BQ2050SN-D119TRG4

bq2050 Lithium Ion Power Gauge™ IC Features General Description ➤ Conservative and repeatable measurement of available capacity in Lithium Ion rechargeable batteries The bq2050 Lithium Ion Power Gauge™ IC is intended for batterypack or in-system installation to maintain an accurate record of available battery capacity. The IC monitors a voltage drop across a sense resistor connected in series between the negative battery termina l a n d g r ou n d t o d e t e r m i n e charge and discharge activity of the battery. Compensations for battery temperature and rate of charge or discharge are applied to the charge, discharge, and self-discharge calculations to provide available capacity information across a wide range of operating conditions. Battery capacity is automatically recalibrated, or “learned,” in the course of a discharge cycle from full to empty. ➤ Designed for battery pack integration - 120µA typical operating current - Small size enables implementations in as little as 1 2 square inch of PCB ➤ Integrate within a system or as a stand-alone device - Display capacity via singlewire serial communication port or direct drive of LEDs ➤ Measurements compensated for current and temperature ➤ Self-discharge compensation using internal temperature sensor supports a simple single-line bidirectional serial link to an external processor (common ground). The bq2050 outputs battery information in response to external commands over the serial link. The bq2050 may operate directly from one cell (VBAT > 3V). With the REF output and an external transistor, a simple, inexpensive regulator can be built for systems with more than one series cell. Internal registers include available capacity, temperature, scaled available energy, battery ID, battery status, and programming pin settings. To support subassembly testing, the outputs may also be controlled. The external processor may also overwrite some of the bq2050 power gauge data registers. Nominal available capacity may be directly indicated using a fivesegment LED display. These segments are used to graphically indicate available capacity. The bq2050 ➤ 16-pin narrow SOIC Pin Connections Pin Names LCOM 1 16 VCC SEG1/PROG1 2 15 REF SEG2/PROG2 3 14 N/C SEG3/PROG3 4 13 DQ SEG4/PROG4 5 12 RBI SEG5/PROG5 6 11 SB PROG6 7 10 DISP VSS 8 9 SR LCOM LED common output REF Voltage reference output SEG1/PROG1 LED segment 1/ program 1 input N/C No connect DQ SEG2/PROG2 LED segment 2/ program 2 input Serial communications input/output RBI Register backup input SEG3/PROG3 LED segment 3/ program 3 input SB Battery sense input DISP Display control input SEG4/PROG4 LED segment 4/ program 4 input SR Sense resistor input SEG5/PROG5 LED segment 5/ program 5 input VCC 3.0–6.5V Program 6 input VSS System ground 16-Pin Narrow SOIC PN205001.eps PROG6 9/96 C 1 bq2050 SR Pin Descriptions LCOM The voltage drop (VSR) across the sense resistor RS is monitored and integrated over time to interpret charge and discharge activity. The SR input is tied between the negative terminal of the battery and the sense resistor. VSR < VSS indicates discharge, and VSR > VSS indicates charge. The effective voltage drop, VSRO, as seen by the bq2050 is VSR + VOS . LED common output Open-drain output switches VCC to source current for the LEDs. The switch is off during initialization to allow reading of the soft pull-up or pull-down program resistors. LCOM is also high impedance when the display is off. SEG1– SEG5 LED display segment outputs (dual function with PROG1–PROG6) DISP Programmed full count selection inputs (dual function with SEG1–SEG2) These three-level input pins define the programmed full count (PFC) thresholds described in Table 2. PROG3– PROG4 SB RBI Self-discharge rate selection (dual function with SEG5) DQ Capacity initialization selection Serial I/O pin This is an open-drain bidirectional pin. This three-level pin defines the battery state of charge at reset as shown in Table 1. N/C Register backup input This pin is used to provide backup potential to the bq2050 registers during periods when VCC ≤ 3V. A storage capacitor or a battery can be connected to RBI. This three-level input pin defines the selfdischarge and battery compensation factors as shown in Table 1. PROG6 Secondary battery input This input monitors the battery cell voltage potential through a high-impedance resistive divider network for end-of-discharge voltage (EDV) thresholds, and battery removed. Power gauge rate selection inputs (dual function with SEG3–SEG4) These three-level input pins define the scale factor described in Table 2. PROG5 Display control input DISP high disables the LED display. DISP tied to VCC allows PROGX to connect directly to VCC or VSS instead of through a pull-up or pull-down resistor. DISP floating allows the LED display to be active during charge. DISP low activates the display. See Table 1. Each output may activate an LED to sink the current sourced from LCOM. PROG1– PROG2 Sense resistor input REF No connect Voltage reference output for regulator REF provides a voltage reference output for an optional micro-regulator. 