bq2016 GAS GAUGE IC FOR HIGH DISCHARGE RATES SLUS475A – JANUARY 2001 – REVISED NOVEMBER 2002 D Provides Accurate Measurement of D D D D D D D TSSOP PACKAGE (TOP VIEW) Available Capacity in Nicd or NiMH Batteries Measures a Wide Dynamic-Current Range Requires ≤ 1 Square Inch of PCB Space for Easy Pack Integration Measures Charge Flow Using a Low-Offset V-to-F Converter Automatically Compensates Measurements for Rate and Temperature Supports 5 LEDs for Remaining Capacity Indication Provides a 1-Wire HDQ Communication Interface Packaging: 28-Pin SSOP HDQ NC NC RBI REG NC VCC VSS DISP LED1 LED2 LED3 LED4 LED5 description 1 28 2 27 3 26 4 25 5 24 6 23 7 22 8 21 9 20 10 19 11 18 12 17 13 16 14 15 NC NC SB PROG VPFC NC SR1 SR2 SRC TS THON CVON NC NC NC — Do not connect The bq2016 gas gauge IC for battery pack or in-system installation maintains an accurate record of available battery capacity. To integrate charge and discharge activity of the battery, the IC monitors a voltage drop across a sense resistor connected in series with the cells of the battery. The bq2016 compensates for battery temperature, charge/discharge rate, and battery self-discharge to the charge counter to provide availablecapacity information across a wide range of operating conditions. The bq2016 works with NiCd or NiMH battery packs that have a capacity of 1 to 4.5 Ah and that are designed for high discharge rate applications such as power tools. The VPFC input sets the initial full charge reference of the battery pack. The bq2016 learns the true discharge capacity of the battery pack and automatically updates the full-charge reference during the course of a discharge cycle from full to empty. The remaining capacity is reported as the ratio between the actual discharge capacity and the full-charge capacity. The bq2016 communicates available capacity using 5 LEDs or the 1-wire communications port. The 1-wire serial communication port (5Kb/s) allows an external processor to read and write the internal registers of the bq2016. Communication with the bq2016 is useful for pack testing or host processing of the available battery information. The internal registers include available battery capacity, voltage, temperature, current, and battery status. The RBI input maintains the register set in the event of pack voltage collapse due to a high discharge pulse. The bq2016 circuit can operate from the cells in the pack. The REG output and an external FET provide a simple, inexpensive voltage regulator to supply power to the circuit from the cells OPTIONS TJ 28-PIN SSOP PACKAGE –20°C to 70°C bq2016DBQ bq2016DBQR Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet. Copyright 2002, Texas Instruments Incorporated PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of Texas Instruments standard warranty. Production processing does not necessarily include testing of all parameters. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 1 bq2016 GAS GAUGE IC FOR HIGH DISCHARGE RATES SLUS475A– JANUARY 2001 – REVISED NOVEMBER 2002 Terminal Functions TERMINAL NAME NO. I/O DESCRIPTION HDQ 1 I/O RBI 4 I Register backup input provides backup potential to the bq2016 registers during periods of low operating voltage. RBI accepts a storage capacitor or a battery input. REG 5 O Regulator output provides a reference to control an n-JFET for VCC regulation to the bq2016 from the battery potential. VCC VSS 7 I Supply voltage input LED1–LED5 8 Serial communication input/output. Open-drain bidirectional communications port. Ground 10–14 O LED display segment outputs that each may drive an external LED. CVON 17 O Cell voltage divider control. Output to connect the voltage divider on the voltage input during measurement. VPFC 24 I Program capacity input. 16-level input to program the initial battery full-charge reference. SB 26 I Battery voltage input. Input connection to monitor battery–pack voltage. 21,22 I Sense resistor inputs. Input connections for a small value sense resistor to monitor the battery charge and discharge current flow. SRC 20 I Current sense voltage input to monitor instantaneous current. DISP 9 I Display activation input that activates the LED drivers LED1–LED5. TS 19 I Temperature sense input connects to an external thermistor or should be grounded when using the internal thermistor. The function depends on the state of the PROG input. PROG 25 I Program input defines the temperature measurement thermistor (internal or external). THON 18 O Thermistor bias control output to control a switch in series with an optional external thermistor. SR2–SR1 NC 2 2, 3, 6, 15, 16, 23, 27, 28 Do not connect. For proper device operation, these pins should not be connected. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 bq2016 GAS GAUGE IC FOR HIGH DISCHARGE RATES SLUS475A– JANUARY 2001 – REVISED NOVEMBER 2002 absolute maximum ratings over operating free-air temperature range (unless otherwise noted)† Relative to VSS: VCC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –0.3 V to 6 V VIN (All other pins) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –0.3 V to 6 V Operating temperature, TOPR . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –20°C to 70°C † 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. dc electrical characteristics PARAMETER VCC ICC Supply voltage VOLS VOLS Sink voltage: LED1–LED5 VIL VIH Input voltage low DISP VOL VILS Output voltage low HDQ VIHS VAI Input voltage high HDQ IRB VRBI RBI data-retention input current ZAI1 ZAI2 Input impedance: SR1, SR2 Input impedance: SB, SRC TEST CONDITIONS MIN TYP 2.7 Operating current MAX 3.3 3.7 V 180 235 µA 0.4 V IOLS = 5 mA IOLS = 1 mA Sink voltage: TI ION, CVON 0.36 V –0.3 0.8 V 2.0 VCC + 0.3 V 0.4 V 0.8 V 1.7 6.0 V VSS–0.3 VCC + 0.3 50 V Input voltage high DISP IOL = 1 mA Input voltage low HDQ –0.3 Input voltage range SB, PROG, VPFC, TS UNIT VRBI > 3 V, VCC < 2 V RBI data-retention voltage 10 nA 1.3 V 0–1.25V 10 MΩ 0–1.25V 5 MΩ 5 MΩ ZAI3 Input impedance: PROG, VPFC 0–VCC NOTE: ZAI specifications are reference numbers based on process data. VFC characteristics, VCC = 3.1–3.5 V, TOPR = 0°C to 70°C (unless otherwise noted) PARAMETER VSR VSROS VSRCOS INL TEST CONDITIONS Input voltage range, VSR2 and VSR1 VSR input offset Calibrated offset Integral nonlinearity error VSR = VSR2 – VSR1 VSR2 = VSR1, autocorrection disabled After autocorrection MIN TYP –0.25 –300 –50 –16 TOPR = 0°C to 50°C MAX UNIT 0.25 V 300 µV 16 V 0.21% REG characteristics PARAMETER VRO REG controlled output voltage IREG REG output current TEST CONDITIONS JFET: Rds(on) < 150 Ω Vgs (off) < –3 V at 10 µA MIN 3.1 1 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 TYP 3.3 MAX 3.5 UNIT V µA 3 bq2016 GAS GAUGE IC FOR HIGH DISCHARGE RATES SLUS475A– JANUARY 2001 – REVISED NOVEMBER 2002 serial communication timing parameters PARAMETER TEST CONDITIONS MIN TYP MAX UNIT µs t(CYCH) t(CYCB) Cycle time, host to bq2016 (write) 190 Cycle time, bq2016 to host (read) 190 t(STRH) t(STRB) Start hold, host to bq2016 (write) 5 Start hold, bq2016 to host (read) 32 t(DSU) t(DSUB) Data setup time 50 µs Data setup time 50 µs t(DH) t(DV) Data hold time 90 µs Data valid time 80 µs t(SSU) t(SSUB) Stop setup time 145 µs Stop setup time 145 µs t(RSPS) t(B) Response time, bq2016 to host 320 µs Break 190 µs t(BR) Break recovery 40 µs 4 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 205 250 µs ns µs bq2016 GAS GAUGE IC FOR HIGH DISCHARGE RATES SLUS475A– JANUARY 2001 – REVISED NOVEMBER 2002 timing requirements t(BR) t(B) Figure 1. Break Timing Write 1 Write 0 t(STRH) t(DSU) t(DH) t(SSU) t(CYCH) Figure 2. Host to bq2016 Read 1 Read 0 t(STRB) t(DSUB) t(DV) t(SSUB) t(CYCB) Figure 3. bq2016 to Host Received by Host from bq2016 Written by Host to bq2016 CMDR = 03h Data (NAC) = 65h LSB Break 0 1 MSB LSB 1 1 2 0 3 0 4 0 5 0 6 0 MSB LSB 7 0 0 1 t(RSPS) MSB 1 0 MSB 2 1 3 0 4 0 5 1 6 1 7 0 LSB 65h = 0 1 1 0 0 1 0 1 03h = 00000011 Figure 4. Typical Communication With the bq2016 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 5 bq2016 GAS GAUGE IC FOR HIGH DISCHARGE RATES SLUS475A– JANUARY 2001 – REVISED NOVEMBER 2002 functional description general operation The bq2016 determines battery capacity by monitoring the amount of charge input to or removed from a rechargeable battery. The bq2016 measures charge and discharge currents, estimates self-discharge, and monitors the battery for low voltage and capacity thresholds. The bq2016 automatically compensates charge and discharge currents for rate and temperature to adjust for battery efficiency under different conditions. The bq2016 is configured to display capacity in a relative display mode. The display mode uses the last measured discharge or learned capacity of the battery as the battery-full reference. The LED display can be activated by a push-button connected to the DISP input or when the bq2016 detects a charge or discharge rate. measurements The bq2016 uses a fully differential, dynamically balanced voltage-to-frequency converter (VFC) for charge measurement and a delta sigma analog-to-digital converter (ADC) for battery voltage, current, and temperature measurement. charge and discharge counting The VFC measures the charge and discharge flow of the battery by monitoring a small-value sense resistor between the SR1 and SR2. The VFC measures bipolar signals up to 250 mV in magnitude. The bq2016 detects charge activity when VSR = VSR2 – VSR1 is positive and a discharge activity when VSR = VSR2 – VSR1 is negative. The bq2016 integrates the signal over time using an internal counter. The bq2016 accumulates charge or discharge at the rate of 3.125 µVh. digital filter and VFC calibration The bq2016 does not integrate charge or discharge counts below the digital filter threshold. The digital filter threshold is set at 300 µV until a VFC calibration is performed. The calibration is performed after the first valid charge after initialization. It takes up to 20 minutes to begin the calibration and up to 60 minutes to complete the VFC calibration. The bq2016 suspends VFC calibration while it detects charge or discharge activity during this period. After successful VFC calibration, the digital filter threshold is set to 100 µV. voltage monitoring and thresholds In conjunction with monitoring SR1 and SR2 for charge and discharge currents, the bq2016 monitors the battery pack potential through the SB pin. The bq2016 measures the pack voltage and reports the result in the battery voltage (VSBH:L) register. The bq2016 converts the signals at the SB input every 2 seconds. The SB input is divided down from the cells using 1% tolerance resistors. To reduce current consumption from the battery, the CVON output can switch the divider to the cells only during measurement period. CVON is high impedance when the cells are measured, and driven low otherwise. The full-scale input for the SB pin is 1.25 V. The bq2016 monitors the voltage at SB for the end-of-discharge voltage (EDV) and maximum voltage (MCV) thresholds. The bq2016 uses the EDV threshold level to determine when the battery has reached an empty state, and the MCV threshold level to detect a fault condition during charge. The EDV and MCV input levels are set at: EDV = 0.45 V MCV = 1.00 V The bq2016 disables EDV monitoring if VSR is greater than the overload threshold. If the bq2016 detects an overload threshold, the bq2016 sets the OLVD flag in the secondary status flags (FLAGS2) register. The bq2016 resumes EDV detection after VSR drops back below the overload threshold. The overload threshold is a function of battery capacity and is defined in the PFC table. 