFOI	CLKX / FSX: Output CLKR / FSR: Input	AXR(Inputs)/CLKR/FSR	MCASP7_VIRTUAL2_SYNC_RX	See Figure 7-43
2	COIFIO	CLKX / FSR: Output CLKR / FSX: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-44
2	COIFIO	CLKX / FSR: Output CLKR / FSX: Input	AXR(Inputs)/CLKR/FSR	MCASP7_VIRTUAL2_SYNC_RX	See Figure 7-44
3	CIOFIO	CLKR / FSR: Output CLKX / FSX: Input	AXR(Outputs)/CLKX/FSX	MCASP7_VIRTUAL2_SYNC_RX	See Figure 7-45
3	CIOFIO	CLKR / FSR: Output CLKX / FSX: Input	AXR(Inputs)/CLKR/FSR	MCASP7_VIRTUAL2_SYNC_RX	See Figure 7-45
4	CIOFOI	CLKR / FSX: Output CLKX / FSR: Input	AXR(Outputs)/CLKX/FSX	MCASP7_VIRTUAL2_SYNC_RX	See Figure 7-46
4	CIOFOI	CLKR / FSX: Output CLKX / FSR: Input	AXR(Inputs)/CLKR/FSR	MCASP7_VIRTUAL2_SYNC_RX	See Figure 7-46
IP Mode : SYNC (CLKR / FSR internally generated from CLKX / FSX)
5	CO-FO-	CLKX / FSX: Output	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-47
5	CO-FO-	CLKX / FSX: Output	AXR(Inputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-47
6	CI-FO-	FSX: Output CLKX: Input	AXR(Outputs)/CLKX/FSX	MCASP7_VIRTUAL2_SYNC_RX	See Figure 7-48
6	CI-FO-	FSX: Output CLKX: Input	AXR(Inputs)/CLKX/FSX	MCASP7_VIRTUAL2_SYNC_RX	See Figure 7-48
7	CI-FI-	CLKX / FSX: Input	AXR(Outputs)/CLKX/FSX	MCASP7_VIRTUAL2_SYNC_RX	See Figure 7-49
7	CI-FI-	CLKX / FSX: Input	AXR(Inputs)/CLKX/FSX	MCASP7_VIRTUAL2_SYNC_RX	See Figure 7-49
8	CO-FI-	CLKX: Output FSX: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-50
8	CO-FI-	CLKX: Output FSX: Input	AXR(Inputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-50

Table 7-59 Virtual Mode Case Details for McASP8

No.	CASE	CASE Description	Virtual Mode Settings		Notes
No.	CASE	CASE Description	Signals	Virtual Mode Value	Notes
IP Mode : ASYNC
1	COIFOI	CLKX / FSX: Output CLKR / FSR: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-43
1	COIFOI	CLKX / FSX: Output CLKR / FSR: Input	AXR(Inputs)/CLKR/FSR	MCASP8_VIRTUAL1_SYNC_RX	See Figure 7-43
2	COIFIO	CLKX / FSR: Output CLKR / FSX: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-44
2	COIFIO	CLKX / FSR: Output CLKR / FSX: Input	AXR(Inputs)/CLKR/FSR	MCASP8_VIRTUAL1_SYNC_RX	See Figure 7-44
3	CIOFIO	CLKR / FSR: Output CLKX / FSX: Input	AXR(Outputs)/CLKX/FSX	MCASP8_VIRTUAL1_SYNC_RX	See Figure 7-45
3	CIOFIO	CLKR / FSR: Output CLKX / FSX: Input	AXR(Inputs)/CLKR/FSR	MCASP8_VIRTUAL1_SYNC_RX	See Figure 7-45
4	CIOFOI	CLKR / FSX: Output CLKX / FSR: Input	AXR(Outputs)/CLKX/FSX	MCASP8_VIRTUAL1_SYNC_RX	See Figure 7-46
4	CIOFOI	CLKR / FSX: Output CLKX / FSR: Input	AXR(Inputs)/CLKR/FSR	MCASP8_VIRTUAL1_SYNC_RX	See Figure 7-46
IP Mode : SYNC (CLKR / FSR internally generated from CLKX / FSX)
5	CO-FO-	CLKX / FSX: Output	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-47
5	CO-FO-	CLKX / FSX: Output	AXR(Inputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-47
6	CI-FO-	FSX: Output CLKX: Input	AXR(Outputs)/CLKX/FSX	MCASP8_VIRTUAL1_SYNC_RX	See Figure 7-48
6	CI-FO-	FSX: Output CLKX: Input	AXR(Inputs)/CLKX/FSX	MCASP8_VIRTUAL1_SYNC_RX	See Figure 7-48
7	CI-FI-	CLKX / FSX: Input	AXR(Outputs)/CLKX/FSX	MCASP8_VIRTUAL1_SYNC_RX	See Figure 7-49
7	CI-FI-	CLKX / FSX: Input	AXR(Inputs)/CLKX/FSX	MCASP8_VIRTUAL1_SYNC_RX	See Figure 7-49
8	CO-FI-	CLKX: Output FSX: Input	AXR(Outputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-50
8	CO-FI-	CLKX: Output FSX: Input	AXR(Inputs)/CLKX/FSX	Default (No Virtual Mode)	See Figure 7-50

Figure 7-43 McASP1-8 COIFOI - ASYNC Mode

Figure 7-44 McASP1-8 COIFIO - ASYNC Mode

Figure 7-45 McASP1-8 CIOFIO - ASYNC Mode

Figure 7-46 McASP1-8 CIOFOI - ASYNC Mode

Figure 7-47 McASP1-8 CO-FO- - SYNC Mode

Figure 7-48 McASP1-8 CI-FO- - SYNC Mode

Figure 7-49 McASP1-8 CI-FI- - SYNC Mode

Figure 7-50 McASP1-8 CO-FI- - SYNC Mode

NOTE

To configure the desired virtual mode the user must set MODESELECT bit and DELAYMODE bitfield for each corresponding pad control register.

The pad control registers are presented in Table 4-3 and described in Device TRM, Control Module Chapter.

CAUTION

Virtual IO Timings Modes must be used to guaranteed some IO timings for McASP1. See Table 7-2, Modes Summary for a list of IO timings requiring the use of Virtual IO Timings Modes. See Table 7-60, Virtual Functions Mapping for McASP1 for a definition of the Virtual modes.

Table 7-60 presents the values for DELAYMODE bitfield.

Table 7-60 Virtual Functions Mapping for McASP1

BALL	BALL NAME	Delay Mode Value		MUXMODE
BALL	BALL NAME	MCASP1_VIRTUAL1_SYNC_RX	MCASP1_VIRTUAL2_ASYNC_RX	0	1	2	3
C14	mcasp1_aclkx	15	14	mcasp1_aclkx
E21	gpio6_14	14	13		mcasp1_axr8
A13	mcasp1_axr13	15	14	mcasp1_axr13
E12	mcasp1_axr4	14	13	mcasp1_axr4
B26	xref_clk2	14	13			mcasp1_axr6
A11	mcasp1_axr9	15	14	mcasp1_axr9
D12	mcasp1_axr7	14	13	mcasp1_axr7
E14	mcasp1_axr12	15	14	mcasp1_axr12
F21	gpio6_16	14	13		mcasp1_axr10
F20	gpio6_15	14	13		mcasp1_axr9
C23	xref_clk3	14	13			mcasp1_axr7
C12	mcasp1_axr6	14	13	mcasp1_axr6
B13	mcasp1_axr10	15	14	mcasp1_axr10
J14	mcasp1_fsr	N/A	14	mcasp1_fsr
B12	mcasp1_axr8	15	14	mcasp1_axr8
A12	mcasp1_axr11	15	14	mcasp1_axr11
G13	mcasp1_axr2	14	13	mcasp1_axr2
D14	mcasp1_fsx	15	14	mcasp1_fsx
G14	mcasp1_axr14	15	14	mcasp1_axr14
F14	mcasp1_axr15	15	14	mcasp1_axr15
F12	mcasp1_axr1	15	14	mcasp1_axr1
B14	mcasp1_aclkr	N/A	14	mcasp1_aclkr
F13	mcasp1_axr5	14	13	mcasp1_axr5
E17	xref_clk1	15	14			mcasp1_axr5
G12	mcasp1_axr0	15	14	mcasp1_axr0
J11	mcasp1_axr3	14	13	mcasp1_axr3
D18	xref_clk0	15	14			mcasp1_axr4	mcasp1_ahclkx

Virtual IO Timings Modes must be used to guaranteed some IO timings for McASP2. See Table 7-2, Modes Summary for a list of IO timings requiring the use of Virtual IO Timings Modes. See Table 7-61, Virtual Functions Mapping for McASP2 for a definition of the Virtual modes.

Table 7-61 presents the values for DELAYMODE bitfield.

Table 7-61 Virtual Functions Mapping for McASP2

BALL	BALL NAME	Delay Mode Value				MUXMODE
BALL	BALL NAME	MCASP2_VIRTUAL1 _SYNC_RX_80M	MCASP2_VIRTUAL2 _ASYNC_RX	MCASP2_VIRTUAL3 _SYNC_RX	MCASP2_VIRTUAL4 _ASYNC_RX_80M	0	1	2	3
B19	mcasp3_axr0	15	14	10	9			mcasp2_axr14
B17	mcasp2_axr6	14	13	12	11	mcasp2_axr6
B16	mcasp2_axr5	14	13	12	11	mcasp2_axr5
A18	mcasp2_fsx	15	14	10	9	mcasp2_fsx
B26	xref_clk2	12	11	10	9		mcasp2_axr10
A16	mcasp2_axr3	15	14	10	9	mcasp2_axr3
E15	mcasp2_aclkr	N/A	14	N/A	13	mcasp2_aclkr
B18	mcasp3_aclkx	15	14	10	9			mcasp2_axr12
A19	mcasp2_aclkx	15	14	10	9	mcasp2_aclkx
A17	mcasp2_axr7	14	13	12	11	mcasp2_axr7
C23	xref_clk3	12	11	10	9		mcasp2_axr11
C17	mcasp3_axr1	15	14	10	8			mcasp2_axr15
F15	mcasp3_fsx	15	14	10	9			mcasp2_axr13
C15	mcasp2_axr2	15	14	10	9	mcasp2_axr2
D15	mcasp2_axr4	14	13	12	11	mcasp2_axr4
A20	mcasp2_fsr	N/A	14	N/A	13	mcasp2_fsr
E17	xref_clk1	10	9	8	6		mcasp2_axr9		mcasp2_ahclkx
A15	mcasp2_axr1	14	13	12	11	mcasp2_axr1
B15	mcasp2_axr0	14	13	12	11	mcasp2_axr0
D18	xref_clk0	10	9	8	6		mcasp2_axr8

Virtual IO Timings Modes must be used to guaranteed some IO timings for McASP3/4/5/6/7/8. See Table 7-2, Modes Summary for a list of IO timings requiring the use of Virtual IO Timings Modes. See Table 7-62, Virtual Functions Mapping for McASP3/4/5/6/7/8 for a definition of the Virtual modes.

Table 7-62 presents the values for DELAYMODE bitfield.

Table 7-62 Virtual Functions Mapping for McASP3/4/5/6/7/8

BALL	BALL NAME	Delay Mode Value	MUXMODE
BALL	BALL NAME	Delay Mode Value	0	1	2
MCASP3_VIRTUAL2_SYNC_RX
A16	mcasp2_axr3	8		mcasp3_axr3
B18	mcasp3_aclkx	8	mcasp3_aclkx	mcasp3_aclkr
B19	mcasp3_axr0	8	mcasp3_axr0
C17	mcasp3_axr1	6	mcasp3_axr1
F15	mcasp3_fsx	8	mcasp3_fsx	mcasp3_fsr
C15	mcasp2_axr2	8		mcasp3_axr2
MCASP4_VIRTUAL1_SYNC_RX
A21	mcasp4_fsx	14	mcasp4_fsx	mcasp4_fsr
C18	mcasp4_aclkx	14	mcasp4_aclkx	mcasp4_aclkr
G16	mcasp4_axr0	14	mcasp4_axr0
D17	mcasp4_axr1	14	mcasp4_axr1
F13	mcasp1_axr5	12		mcasp4_axr3
E12	mcasp1_axr4	12		mcasp4_axr2
MCASP5_VIRTUAL1_SYNC_RX
AA3	mcasp5_aclkx	14	mcasp5_aclkx	mcasp5_aclkr
AB9	mcasp5_fsx	14	mcasp5_fsx	mcasp5_fsr
AA4	mcasp5_axr1	14	mcasp5_axr1
C12	mcasp1_axr6	12		mcasp5_axr2
AB3	mcasp5_axr0	14	mcasp5_axr0
D12	mcasp1_axr7	12		mcasp5_axr3
MCASP6_VIRTUAL1_SYNC_RX
G13	mcasp1_axr2	12		mcasp6_axr2
J11	mcasp1_axr3	12		mcasp6_axr3
B13	mcasp1_axr10	10		mcasp6_aclkx	mcasp6_aclkr
A11	mcasp1_axr9	10		mcasp6_axr1
B12	mcasp1_axr8	10		mcasp6_axr0
A12	mcasp1_axr11	10		mcasp6_fsx	mcasp6_fsr
MCASP7_VIRTUAL2_SYNC_RX
E14	mcasp1_axr12	10		mcasp7_axr0
F14	mcasp1_axr15	10		mcasp7_fsx	mcasp7_fsr
G14	mcasp1_axr14	10		mcasp7_aclkx	mcasp7_aclkr
A13	mcasp1_axr13	10		mcasp7_axr1
B14	mcasp1_aclkr	13		mcasp7_axr2
J14	mcasp1_fsr	13		mcasp7_axr3
MCASP8_VIRTUAL1_SYNC_RX
D15	mcasp2_axr4	10		mcasp8_axr0
A17	mcasp2_axr7	10		mcasp8_fsx	mcasp8_fsr
B17	mcasp2_axr6	10		mcasp8_aclkx	mcasp8_aclkr
A20	mcasp2_fsr	12		mcasp8_axr3
B16	mcasp2_axr5	10		mcasp8_axr1
E15	mcasp2_aclkr	12		mcasp8_axr2

7.19 Universal Serial Bus (USB)

SuperSpeed USB DRD Subsystem has four instances in the device providing the following functions:

USB1: SuperSpeed (SS) USB 3.0 Dual-Role-Device (DRD) subsystem with integrated SS (USB3.0) PHY and HS/FS (USB2.0) PHY.
USB2: High-Speed (HS) USB 2.0 Dual-Role-Device (DRD) subsystem with integrated HS/FS PHY.

NOTE

For more information, see the SuperSpeed USB DRD section of the Device TRM.

7.19.1 USB1 DRD PHY

The USB1 DRD interface supports the following applications:

USB2.0 High-Speed PHY port (1.8 V and 3.3 V): this asynchronous high-speed interface is compliant with the USB2.0 PHY standard with an internal transceiver (USB2.0 standard v2.0), for a maximum data rate of 480 Mbps.
USB3.0 Super-Speed PHY port (1.8 V): this asynchronous differential super-speed interface is compliant with the USB3.0 RX/TX PHY standard (USB3.0 standard v1.0) for a maximum data bit rate of 5Gbps.

7.19.2 USB2 PHY

The USB2 interface supports the following applications:

USB2.0 High-Speed PHY port (1.8 V and 3.3 V): this asynchronous high-speed interface is compliant with the USB2.0 PHY standard with an internal transceiver (USB2.0 standard v2.0), for a maximum data rate of 480 Mbps.

7.20 Serial Advanced Technology Attachment (SATA)

The SATA RX/TX PHY interface is compliant with the SATA standard v2.6 for a maximum data rate:

Gen2i, Gen2m, Gen2x: 3Gbps.
Gen1i, Gen1m, Gen1x: 1.5Gbps.

NOTE

For more information, see the SATA Controller section of the Device TRM.

7.21 Peripheral Component Interconnect Express (PCIe)

The device supports connections to PCIe-compliant devices via the integrated PCIe master/slave bus interface. The PCIe module is comprised of a dual-mode PCIe core and a SerDes PHY. Each PCIe subsystem controller has support for PCIe Gen-II mode (5.0 Gbps /lane) and Gen-I mode (2.5 Gbps/lane) (Single Lane and Flexible dual lane configuration).

The device PCIe supports the following features:

16-bit operation @250 MHz on PIPE interface (per 16-bit lane)
Supports 2 ports x 1 lane or 1 port x 2 lanes configuration
Single virtual channel (VC0), single traffic class (TC0)
Single function in end-point mode
Automatic width and speed negotiation
Max payload: 128 byte outbound, 256 byte inbound
Automatic credit management
ECRC generation and checking
Configurable BAR filtering
Legacy interrupt reception (RC) and generation (EP)
MSI generation and reception
PCI Express Active State Power Management (ASPM) state L0s and L1 (with exceptions)
All PCI Device Power Management D-states with the exception of D3_cold / L2 state

The PCIe controller on this device conforms to the PCI Express Base 3.0 Specification, revision 1.0 and the PCI Local Bus Specification, revision 3.0.

NOTE

For more information, see the PCIe Controller section of the Device TRM.

7.22 Controller Area Network Interface (DCAN)

The device provides two DCAN interfaces for supporting distributed realtime control with a high level of security. The DCAN interfaces implement the following features:

Supports CAN protocol version 2.0 part A, B
Bit rates up to 1 MBit/s
64 message objects
Individual identifier mask for each message object
Programmable FIFO mode for message objects
Programmable loop-back modes for self-test operation
Suspend mode for debug support
Software module reset
Automatic bus on after Bus-Off state by a programmable 32-bit timer
Direct access to Message RAM during test mode
CAN Rx/Tx pins are configurable as general-purpose IO pins
Two interrupt lines (plus additional parity-error interrupts line)
RAM initialization
DMA support

NOTE

For more information, see the DCAN section of the Device TRM.

NOTE

The Controller Area Network Interface x (x = 1 to 2) is also referred to as DCANx.

Table 7-63, Table 7-64 and Figure 7-51 present timing and switching characteristics for DCANx Interface.

Table 7-63 Timing Requirements for DCANx Receive^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	MIN	NOM	MAX	UNIT
	f(baud)	Maximum programmable baud rate			1	Mbps
1	t_w(DCANRX)	Pulse duration, receive data bit (DCANx_RX)	H - 15		H + 15	ns

H = period of baud rate, 1/programmed baud rate.

Table 7-64 Switching Characteristics Over Recommended Operating Conditions for DCANx Transmit ^⁽¹⁾

NO.	PARAMETER	DESCRIPTION		MIN	MAX	UNIT
	f(baud)	Maximum programmable baud rate			1	Mbps
2	t_w(DCANTX)	Pulse duration, transmit data bit (DCANx_TX)		H - 15	H + 15	ns

H = period of baud rate, 1/programmed baud rate.

Figure 7-51 DCANx Timings

7.23 Ethernet Interface (GMAC_SW)

The three-port gigabit ethernet switch subsystem (GMAC_SW) provides ethernet packet communication and can be configured as an ethernet switch. It provides the Gigabit Media Independent Interface (G/MII) in MII mode, Reduced Gigabit Media Independent Interface (RGMII), Reduced Media Independent Interface (RMII), and the Management Data Input/Output (MDIO) for physical layer device (PHY) management.

NOTE

For more information, see the Ethernet Subsystem section of the Device TRM.

NOTE

The Gigabit, Reduced and Media Independent Interface n (n = 0 to 1) are also referred to as MIIn, RMIIn and RGMIIn.

CAUTION

The I/O timings provided in this section are valid only if signals within a single IOSET are used. The IOSETs are defined in Table 7-69, Table 7-72, Table 7-77 and Table 7-84.

CAUTION

The I/O Timings provided in this section are valid only for some GMAC usage modes when the corresponding Virtual I/O Timings or Manual I/O Timings are configured as described in the tables found in this section.

Table 7-65 and Figure 7-52 present timing requirements for MIIn in receive operation.

7.23.1 GMAC MII Timings

Table 7-65 Timing Requirements for miin_rxclk - MII Operation

NO.	PARAMETER	DESCRIPTION	SPEED	MIN	MAX	UNIT
1	t_{c(RX_CLK)}	Cycle time, miin_rxclk	10 Mbps	400		ns
1	t_{c(RX_CLK)}	Cycle time, miin_rxclk	100 Mbps	40		ns
2	t_{w(RX_CLKH)}	Pulse duration, miin_rxclk high	10 Mbps	140	260	ns
2	t_{w(RX_CLKH)}	Pulse duration, miin_rxclk high	100 Mbps	14	26	ns
3	t_{w(RX_CLKL)}	Pulse duration, miin_rxclk low	10 Mbps	140	260	ns
3	t_{w(RX_CLKL)}	Pulse duration, miin_rxclk low	100 Mbps	14	26	ns
4	t_{t(RX_CLK)}	Transition time, miin_rxclk	10 Mbps		3	ns
4	t_{t(RX_CLK)}	Transition time, miin_rxclk	100 Mbps		3	ns

AM5718-HIREL SPRS906_TIMING_GMAC_MIIRXCLK_01.gif

Figure 7-52 Clock Timing (GMAC Receive) - MIIn operation

Table 7-66 and Figure 7-53 present timing requirements for MIIn in transmit operation.

Table 7-66 Timing Requirements for miin_txclk - MII Operation

NO.	PARAMETER	DESCRIPTION	SPEED	MIN	MAX	UNIT
1	t_{c(TX_CLK)}	Cycle time, miin_txclk	10 Mbps	400		ns
1	t_{c(TX_CLK)}	Cycle time, miin_txclk	100 Mbps	40		ns
2	t_{w(TX_CLKH)}	Pulse duration, miin_txclk high	10 Mbps	140	260	ns
2	t_{w(TX_CLKH)}	Pulse duration, miin_txclk high	100 Mbps	14	26	ns
3	t_{w(TX_CLKL)}	Pulse duration, miin_txclk low	10 Mbps	140	260	ns
3	t_{w(TX_CLKL)}	Pulse duration, miin_txclk low	100 Mbps	14	26	ns
4	t_{t(TX_CLK)}	Transition time, miin_txclk	10 Mbps		3	ns
4	t_{t(TX_CLK)}	Transition time, miin_txclk	100 Mbps		3	ns

AM5718-HIREL SPRS906_TIMING_GMAC_MIITXCLK_02.gif

Figure 7-53 Clock Timing (GMAC Transmit) - MIIn operation

Table 7-67 and Figure 7-54 present timing requirements for GMAC MIIn Receive 10/100Mbit/s.