2 VCC Supply voltage input VSS Ground bq2050 Functional Description scaled available energy measurement is corrected for the environmental and operating conditions. General Operation Figure 1 shows a typical battery pack application of the bq2050 using the LED display capability as a chargestate indicator. The bq2050 is configured to display capacity in relative display mode. The relative display mode uses the last measured discharge capacity of the battery as the battery “full” reference. A push-button display feature is available for momentarily enabling the LED display. The bq2050 determines battery capacity by monitoring the amount of current input to or removed from a rechargeable battery. The bq2050 measures discharge and charge currents, measures battery voltage, estimates self-discharge, monitors the battery for low battery voltage thresholds, and compensates for temperature and charge/discharge rates. The current measurement is made by monitoring the voltage across a small-value series sense resistor between the negative battery terminal and ground. The estimate of scaled available energy is made using the remaining average battery voltage during the discharge cycle and the remaining nominal available charge. The The bq2050 monitors the charge and discharge currents as a voltage across a sense resistor (see RS in Figure 1). A filter between the negative battery terminal and the SR pin may be required if the rate of change of the battery current is too great. R1 1M bq2050 Power Gauge IC Q1 ZVNL110A REF C1 0.1 F LCOM SEG1/PROG1 VCC VCC SB VCC SEG2/PROG2 C2 RB2 SEG3/PROG3 DISP SEG4/PROG4 SR SEG5/PROG5 PROG6 RB1 RS VSS RBI PSTAT DQ Charger Indicates optional. Load Directly connect to VCC across 1 cell (VBAT > 3V). Otherwise, R1, C1, and Q1 are needed for regulation of > 1 cell. Programming resistors (6 max.) and ESD-protection diodes are not shown. R-C on SR may be required, application-specific. A series Zener may be used to limit discharge current at low voltages in designs using 3 or more cells. FG205001.eps Figure 1. Battery Pack Application Diagram—LED Display 3 bq2050 Voltage Thresholds In conjunction with monitoring VSR for charge/discharge currents, the bq2050 monitors the battery potential through the SB pin. The voltage is determined through a resistor-divider network per the following equation: RB1 = 2N − 1 RB2 where N is the number of cells, RB1 is connected to the positive battery terminal, and RB2 is connected to the negative battery terminal. The single-cell battery voltage is monitored for the end-of-discharge voltage (EDV). EDV threshold levels are used to determine when the battery has reached an “empty” state. Two EDV thresholds for the bq2050 are programmable with the default values fixed at: EDV1 (early warning) = 1.52V EDVF (empty) = 1.47V If VSB is below either of the two EDV thresholds, the associated flag is latched and remains latched, independent of VSB, until the next valid charge. The VSB value is also available over the serial port. During discharge and charge, the bq2050 monitors VSR for various thresholds used to compensate the charge and discharge rates. Refer to the count compensation section for details. EDV monitoring is disabled if the discharge rate is greater than 2C (typical) and resumes 1 second after the rate falls below 2C. 2 TMP (hex) Temperature Range 0x < -30°C 1x -30°C to -20°C 2x -20°C to -10°C 3x -10°C to 0°C 4x 0°C to 10°C 5x 10°C to 20°C 6x 20°C to 30°C 7x 30°C to 40°C 8x 40°C to 50°C 9x 50°C to 60°C Ax 60°C to 70°C Bx 70°C to 80°C Cx > 80°C Layout Considerations RBI Input The bq2050 measures the voltage differential between the SR and VSS pins. VOS (the offset voltage at the SR pin) is greatly affected by PC board layout. For optimal results, the PC board layout should follow the strict rule of a single-point ground return. Sharing high-current ground with small signal ground causes undesirable noise on the small signal nodes. Additionally: The RBI input pin is intended to be used with a storage capacitor or external supply to provide backup potential to the internal bq2050 registers when VCC drops below 3.0V. VCC is output on RBI when VCC is above 3.0V. A diode is required to isolate the external supply. Reset n The bq2050 can be reset either by removing VCC and grounding the RBI pin for 15 seconds or by writing 0x80 to register 0x39. Temperature n The bq2050 internally determines the temperature in 10°C steps centered from approximately -35°C to +85°C. The temperature steps are used to adapt charge and discharge rate compensations, self-discharge counting, and available charge display translation. The temperature range is available over the serial port in 10°C increments as shown in the following table: n 4 The capacitors (C1 and C2) should be placed as close as possible to the VCC and SB pins, respectively, and their paths to VSS should be as short as possible. A high-quality ceramic capacitor of 0.1µf is recommended for VCC. The sense resistor capacitor should be placed as close as possible to the SR pin. The sense resistor (RS) should be as close as possible to the bq2050. bq2050 The battery's initial capacity is equal to the Programmed Full Count (PFC) shown in Table 2. Until LMD is updated, NAC counts up to but not beyond this threshold during subsequent charges. This approach allows the gas gauge to be charger-independent and compatible with any type of charge regime. Gas Gauge Operation The operational overview diagram in Figure 2 illustrates the operation of the bq2050. The bq2050 accumulates a measure of charge and discharge currents, as well as an estimation of self-discharge. Charge and discharge currents are temperature and rate compensated, whereas self-discharge is only temperature compensated. 