SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 D Dynamic Power Management, DPM D D D D D D D D D PW PACKAGE (TOP VIEW) Minimizes Battery Charge Time Integrated Selector Supports Battery Conditioning and Smart Battery Learn Cycle Selector Feedback Circuit Insures Break-Before-Make Transition ±0.4% Charge Voltage Accuracy, Suitable for Charging Li-Ion Cells ±4% Charge Current Accuracy 300-kHz Integrated PWM Controller for High-Efficiency Buck Regulation Depleted Battery Detection and Indication to Protect Battery From Over Discharge 15-µA Sleep Mode Current for Low Battery Drain Designed for Charge Management of NiCd/NiMH and Li-Ion/Li-Pol Battery Packs 24-Pin TSSOP Package ACDET ACPRES ACSEL BATDEP SRSET ACSET VREF ENABLE BATSET COMP ACN ACP 1 24 2 23 3 22 4 21 5 20 6 19 7 18 8 17 9 16 10 15 11 14 12 13 ACDRV BATDRV VCC PWM VHSP ALARM VS GND SRP SRN IBAT BATP application schematic D1 R5 ADAPTER MBRD640CT 0.025 SUPPLY DPAK 1W Q1 IRFR5305 100Ω 11 ACN ACDRV 24 1 µF 12 ACP 1 ACDET VBAT R6 D1 MBRD640CT 0.05 0.5 W DPAK 220µF 30 V bq24700PW 100Ω R1 499 kΩ 33 µH D05022p–333 Q2 IRFR5305 4.7 Ω PWM 21 TO SYSTEM D4 17 V R7 523 k Ω VCC 22 100 kΩ Q3 IRFR5305 12.6 V + C5, C6 22 µF x2 35 V D4 17 V R14 523 k Ω 4.7µF R10 Ω 20Ω 8 ENABLE SRP 16 3 ACSEL SRN 15 19 ALARM BATP 13 C3 10µ F R9 57.6 k Ω R15 57.6 k Ω 10Ω B330 100 kΩ B330 5 SRSET BATDRV 23 J1 6 ACSET 2 ACPRES 14 IBAT 20 k Ω 5VREF C7 3.3µF C8 7 VREF VS 18 D3 18 V VHSP 20 VCC BATSET 9 499 k Ω BATDEP 4 150 pF GND 17 VBAT C4 10 µF 35 V 180 pF 76.8 kΩ 10 COMP C9 4.7µF R13 100Ω UDG–00138 CHARGE VOLTAGE SETPOINT 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 !"#$%&" ' ()##* & %' "! +),(%&" -%&*. #"-)(&' (" !"#$ &" '+*(!(%&" ' +*# &/* &*#$' "! *0%' '&#)$* &' '&% -%#- 1%##% &2. #"-)(&" +#"(*'' 3 -"*' "& *(*''%#,2 (,)-* &*'& 3 "! %,, +%#%$*&*#'. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 1 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 description The bq24700/bq24701 is a highly integrated battery charge controller and selector tailored for the notebook and sub-notebook PC applications. The bq24700/bq24701 uses dynamic power management (DPM) to minimize battery charge time by maximizing use of available wall-adapter power. This is achieved by dynamically adjusting the battery charge current based on the total system (adapter) current. The bq24700/bq24701 uses a fixed frequency, pulse width modulator (PWM) to accurately control battery charge current and voltage. Charge current limits can be programmed from a keyboard controller DAC or by external resistor dividers from the precision 5-V, ±0.6%, externally bypassed voltage reference (VREF), supplied by the bq24700/bq24701. The battery voltage limit can be programmed by using the internal 1.25-V, ±0.5% precision reference, making it suitable for the critical charging demands of lithium-ion cells. Also, the bq24700/bq24701 provides an option to override the precision 1.25-V reference and drive the error amplifier either directly from an external reference or from a resistor divider off the 5 V supplied by the integrated circuit. The selector function allows the manual selection of the system power source, battery or