Table 7-67 Timing Requirements for GMAC MIIn Receive 10/100 Mbit/s

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
1	t_{su(RXD-RX_CLK)}	Setup time, receive selected signals valid before miin_rxclk	8	ns
	t_{su(RX_DV-RX_CLK)}
	t_{su(RX_ER-RX_CLK)}
2	t_{h(RX_CLK-RXD)}	Hold time, receive selected signals valid after miin_rxclk	8	ns
	t_{h(RX_CLK-RX_DV)}
	t_{h(RX_CLK-RX_ER)}

AM5718-HIREL SPRS906_TIMING_GMAC_MIIRCV_03.gif

Figure 7-54 GMAC Receive Interface Timing MIIn operation

Table 7-68 and Figure 7-55 present timing requirements for GMAC MIIn Transmit 10/100Mbit/s.

Table 7-68 Switching Characteristics Over Recommended Operating Conditions for GMAC MIIn Transmit 10/100 Mbits/s

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
1	t_{d(TX_CLK-TXD)}	Delay time, miin_txclk to transmit selected signals valid	0	25	ns
1	t_{d(TX_CLK-TX_EN)}	Delay time, miin_txclk to transmit selected signals valid	0	25	ns

AM5718-HIREL SPRS906_TIMING_GMAC_MIITX_04.gif

Figure 7-55 GMAC Transmit Interface Timing MIIn operation

In Table 7-69 are presented the specific groupings of signals (IOSET) for use with GMAC MII signals.

Table 7-69 GMAC MII IOSETs

SIGNALS	IOSET5		IOSET6
SIGNALS	BALL	MUX	BALL	MUX
GMAC MII1
mii1_txd3	C5	8
mii1_txd2	D6	8
mii1_txd1	B2	8
mii1_txd0	C4	8
mii1_rxd3	F5	8
mii1_rxd2	E4	8
mii1_rxd1	C1	8
mii1_rxd0	E6	8
mii1_col	B4	8
mii1_rxer	B3	8
mii1_txer	A3	8
mii1_txen	A4	8
mii1_crs	B5	8
mii1_rxclk	D5	8
mii1_txclk	C3	8
mii1_rxdv	C2	8
GMAC MII0
mii0_txd3			V5	3
mii0_txd2			V4	3
mii0_txd1			Y2	3
mii0_txd0			W2	3
mii0_rxd3			W9	3
mii0_rxd2			V9	3
mii0_rxd1			V6	3
mii0_rxd0			U6	3
mii0_txclk			U5	3
mii0_txer			U4	3
mii0_rxer			U7	3
mii0_rxdv			V2	3
mii0_crs			V7	3
mii0_col			V1	3
mii0_rxclk			Y1	3
mii0_txen			V3	3

7.23.2 GMAC MDIO Interface Timings

CAUTION

Table 7-70, Table 7-70 and Figure 7-56 present timing requirements for MDIO.

Table 7-70 Timing Requirements for MDIO Input

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
MDIO1	t_c(MDC)	Cycle time, MDC	400	ns
MDIO2	t_w(MDCH)	Pulse Duration, MDC High	160	ns
MDIO3	t_w(MDCL)	Pulse Duration, MDC Low	160	ns
MDIO4	t_su(MDIO-MDC)	Setup time, MDIO valid before MDC High	90	ns
MDIO5	t_{h(MDIO_MDC)}	Hold time, MDIO valid from MDC High	0	ns

Table 7-71 Switching Characteristics Over Recommended Operating Conditions for MDIO Output

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
MDIO6	t_t(MDC)	Transition time, MDC		5	ns
MDIO7	t_d(MDC-MDIO)	Delay time, MDC High to MDIO valid	10	390	ns

AM5718-HIREL SPRS906_TIMING_GMAC_MDIO_05.gif

Figure 7-56 GMAC MDIO diagrams

In Table 7-72 are presented the specific groupings of signals (IOSET) for use with GMAC MDIO signals.

Table 7-72 GMAC MDIO IOSETs

SIGNALS	IOSET7		IOSET8		IOSET9		IOSET10
SIGNALS	BALL	MUX	BALL	MUX	BALL	MUX	BALL	MUX
mdio_d	F6	3	U4	0	AB4	1	B20	5
mdio_mclk	D3	3	V1	0	AC5	1	B21	5

7.23.3 GMAC RMII Timings

The main reference clock REF_CLK (RMII_50MHZ_CLK) of RMII interface is internally supplied from PRCM. The source of this clock could be either externally sourced from the RMII_MHZ_50_CLK pin of the device or internally generated from DPLL_GMAC output clock GMAC_RMII_HS_CLK. Please see the PRCM chapter of the device TRM for full details about RMII reference clock.

CAUTION

Table 7-73, Table 7-74 and Figure 7-57 present timing requirements for GMAC RMIIn Receive.

Table 7-73 Timing Requirements for GMAC REF_CLK - RMII Operation

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
RMII1	t_{c(REF_CLK)}	Cycle time, REF_CLK	20		ns
RMII2	t_{w(REF_CLKH)}	Pulse duration, REF_CLK high	7	13	ns
RMII3	t_{w(REF_CLKL)}	Pulse duration, REF_CLK low	7	13	ns
RMII4	t_{tt(REF_CLK)}	Transistion time, REF_CLK		3	ns

Table 7-74 Timing Requirements for GMAC RMIIn Receive

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
RMII5	t_{su(RXD-REF_CLK)}	Setup time, receive selected signals valid before REF_CLK	4	ns
	t_{su(CRS_DV-REF_CLK)}
	t_{su(RX_ER-REF_CLK)}
RMII6	t_{h(REF_CLK-RXD)}	Hold time, receive selected signals valid after REF_CLK	2	ns
	t_{h(REF_CLK-CRS_DV)}
	t_{h(REF_CLK-RX_ER)}

AM5718-HIREL SPRS906_TIMING_GMAC_RMIIRX_06.gif

Figure 7-57 GMAC Receive Interface Timing RMIIn operation

Table 7-75, Table 7-75 and Figure 7-58 present switching characteristics for GMAC RMIIn Transmit 10/100Mbit/s.

Table 7-75 Switching Characteristics Over Recommended Operating Conditions for GMAC REF_CLK - RMII Operation

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
RMII7	t_{c(REF_CLK)}	Cycle time, REF_CLK	20		ns
RMII8	t_{w(REF_CLKH)}	Pulse duration, REF_CLK high	7	13	ns
RMII9	t_{w(REF_CLKL)}	Pulse duration, REF_CLK low	7	13	ns
RMII10	t_{t(REF_CLK)}	Transistion time, REF_CLK		3	ns

Table 7-76 Switching Characteristics Over Recommended Operating Conditions for GMAC RMIIn Transmit 10/100 Mbits/s

NO.	PARAMETER	DESCRIPTION	RMIIn	MIN	MAX	UNIT
RMII11	t_{d(REF_CLK-TXD)}	Delay time, REF_CLK high to selected transmit signals valid	RMII0	2	13.5	ns
	t_{dd(REF_CLK-TXEN)}		RMII0	2	13.5	ns
	t_{d(REF_CLK-TXD)}		RMII1	2	13.8	ns
	t_{dd(REF_CLK-TXEN)}		RMII1	2	13.8	ns

AM5718-HIREL SPRS906_TIMING_GMAC_RMIITX_07.gif

Figure 7-58 GMAC Transmit Interface Timing RMIIn Operation

In Table 7-77 are presented the specific groupings of signals (IOSET) for use with GMAC RMII signals.

Table 7-77 GMAC RMII IOSETs

SIGNALS	IOSET1		IOSET2
SIGNALS	BALL	MUX	BALL	MUX
GMAC RMII1
RMII_MHZ_50_CLK	U3	0
rmii1_txd1	V5	2
rmii1_txd0	V4	2
rmii1_rxd1	W9	2
rmii1_rxd0	V9	2
rmii1_rxer	Y1	2
rmii1_txen	U5	2
rmii1_crs	V2	2
GMAC RMII0
RMII_MHZ_50_CLK			U3	0
rmii0_txd1			Y2	1
rmii0_txd0			W2	1
rmii0_rxd1			V6	1
rmii0_rxd0			U6	1
rmii0_txen			V3	1
rmii0_rxer			U7	1
rmii0_crs			V7	1

Manual IO Timings Modes must be used to guaranteed some IO timings for GMAC. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-78 Manual Functions Mapping for GMAC RMII0 for a definition of the Manual modes.

Table 7-78 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-78 Manual Functions Mapping for GMAC RMII0

BALL	BALL NAME	GMAC_RMII0_MANUAL1		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	0	1
U3	RMII_MHZ_50_CLK	0	0	CFG_RMII_MHZ_50_CLK_IN	RMII_MHZ_50_CLK
U6	rgmii0_txd0	2444	804	CFG_RGMII0_TXD0_IN		rmii0_rxd0
V6	rgmii0_txd1	2453	981	CFG_RGMII0_TXD1_IN		rmii0_rxd1
U7	rgmii0_txd2	2356	847	CFG_RGMII0_TXD2_IN		rmii0_rxer
V7	rgmii0_txd3	2415	993	CFG_RGMII0_TXD3_IN		rmii0_crs

Manual IO Timings Modes must be used to guaranteed some IO timings for GMAC. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-79 Manual Functions Mapping for GMAC RMII1 for a definition of the Manual modes.

Table 7-79 list the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-79 Manual Functions Mapping for GMAC RMII1

BALL	BALL NAME	GMAC_RMII1_MANUAL1		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	0	2
U3	RMII_MHZ_50_CLK	0	0	CFG_RMII_MHZ_50_CLK_IN	RMII_MHZ_50_CLK
V9	rgmii0_txctl	2450	909	CFG_RGMII0_TXCTL_IN		rmii1_rxd0
W9	rgmii0_txc	2327	926	CFG_RGMII0_TXC_IN		rmii1_rxd1
Y1	uart3_txd	2553	443	CFG_UART3_TXD_IN		rmii1_rxer
V2	uart3_rxd	1943	1110	CFG_UART3_RXD_IN		rmii1_crs

7.23.4 GMAC RGMII Timings

CAUTION

Table 7-80, Table 7-81 and Figure 7-59 present timing requirements for receive RGMIIn operation.

Table 7-80 Timing Requirements for rgmiin_rxc - RGMIIn Operation

NO.	PARAMETER	DESCRIPTION	SPEED	MIN	MAX	UNIT
1	t_c(RXC)	Cycle time, rgmiin_rxc	10 Mbps	360	440	ns
			100 Mbps	36	44	ns
			1000 Mbps	7.2	8.8	ns
2	t_w(RXCH)	Pulse duration, rgmiin_rxc high	10 Mbps	160	240	ns
			100 Mbps	16	24	ns
			1000 Mbps	3.6	4.4	ns
3	t_w(RXCL)	Pulse duration, rgmiin_rxc low	10 Mbps	160	240	ns
			100 Mbps	16	24	ns
			1000 Mbps	3.6	4.4	ns
4	t_t(RXC)	Transition time, rgmiin_rxc	10 Mbps		0.75	ns
			100 Mbps		0.75	ns
			1000 Mbps		0.75	ns

Table 7-81 Timing Requirements for GMAC RGMIIn Input Receive for 10/100/1000 Mbps ^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	MODE	MIN	MAX	UNIT
5	t_su(RXD-RXCH)	Setup time, receive selected signals valid before rgmiin_rxc high/low	RGMII0/1	1		ns
6	t_h(RXCH-RXD)	Hold time, receive selected signals valid after rgmiin_rxc high/low	RGMII0/1	1		ns

For RGMII, receive selected signals include: rgmiin_rxd[3:0] and rgmiin_rxctl.

AM5718-HIREL SPRS906_TIMING_GMAC_RGMIIRX_08.gif

A. rgmiin_rxc must be externally delayed relative to the data and control pins.

B. Data and control information is received using both edges of the clocks. rgmiin_rxd[3:0] carries data bits 3-0 on the rising edge of rgmiin_rxc and data bits 7-4 on the falling edge ofrgmiin_rxc. Similarly, rgmiin_rxctl carries RXDV on rising edge of rgmiin_rxc and RXERR on falling edge of rgmiin_rxc.

Figure 7-59 GMAC Receive Interface Timing, RGMIIn operation

Table 7-82, Table 7-83 and Figure 7-60 present switching characteristics for transmit - RGMIIn for 10/100/1000Mbit/s.

Table 7-82 Switching Characteristics Over Recommended Operating Conditions for rgmiin_txctl - RGMIIn Operation for 10/100/1000 Mbit/s

NO.	PARAMETER	DESCRIPTION	SPEED	MIN	MAX	UNIT
1	t_c(TXC)	Cycle time, rgmiin_txc	10 Mbps	360	440	ns
			100 Mbps	36	44	ns
			1000 Mbps	7.2	8.8	ns
2	t_w(TXCH)	Pulse duration, rgmiin_txc high	10 Mbps	160	240	ns
			100 Mbps	16	24	ns
			1000 Mbps	3.6	4.4	ns
3	t_w(TXCL)	Pulse duration, rgmiin_txc low	10 Mbps	160	240	ns
			100 Mbps	16	24	ns
			1000 Mbps	3.6	4.4	ns
4	t_t(TXC)	Transition time, rgmiin_txc	10 Mbps		0.75	ns
			100 Mbps		0.75	ns
			1000 Mbps		0.75	ns

Table 7-83 Switching Characteristics for GMAC RGMIIn Output Transmit for 10/100/1000 Mbps ^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	MODE	MIN	UNIT
5	t_osu(TXD-TXC)	Output Setup time, transmit selected signals valid to rgmiin_txc high/low	RGMII0, Internal Delay Enabled, 1000 Mbps	1.05 ^⁽²⁾	ns
			RGMII0, Internal Delay Enabled, 10/100 Mbps	1.2	ns
			RGMII1, Internal Delay Enabled, 1000 Mbps	1.05^⁽³⁾	ns
			RGMII1, Internal Delay Enabled, 10/100 Mbps	1.2	ns
6	t_oh(TXC-TXD)	Output Hold time, transmit selected signals valid after rgmiin_txc high/low	RGMII0, Internal Delay Enabled, 1000 Mbps	1.05 ^⁽²⁾	ns
			RGMII0, Internal Delay Enabled, 10/100 Mbps	1.2	ns
			RGMII1, Internal Delay Enabled, 1000 Mbps	1.05^⁽³⁾	ns
			RGMII1, Internal Delay Enabled, 10/100 Mbps	1.2	ns

For RGMII, transmit selected signals include: rgmiin_txd[3:0] and rgmiin_txctl.
RGMII0 requires that the 4 data pins rgmii0_txd[3:0] and rgmii0_txctl have their board propagation delays matched within 50pS of rgmii0_txc.
RGMII1 requires that the 4 data pins rgmii1_txd[3:0] and rgmii1_txctl have their board propagation delays matched within 50pS of rgmii1_txc.

AM5718-HIREL SPRS906_TIMING_GMAC_RGMIITX_09.gif

A. TXC is delayed internally before being driven to the rgmiin_txc pin. This internal delay is always enabled.

B. Data and control information is transmitted using both edges of the clocks. rgmiin_txd[3:0] carries data bits 3-0 on the rising edge of rgmiin_txc and data bits 7-4 on the falling edge of rgmiin_txc. Similarly, rgmiin_txctl carries TXEN on rising edge of rgmiin_txc and TXERR of falling edge of rgmiin_txc.

Figure 7-60 GMAC Transmit Interface Timing RGMIIn operation

In Table 7-84 are presented the specific groupings of signals (IOSET) for use with GMAC RGMII signals.

Table 7-84 GMAC RGMII IOSETs

SIGNALS	IOSET3		IOSET4
SIGNALS	BALL	MUX	BALL	MUX
GMAC RGMII1
rgmii1_txd3	C3	3
rgmii1_txd2	C4	3
rgmii1_txd1	B2	3
rgmii1_txd0	D6	3
rgmii1_rxd3	B3	3
rgmii1_rxd2	B4	3
rgmii1_rxd1	B5	3
rgmii1_rxd0	A4	3
rgmii1_rxctl	A3	3
rgmii1_txc	D5	3
rgmii1_txctl	C2	3
rgmii1_rxc	C5	3
GMAC RGMII0
rgmii0_txd3			V7	0
rgmii0_txd2			U7	0
rgmii0_txd1			V6	0
rgmii0_txd0			U6	0
rgmii0_rxd3			V4	0
rgmii0_rxd2			V3	0
rgmii0_rxd1			Y2	0
rgmii0_rxd0			W2	0
rgmii0_txc			W9	0
rgmii0_rxctl			V5	0
rgmii0_rxc			U5	0
rgmii0_txctl			V9	0

NOTE

To configure the desired Manual IO Timing Mode the user must follow the steps described in section "Manual IO Timing Modes" of the Device TRM.

The associated registers to configure are listed in the CFG REGISTER column. For more information please see the Control Module Chapter in the Device TRM.

Manual IO Timings Modes must be used to guaranteed some IO timings for GMAC. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-85 Manual Functions Mapping for GMAC RGMII0 for a definition of the Manual modes.

Table 7-85 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-85 Manual Functions Mapping for GMAC RGMII0

BALL	BALL NAME	GMAC_RGMII0_MANUAL1		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	0
U5	rgmii0_rxc	413	0	CFG_RGMII0_RXC_IN	rgmii0_rxc
V5	rgmii0_rxctl	27	2296	CFG_RGMII0_RXCTL_IN	rgmii0_rxctl
W2	rgmii0_rxd0	3	1721	CFG_RGMII0_RXD0_IN	rgmii0_rxd0
Y2	rgmii0_rxd1	134	1786	CFG_RGMII0_RXD1_IN	rgmii0_rxd1
V3	rgmii0_rxd2	40	1966	CFG_RGMII0_RXD2_IN	rgmii0_rxd2
V4	rgmii0_rxd3	0	2057	CFG_RGMII0_RXD3_IN	rgmii0_rxd3

W9	rgmii0_txc	0	60	CFG_RGMII0_TXC_OUT	rgmii0_txc
V9	rgmii0_txctl	0	60	CFG_RGMII0_TXCTL_OUT	rgmii0_txctl
U6	rgmii0_txd0	0	60	CFG_RGMII0_TXD0_OUT	rgmii0_txd0
V6	rgmii0_txd1	0	0	CFG_RGMII0_TXD1_OUT	rgmii0_txd1
U7	rgmii0_txd2	0	60	CFG_RGMII0_TXD2_OUT	rgmii0_txd2
V7	rgmii0_txd3	0	120	CFG_RGMII0_TXD3_OUT	rgmii0_txd3

Manual IO Timings Modes must be used to guaranteed some IO timings for GMAC. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-86 Manual Functions Mapping for GMAC RGMII1 for a definition of the Manual modes.

Table 7-86 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-86 Manual Functions Mapping for GMAC RGMII1

BALL	BALL NAME	GMAC_RGMII1_MANUAL1		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	3
C5	vin2a_d18	530	0	CFG_VIN2A_D18_IN	rgmii1_rxc
A3	vin2a_d19	71	1099	CFG_VIN2A_D19_IN	rgmii1_rxctl
B3	vin2a_d20	142	1337	CFG_VIN2A_D20_IN	rgmii1_rxd3
B4	vin2a_d21	114	1517	CFG_VIN2A_D21_IN	rgmii1_rxd2
B5	vin2a_d22	171	1331	CFG_VIN2A_D22_IN	rgmii1_rxd1
A4	vin2a_d23	0	1328	CFG_VIN2A_D23_IN	rgmii1_rxd0

D5	vin2a_d12	0	0	CFG_VIN2A_D12_OUT	rgmii1_txc
C2	vin2a_d13	170	0	CFG_VIN2A_D13_OUT	rgmii1_txctl
C3	vin2a_d14	150	0	CFG_VIN2A_D14_OUT	rgmii1_txd3
C4	vin2a_d15	0	0	CFG_VIN2A_D15_OUT	rgmii1_txd2
B2	vin2a_d16	60	0	CFG_VIN2A_D16_OUT	rgmii1_txd1
D6	vin2a_d17	60	0	CFG_VIN2A_D17_OUT	rgmii1_txd0

7.24 eMMC/SD/SDIO

The Device includes the following external memory interfaces 4 MultiMedia Card/Secure Digital/Secure Digital Input Output Interface (MMC/SD/SDIO)

NOTE

The eMMC/SD/SDIOi (i = 1 to 4) controller is also referred to as MMCi.

7.24.1 MMC1-SD Card Interface

MMC1 interface is compliant with the SD Standard v3.01 and it supports the following SD Card applications:

Default speed, 4-bit data, SDR, half-cycle
High speed, 4-bit data, SDR, half-cycle
SDR12, 4-bit data, half-cycle
SDR25, 4-bit data, half-cycle
UHS-I SDR50, 4-bit data, half-cycle
UHS-I SDR104, 4-bit data, half-cycle
UHS-I DDR50, 4-bit data

NOTE

For more information, see the eMMC/SD/SDIO chapter of the Device TRM.

7.24.1.1 Default speed, 4-bit data, SDR, half-cycle

Table 7-87 and Table 7-88 present Timing requirements and Switching characteristics for MMC1 - Default Speed in receiver and transmitter mode (see Figure 7-61 and Figure 7-62).

Table 7-87 Timing Requirements for MMC1 - SD Card Default Speed Mode

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
DSSD5	t_{su(cmdV-clkH)}	Setup time, mmc1_cmd valid before mmc1_clk rising clock edge	5.11	ns
DSSD6	t_h(clkH-cmdV)	Hold time, mmc1_cmd valid after mmc1_clk rising clock edge	20.46	ns
DSSD7	t_su(dV-clkH)	Setup time, mmc1_dat[3:0] valid before mmc1_clk rising clock edge	5.11	ns
DSSD8	t_h(clkH-dV)	Hold time, mmc1_dat[3:0] valid after mmc1_clk rising clock edge	20.46	ns

Table 7-88 Switching Characteristics for MMC1 - SD Card Default Speed Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
DSSD0	fop(clk)	Operating frequency, mmc1_clk		24	MHz
DSSD1	t_w(clkH)	Pulse duration, mmc1_clk high	0.5*P-0.185 ^⁽¹⁾		ns
DSSD2	t_w(clkL)	Pulse duration, mmc1_clk low	0.5*P-0.185 ^⁽¹⁾		ns
DSSD3	t_d(clkL-cmdV)	Delay time, mmc1_clk falling clock edge to mmc1_cmd transition	-14.93	14.93	ns
DSSD4	t_d(clkL-dV)	Delay time, mmc1_clk falling clock edge to mmc1_dat[3:0] transition	-14.93	14.93	ns

P = output mmc1_clk period in ns

Figure 7-61 MMC/SD/SDIO in - Default Speed - Receiver Mode

Figure 7-62 MMC/SD/SDIO in - Default Speed - Transmitter Mode

7.24.1.2 High speed, 4-bit data, SDR, half-cycle

Table 7-89 and Table 7-90 present Timing requirements and Switching characteristics for MMC1 - High Speed in receiver and transmitter mode (see Figure 7-63 and Figure 7-64).