1. Last Measured Discharge (LMD) or learned battery capacity: The main counter, Nominal Available Capacity (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 and increment the DCR (Discharge Count Register). LMD is the last measured discharge capacity of the battery. On initialization (application of VCC or battery replacement), LMD = PFC. During subsequent discharges, the LMD is updated with the latest measured capacity in the Discharge Count Register (DCR) representing a discharge from full to below EDV1. A qualified discharge is necessary for a capacity transfer from the DCR to the LMD register. The LMD also serves as the 100% reference threshold used by the relative display mode. The Discharge Count Register (DCR) is used to update the Last Measured Discharge (LMD) register only if a complete battery discharge from full to empty occurs without any partial battery charges. Therefore, the bq2050 adapts its capacity determination based on the actual conditions of discharge. 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 Discharge Count Qualified Register (DCR) Transfer Measured < Discharged (LMD) Temperature Step, Other Data Temperature Translation Outputs Compensated Available Charge LED Display, etc. Serial Port Figure 2. Operational Overview 5 + FG205002.eps bq2050 2. Programmed Full Count (PFC) or initial battery capacity: Example: Selecting a PFC Value Given: The initial LMD and gas gauge rate values are programmed by using PROG1–PROG4. The bq2050 is configured for a given application by selecting a PFC value from Table 2. The correct PFC may be determined by multiplying the rated battery capacity in mAh by the sense resistor value: Sense resistor = 0.05Ω Number of cells = 2 Capacity = 1000mAh, Li-Ion battery, coke-anode Current range = 50mA to 1A Relative display mode Serial port only Self-discharge = NAC 512 per day @ 25°C Voltage drop over sense resistor = 2.5mV to 50mV Nominal discharge voltage = 3.6V Battery capacity (mAh) * sense resistor (Ω) = PFC (mVh) Selecting a PFC slightly less than the rated capacity provides a conservative capacity reference until the bq2050 “learns” a new capacity reference. Therefore: 1000mAh * 0.05Ω = 50mVh Table 1. bq2050 Programming Pin Connection PROG5 Compensation/ Self-Discharge PROG6 NAC on Reset DISP Display State H Table 4/Disabled PFC LEDs disabled 512 0 LEDs on when charging 512 0 LEDs on for 4 sec. Z Table 4/ NAC L Table 3/ NAC Note: PROG5 and PROG6 states are independent. Table 2. bq2050 Programmed Full Count mVh Selections PROGx 1 2 Programmed Full Count (PFC) PROG4 = L PROG3 = H PROG4 = Z PROG3 = Z PROG3 = L PROG3 = H PROG3 = Z PROG3 = L Units - - - SCALE = 1/80 H H 49152 614 307 154 76.8 38.4 19.2 mVh H Z 45056 563 282 141 70.4 35.2 17.6 mVh H L 40960 512 256 128 64.0 32.0 16.0 mVh Z H 36864 461 230 115 57.6 28.8 14.4 mVh Z Z 33792 422 211 106 53.0 26.4 13.2 mVh Z L 30720 384 192 96.0 48.0 24.0 12.0 mVh L H 27648 346 173 86.4 43.2 21.6 10.8 mVh L Z 25600 320 160 80.0 40.0 20.0 10.0 mVh L L 22528 282 141 70.4 35.2 17.6 8.8 mVh 90 45 22.5 11.25 5.6 2.8 mV VSR equivalent to 2 counts/sec. (nom.) SCALE = 1/160 SCALE = 1/320 SCALE = 1/640 SCALE = 1/1280 SCALE = 1/2560 mVh/ count 6 bq2050 E(mWh) = (SAEH * 256 + SAEL) * Select: 2.4 ∗ SCALE ∗ (R B1 + R B2 ) R S ∗ R B2 PFC = 30720 counts or 48mVh PROG1 = float PROG2 = low PROG3 = high PROG4 = float PROG5 = float PROG6 = float where RB1, RB2 and RS are resistor values in ohms. SCALE is the selected scale from Table 2. SAEH and SAEL are digital values read via DQ. 6. Compensated Available Capacity (CAC) The initial full battery capacity is 48mVh (960mAh) until the bq2050 “learns” a new capacity with a qualified discharge from full to EDV1. 3. CAC counts similar to NAC, but contains the available capacity compensated for discharge rate and temperature. Nominal Available Capacity (NAC): Charge Counting NAC counts up during charge to a maximum value of LMD and down during discharge and self-discharge to 0. NAC is reset to 0 on initialization and on the first valid charge following discharge to EDV1. To prevent overstatement of charge during periods of overcharge, NAC stops incrementing when NAC = LMD. 4. Charge activity is detected based on a positive voltage on the VSR input. If charge activity is detected, the bq2050 increments NAC at a rate proportional to VSR and, if enabled, activates an LED display. Charge actions increment the NAC after compensation for temperature. The bq2050 determines charge activity sustained at a continuous rate equivalent to VSRO > VSRQ. A valid charge equates to sustained charge activity greater than 256 NAC counts. Once a valid charge is detected, charge counting continues until VSRO (VSR + VOS) falls below VSRQ. VSRQ is 210µV, and is described in the Digital Magnitude Filter section. Discharge Count Register (DCR): The DCR counts up during discharge independent of NAC and could continue increasing after NAC has decremented to 0. Prior to 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 NAC = LMD. The DCR does not roll over but stops counting when it reaches FFFFh. Discharge Counting Discharge activity is detected based on a negative voltage on the VSR input. All discharge counts where VSRO < VSRD cause the NAC register to decrement and the DCR to increment. VSRD is -200µV, and is described in the Digital Magnitude Filter section. The DCR value becomes the new LMD value on the first charge after a valid discharge to VEDV1 if: No valid charge initiations (charges greater than 256 NAC counts, where VSRO > VSRQ) occurred during the period between NAC = LMD and EDV1 detected. Self-Discharge Estimation The bq2050 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 1 512 * NAC per day or disabled. This is the rate for a battery whose temperature is between 20°–30°C. The NAC register cannot be decremented below 0. The self-discharge count is not more than 4096 counts (8% to 18% of PFC, specific percentage threshold determined by PFC). The temperature is ≥ 0°C when the EDV1 level is reached during discharge. Count Compensations The valid discharge flag (VDQ) indicates whether the present discharge is valid for LMD update. 