SWRS121E July   2012  – January 2016 CC2560B , CC2564

PRODUCTION DATA.  

  1. 1Device Overview
    1. 1.1 Features
    2. 1.2 Applications
    3. 1.3 Description
    4. 1.4 Functional Block Diagram
  2. 2Revision History
  3. 3Device Comparison
  4. 4Terminal Configuration and Functions
    1. 4.1 Pin Attributes
    2. 4.2 Connections for Unused Signals
  5. 5Specifications
    1. 5.1 Absolute Maximum Ratings
      1. 5.1.1 ESD Ratings
      2. 5.1.2 Power-On Hours
    2. 5.2 Recommended Operating Conditions
    3. 5.3 Power Consumption Summary
      1. 5.3.1 Static Current Consumption
      2. 5.3.2 Dynamic Current Consumption
        1. 5.3.2.1 Current Consumption for Different Bluetooth BR/EDR Scenarios
        2. 5.3.2.2 Current Consumption for Different LE Scenarios
    4. 5.4 Electrical Characteristics
    5. 5.5 Timing and Switching Characteristics
      1. 5.5.1 Device Power Supply
        1. 5.5.1.1 Power Sources
        2. 5.5.1.2 Device Power-Up and Power-Down Sequencing
        3. 5.5.1.3 Power Supplies and Shutdown - Static States
        4. 5.5.1.4 I/O States in Various Power Modes
        5. 5.5.1.5 nSHUTD Requirements
      2. 5.5.2 Clock Specifications
        1. 5.5.2.1 Slow Clock Requirements
        2. 5.5.2.2 External Fast Clock Crystal Requirements and Operation
        3. 5.5.2.3 Fast Clock Source Requirements (-40°C to +85°C)
      3. 5.5.3 Peripherals
        1. 5.5.3.1 UART
        2. 5.5.3.2 PCM
      4. 5.5.4 RF Performance
        1. 5.5.4.1 Bluetooth BR/EDR RF Performance
          1. 5.5.4.1.1 Bluetooth Receiver—In-Band Signals
          2. 5.5.4.1.2 Bluetooth Receiver—General Blocking
          3. 5.5.4.1.3 Bluetooth Transmitter—GFSK
          4. 5.5.4.1.4 Bluetooth Transmitter—EDR
          5. 5.5.4.1.5 Bluetooth Modulation—GFSK
          6. 5.5.4.1.6 Bluetooth Modulation—EDR
          7. 5.5.4.1.7 Bluetooth Transmitter—Out-of-Band and Spurious Emissions
        2. 5.5.4.2 Bluetooth LE RF Performance
          1. 5.5.4.2.1 BLE Receiver—In-Band Signals
          2. 5.5.4.2.2 BLE Receiver—General Blocking
          3. 5.5.4.2.3 BLE Transmitter
          4. 5.5.4.2.4 BLE Modulation
          5. 5.5.4.2.5 BLE Transceiver, Out-Of-Band and Spurious Emissions
  6. 6Detailed Description
    1. 6.1 Overview
    2. 6.2 Functional Block Diagram
    3. 6.3 Clock Inputs
      1. 6.3.1 Slow Clock
      2. 6.3.2 Fast Clock Using External Clock Source
        1. 6.3.2.1 External FREF DC-Coupled
        2. 6.3.2.2 External FREF Sine Wave, AC-Coupled
        3. 6.3.2.3 Fast Clock Using External Crystal
    4. 6.4 Functional Blocks
      1. 6.4.1 RF
        1. 6.4.1.1 Receiver
        2. 6.4.1.2 Transmitter
      2. 6.4.2 Host Controller Interface
        1. 6.4.2.1 4-Wire UART Interface—H4 Protocol
        2. 6.4.2.2 3-Wire UART Interface—H5 Protocol (CC2560B and CC2564B Devices)
      3. 6.4.3 Digital Codec Interface
        1. 6.4.3.1 Hardware Interface
        2. 6.4.3.2 I2S
        3. 6.4.3.3 Data Format
        4. 6.4.3.4 Frame Idle Period
        5. 6.4.3.5 Clock-Edge Operation
        6. 6.4.3.6 Two-Channel Bus Example
        7. 6.4.3.7 Improved Algorithm For Lost Packets
        8. 6.4.3.8 Bluetooth and Codec Clock Mismatch Handling
      4. 6.4.4 Assisted Modes (CC2560B and CC2564B Devices)
        1. 6.4.4.1 Assisted HFP 1.6 (WBS)
        2. 6.4.4.2 Assisted A2DP
          1. 6.4.4.2.1 Assisted A2DP Sink
          2. 6.4.4.2.2 Assisted A2DP Source
    5. 6.5 Bluetooth BR/EDR Features
    6. 6.6 Bluetooth LE Description
    7. 6.7 Bluetooth Transport Layers
    8. 6.8 Changes from CC2560A and CC2564 to CC2560B and CC2564B Devices
  7. 7Applications, Implementation, and Layout
    1. 7.1 Reference Design Schematics and BOM for Power and Radio Connections
  8. 8Device and Documentation Support
    1. 8.1 Device Support
      1. 8.1.1 Development Support
      2. 8.1.2 Device Nomenclature
    2. 8.2 Documentation Support
    3. 8.3 Related Links
    4. 8.4 Community Resources
    5. 8.5 Trademarks
    6. 8.6 Electrostatic Discharge Caution
    7. 8.7 Glossary
  9. 9Mechanical, Packaging, and Orderable Information
    1. 9.1 mrQFN Mechanical Data
    2. 9.2 Packaging and Ordering
      1. 9.2.1 Package and Ordering Information
      2. 9.2.2 Empty Tape Portion
      3. 9.2.3 Device Quantity and Direction
      4. 9.2.4 Insertion of Device
      5. 9.2.5 Tape Specification
      6. 9.2.6 Reel Specification
      7. 9.2.7 Packing Method
      8. 9.2.8 Packing Specification
        1. 9.2.8.1 Reel Box
        2. 9.2.8.2 Reel Box Material
        3. 9.2.8.3 Shipping Box
        4. 9.2.8.4 Shipping Box Material