wall-adapter power. The bq24700 supports battery-conditioning and battery-lean cycles through the ACSEL function. The ACSEL function allows manual selection of the battery or wall power as the main system power. It also provides autonomous switching to the remaining source (battery or ac power) should the selected system power source terminate (refer to Table 1 for the differences between the bq24700 and the bq24701). The bq24700/bq24701 also provides an alarm function to indicate a depleted battery condition. The bq24700/bq24701 PWM controller is ideally suited for operation in a buck converter for applications when the wall-adapter voltage is greater than the battery voltage. AVAILABLE OPTIONS Condition –40 C TA 85 C Selector Operation bq24700PW bq24701PW Battery as Power Source Battery removal Automatically selects ac Automatically selects ac Battery reinserted Selection based on selector inputs Selection based on selector inputs AC removal Automatically selects battery Automatically selects battery AC reinserted Selection based on selector inputs Selection based on selector inputs Battery as power source Sends ALARM signal Automatically selects ac Sends ALARM signal AC as power source Sends ALARM signal Sends ALARM signal Depleted battery condition Depleted battery condition ac as Power Source Depleted Battery Condition ALARM Signal Active Selector inputs do not match selector outputs 2 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 absolute maximum ratings over operating free-air temperature (unless otherwise noted)Ĕ} Supply voltage range: VCC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –0.3 V to 20 V Battery voltage range: SRP, SRN . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –0.3 V to 19 V Input voltage: ACN, ACP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –0.3 V to 20 V Virtual junction temperature range, TJ . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –40°C to 85°C Storage temperature range Tstg . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –65°C to 150°C Lead temperature (Soldering, 10 seconds) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 300°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. ‡ All voltages are with respect to ground. Currents are positive into and negative out of the specified terminals. Consult the Packaging section of the databook for thermal limitations and considerations of the package. recommended operating conditions (TA = TOPR) all voltages relative to Vss MIN MAX Analog and PWM operation 7.0 20 Selector operation 4.5 20 Negative ac current sense, (ACN) 7.0 20 V Positive ac current sense, (ACP) 7.0 20 V Negative battery current sense, (SRN) 5.0 18 V S ppl voltage, Supply oltage (VCC) Positive battery current sense, (SRP) UNIT V 5.0 18 V AC or adapter power detection (ACDET) –0.3 8 V AC power indicator (ACPRES) –0.3 8 V AC adapter power select (ACSEL) –0.3 8 V Depleted battery level (BATDEP) –0.3 8 V Battery charge current programming voltage (SRSET) –0.3 8 V Charge enable (ENABLE) –0.3 8 V External override to an internal 0.5% precision reference (BATSET) –0.3 8 V Inverting input to the PWM comparator (COMP) –0.3 8 V Battery charge