5. Discharge Compensation Scaled Available Energy (SAE): Corrections for the rate of discharge, temperature, and anode type are made by adjusting an internal compensation factor. This factor is based on the measured rate of discharge of the battery. Tables 3A and 3B outline the correction factor typically used for graphite anode Li-Ion batteries, and Tables 4A and 4B outline the factors typically used for coke anode Li-Ion batteries. The compensation factor is applied to CAC and is based on discharge rate and temperature. SAE is useful in determining the available energy within the battery, and may provide a more useful capacity reference in battery chemistries with sloped voltage profiles during discharge. SAE may be converted to a mWh value using the following formula: 7 bq2050 Charge Compensation Table 3A. Graphite Anode The bq2050 applies the following temperature compensation to NAC during charge: Approximate Discharge Rate Discharge Compensation Factor Efficiency < 0.5C 1.00 100% ≥ 0.5C 1.05 95% Temperature Temperature Compensation Factor < 10°C 0.95 95% ≥ 10°C 1.00 100% Efficiency This compensation applies to both types of Li-Ion cells. Table 3B. Graphite Anode Self-Discharge Compensation Temperature Temperature Compensation Factor Efficiency ≥ 10°C 1.00 100% 0°C to 10°C 1.10 90% -10°C to 0°C 1.35 74% ≤ -10°C 2.50 40% The self-discharge compensation is programmed for a nominal rate of 1 512 * NAC per day. This is the rate for a battery within the 20°C–30°C temperature range. This rate varies across 8 ranges from < 10°C to > 70°C, changing with each higher temperature (approximately 10°C). See Table 5 below: Table 5. Self-Discharge Compensation Typical Rate Temperature Range Table 4A. Coke Anode Approximate Discharge Rate Discharge Compensation Factor 70°C NAC 1.15 512 256 128 64 32 16 Self-discharge may be disabled by connecting PROG5 = H. Table 4B. Coke Anode Digital Magnitude Filter Temperature Temperature Compensation Factor Efficiency ≥ 10°C 1.00 100% 0°C to 10°C 1.25 80% -10°C to 0°C 2.00 50% ≤ -10°C 8.00 12% The bq2050 has a digital filter to eliminate charge and discharge counting below a set threshold. The bq2050 setting is 200µV for VSRD and 210µV for VSRQ. 8 bq2050 Table 6. bq2050 Current-Sensing Errors Symbol Parameter Typical INL Integrated non-linearity error ±2 INR Integrated nonrepeatability error ±1 Maximum Units Notes ±4 % Add 0.1% per °C above or below 25°C and 1% per volt above or below 4.25V. ±2 % Measurement repeatability given similar operating conditions. eight bits that have a maximum transmission rate of 333 bits/sec. 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 bq2050 may be sampled using the pulsewidth capture timers available on some microcontrollers. 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 (see the DCR description on page 7). 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. If a communication error occurs, e.g. tCYCB > 6ms, the bq2050 should be sent a BREAK to reinitiate the serial interface. A BREAK is detected when the DQ pin is driven to a logic-low state for a time, tB or greater. The DQ pin should then be returned to its normal readyhigh logic state for a time, tBR. The bq2050 is now ready to receive a command from the host processor. A Capacity Inaccurate counter (CPI) is maintained and incremented each time a valid charge occurs (qualified by NAC; see the CPI register description) 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. 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 bq2050 taking the DQ 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, after the negative edge used to start communication. The data should be held for a period, tDV, to allow the host or bq2050 to sample the data bit. Current-Sensing Error Table 5 illustrates the current-sensing error as a function of VSRO. A digital filter eliminates charge and discharge counts to the NAC register when VSRO is between VSRQ and VSRD. The final section is used to stop the transmission by returning the DQ pin to a logic-high state by at least a period, tSSU, after the negative edge used to start communication. The final logic-high state should be held until a period, tSV, 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. Communicating With the bq2050 The bq2050 includes a simple single-pin (DQ plus return) serial data interface. A host processor uses the interface to access various bq2050 registers. Battery characteristics may be easily monitored by adding a single contact to the battery pack. The open-drain DQ pin on the bq2050 should be pulled up by the host system, or may be left floating if the serial interface is not used. Communication with the bq2050 is always performed with the least-significant bit being transmitted first. Figure 3 shows an example of a communication sequence to read the bq2050 NAC register. The interface uses a command-based protocol, where the host processor sends a command byte to the bq2050. The command directs the bq2050 