SLUSE13B January   2020  – November 2021 BQ76952

PRODUCTION DATA  

  1. Features
  2. Applications
  3. Description
  4. Revision History
  5. Device Comparison Table
  6. Pin Configuration and Functions
  7. Specifications
    1. 7.1  Absolute Maximum Ratings
    2. 7.2  ESD Ratings
    3. 7.3  Recommended Operating Conditions
    4. 7.4  Thermal Information BQ76952
    5. 7.5  Supply Current
    6. 7.6  Digital I/O
    7. 7.7  LD Pin
    8. 7.8  Precharge (PCHG) and Predischarge (PDSG) FET Drive
    9. 7.9  FUSE Pin Functionality
    10. 7.10 REG18 LDO
    11. 7.11 REG0 Pre-regulator
    12. 7.12 REG1 LDO
    13. 7.13 REG2 LDO
    14. 7.14 Voltage References
    15. 7.15 Coulomb Counter
    16. 7.16 Coulomb Counter Digital Filter (CC1)
    17. 7.17 Current Measurement Digital Filter (CC2)
    18. 7.18 Current Wake Detector
    19. 7.19 Analog-to-Digital Converter
    20. 7.20 Cell Balancing
    21. 7.21 Cell Open Wire Detector
    22. 7.22 Internal Temperature Sensor
    23. 7.23 Thermistor Measurement
    24. 7.24 Internal Oscillators
    25. 7.25 High-side NFET Drivers
    26. 7.26 Comparator-Based Protection Subsystem
    27. 7.27 Timing Requirements - I2C Interface, 100kHz Mode
    28. 7.28 Timing Requirements - I2C Interface, 400kHz Mode
    29. 7.29 Timing Requirements - HDQ Interface
    30. 7.30 Timing Requirements - SPI Interface
    31. 7.31 Interface Timing Diagrams
    32. 7.32 Typical Characteristics
  8. Device Description
    1. 8.1 Overview
    2. 8.2 Functional Block Diagram
    3. 8.3 BQ76952 Device Versions
    4. 8.4 Diagnostics
  9. Device Configuration
    1. 9.1 Commands and Subcommands
    2. 9.2 Configuration Using OTP or Registers
    3. 9.3 Device Security
    4. 9.4 Scratchpad Memory
  10. 10Measurement Subsystem
    1. 10.1  Voltage Measurement
      1. 10.1.1 Voltage Measurement Schedule
      2. 10.1.2 Usage of VC Pins for Cells Versus Interconnect
      3. 10.1.3 Cell 1 Voltage Validation During SLEEP Mode
    2. 10.2  General Purpose ADCIN Functionality
    3. 10.3  Coulomb Counter and Digital Filters
    4. 10.4  Synchronized Voltage and Current Measurement
    5. 10.5  Internal Temperature Measurement
    6. 10.6  Thermistor Temperature Measurement
    7. 10.7  Factory Trim of Voltage ADC
    8. 10.8  Voltage Calibration (ADC Measurements)
    9. 10.9  Voltage Calibration (COV and CUV Protections)
    10. 10.10 Current Calibration
    11. 10.11 Temperature Calibration
  11. 11Primary and Secondary Protection Subsystems
    1. 11.1 Protections Overview
    2. 11.2 Primary Protections
    3. 11.3 Secondary Protections
    4. 11.4 High-Side NFET Drivers
    5. 11.5 Protection FETs Configuration and Control
      1. 11.5.1 FET Configuration
      2. 11.5.2 PRECHARGE and PREDISCHARGE Modes
    6. 11.6 Load Detect Functionality
  12. 12Device Hardware Features
    1. 12.1  Voltage References
    2. 12.2  ADC Multiplexer
    3. 12.3  LDOs
      1. 12.3.1 Preregulator Control
      2. 12.3.2 REG1 and REG2 LDO Controls
    4. 12.4  Standalone Versus Host Interface
    5. 12.5  Multifunction Pin Controls
    6. 12.6  RST_SHUT Pin Operation
    7. 12.7  CFETOFF, DFETOFF, and BOTHOFF Pin Functionality
    8. 12.8  ALERT Pin Operation
    9. 12.9  DDSG and DCHG Pin Operation
    10. 12.10 Fuse Drive
    11. 12.11 Cell Open Wire
    12. 12.12 Low Frequency Oscillator
    13. 12.13 High Frequency Oscillator
  13. 13Device Functional Modes
    1. 13.1 Overview
    2. 13.2 NORMAL Mode
    3. 13.3 SLEEP Mode
    4. 13.4 DEEPSLEEP Mode
    5. 13.5 SHUTDOWN Mode
    6. 13.6 CONFIG_UPDATE Mode
  14. 14Serial Communications Interface
    1. 14.1 Serial Communications Overview
    2. 14.2 I2C Communications
    3. 14.3 SPI Communications
      1. 14.3.1 SPI Protocol
    4. 14.4 HDQ Communications
  15. 15Cell Balancing
    1. 15.1 Cell Balancing Overview
  16. 16Application and Implementation
    1. 16.1 Application Information
    2. 16.2 Typical Applications
      1. 16.2.1 Design Requirements (Example)
      2. 16.2.2 Detailed Design Procedure
      3. 16.2.3 Application Performance Plot
      4. 16.2.4 Calibration Process
    3. 16.3 Random Cell Connection Support
    4. 16.4 Startup Timing
    5. 16.5 FET Driver Turn-Off
    6. 16.6 Unused Pins
  17. 17Power Supply Requirements
  18. 18Layout
    1. 18.1 Layout Guidelines
    2. 18.2 Layout Example
  19. 19Device and Documentation Support
    1. 19.1 Documentation Support
    2. 19.2 Support Resources
    3. 19.3 Trademarks
    4. 19.4 Electrostatic Discharge Caution
    5. 19.5 Glossary
  20. 20Mechanical, Packaging, Orderable Information