regulation voltage measurement input to the battery—voltage gm amplifier (BATP) –0.3 8 V Battery current differential amplifier output (IBAT) –0.3 8 V System load voltage input pin (VS) –0.3 8 V Depleted battery alarm output (ALARM) –0.3 8 V Gate drive output (PWM) –0.3 20 V Battery power source select output (BATDRV) –0.3 20 V AC or adapter power source selection output (ACDRV) –0.3 20 V Operating free–air temperature, TA –40 85 °C POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 3 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 block diagram VHSP VCC 20 22 VREF 7 VREF = 5 V 0.5% ACPRES VCC/2 2 VCC > 15 V REF1 = 1.22 V ACPRES 1 REF2 = 1.25 V 0.5% ACPRES HYST = 6% ACDET VOLTAGE REFERENCE + VCC 300 kHz S Q R Q 2V REF1 = 1.22 V ACSEL 3 ENABLE 8 OSC PWM LOGIC LEVEL SHIFT HIGH–SIDE DRIVE 21 PWM 13 BATP 9 BATSET 16 SRP 15 SRN 5 SRSET 24 ACDRV 23 BATDRV 17 GND 14 IBAT + VHSP 5V 100 µA COMP BATTERY VOLTAGE ERROR AMPLIFIER 10 VCC 2 kΩ ACP 12 + ACN 11 ACSET 6 ac CURRENT ERROR AMPLIFIER + SRN 4 DEPLETED BATTERY COMPARATOR BATP VS 18 ALARM 19 2 kΩ + + VCC + 50 kΩ ADAPTER SELECT DRIVE NO BATTERY COMPARATOR + VHSP 2 + SWITCH TO BATTERY 0.25 V 1.25 V 0.5% BATTERY CURRENT ERROR AMPLIFIER 0.8 x REF1 REF1=1.22 V + + 25 kΩ BATDEP 5V ACPRES ACSEL 1 1 bq24700 ONLY VCC BATTERY SELECT LOGIC AND ANTI–CROSS CONDUCT ACDRV ACSEL BATTERY SELECT DRIVE SRN VREF SRP SRN + A=20 2 bq24701 ONLY UDG–00137 4 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 electrical characteristics (TA = TOPR, 7.0 Vdc otherwise specified) VCC 20.0 Vdc, all voltages relative to Vss) (unless quiescent current PARAMETER IDDOP TEST CONDITIONS Total chip operating current, switching and no load on PWMB ISLEEP Total battery sleep current, ac not present ACPRES = High, PWM ON, VCC = 30 V MIN TYP MAX 1 3 6 mA 15 22 µA ACPRES = Low, VCC = SRN = 18 V UNIT logic interface dc characteristics PARAMETER VOL VIL TEST CONDITIONS Low-level output voltage (ACPRES, ALARM) MIN TYP IOL = 1 mA Low–level input voltage (ACSEL, ENABLE) VIH High-level input voltage (ACSEL, ENABLE) ISINK1 Sink current (ACPRES) ISINK2 Sink current (ALARM) MAX 0.4 V 0.8 V 1.8 VOL = 0.4 VOL = 0.4 UNIT V 2 5 8 mA 0.75 1.5 3.5 mA pwm oscillator PARAMETER fOSC(PWM) TEST CONDITIONS Oscillator frequency MIN TYP MAX 0°C ≤ TA ≤ 85°C 260 300 340 –40°C ≤ TA ≤ 0°C 240 300 340 Maximum duty cycle UNIT kHz 100% Input voltage for maximum dc (COMP) 3.8 V Minimum duty cycle 0% Input voltage for minimum dc (COMP) 0.8 VRAMP (peak to peak) Oscillator ramp voltage (peak-to-peak) VIK(COMP) Internal input clamp voltage (tracks COMP voltage for maximum dc) IS(COMP) Internal source current (COMP) 0°C ≤ TA ≤ 85°C 1.85 2.15 2.30 –40°C ≤ TA ≤ 0°C 1.60 2.15 2.30 3.8 4.5 70 110 140 µA MIN TYP MAX UNIT Error amplifier = OFF, VCOMP = 1 V V leakage current PARAMETER TEST CONDITIONS IL_ACDET IL_SRSET Leakage current, ACDET 1 µA Leakage current, SRSET 1 µA IL_ACSET IL_BATDEP Leakage current, ACSET 1 µA Leakage current, BATDEP 1 µA IL_VS Leakage current, VS 1 µA POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 5 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 electrical characteristics (TA = TOPR, 7.0 Vdc otherwise specified) (continued) VCC 