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-toone. Command and data bytes consist of a stream of 9 bq2050 Written by Host to bq2050 CMDR = 03h LSB MSB Break 1 1 0 0 0 0 0 0 Received by Host to bq2050 NAC = 65h LSB MSB 1 0 1 0 011 0 DQ TD205002.eps Figure 3. Typical Communication With the bq2050 bq2050 Registers Primary Status Flags Register (FLGS1) The bq2050 command and status registers are listed in Table 7 and described below. The read-only FLGS1 register (address=01h) contains the primary bq2050 flags. Command Register (CMDR) The charge status flag (CHGS) is asserted when a valid charge rate is detected. Charge rate is deemed valid when VSRO > VSRQ. A VSRO of less than VSRQ or discharge activity clears CHGS. The write-only CMDR register is accessed when eight valid command bits have been received by the bq2050. The CMDR register contains two fields: n W/R bit n Command address The CHGS values are: FLGS1 Bits The W/R bit of the command register is used to select whether the received command is for a read or a write function. 7 6 5 4 3 2 1 0 CHGS - - - - - - - Where CHGS is: The W/R values are: 0 Either discharge activity detected or VSRO < VSRQ 1 VSRO > VSRQ CMDR Bits 7 6 5 4 3 2 1 0 W/R - - - - - - - The battery replaced flag (BRP) is asserted whenever the bq2050 is reset either by application of VCC or by a serial port command. BRP is reset when either a valid charge action increments NAC to be equal to LMD, or a valid charge action is detected after the EDV1 flag is asserted. BRP = 1 signifies that the device has been reset. Where W/R is: 0 The bq2050 outputs the requested register contents specified by the address portion of CMDR. 1 The following eight bits should be written to the register specified by the address portion of CMDR. The BRP values are: FLGS1 Bits The lower seven-bit field of CMDR contains the address portion of the register to be accessed. Attempts to write to invalid addresses are ignored. CMDR Bits 7 - 6 5 AD6 AD5 7 6 5 4 3 2 1 0 - BRP - - - - - - Where BRP is: 4 3 2 1 0 AD4 AD3 AD2 AD1 AD0 (LSB) 10 0 Battery is charged until NAC = LMD or discharged until the EDV1 flag is asserted 1 bq2050 is reset bq2050 Table 7. bq2050 Command and Status Registers Symbol CMDR Register Name Command register Primary status flags FLGS1 register TMP Temperature register Nominal available caNACH pacity high byte register Nominal available NACL capacity low byte register Battery BATID identification register Last measured disLMD charge register Secondary status FLGS2 flags register Program pin pullPPD down register Program pin pull-up PPU register Capacity CPI inaccurate count register Battery voltage VSB register End-of-discharge threshVTS old select register Compensated availCACH able capacity high byte register Compensated CACL available capacity low byte register Scaled available SAEH energy high byte register Scaled available SAEL energy low byte register RST Reset register Note: n/u = not used Loc. Read/ Control Field (hex) Write 7(MSB) 6 AD6 00h Write W/R 5 AD5 4 AD4 3 AD3 2 AD2 1 AD1 0(LSB) AD0 01h Read CHGS BRP n/u CI VDQ n/u EDV1 EDVF 02h Read TMP3 TMP2 TMP1 TMP0 GG3 GG2 GG1 GG0 03h R/W NACH7 NACH6 NACH5 NACH4 NACH3 NACH2 NACH1 NACH0 17h Read NACL7 NACL6 NACL5 NACL4 NACL3 NACL2 NACL1 NACL0 04h R/W BATID7 BATID6 BATID5 BATID4 BATID3 BATID2 BATID1 BATID0 05h R/W LMD7 LMD6 LMD5 LMD4 LMD3 LMD2 LMD1 LMD0 06h Read n/u DR2 DR1 DR0 n/u n/u n/u OVLD 07h Read n/u n/u PPD6 PPD5 PPD4 PPD3 PPD2 PPD1 08h Read n/u n/u PPU6 PPU5 PPU4 PPU3 PPU2 PPU1 09h Read CPI7 CPI6 CPI5 CPI4 CPI3 CPI2 CPI1 CPI0 0Bh Read VSB7 VSB6 VSB5 VSB4 VSB3 VSB2 VSB1 VSB0 0Ch VTS7 VTS6 VTS5 VTS4 VTS3 VTS2 VTS1 VTS0 R/W 0Dh Read CACH7 CACH6 CACH5 CACH4 CACH3 CACH2 CACH1 CACH0 0Eh Read CACL7 CACL6 CACL5 CACL4 CACL3 CACL2 CACL1 CACL0 0Fh Read SAEH7 SAEH6 SAEH5 SAEH4 SAEH3 SAEH2 SAEH1 SAEH0 10h Read SAEL7 SAEL6 39h Write RST 0 11 SAEL5 SAEL4 SAEL3 SAEL2 SAEL1 SAEL0 0 0 0 0 0 0 bq2050 The EDV1 values are: The capacity inaccurate flag (CI) is used to warn the user that the battery has been charged a substantial number of times since LMD has been updated. The CI flag is asserted on the 64th charge after the last LMD update or when the bq2050 is reset. The flag is cleared after an LMD update. FLGS1 Bits 7 6 5 4 3 2 1 0 - - - - - - EDV1 - The CI values are: Where EDV1 is: FLGS1 Bits 7 6 5 4 3 2 1 0 - - - CI - - - - When LMD is updated with a valid full discharge 1 After the 64th valid charge action with no LMD updates or the bq2050 is reset n n 1 VSB < VTS providing that the discharge rate is < 2C The EDVF values are: The valid discharge flag (VDQ) is asserted when the bq2050 is discharged from NAC=LMD. The flag remains set until either LMD is updated or one of three actions that can clear VDQ occurs: n Valid charge action detected, VSB ≥ VTS The final end-of-discharge warning flag (EDVF) flag is used to warn that battery power is at a failure condition. All segment drivers are turned off. The EDVF flag is latched until a valid charge has been detected. The EDVF threshold is set 50mV below the EDV1 threshold. Where CI is: 0 0 FLGS1 Bits The self-discharge count register (SDCR) has exceeded the maximum acceptable value (4096 counts) for an LMD update. 7 6 5 4 3 2 1 0 - - - - - - - EDVF Where EDVF is: A valid charge action sustained at VSRO > VSRQ for at least 256 NAC counts. 