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発注情報

5 Specifications

Unless otherwise indicated, all measurements are taken at the device pins of the TI test evaluation board (EVB). All specifications are over process, voltage, and temperature, unless otherwise indicated.

5.1 Absolute Maximum Ratings(1)

Over operating free-air temperature range (unless otherwise indicated). All parameters are measured as follows: VDD_IN = 3.6 V and VDD_IO = 1.8 V (unless otherwise indicated).
PARAMETERS MIN MAX UNIT
Supply voltage range VDD_IN –0.5 4.8 V(2)
VDDIO_1.8V –0.5 2.145 V
Input voltage to analog pins(3) –0.5 2.1 V
Input voltage to all other pins –0.5 VDD_IO + 0.5 V
Bluetooth RF inputs 10 dBm
Operating ambient temperature range, TA(4) –40 85 °C
Storage temperature range, Tstg –55 125 °C
(1) Stresses beyond those listed under absolute maximum ratings may cause permanent damage to the device. These are stress ratings only and functional operation of the device at these or any other conditions beyond those indicated under recommended operating conditions is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
(2) Maximum allowed depends on accumulated time at that voltage: VDD_IN is defined in Section 7.1, Reference Design for Power and Radio Connections.
(3) Analog pins: BT_RF, XTALP, and XTALM
(4) The reference design supports a temperature range of –20°C to 70°C because of the operating conditions of the crystal.

5.1.1 ESD Ratings

VALUE UNIT
V(ESD) electrostatic discharge Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001(1) ±500 V
Charged device model (CDM), per JEDEC specification JESD22- ±YYY V C101(2) ±250
(1) JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.
(2) JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.

