SLUUBW5A July   2018  – September 2021 BQ34Z100-G1

 

  1. Read This First
    1. 1.1 About This Manual
    2. 1.1 Notational Conventions
    3. 1.1 Glossary
    4. 1.1 Trademarks
  2. Introduction
  3. Data Commands
    1. 2.1 Standard Data Commands
      1. 2.1.1  Control(): 0x00/0x01
        1. 2.1.1.1  CONTROL_STATUS: 0x0000
        2. 2.1.1.2  DEVICE TYPE: 0x0001
        3. 2.1.1.3  FW_VERSION: 0x0002
        4. 2.1.1.4  HW_VERSION: 0x0003
        5. 2.1.1.5  RESET_DATA: 0x0005
        6. 2.1.1.6  PREV_MACWRITE: 0x0007
        7. 2.1.1.7  CHEM ID: 0x0008
        8. 2.1.1.8  BOARD_OFFSET: 0x0009
        9. 2.1.1.9  CC_OFFSET: 0x000A
        10. 2.1.1.10 CC_OFFSET_SAVE: 0x000B
        11. 2.1.1.11 DF_VERSION: 0x000C
        12. 2.1.1.12 SET_FULLSLEEP: 0x0010
        13. 2.1.1.13 STATIC_CHEM_DF_CHKSUM: 0x0017
        14. 2.1.1.14 SEALED: 0x0020
        15. 2.1.1.15 IT ENABLE: 0x0021
        16. 2.1.1.16 CAL_ENABLE: 0x002D
        17. 2.1.1.17 RESET: 0x0041
        18. 2.1.1.18 EXIT_CAL: 0x0080
        19. 2.1.1.19 ENTER_CAL: 0x0081
        20. 2.1.1.20 OFFSET_CAL: 0x0082
      2. 2.1.2  StateOfCharge(): 0x02
      3. 2.1.3  MaxError(): 0x03
      4. 2.1.4  RemainingCapacity(): 0x04/0x05
      5. 2.1.5  FullChargeCapacity(): 0x06/07
      6. 2.1.6  Voltage(): 0x08/0x09
      7. 2.1.7  AverageCurrent(): 0x0A/0x0B
      8. 2.1.8  Temperature(): 0x0C/0x0D
      9. 2.1.9  Flags(): 0x0E/0x0F
      10. 2.1.10 FlagsB(): 0x12/0x13
      11. 2.1.11 Current(): 0x10/0x11
    2. 2.2 Extended Data Commands
      1. 2.2.1  AverageTimeToEmpty(): 0x18/0x19
      2. 2.2.2  AverageTimeToFull(): 0x1A/0x1B
      3. 2.2.3  PassedCharge(): 0x1C/0x1D
      4. 2.2.4  DOD0Time(): 0x1E/0x1F
      5. 2.2.5  AvailableEnergy(): 0x24/0x25
      6. 2.2.6  AveragePower(): 0x26/0x27
      7. 2.2.7  SerialNumber(): 0x28/0x29
      8. 2.2.8  InternalTemperature(): 0x2A/0x2B
      9. 2.2.9  CycleCount(): 0x2C/0x2D
      10. 2.2.10 StateOfHealth(): 0x2E/0x2F
      11. 2.2.11 ChargeVoltage(): 0x30/0x31
      12. 2.2.12 ChargeCurrent(): 0x32/0x33
      13. 2.2.13 PackConfiguration(): 0x3A/0x3B
      14. 2.2.14 DesignCapacity(): 0x3C/0x3D
      15. 2.2.15 DataFlashClass(): 0x3E
      16. 2.2.16 DataFlashBlock(): 0x3F
      17. 2.2.17 AuthenticateData/BlockData(): 0x40…0x53
      18. 2.2.18 AuthenticateChecksum/BlockData(): 0x54
      19. 2.2.19 BlockData(): 0x55…0x5F
      20. 2.2.20 BlockDataChecksum(): 0x60
      21. 2.2.21 BlockDataControl(): 0x61
      22. 2.2.22 GridNumber(): 0x62
      23. 2.2.23 LearnedStatus(): 0x63
      24. 2.2.24 Dod@Eoc(): 0x64/0x65
      25. 2.2.25 QStart(): 0x66/0x67
      26. 2.2.26 TrueRC(): 0x68/0x69
      27. 2.2.27 TrueFCC(): 0x6A/0x6B
      28. 2.2.28 StateTime(): 0x6C/0x6D
      29. 2.2.29 QmaxPassedQ(): 0x6E/0x6F
      30. 2.2.30 DOD0(): 0x70/0x71
      31. 2.2.31 QmaxDod0(): 0x72/0x73
      32. 2.2.32 QmaxTime(): 0x74/0x75
      33. 2.2.33 Data Flash Interface
        1. 2.2.33.1 Accessing Data Flash
        2. 2.2.33.2 Manufacturer Information Block
        3. 2.2.33.3 Access Modes
        4. 2.2.33.4 Sealing/Unsealing Data Flash Access
  4. Fuel Gauging
    1. 3.1  Overview
    2. 3.2  Impedance Track Variables
      1. 3.2.1  Load Mode
      2. 3.2.2  Load Select
      3. 3.2.3  Reserve Cap-mAh
      4. 3.2.4  Reserve Cap-mWh/cWh
      5. 3.2.5  Design Energy Scale
      6. 3.2.6  Dsg Current Threshold
      7. 3.2.7  Chg Current Threshold
      8. 3.2.8  Quit Current, Dsg Relax Time, Chg Relax Time, and Quit Relax Time
      9. 3.2.9  Qmax
      10. 3.2.10 Update Status
      11. 3.2.11 Avg I Last Run
      12. 3.2.12 Avg P Last Run
      13. 3.2.13 Cell Delta Voltage
      14. 3.2.14 Ra Tables
      15. 3.2.15 StateOfCharge() Smoothing
      16. 3.2.16 Charge Efficiency
      17. 3.2.17 Lifetime Data Logging
    3. 3.3  Device Configuration
      1. 3.3.1 Pack Configuration Register
      2. 3.3.2 Pack Configuration B Register
      3. 3.3.3 Pack Configuration C Register
    4. 3.4  Voltage Measurement and Calibration
      1. 3.4.1 1S Example
      2. 3.4.2 7S Example
      3. 3.4.3 Autocalibration
    5. 3.5  Temperature Measurement
    6. 3.6  Overtemperature Indication
      1. 3.6.1 Overtemperature: Charge
      2. 3.6.2 Overtemperature: Discharge
    7. 3.7  Charging and Charge Termination Indication
    8. 3.8  SCALED Mode
    9. 3.9  LED Display
    10. 3.10 Alert Signal
  5. Communications
    1. 4.1 Authentication
    2. 4.2 Key Programming
    3. 4.3 Executing an Authentication Query
    4. 4.4 HDQ Single-Pin Serial Interface
    5. 4.5 I2C Interface
    6. 4.6 Switching Between I2C and HDQ Modes
      1. 4.6.1 Converting to HDQ Mode
      2. 4.6.2 Converting to I2C Mode
  6. Device Functional Modes
    1. 5.1 NORMAL Mode
    2. 5.2 SLEEP Mode
    3. 5.3 FULL SLEEP Mode
  7. Power Control
    1. 6.1 Reset Functions
    2. 6.2 Wake-Up Comparator
    3. 6.3 Flash Updates
  8. Data Flash Summary
  9. Gas Gauge Timing Considerations
    1. 8.1 Gauging Effects on I2C Transactions
    2. 8.2 HDQ Bus Effects on Gauging
    3. 8.3 Gauging Effects on HDQ Transactions
    4. 8.4 Manufacturer Timing Notes
  10. HDQ Communication Basics
    1. 9.1 Basic HDQ Protocol
    2. 9.2 Break
    3. 9.3 Basic Timing
    4. 9.4 Reading 16-Bit Words
    5. 9.5 Host Processor Interrupts Using Discrete I/O Port for HDQ
    6. 9.6 Using UART Interface to HDQ
  11. 10Procedures to Seal and Unseal the Gauge
    1. 10.1 Unseal the Gauge to UNSEALED Mode
    2. 10.2 Unseal the Gauge to FULL ACCESS Mode
    3. 10.3 Seal the Gauge
  12. 11Impedance Track Gauge Configuration
    1. 11.1 Introduction
    2. 11.2 Determining ChemID
    3. 11.3 Learning Cycle
    4. 11.4 Common Problems Seen During the Learning Cycle
    5. 11.5 Test Gauge and Optimize
    6. 11.6 Finalize Golden File
    7. 11.7 Program and Test the PCB
  13. 12Revision History