0 Valid charge action detected, VSB ≥ (VTS 50mV) 1 VSB < (VTS - 50mV) providing the discharge rate is < 2C The EDV1 flag was set at a temperature below 0°C The VDQ values are: Temperature Register (TMP) The read-only TMP register (address=02h) contains the battery temperature. FLGS1 Bits 7 6 5 4 3 2 1 0 - - - - VDQ - - - TMP Temperature Bits 7 Where VDQ is: 0 1 6 5 4 TMP4 TMP3 TMP2 TMP1 SDCR ≥ 4096, subsequent valid charge action detected, or EDV1 is asserted with the temperature less than 0°C 3 2 1 0 - - - - The bq2050 contains an internal temperature sensor. The temperature is used to set charge and discharge efficiency factors as well as to adjust the self-discharge coefficient. The temperature register contents may be translated as shown in Table 7. On first discharge after NAC = LMD The first end-of-discharge warning flag (EDV1) warns the user that the battery is almost empty. The first segment pin, SEG1, is modulated at a 4Hz rate if the display is enabled once EDV1 is asserted, which should warn the user that loss of battery power is imminent. The EDV1 flag is latched until a valid charge has been detected. The EDV1 threshold is externally controlled via the VTS register (see Voltage Threshold Register on this page). The bq2050 calculates the gas gauge bits, GG3-GG0 as a function of CACH and LMD. The results of the calculation give available capacity in 1 16 increments from 0 to 15 16. 12 bq2050 Table 7. Temperature Register Last Measured Discharge Register (LMD) TMP3 TMP2 TMP1 TMP0 0 0 0 0 T < -30°C 0 0 0 1 -30°C < T < -20°C 0 0 1 0 -20°C < T < -10°C 0 0 1 1 -10°C < T < 0°C 0 1 0 0 0°C < T < 10°C 0 1 0 1 10°C < T < 20°C 0 1 1 0 20°C < T < 30°C 0 1 1 1 30°C < T < 40°C LMD is a read/write register (address=05h) that the bq2050 uses as a measured full reference. The bq2050 adjusts LMD based on the measured discharge capacity of the battery from full to empty. In this way the bq2050 updates the capacity of the battery. LMD is set to PFC during a bq2050 reset. Temperature 1 0 0 0 40°C < T < 50°C 1 0 0 1 50°C < T < 60°C 1 0 1 0 60°C < T < 70°C 1 0 1 1 70°C < T < 80°C 1 1 0 0 T > 80°C Secondary Status Flags Register (FLGS2) The read-only FLGS2 register (address=06h) contains the secondary bq2050 flags. 7 - TMPGG Gas Gauge Bits 6 5 4 3 2 1 0 - - - - GG3 GG2 GG1 GG0 2 - 1 - 0 The discharge rate flags, DR2–0, are bits 6–4. DR2 0 0 0 7 FLGS2 Bits 5 4 3 DR1 DR0 - 6 DR2 DR1 0 0 1 DR0 0 1 0 Discharge Rate DRATE < 0.5C 0.5C ≤ DRATE < 2C DRATE ≥ 2C (OVLD = 1) They are used to determine the current discharge regime as follows: Nominal Available Charge Registers (NACH/NACL) 7 - The read/write NACH high-byte register (address=03h) and the read-only NACL low-byte register (address=17h) are the main gas gauging register for the bq2050. The NAC registers are incremented during charge actions and decremented during discharge and self-discharge actions. The correction factors for charge/discharge efficiency are applied automatically to NAC. NACH and NACL are set to 0 during a bq2050 reset. 6 - 5 - FLGS2 Bits 4 3 - 2 - 1 - 0 OVLD The overload flag (OVLD) is asserted when a discharge rate in excess of 2C is detected. OVLD remains asserted as long as the condition persists and is cleared 0.5 seconds after the rate drops below 2C. The overload condition is used to stop sampling of the battery terminal characteristics for end-of-discharge determination. Program Pin Pull-Down Register (PPD) Writing to the NAC registers affects the available charge counts and, therefore, affects the bq2050 gas gauge operation. Do not write the NAC registers to a value greater than LMD. The read-only PPD register (address=07h) contains some of the programming pin information for the bq2050. The segment drivers, SEG1–6, have a corresponding PPD register location, PPD1–6. A given location is set if a pull-down resistor has been detected on its corresponding segment driver. For example, if SEG1 and SEG4 have pull-down resistors, the contents of PPD are xx001001. Battery Identification Register (BATID) The read/write BATID register (address=04h) is available for use by the system to determine the type of battery pack. The BATID contents are retained as long as VCC is greater than 2V. The contents of BATID have no effect on the operation of the bq2050. There is no default setting for this register. Program Pin Pull-Up Register (PPU) The read-only PPU register (address=08h) contains the rest of the programming pin information for the bq2050. The segment drivers, SEG1–6, have a corresponding PPU register location, PPU1–6. A given location is set if a pull-up resistor has been detected on its corresponding segment 13 bq2050 driver. For example, if SEG3 and SEG6 have pull-up resistors, the contents of PPU are xx100100. VTS Register Bits 7 PPD/PPU Bits 5 4 3 6 5 4 3 2 1 0 VTS7 VTS6 VTS5 VTS4 VTS3 VTS2 VTS1 VTS0 7 6 2 1 0 - - PPU6 PPU5 PPU4 PPU3 PPU2 PPU1 - - PPD6 PPD5 PPD4 PPD3 PPD2 PPD1 Compensated Available Charge Registers (CACH/CACL) The read-only CACH high-byte register (address = 0Dh) and the read-only CACL low-byte register (address = 0Eh) represent the available charge compensated for discharge rate and temperature. CACH and CACL use piece-wise corrections as outlined in Tables 3A, 3B, 4A, and 4B, and will vary as conditions change. The NAC and LMD registers are not affected by the discharge rate and temperature. Capacity Inaccurate Count Register (CPI) The read-only CPI register (address=09h) is used to indicate the number of times a battery has been charged without an LMD update. Because the capacity of a rechargeable battery varies with age and operating conditions, the bq2050 adapts to the changing capacity over time. A