20.0 Vdc, all voltages relative to Vss) (unless battery current-sense amplifier PARAMETER gm CMRR TEST CONDITIONS Transconductance gain MIN TYP MAX UNIT 90 150 210 mA/V Common-mode rejection ratio See Note 1 90 VICR Common-mode input (SRP) voltage range VCC = SRN + 2 V ISINK Sink current (COMP) COMP = 1 V, (SRP – SRN) = 10 mV Input bias current (SRP) VSRP = 16 V, SRSET = 0 V, VCC = 20 IIB Input bias current (SRN) VSRP = 16 V, SRSET = 0 V, VCC = 20 VSET Battery current programming voltage (SRSET) AV Battery current set gain 0.65 V ≤ SRSET ≤ 2.5 V, 8 V ≤ SRN ≤ 16 V, –40°C ≤ TA ≤ 85°C, See Note 2 Total battery current current-sense sense mid mid-scale scale accuracy SRSET = 1.25 V, TA = 25°C, See Note 3 SRSET = 1.25 V, –40°C ≤ TA ≤ 85°C, See Note 3 –5% 5% –6% 6% current-sense full-scale Total battery current sense full scale accuracy SRSET = 2.5 V, TA = 25°C, See Note 3 SRSET = 2.5 V, –40°C ≤ TA ≤ 85°C, See Note 3 –3% 3% –4% 4% 5 0.5 18.2 V 1.5 2.5 mA 6 10 200 300 0 24 dB 25 µA A 2.5 V 26 V/V NOTES: 1. Ensured by design. Not production tested. 1 2. I + SRSET BAT A R V SENSE 3. Total battery-current set is based on the measured value of (SRP–SRN) = ∆m, and the calculated value of (SRP–SRN) = ∆C, using (Dm * Dc) the measured gain, AV. DC + SRSET , Total accuracy in % + 100 Dc A V 6 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 electrical characteristics (TA = TOPR, 7.0 Vdc otherwise specified) (continued) VCC 20.0 Vdc, all voltages relative to Vss) (unless adapter current-sense amplifier PARAMETER gm CMRR TEST CONDITIONS Transconductance gain Common-mode rejection ratio ISINK Sink current (COMP) COMP = 1 V, Input bias current (ACP, ACN) ACP = ACN = 20 V, SRSET = 0 V, VCC = 20 V, ACSET = 1.25 V Input bias current accuracy ratio (ACP, ACN) ACP = ACN = 20 V, ACSET = 1.25 V AC current programming voltage (ACSET) AV AC current set gain MAX UNIT 90 150 210 mA/V 90 Common-mode input voltage range (ACP) VSET TYP See Note 1 VICR IIB MIN 7.0 (ACP – ACN) = 10 mV VCC = 20 V, dB VCC+0.2 0.5 1.5 2.5 mA 15 25 35 µA 0.95 1.00 1.05 0 2.5 V 26.5 V/V 0.65 V ≤ ACSET ≤ 2.5 V, 12 V ≤ ACP ≤ 20 V, –40°C ≤ TA ≤ 85°C, See Note 4 24.5 Total ac current current-sense sense mid mid-scale scale accuracy ACSET = 1.25 V, –5% 5% –6% 6% Total ac current current-sense sense full full-scale scale accuracy ACSET = 2.5 V, –3.5% 3.5% –4% 4% TA = 25°C, See Note 5 ACSET = 1.25 V, –40°C ≤ TA ≤ 85°C, See Note 5 ACSET = 2.5 V, TA = 25°C, See Note 5 –40°C ≤ TA ≤ 85°C, See Note 5 V 25.5 battery voltage error amplifier PARAMETER TEST CONDITIONS gm CMRR Transconductance gain VICR VIT BATSET common-mode input voltage range ISINK VFB Common-mode rejection ratio MIN TYP MAX UNIT 75 135 195 mA/V See Note 1 Internal reference override input threshold voltage Error-amplifier Error am lifier precision recision reference voltage dB 2.5 V 0.20 0.25 0.30 V 0.5 1.5 2.5 mA TA = 25°C 0°C ≤ TA ≤ 70°C 1.241 1.246 1.251 1.239 1.246 1.252 –40°C ≤ TA ≤ 85°C 1.234 1.246 1.254 COMP = 1 V, (BATP – BATSET) = 10 mV, BATSET = 1.25 V Sink current COMP 90 1 V NOTES: 1. Ensured by design. Not production tested. 