6 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 bq2016 GAS GAUGE IC FOR HIGH DISCHARGE RATES SLUS475A– JANUARY 2001 – REVISED NOVEMBER 2002 functional description (continued) current The SRC input of the bq2016 measures battery charge and discharge current. The SRC ADC input converts the current signal from the series sense resistor every 2 seconds and stores the result in the current scale register (VSRH:L). The full scale input range to SRC is limited to ±250 mV as shown in Table 1. Table 1. SRC Input Range SENSE RESISTOR (mΩ) FULL SCALE INPUT (±A) 5 50 7.5 33 10 25 temperature The bq2016 measures temperature, either with its internal thermistor or with an external thermistor, depending on the state of the PROG input. The bq2016 accepts an external NTC thermistor on the TS input. The bq2016 samples the TS input voltage every 2 seconds and stores the voltage in the TS Input Voltage (TEMPVH:L) register and the actual temperature in the temperature (TEMP) register. With an external thermistor, the bq2016 develops the temperature value for the temperature register on the basis of a Semitec 103AT (10K) NTC model. The bq2016 reports the temperature in 1°C steps with an accuracy of 4°C or 6°C for an external and internal thermistor, respectively. The temperature reading is used to adapt remaining capacity for charge and discharge efficiency and to adjust for the battery’s self discharge. If an internal thermistor is selected for temperature measurement, the TS input should be grounded. THON may be used to connect the bias source to the thermistor when the bq2016 samples the TS input. THON is high impedance when the temperature is measured, and driven low otherwise. gas gauge operation general The operational overview diagram in Figure 5 illustrates the operation of the bq2016. The bq2016 accumulates a measure of charge and discharge currents and estimates self-discharge. The bq2016 compensates the charge and discharge currents for rate and temperature efficiencies. It also adjusts the self-discharge estimation for temperature variation. The bq2016 stores the compensated charge accumulation in the nominal available capacity (NAC) register. For LED indication, the bq2016 adjusts NAC for the battery pack operating temperature. The discharge count register (DCR) tracks discharge activity of the battery. The last measured discharge (LMD) represents the discharge capacity or learned full capacity of the battery in the application. The bq2016 transfers the value in DCR to LMD when a qualified discharge occurs. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 7 bq2016 GAS GAUGE IC FOR HIGH DISCHARGE RATES SLUS475A– JANUARY 2001 – REVISED NOVEMBER 2002 functional description (continued) Inputs Charge Current Discharge Current Self-Discharge Timer Rate and Temperature Compensation Rate and Temperature Compensation Temperature Compensation – + Main Counters and Capacity Reference (LMD) – Nominal Available Charge (NAC) + ≤ Last Measured Discharge (LMD) Qualified Transfer + Discharge Count Register (DCR) Temperature, Voltage, Other Data Temperature Translation Outputs Chip-Controlled Available Charge LED Display Serial Port Figure 5. Operational Overview Diagram main gas gauge registers programmed full count (PFC) The programmed full count (PFC) register stores the user-specified battery full capacity. The 8-bit PFC registers stores the full capacity in mVh scaled as shown in Table 2. The VPFC input sets the PFC value and the counting scale on a bq2016 initialization (power on reset). nominal available capacity (NAC) The main counter, NAC, represents the available battery capacity at any given time. Battery charging increments the NAC register, while battery discharging and self-discharge decrement the NAC register. The bq2016 compensates the charge and discharge inputs to NAC for rate and temperature efficiencies. NAC counts up during charge to a maximum value of LMD and down during discharge and self-discharge to 0. The bq2016 resets NAC to 0 on initialization and when the bq2016 sets the EDV bit on discharge. To prevent overstatement of charge during periods of overcharge, NAC stops incrementing when NAC = LMD. 8 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 bq2016 GAS GAUGE IC FOR HIGH DISCHARGE RATES SLUS475A– JANUARY 2001 – REVISED NOVEMBER 2002 main gas gauge registers (continued) NAC calibration The bq2016 sets NAC to 85% of LMD when it detects a transition from fast-charge to a trickle charge provided that 85% ≥ NAC > 80% of LMD when the bq2016 detects the transition. For this determination, fast-charge detection (FCDT) corresponds to the FCDT value set by the PROG pin. Fast-charge detection occurs when the FCDT condition is met for 30s after the CHGS bit is set in FLGS1. Once fast-charge activity is qualified, a transition of the SRC signal below the FCDT threshold enables trickle-charge detection. The bq2016 verifies trickle charge by continuing to sample the SRC input for signals above the trickle-charge threshold and below the fast-charge threshold. This sampling