complete discharge from full (NAC=LMD) to empty (EDV1=1) is required to perform an LMD update assuming there have been no intervening valid charges, the temperature is greater than or equal to 0°C, and the self-discharge counter is less than 4096 counts. Scaled Available Energy Registers (SAEH/SAEL) The read-only SAEH high-byte register (address = 0Fh) and the read only SAEL low-byte register (address = 10h) are used to scale battery voltage and CAC to a value which can be translated to watt-hours remaining under the present conditions. SAEL and SAEH may be converted to mWh using the formula on page 7. The CPI register is incremented every time a valid charge is detected. When NAC > 0.94 * LMD, however, the CPI register increments on the first valid charge; CPI does not increment again for a valid charge until NAC < 0.94 * LMC. This prevents continuous trickle charging from incrementing CPI if self-discharge decrements NAC. The CPI register increments to 255 without rolling over. When the contents of CPI are incremented to 64, the capacity inaccurate flag, CI, is asserted in the FLGS1 register. The CPI register is reset whenever an update of the LMD register is performed, and the CI flag is also cleared. Reset Register (RST) The reset register (address = 39h) enables a softwarecontrolled reset of the device. By writing the RST register contents from 00h to 80h, a bq2050 reset is performed. Setting any bit other than the most-significant bit of the RST register is not allowed and results in improper operation of the bq2050. Battery Voltage Register (VSB) Resetting the bq2050 sets the following: The read-only battery voltage register is used to read the single-cell battery voltage on the SB pin. The VSB register (address = 0Bh) is updated approximately once per second with the present value of the battery voltage. VSB = 2.4V * (VSB/256). n LMD = PFC n CPI, VDQ, NACH, and NACL = 0 n CI and BRP = 1 Note: Self-discharge is disabled when PROG5 = H. VSB Register Bits 7 6 5 4 3 2 1 Display 0 VSB7 VSB6 VSB5 VSB4 VSB3 VSB2 VSB1 VSB0 The bq2050 can directly display capacity information using low-power LEDs. If LEDs are used, the program pins should be resistively tied to VCC or VSS for a program high or program low, respectively. Voltage Threshold Register (VTS) The end-of-discharge threshold voltages (EDV1 and EDVF) can be set using the VTS register (address = 0Ch). The read/write VTS register sets the EDV1 trip point. EDVF is set 50mV below EDV1. The default value in the VTS register is A2h, representing EDV1 = 1.52V and EDVF = 1.47V. EDV1 = 2.4V * (VTS/256). The bq2050 displays the battery charge state in relative mode. In relative mode, the battery charge is represented as a percentage of the LMD. Each LED segment represents 20% 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 14 bq2050 SEG1 blinks at a 4Hz rate whenever VSB has been detected to be below VEDV1 (EDV1 = 1), indicating a lowbattery condition. VSB below VEDVF (EDVF = 1) disables the display output. not affect the NAC register. The temperature adjustments are detailed in the CACH and CACL register descriptions. When DISP is tied to VCC, the SEG1–5 outputs are inactive. When DISP is left floating, the display becomes active whenever the bq2050 detects a charge in progress VSRO > VSRQ . When pulled low, the segment outputs become active for a period of four seconds, ± 0.5 seconds. Microregulator The bq2050 can operate directly from one cell. A micropower source for the bq2050 can be inexpensively built using the FET and an external resistor to accommodate a greater number of cells; see Figure 1. The segment outputs are modulated as two banks, with segments 1, 3, and 5 alternating with segments 2 and 4. The segment outputs are modulated at approximately 100Hz with each segment bank active for 30% of the period. 15 bq2050 Absolute Maximum Ratings Symbol Parameter Minimum Maximum Unit Notes VCC Relative to VSS -0.3 7.0 V All other pins Relative to VSS -0.3 7.0 V REF Relative to VSS -0.3 8.5 V Current limited by R1 (see Figure 1) VSR Relative to VSS -0.3 7.0 V Minimum 100Ω series resistor should be used to protect SR in case of a shorted battery (see the bq2050 application note for details). TOPR Operating temperature 0 70 °C Commercial Note: Permanent device damage may occur if Absolute Maximum Ratings are exceeded. Functional operation should be limited to the Recommended DC Operating Conditions detailed in this data sheet. Exposure to conditions beyond the operational limits for extended periods of time may affect device reliability. DC Voltage Thresholds (TA = TOPR; V = 3.0 to 6.5V) Symbol Parameter Minimum Typical Maximum Unit Notes VEDVF Final empty warning 1.44 1.47 1.50 V SB VEDV1 First empty warning 1.49 1.52 1.55 V SB VSRO SR sense range -300 - 2000 mV SR, VSR + VOS VSRQ Valid charge 210 - - µV VSR + VOS (see note) VSRD Valid discharge - - -200 µV VSR + VOS (see note) VMCV Maximum single-cell voltage 2.20 2.25 2.30 V Note: VOS is affected by PC board layout. Proper layout guidelines should be followed for optimal performance. See “Layout Considerations.” 