5.1.2 Power-On Hours

DEVICE CONDITIONS POWER-ON HOURS
CC256x Duty cycle = 25% active and 75% sleep
Tambient = 70ºC		 15,400 (7 Years)

5.2 Recommended Operating Conditions


RATING CONDITION SYM MIN MAX UNIT
Power supply voltage VDD_IN 2.2 4.8 V
I/O power supply voltage VDD_IO 1.62 1.92 V
High-level input voltage Default VIH 0.65 x VDD_IO VDD_IO V
Low-level input voltage Default VIL 0 0.35 x VDD_IO V
I/O input rise and all times,10% to 90% — asynchronous mode tr and tf 1 10 ns
I/O input rise and fall times, 10% to 90% — synchronous mode (PCM) 1 2.5 ns
Voltage dips on VDD_IN (VBAT)
duration = 577 μs to 2.31 ms, period = 4.6 ms		 400 mV
Maximum ambient operating temperature(1) (2) –40 85 °C
(1) The device can be reliably operated for 7 years at Tambient of 85°C, assuming 25% active mode and 75% sleep mode (15,400 cumulative active power-on hours).
(2) A crystal-based solution is limited by the temperature range required for the crystal to meet 20 ppm.

5.3 Power Consumption Summary

5.3.1 Static Current Consumption


OPERATIONAL MODE MIN TYP MAX UNIT
Shutdown mode(1) 1 7 µA
Deep sleep mode(2) 40 105 µA
Total I/O current consumption in active mode 1 mA
Continuous transmission—GFSK(3) 107 mA
Continuous transmission—EDR(4)(5) 112.5 mA
(1) VBAT + VIO + VSHUTDOWN
(2) VBAT + VIO
(3) At maximum output power (10 dBm)
(4) At maximum output power (8 dBm)
(5) Both π/4 DQPSK and 8DPSK

5.3.2 Dynamic Current Consumption

5.3.2.1 Current Consumption for Different Bluetooth BR/EDR Scenarios


Conditions: VDD_IN = 3.6 V, 25°C, 26-MHz XTAL, nominal unit, 10-dBm output power
OPERATIONAL MODE MASTER AND SLAVE AVERAGE CURRENT UNIT
Synchronous connection oriented (SCO) link HV3 Master and slave 13.7 mA
Extended SCO (eSCO) link EV3 64 kbps, no retransmission Master and slave 13.2 mA
eSCO link 2-EV3 64 kbps, no retransmission Master and slave 10 mA
GFSK full throughput: TX = DH1, RX = DH5 Master and slave 40.5 mA
EDR full throughput: TX = 2-DH1, RX = 2-DH5 Master and slave 41.2 mA
EDR full throughput: TX = 3-DH1, RX = 3-DH5 Master and slave 41.2 mA
Sniff, four attempt, 1.28 seconds Master and slave 145 μA
Page or inquiry scan 1.28 seconds, 11.25 ms Master and slave 320 μA
Page (1.28 seconds) and inquiry (2.56 seconds) scans, 11.25 ms Master and slave 445 μA
A2DP source Master 13.9 mA
A2DP sink Master 15.2 mA
Assisted A2DP source Master 16.9 mA
Assisted A2DP sink Master 18.1 mA
Assisted WBS EV3; retransmit effort = 2;
maximum latency = 8 ms		 Master and slave 17.5 and 18.5 mA
Assisted WBS 2EV3; retransmit effort = 2;
maximum latency = 12 ms		 Master and slave 11.9 and 13 mA

5.3.2.2 Current Consumption for Different LE Scenarios

Conditions: VDD_IN = 3.6 V, 25°C, 26-MHz fast clock, nominal unit, 10-dBm output power


MODE DESCRIPTION AVERAGE CURRENT UNIT
Advertising, nonconnectable Advertising in all three channels
1.28-seconds advertising interval
15 bytes advertise data 		114 µA
Advertising, discoverable Advertising in all three channels
1.28-seconds advertising interval
15 bytes advertise data 		138 µA
Scanning Listening to a single frequency per window
1.28-seconds scan interval
11.25-ms scan window 		324 µA
Connected Master role 500-ms connection interval
0-ms slave connection latency
Empty TX and RX LL packets		 169 µA
Slave role 199