Table 7-89 Timing Requirements for MMC1 - SD Card High Speed

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
HSSD3	t_{su(cmdV-clkH)}	Setup time, mmc1_cmd valid before mmc1_clk rising clock edge	5.3	ns
HSSD4	t_h(clkH-cmdV)	Hold time, mmc1_cmd valid after mmc1_clk rising clock edge	2.6	ns
HSSD7	t_su(dV-clkH)	Setup time, mmc1_dat[3:0] valid before mmc1_clk rising clock edge	5.3	ns
HSSD8	t_h(clkH-dV)	Hold time, mmc1_dat[3:0] valid after mmc1_clk rising clock edge	2.6	ns

Table 7-90 Switching Characteristics for MMC1 - SD Card High Speed

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
HSSD1	fop(clk)	Operating frequency, mmc1_clk		48	MHz
HSSD2H	t_w(clkH)	Pulse duration, mmc1_clk high	0.5*P-0.185 ^⁽¹⁾		ns
HSSD2L	t_w(clkL)	Pulse duration, mmc1_clk low	0.5*P-0.185 ^⁽¹⁾		ns
HSSD5	t_d(clkL-cmdV)	Delay time, mmc1_clk falling clock edge to mmc1_cmd transition	-7.6	3.6	ns
HSSD6	t_d(clkL-dV)	Delay time, mmc1_clk falling clock edge to mmc1_dat[3:0] transition	-7.6	3.6	ns

P = output mmc1_clk period in ns

Figure 7-63 MMC/SD/SDIO in - High Speed - Receiver Mode

Figure 7-64 MMC/SD/SDIO in - High Speed - Transmitter Mode

7.24.1.3 SDR12, 4-bit data, half-cycle

Table 7-91 and Table 7-92 present Timing requirements and Switching characteristics for MMC1 - SDR12 in receiver and transmitter mode (see Figure 7-65 and Figure 7-66).

Table 7-91 Timing Requirements for MMC1 - SD Card SDR12 Mode

NO.	PARAMETER	DESCRIPTION	MODE	MIN	UNIT
SDR125	t_{su(cmdV-clkH)}	Setup time, mmc1_cmd valid before mmc1_clk rising clock edge		25.99	ns
SDR126	t_h(clkH-cmdV)	Hold time, mmc1_cmd valid after mmc1_clk rising clock edge	Pad Loopback Clock	1.6	ns
SDR126	t_h(clkH-cmdV)	Hold time, mmc1_cmd valid after mmc1_clk rising clock edge	Internal Loopback Clock	1.6	ns
SDR127	t_su(dV-clkH)	Setup time, mmc1_dat[3:0] valid before mmc1_clk rising clock edge		25.99	ns
SDR128	t_h(clkH-dV)	Hold time, mmc1_dat[3:0] valid after mmc1_clk rising clock edge	Pad Loopback Clock	1.6	ns
SDR128	t_h(clkH-dV)		Internal Loopback Clock	1.6	ns

Table 7-92 Switching Characteristics for MMC1 - SD Card SDR12 Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
SDR120	fop(clk)	Operating frequency, mmc1_clk		24	MHz
SDR121	t_w(clkH)	Pulse duration, mmc1_clk high	0.5*P-0.185 ^⁽¹⁾		ns
SDR122	t_w(clkL)	Pulse duration, mmc1_clk low	0.5*P-0.185^⁽¹⁾		ns
SDR123	t_d(clkL-cmdV)	Delay time, mmc1_clk falling clock edge to mmc1_cmd transition	-19.13	16.93	ns
SDR124	t_d(clkL-dV)	Delay time, mmc1_clk falling clock edge to mmc1_dat[3:0] transition	-19.13	16.93	ns

P = output mmc1_clk period in ns

Figure 7-65 MMC/SD/SDIO in - High Speed SDR12 - Receiver Mode

Figure 7-66 MMC/SD/SDIO in - High Speed SDR12 - Transmitter Mode

7.24.1.4 SDR25, 4-bit data, half-cycle

Table 7-93 and Table 7-94 present Timing requirements and Switching characteristics for MMC1 - SDR25 in receiver and transmitter mode (see Figure 7-67 and Figure 7-68).

Table 7-93 Timing Requirements for MMC1 - SD Card SDR25 Mode

NO.	PARAMETER	DESCRIPTION	MODE	MIN	UNIT
SDR253	t_{su(cmdV-clkH)}	Setup time, mmc1_cmd valid before mmc1_clk rising clock edge		5.3	ns
SDR254	t_h(clkH-cmdV)	Hold time, mmc1_cmd valid after mmc1_clk rising clock edge		1.6	ns
SDR257	t_su(dV-clkH)	Setup time, mmc1_dat[3:0] valid before mmc1_clk rising clock edge		5.3	ns
SDR258	t_h(clkH-dV)	Hold time, mmc1_dat[3:0] valid after mmc1_clk rising clock edge	Pad Loopback Clock	1.6	ns
SDR258	t_h(clkH-dV)		Internal Loopback Clock	1.6	ns

Table 7-94 Switching Characteristics for MMC1 - SD Card SDR25 Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
SDR251	fop(clk)	Operating frequency, mmc1_clk		48	MHz
SDR252H	t_w(clkH)	Pulse duration, mmc1_clk high	0.5*P-0.185 ^⁽¹⁾		ns
SDR252L	t_w(clkL)	Pulse duration, mmc1_clk low	0.5*P-0.185 ^⁽¹⁾		ns
SDR255	t_d(clkL-cmdV)	Delay time, mmc1_clk falling clock edge to mmc1_cmd transition	-8.8	6.6	ns
SDR256	t_d(clkL-dV)	Delay time, mmc1_clk falling clock edge to mmc1_dat[3:0] transition	-8.8	6.6	ns

P = output mmc1_clk period in ns

Figure 7-67 MMC/SD/SDIO in - High Speed SDR25 - Receiver Mode

Figure 7-68 MMC/SD/SDIO in - High Speed SDR25 - Transmitter Mode

7.24.1.5 UHS-I SDR50, 4-bit data, half-cycle

Table 7-95 and Table 7-96 present Timing requirements and Switching characteristics for MMC1 - SDR50 in receiver and transmitter mode (see Figure 7-69 and Figure 7-70).

Table 7-95 Timing Requirements for MMC1 - SD Card SDR50 Mode

NO.	PARAMETER	DESCRIPTION	MODE	MIN	UNIT
SDR503	t_{su(cmdV-clkH)}	Setup time, mmc1_cmd valid before mmc1_clk rising clock edge		1.48	ns
SDR504	t_h(clkH-cmdV)	Hold time, mmc1_cmd valid after mmc1_clk rising clock edge		1.7	ns
SDR507	t_su(dV-clkH)	Setup time, mmc1_dat[3:0] valid before mmc1_clk rising clock edge		1.48	ns
SDR508	t_h(clkH-dV)	Hold time, mmc1_dat[3:0] valid after mmc1_clk rising clock edge	Pad Loopback Clock	1.7	ns
SDR508	t_h(clkH-dV)		Internal Loopback Clock	1.6	ns

Table 7-96 Switching Characteristics for MMC1 - SD Card SDR50 Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
SDR501	fop(clk)	Operating frequency, mmc1_clk		96	MHz
SDR502H	t_w(clkH)	Pulse duration, mmc1_clk high	0.5*P-0.185 ^⁽¹⁾		ns
SDR502L	t_w(clkL)	Pulse duration, mmc1_clk low	0.5*P-0.185 ^⁽¹⁾		ns
SDR505	t_d(clkL-cmdV)	Delay time, mmc1_clk falling clock edge to mmc1_cmd transition	-8.8	6.6	ns
SDR506	t_d(clkL-dV)	Delay time, mmc1_clk falling clock edge to mmc1_dat[3:0] transition	-3.66	1.46	ns

P = output mmc1_clk period in ns

Figure 7-69 MMC/SD/SDIO in - High Speed SDR50 - Receiver Mode

Figure 7-70 MMC/SD/SDIO in - High Speed SDR50 - Transmitter Mode

7.24.1.6 UHS-I SDR104, 4-bit data, half-cycle

Table 7-97 presents Timing requirements and Switching characteristics for MMC1 - SDR104 in receiver and transmitter mode (see Figure 7-71 and Figure 7-72).

Table 7-97 Switching Characteristics for MMC1 - SD Card SDR104 Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
SDR1041	fop(clk)	Operating frequency, mmc1_clk		192	MHz
SDR1042H	t_w(clkH)	Pulse duration, mmc1_clk high	0.5*P-0.185 ^⁽¹⁾		ns
SDR1042L	t_w(clkL)	Pulse duration, mmc1_clk low	0.5*P-0.185 ^⁽¹⁾		ns
SDR1045	t_d(clkL-cmdV)	Delay time, mmc1_clk falling clock edge to mmc1_cmd transition	-1.09	0.49	ns
SDR1046	t_d(clkL-dV)	Delay time, mmc1_clk falling clock edge to mmc1_dat[3:0] transition	-1.09	0.49	ns

P = output mmc1_clk period in ns

Figure 7-71 MMC/SD/SDIO in - High Speed SDR104 - Receiver Mode

Figure 7-72 MMC/SD/SDIO in - High Speed SDR104 - Transmitter Mode

7.24.1.7 UHS-I DDR50, 4-bit data

Table 7-98 and Table 7-99 present Timing requirements and Switching characteristics for MMC1 - DDR50 in receiver and transmitter mode (see Figure 7-73 and Figure 7-74).

Table 7-98 Timing Requirements for MMC1 - SD Card DDR50 Mode

NO.	PARAMETER	DESCRIPTION	MODE	MIN	UNIT
DDR505	t_su(cmdV-clk)	Setup time, mmc1_cmd valid before mmc1_clk transition		1.79	ns
DDR506	t_h(clk-cmdV)	Hold time, mmc1_cmd valid after mmc1_clk transition		2	ns
DDR507	t_su(dV-clk)	Setup time, mmc1_dat[3:0] valid before mmc1_clk transition	Pad Loopback	1.79	ns
DDR507	t_su(dV-clk)	Setup time, mmc1_dat[3:0] valid before mmc1_clk transition	Internal Loopback	1.79	ns
DDR508	t_h(clk-dV)	Hold time, mmc1_dat[3:0] valid after mmc1_clk transition	Pad Loopback	2	ns
DDR508	t_h(clk-dV)	Hold time, mmc1_dat[3:0] valid after mmc1_clk transition	Internal Loopback	1.6	ns

Table 7-99 Switching Characteristics for MMC1 - SD Card DDR50 Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
DDR500	fop(clk)	Operating frequency, mmc1_clk		48	MHz
DDR501	t_w(clkH)	Pulse duration, mmc1_clk high	0.5*P-0.185 ^⁽¹⁾		ns
DDR502	t_w(clkL)	Pulse duration, mmc1_clk low	0.5*P-0.185 ^⁽¹⁾		ns
DDR503	t_d(clk-cmdV)	Delay time, mmc1_clk transition to mmc1_cmd transition	1.225	6.6	ns
DDR504	t_d(clk-dV)	Delay time, mmc1_clk transition to mmc1_dat[3:0] transition	1.225	6.6	ns

P = output mmc1_clk period in ns

Figure 7-73 SDMMC - High Speed SD - DDR - Data/Command Receive

Figure 7-74 SDMMC - High Speed SD - DDR - Data/Command Transmit

NOTE

To configure the desired virtual mode the user must set MODESELECT bit and DELAYMODE bitfield for each corresponding pad control register.

The pad control registers are presented in Table 4-3 and described in Device TRM, Control Module Chapter.

Virtual IO Timings Modes must be used to guaranteed some IO timings for MMC1. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Virtual IO Timings Modes. See Table 7-100 Virtual Functions Mapping for MMC1 for a definition of the Virtual modes.

Table 7-100 presents the values for DELAYMODE bitfield.

Table 7-100 Virtual Functions Mapping for MMC1

BALL	BALL NAME	Delay Mode Value				MUXMODE
BALL	BALL NAME	MMC1_ VIRTUAL1	MMC1_ VIRTUAL4	MMC1_ VIRTUAL5	MMC1_ VIRTUAL6	0
W6	mmc1_clk	15	12	11	10	mmc1_clk
Y6	mmc1_cmd	15	12	11	10	mmc1_cmd
AA6	mmc1_dat0	15	12	11	10	mmc1_dat0
Y4	mmc1_dat1	15	12	11	10	mmc1_dat1
AA5	mmc1_dat2	15	12	11	10	mmc1_dat2
Y3	mmc1_dat3	15	12	11	10	mmc1_dat3

NOTE

To configure the desired Manual IO Timing Mode the user must follow the steps described in section Manual IO Timing Modes of the Device TRM.

The associated registers to configure are listed in the CFG REGISTER column. For more information see the Control Module chapter in the Device TRM.

Manual IO Timings Modes must be used to guaranteed some IO timings for MMC1. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-101 Manual Functions Mapping for MMC1 for a definition of the Manual modes.

Table 7-101 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-101 Manual Functions Mapping for MMC1

BALL	BALL NAME	MMC1_MANUAL1		MMC1_MANUAL2		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	0
W6	mmc1_clk	588	0	-	-	CFG_MMC1_CLK_IN	mmc1_clk
Y6	mmc1_cmd	1000	0	-	-	CFG_MMC1_CMD_IN	mmc1_cmd
AA6	mmc1_dat0	1375	0	-	-	CFG_MMC1_DAT0_IN	mmc1_dat0
Y4	mmc1_dat1	1000	0	-	-	CFG_MMC1_DAT1_IN	mmc1_dat1
AA5	mmc1_dat2	1000	0	-	-	CFG_MMC1_DAT2_IN	mmc1_dat2
Y3	mmc1_dat3	1000	0	-	-	CFG_MMC1_DAT3_IN	mmc1_dat3

W6	mmc1_clk	1230	0	520	320	CFG_MMC1_CLK_OUT	mmc1_clk
Y6	mmc1_cmd	0	0	0	0	CFG_MMC1_CMD_OUT	mmc1_cmd
AA6	mmc1_dat0	56	0	40	0	CFG_MMC1_DAT0_OUT	mmc1_dat0
Y4	mmc1_dat1	76	0	83	0	CFG_MMC1_DAT1_OUT	mmc1_dat1
AA5	mmc1_dat2	91	0	98	0	CFG_MMC1_DAT2_OUT	mmc1_dat2
Y3	mmc1_dat3	99	0	106	0	CFG_MMC1_DAT3_OUT	mmc1_dat3

Y6	mmc1_cmd	0	0	51	0	CFG_MMC1_CMD_OEN	mmc1_cmd
AA6	mmc1_dat0	0	0	0	0	CFG_MMC1_DAT0_OEN	mmc1_dat0
Y4	mmc1_dat1	0	0	363	0	CFG_MMC1_DAT1_OEN	mmc1_dat1
AA5	mmc1_dat2	0	0	199	0	CFG_MMC1_DAT2_OEN	mmc1_dat2
Y3	mmc1_dat3	0	0	273	0	CFG_MMC1_DAT3_OEN	mmc1_dat3

7.24.2 MMC2 - eMMC

MMC2 interface is compliant with the JC64 eMMC Standard v4.5 and it supports the following eMMC applications:

Standard JC64 SDR, 8-bit data, half cycle
High-speed JC64 SDR, 8-bit data, half cycle
High-speed HS200 JEDS84, 8-bit data, half cycle
High-speed JC64 DDR, 8-bit data

NOTE

For more information, see the eMMC/SD/SDIO chapter of the Device TRM.

7.24.2.1 Standard JC64 SDR, 8-bit data, half cycle

Table 7-102 and Table 7-103 present Timing requirements and Switching characteristics for MMC2 - Standart SDR in receiver and transmitter mode (see Figure 7-75 and Figure 7-76).

Table 7-102 Timing Requirements for MMC2 - JC64 Standard SDR Mode

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
SSDR5	t_{su(cmdV-clkH)}	Setup time, mmc2_cmd valid before mmc2_clk rising clock edge	13.19	ns
SSDR6	t_h(clkH-cmdV)	Hold time, mmc2_cmd valid after mmc2_clk rising clock edge	8.4	ns
SSDR7	t_su(dV-clkH)	Setup time, mmc2_dat[7:0] valid before mmc2_clk rising clock edge	13.19	ns
SSDR8	t_h(clkH-dV)	Hold time, mmc2_dat[7:0] valid after mmc2_clk rising clock edge	8.4	ns

Table 7-103 Switching Characteristics for MMC2 - JC64 Standard SDR Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
SSDR1	fop(clk)	Operating frequency, mmc2_clk		24	MHz
SSDR2H	t_w(clkH)	Pulse duration, mmc2_clk high	0.5*P-0.172 ^⁽¹⁾		ns
SSDR2L	t_w(clkL)	Pulse duration, mmc2_clk low	0.5*P-0.172 ^⁽¹⁾		ns
SSDR3	t_d(clkL-cmdV)	Delay time, mmc2_clk falling clock edge to mmc2_cmd transition	-16.96	16.96	ns
SSDR4	t_d(clkL-dV)	Delay time, mmc2_clk falling clock edge to mmc2_dat[7:0] transition	-16.96	16.96	ns

P = output mmc2_clk period in ns

Figure 7-75 MMC/SD/SDIO in - Standard JC64 - Receiver Mode

Figure 7-76 MMC/SD/SDIO in - Standard JC64 - Transmitter Mode

7.24.2.2 High-speed JC64 SDR, 8-bit data, half cycle

Table 7-104 and Table 7-105 present Timing requirements and Switching characteristics for MMC2 - High speed SDR in receiver and transmitter mode (see Figure 7-77 and Figure 7-78).

Table 7-104 Timing Requirements for MMC2 - JC64 High Speed SDR Mode

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
JC643	t_{su(cmdV-clkH)}	Setup time, mmc2_cmd valid before mmc2_clk rising clock edge	5.6	ns
JC644	t_h(clkH-cmdV)	Hold time, mmc2_cmd valid after mmc2_clk rising clock edge	2.6	ns
JC647	t_su(dV-clkH)	Setup time, mmc2_dat[7:0] valid before mmc2_clk rising clock edge	5.6	ns
JC648	t_h(clkH-dV)	Hold time, mmc2_dat[7:0] valid after mmc2_clk rising clock edge	2.6	ns

Table 7-105 Switching Characteristics for MMC2 - JC64 High Speed SDR Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
JC641	fop(clk)	Operating frequency, mmc2_clk		48	MHz
JC642H	t_w(clkH)	Pulse duration, mmc2_clk high	0.5*P-0.172 ^⁽¹⁾		ns
JC642L	t_w(clkL)	Pulse duration, mmc2_clk low	0.5*P-0.172 ^⁽¹⁾		ns
JC645	t_d(clkL-cmdV)	Delay time, mmc2_clk falling clock edge to mmc2_cmd transition	-6.64	6.64	ns
JC646	t_d(clkL-dV)	Delay time, mmc2_clk falling clock edge to mmc2_dat[7:0] transition	-6.64	6.64	ns

P = output mmc2_clk period in ns

Figure 7-77 MMC/SD/SDIO in - High Speed JC64 - Receiver Mode

Figure 7-78 MMC/SD/SDIO in - High Speed JC64 - Transmitter Mode

7.24.2.3 High-speed HS200 JEDS84, 8-bit data, half cycle

Table 7-106 presents Switching characteristics for MMC2 - HS200 in transmitter mode (see Figure 7-79).

Table 7-106 Switching Characteristics for MMC2 - JEDS84 HS200 Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
HS2001	fop(clk)	Operating frequency, mmc2_clk		192	MHz
HS2002H	t_w(clkH)	Pulse duration, mmc2_clk high	0.5*P-0.172 ^⁽¹⁾		ns
HS2002L	t_w(clkL)	Pulse duration, mmc2_clk low	0.5*P-0.172 ^⁽¹⁾		ns
HS2005	t_d(clkL-cmdV)	Delay time, mmc2_clk falling clock edge to mmc2_cmd transition	-1.136	0.536	ns
HS2006	t_d(clkL-dV)	Delay time, mmc2_clk falling clock edge to mmc2_dat[7:0] transition	-1.136	0.536	ns

P = output mmc2_clk period in ns

Figure 7-79 eMMC in - HS200 SDR - Transmitter Mode

7.24.2.4 High-speed JC64 DDR, 8-bit data

Table 7-107 and Table 7-108 present Timing requirements and Switching characteristics for MMC2 - High speed DDR in receiver and transmitter mode (see Figure 7-80 and Figure 7-81).

Table 7-107 Timing Requirements for MMC2 - JC64 High Speed DDR Mode

NO.	PARAMETER	DESCRIPTION	MODE	MIN	UNIT
DDR3	t_su(cmdV-clk)	Setup time, mmc2_cmd valid before mmc2_clk transition		1.8	ns
DDR4	t_h(clk-cmdV)	Hold time, mmc2_cmd valid after mmc2_clk transition		1.6	ns
DDR7	t_su(dV-clk)	Setup time, mmc2_dat[7:0] valid before mmc2_clk transition		1.8	ns
DDR8	t_h(clk-dV)	Hold time, mmc2_dat[7:0] valid after mmc2_clk transition	Pad Loopback (1.8V and 3.3V), Boot	1.6	ns
			Internal Loopback (1.8V with MMC2_VIRTUAL2)	1.86	ns
			Internal Loopback (3.3V with MMC2_VIRTUAL2)	1.95	ns
			Internal Loopback (1.8V with MMC2_MANUAL2)		ns
			Internal Loopback (3.3V with MMC2_MANUAL2)	1.6	ns

Table 7-108 Switching Characteristics for MMC2 - JC64 High Speed DDR Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
DDR1	fop(clk)	Operating frequency, mmc2_clk		48	MHz
DDR2H	t_w(clkH)	Pulse duration, mmc2_clk high	0.5*P-0.172	^⁽¹⁾	ns
DDR2L	t_w(clkL)	Pulse duration, mmc2_clk low	0.5*P-0.172	^⁽¹⁾	ns
DDR5	t_d(clk-cmdV)	Delay time, mmc2_clk transition to mmc2_cmd transition	2.9	7.14	ns
DDR6	t_d(clk-dV)	Delay time, mmc2_clk transition to mmc2_dat[7:0] transition	2.9	7.14	ns

P = output mmc2_clk period in ns

Figure 7-80 MMC/SD/SDIO in - High Speed DDR JC64 - Receiver Mode

Figure 7-81 MMC/SD/SDIO in - High Speed DDR JC64 - Transmitter Mode

NOTE

To configure the desired virtual mode the user must set MODESELECT bit and DELAYMODE bitfield for each corresponding pad control register.

The pad control registers are presented in Table 4-3 and described in Device TRM, Control Module Chapter.

Virtual IO Timings Modes must be used to guaranteed some IO timings for MMC2. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Virtual IO Timings Modes. See Table 7-109 Virtual Functions Mapping for MMC2 for a definition of the Virtual modes.