9.1 Basic HDQ Protocol

HDQ communication between a host device and slave device uses a single-wire, open-drain interface. The communication protocol is asynchronous return-to-one referenced to VSS. A passive pullup resistance is required to pull the HDQ line to a high state when neither the host nor the slave is pulling the line low during the two-way communication over the single-wire interface. The interface uses a command-based protocol where the host sends a command byte to the HDQ slave device. The command directs the slave either to store the next 8 bits of data received to a register specified by the command byte (write command), or to output the 8 bits of data from a register specified by the command byte (read command). Command and data bytes consist of a stream of bits that have a maximum transmission rate of 5 Kb/s. The least-significant bit of a command or data byte is transmitted first. The first 7 bits of the command word are the register address, and the last command bit transmitted is the read/write (R/W) bit. Figure 10-1 illustrates a typical HDQ read cycle.

GUID-DB27058E-07EB-48A6-8124-680DD659E0E8-low.gifFigure 9-1 Typical HDQ Read Cycle

The HDQ line may remain high for an indefinite period of time between each bit of address or between each bit of data on a write cycle. After the last bit of address is sent on a read cycle, the HDQ slave starts outputting the data after the specified response time, t(RSPS). The response time is measured from the fall time of the command R/W bit to the fall time of the first data bit returned by the slave and therefore includes the entire bit time for the R/W bit. (The response time is not the time after the last command bit before the first data bit of the response begins.) Because the minimum response time is equal to the minimum bit cycle time, this means that the first data bit may begin as soon as the command R/W bit time ends.

This communication protocol may be referred to as HDQ8 to distinguish it from the HDQ16 protocol used by some devices like the BQ2060 and BQ2063. The bit timing of HDQ16 is identical to that of HDQ8, except that 16 bits of data are written or read instead of 8 bits. The HDQ16 command word is still a 7-bit address plus a R/W bit.