5.4 Electrical Characteristics


RATING CONDITION MIN MAX UNIT
High-level output voltage, VOH At 2, 4, 8 mA 0.8 x VDD_IO VDD_IO V
At 0.1 mA VDD_IO – 0.2 VDD_IO
Low-level output voltage, VOL At 2, 4, 8 mA 0 0.2 x VDD_IO V
At 0.1 mA 0 0.2
I/O input impedance Resistance 1
Capacitance 5 pF
Output rise and fall times, 10% to 90% (digital pins) CL = 20 pF 10 ns
I/O pull currents PCM-I2S bus, TX_DBG PU typ = 6.5 3.5 9.7 μA
PD typ = 27 9.5 55
All others PU typ = 100 50 300
PD typ = 100 50 360

5.5 Timing and Switching Characteristics

5.5.1 Device Power Supply

The CC256x power-management hardware and software algorithms provide significant power savings, which is a critical parameter in an MCU-based system.

The power-management module is optimized for drawing extremely low currents.

5.5.1.1 Power Sources

The CC256x device requires two power sources:

  • VDD_IN: main power supply for the device
  • VDD_IO: power source for the 1.8-V I/O ring

The HCI module includes several on-chip voltage regulators for increased noise immunity and can be connected directly to the battery.

5.5.1.2 Device Power-Up and Power-Down Sequencing

The device includes the following power-up requirements (see Figure 5-1):

  • nSHUTD must be low. VDD_IN and VDD_IO are don't-care when nSHUTD is low. However, signals are not allowed on the I/O pins if I/O power is not supplied, because the I/Os are not fail-safe. Exceptions are SLOW_CLK_IN and AUD_xxx, which are fail-safe and can tolerate external voltages with no VDD_IO and VDD_IN.
  • VDD_IO and VDD_IN must be stable before releasing nSHUTD.
  • The fast clock must be stable within 20 ms of nSHUTD going high.
  • The slow clock must be stable within 2 ms of nSHUTD going high.

The device indicates that the power-up sequence is complete by asserting RTS low, which occurs up to 100 ms after nSHUTD goes high. If RTS does not go low, the device is not powered up. In this case, ensure that the sequence and requirements are met.

CC2560A CC2560B CC2564 CC2564B SWRS098-008.gif Figure 5-1 Power-Up and Power-Down Sequence

5.5.1.3 Power Supplies and Shutdown – Static States

The nSHUTD signal puts the device in ultra-low power mode and performs an internal reset to the device. The rise time for nSHUTD must not exceed 20 μs; nSHUTD must be low for a minimum of 5 ms.

To prevent conflicts with external signals, all I/O pins are set to the high-impedance (Hi-Z) state during shutdown and power up of the device. The internal pull resistors are enabled on each I/O pin, as described in Section 4.1, Pin Attributes. Table 5-1 describes the static operation states.

Table 5-1 Power Modes

VDD_IN (1) VDD_IO(1) nSHUTD(1) PM_MODE COMMENTS
1 None None Asserted Shut down I/O state is undefined. No I/O voltages are allowed on nonfail-safe pins.
2 None None Deasserted Not allowed I/O state is undefined. No I/O voltages are allowed on nonfail-safe pins.
3 None Present Asserted Shut down I/Os are defined as 3-state with internal pullup or pulldown enabled.
4 None Present Deasserted Not allowed I/O state is undefined. No I/O voltages are allowed on nonfail-safe pins.
5 Present None Asserted Shut down I/O state is undefined.
6 Present None Deasserted Not allowed I/O state is undefined. No I/O voltages are allowed on nonfail-safe pins.
7 Present Present Asserted Shut down I/Os are defined as 3-state with internal pullup or pulldown enabled.
8 Present Present Deasserted Active See Section 5.5.1.4, I/O States in Various Power Modes
(1) The terms None or Asserted can imply any of the following conditions: directly pulled to ground or driven low, pulled to ground through a pulldown resistor, or left NC or floating (high-impedance output stage).

5.5.1.4 I/O States in Various Power Modes

CAUTION

Some device I/Os are not fail-safe (see Section 4.1, Pin Attributes). Fail-safe means that the pins do not draw current from an external voltage applied to the pin when I/O power is not supplied to the device. External voltages are not allowed on these I/O pins when the I/O supply voltage is not supplied because of possible damage to the device.