Table 7-109 presents the values for DELAYMODE bitfield.

Table 7-109 Virtual Functions Mapping for MMC2

BALL	BALL NAME	Delay Mode Value	MUXMODE
BALL	BALL NAME	MMC2_VIRTUAL2	1
H6	gpmc_cs1	13	mmc2_cmd
K7	gpmc_a19	13	mmc2_dat4
M7	gpmc_a20	13	mmc2_dat5
J5	gpmc_a21	13	mmc2_dat6
K6	gpmc_a22	13	mmc2_dat7
J7	gpmc_a23	13	mmc2_clk
J4	gpmc_a24	13	mmc2_dat0
J6	gpmc_a25	13	mmc2_dat1
H4	gpmc_a26	13	mmc2_dat2
H5	gpmc_a27	13	mmc2_dat3

NOTE

To configure the desired Manual IO Timing Mode the user must follow the steps described in section Manual IO Timing Modes of the Device TRM.

The associated registers to configure are listed in the CFG REGISTER column. For more information see the Control Module chapter in the Device TRM.

Manual IO Timings Modes must be used to guaranteed some IO timings for MMC2. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-110 Manual Functions Mapping for MMC2 for a definition of the Manual modes.

Table 7-110 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-110 Manual Functions Mapping for MMC2

BALL	BALL NAME	MMC2_MANUAL1		MMC2_MANUAL2		MMC2_MANUAL3		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	A_DELAY (ps)	G_DELAY (ps)	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	1
K7	gpmc_a19	0	0	0	14	-	-	CFG_GPMC_A19_IN	mmc2_dat4
M7	gpmc_a20	119	0	127	0	-	-	CFG_GPMC_A20_IN	mmc2_dat5
J5	gpmc_a21	0	0	22	0	-	-	CFG_GPMC_A21_IN	mmc2_dat6
K6	gpmc_a22	18	0	72	0	-	-	CFG_GPMC_A22_IN	mmc2_dat7
J7	gpmc_a23	894	0	410	4000	-	-	CFG_GPMC_A23_IN	mmc2_clk
J4	gpmc_a24	30	0	82	0	-	-	CFG_GPMC_A24_IN	mmc2_dat0
J6	gpmc_a25	0	0	0	0	-	-	CFG_GPMC_A25_IN	mmc2_dat1
H4	gpmc_a26	23	0	77	0	-	-	CFG_GPMC_A26_IN	mmc2_dat2
H5	gpmc_a27	0	0	0	0	-	-	CFG_GPMC_A27_IN	mmc2_dat3
H6	gpmc_cs1	0	0	0	0	-	-	CFG_GPMC_CS1_IN	mmc2_cmd

K7	gpmc_a19	152	0	152	0	285	0	CFG_GPMC_A19_OUT	mmc2_dat4
M7	gpmc_a20	206	0	206	0	189	0	CFG_GPMC_A20_OUT	mmc2_dat5
J5	gpmc_a21	78	0	78	0	0	120	CFG_GPMC_A21_OUT	mmc2_dat6
K6	gpmc_a22	2	0	2	0	0	70	CFG_GPMC_A22_OUT	mmc2_dat7
J7	gpmc_a23	266	0	266	0	730	360	CFG_GPMC_A23_OUT	mmc2_clk
J4	gpmc_a24	0	0	0	0	0	0	CFG_GPMC_A24_OUT	mmc2_dat0
J6	gpmc_a25	0	0	0	0	0	0	CFG_GPMC_A25_OUT	mmc2_dat1
H4	gpmc_a26	43	0	43	0	70	0	CFG_GPMC_A26_OUT	mmc2_dat2
H5	gpmc_a27	0	0	0	0	0	0	CFG_GPMC_A27_OUT	mmc2_dat3
H6	gpmc_cs1	0	0	0	0	0	120	CFG_GPMC_CS1_OUT	mmc2_cmd

K7	gpmc_a19	0	0	0	0	0	0	CFG_GPMC_A19_OEN	mmc2_dat4
M7	gpmc_a20	0	0	0	0	231	0	CFG_GPMC_A20_OEN	mmc2_dat5
J5	gpmc_a21	0	0	0	0	39	0	CFG_GPMC_A21_OEN	mmc2_dat6
K6	gpmc_a22	0	0	0	0	91	0	CFG_GPMC_A22_OEN	mmc2_dat7
J4	gpmc_a24	0	0	0	0	176	0	CFG_GPMC_A24_OEN	mmc2_dat0
J6	gpmc_a25	0	0	0	0	0	0	CFG_GPMC_A25_OEN	mmc2_dat1
H4	gpmc_a26	0	0	0	0	101	0	CFG_GPMC_A26_OEN	mmc2_dat2
H5	gpmc_a27	0	0	0	0	0	0	CFG_GPMC_A27_OEN	mmc2_dat3
H6	gpmc_cs1	0	0	0	0	360	0	CFG_GPMC_CS1_OEN	mmc2_cmd

7.24.3 MMC3 and MMC4-SDIO/SD

MMC3 and MMC4 interfaces are compliant with the SDIO3.0 standard v1.0, SD Part E1 and for generic SDIO devices, it supports the following applications:

MMC3 8-bit data and MMC4 4-bit data, SD Default speed, SDR
MMC3 8-bit data and MMC4 4-bit data, SD High speed, SDR
MMC3 8-bit data and MMC4 4-bit data, UHS-1 SDR12 (SD Standard v3.01), 4-bit data, SDR, half cycle
MMC3 8-bit data and MMC4 4-bit data, UHS-I SDR25 (SD Standard v3.01), 4-bit data, SDR, half cycle
MMC3 8-bit data, UHS-I SDR50

NOTE

The eMMC/SD/SDIOj (j = 3 to 4) controller is also referred to as MMCj.

NOTE

For more information, see the MMC/SDIO chapter of the Device TRM.

7.24.3.1 MMC3 and MMC4, SD Default Speed

Figure 7-82, Figure 7-83, and Table 7-111 through Table 7-114 present Timing requirements and Switching characteristics for MMC3 and MMC4 - SD Default speed in receiver and transmitter mode.

Table 7-111 Timing Requirements for MMC3 - Default Speed Mode ^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
DS5	t_{su(cmdV-clkH)}	Setup time, mmc3_cmd valid before mmc3_clk rising clock edge	5.11	ns
DS6	t_h(clkH-cmdV)	Hold time, mmc3_cmd valid after mmc3_clk rising clock edge	20.46	ns
DS7	t_su(dV-clkH)	Setup time, mmc3_dat[i:0] valid before mmc3_clk rising clock edge	5.11	ns
DS8	t_h(clkH-dV)	Hold time, mmc3_dat[i:0] valid after mmc3_clk rising clock edge	20.46	ns

i in [i:0] = 7

Table 7-112 Switching Characteristics for MMC3 - SD/SDIO Default Speed Mode ^⁽²⁾

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
DS0	fop(clk)	Operating frequency, mmc3_clk		24	MHz
DS1	t_w(clkH)	Pulse duration, mmc3_clk high	0.5*P-0.270 ^⁽¹⁾		ns
DS2	t_w(clkL)	Pulse duration, mmc3_clk low	0.5*P-0.270 ^⁽¹⁾		ns
DS3	t_d(clkL-cmdV)	Delay time, mmc3_clk falling clock edge to mmc3_cmd transition	-14.93	14.93	ns
DS4	t_d(clkL-dV)	Delay time, mmc3_clk falling clock edge to mmc3_dat[i:0] transition	-14.93	14.93	ns

P = output mmc3_clk period in ns
i in [i:0] = 7

Table 7-113 Timing Requirements for MMC4 - Default Speed Mode ^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
DS5	t_{su(cmdV-clkH)}	Setup time, mmc4_cmd valid before mmc4_clk rising clock edge	5.11	ns
DS6	t_h(clkH-cmdV)	Hold time, mmc4_cmd valid after mmc4_clk rising clock edge	20.46	ns
DS7	t_su(dV-clkH)	Setup time, mmc4_dat[i:0] valid before mmc4_clk rising clock edge	5.11	ns
DS8	t_h(clkH-dV)	Hold time, mmc4_dat[i:0] valid after mmc4_clk rising clock edge	20.46	ns

i in [i:0] = 3

Table 7-114 Switching Characteristics for MMC4 - Default Speed Mode ^⁽²⁾

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
DS0	fop(clk)	Operating frequency, mmc4_clk		24	MHz
DS1	t_w(clkH)	Pulse duration, mmc4_clk high	0.5*P-0.270 ^⁽¹⁾		ns
DS2	t_w(clkL)	Pulse duration, mmc4_clk low	0.5*P-0.270 ^⁽¹⁾		ns
DS3	t_d(clkL-cmdV)	Delay time, mmc4_clk falling clock edge to mmc4_cmd transition	-14.93	14.93	ns
DS4	t_d(clkL-dV)	Delay time, mmc4_clk falling clock edge to mmc4_dat[i:0] transition	-14.93	14.93	ns

P = output mmc4_clk period in ns
i in [i:0] = 3

Figure 7-82 MMC/SD/SDIOj in - Default Speed - Receiver Mode

Figure 7-83 MMC/SD/SDIOj in - Default Speed - Transmitter Mode

7.24.3.2 MMC3 and MMC4, SD High Speed

Figure 7-84, Figure 7-85, and Table 7-115 through Table 7-118 present Timing requirements and Switching characteristics for MMC3 and MMC4 - SD and SDIO High speed in receiver and transmitter mode.

Table 7-115 Timing Requirements for MMC3 - SD/SDIO High Speed Mode ^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
HS3	t_{su(cmdV-clkH)}	Setup time, mmc3_cmd valid before mmc3_clk rising clock edge	5.3	ns
HS4	t_h(clkH-cmdV)	Hold time, mmc3_cmd valid after mmc3_clk rising clock edge	2.6	ns
HS7	t_su(dV-clkH)	Setup time, mmc3_dat[i:0] valid before mmc3_clk rising clock edge	5.3	ns
HS8	t_h(clkH-dV)	Hold time, mmc3_dat[i:0] valid after mmc3_clk rising clock edge	2.6	ns

i in [i:0] = 7

Table 7-116 Switching Characteristics for MMC3 - SD/SDIO High Speed Mode ^⁽²⁾

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
HS1	fop(clk)	Operating frequency, mmc3_clk		48	MHz
HS2H	t_w(clkH)	Pulse duration, mmc3_clk high	0.5*P-0.270 ^⁽¹⁾		ns
HS2L	t_w(clkL)	Pulse duration, mmc3_clk low	0.5*P-0.270 ^⁽¹⁾		ns
HS5	t_d(clkL-cmdV)	Delay time, mmc3_clk falling clock edge to mmc3_cmd transition	-7.6	3.6	ns
HS6	t_d(clkL-dV)	Delay time, mmc3_clk falling clock edge to mmc3_dat[i:0] transition	-7.6	3.6	ns

P = output mmc3_clk period in ns
i in [i:0] = 7

Table 7-117 Timing Requirements for MMC4 - High Speed Mode ^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
HS3	t_{su(cmdV-clkH)}	Setup time, mmc4_cmd valid before mmc4_clk rising clock edge	5.3	ns
HS4	t_h(clkH-cmdV)	Hold time, mmc4_cmd valid after mmc4_clk rising clock edge	1.6	ns
HS7	t_su(dV-clkH)	Setup time, mmc4_dat[i:0] valid before mmc4_clk rising clock edge	5.3	ns
HS8	t_h(clkH-dV)	Hold time, mmc4_dat[i:0] valid after mmc4_clk rising clock edge	1.6	ns

i in [i:0] = 3

Table 7-118 Switching Characteristics for MMC4 - High Speed Mode ^⁽²⁾

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
HS1	fop(clk)	Operating frequency, mmc4_clk		48	MHz
HS2H	t_w(clkH)	Pulse duration, mmc4_clk high	0.5*P-0.270 ^⁽¹⁾		ns
HS2L	t_w(clkL)	Pulse duration, mmc4_clk low	0.5*P-0.270 ^⁽¹⁾		ns
HS5	t_d(clkL-cmdV)	Delay time, mmc4_clk falling clock edge to mmc4_cmd transition	-8.8	6.6	ns
HS6	t_d(clkL-dV)	Delay time, mmc4_clk falling clock edge to mmc4_dat[i:0] transition	-8.8	6.6	ns

P = output mmc4_clk period in ns
i in [i:0] = 3

Figure 7-84 MMC/SD/SDIOj in - High Speed Signaling - Receiver Mode

Figure 7-85 MMC/SD/SDIOj in - High Speed Signaling - Transmitter Mode

7.24.3.3 MMC3 and MMC4, SD and SDIO SDR12 Mode

Figure 7-86, Figure 7-87, and Table 7-119, through Table 7-122 present Timing requirements and Switching characteristics for MMC3 and MMC4 - SD and SDIO SDR12 in receiver and transmitter mode.

Table 7-119 Timing Requirements for MMC3 - SDR12 Mode ^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
SDR125	t_{su(cmdV-clkH)}	Setup time, mmc3_cmd valid before mmc3_clk rising clock edge	25.99	ns
SDR126	t_h(clkH-cmdV)	Hold time, mmc3_cmd valid after mmc3_clk rising clock edge	1.6	ns
SDR127	t_su(dV-clkH)	Setup time, mmc3_dat[i:0] valid before mmc3_clk rising clock edge	25.99	ns
SDR128	t_h(clkH-dV)	Hold time, mmc3_dat[i:0] valid after mmc3_clk rising clock edge	1.6	ns

i in [i:0] = 7

Table 7-120 Switching Characteristics for MMC3 - SDR12 Mode ^⁽²⁾

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
SDR120	fop(clk)	Operating frequency, mmc3_clk		24	MHz
SDR121	t_w(clkH)	Pulse duration, mmc3_clk high	0.5*P-0.270 ^⁽¹⁾		ns
SDR122	t_w(clkL)	Pulse duration, mmc3_clk low	0.5*P-0.270 ^⁽¹⁾		ns
SDR123	t_d(clkL-cmdV)	Delay time, mmc3_clk falling clock edge to mmc3_cmd transition	-19.13	16.93	ns
SDR124	t_d(clkL-dV)	Delay time, mmc3_clk falling clock edge to mmc3_dat[i:0] transition	-19.13	16.93	ns

P = output mmc3_clk period in ns
i in [i:0] = 7

Table 7-121 Timing Requirements for MMC4 - SDR12 Mode ^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
SDR125	t_{su(cmdV-clkH)}	Setup time, mmc4_cmd valid before mmc4_clk rising clock edge	25.99	ns
SDR126	t_h(clkH-cmdV)	Hold time, mmc4_cmd valid after mmc4_clk rising clock edge	1.6	ns
SDR127	t_su(dV-clkH)	Setup time, mmc4_dat[i:0] valid before mmc4_clk rising clock edge	25.99	ns
SDR128	t_h(clkH-dV)	Hold time, mmc4_dat[i:0] valid after mmc4_clk rising clock edge	1.6	ns

j in [i:0] = 3

Table 7-122 Switching Characteristics for MMC4 - SDR12 Mode ^⁽²⁾

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
SDR120	fop(clk)	Operating frequency, mmc4_clk		24	MHz
SDR121	t_w(clkH)	Pulse duration, mmc4_clk high	0.5*P-0.270 ^⁽¹⁾		ns
SDR122	t_w(clkL)	Pulse duration, mmc4_clk low	0.5*P-0.270 ^⁽¹⁾		ns
SDR125	t_d(clkL-cmdV)	Delay time, mmc4_clk falling clock edge to mmc4_cmd transition	-19.13	16.93	ns
SDR126	t_d(clkL-dV)	Delay time, mmc4_clk falling clock edge to mmc4_dat[i:0] transition	-19.13	16.93	ns

P = output mmc4_clk period in ns
j in [i:0] = 3

Figure 7-86 MMC/SD/SDIOj in - SDR12 - Receiver Mode

Figure 7-87 MMC/SD/SDIOj in - SDR12 - Transmitter Mode

7.24.3.4 MMC3 and MMC4, SD SDR25 Mode

Figure 7-88, Figure 7-89, and Table 7-123, through Table 7-126 present Timing requirements and Switching characteristics for MMC3 and MMC4 - SD and SDIO SDR25 in receiver and transmitter mode.

Table 7-123 Timing Requirements for MMC3 - SDR25 Mode ^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
SDR253	t_{su(cmdV-clkH)}	Setup time, mmc3_cmd valid before mmc3_clk rising clock edge	5.3	ns
SDR254	t_h(clkH-cmdV)	Hold time, mmc3_cmd valid after mmc3_clk rising clock edge	1.6	ns
SDR257	t_su(dV-clkH)	Setup time, mmc3_dat[i:0] valid before mmc3_clk rising clock edge	5.3	ns
SDR258	t_h(clkH-dV)	Hold time, mmc3_dat[i:0] valid after mmc3_clk rising clock edge	1.6	ns

i in [i:0] = 7

Table 7-124 Switching Characteristics for MMC3 - SDR25 Mode ^⁽²⁾

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
SDR251	fop(clk)	Operating frequency, mmc3_clk		48	MHz
SDR252H	t_w(clkH)	Pulse duration, mmc3_clk high	0.5*P-0.270 ^⁽¹⁾		ns
SDR252L	t_w(clkL)	Pulse duration, mmc3_clk low	0.5*P-0.270 ^⁽¹⁾		ns
SDR255	t_d(clkL-cmdV)	Delay time, mmc3_clk falling clock edge to mmc3_cmd transition	-8.8	6.6	ns
SDR256	t_d(clkL-dV)	Delay time, mmc3_clk falling clock edge to mmc3_dat[i:0] transition	-8.8	6.6	ns

P = output mmc3_clk period in ns
i in [i:0] = 7

Table 7-125 Timing Requirements for MMC4 - SDR25 Mode ^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
SDR255	t_{su(cmdV-clkH)}	Setup time, mmc4_cmd valid before mmc4_clk rising clock edge	5.3	ns
SDR256	t_h(clkH-cmdV)	Hold time, mmc4_cmd valid after mmc4_clk rising clock edge	1.6	ns
SDR257	t_su(dV-clkH)	Setup time, mmc4_dat[i:0] valid before mmc4_clk rising clock edge	5.3	ns
SDR258	t_h(clkH-dV)	Hold time, mmc4_dat[i:0] valid after mmc4_clk rising clock edge	1.6	ns

i in [i:0] = 3

Table 7-126 Switching Characteristics for MMC4 - SDR25 Mode ^⁽²⁾

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
SDR251	fop(clk)	Operating frequency, mmc4_clk		48	MHz
SDR252H	t_w(clkH)	Pulse duration, mmc4_clk high	0.5*P-0.270 ^⁽¹⁾		ns
SDR252L	t_w(clkL)	Pulse duration, mmc4_clk low	0.5*P-0.270 ^⁽¹⁾		ns
SDR255	t_d(clkL-cmdV)	Delay time, mmc4_clk falling clock edge to mmc4_cmd transition	-8.8	6.6	ns
SDR256	t_d(clkL-dV)	Delay time, mmc4_clk falling clock edge to mmc4_dat[i:0] transition	-8.8	6.6	ns

P = output mmc4_clk period in ns
i in [i:0] = 3

Figure 7-88 MMC/SD/SDIOj in - SDR25 - Receiver Mode

Figure 7-89 MMC/SD/SDIOj in - SDR25 - Transmitter Mode

7.24.3.5 MMC3 SDIO High-Speed UHS-I SDR50 Mode, Half Cycle

Figure 7-90, Figure 7-91, Table 7-127, and Table 7-128 present Timing requirements and Switching characteristics for MMC3 - SDIO High speed SDR50 in receiver and transmitter mode.

Table 7-127 Timing Requirements for MMC3 - SDR50 Mode ^⁽¹⁾

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
SDR503	t_{su(cmdV-clkH)}	Setup time, mmc3_cmd valid before mmc3_clk rising clock edge	1.48	ns
SDR504	t_h(clkH-cmdV)	Hold time, mmc3_cmd valid after mmc3_clk rising clock edge	1.6	ns
SDR507	t_su(dV-clkH)	Setup time, mmc3_dat[i:0] valid before mmc3_clk rising clock edge	1.48	ns
SDR508	t_h(clkH-dV)	Hold time, mmc3_dat[i:0] valid after mmc3_clk rising clock edge	1.6	ns

i in [i:0] = 7

Table 7-128 Switching Characteristics for MMC3 - SDR50 Mode ^⁽²⁾

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
SDR501	fop(clk)	Operating frequency, mmc3_clk		64	MHz
SDR502H	t_w(clkH)	Pulse duration, mmc3_clk high	0.5*P-0.270 ^⁽¹⁾		ns
SDR502L	t_w(clkL)	Pulse duration, mmc3_clk low	0.5*P-0.270 ^⁽¹⁾		ns
SDR505	t_d(clkL-cmdV)	Delay time, mmc3_clk falling clock edge to mmc3_cmd transition	-3.66	1.46	ns
SDR506	t_d(clkL-dV)	Delay time, mmc3_clk falling clock edge to mmc3_dat[i:0] transition	-3.66	1.46	ns

P = output mmc3_clk period in ns
i in [i:0] = 7

Figure 7-90 MMC/SD/SDIOj in - High Speed SDR50 - Receiver Mode

Figure 7-91 MMC/SD/SDIOj in - High Speed SDR50 - Transmitter Mode

NOTE

To configure the desired Manual IO Timing Mode the user must follow the steps described in section Manual IO Timing Modes of the Device TRM.

The associated registers to configure are listed in the CFG REGISTER column. For more information see the Control Module chapter in the Device TRM.

Manual IO Timings Modes must be used to guaranteed some IO timings for MMC3. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-129 Manual Functions Mapping for MMC3 for a definition of the Manual modes.