can take up to 3 minutes. Once a trickle-charge is verified, the bq2016 adjusts NAC up to 85% of LMD if NAC was between 80% and 85% of LMD. If NAC was greater then 85% of LMD, NAC is unchanged upon transition detection. last measured discharge (LMD) Last measured discharge is the most recent measured discharge capacity of the battery. On initialization, the bq2016 sets LMD = PFC. When a valid charge is detected following a valid discharge, the bq2016 updates LMD with the current value in DCR. During subsequent discharges, the bq2016 updates LMD with the current value in DCR. (The DCR value represents the measured discharge capacity of the battery from full to the EDV threshold.) The bq2016 limits the adjustment of LMD down to 75% of its previous value. A qualified discharge is necessary for a capacity transfer from DCR to the LMD register. The LMD register also serves as the 100% reference threshold used by the display mode. discharge count register (DCR) The discharge count register (DCR) is used to update the last measured discharge register only if a complete battery discharge from full to empty occurs without any partial battery charges. In this way, the bq2016 adapts its capacity determination based on the actual conditions of discharge. The DCR counts up during discharge independent of NAC and can continue to increase after NAC decrements to 0. Before NAC = 0 (empty battery), both discharge and self-discharge increment the DCR. After NAC = 0, only discharge increments the DCR. The DCR resets to 0 when the VDQ bit in the primary status flags register (FLAGS1) is set on charge. The bq2016 sets VDQ=1 on a fast charge-to-trickle detection if NAC is greater than 80% of LMD or when NAC=LMD. The DCR does not roll over but stops counting when it reaches ffffh. The DCR value becomes the new LMD value on the first valid charge after a discharge to EDV threshold if the bq2016 detects a qualified discharge. A valid charge is a minimum of one (maximum of two) NAC increments. A qualified discharge occurs if D No valid charge initiations occurred during the period between when VDQ gets set on charge and when the bq2016 detects EDV on discharge. D The self-discharge count is not more than 10% of PFC. D The temperature is greater than or equal to 0°C when the EDV level is reached during discharge. D The EDV bit gets set. The VDQ bit set to a one indicates whether the present discharge is valid for LMD update. programming the bq2016 The bq2016 is programmed with the VPFC and the PROG pins. During power-up or initialization, the bq2016 reads the state of these multilevel inputs and latches in the programmable configuration settings. Resistor divider networks for VPFC and PROG should target the nominal thresholds as defined in the programming tables. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 9 bq2016 GAS GAUGE IC FOR HIGH DISCHARGE RATES SLUS475A– JANUARY 2001 – REVISED NOVEMBER 2002 programmable configuration settings design capacity The battery’s rated design capacity or programmed full count (PFC) is programmed with the VPFC pin as shown in Table 2, and represents the battery’s full reference. The VPFC pin is a 16-level input. Table 2. PFC Selections PFC LEVEL LOWER 1 0/32 NOMINAL THRESHOLD (VCC) ≤ 1/32 < UPPER PFC (COUNT) SCALE (mVh/ COUNT) CAPACITY (mVh) OVERLOAD THRESHOLD (mV) Rv (kΩ) 2 2/32 ≤ 3/32 < 2/32 30720 1/2560 12.0 50 Open 0 NiCd 4/32 25344 1/2560 9.9 50 1000 102 3 4/32 ≤ 5/32 < NiCd 6/32 41472 1/5120 8.1 50 1000 187 NiCd 4 6/32 5 8/32 ≤ 7/32 < 8/32 33792 1/5120 6.6 50 1000 280 NiCd ≤ 9/32 < 10/32 27648 1/5120 5.4 30 1000 392 NiCd 6 7 10/32 ≤ 11/32 < 12/32 46080 1/10240 4.5 30 1000 523 NiCd 12/32 ≤ 13/32 < 14/32 36864 1/10240 3.6 30 1000 681 NiCd 8 14/32 ≤ 15/32 < 16/32 30720 1/10240 3.0 30 1000 887 NiCd Rg (kΩ) CHEMISTRY 9 16/32 ≤ 17/32 < 18/32 39936 1/10240 3.9 30 887 1000 NiMH 10 18/32 ≤ 19/32 < 20/32 46080 1/10240 4.5 30 681 1000 NiMH 11 20/32 ≤ 21/32 < 22/32 27648 1/5120 5.4 30 523 1000 NiMH 12 22/32 ≤ 23/32 < 24/32 33792 1/5120 6.6 30 392 1000 NiMH 13 24/32 ≤ 25/32 < 26/32 39936 1/5120 7.8 50 280 1000 NiMH 14 26/32 ≤ 27/32 < 28/32 47616 1/5120 9.3 50 187 1000 NiMH 15 28/32 ≤ 29/32 < 30/32 28416 1/2560 11.1 50 102 1000 NiMH 16 30/32 ≤ 31/32 ≤ 32/32 33792 1/2560 13.2 50 0 Open NiMH The correct PFC may be determined by multiplying the rated battery capacity in mAh by the sense-resistor value: Battery capacity (mAh) × sense resistor (Ω) = PFC (mVh) Selecting a PFC slightly less than the rated capacity provides a conservative capacity reference. The bq2016 stores the selected PFC in the PFC register. 10 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 bq2016 GAS GAUGE IC FOR HIGH DISCHARGE RATES SLUS475A– JANUARY 2001 – REVISED NOVEMBER 2002 programmable configuration settings (continued) internal or external thermistor The PROG pin programs whether the bq2016 uses an internal or external thermistor according to the following table. It also defines the fast charge and trickle-rate detection thresholds for NAC calibration. Table 3. PROG Selections FAST CHARGE DETECTION THRESHOLD (FCDT) PROG LEVEL LOW NOM (VCC) HI T TRICKLE RATE 1 0/12 ≤ 1/12 < 2/12 I VDMF < VSR < 2 mV 0 2/12 ≤ 3/12 < 4/12 I VDMF < CRate < C/8 VSR > 2 mV for 30s CRate > C/5 for 30s Open 2 1000 332 3 4/12 ≤ 5/12 < 6/12 I — — 1000 715 4 6/12 ≤ 7/12 < 8/12 E VDMF < VSR < 2 mV > 2 mV for 30s 715 1000 332 1000 0 Open 5 8/12 ≤ 9/12 < 10/12 E VDMF < CRate < C/8 6 10/12 ≤ 11/12 ≤ 12/12 E — CRate > C/5 for 30s — Rv (k) Rg (k) NOTE: The bq2016 does not perform NAC calibration on charge