Table 5-2 lists the I/O states in various power modes.

Table 5-2 I/O States in Various Power Modes

I/O NAME SHUT DOWN(1) DEFAULT ACTIVE(1) DEEP SLEEP(1)
I/O State Pull I/O State Pull I/O State Pull
HCI_RX Z PU I PU I PU
HCI_TX Z PU O-H O
HCI_RTS Z PU O-H O
HCI_CTS Z PU I PU I PU
AUD_CLK Z PD I PD I PD
AUD_FSYNC Z PD I PD I PD
AUD_IN Z PD I PD I PD
AUD_OUT Z PD Z PD Z PD
TX_DBG Z PU O
(1) I = input, O = output, Z = Hi-Z, — = no pull, PU = pullup, PD = pulldown, H = high, L = low

5.5.1.5 nSHUTD Requirements


PARAMETER SYM MIN MAX UNIT
Operation mode level (1) VIH 1.42 1.98 V
Shutdown mode level (1) VIL 0 0.4 V
Minimum time for nSHUT_DOWN low to reset the device 5 ms
Rise and fall times tr and tf 20 μs
(1) An internal pulldown retains shut-down mode when no external signal is applied to this pin.

5.5.2 Clock Specifications

5.5.2.1 Slow Clock Requirements

An external source must supply the slow clock and connect to the SLOW_CLK_IN pin (for example, the host or external crystal oscillator). The source must be a digital signal in the range of 0 to 1.8 V. The accuracy of the slow clock frequency must be 32.768 kHz ±250 ppm for Bluetooth use (as specified in the Bluetooth specification). The external slow clock must be stable within 64 slow-clock cycles (2 ms) following the release of nSHUTD.

space

CHARACTERISTICS CONDITION SYM MIN TYP MAX UNIT
Input slow clock frequency 32768 Hz
Input slow clock accuracy
(Initial + temp + aging)		 Bluetooth ±250 ppm
ANT ±50
Input transition time tr and tf
(10% to 90%)		 tr and tf 200 ns
Frequency input duty cycle 15% 50% 85%
Slow clock input voltage limits Square wave, DC-coupled VIH 0.65 × VDD_IO VDD_IO V peak
VIL 0 0.35 × VDD_IO V peak
Input impedance 1
Input capacitance 5 pF

5.5.2.2 External Fast Clock Crystal Requirements and Operation


CHARACTERISTICS CONDITION SYM MIN TYP MAX UNIT
Supported crystal frequencies fin 26, 38.4 MHz
Frequency accuracy
(Initial + temperature + aging) 		±20 ppm
Crystal oscillator negative resistance 26 MHz, external capacitance = 8 pF 650 940 Ω
Iosc = 0.5 mA
26 MHz, external capacitance = 20 pF 490 710
Iosc = 2.2 mA

5.5.2.3 Fast Clock Source Requirements (–40°C to +85°C)

CHARACTERISTICS CONDITION SYM MIN TYP MAX UNIT
Supported frequencies FREF 26, 38.4 MHz
Reference frequency accuracy Initial + temp + aging ±20 ppm
Fast clock input voltage limits Square wave, DC-coupled VIL –0.2 0.37 V
VIH 1.0 2.1 V
Sine wave, AC-coupled 0.4 1.6 Vp-p
Sine wave, DC-coupled 0.4 1.6 Vp-p
Sine wave input limits, DC-coupled 0.0 1.6 V
Fast clock input rise time
(as % of clock period)		 Square wave, DC-coupled 10%
Duty cycle 35% 50% 65%
Phase noise for 26 MHz @ offset = 1 kHz –123.4 dBc/Hz
@ offset = 10 kHz –133.4
@ offset = 100 kHz –138.4

5.5.3 Peripherals

5.5.3.1 UART

Figure 5-2 shows the UART timing diagram.

CC2560A CC2560B CC2564 CC2564B td_uart_wrs064.gif Figure 5-2 UART Timing

Table 5-3 lists the UART timing characteristics.