Table 7-129 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-129 Manual Functions Mapping for MMC3

BALL	BALL NAME	MMC3_MANUAL1		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	0
AD4	mmc3_clk	1085	21	CFG_MMC3_CLK_IN	mmc3_clk
AD4	mmc3_clk	1269	0	CFG_MMC3_CLK_OUT	mmc3_clk
AC4	mmc3_cmd	0	0	CFG_MMC3_CMD_IN	mmc3_cmd
AC4	mmc3_cmd	128	0	CFG_MMC3_CMD_OEN	mmc3_cmd
AC4	mmc3_cmd	98	0	CFG_MMC3_CMD_OUT	mmc3_cmd
AC7	mmc3_dat0	0	0	CFG_MMC3_DAT0_IN	mmc3_dat0
AC7	mmc3_dat0	362	0	CFG_MMC3_DAT0_OEN	mmc3_dat0
AC7	mmc3_dat0	0	0	CFG_MMC3_DAT0_OUT	mmc3_dat0
AC6	mmc3_dat1	7	0	CFG_MMC3_DAT1_IN	mmc3_dat1
AC6	mmc3_dat1	333	0	CFG_MMC3_DAT1_OEN	mmc3_dat1
AC6	mmc3_dat1	0	0	CFG_MMC3_DAT1_OUT	mmc3_dat1
AC9	mmc3_dat2	0	0	CFG_MMC3_DAT2_IN	mmc3_dat2
AC9	mmc3_dat2	402	0	CFG_MMC3_DAT2_OEN	mmc3_dat2
AC9	mmc3_dat2	0	0	CFG_MMC3_DAT2_OUT	mmc3_dat2
AC3	mmc3_dat3	203	0	CFG_MMC3_DAT3_IN	mmc3_dat3
AC3	mmc3_dat3	549	0	CFG_MMC3_DAT3_OEN	mmc3_dat3
AC3	mmc3_dat3	1	0	CFG_MMC3_DAT3_OUT	mmc3_dat3
AC8	mmc3_dat4	121	0	CFG_MMC3_DAT4_IN	mmc3_dat4
AC8	mmc3_dat4	440	0	CFG_MMC3_DAT4_OEN	mmc3_dat4
AC8	mmc3_dat4	206	0	CFG_MMC3_DAT4_OUT	mmc3_dat4
AD6	mmc3_dat5	336	0	CFG_MMC3_DAT5_IN	mmc3_dat5
AD6	mmc3_dat5	283	0	CFG_MMC3_DAT5_OEN	mmc3_dat5
AD6	mmc3_dat5	174	0	CFG_MMC3_DAT5_OUT	mmc3_dat5
AB8	mmc3_dat6	320	0	CFG_MMC3_DAT6_IN	mmc3_dat6
AB8	mmc3_dat6	443	0	CFG_MMC3_DAT6_OEN	mmc3_dat6
AB8	mmc3_dat6	0	0	CFG_MMC3_DAT6_OUT	mmc3_dat6
AB5	mmc3_dat7	2	0	CFG_MMC3_DAT7_IN	mmc3_dat7
AB5	mmc3_dat7	344	0	CFG_MMC3_DAT7_OEN	mmc3_dat7
AB5	mmc3_dat7	0	0	CFG_MMC3_DAT7_OUT	mmc3_dat7

NOTE

To configure the desired virtual mode the user must set MODESELECT bit and DELAYMODE bitfield for each corresponding pad control register.

The pad control registers are presented in Table 4-3 and described in Device TRM, Control Module Chapter.

7.25 General-Purpose Interface (GPIO)

The general-purpose interface combines eight general-purpose input/output (GPIO) banks. Each GPIO module provides up to 32 dedicated general-purpose pins with input and output capabilities; thus, the general-purpose interface supports up to 215 pins.

These pins can be configured for the following applications:

Data input (capture)/output (drive)
Keyboard interface with a debounce cell
Interrupt generation in active mode upon the detection of external events. Detected events are processed by two parallel independent interrupt-generation submodules to support biprocessor operations
Wake-up request generation in idle mode upon the detection of external events

NOTE

For more information, see the General-Purpose Interface chapter of the Device TRM.

NOTE

The general-purpose input/output i (i = 1 to 8) bank is also referred to as GPIOi.

7.26 PRU-ICSS Interfaces

The device Programmable Real-Time Unit Subsystem and Industrial Communication Subsystem (PRU-ICSS) consists of dual 32-bit Load / Store RISC CPU cores - Programmable Real-Time Units (PRU0 and PRU1), shared, data, and instruction memories, internal peripheral modules, and an interrupt controller (PRU-ICSS_INTC). The programmable nature of the PRUs, along with their access to pins, events and all SoC resources, provides flexibility in implementing fast real-time responses, specialized data handling operations, customer peripheral interfaces, and in off-loading tasks from the other processor cores of the system-on-chip (SoC).

The each PRU-ICSS includes the following main features:

21x Enhanced GPIs (EGPIs) and 21x Enhanced GPOs (EGPOs) with asynchronous capture and serial support per each PRU CPU core
One Ethernet MII_RT module (PRU-ICSS_MII_RT) with two MII ports and configurable connections to PRUs
1 MDIO Port (PRU-ICSS_MII_MDIO)
One Industrial Ethernet Peripheral (IEP) to manage/generate Industrial Ethernet functions
1 x 16550-compatible UART with a dedicated 192 MHz clock to support 12Mbps Profibus
1 Industrial Ethernet timer with 7/9 capture and 8 compare events
1 Enhanced Capture Module (ECAP)
1 Interrupt Controller (PRU-ICSS_INTC)
A flexible power management support
Integrated switched central resource with programmable priority
Parity control supported by all memories

CAUTION

The I/O timings provided in this section are valid only if signals within a single IOSET are used. The IOSETs are defined in the Table 7-152 and Table 7-153.

NOTE

For more information about PRU-ICSS subsystems interfaces, please see the device TRM.

NOTE

To configure the desired virtual mode the user must set MODESELECT bit and DELAYMODE bitfield for each corresponding pad control register.

The pad control registers are presented in Table 4-3 and described in Device TRM, Control Module Chapter.

7.26.1 Programmable Real-Time Unit (PRU-ICSS PRU)

7.26.1.1 PRU-ICSS PRU Direct Input/Output Mode Electrical Data and Timing

Table 7-130 PRU-ICSS PRU Timing Requirements - Direct Input Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
1	t_w(GPI)	Pulse width, GPI	2*P ^⁽¹⁾		ns
2	t_sk(GPI)	Skew between GPI[20:0] signals		4.5	ns

ICSS_CLK clock period

Figure 7-92 PRU-ICSS PRU Direct Input Timing

m in GPI[m:0] = 20

Table 7-131 PRU-ICSS PRU Switching Requirements - Direct Output Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
1	t_w(GPO)	Pulse width, GPO	2*P ^⁽¹⁾		ns
2	t_sk(GPO)	Skew between GPO[20:0] signals		4.5	ns

ICSS_CLK clock period

Figure 7-93 PRU-ICSS PRU Direct Output Timing

n in GPO[n:0] = 20

7.26.1.2 PRU-ICSS PRU Parallel Capture Mode Electrical Data and Timing

Table 7-132 PRU-ICSS PRU Timing Requirements - Parallel Capture Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
1	t_w(CLOCKIN)	Cyle time, CLOCKIN	20		ns
2	t_{w(CLOCKIN_L)}	Pulse duration, CLOCKIN low	9	11	ns
3	t_{w(CLOCKIN_H)}	Pulse duration, CLOCKIN high	9	11	ns
4	t_{su(DATAIN-CLOCKIN)}	Setup time, DATAIN valid before CLOCKIN	4.5		ns
5	t_{h(CLOCKIN-DATAIN)}	Hold time, DATAIN valid after CLOCKIN	0		ns

Figure 7-94 PRU-ICSS PRU Parallel Capture Timing - Rising Edge Mode

Figure 7-95 PRU-ICSS PRU Parallel Capture Timing - Falling Edge Mode

7.26.1.3 PRU-ICSS PRU Shift Mode Electrical Data and Timing

Table 7-133 PRU-ICSS PRU Timing Requirements - Shift In Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
1	t_c(DATAIN)	Cycle time, DATAIN	10.00		ns
2	t_w(DATAIN)	Pulse width, DATAIN	0.45*P ^⁽¹⁾		ns

P = 10.00ns

Figure 7-96 PRU-ICSS PRU Shift In Timing

Table 7-134 PRU-ICSS PRU Switching Requirements - Shift Out Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
1	t_c(CLOCKOUT)	Cycle time, CLOCKOUT	10.00		ns
2	t_w(CLOCKOUT)	Pulse width, CLOCKOUT	0.45*P ^⁽¹⁾		ns
3	t_{d(CLOCKOUT-DATAOUT)}	Delay time, CLOCKOUT to DATAOUT Valid	-3.00	3.60	ns

P = 10.00ns

Figure 7-97 PRU-ICSS PRU Shift Out Timing

7.26.1.4 PRU-ICSS PRU Sigma Delta and EnDAT Modes

Table 7-135 PRU-ICSS PRU Timing Requirements - Sigma Delta Mode

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
1	tw(SDx_CLK)	Pulse width, SDx_CLK	20	ns
2	tsu(SDx_D-SDx_CLK)	Setup time, SDx_D valid before SDx_CLK active edge	10	ns
3	th(SDx_CLK-SDx_D)	Hold time, SDx_D valid before SDx_CLK active edge	5	ns

Figure 7-98 PRU-ICSS PRU SD_CLK Falling Active Edge

Figure 7-99 PRU-ICSS PRU SD_CLK Rising Active Edge

Table 7-136 PRU-ICSS PRU Timing Requirements - EnDAT Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
1	tw(ENDATx_IN)	Pulse width, ENDATx_IN	40		ns

Table 7-137 PRU-ICSS PRU Switching Requirements - EnDAT Mode

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
2	tw(ENDATx_CLK)	Pulse width, ENDATx_CLK	20		ns
3	td(ENDATx_OUT-ENDATx_CLK)	Delay time, ENDATx_CLK fall to ENDATx_OUT	-10	10	ns
4	td(ENDATx_OUT_EN-ENDATx_CLK)	Delay time, ENDATx_CLK Fall to ENDATx_OUT_EN	-10	10	ns

Figure 7-100 PRU-ICSS PRU EnDAT Timing

7.26.2 PRU-ICSS EtherCAT (PRU-ICSS ECAT)

7.26.2.1 PRU-ICSS ECAT Electrical Data and Timing

Table 7-138 PRU-ICSS ECAT Timing Requirements - Input Validated With LATCH_IN

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
1	t_{w(EDIO_LATCH_IN)}	Pulse width, EDIO_LATCH_IN	100.00	ns
2	t_{su(EDIO_DATA_IN-EDIO_LATCH_IN)}	Setup time, EDIO_DATA_IN valid before EDIO_LATCH_IN active edge	20.00	ns
3	t_{h(EDIO_LATCH_IN-EDIO_DATA_IN)}	Hold time, EDIO_DATA_IN valid after EDIO_LATCH_IN active edge	20.00	ns

AM5718-HIREL SPRS91x_TIMING_PRU_ECAT_01.gif

Figure 7-101 PRU-ICSS ECAT Input Validated with LATCH_IN Timing

Table 7-139 PRU-ICSS ECAT Timing Requirements - Input Validated With SYNCx

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
1	t_{w(EDC_SYNCx_OUT)}	Pulse width, EDC_SYNCx_OUT	100.00	ns
2	t_{su(EDIO_DATA_IN-EDC_SYNCx_OUT)}	Setup time, EDIO_DATA_IN valid before EDC_SYNCx_OUT active edge	20.00	ns
3	t_{h(EDC_SYNCx_OUT-EDIO_DATA_IN)}	Hold time, EDIO_DATA_IN valid after EDC_SYNCx_OUT active edge	20.00	ns

AM5718-HIREL SPRS91x_TIMING_PRU_ECAT_02.gif

Figure 7-102 PRU-ICSS ECAT Input Validated With SYNCx Timing

Table 7-140 PRU-ICSS ECAT Timing Requirements - Input Validated With Start of Frame (SOF)

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
1	t_{w(EDIO_SOF)}	Pulse duration, EDIO_SOF	4*P ^⁽¹⁾	5*P ^⁽¹⁾	ns
2	t_{su(EDIO_DATA_IN-EDIO_SOF)}	Setup time, EDIO_DATA_IN valid before EDIO_SOF active edge	20.00		ns
3	t_{h(EDIO_SOF-EDIO_DATA_IN)}	Hold time, EDIO_DATA_IN valid after EDIO_SOF active edge	20.00		ns

ICSS_IEP_CLK clock period

AM5718-HIREL SPRS91x_TIMING_PRU_ECAT_03.gif

Figure 7-103 PRU-ICSS ECAT Input Validated With SOF

Table 7-141 PRU-ICSS ECAT Timing Requirements - LATCHx_IN

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
1	t_{w(EDC_LATCHx_IN)}	Pulse duration, EDC_LATCHx_IN	3*P ^⁽¹⁾		ns

ICSS_IEP_CLK clock period

AM5718-HIREL SPRS91x_TIMING_PRU_ECAT_04.gif

Figure 7-104 PRU-ICSS ECAT LATCHx_IN Timing

Table 7-142 PRU-ICSS ECAT Switching Requirements - Digital IOs

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
1	t_{w(EDIO_OUTVALID)}	Pulse duration, EDIO_OUTVALID	14*P ^⁽¹⁾	32*P ^⁽¹⁾	ns
2	t_{d(EDIO_OUTVALID-EDIO_DATA_OUT)}	Delay time, EDIO_OUTVALID to EDIO_DATA_OUT	0.00	18 × P ^⁽¹⁾	ns
1	t_{sk(EDIO_DATA_OUT)}	EDIO_DATA_OUT skew		8	ns

ICSS_IEP_CLK clock period

7.26.3 PRU-ICSS MII_RT and Switch

7.26.3.1 PRU-ICSS MDIO Electrical Data and Timing

Table 7-143 PRU-ICSS MDIO Timing Requirements - MDIO_DATA

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
1	t_su(MDIO-MDC)	Setup time, MDIO valid before MDC high	90		ns
2	t_h(MDIO-MDC)	Hold time, MDIO valid from MDC high	0		ns

AM5718-HIREL SPRS91x_TIMING_PRU_MII_RT_01.gif

Figure 7-105 PRU-ICSS MDIO_DATA Timing - Input Mode

Table 7-144 PRU-ICSS MDIO Switching Characteristics - MDIO_CLK

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
1	t_c(MDC)	Cycle time, MDC	400		ns
2	t_w(MDCH)	Pulse duration, MDC high	160		ns
3	t_w(MDCL)	Pulse duration, MDC low	160		ns
4	t_t(MDC)	Transition time, MDC		5	ns

AM5718-HIREL SPRS91x_TIMING_PRU_MII_RT_02.gif

Figure 7-106 PRU-ICSS MDIO_CLK Timing

Table 7-145 PRU-ICSS MDIO Switching Characteristics - MDIO_DATA

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
1	t_d(MDC-MDIO)	Delay time, MDC high to MDIO valid	0	390	ns

AM5718-HIREL SPRS91x_TIMING_PRU_MII_RT_03.gif

Figure 7-107 PRU-ICSS MDIO_DATA Timing - Output Mode

7.26.3.2 PRU-ICSS MII_RT Electrical Data and Timing

NOTE

In order to guarantee the MII_RT IO timing values published in the device data manual, the ICSS_CLK clock must be configured for 200MHz (default value) and the TX_CLK_DELAY bitfield in the PRUSS_MII_RT_TXCFG0/1 register must be set to 6h (non-default value).

Table 7-146 PRU-ICSS MII_RT Timing Requirements - MII[x]_RXCLK

NO.	PARAMETER	DESCRIPTION	SPEED	MIN	MAX	UNIT
1	t_{c(RX_CLK)}	Cycle time, RX_CLK	10 Mbps	399.96	400.04	ns
1	t_{c(RX_CLK)}	Cycle time, RX_CLK	100 Mbps	39.996	40.004	ns
2	t_{w(RX_CLKH)}	Pulse duration, RX_CLK high	10 Mbps	140	260	ns
2	t_{w(RX_CLKH)}	Pulse duration, RX_CLK high	100 Mbps	14	26	ns
3	t_{w(RX_CLKL)}	Pulse duration, RX_CLK low	10 Mbps	140	260	ns
3	t_{w(RX_CLKL)}	Pulse duration, RX_CLK low	100 Mbps	14	26	ns

AM5718-HIREL SPRS91x_TIMING_PRU_MII_RT_04.gif

Figure 7-108 PRU-ICSS MII[x]_RXCLK Timing

Table 7-147 PRU-ICSS MII_RT Timing Requirements - MII[x]_TXCLK

NO.	PARAMETER	DESCRIPTION	SPEED	MIN	MAX	UNIT
1	t_{c(TX_CLK)}	Cycle time, TX_CLK	10 Mbps	399.96	400.04	ns
1	t_{c(TX_CLK)}	Cycle time, TX_CLK	100 Mbps	39.996	40.004	ns
2	t_{w(TX_CLKH)}	Pulse duration, TX_CLK high	10 Mbps	140	260	ns
2	t_{w(TX_CLKH)}	Pulse duration, TX_CLK high	100 Mbps	14	26	ns
3	t_{w(TX_CLKL)}	Pulse duration, TX_CLK low	10 Mbps	140	260	ns
3	t_{w(TX_CLKL)}	Pulse duration, TX_CLK low	100 Mbps	14	26	ns
4	t_{t(TX_CLK)}	Transition time, TX_CLK	10 Mbps		3	ns
4	t_{t(TX_CLK)}	Transition time, TX_CLK	100 Mbps		3	ns

AM5718-HIREL SPRS91x_TIMING_PRU_MII_RT_05.gif

Figure 7-109 PRU-ICSS MII[x]_TXCLK Timing

Table 7-148 PRU-ICSS MII_RT Timing Requirements - MII_RXD[3:0], MII_RXDV, and MII_RXER

NO.	PARAMETER	DESCRIPTION	SPEED	MIN	UNIT
1	t_{su(RXD-RX_CLK)}	Setup time, RXD[3:0] valid before RX_CLK	10 Mbps	8	ns
	t_{su(RX_DV-RX_CLK)}	Setup time, RX_DV valid before RX_CLK
	t_{su(RX_ER-RX_CLK)}	Setup time, RX_ER valid before RX_CLK
	t_{su(RXD-RX_CLK)}	Setup time, RXD[3:0] valid before RX_CLK	100 Mbps	8	ns
	t_{su(RX_DV-RX_CLK)}	Setup time, RX_DV valid before RX_CLK
	t_{su(RX_ER-RX_CLK)}	Setup time, RX_ER valid before RX_CLK
2	t_{h(RX_CLK-RXD)}	Hold time RXD[3:0] valid after RX_CLK	10 Mbps	8	ns
	t_{h(RX_CLK-RX_DV)}	Hold time RX_DV valid after RX_CLK
	t_{h(RX_CLK-RX_ER)}	Hold time RX_ER valid after RX_CLK
	t_{h(RX_CLK-RXD)}	Hold time RXD[3:0] valid after RX_CLK	100 Mbps	8	ns
	t_{h(RX_CLK-RX_DV)}	Hold time RX_DV valid after RX_CLK
	t_{h(RX_CLK-RX_ER)}	Hold time RX_ER valid after RX_CLK

AM5718-HIREL SPRS91x_TIMING_PRU_MII_RT_06.gif

Figure 7-110 PRU-ICSS MII_RXD[3:0], MII_RXDV, and MII_RXER Timing

Table 7-149 PRU-ICSS MII_RT Switching Characteristics - MII_TXD[3:0] and MII_TXEN

NO.	PARAMETER	DESCRIPTION	SPEED	MIN	MAX	UNIT
1	t_{d(TX_CLK-TXD)}	Delay time, TX_CLK high to TXD[3:0] valid	10 Mbps	5	25	ns
	t_{d(TX_CLK-TX_EN)}	Delay time, TX_CLK to TX_EN valid	10 Mbps	5	25	ns
	t_{d(TX_CLK-TXD)}	Delay time, TX_CLK high to TXD[3:0] valid	100 Mbps	5	25	ns
	t_{d(TX_CLK-TX_EN)}	Delay time, TX_CLK to TX_EN valid	100 Mbps	5	25	ns

AM5718-HIREL SPRS91x_TIMING_PRU_MII_RT_07.gif

Figure 7-111 PRU-ICSS MII_TXD[3:0], MII_TXEN Timing

7.26.4 PRU-ICSS Universal Asynchronous Receiver Transmitter (PRU-ICSS UART)

Table 7-150 Timing Requirements for PRU-ICSS UART Receive

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
3	t_w(RX)	Pulse duration, receive start, stop, data bit	0.96U ^⁽¹⁾	1.05U	ns

U = UART baud time = 1/programmed baud rate.

Table 7-151 Switching Characteristics Over Recommended Operating Conditions for PRU-ICSS UART Transmit

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
1	ƒbaud(baud)	Maximum programmable baud rate	0	12	MHz
2	t_w(TX)	Pulse duration, transmit start, stop, data bit	U - 2 ^⁽¹⁾	U + 2	ns

U = UART baud time = 1/programmed baud rate.

AM5718-HIREL SPRS91x_TIMING_PRU_UART_01.gif

Figure 7-112 PRU-ICSS UART Timing

In Table 7-152 are presented the specific groupings of signals (IOSET) for use with PRU-ICSS1.