16 SB bq2050 DC Electrical Characteristics (TA = TOPR) Symbol Parameter VCC Supply voltage VOS Offset referred to VSR VREF Minimum Typical Maximum Unit Notes VCC excursion from < 2.0V to ≥ 3.0V initializes the unit. 3.0 4.25 6.5 V - ±50 ±150 µV DISP = VCC Reference at 25°C 5.7 6.0 6.3 V IREF = 5µA Reference at -40°C to +85°C 4.5 - 7.5 V IREF = 5µA RREF Reference input impedance 2.0 5.0 - MΩ VREF = 3V - 90 135 µA VCC = 3.0V, DQ = 0 ICC Normal operation - 120 180 µA VCC = 4.25V, DQ = 0 - 170 250 µA VCC = 6.5V, DQ = 0 - VCC V VSB Battery input 0 RSBmax SB input impedance 10 - - MΩ 0 < VSB < VCC IDISP DISP input leakage - - 5 µA VDISP = VSS ILCOM LCOM input leakage -0.2 - 0.2 µA DISP = VCC VRBI > VCC < 3V IRBI RBI data retention current - - 100 nA RDQ Internal pulldown 500 - - KΩ VSR Sense resistor input -0.3 - 2.0 V RSR SR input impedance VIH Logic input high VIL Logic input low VIZ Logic input Z VOLSL 10 - - MΩ VCC - 0.2 - - V VSR < VSS = discharge; VSR > VSS = charge -200mV < VSR < VCC PROG1–PROG6 - - VSS + 0.2 V PROG1–PROG6 float - float V PROG1–PROG6 SEGX output low, low VCC - 0.1 - V VCC = 3V, IOLS ≤ 1.75mA SEG1–SEG5 VOLSH SEGX output low, high VCC - 0.4 - V VCC = 6.5V, IOLS ≤ 11.0mA SEG1–SEG5 VCC = 3V, IOHLCOM = -5.25mA VOHLCL LCOM output high, low VCC VCC - 0.3 - - V VOHLCH LCOM output high, high VCC VCC - 0.6 - - V IIH PROG1-6 input high current - 1.2 - µA IIL PROG1-6 input low current IOHLCOM LCOM source current VCC = 6.5V, IOHLCOM = -33.0mA VPROG = VCC/2 - 1.2 - µA VPROG = VCC/2 -33 - - mA At VOHLCH = VCC - 0.6V IOLS SEG1-5 sink current - - 11.0 mA At VOLSH = 0.4V IOL Open-drain sink current - - 5.0 mA At VOL = VSS + 0.3V DQ IOL ≤ 5mA, DQ VOL Open-drain output low - - 0.5 V VIHDQ DQ input high 2.5 - - V DQ VILDQ DQ input low - - 0.8 V DQ RPROG Soft pull-up or pull-down resistor value (for programming) - - 200 KΩ PROG1–PROG6 RFLOAT Float state external impedance - 5 - MΩ PROG1–PROG6 Note: All voltages relative to VSS. 17 bq2050 Serial Communication Timing Specification (TA = TOPR) Symbol Parameter Minimum Typical Maximum Unit tCYCH Cycle time, host to bq2050 3 - - ms tCYCB Cycle time, bq2050 to host 3 - 6 ms tSTRH Start hold, host to bq2050 5 - - ns tSTRB Start hold, bq2050 to host 500 - - µs tDSU Data setup - - 750 µs tDH Data hold 750 - - µs tDV Data valid 1.50 - - ms tSSU Stop setup - - 2.25 ms tSH Stop hold 700 - - µs tSV Stop valid 2.95 - - ms tB Break 3 - - ms tBR Break recovery 1 - - ms Notes: Notes See note The open-drain DQ pin should be pulled to at least VCC by the host system for proper DQ operation. DQ may be left floating if the serial interface is not used. Serial Communication Timing DQ (R/W "1") DQ (R/W "0") tSTRH tSTRB tDH tDSU tDV tSH tSSU DQ (BREAK) tSV tCYCH, tCYCB, tB tBR TD201002.eps 18 bq2050 16-Pin SOIC Narrow (SN) 16-Pin SN (0.150" SOIC) D e Inches B Dimension Min. Max. Min. Max. A 0.060 0.070 1.52 1.78 A1 0.004 0.010 0.10 0.25 B 0.013 0.020 0.33 0.51 C 0.007 0.010 0.18 0.25 E H A C Millimeters A1 D 0.385 0.400 9.78 10.16 E 0.150 0.160 3.81 4.06 e 0.045 0.055 1.14 1.40 H 0.225 0.245 5.72 6.22 L 0.015 0.035 0.38 0.89 .004 L Data Sheet Revision History Change No. 1 Page No. 4 1 2 11, 14 16 2 2 2 Notes: Description Changed reset procedure Was: Is: Deleted reset register Changed values VEDVF: VEDV1: VCC: 17 Changed values 4, 11, 13, 14 Reinserted reset register 9 Maximum offset VOS: Change 1 = June 1995 B changes from Dec. 1994. Change 2 = Sept. 1996 C changes from June 1995 B. 19 Nature of Change Reset by issuing command over serial port Reset by removing VCC and grounding RBI for 15 s. Min. was 1.45; Max. was 1.49 Min. now is 1.44; Max. now is 1.50 Min. was 1.50; Min. now is 1.49 Min. was 2.5; Min. now is 3.0 Max. was 150 Max. now is 180 bq2050 Ordering Information bq2050 Temperature Range: blank = Commercial (-20 to +70°C) Package Option: SN = 16-pin narrow SOIC Device: bq2040 Gas Gauge IC With SMB Interface 17919 Waterview Parkway Dallas, Texas 75252 Fax: (972) 437-9198 Tel: (972) 437-9195 www.benchmarq.com or www.unitrode.com Copyright © 1996, Unitrode Corporation All rights reserved. No part of this data sheet may be reproduced in any form or means, without express permission from Unitrode. Unitrode reserves the right to make changes in its products without notice. Unitrode assumes no responsibility for use of any products or circuitry described within. No license for use of intellectual property (patents, copyrights, or other rights) owned by Unitrode or other parties is granted or implied. Unitrode does not authorize the use of its components in life-support systems where failure or malfunction may cause injury to the user. If Unitrode components are used in life-support systems, the user assumes all responsibilities and indemnifies Unitrode from all liability or damages. Benchmarq is a registered trademark of Unitrode Corporation. 20 Printed in U.S.A. PACKAGE OPTION ADDENDUM www.ti.com 10-Dec-2020 PACKAGING INFORMATION Orderable Device Status (1) Package Type Package Pins Package Drawing Qty Eco Plan (2) Lead finish/ Ball material MSL Peak Temp Op Temp (°C) Device Marking (3) (4/5) (6) BQ2050SN-D119 ACTIVE SOIC D 16 40 RoHS & Green NIPDAU Level-2-260C-1 YEAR 0 to 70 2050 D119 BQ2050SN-D119TR ACTIVE SOIC D 16 2500 RoHS & Green NIPDAU Level-2-260C-1 YEAR 0 to 70 2050 D119 (1) The marketing status values are defined as follows: ACTIVE: Product device recommended for new designs. LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect. NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design. PREVIEW: Device has been announced but is not in production. Samples may or may not be available. OBSOLETE: TI has discontinued the production of the device. (2) RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may reference these types of products as "Pb-Free". RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption. Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of