with options 3 and 6. VDMF = 300 µV uncalibrated or 100 µV calibrated. programming example Given: Sense resistor = 0.003 Ω Chemistry = NiCd Capacity = 2000 mAh Discharge current range = 1 A to 10 A Charge current = 200 mA to 4 A Voltage drop over sense resistor = –30 mV to 12 mV Internal thermistor with 2 mV FCDT Therefore 2000 mAh × 0.003 = 6 mVh Select VPFC level = 5 PROG level = 1 TS pin = grounded The initial full battery capacity is 5.4 mVh (1800 mAh) until the bq2016 learns a new capacity with a qualified discharge from full to EDV. charge and discharge count counting charge counting The bq2016 detects charge activity when VSR = VSR2 – VSR1 is greater than the digital filter threshold. If charge activity is detected, the bq2016 increments NAC at a rate proportional to VSR and activates the LED display if VSR > 2 mV. Charge actions increment the NAC after compensation for charge rate and temperature. Charge counting continues until VSR drops below VDMF. discharge counting The bq2016 detects discharge activity when VSR = VSR2 – VSR1 is more negative than the digital filter threshold. If discharge activity is detected, the bq2016 decrements NAC and increments DCR at a rate proportional to VSR and activates the LED display if VSR < –2 mV. Discharge actions decrement NAC and increment DCR after compensation for discharge rate and temperature. Discharge counting continues until VSR rises above –VDMF. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 11 bq2016 GAS GAUGE IC FOR HIGH DISCHARGE RATES SLUS475A– JANUARY 2001 – REVISED NOVEMBER 2002 charge and discharge count counting (continued) self-discharge estimation The bq2016 continuously decrements NAC and increments DCR for self-discharge based on time and temperature. The self-discharge count rate is programmed to be a nominal 1/80 NAC rate per day for NiCd and a nominal 1/60 × NAC for NiMH. This is the rate for a battery whose temperature is between 20°C–30°C. The self-discharge rate doubles every 10°C increase in temperature. count compensations The bq2016 compensates charge and discharge counting for temperature and rate before updating the NAC and/or DCR. The bq2016 compensates self-discharge estimation for temperature before updating the NAC or DCR. charge compensations The bq2016 compensates for charge efficiencies at a quick-charge and fast-charge rate at two different temperature thresholds. The bq2016 applies the NiCd or NiMH factors based on the VPFC setting. For charge compensation, quick charge is defined as a C/5 charge rate or less and fast charge is defined as a rate greater than C/5. The charge-compensation factors are shown in Tables 4 and 5. charge compensations Table 4. Charge Compensation for NiCd CHARGE TEMPERATURE QUICK CHARGE ( ≤ C / 5 ) COMPENSATION FAST CHARGE ( > C / 5 ) COMPENSATION <40C 0.80 0.95 ≥ 40 0.75 0.90 Table 5. Charge Compensation for NiMH CHARGE TEMPERATURE QUICK CHARGE ( ≤ C / 5 ) COMPENSATION FAST CHARGE ( > C / 5 ) COMPENSATION <40C 0.80 0.90 ≥ 40 0.75 0.85 discharge compensation The bq2016 corrects for the rate of discharge by adjusting an internal discharge-compensation factor. The discharge factor is based on the calculated discharge rate determined from the VSR potential and the PFC setting. The table below shows the compensation factors for NiCd and NiMH during discharge: DISCHARGE RATE DISCHARGE EFFICIENCY ( FDE ) (%) ≤1C 100 >3C 100 >6C 95 >9C 95 >12C 90 NOTE: The C Rate determination is made from LMD. 12 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 bq2016 GAS GAUGE IC FOR HIGH DISCHARGE RATES SLUS475A– JANUARY 2001 – REVISED NOVEMBER 2002 discharge compensation (continued) The bq2016 adjusts the discharge-compensation efficiency for temperature. At lower temperatures, the discharge-efficiency factor decreases by 5% for each 10°C temperature step below 10°C. FDE (new) = FDE – (5% × N) where N = number of 10°C steps below 10°C. For example at a 1C discharge, T > 10°C: 0°C < T < 10°C: –10°C < T < 0°C: –20°C < T < –10°C: –20°C < T < –30°C: N = 0 and FDE(NEW) = 100% N = 1 and FDE(NEW) = 95% N = 2 and FDE(NEW) = 90% N = 3 and FDE(NEW) = 85% N = 4 and FDE(NEW) = 80% error summary capacity inaccurate The LMD is susceptible to error on initialization or if no updates occur. On initialization, the LMD value includes the error between the programmed full capacity and the actual capacity. This error is present until a valid discharge occurs and LMD is updated. The other cause of LMD error is battery wear-out. As the battery ages, the measured capacity must be adjusted to account for changes in actual battery capacity. The bq2016 increments the capacity inaccurate count (CPI) register each time a valid charge occurs and is reset whenever LMD is updated from the DCR. The counter does not wrap around but stops counting at 255. The capacity inaccurate flag (CI) is set if LMD has not been updated following 64 valid charges. display The bq2016 can directly display capacity information using low-power LEDs. The bq2016 displays the battery charge as a percentage of the LMD. The capacity display is also adjusted for the present battery temperature. The temperature adjustment reflects the available capacity at a given temperature but does not affect the NAC register. Tables 6 and 7 show the temperature adjustments: Table 6. Temperature Translation for NiCd TEMPERATURE (C) TEMPERATURE TRANSLATION (%) T ≥ 10 100 10 > T ≥ 0 100 0 > T ≥ –10 90 –10 > T ≥ –20 75 T < –20 50 Table 7. Temperature Translation for NiMH TEMPERATURE (C) TEMPERATURE TRANSLATION (%) T ≥ 10 100 10 > T ≥ 0 