Table 7-152 PRU-ICSS1 IOSETs

SIGNALS	IOSET1		IOSET2		IOSET3^⁽¹⁾		IOSET4^⁽¹⁾
	BALL	MUX	BALL	MUX	BALL	MUX	BALL	MUX
PRU-ICSS 1
pr1_pru1_gpi20	A4	12
pr1_pru1_gpi19	B5	12
pr1_pru1_gpi18	B4	12
pr1_pru1_gpi17	B3	12
pr1_pru1_gpi16	A3	12
pr1_pru1_gpi15	C5	12
pr1_pru1_gpi14	D6	12
pr1_pru1_gpi13	B2	12
pr1_pru1_gpi12	C4	12
pr1_pru1_gpi11	C3	12
pr1_pru1_gpi10	C2	12
pr1_pru1_gpo20	A4	13
pr1_pru1_gpo19	B5	13
pr1_pru1_gpo18	B4	13
pr1_pru1_gpo17	B3	13
pr1_pru1_gpo16	A3	13
pr1_pru1_gpo15	C5	13
pr1_pru1_gpo14	D6	13
pr1_pru1_gpo13	B2	13
pr1_pru1_gpo12	C4	13
pr1_pru1_gpo11	C3	13
pr1_pru1_gpo10	C2	13
pr1_pru1_gpi9	D5	12
pr1_pru1_gpi8	F6	12
pr1_pru1_gpi7	D3	12
pr1_pru1_gpi6	E6	12
pr1_pru1_gpi5	F5	12
pr1_pru1_gpi4	E4	12
pr1_pru1_gpi3	C1	12
pr1_pru1_gpi2	F4	12
pr1_pru1_gpi1	D2	12
pr1_pru1_gpi0	E2	12
pr1_pru1_gpo9	D5	13
pr1_pru1_gpo8	F6	13
pr1_pru1_gpo7	D3	13
pr1_pru1_gpo6	E6	13
pr1_pru1_gpo5	F5	13
pr1_pru1_gpo4	E4	13
pr1_pru1_gpo3	C1	13
pr1_pru1_gpo2	F4	13
pr1_pru1_gpo1	D2	13
pr1_pru1_gpo0	E2	13
pr1_edio_data_out7			D1	13
pr1_edio_data_out6			F3	13
pr1_edio_data_out5			F2	13
pr1_edio_data_out4			G6	13
pr1_edio_data_out3			G1	13
pr1_edio_data_out2			H7	13
pr1_edio_data_out1			G2	13
pr1_edio_data_out0			E1	13
pr1_edio_data_in7			D1	12
pr1_edio_data_in6			F3	12
pr1_edio_data_in5			F2	12
pr1_edio_data_in4			G6	12
pr1_edio_data_in3			G1	12
pr1_edio_data_in2			H7	12
pr1_edio_data_in1			G2	12
pr1_edio_data_in0			E1	12
pr1_edio_sof			F4	11
pr1_edc_latch0_in			E2	11
pr1_edc_sync0_out			D2	11
pr1_uart0_cts_n	G1	11	F11	10
pr1_uart0_rts_n	G6	11	G10	10
pr1_uart0_txd	F3	11	G11	10
pr1_uart0_rxd	F2	11	F10	10
pr1_ecap0_ecap_capin_apwm_o	D1	11	E9	10
PRU-ICSS 1 MII
pr1_mii1_crs	A4	11					G10	12
pr1_mii1_rxlink	B4	11					F11	12
pr1_mii1_col	B5	11					E2	12
pr1_mii0_col	V1	11			B9	12
pr1_mii0_rxlink	U4	11			A9	12
pr1_mii0_crs	V7	11			A10	12
pr1_mii1_txd3	F5	11					F5	11
pr1_mii1_txd2	E6	11					E6	11
pr1_mii1_txd1	D5	11					D2	13
pr1_mii1_txd0	C2	11					F4	13
pr1_mii1_rxd3	B2	11					E9	12
pr1_mii1_rxd2	D6	11					F9	12
pr1_mii1_rxd1	C5	11					F8	12
pr1_mii1_rxd0	A3	11					E7	12
pr1_mii1_rxdv	C4	11					G11	12
pr1_mii1_txen	E4	11					E4	11
pr1_mii1_rxer	B3	11					E11	12
pr1_mii_mr1_clk	C3	11					F10	12
pr1_mii_mt1_clk	C1	11					C1	11
pr1_mii0_txd3	V5	11			D9	13
pr1_mii0_txd2	V4	11			D7	13
pr1_mii0_txd1	Y2	11			A5	13
pr1_mii0_txd0	W2	11			C6	13
pr1_mii0_rxd3	W9	11			B7	12
pr1_mii0_rxd2	V9	11			B8	12
pr1_mii0_rxd1	V6	11			A7	12
pr1_mii0_rxd0	U6	11			A8	12
pr1_mii0_rxdv	V2	11			C7	12
pr1_mii0_txen	V3	11			D8	13
pr1_mii0_rxer	U7	11			C9	12
pr1_mii_mt0_clk	U5	11			E8	12
pr1_mii_mr0_clk	Y1	11			C8	12
pr1_mdio_mdclk	D3	11
pr1_mdio_data	F6	11

These signals are internally muxed with the PRU GPI/GPO signals. Refer to the PRU chapter in the TRM for more details about the PRU-ICSS internal wrapper multiplexing.

In Table 7-153, Table 7-154 and Table 7-155 are presented the specific groupings of signals (IOSET) for use with PRU-ICSS2.

Table 7-153 PRU-ICSS2 IOSETs

SIGNALS	IOSET1		IOSET2
SIGNALS	BALL	MUX	BALL	MUX
PRU-ICSS 2
pr2_pru1_gpi20	F10	12	F10	12
pr2_pru1_gpi19	G10	12	G10	12
pr2_pru1_gpi18	F11	12	F11	12
pr2_pru1_gpi17	E11	12	E11	12
pr2_pru1_gpi16	W2	12	G14	12
pr2_pru1_gpi15	Y2	12	A13	12
pr2_pru1_gpi14	V3	12	E14	12
pr2_pru1_gpi13	V4	12	A12	12
pr2_pru1_gpi12	V5	12	B13	12
pr2_pru1_gpi11	U5	12	A11	12
pr2_pru1_gpi10	U6	12	B12	12
pr2_pru1_gpi9	V6	12	F12	12
pr2_pru1_gpi8	U7	12	G12	12
pr2_pru1_gpi7	V7	12	C14	12
pr2_pru1_gpi6	V9	12	E17	12
pr2_pru1_gpi5	W9	12	D18	12
pr2_pru1_gpi4	Y1	12	AA4	12
pr2_pru1_gpi3	V2	12	AB3	12
pr2_pru1_gpi2	U3	12	AB9	12
pr2_pru1_gpi1	U4	12	AA3	12
pr2_pru1_gpi0	V1	12	D17	12
pr2_pru1_gpo20	F10	13	F10	13
pr2_pru1_gpo19	G10	13	G10	13
pr2_pru1_gpo18	F11	13	F11	13
pr2_pru1_gpo17	E11	13	E11	13
pr2_pru1_gpo16	W2	13	G14	13
pr2_pru1_gpo15	Y2	13	A13	13
pr2_pru1_gpo14	V3	13	E14	13
pr2_pru1_gpo13	V4	13	A12	13
pr2_pru1_gpo12	V5	13	B13	13
pr2_pru1_gpo11	U5	13	A11	13
pr2_pru1_gpo10	U6	13	B12	13
pr2_pru1_gpo9	V6	13	F12	13
pr2_pru1_gpo8	U7	13	G12	13
pr2_pru1_gpo7	V7	13	C14	13
pr2_pru1_gpo6	V9	13	E17	13
pr2_pru1_gpo5	W9	13	D18	13
pr2_pru1_gpo4	Y1	13	AA4	13
pr2_pru1_gpo3	V2	13	AB3	13
pr2_pru1_gpo2	U3	13	AB9	13
pr2_pru1_gpo1	U4	13	AA3	13
pr2_pru1_gpo0	V1	13	D17	13
pr2_pru0_gpi20	A10	12	F14	12
pr2_pru0_gpi19	B9	12	A18	12
pr2_pru0_gpi18	A9	12	A19	12
pr2_pru0_gpi17	C9	12	A16	12
pr2_pru0_gpi16	A8	12	C15	12
pr2_pru0_gpi15	A7	12	C17	12
pr2_pru0_gpi14	B8	12	B19	12
pr2_pru0_gpi13	B7	12	F15	12
pr2_pru0_gpi12	C7	12	B18	12
pr2_pru0_gpi11	C8	12	AB5	12
pr2_pru0_gpi10	C6	12	AB8	12
pr2_pru0_gpi9	A5	12	AD6	12
pr2_pru0_gpi8	D8	12	AC8	12
pr2_pru0_gpi7	D7	12	AC3	12
pr2_pru0_gpi6	D9	12	AC9	12
pr2_pru0_gpi5	E8	12	AC6	12
pr2_pru0_gpi4	E7	12	AC7	12
pr2_pru0_gpi3	F8	12	AC4	12
pr2_pru0_gpi2	F9	12	AD4	12
pr2_pru0_gpi1	E9	12	AB4	12
pr2_pru0_gpi0	G11	12	AC5	12
pr2_pru0_gpo20	A10	13	F14	13
pr2_pru0_gpo19	B9	13	A18	13
pr2_pru0_gpo18	A9	13	A19	13
pr2_pru0_gpo17	C9	13	A16	13
pr2_pru0_gpo16	A8	13	C15	13
pr2_pru0_gpo15	A7	13	C17	13
pr2_pru0_gpo14	B8	13	B19	13
pr2_pru0_gpo13	B7	13	F15	13
pr2_pru0_gpo12	C7	13	B18	13
pr2_pru0_gpo11	C8	13	AB5	13
pr2_pru0_gpo10	C6	13	AB8	13
pr2_pru0_gpo9	A5	13	AD6	13
pr2_pru0_gpo8	D8	13	AC8	13
pr2_pru0_gpo7	D7	13	AC3	13
pr2_pru0_gpo6	D9	13	AC9	13
pr2_pru0_gpo5	E8	13	AC6	13
pr2_pru0_gpo4	E7	13	AC7	13
pr2_pru0_gpo3	F8	13	AC4	13
pr2_pru0_gpo2	F9	13	AD4	13
pr2_pru0_gpo1	E9	13	AB4	13
pr2_pru0_gpo0	G11	13	AC5	13
pr2_mii1_crs	E17	11
pr2_mii1_rxlink	C17	11
pr2_mii0_crs	B18	11
pr2_mii0_rxlink	A16	11
pr2_mii0_col	F15	11
pr2_mii1_col	D18	11
pr2_edio_data_out7	A10	11
pr2_edio_data_out6	B9	11
pr2_edio_data_out5	A9	11
pr2_edio_data_out4	C9	11
pr2_edio_data_out3	A8	11
pr2_edio_data_out2	A7	11
pr2_edio_data_out1	B8	11
pr2_edio_data_out0	B7	11
pr2_edio_data_in7	A10	10
pr2_edio_data_in6	B9	10
pr2_edio_data_in5	A9	10
pr2_edio_data_in4	C9	10
pr2_edio_data_in3	A8	10
pr2_edio_data_in2	A7	10
pr2_edio_data_in1	B8	10
pr2_edio_data_in0	B7	10
pr2_edio_latch_in	D9	10
pr2_edio_sof	D7	10
pr2_edc_sync0_out	E7	10
pr2_edc_sync1_out	E8	10
pr2_edc_latch0_in	F9	10
pr2_edc_latch1_in	F8	10
pr2_uart0_rxd	C6	10
pr2_uart0_txd	C8	10
pr2_uart0_cts_n	D8	10
pr2_uart0_rts_n	A5	10
pr2_ecap0_ecap_capin_apwm_o	C7	10
PRU-ICSS 2 MII
pr2_mii1_txd3	AD4	11
pr2_mii1_txd2	AC4	11
pr2_mii1_txd1	AC7	11
pr2_mii1_txd0	AC6	11
pr2_mii1_rxd3	AC8	11
pr2_mii1_rxd2	AD6	11
pr2_mii1_rxd1	AB8	11
pr2_mii1_rxd0	AB5	11
pr2_mii_mr1_clk	AC9	11
pr2_mii1_rxer	B19	11
pr2_mii_mt1_clk	AC5	11
pr2_mii1_rxdv	AC3	11
pr2_mii1_txen	AB4	11
pr2_mii0_txd3	A11	11
pr2_mii0_txd2	B13	11
pr2_mii0_txd1	A12	11
pr2_mii0_txd0	E14	11
pr2_mii0_rxd3	F14	11
pr2_mii0_rxd2	A19	11
pr2_mii0_rxd1	A18	11
pr2_mii0_rxd0	C15	11
pr2_mii_mr0_clk	A13	11
pr2_mii0_rxer	G12	11
pr2_mii_mt0_clk	F12	11
pr2_mii0_rxdv	G14	11
pr2_mii0_txen	B12	11
pr2_mdio_mdclk	C14	11	AB3	11
pr2_mdio_data	D14	11	AA4	11

Table 7-154 PRU-ICSS2 IOSETs (EnDAT)^⁽¹⁾

SIGNALS	IOSET3		IOSET4
	BALL	MUX	BALL	MUX
PRU-ICSS 2 EnDAT
pr2_pru1_endat0_clk	V1	13	D17	13
pr2_pru1_endat0_out	U4	13	AA3	13
pr2_pru1_endat0_out_en	U3	13	AB9	13
pr2_pru1_endat1_clk	V2	13	AB3	13
pr2_pru1_endat1_out	Y1	13	AA4	13
pr2_pru1_endat1_out_en	W9	13	D18	13
pr2_pru1_endat2_clk	V9	13	E17	13
pr2_pru1_endat2_out	V7	13	C14	13
pr2_pru1_endat2_out_en	U7	13	G12	13
pr2_pru1_endat0_in	V6	12	F12	12
pr2_pru1_endat1_in	U6	12	B12	12
pr2_pru1_endat2_in	U5	12	A11	12

These signals are internally muxed with the PRU GPI/GPO signals. Refer to the PRU chapter in the TRM for more details about the PRU-ICSS internal wrapper multiplexing.

Table 7-155 PRU-ICSS2 IOSETs (Sigma Delta)^⁽¹⁾

SIGNALS	IOSET3		IOSET4
	BALL	MUX	BALL	MUX
PRU-ICSS 2 SD
pr2_pru0_sd0_clk	G11	12	AC5	12
pr2_pru0_sd0_d	E9	12	AB4	12
pr2_pru0_sd1_clk	F9	12	AD4	12
pr2_pru0_sd1_d	F8	12	AC4	12
pr2_pru0_sd2_clk	E7	12	AC7	12
pr2_pru0_sd2_d	E8	12	AC6	12
pr2_pru0_sd3_clk	D9	12	AC9	12
pr2_pru0_sd3_d	D7	12	AC3	12
pr2_pru0_sd4_clk	D8	12	AC8	12
pr2_pru0_sd4_d	A5	12	AD6	12
pr2_pru0_sd5_clk	C6	12	AB8	12
pr2_pru0_sd5_d	C8	12	AB5	12
pr2_pru0_sd6_clk	C7	12	B18	12
pr2_pru0_sd6_d	B7	12	F15	12
pr2_pru0_sd7_clk	B8	12	B19	12
pr2_pru0_sd7_d	A7	12	C17	12
pr2_pru0_sd8_clk	A8	12	C15	12
pr2_pru0_sd8_d	C9	12	A16	12

These signals are internally muxed with the PRU GPI/GPO signals. Refer to the PRU chapter in the TRM for more details about the PRU-ICSS internal wrapper multiplexing.

7.26.5 PRU-ICSS Manual Functional Mapping

NOTE

To configure the desired Manual IO Timing Mode the user must follow the steps described in section "Manual IO Timing Modes" of the Device TRM.

The associated registers to configure are listed in the CFG REGISTER column. For more information see the Control Module Chapter in the Device TRM.

Manual IO Timings Modes must be used to guaranteed some IO timings for PRU-ICSS1 PRU1 Direct Input mode. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-156 Manual Functions Mapping for PRU-ICSS1 PRU1 Direct Input mode for a definition of the Manual modes.

Table 7-156 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-156 Manual Functions Mapping for PRU-ICSS1 PRU1 Direct Input mode

BALL	BALL NAME	PR1_PRU1_DIR_IN_MANUAL		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	12
D3	vin2a_d10	0	800	CFG_VIN2A_D10_IN	pr1_pru1_gpi7
F6	vin2a_d11	0	0	CFG_VIN2A_D11_IN	pr1_pru1_gpi8
D5	vin2a_d12	0	200	CFG_VIN2A_D12_IN	pr1_pru1_gpi9
C2	vin2a_d13	0	0	CFG_VIN2A_D13_IN	pr1_pru1_gpi10
C3	vin2a_d14	0	0	CFG_VIN2A_D14_IN	pr1_pru1_gpi11
C4	vin2a_d15	0	400	CFG_VIN2A_D15_IN	pr1_pru1_gpi12
B2	vin2a_d16	0	300	CFG_VIN2A_D16_IN	pr1_pru1_gpi13
D6	vin2a_d17	0	400	CFG_VIN2A_D17_IN	pr1_pru1_gpi14
C5	vin2a_d18	0	900	CFG_VIN2A_D18_IN	pr1_pru1_gpi15
A3	vin2a_d19	0	1500	CFG_VIN2A_D19_IN	pr1_pru1_gpi16
B3	vin2a_d20	0	100	CFG_VIN2A_D20_IN	pr1_pru1_gpi17
B4	vin2a_d21	0	500	CFG_VIN2A_D21_IN	pr1_pru1_gpi18
B5	vin2a_d22	0	500	CFG_VIN2A_D22_IN	pr1_pru1_gpi19
A4	vin2a_d23	0	600	CFG_VIN2A_D23_IN	pr1_pru1_gpi20
E2	vin2a_d3	0	900	CFG_VIN2A_D3_IN	pr1_pru1_gpi0
D2	vin2a_d4	0	100	CFG_VIN2A_D4_IN	pr1_pru1_gpi1
F4	vin2a_d5	0	600	CFG_VIN2A_D5_IN	pr1_pru1_gpi2
C1	vin2a_d6	0	200	CFG_VIN2A_D6_IN	pr1_pru1_gpi3
E4	vin2a_d7	0	400	CFG_VIN2A_D7_IN	pr1_pru1_gpi4
F5	vin2a_d8	0	500	CFG_VIN2A_D8_IN	pr1_pru1_gpi5
E6	vin2a_d9	0	600	CFG_VIN2A_D9_IN	pr1_pru1_gpi6

Manual IO Timings Modes must be used to guaranteed some IO timings for PRU-ICSS1 PRU1 Direct Output mode. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-157 Manual Functions Mapping for PRU-ICSS1 PRU1 Direct Output mode for a definition of the Manual modes.

Table 7-157 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-157 Manual Functions Mapping for PRU-ICSS1 PRU1 Direct Output mode

BALL	BALL NAME	PR1_PRU1_DIR_OUT_MANUAL		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	13
D3	vin2a_d10	0	1000	CFG_VIN2A_D10_OUT	pr1_pru1_gpo7
F6	vin2a_d11	0	1300	CFG_VIN2A_D11_OUT	pr1_pru1_gpo8
D5	vin2a_d12	0	2300	CFG_VIN2A_D12_OUT	pr1_pru1_gpo9
C2	vin2a_d13	0	2200	CFG_VIN2A_D13_OUT	pr1_pru1_gpo10
C3	vin2a_d14	0	1800	CFG_VIN2A_D14_OUT	pr1_pru1_gpo11
C4	vin2a_d15	0	1800	CFG_VIN2A_D15_OUT	pr1_pru1_gpo12
B2	vin2a_d16	0	1600	CFG_VIN2A_D16_OUT	pr1_pru1_gpo13
D6	vin2a_d17	0	2000	CFG_VIN2A_D17_OUT	pr1_pru1_gpo14
C5	vin2a_d18	0	700	CFG_VIN2A_D18_OUT	pr1_pru1_gpo15
A3	vin2a_d19	0	700	CFG_VIN2A_D19_OUT	pr1_pru1_gpo16
B3	vin2a_d20	0	500	CFG_VIN2A_D20_OUT	pr1_pru1_gpo17
B4	vin2a_d21	0	400	CFG_VIN2A_D21_OUT	pr1_pru1_gpo18
B5	vin2a_d22	0	0	CFG_VIN2A_D22_OUT	pr1_pru1_gpo19
A4	vin2a_d23	0	400	CFG_VIN2A_D23_OUT	pr1_pru1_gpo20
E2	vin2a_d3	0	2200	CFG_VIN2A_D3_OUT	pr1_pru1_gpo0
D2	vin2a_d4	540	2800	CFG_VIN2A_D4_OUT	pr1_pru1_gpo1
F4	vin2a_d5	0	400	CFG_VIN2A_D5_OUT	pr1_pru1_gpo2
C1	vin2a_d6	0	1500	CFG_VIN2A_D6_OUT	pr1_pru1_gpo3
E4	vin2a_d7	0	2200	CFG_VIN2A_D7_OUT	pr1_pru1_gpo4
F5	vin2a_d8	0	2600	CFG_VIN2A_D8_OUT	pr1_pru1_gpo5
E6	vin2a_d9	0	2300	CFG_VIN2A_D9_OUT	pr1_pru1_gpo6

Manual IO Timings Modes must be used to guaranteed some IO timings for PRU-ICSS1 PRU1 Parallel Capture Mode. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-158 Manual Functions Mapping for PRU-ICSS1 PRU1 Parallel Capture Mode for a definition of the Manual modes.

Table 7-158 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-158 Manual Functions Mapping for PRU-ICSS1 PRU1 Parallel Capture Mode

BALL	BALL NAME	PR1_PRU1_PAR_CAP_MANUAL		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	12
D3	vin2a_d10	1535	0	CFG_VIN2A_D10_IN	pr1_pru1_gpi7
F6	vin2a_d11	1151	0	CFG_VIN2A_D11_IN	pr1_pru1_gpi8
D5	vin2a_d12	1173	0	CFG_VIN2A_D12_IN	pr1_pru1_gpi9
C2	vin2a_d13	970	0	CFG_VIN2A_D13_IN	pr1_pru1_gpi10
C3	vin2a_d14	1196	0	CFG_VIN2A_D14_IN	pr1_pru1_gpi11
C4	vin2a_d15	1286	0	CFG_VIN2A_D15_IN	pr1_pru1_gpi12
B2	vin2a_d16	1354	0	CFG_VIN2A_D16_IN	pr1_pru1_gpi13
D6	vin2a_d17	1331	0	CFG_VIN2A_D17_IN	pr1_pru1_gpi14
C5	vin2a_d18	2097	0	CFG_VIN2A_D18_IN	pr1_pru1_gpi15
A3	vin2a_d19	0	453	CFG_VIN2A_D19_IN	pr1_pru1_gpi16
E2	vin2a_d3	1566	0	CFG_VIN2A_D3_IN	pr1_pru1_gpi0
D2	vin2a_d4	1012	0	CFG_VIN2A_D4_IN	pr1_pru1_gpi1
F4	vin2a_d5	1337	0	CFG_VIN2A_D5_IN	pr1_pru1_gpi2
C1	vin2a_d6	1130	0	CFG_VIN2A_D6_IN	pr1_pru1_gpi3
E4	vin2a_d7	1202	0	CFG_VIN2A_D7_IN	pr1_pru1_gpi4
F5	vin2a_d8	1395	0	CFG_VIN2A_D8_IN	pr1_pru1_gpi5
E6	vin2a_d9	1338	0	CFG_VIN2A_D9_IN	pr1_pru1_gpi6

Manual IO Timings Modes must be used to guaranteed some IO timings for PRU-ICSS2 PRU0 IOSET1 Direct Input mode. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-159 Manual Functions Mapping for PRU-ICSS2 PRU0 IOSET1 Direct Input mode for a definition of the Manual modes.