Package Options

Mechanical Data (Package|Pins)
Thermal pad, mechanical data (Package|Pins)
Orderable Information

I2C Communications

The I2C serial communications interface in the BQ76952 device acts as a responder device and supports rates up to 400 kHz with an optional CRC check. If the OTP is not programmed, the BQ76952 device will initially power up by default in 400 kHz I2C mode, although other versions of the device may initially power up in a different mode (as described in the Device Comparison Table. The OTP setting can be programmed on the manufacturing line, then when the device powers up, it automatically enters the selected mode per OTP setting. The host can also change the I2C speed setting while in CONFIG_UPDATE mode, then the new speed setting takes effect upon exit of CONFIG_UPDATE mode. Alternatively, the host can use the SWAP_TO_I2C() subcommand to change the communications interface to I2C immediately.

The I2C device address (as an 8-bit value including responder address and R/W bit) is set by default as 0x10 (write), 0x11 (read), which can be changed by configuration setting.

The communications interface includes programmable timeout capability. This should only be used if the bus will be operating at 100 kHz or 400 kHz. If this is enabled with the device set to 100-kHz mode, then the device will reset the communications interface logic if a clock is detected low longer than a tTIMEOUT of 25 ms to 35 ms, or if the cumulative clock low responder extend time exceeds ≈25 ms, or if the cumulative clock low controller extend time exceeds 10 ms. If the timeouts are enabled with the device set to 400-kHz mode, then the device will reset the communications interface logic if a clock is detected low longer than tTIMEOUT of 5 ms to 20 ms. The bus also includes a long-term timeout if the SCL pin is detected low for more than 2 seconds, which applies whether or not the timeouts above are enabled.

Figure 14-1 shows an I2C write transaction. Block writes are allowed by sending additional data bytes before the Stop. The I2C logic will auto-increment the register address after each data byte.

When enabled, the CRC is calculated as follows:

  • In a single-byte write transaction, the CRC is calculated over the responder address, register address, and data.
  • In a block write transaction, the CRC for the first data byte is calculated over the responder address, register address, and data. The CRC for subsequent data bytes is calculated over the data byte only.

The CRC polynomial is x8 + x2 + x + 1, and the initial value is 0.

When the responder detects an invalid CRC, the I2C responder NACKs the CRC, which causes the I2C responder to go to an idle state.


GUID-7A390402-C61F-46E8-8342-20B9CC47BC66-low.gif

Figure 14-1 I2C Write

Figure 14-2 shows a read transaction using a Repeated Start.


GUID-2D99981C-EB89-4703-92BA-4C62900F978F-low.gif

Figure 14-2 I2C Read with Repeated Start

Figure 14-3 shows a read transaction where a Repeated Start is not used; for example, if not available in hardware. For a block read, the controller ACKs each data byte except the last and continues to clock the interface. The I2C block auto-increments the register address after each data byte.

When enabled, the CRC for a read transaction is calculated as follows:

  • In a single-byte read transaction, the CRC is calculated beginning at the first start, so includes the responder address, the register address, then the responder address with a read bit set, then the data byte.
  • In a block read transaction, the CRC for the first data byte is calculated beginning at the first start and will include the responder address, the register address, then the responder address with a read bit set, then the data byte. The CRC resets after each data byte and after each stop. The CRC for subsequent data bytes is calculated over the data byte only.

The CRC polynomial is x8 + x2 + x + 1, and the initial value is 0.

When the controller detects an invalid CRC, the I2C controller will NACK the CRC, which causes the I2C responder to go to an idle state.


GUID-E15DDBA3-EFFA-4B6E-A58A-C61E511B2826-low.gif

Figure 14-3 I2C Read Without Repeated Start