75 0 > T ≥ –10 40 –10 > T ≥ –20 0 T < –20 0 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 13 bq2016 GAS GAUGE IC FOR HIGH DISCHARGE RATES SLUS475A– JANUARY 2001 – REVISED NOVEMBER 2002 error summary (continued) The display becomes active during charge if the NAC registers are counting at a rate equivalent to VSR > 2 mV or discharge if the NAC registers are counting at a rate equivalent to VSR < –2 mV. When DISP is pulled low, the segment output becomes active for 4 seconds. LED1 blinks at a 4-Hz rate whenever NAC is less than 6% of LMD or VSB ≤ VEDV. Table 8. Display Mode LED1 LED2 LED3 LED4 LED5 NAC / LMD ON ON ON ON ON 80 – 100% ON ON ON ON OFF 60 – < 80% ON ON ON OFF OFF 40 – < 60% ON ON OFF OFF OFF 20 – < 40% 6 < 20% ON OFF OFF OFF OFF BLINK OFF OFF OFF OFF < 6% BLINK OFF OFF OFF OFF VSB ≤ VEDV RBI input The RBI input pin should be used with a storage capacitor or external supply to provide backup potential to the internal bq2016 registers when VCC drops below 3.0 V. VCC is output on RBI when VCC is above 3.0 V. If an external supply (such as the bottom series cell) is the backup source, then an external diode is required for isolation. initialization The bq2016 can be initialized by removing VCC and grounding the RBI pin for 5 seconds or by a command over the serial port. The HDQ port reset command requires writing 78h to register CMDWD. microregulator A REG output is provided to regulate an external low-threshold JFET to supply power to the bq2016 based circuit from the series cells. The REG output maintains VCC to the bq2016 at 3.3 V. communicating with the bq2016 The bq2016 includes a simple single-pin (HDQ referenced to Vss) serial data interface. A host processor uses the interface to access various bq2016 registers. By adding a single contact to the battery pack, the host can easily monitor the battery characteristics. The open-drain HDQ pin on the bq2016 should be pulled up by the host system or pulled down to ground. The interface uses a command-based protocol, in which the host processor sends a command byte to the bq2016. The command directs the bq2016 to either store the next eight bits of data received to a register specified by the command byte or output the eight bits of data specified by the command byte. The communication protocol is asynchronous return-to-one. Command and data bytes consist of a stream of eight bits that have a maximum transmission rate of 5K bits/s. The least-significant bit of a command or data byte is transmitted first. The protocol is simple enough that it can be implemented by most host processors using either polled or interrupt processing. Data input from the bq2016 may be sampled using the pulse-width capture timers available on some microcontrollers. If a communication error occurs (e.g., tCYCB > 250µs), the bq2016 should be sent a BREAK to reinitiate the serial interface. A BREAK is detected when the HDQ pin is driven to a logic-low state for a time tB or greater. The HDQ pin should then be returned to its normal ready-high logic state for a time tBR. The bq2016 is now ready to receive a command from the host processor. 14 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 bq2016 GAS GAUGE IC FOR HIGH DISCHARGE RATES SLUS475A– JANUARY 2001 – REVISED NOVEMBER 2002 communicating with the bq2016 (continued) The return-to-one data bit frame consists of three distinct sections. The first section is used to start the transmission by either the host or the bq2016 taking the HDQ pin to a logic-low state for a period tSTRH;B. The next section is the actual data transmission, where the data should be valid by a period tDSU;B, after the negative edge used to start communication. The data should be held for a period tDH;DV, to allow the host or bq2016 to sample the data bit. The final section is used to stop the transmission by returning the HDQ pin to a logic-high state by at least a period tSSU;B, after the negative edge used to start communication. The final logic-high state should continue during a period tCYCH;B, to allow time to ensure that the bit transmission was stopped properly. The timings for data and break communication are given in the serial communication timing specification and illustration sections. In communication with the bq2016 the least-significant bit is always transmitted first. command code and registers The bq2016 status registers are listed in Table 9 and are described below. command code The bq2016 latches the command code when eight valid command bits have been received by the bq2016. The command code contains two fields: D W/R bit D Command address The W/R bit of the command code determines whether the received command is for a read or a write function. command code (continued) W/R is: 0 1 The bq2016 outputs the requested register contents specified by the address portion of command code. The host writes to the register specified by the address portion of the command code. The lower seven-bit field of the command code contains the address portion of the register to be accessed. The bq2016 ignores writes to invalid addresses. registers FLAGS1 (0x01) – Primary Status Flags The FLAGS1 register provides bq2016 status information. The 8-bit register includes the following status bits: 7 6 5 4 3 2 1 0 CHGS BRP MCV CI VDQ RSVD EDV OCE CHGS The bq2016 set the CHGS bit when it detects charge activity. The bq2016 clears the CHGS bit on discharge. Bit = Condition 0 The bq2016 detects discharge. 1 The bq2016 detects charge. BRP The bq2016 sets the BRP bit when it performs a full reset. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 15 bq2016 GAS GAUGE IC FOR HIGH DISCHARGE RATES SLUS475A– JANUARY 2001 – REVISED NOVEMBER 2002 registers (continued) MCV The bq2016 sets the MCV bit when it detects that the maximum cell voltage threshold is being exceeded. Bit = Condition 0 Cell voltage is below the threshold. 1 Cell voltage is above the threshold. CI The bq2016 sets the CI bit on reset and when the CPI register exceeds 64. Bit = Condition 0 An LMD update has occurred. 1 The bq2016 has been reset or the CPI register exceeds 64. VDQ The bq2016 sets the VDQ bit when the present discharge cycle is considered valid for an LMD update. Bit = Condition 0 The present discharge cycle is not valid for an LMD update. 1 The present discharge cycle is valid for an LMD update. Bit 2 is reserved. EDV The bq2016 sets the EDV bit when the battery voltage drops below the EDV threshold. The bit is latched and remains set until valid charge activity is detected. Bit = Condition 0 The battery voltage is greater than the EDV threshold. 1 The battery voltage is less than the EDV threshold. OCE The bq2016 sets the OCE bit when an VFC offset calibration has been performed. Bit = Condition 0 Offset calibration not completed 1 Offset calibration completed TEMP (0x02) – Temperature The TEMP register contains the battery temperature as computed using the internal temperature sensor of the bq2016. It is represented in degrees C. The data is an 8-bit signed integer. For example, –10°C is represented as F6h. NAC (0x03) – Nominal Available Capacity NAC is an 8-bit register that contains the present remaining capacity of the battery pack. The NAC contents are compensated for rate and temperature. The data is represented in the same units as PFC. LMD (0x05) – Last Measured Discharge LMD stores the learned discharge capacity of the battery pack and represents the full charge reference. The 8-bit register presents data in the same units as PFC. FLAGS2 (0x06) – Second Status Flags The FLAGS2 register provides bq2016 status information. The 8-bit register includes the following status bits: 16 7 6 5 4 3 2 1 0 RSVD DR2 DR1 DR0 RSVD RSVD RSVD OVLD POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 bq2016 GAS GAUGE IC FOR HIGH DISCHARGE RATES SLUS475A– JANUARY 2001 – REVISED NOVEMBER 2002 registers (continued) DR2–0 The DR2–0 bits represent the present discharge rate of the battery according to the following code: DISCHARGE RATE INDICATION DISCHARGE RATE (R) DR2 DR1 DR0 R ≤ 1C 0 0 0 1C < R ≤ 3C 0 0 1 3C < R ≤ 6C 0 1 0 6C < R ≤ 9C 0 1 1 9C < R ≤ 12C 1 0 0 R > 12C 1 0 1 OVLD The bq2016 set the OVLD bit when it detects that the present discharge rate exceeds the programmed overload threshold. Bit = Condition 0 Discharge rate is below the overload threshold. 1 Discharge rate is above the overload threshold. VPFC (0x07) – VPFC Pin Input Level VPFC stores the input level at the VPFC programming pin. The voltage at the VPFC (VVPFC) pin is calculated by VVPFC (mV) = Vcc × (VPFC/256) VPROG (0x08) – VPROG Pin Input Level VPROG stores the input level at the VPROG programming pin. The voltage at the VPROG (VPROG) pin is calculated by: VVPROG (mV) = Vcc × (VPROG/256) CPI (0x09) – Capacity Input Level CPI stores the number of valid charge actions since the last LMD update. OCTL (0x0a) – Output Control OCTL provides a means of testing LED functionality. The register consists of: 7 6 5 4 3 2 1 0 RSVD RSVD OCTL5 OCTL4 OCTL3 OCTL2 OCTL1 Enable When Enable is low, the bq2016 writes the data in OCTL5–1 to the LED5–1 pins. A one in OCTL5–1 turns the corresponding LED on. This function overrides the LED indication as a representation of capacity. FULCNT (0x0b) – Full Count Register FULCNT store the number of times the battery has been charged to full (NAC=LMD) in 16 count increments. CMDWD (0x0c) – Command Word The CMDWD register can be used to reset the bq2016 or initiate a VFC offset calibration. To reset the bq2016, 0x78 must be written to this location. When reset, the bq2016 sets the following values: NAC = 0 LMD = PFC CPI = 0 FULCNT = 0 DCR = 0 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 17 bq2016 GAS GAUGE IC FOR HIGH DISCHARGE RATES SLUS475A– JANUARY 2001 – REVISED NOVEMBER 2002 To calibrate the VFC, 0x68 must be written to this location. During VFC offset calibration, the bq2016 deselects the SR1 and SR2 inputs and disables the LEDs. When the bq2016 successfully completes VFC calibration, it sets the OCE bit in FLAGS1. The command 0x60 terminates a VFC calibration. The bq2016 automatically performs VFC calibration after trickle detection and initial power-up, and when NAC = LMD. PFC (0x0f) – Programmed Full Count The PFC register stores the battery design capacity as defined by the VPFC input. VSB (0x10 and 0x11) – Battery Voltage VSBH (0x11) and VSBL (0x10) form the 16-bit register that contains the voltage present at the SB input pin in mV. VSR (0x12 and 0x13) – Current Scale VSRH (0x13) and VSBL (0x12) form the 16-bit register that contains the voltage present across the SR inputs pin in mV. TEMPV (0x14 and 0x15) – Thermistor Voltage TEMPVH (0x15) and TEMPVL (0x14) form the 16-bit register that contains the voltage present at the TS inputs pin in mV. DCR (0x18) – Discharge Count Register DCR stores the cumulative discharge count from the time VDQ is set on a charge. The data is represented in the same units as PFC. The number of counts equals DRC × 256. FLAGS3 (0x4c) – Third Status Flags The FLAGS3 register provides bq2016 status information. The 8-bit register includes the following status