Table 7-159 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-159 Manual Functions Mapping for PRU-ICSS2 PRU0 IOSET1 Direct Input mode

BALL	BALL NAME	PR2_PRU0_DIR_IN_MANUAL1		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	12
D7	vout1_d10	0	0	CFG_VOUT1_D10_IN	pr2_pru0_gpi7
D8	vout1_d11	0	0	CFG_VOUT1_D11_IN	pr2_pru0_gpi8
A5	vout1_d12	0	0	CFG_VOUT1_D12_IN	pr2_pru0_gpi9
C6	vout1_d13	0	0	CFG_VOUT1_D13_IN	pr2_pru0_gpi10
C8	vout1_d14	0	0	CFG_VOUT1_D14_IN	pr2_pru0_gpi11
C7	vout1_d15	0	0	CFG_VOUT1_D15_IN	pr2_pru0_gpi12
B7	vout1_d16	0	0	CFG_VOUT1_D16_IN	pr2_pru0_gpi13
B8	vout1_d17	0	0	CFG_VOUT1_D17_IN	pr2_pru0_gpi14
A7	vout1_d18	0	0	CFG_VOUT1_D18_IN	pr2_pru0_gpi15
A8	vout1_d19	0	0	CFG_VOUT1_D19_IN	pr2_pru0_gpi16
C9	vout1_d20	0	0	CFG_VOUT1_D20_IN	pr2_pru0_gpi17
A9	vout1_d21	0	0	CFG_VOUT1_D21_IN	pr2_pru0_gpi18
B9	vout1_d22	0	0	CFG_VOUT1_D22_IN	pr2_pru0_gpi19
A10	vout1_d23	0	0	CFG_VOUT1_D23_IN	pr2_pru0_gpi20
G11	vout1_d3	0	0	CFG_VOUT1_D3_IN	pr2_pru0_gpi0
E9	vout1_d4	0	0	CFG_VOUT1_D4_IN	pr2_pru0_gpi1
F9	vout1_d5	0	0	CFG_VOUT1_D5_IN	pr2_pru0_gpi2
F8	vout1_d6	0	0	CFG_VOUT1_D6_IN	pr2_pru0_gpi3
E7	vout1_d7	0	0	CFG_VOUT1_D7_IN	pr2_pru0_gpi4
E8	vout1_d8	0	0	CFG_VOUT1_D8_IN	pr2_pru0_gpi5
D9	vout1_d9	0	0	CFG_VOUT1_D9_IN	pr2_pru0_gpi6

Manual IO Timings Modes must be used to guaranteed some IO timings for PRU-ICSS2 PRU0 IOSET2 Direct Input mode. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-160 Manual Functions Mapping for PRU-ICSS2 PRU0 IOSET2 Direct Input mode for a definition of the Manual modes.

Table 7-160 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-160 Manual Functions Mapping for PRU-ICSS2 PRU0 IOSET2 Direct Input mode

BALL	BALL NAME	PR2_PRU0_DIR_IN_MANUAL2		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	12
AC5	gpio6_10	1000	3300	CFG_GPIO6_10_IN	pr2_pru0_gpi0
AB4	gpio6_11	1000	3400	CFG_GPIO6_11_IN	pr2_pru0_gpi1
F14	mcasp1_axr15	0	1300	CFG_MCASP1_AXR15_IN	pr2_pru0_gpi20
A19	mcasp2_aclkx	0	800	CFG_MCASP2_ACLKX_IN	pr2_pru0_gpi18
C15	mcasp2_axr2	0	1900	CFG_MCASP2_AXR2_IN	pr2_pru0_gpi16
A16	mcasp2_axr3	0	1400	CFG_MCASP2_AXR3_IN	pr2_pru0_gpi17
A18	mcasp2_fsx	0	1400	CFG_MCASP2_FSX_IN	pr2_pru0_gpi19
B19	mcasp3_axr0	0	1400	CFG_MCASP3_AXR0_IN	pr2_pru0_gpi14
C17	mcasp3_axr1	0	1000	CFG_MCASP3_AXR1_IN	pr2_pru0_gpi15
F15	mcasp3_fsx	0	1300	CFG_MCASP3_FSX_IN	pr2_pru0_gpi13
AD4	mmc3_clk	1000	3700	CFG_MMC3_CLK_IN	pr2_pru0_gpi2
AC4	mmc3_cmd	1000	3500	CFG_MMC3_CMD_IN	pr2_pru0_gpi3
AC7	mmc3_dat0	1000	3500	CFG_MMC3_DAT0_IN	pr2_pru0_gpi4
AC6	mmc3_dat1	1000	4000	CFG_MMC3_DAT1_IN	pr2_pru0_gpi5
AC9	mmc3_dat2	1000	3300	CFG_MMC3_DAT2_IN	pr2_pru0_gpi6
AC3	mmc3_dat3	1000	3900	CFG_MMC3_DAT3_IN	pr2_pru0_gpi7
AC8	mmc3_dat4	1000	3500	CFG_MMC3_DAT4_IN	pr2_pru0_gpi8
AD6	mmc3_dat5	1000	3600	CFG_MMC3_DAT5_IN	pr2_pru0_gpi9
AB8	mmc3_dat6	1000	3500	CFG_MMC3_DAT6_IN	pr2_pru0_gpi10
AB5	mmc3_dat7	1000	3100	CFG_MMC3_DAT7_IN	pr2_pru0_gpi11
B18	mcasp3_aclkx	0	0	CFG_MCASP3_ACLKX_IN	pr2_pru0_gpi12

Manual IO Timings Modes must be used to guaranteed some IO timings for PRU-ICSS2 PRU0 IOSET1 Direct Output mode. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-161 Manual Functions Mapping for PRU-ICSS2 PRU0 IOSET1 Direct Output mode for a definition of the Manual modes.

Table 7-161 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-161 Manual Functions Mapping for PRU-ICSS2 PRU0 IOSET1 Direct Output mode

BALL	BALL NAME	PR2_PRU0_DIR_OUT_MANUAL1		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	13
D7	vout1_d10	0	600	CFG_VOUT1_D10_OUT	pr2_pru0_gpo7
D8	vout1_d11	0	700	CFG_VOUT1_D11_OUT	pr2_pru0_gpo8
A5	vout1_d12	1200	200	CFG_VOUT1_D12_OUT	pr2_pru0_gpo9
C6	vout1_d13	0	600	CFG_VOUT1_D13_OUT	pr2_pru0_gpo10
C8	vout1_d14	200	300	CFG_VOUT1_D14_OUT	pr2_pru0_gpo11
C7	vout1_d15	400	0	CFG_VOUT1_D15_OUT	pr2_pru0_gpo12
B7	vout1_d16	0	0	CFG_VOUT1_D16_OUT	pr2_pru0_gpo13
B8	vout1_d17	0	300	CFG_VOUT1_D17_OUT	pr2_pru0_gpo14
A7	vout1_d18	120	300	CFG_VOUT1_D18_OUT	pr2_pru0_gpo15
A8	vout1_d19	0	0	CFG_VOUT1_D19_OUT	pr2_pru0_gpo16
C9	vout1_d20	250	200	CFG_VOUT1_D20_OUT	pr2_pru0_gpo17
A9	vout1_d21	300	200	CFG_VOUT1_D21_OUT	pr2_pru0_gpo18
B9	vout1_d22	0	0	CFG_VOUT1_D22_OUT	pr2_pru0_gpo19
A10	vout1_d23	0	0	CFG_VOUT1_D23_OUT	pr2_pru0_gpo20
G11	vout1_d3	920	0	CFG_VOUT1_D3_OUT	pr2_pru0_gpo0
E9	vout1_d4	1500	300	CFG_VOUT1_D4_OUT	pr2_pru0_gpo1
F9	vout1_d5	460	100	CFG_VOUT1_D5_OUT	pr2_pru0_gpo2
F8	vout1_d6	300	300	CFG_VOUT1_D6_OUT	pr2_pru0_gpo3
E7	vout1_d7	160	0	CFG_VOUT1_D7_OUT	pr2_pru0_gpo4
E8	vout1_d8	0	0	CFG_VOUT1_D8_OUT	pr2_pru0_gpo5
D9	vout1_d9	0	1200	CFG_VOUT1_D9_OUT	pr2_pru0_gpo6

Manual IO Timings Modes must be used to guaranteed some IO timings for PRU-ICSS2 PRU0 IOSET2 Direct Output mode. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-162 Manual Functions Mapping for PRU-ICSS2 PRU0 IOSET2 Direct Output mode for a definition of the Manual modes.

Table 7-162 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-162 Manual Functions Mapping for PRU-ICSS2 PRU0 IOSET2 Direct Output mode

BALL	BALL NAME	PR2_PRU0_DIR_OUT_MANUAL2		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	13
AC5	gpio6_10	1800	1900	CFG_GPIO6_10_OUT	pr2_pru0_gpo0
AB4	gpio6_11	2500	2100	CFG_GPIO6_11_OUT	pr2_pru0_gpo1
F14	mcasp1_axr15	0	400	CFG_MCASP1_AXR15_OUT	pr2_pru0_gpo20
A19	mcasp2_aclkx	0	400	CFG_MCASP2_ACLKX_OUT	pr2_pru0_gpo18
C15	mcasp2_axr2	0	500	CFG_MCASP2_AXR2_OUT	pr2_pru0_gpo16
A16	mcasp2_axr3	0	500	CFG_MCASP2_AXR3_OUT	pr2_pru0_gpo17
A18	mcasp2_fsx	0	0	CFG_MCASP2_FSX_OUT	pr2_pru0_gpo19
B18	mcasp3_aclkx	0	500	CFG_MCASP3_ACLKX_OUT	pr2_pru0_gpo12
B19	mcasp3_axr0	0	0	CFG_MCASP3_AXR0_OUT	pr2_pru0_gpo14
C17	mcasp3_axr1	0	200	CFG_MCASP3_AXR1_OUT	pr2_pru0_gpo15
F15	mcasp3_fsx	0	300	CFG_MCASP3_FSX_OUT	pr2_pru0_gpo13
AD4	mmc3_clk	2100	2200	CFG_MMC3_CLK_OUT	pr2_pru0_gpo2
AC4	mmc3_cmd	2300	2300	CFG_MMC3_CMD_OUT	pr2_pru0_gpo3
AC7	mmc3_dat0	2000	1600	CFG_MMC3_DAT0_OUT	pr2_pru0_gpo4
AC6	mmc3_dat1	2000	1700	CFG_MMC3_DAT1_OUT	pr2_pru0_gpo5
AC9	mmc3_dat2	2050	2200	CFG_MMC3_DAT2_OUT	pr2_pru0_gpo6
AC3	mmc3_dat3	2000	2000	CFG_MMC3_DAT3_OUT	pr2_pru0_gpo7
AC8	mmc3_dat4	2150	2600	CFG_MMC3_DAT4_OUT	pr2_pru0_gpo8
AD6	mmc3_dat5	2400	2600	CFG_MMC3_DAT5_OUT	pr2_pru0_gpo9
AB8	mmc3_dat6	2200	2300	CFG_MMC3_DAT6_OUT	pr2_pru0_gpo10
AB5	mmc3_dat7	1800	2400	CFG_MMC3_DAT7_OUT	pr2_pru0_gpo11

Manual IO Timings Modes must be used to guaranteed some IO timings for PRU-ICSS2 PRU1 IOSET1 Direct Input mode. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-163 Manual Functions Mapping for PRU-ICSS2 PRU1 IOSET1 Direct Input mode for a definition of the Manual modes.

Table 7-163 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-163 Manual Functions Mapping for PRU-ICSS2 PRU1 IOSET1 Direct Input mode

BALL	BALL NAME	PR2_PRU1_DIR_IN_MANUAL1		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	12
U3	RMII_MHZ_50_CLK	1400	1200	CFG_RMII_MHZ_50_CLK_IN	pr2_pru1_gpi2
U4	mdio_d	1300	1600	CFG_MDIO_D_IN	pr2_pru1_gpi1
V1	mdio_mclk	1400	800	CFG_MDIO_MCLK_IN	pr2_pru1_gpi0
U5	rgmii0_rxc	1400	500	CFG_RGMII0_RXC_IN	pr2_pru1_gpi11
V5	rgmii0_rxctl	1400	1800	CFG_RGMII0_RXCTL_IN	pr2_pru1_gpi12
W2	rgmii0_rxd0	1400	1300	CFG_RGMII0_RXD0_IN	pr2_pru1_gpi16
Y2	rgmii0_rxd1	1400	1650	CFG_RGMII0_RXD1_IN	pr2_pru1_gpi15
V3	rgmii0_rxd2	1400	1400	CFG_RGMII0_RXD2_IN	pr2_pru1_gpi14
V4	rgmii0_rxd3	1400	1650	CFG_RGMII0_RXD3_IN	pr2_pru1_gpi13
W9	rgmii0_txc	1400	900	CFG_RGMII0_TXC_IN	pr2_pru1_gpi5
V9	rgmii0_txctl	1400	1300	CFG_RGMII0_TXCTL_IN	pr2_pru1_gpi6
U6	rgmii0_txd0	1400	900	CFG_RGMII0_TXD0_IN	pr2_pru1_gpi10
V6	rgmii0_txd1	1300	1400	CFG_RGMII0_TXD1_IN	pr2_pru1_gpi9
U7	rgmii0_txd2	1300	1100	CFG_RGMII0_TXD2_IN	pr2_pru1_gpi8
V7	rgmii0_txd3	1300	1300	CFG_RGMII0_TXD3_IN	pr2_pru1_gpi7
V2	uart3_rxd	1300	1000	CFG_UART3_RXD_IN	pr2_pru1_gpi3
Y1	uart3_txd	1300	800	CFG_UART3_TXD_IN	pr2_pru1_gpi4
E11	vout1_vsync	0	0	CFG_VOUT1_VSYNC_IN	pr2_pru1_gpi17
F11	vout1_d0	0	0	CFG_VOUT1_D0_IN	pr2_pru1_gpi18
G10	vout1_d1	0	0	CFG_VOUT1_D1_IN	pr2_pru1_gpi19
F10	vout1_d2	0	0	CFG_VOUT1_D2_IN	pr2_pru1_gpi20

Manual IO Timings Modes must be used to guaranteed some IO timings for PRU-ICSS2 PRU1 IOSET2 Direct Input mode. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-164 Manual Functions Mapping for PRU-ICSS2 PRU1 IOSET2 Direct Input mode for a definition of the Manual modes.

Table 7-164 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-164 Manual Functions Mapping for PRU-ICSS2 PRU1 IOSET2 Direct Input mode

BALL	BALL NAME	PR2_PRU1_DIR_IN_MANUAL2		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	12
C14	mcasp1_aclkx	400	0	CFG_MCASP1_ACLKX_IN	pr2_pru1_gpi7
G12	mcasp1_axr0	700	200	CFG_MCASP1_AXR0_IN	pr2_pru1_gpi8
F12	mcasp1_axr1	600	300	CFG_MCASP1_AXR1_IN	pr2_pru1_gpi9
B13	mcasp1_axr10	600	500	CFG_MCASP1_AXR10_IN	pr2_pru1_gpi12
A12	mcasp1_axr11	700	500	CFG_MCASP1_AXR11_IN	pr2_pru1_gpi13
E14	mcasp1_axr12	500	0	CFG_MCASP1_AXR12_IN	pr2_pru1_gpi14
A13	mcasp1_axr13	600	200	CFG_MCASP1_AXR13_IN	pr2_pru1_gpi15
G14	mcasp1_axr14	600	0	CFG_MCASP1_AXR14_IN	pr2_pru1_gpi16
E11	vout1_vsync	0	0	CFG_VOUT1_VSYNC_IN	pr2_pru1_gpi17
F11	vout1_d0	0	0	CFG_VOUT1_D0_IN	pr2_pru1_gpi18
G10	vout1_d1	0	0	CFG_VOUT1_D1_IN	pr2_pru1_gpi19
F10	vout1_d2	0	0	CFG_VOUT1_D2_IN	pr2_pru1_gpi20
B12	mcasp1_axr8	800	0	CFG_MCASP1_AXR8_IN	pr2_pru1_gpi10
A11	mcasp1_axr9	600	300	CFG_MCASP1_AXR9_IN	pr2_pru1_gpi11
D17	mcasp4_axr1	500	0	CFG_MCASP4_AXR1_IN	pr2_pru1_gpi0
AA3	mcasp5_aclkx	2100	1959	CFG_MCASP5_ACLKX_IN	pr2_pru1_gpi1
AB3	mcasp5_axr0	2300	2000	CFG_MCASP5_AXR0_IN	pr2_pru1_gpi3
AA4	mcasp5_axr1	2300	1800	CFG_MCASP5_AXR1_IN	pr2_pru1_gpi4
AB9	mcasp5_fsx	2100	1780	CFG_MCASP5_FSX_IN	pr2_pru1_gpi2
D18	xref_clk0	0	0	CFG_XREF_CLK0_IN	pr2_pru1_gpi5
E17	xref_clk1	0	0	CFG_XREF_CLK1_IN	pr2_pru1_gpi6

Manual IO Timings Modes must be used to guaranteed some IO timings for PRU-ICSS2 PRU1 IOSET1 Direct Output mode. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-165 Manual Functions Mapping for PRU-ICSS2 PRU1 IOSET1 Direct Output mode for a definition of the Manual modes.

Table 7-165 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-165 Manual Functions Mapping for PRU-ICSS2 PRU1 IOSET1 Direct Output mode

BALL	BALL NAME	PR2_PRU1_DIR_OUT_MANUAL1		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	13
U3	RMII_MHZ_50_CLK	2306	100	CFG_RMII_MHZ_50_CLK_OUT	pr2_pru1_gpo2
U4	mdio_d	1900	2000	CFG_MDIO_D_OUT	pr2_pru1_gpo1
V1	mdio_mclk	2000	1100	CFG_MDIO_MCLK_OUT	pr2_pru1_gpo0
U5	rgmii0_rxc	2000	1200	CFG_RGMII0_RXC_OUT	pr2_pru1_gpo11
V5	rgmii0_rxctl	2000	1700	CFG_RGMII0_RXCTL_OUT	pr2_pru1_gpo12
W2	rgmii0_rxd0	2000	1000	CFG_RGMII0_RXD0_OUT	pr2_pru1_gpo16
Y2	rgmii0_rxd1	2200	1000	CFG_RGMII0_RXD1_OUT	pr2_pru1_gpo15
V3	rgmii0_rxd2	2200	1300	CFG_RGMII0_RXD2_OUT	pr2_pru1_gpo14
V4	rgmii0_rxd3	2250	1100	CFG_RGMII0_RXD3_OUT	pr2_pru1_gpo13
W9	rgmii0_txc	2350	1000	CFG_RGMII0_TXC_OUT	pr2_pru1_gpo5
V9	rgmii0_txctl	2000	1200	CFG_RGMII0_TXCTL_OUT	pr2_pru1_gpo6
U6	rgmii0_txd0	2000	1500	CFG_RGMII0_TXD0_OUT	pr2_pru1_gpo10
V6	rgmii0_txd1	1850	1000	CFG_RGMII0_TXD1_OUT	pr2_pru1_gpo9
U7	rgmii0_txd2	2100	1100	CFG_RGMII0_TXD2_OUT	pr2_pru1_gpo8
V7	rgmii0_txd3	2200	1000	CFG_RGMII0_TXD3_OUT	pr2_pru1_gpo7
V2	uart3_rxd	2000	1600	CFG_UART3_RXD_OUT	pr2_pru1_gpo3
Y1	uart3_txd	2000	1000	CFG_UART3_TXD_OUT	pr2_pru1_gpo4
F11	vout1_d0	400	0	CFG_VOUT1_D0_OUT	pr2_pru1_gpo18
G10	vout1_d1	0	0	CFG_VOUT1_D1_OUT	pr2_pru1_gpo19
F10	vout1_d2	200	0	CFG_VOUT1_D2_OUT	pr2_pru1_gpo20
E11	vout1_vsync	500	0	CFG_VOUT1_VSYNC_OUT	pr2_pru1_gpo17

Manual IO Timings Modes must be used to guaranteed some IO timings for PRU-ICSS2 PRU1 IOSET2 Direct Output mode. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-166 Manual Functions Mapping for PRU-ICSS2 PRU1 IOSET2 Direct Output mode for a definition of the Manual modes.

Table 7-166 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-166 Manual Functions Mapping for PRU-ICSS2 PRU1 IOSET2 Direct Output mode

BALL	BALL NAME	PR2_PRU1_DIR_OUT_MANUAL2		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	13
C14	mcasp1_aclkx	200	800	CFG_MCASP1_ACLKX_OUT	pr2_pru1_gpo7
G12	mcasp1_axr0	200	1000	CFG_MCASP1_AXR0_OUT	pr2_pru1_gpo8
F12	mcasp1_axr1	0	1110	CFG_MCASP1_AXR1_OUT	pr2_pru1_gpo9
B13	mcasp1_axr10	0	2500	CFG_MCASP1_AXR10_OUT	pr2_pru1_gpo12
A12	mcasp1_axr11	0	1900	CFG_MCASP1_AXR11_OUT	pr2_pru1_gpo13
E14	mcasp1_axr12	0	2300	CFG_MCASP1_AXR12_OUT	pr2_pru1_gpo14
A13	mcasp1_axr13	200	1200	CFG_MCASP1_AXR13_OUT	pr2_pru1_gpo15
G14	mcasp1_axr14	200	1100	CFG_MCASP1_AXR14_OUT	pr2_pru1_gpo16
E11	vout1_vsync	0	0	CFG_VOUT1_VSYNC_OUT	pr2_pru1_gpo17
F11	vout1_d0	0	0	CFG_VOUT1_D0_OUT	pr2_pru1_gpo18
G10	vout1_d1	0	0	CFG_VOUT1_D1_OUT	pr2_pru1_gpo19
F10	vout1_d2	0	0	CFG_VOUT1_D2_OUT	pr2_pru1_gpo20
B12	mcasp1_axr8	200	1600	CFG_MCASP1_AXR8_OUT	pr2_pru1_gpo10
A11	mcasp1_axr9	0	1900	CFG_MCASP1_AXR9_OUT	pr2_pru1_gpo11
D17	mcasp4_axr1	0	700	CFG_MCASP4_AXR1_OUT	pr2_pru1_gpo0
AA3	mcasp5_aclkx	1400	4000	CFG_MCASP5_ACLKX_OUT	pr2_pru1_gpo1
AB3	mcasp5_axr0	1500	3000	CFG_MCASP5_AXR0_OUT	pr2_pru1_gpo3
AA4	mcasp5_axr1	1500	1900	CFG_MCASP5_AXR1_OUT	pr2_pru1_gpo4
AB9	mcasp5_fsx	1300	2700	CFG_MCASP5_FSX_OUT	pr2_pru1_gpo2
D18	xref_clk0	0	160	CFG_XREF_CLK0_OUT	pr2_pru1_gpo5
E17	xref_clk1	0	0	CFG_XREF_CLK1_OUT	pr2_pru1_gpo6

Manual IO Timings Modes must be used to guaranteed some IO timings for PRU-ICSS2 PRU0 IOSET1 Parallel Capture Mode. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-167 Manual Functions Mapping for PRU-ICSS2 PRU0 IOSET1 Parallel Capture Mode for a definition of the Manual modes.