Table 5-3 UART Timing Characteristics

SYMBOL CHARACTERISTICS CONDITION MIN TYP MAX UNIT
Baud rate 37.5 4000 kbps
Baud rate accuracy per byte Receive and transmit –2.5% 1.5%
Baud rate accuracy per bit Receive and transmit –12.5% 12.5%
t3 CTS low to TX_DATA on 0 2 μs
t4 CTS high to TX_DATA off Hardware flow control 1 byte
t6 CTS-high pulse width 1 bit
t1 RTS low to RX_DATA on 0 2 μs
t2 RTS high to RX_DATA off Interrupt set to 1/4 FIFO 16 byte

Figure 5-3 shows the UART data frame.

CC2560A CC2560B CC2564 CC2564B td_uart2_wrs064.gif Figure 5-3 Data Frame

Table 5-4 describes the symbols used in Figure 5-3.

Table 5-4 Data Frame Key

SYMBOL DESCRIPTION
STR Start bit
D0...Dn Data bits (LSB first)
PAR Parity bit (optional)
STP Stop bit

5.5.3.2 PCM

Figure 5-4 shows the interface timing for the PCM.

CC2560A CC2560B CC2564 CC2564B td_aud_wrs064.gif Figure 5-4 PCM Interface Timing

Table 5-5 lists the associated PCM master parameters.

Table 5-5 PCM Master

Symbol PARAMETER CONDITION MIN MAX UNIT
Tclk Cycle time 244.14
(4.096 MHz)		 15625
(64 kHz)		 ns
Tw High or low pulse width 50% of Tclk min ns
tis AUD_IN setup time 25 ns
tih AUD_IN hold time 0 ns
top AUD_OUT propagation time 40-pF load 0 10 ns
top FSYNC_OUT propagation time 40-pF load 0 10 ns

Table 5-6 lists the associated PCM slave parameters.

Table 5-6 PCM Slave

SYMBOL PARAMETER CONDITION MIN MAX UNIT
Tclk Cycle time 66.67
(15 MHz)		 ns
Tw High or low pulse width 40% of Tclk ns
Tis AUD_IN setup time 8 ns
Tih AUD_IN hold time 0 ns
tis AUD_FSYNC setup time 8 ns
tih AUD_FSYNC hold time 0 ns
top AUD_OUT propagation time 40-pF load 0 21 ns

5.5.4 RF Performance

5.5.4.1 Bluetooth BR/EDR RF Performance

All parameters in this section that are fast-clock dependent are verified using a 26-MHz XTAL under a temperature range from –20°C to 70°C and an RF load of 50 Ω at the BT_RF port.

5.5.4.1.1 Bluetooth Receiver—In-Band Signals


CHARACTERISTICS CONDITION MIN TYP MAX BLUETOOTH SPECIFICATION UNIT
Operation frequency range 2402 2480 MHz
Channel spacing 1 MHz
Input impedance 50 Ω
Sensitivity, dirty TX on(1) GFSK, BER = 0.1% –91.5 –95 –70 dBm
Pi/4-DQPSK, BER = 0.01% –90.5 –94.5 –70
8DPSK, BER = 0.01% –81 –87.5 –70
BER error floor at sensitivity + 10dB, dirty TX off Pi/4-DQPSK 1E–6 1E–7 1E–5
8DPSK 1E–6 1E–5
Maximum usable input power GFSK, BER = 0.1% –5 –20 dBm
Pi/4-DQPSK, BER = 0.1% –10
8DPSK, BER = 0.1% –10
Intermodulation characteristics Level of interferers (for n = 3, 4, and 5) –36 –30 –39 dBm
C/I performance(2) GFSK, co-channel 8 10 11 dB
EDR, co-channel Pi/4-DQPSK 9.5 11 13
Image = –1 MHz 8DPSK 16.5 20 21
GFSK, adjacent ±1 MHz –10 –5 0
EDR, adjacent ±1 MHz, (image) Pi/4-DQPSK –10 –5 0
8DPSK –5 –1 5
GFSK, adjacent +2 MHz –38 –35 –30
EDR, adjacent, +2 MHz Pi/4-DQPSK –38 –35 –30
8DPSK –38 –30 –25
GFSK, adjacent –2 MHz –28 –20 –20
EDR, adjacent –2 MHz Pi/4-DQPSK –28 –20 –20
8DPSK –22 –13 –13
GFSK, adjacent ≥ |±3| MHz –45 –43 –40
EDR, adjacent ≥ |±3| MHz Pi/4-DQPSK –45 –43 –40
8DPSK –44 –36 –33
RF return loss –10 dB
RX mode LO leakage Frf = (received RF – 0.6 MHz) –63 –58 dBm
(1) Sensitivity degradation up to 3 dB may occur for minimum and typical values where the Bluetooth frequency is a harmonic of the fast clock.
(2) Numbers show ratio of desired signal to interfering signal. Smaller numbers indicate better C/I performance.