bits: 7 6 5 4 3 2 1 0 RSVD RSVD RSVD RSVD VQ CR1 CR0 RSVD CR1–CR0 The CR1–CR0 bits represent the present charge rate of the battery according to the following code: CHARGE RATE INDICATION CR1 CR0 R≤C/8 CHARGE RATE (R) 0 0 C/5≥R>C/8 0 1 R>C/5 1 1 VQ The bq2016 sets the VQ bit when it detects a valid charge condition. A valid charge is two NAC increments. Bit = Condition 0 = No valid charge condition 1 = Valid charge condition present 18 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 bq2016 GAS GAUGE IC FOR HIGH DISCHARGE RATES SLUS475A– JANUARY 2001 – REVISED NOVEMBER 2002 registers (continued) Table 9. Command and Status Registers LOC (HEX) READ/ WRITE 7 6 5 Primary status flags 0x01 R CHGS BRP Temperature 0x02 R TP7 TP6 NAC Nominal available charge 0x03 R/W NCH7 LMD Last measured discharge 0x05 R/W Secondary status flags 0x06 R VPFC VPFC pin input level 0x07 R VPFC7 VPFC6 VPFC5 VPFC4 VPFC3 VPFC2 VPFC1 VPFC0 VPROG PROG pin input level 0x08 R VPRO7 VPRO6 VPRO5 VPRO4 VPRO3 VPRO2 VPRO1 VPRO0 Capacity inaccurate count 0x09 R CPI7 CPI6 CPI5 CPI4 CPI3 CPI2 CPI1 CPI0 OCTL LED output control 0x0a R/W NA NA OCTL5 OCTL4 OCTL3 OCTL2 OCTL1 Enable FCNT Full count register 0x0b R/W FCNT7 FCNT6 FCNT5 FCNT4 FCNT3 FCNT2 FCNT1 FCNT0 Command word 0x0c R/W CMD7 CMD6 CMD5 CMD4 CMD3 CMD2 CMD1 CMD0 SYMBOL FLAGS1 TEMP FLAGS2 CPI CMDWD REGISTER NAME 4 3 2 1 0 MCV CI VDQ RSVD EDV OCE TP5 TP4 TP3 TP2 TP1 TP0 NCH6 NCH5 NCH4 NCH3 NCH2 NCH1 NCH0 LMD7 LMD6 LMD5 LMD4 LMD3 LMD2 LMD1 LMD0 RSVD DR2 DR1 DR0 RSVD RSVD RSVD OVLD PFC Program PFC 0x0f R/W PFC7 PFC6 PCF5 PFC4 PFC3 PFC2 PFC1 PFC0 VSBL Battery voltage (low byte) 0x10 R VSBL7 VSBL6 VSBL5 VSBL4 VSBL3 VSBL2 VSBL1 VSBL0 VSBH Battery voltage (high byte) 0x11 R VSBH7 VSBH6 VSBH5 VSBH4 VSBH3 VSBH2 VSBH1 VSBH0 VSRL Current scale (low byte) 0x12 R VSRL7 VSRL6 VSRL5 VSRL4 VSRL3 VSRL2 VSRL1 VSRL0 VSRH Current scale (high byte) 0x13 R VSRH7 VSRH6 VSRH5 VSRH4 VSRH3 VSRH2 VSRH1 VSRH0 TEMPVL TS input voltage (low byte) 0x14 R TPVL7 TPVL6 TPVL5 TPVL4 TPVL3 TPVL2 TPVL1 TPVL0 TEMPVH TS input voltage (high byte) 0x15 R TPVH7 TPVH6 TPVH5 TPVH4 TPVH3 TPVH2 TPVH1 TPVH0 Discharge count register 0x18 R DCR7 DCR6 DCR5 DCR4 DCR3 DCR2 DCR1 DCR0 Third status flags 0x4c R RSVD RSVD RSVD RSVD VQ CR1 CR0 RSVD DCR FLAGS3 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 19 bq2016 GAS GAUGE IC FOR HIGH DISCHARGE RATES SLUS475A– JANUARY 2001 – REVISED NOVEMBER 2002 APPLICATION INFORMATION bq2016 applications schematic PACK+ VCC MMBT3904 HDQ 100 Ω BZX84C5V6 1.5 MΩ SST113 D G S 0.01 µF 100 Ω ZVP3306F R1 RBI VCC REG 0.1 µF Rv VSS SR1 DISP SR2 LED1 SRC 330 Ω 330 Ω 20 TS LED3 LED5 Rg 100 kΩ 0.1 µF 100 kΩ PACK– Rs 0.1 µF VCC 100 kΩ 0.1 µF LED2 LED4 Rg VPFC 330 Ω 330 Ω Cells Rv PROG VCC 100 kΩ Display 330 Ω VCC SB HDQ 1 µF R2 0.01 µF U1 bq2016 VCC THON 1 MΩ CVON POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 2N7002 IMPORTANT NOTICE Texas Instruments Incorporated and its subsidiaries (TI) reserve the right to make corrections, modifications, enhancements, improvements, and other changes to its products and services at any time and to discontinue any product or service without notice. Customers should obtain the latest relevant information before placing orders and should verify that such information is current and complete. All products are sold subject to TI’s terms and conditions of sale supplied at the time of order acknowledgment. TI warrants performance of its hardware products to the specifications applicable at the time of sale in accordance with TI’s standard warranty. Testing and other quality control techniques are used to the extent TI deems necessary to support this warranty. Except where mandated by government requirements, testing of all parameters of each product is not necessarily performed. TI assumes no liability for applications assistance or customer product design. Customers are responsible for their products and applications using TI components. To minimize the risks associated with customer products and applications, customers should provide adequate design and operating safeguards. TI does not warrant or represent that any license, either express or implied, is granted under any TI patent right, copyright, mask work right, or other TI intellectual property right relating to any combination, machine, or process in which TI products or services are used. Information published by TI regarding third–party products or services does not constitute a license from TI to use such products or services or a warranty or endorsement thereof. Use of such information may require a license from a third party under the patents or other intellectual property of the third party, or a license from TI under the patents or other intellectual property of TI. Reproduction of information in TI data books or data sheets is permissible only if reproduction is without alteration and is accompanied by all associated warranties, conditions, limitations, and notices. Reproduction of this information with alteration is an unfair and deceptive business practice. TI is not responsible or liable for such altered documentation. Resale of TI products or services with statements different from or beyond the parameters stated by TI for that product or service voids all express and any implied warranties for the associated TI product or service and is an unfair and deceptive business practice. TI is not responsible or liable for any such statements. Mailing Address: Texas Instruments Post Office Box 655303 Dallas, Texas 75265 Copyright 2002, Texas Instruments Incorporated