Table 7-167 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-167 Manual Functions Mapping for PRU-ICSS2 PRU0 IOSET1 Parallel Capture Mode

BALL	BALL NAME	PR2_PRU0_PAR_CAP_MANUAL1		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	12
D7	vout1_d10	1994	0	CFG_VOUT1_D10_IN	pr2_pru0_gpi7
D8	vout1_d11	1888	0	CFG_VOUT1_D11_IN	pr2_pru0_gpi8
A5	vout1_d12	2024	0	CFG_VOUT1_D12_IN	pr2_pru0_gpi9
C6	vout1_d13	1819	0	CFG_VOUT1_D13_IN	pr2_pru0_gpi10
C8	vout1_d14	1971	0	CFG_VOUT1_D14_IN	pr2_pru0_gpi11
C7	vout1_d15	2147	0	CFG_VOUT1_D15_IN	pr2_pru0_gpi12
B7	vout1_d16	2016	0	CFG_VOUT1_D16_IN	pr2_pru0_gpi13
B8	vout1_d17	1546	0	CFG_VOUT1_D17_IN	pr2_pru0_gpi14
A7	vout1_d18	1557	0	CFG_VOUT1_D18_IN	pr2_pru0_gpi15
A8	vout1_d19	0	0	CFG_VOUT1_D19_IN	pr2_pru0_gpi16
G11	vout1_d3	1734	0	CFG_VOUT1_D3_IN	pr2_pru0_gpi0
E9	vout1_d4	1861	0	CFG_VOUT1_D4_IN	pr2_pru0_gpi1
F9	vout1_d5	1684	0	CFG_VOUT1_D5_IN	pr2_pru0_gpi2
F8	vout1_d6	1547	0	CFG_VOUT1_D6_IN	pr2_pru0_gpi3
E7	vout1_d7	1504	0	CFG_VOUT1_D7_IN	pr2_pru0_gpi4
E8	vout1_d8	2238	0	CFG_VOUT1_D8_IN	pr2_pru0_gpi5
D9	vout1_d9	2133	0	CFG_VOUT1_D9_IN	pr2_pru0_gpi6

Manual IO Timings Modes must be used to guaranteed some IO timings for PRU-ICSS2 PRU0 IOSET2 Parallel Capture Mode. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-168 Manual Functions Mapping for PRU-ICSS2 PRU0 IOSET2 Parallel Capture Mode for a definition of the Manual modes.

Table 7-168 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-168 Manual Functions Mapping for PRU-ICSS2 PRU0 IOSET2 Parallel Capture Mode

BALL	BALL NAME	PR2_PRU0_PAR_CAP_MANUAL2		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	12
AC5	gpio6_10	4125	481	CFG_GPIO6_10_IN	pr2_pru0_gpi0
AB4	gpio6_11	3935	997	CFG_GPIO6_11_IN	pr2_pru0_gpi1
C15	mcasp2_axr2	0	0	CFG_MCASP2_AXR2_IN	pr2_pru0_gpi16
B18	mcasp3_aclkx	571	0	CFG_MCASP3_ACLKX_IN	pr2_pru0_gpi12
B19	mcasp3_axr0	1570	0	CFG_MCASP3_AXR0_IN	pr2_pru0_gpi14
C17	mcasp3_axr1	1405	0	CFG_MCASP3_AXR1_IN	pr2_pru0_gpi15
F15	mcasp3_fsx	1946	0	CFG_MCASP3_FSX_IN	pr2_pru0_gpi13
AD4	mmc3_clk	4093	1066	CFG_MMC3_CLK_IN	pr2_pru0_gpi2
AC4	mmc3_cmd	4043	921	CFG_MMC3_CMD_IN	pr2_pru0_gpi3
AC7	mmc3_dat0	4010	864	CFG_MMC3_DAT0_IN	pr2_pru0_gpi4
AC6	mmc3_dat1	3817	1643	CFG_MMC3_DAT1_IN	pr2_pru0_gpi5
AC9	mmc3_dat2	4040	673	CFG_MMC3_DAT2_IN	pr2_pru0_gpi6
AC3	mmc3_dat3	3923	1478	CFG_MMC3_DAT3_IN	pr2_pru0_gpi7
AC8	mmc3_dat4	4096	729	CFG_MMC3_DAT4_IN	pr2_pru0_gpi8
AD6	mmc3_dat5	3926	1271	CFG_MMC3_DAT5_IN	pr2_pru0_gpi9
AB8	mmc3_dat6	4004	929	CFG_MMC3_DAT6_IN	pr2_pru0_gpi10
AB5	mmc3_dat7	3963	666	CFG_MMC3_DAT7_IN	pr2_pru0_gpi11

Manual IO Timings Modes must be used to guaranteed some IO timings for PRU-ICSS2 PRU1 IOSET1 Parallel Capture Mode. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-169 Manual Functions Mapping for PRU-ICSS2 PRU1 IOSET1 Parallel Capture Mode for a definition of the Manual modes.

Table 7-169 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-169 Manual Functions Mapping for PRU-ICSS2 PRU1 IOSET1 Parallel Capture Mode

BALL	BALL NAME	PR2_PRU1_PAR_CAP_MANUAL1		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	12
U3	RMII_MHZ_50_CLK	1717	0	CFG_RMII_MHZ_50_CLK_IN	pr2_pru1_gpi2
U4	mdio_d	2088	0	CFG_MDIO_D_IN	pr2_pru1_gpi1
V1	mdio_mclk	1321	0	CFG_MDIO_MCLK_IN	pr2_pru1_gpi0
U5	rgmii0_rxc	1287	0	CFG_RGMII0_RXC_IN	pr2_pru1_gpi11
V5	rgmii0_rxctl	2456	0	CFG_RGMII0_RXCTL_IN	pr2_pru1_gpi12
W2	rgmii0_rxd0	0	0	CFG_RGMII0_RXD0_IN	pr2_pru1_gpi16
Y2	rgmii0_rxd1	2157	0	CFG_RGMII0_RXD1_IN	pr2_pru1_gpi15
V3	rgmii0_rxd2	2008	0	CFG_RGMII0_RXD2_IN	pr2_pru1_gpi14
V4	rgmii0_rxd3	2271	0	CFG_RGMII0_RXD3_IN	pr2_pru1_gpi13
W9	rgmii0_txc	1851	0	CFG_RGMII0_TXC_IN	pr2_pru1_gpi5
V9	rgmii0_txctl	1875	0	CFG_RGMII0_TXCTL_IN	pr2_pru1_gpi6
U6	rgmii0_txd0	1685	0	CFG_RGMII0_TXD0_IN	pr2_pru1_gpi10
V6	rgmii0_txd1	2131	0	CFG_RGMII0_TXD1_IN	pr2_pru1_gpi9
U7	rgmii0_txd2	1734	0	CFG_RGMII0_TXD2_IN	pr2_pru1_gpi8
V7	rgmii0_txd3	1764	0	CFG_RGMII0_TXD3_IN	pr2_pru1_gpi7
V2	uart3_rxd	1654	0	CFG_UART3_RXD_IN	pr2_pru1_gpi3
Y1	uart3_txd	1242	0	CFG_UART3_TXD_IN	pr2_pru1_gpi4

Manual IO Timings Modes must be used to guaranteed some IO timings for PRU-ICSS2 PRU1 IOSET2 Parallel Capture Mode. See Table 7-2 Modes Summary for a list of IO timings requiring the use of Manual IO Timings Modes. See Table 7-170 Manual Functions Mapping for PRU-ICSS2 PRU1 IOSET2 Parallel Capture Mode for a definition of the Manual modes.

Table 7-170 lists the A_DELAY and G_DELAY values needed to calculate the correct values to be set in the CFG_x registers.

Table 7-170 Manual Functions Mapping for PRU-ICSS2 PRU1 IOSET2 Parallel Capture Mode

BALL	BALL NAME	PR2_PRU1_PAR_CAP_MANUAL2		CFG REGISTER	MUXMODE
BALL	BALL NAME	A_DELAY (ps)	G_DELAY (ps)	CFG REGISTER	12
C14	mcasp1_aclkx	1928	0	CFG_MCASP1_ACLKX_IN	pr2_pru1_gpi7
G12	mcasp1_axr0	2413	0	CFG_MCASP1_AXR0_IN	pr2_pru1_gpi8
F12	mcasp1_axr1	2523	25	CFG_MCASP1_AXR1_IN	pr2_pru1_gpi9
B13	mcasp1_axr10	2607	0	CFG_MCASP1_AXR10_IN	pr2_pru1_gpi12
A12	mcasp1_axr11	2669	92	CFG_MCASP1_AXR11_IN	pr2_pru1_gpi13
E14	mcasp1_axr12	2225	0	CFG_MCASP1_AXR12_IN	pr2_pru1_gpi14
A13	mcasp1_axr13	2315	0	CFG_MCASP1_AXR13_IN	pr2_pru1_gpi15
G14	mcasp1_axr14	0	0	CFG_MCASP1_AXR14_IN	pr2_pru1_gpi16
B12	mcasp1_axr8	2201	0	CFG_MCASP1_AXR8_IN	pr2_pru1_gpi10
A11	mcasp1_axr9	2293	278	CFG_MCASP1_AXR9_IN	pr2_pru1_gpi11
D17	mcasp4_axr1	1759	0	CFG_MCASP4_AXR1_IN	pr2_pru1_gpi0
AA3	mcasp5_aclkx	3732	1810	CFG_MCASP5_ACLKX_IN	pr2_pru1_gpi1
AB3	mcasp5_axr0	3776	2255	CFG_MCASP5_AXR0_IN	pr2_pru1_gpi3
AA4	mcasp5_axr1	3886	1923	CFG_MCASP5_AXR1_IN	pr2_pru1_gpi4
AB9	mcasp5_fsx	3800	1449	CFG_MCASP5_FSX_IN	pr2_pru1_gpi2
D18	xref_clk0	1375	21	CFG_XREF_CLK0_IN	pr2_pru1_gpi5
E17	xref_clk1	1320	0	CFG_XREF_CLK1_IN	pr2_pru1_gpi6

7.27 System and Miscellaneous interfaces

The Device includes the following System and Miscellaneous interfaces:

Sysboot Interface
System DMA Interface
Interrupt Controllers (INTC) Interface
Observability Signal (OBS) Interface

7.28 Test Interfaces

The Device includes the following Test interfaces:

IEEE 1149.1 Standard-Test-Access Port (JTAG)
Trace Port Interface Unit (TPIU)
Advanced Event Triggering Interface (AET)

7.28.1 IEEE 1149.1 Standard-Test-Access Port (JTAG)

The JTAG (IEEE Standard 1149.1-1990 Standard-Test-Access Port and Boundary Scan Architecture) interface is used for BSDL testing and emulation of the device. The trstn pin only needs to be released when it is necessary to use a JTAG controller to debug the device or exercise the device's boundary scan functionality. For maximum reliability, the device includes an internal Pulldown (IPD) on the trstn pin to ensure that trstn is always asserted upon power up and the device's internal emulation logic is always properly initialized. JTAG controllers from Texas Instruments actively drive trstn high. However, some third-party JTAG controllers may not drive trstn high but expect the use of a Pullup resistor on trstn. When using this type of JTAG controller, assert trstn to initialize the device after powerup and externally drive trstn high before attempting any emulation or boundary-scan operations.

The main JTAG features include:

32KB embedded trace buffer (ETB)
5-pin system trace interface for debug
Supports Advanced Event Triggering (AET)
All processors can be emulated via JTAG ports
All functions on EMU pins of the device:
- EMU[1:0] - cross-triggering, boot mode (WIR), STM trace
- EMU[4:2] - STM trace only (single direction)

7.28.1.1 JTAG Electrical Data/Timing

Table 7-171, Table 7-172 and Figure 7-113 assume testing over the recommended operating conditions and electrical characteristic conditions below.

Table 7-171 Timing Requirements for IEEE 1149.1 JTAG

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
1	t_c(TCK)	Cycle time, TCK	62.29	ns
1a	t_w(TCKH)	Pulse duration, TCK high (40% of t_c)	24.92	ns
1b	t_w(TCKL)	Pulse duration, TCK low (40% of t_c)	24.92	ns
3	t_su(TDI-TCK)	Input setup time, TDI valid to TCK high	6.23	ns
3	t_su(TMS-TCK)	Input setup time, TMS valid to TCK high	6.23	ns
4	t_h(TCK-TDI)	Input hold time, TDI valid from TCK high	31.15	ns
4	t_h(TCK-TMS)	Input hold time, TMS valid from TCK high	31.15	ns

Table 7-172 Switching Characteristics Over Recommended Operating Conditions for IEEE 1149.1 JTAG

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
2	t_d(TCKL-TDOV)	Delay time, TCK low to TDO valid	0	30.5	ns

Figure 7-113 JTAG Timing

Table 7-173, Table 7-174 and Figure 7-114 assume testing over the recommended operating conditions and electrical characteristic conditions below.

Table 7-173 Timing Requirements for IEEE 1149.1 JTAG With RTCK

NO.	PARAMETER	DESCRIPTION	MIN	UNIT
1	t_c(TCK)	Cycle time, TCK	62.29	ns
1a	t_w(TCKH)	Pulse duration, TCK high (40% of t_c)	24.92	ns
1b	t_w(TCKL)	Pulse duration, TCK low (40% of t_c)	24.92	ns
3	t_su(TDI-TCK)	Input setup time, TDI valid to TCK high	6.23	ns
3	t_su(TMS-TCK)	Input setup time, TMS valid to TCK high	6.23	ns
4	t_h(TCK-TDI)	Input hold time, TDI valid from TCK high	31.15	ns
4	t_h(TCK-TMS)	Input hold time, TMS valid from TCK high	31.15	ns

Table 7-174 Switching Characteristics Over Recommended Operating Conditions for
IEEE 1149.1 JTAG With RTCK

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
5	t_d(TCK-RTCK)	Delay time, TCK to RTCK with no selected subpaths (i.e. ICEPick is the only tap selected - when the ARM is in the scan chain, the delay time is a function of the ARM functional clock).	0	27	ns
6	t_c(RTCK)	Cycle time, RTCK	62.29		ns
7	t_w(RTCKH)	Pulse duration, RTCK high (40% of t_c)	24.92		ns
8	t_w(RTCKL)	Pulse duration, RTCK low (40% of t_c)	24.92		ns

Figure 7-114 JTAG With RTCK Timing

7.28.2 Trace Port Interface Unit (TPIU)

CAUTION

The I/O timings provided in this section are valid only if signals within a single IOSET are used. The IOSETs are defined in Table 7-176.

7.28.2.1 TPIU PLL DDR Mode

Table 7-175 and Figure 7-115 assume testing over the recommended operating conditions and electrical characteristic conditions below.

Table 7-175 Switching Characteristics for TPIU

NO.	PARAMETER	DESCRIPTION	MIN	MAX	UNIT
TPIU1	t_c(clk)	Cycle time, TRACECLK period	5.56		ns
TPIU4	t_d(clk-ctlV)	Skew time, TRACECLK transition to TRACECTL transition	-1.61	1.98	ns
TPIU5	t_d(clk-dataV)	Skew time, TRACECLK transition to TRACEDATA[17:0]	-1.61	1.98	ns

Figure 7-115 TPIU-PLL DDR Transmit Mode^⁽¹⁾

In d[X:0], X is equal to 15 or 17.

In Table 7-176 are presented the specific groupings of signals (IOSET) for use with TPIU signals.

Table 7-176 TPIU IOSETs

SIGNALS	IOSET1		IOSET2
SIGNALS	BALL	MUX	BALL	MUX
emu19	E6	5	A10	2
emu18	F5	5	B9	2
emu17	E4	5	A9	2
emu16	C1	5	C9	2
emu15	F4	5	A8	2
emu14	D2	5	C7	2
emu13	E2	5	C8	2
emu12	D1	5	C6	2
emu11	F3	5	A5	2
emu10	F2	5	D8	2
emu9	G6	5	E7	2
emu8	G1	5	F8	2
emu7	H7	5	F9	2
emu6	G2	5	E9	2
emu5	E1	5	G11	2
emu4	A7	2	A7	2
emu3	D7	2	D7	2
emu2	F10	2	F10	2
emu1	D24	0	D24	0
emu0	G21	0	G21	0

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サーマルパッド・メカニカル・データ

発注情報

7 Timing Requirements and Switching Characteristics

7.1 Timing Test Conditions

7.2 Interface Clock Specifications

7.2.1 Interface Clock Terminology

7.2.2 Interface Clock Frequency

7.3 Timing Parameters and Information

Table 7-1 Timing Parameters

7.3.1 Parameter Information

7.3.1.1 1.8V and 3.3V Signal Transition Levels

7.3.1.2 1.8V and 3.3V Signal Transition Rates

7.3.1.3 Timing Parameters and Board Routing Analysis

7.4 Recommended Clock and Control Signal Transition Behavior

7.5 Virtual and Manual I/O Timing Modes

Table 7-2 Modes Summary

7.6 Video Input Ports (VIP)

Table 7-3 Timing Requirements for VIP (3)(4)(5)

Table 7-4 VIN1 IOSETs

Table 7-5 VIN2 IOSETs

Table 7-6 Manual Functions Mapping for VIP1 1A IOSET7 and 2A IOSET10

Table 7-7 Manual Functions Mapping for VIN2A (IOSET4/5/6)

Table 7-8 Manual Functions Mapping for VIN2B (IOSET7/8/9)

Table 7-9 Manual Functions Mapping for VIN1A (IOSET2/3/4) and VIN1B (IOSET4/7) and VIN2B (IOSET1/10)

Table 7-10 Manual Functions Mapping for VIN1A (IOSET5/6) and VIN2A (IOSET7/8/9)

Table 7-11 Manual Functions Mapping for VIN1B (IOSET6/7)

Table 7-12 Manual Functions Mapping for VIN1B (IOSET5) and VIN2B (IOSET2/11)

Table 7-13 Manual Functions Mapping for VIN1A (IOSET8/9/10)

7.7 Display Subsystem - Video Output Ports

Table 7-14 DPI Video Output i (i = 1..3) Default Switching Characteristics

Table 7-15 DPI Video Output i (i = 1..3) Alternate Switching Characteristics(2)

Table 7-16 VOUT2 IOSETs

Table 7-17 Virtual Functions Mapping for DSS VOUT1

Table 7-18 Manual Functions Mapping for DSS VOUT1

Table 7-19 Manual Functions Mapping for DSS VOUT2 IOSET1

Table 7-20 Manual Functions Mapping for DSS VOUT2 IOSET2

Table 7-21 Manual Functions Mapping for DSS VOUT3

7.8 Display Subsystem - High-Definition Multimedia Interface (HDMI)

7.9 Camera Serial Interface 2 CAL bridge (CSI2)

7.9.1 CSI-2 MIPI D-PHY-1.5 V and 1.8 V

7.10 External Memory Interface (EMIF)

7.11 General-Purpose Memory Controller (GPMC)

7.11.1 GPMC/NOR Flash Interface Synchronous Timing

Table 7-22 GPMC/NOR Flash Interface Timing Requirements - Synchronous Mode - Default

Table 7-23 GPMC/NOR Flash Interface Switching Characteristics - Synchronous Mode - Default

Table 7-24 GPMC/NOR Flash Interface Timing Requirements - Synchronous Mode - Alternate(1)

Table 7-25 GPMC/NOR Flash Interface Switching Characteristics - Synchronous Mode - Alternate(1)

7.11.2 GPMC/NOR Flash Interface Asynchronous Timing

Table 7-26 GPMC/NOR Flash Interface Timing Requirements - Asynchronous Mode

Table 7-27 GPMC/NOR Flash Interface Switching Characteristics - Asynchronous Mode

7.11.3 GPMC/NAND Flash Interface Asynchronous Timing

Table 7-28 GPMC/NAND Flash Interface Timing Requirements

Table 7-29 GPMC/NAND Flash Interface Switching Characteristics

Table 7-30 Virtual Functions Mapping for GPMC

7.12 Timers

7.13 Inter-Integrated Circuit Interface (I2C)

Table 7-31 Timing Requirements for I2C Input Timings(1)

Table 7-32 Timing Requirements for I2C HS-Mode (I2C3/4/5 Only)(1)

Table 7-33 Switching Characteristics Over Recommended Operating Conditions for I2C Output Timings(2)

7.14 HDQ / 1-Wire Interface (HDQ1W)

7.14.1 HDQ / 1-Wire - HDQ Mode

Table 7-34 HDQ/1-Wire Timing Requirements-HDQ Mode

Table 7-35 HDQ / 1-Wire Switching Characteristics - HDQ Mode

7.14.2 HDQ/1-Wire-1-Wire Mode

Table 7-36 HDQ / 1-Wire Timing Requirements - 1-Wire Mode

Table 7-37 HDQ / 1-Wire Switching Characteristics - 1-Wire Mode

7.15 Universal Asynchronous Receiver Transmitter (UART)

Table 7-38 Timing Requirements for UART

Table 7-39 Switching Characteristics Over Recommended Operating Conditions for UART

7.16 Multichannel Serial Peripheral Interface (McSPI)

Table 7-40 Timing Requirements for SPI - Master Mode (1)

Table 7-41 Timing Requirements for SPI - Slave Mode

Table 7-42 McSPI3/4 IOSETs

7.17 Quad Serial Peripheral Interface (QSPI)

Table 7-43 Switching Characteristics for QSPI

Table 7-44 Timing Requirements for QSPI(3)(2)

Table 7-45 Manual Functions Mapping for QSPI

7.18 Multichannel Audio Serial Port (McASP)

Table 7-3 Timing Requirements for VIP ^{⁽³⁾⁽⁴⁾⁽⁵⁾}

Table 7-15 DPI Video Output i (i = 1..3) Alternate Switching Characteristics^⁽²⁾

Table 7-24 GPMC/NOR Flash Interface Timing Requirements - Synchronous Mode - Alternate^⁽¹⁾

Table 7-25 GPMC/NOR Flash Interface Switching Characteristics - Synchronous Mode - Alternate^⁽¹⁾

Table 7-31 Timing Requirements for I2C Input Timings^⁽¹⁾

Table 7-32 Timing Requirements for I²C HS-Mode (I²C3/4/5 Only)^⁽¹⁾

Table 7-33 Switching Characteristics Over Recommended Operating Conditions for I2C Output Timings^⁽²⁾

Table 7-40 Timing Requirements for SPI - Master Mode ^⁽¹⁾

Table 7-44 Timing Requirements for QSPI^⁽³⁾^⁽²⁾

Table 7-46 Timing Requirements for McASP1^⁽¹⁾

Table 7-47 Timing Requirements for McASP2^⁽¹⁾

Table 7-48 Timing Requirements for McASP3/4/5/6/7/8^⁽¹⁾

Table 7-49 Switching Characteristics Over Recommended Operating Conditions for McASP1^⁽¹⁾

Table 7-50 Switching Characteristics Over Recommended Operating Conditions for McASP2 ^⁽¹⁾

Table 7-51 Switching Characteristics Over Recommended Operating Conditions for McASP3/4/5/6/7/8^⁽¹⁾

Table 7-63 Timing Requirements for DCANx Receive^⁽¹⁾

Table 7-64 Switching Characteristics Over Recommended Operating Conditions for DCANx Transmit ^⁽¹⁾

Table 7-81 Timing Requirements for GMAC RGMIIn Input Receive for 10/100/1000 Mbps ^⁽¹⁾

Table 7-83 Switching Characteristics for GMAC RGMIIn Output Transmit for 10/100/1000 Mbps ^⁽¹⁾