5.5.4.1.2 Bluetooth Receiver—General Blocking


CHARACTERISTICS CONDITION MIN TYP UNIT
Blocking performance over full range, according to Bluetooth specification (1) 30 to 2000 MHz –6 dBm
2000 to 2399 MHz –6
2484 to 3000 MHz –6
3 to 12.75 GHz –6
(1) Exceptions are taken out of the total 24 allowed in the Bluetooth specification.

5.5.4.1.3 Bluetooth Transmitter—GFSK


CHARACTERISTICS MIN TYP MAX BLUETOOTH SPECIFICATION UNIT
Maximum RF output power(1) 10 12 dBm
Power variation over Bluetooth band –1 1 dB
Gain control range 30 dB
Power control step 2 5 8 2 to 8
Adjacent channel power |M–N| = 2 –45 –39 ≤ –20 dBm
Adjacent channel power |M–N| > 2 –50 –42 ≤ –40
(1) To modify maximum output power, use an HCI VS command.

5.5.4.1.4 Bluetooth Transmitter—EDR


CHARACTERISTICS MIN TYP MAX BLUETOOTH SPECIFICATION UNIT
Maximum RF output power(2) Pi/4-DQPSK 6 8 dBm
8DPSK 6 8
Relative power –2 1 –4 to +1 dB
Power variation over Bluetooth band –1 1 dB
Gain control range 30 dB
Power control step 2 5 8 2 to 8 dB
Adjacent channel power |M–N| = 1 –36 –30 ≤ –26 dBc
Adjacent channel power |M–N| = 2 (1) –30 –23 ≤ –20 dBm
Adjacent channel power |M–N| > 2 (1) –42 –40 ≤ –40 dBm
(1) Assumes 3-dB insertion loss from Bluetooth RF ball to antenna
(2) To modify maximum output power, use an HCI VS command.

5.5.4.1.5 Bluetooth Modulation—GFSK


CHARACTERISTICS CONDITION SYM MIN TYP MAX BLUETOOTH SPECIFICATION UNIT
–20 dB bandwidth GFSK 925 995 ≤ 1000 kHz
Modulation characteristics Δf1avg Mod data = 4 1 s, 4 0 s:
111100001111...		 F1 avg 150 165 170 140 to 175 kHz
Δf2max ≥ limit for at least 99.9% of all Δf2max Mod data = 1010101... F2 max 115 130 > 115 kHz
Δf2avg, Δf1avg 85% 88% > 80%
Absolute carrier frequency drift DH1 –25 25 < ±25 kHz
DH3 and DH5 –35 35 < ±40
Drift rate 15 < 20 kHz/
50 μs
Initial carrier frequency tolerance f0 – fTX –75 +75 < ±75 kHz

5.5.4.1.6 Bluetooth Modulation—EDR


CHARACTERISTICS CONDITION MIN TYP MAX BLUETOOTH SPECIFICATION UNIT
Carrier frequency stability ±5 ≤ 10 kHz
Initial carrier frequency tolerance ±75 ±75 kHz
RMS DEVM (1) Pi/4-DQPSK 6% 15% 20%
8DPSK 6% 13% 13%
99% DEVM(1) Pi/4-DQPSK 30% 30%
8DPSK 20% 20%
Peak DEVM (1) Pi/4-DQPSK 14% 30% 35%
8DPSK 16% 25% 25%
(1) Max performance refers to maximum TX power.

5.5.4.1.7 Bluetooth Transmitter—Out-of-Band and Spurious Emissions


CHARACTERISTICS CONDITION TYP MAX UNIT
Second harmonic(1) Measured at maximum output power –14 –2 dBm
Third harmonic(1) –10 –6 dBm
Fourth harmonics(1) –19 –11 dBm
(1) Meets FCC and ETSI requirements with external filter shown in Figure 7-1

5.5.4.2 Bluetooth LE RF Performance

All parameters in this section that are fast-clock dependent are verified using a 26-MHz XTAL under a temperature range from –20°C to 70°C and an RF load of 50 Ω at the BT_RF port.

5.5.4.2.1 BLE Receiver—In-Band Signals


CHARACTERISTIC CONDITION MIN TYP MAX BLE
SPECIFICATION		 UNIT
Operation frequency range 2402 2480 MHz
Channel spacing 2 MHz
Input impedance 50 Ω
Sensitivity, dirty TX on(1) PER = 30.8%; dirty TX on –93 –96 ≤ –70 dBm
Maximum usable input power GMSK, PER = 30.8% –5 ≥ –10 dBm
Intermodulation characteristics Level of interferers
(for n = 3, 4, 5)		 –36 –30 ≥ –50 dBm
C/I performance(2)
Image = –1 MHz		 GMSK, co-channel 8 12 ≤ 21 dB
GMSK, adjacent ±1 MHz –5 0 ≤ 15
GMSK, adjacent +2 MHz –45 –38 ≤ –17
GMSK, adjacent –2 MHz –22 –15 ≤ –15
GMSK, adjacent ≥ |±3| MHz –47 –40 ≤ –27
RX mode LO leakage Frf = (received RF – 0.6 MHz) –63 –58 dBm
(1) Sensitivity degradation up to 3 dB may occur where the BLE frequency is a harmonic of the fast clock.
(2) Numbers show wanted signal-to-interfering signal ratio. Smaller numbers indicate better C/I performance.

5.5.4.2.2 BLE Receiver—General Blocking


CHARACTERISTICS CONDITION MIN TYP BLE SPECIFICATION UNIT
Blocking performance over full range, according to BLE specification(1) 30 to 2000 MHz –15 ≥ –30 dBm
2000 to 2399 MHz –15 ≥ –35
2484 to 3000 MHz –15 ≥ –35
3 to 12.75 GHz –15 ≥ –30
(1) Exceptions are taken out of the total 10 allowed in the BLE specification.

5.5.4.2.3 BLE Transmitter


CHARACTERISTICS MIN TYP MAX BLE SPECIFICATION UNIT
Maximum RF output power(2) 10 12(1) ≤10 dBm
Power variation over BLE band –1 1 dB
Adjacent channel power |M-N| = 2 –45 –39 ≤ –20 dBm
Adjacent channel power |M-N| > 2 –50 –42 ≤ –30
(1) To achieve the BLE specification of 10-dBm maximum, an insertion loss of > 2 dB is assumed between the RF ball and the antenna. Otherwise, use an HCI VS command to modify the output power.
(2) To modify maximum output power, use an HCI VS command.

5.5.4.2.4 BLE Modulation


CHARACTERISTICS CONDITION SYM MIN TYP MAX BLE
SPEC.		 UNIT
Modulation characteristics Δf1avg Mod data = 4 1s, 4 0 s:
1111000011110000...		 Δf1 avg 240 250 260 225 to 275 kHz
Δf2max ≥ limit for at least 99.9% of all Δf2max Mod data = 1010101... Δf2 max 185 210 ≥ 185 kHz
Δf2avg, Δf1avg 0.85 0.9 ≥ 0.8
Absolute carrier frequency drift –25 25 ≤ ±50 kHz
Drift rate 15 ≤ 20 kHz/50 ms
Initial carrier frequency tolerance –75 75 ≤ ±100 kHz

5.5.4.2.5 BLE Transceiver, Out-Of-Band and Spurious Emissions

See Section 5.5.4.1.7, Bluetooth Transmitter, Out-of-Band and Spurious Emissions.