1 2. I + SRSET BAT A R V SENSE 3. Total battery-current set is based on the measured value of (SRP–SRN) = ∆m, and the calculated value of (SRP–SRN) = ∆C, using (Dm * Dc) the measured gain, AV. Dc + SRSET , Total accuracy in % + 100 Dc A V 1 4. Calculation of the AC current: I + ACSET AC A R V SENSE 5. Total ac-current set accuracy is based on the measured value of (ACP–ACN) = ∆c, using the measured gain, AV. (Dm * Dc) Dc + ACSET , Total accuracy in % + 100 Dc A V POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 7 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 electrical characteristics (TA = TOPR, 7.0 Vdc otherwise specified) (continued) VCC 20.0 Vdc, all voltages relative to Vss) (unless battery current output amplifier PARAMETER TEST CONDITIONS MIN 5 GTR Transfer gain (SRP – SRN) = 50 mV, See Note 6 VIBAT Battery current readback output voltage (IBAT) (SRP – SRN) = 50 mV, SRP = 12 V, VCC = 18 V, TA = 25°C Line rejection voltage TA = 25°C 0.97 TYP 1.00 MAX UNIT 18.2 V 1.03 V 10 mV/V CM Common-mode input range (SRP) 5 18.2 V VO(IBAT) Battery current output voltage range (IBAT) 0 2.5 V IS(O) Output source current (IBAT) (SRP – SRN) = 100 mV 1200 µA –4% 4% Total batter battery ccurrent rrent readback mid mid-scale scale accuracy (SRP – SRN) = 50 mV, TA = 25°C, See Note 7 (SRP – SRN) = 50 mV, –40°C ≤ TA ≤ 85°C, See Note 7 –6% 6% (SRP – SRN) = 100 mV, TA = 25°C, See Note 7 (SRP – SRN) = 100 mV, –40°C ≤ TA ≤ 85°C, See Note 7 –6% 6% Total battery batter current c rrent readback full-scale f ll scale accuracy –8% 8% 150 600 5-V voltage reference PARAMETER VREF TEST CONDITIONS O tp t voltage Output oltage (VREF) MIN TYP MAX UNIT 0°C ≤ TA ≤ 70°C 5.000 5.030 5.060 V –40°C ≤ TA ≤ 85°C 4.960 5.030 5.070 V 0.15 0.37 mV/V 1.0 2.5 mV/mA 8 18 30 mA MIN TYP MAX UNIT 14.5 15.5 16.5 V –7.2% –6.5% –6% 0.45 0.50 0.55 Line regulation 1 mA ≤ ILOAD ≤ 5 mA Load regulation Short circuit current half supply regulator PARAMETER VHSP(on) TEST CONDITIONS VCC up-threshold for half supply regulation VCC hysteresis for half supply regulation VHSP/VCC VHSP Voltage regulation VCC ≥ VHSP(on), 16.5 V ≤ VCC ≤ 20 V VCC < VHSP(on), 7 V ≤ VCC ≤ 14.5 V 2.0 V V IBAT + TR (SRP * SRN) 7. Total battery current readback accuracy is based on the measured value of VIBAT, VIBATm, and the calculated value of VIBAT, VIBATc, using the measured value of the transfer gain, GTR. V *V IBATc 100 V + (SRP * SRN) GTR Total Accuracy in % + IBATm IBATc V IBATm NOTES: 6. Battery readback transfer gain G 8 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 electrical characteristics (TA = TOPR, 7.0 Vdc otherwise specified) (continued) VCC 20.0 Vdc, all voltages relative to Vss) (unless MOSFET gate drive PARAMETER TEST CONDITIONS TYP MAX UNIT VCC = 18 V VCC = 18 V 150 250 Ω 60 120 Ω VCC = 18 V VCC = 18 V 200 370 Ω Battery driver RDS(on) low 100 170 Ω Time delay from ac driver off to battery driver on ACSEL 2.4 V ⇓ 0.2 V 0.5 1.5 µs Time delay from battery driver off to ac driver on ACSEL 0.2 V ⇑ 2.4 V 1.0 2.0 µs high level output voltage PWM driver high-level IOUT = –10 mA, VCC = 18 V IOUT = –100 mA, VCC = 18 V AC driver RDS(on) high AC driver RDS(on) low Battery driver RDS(on) high tDa tDb VOH MIN –0.12 –0.07 –1.2 –0.7 7 14 Ω VHSP+0.04 VHSP+0.5 VHSP+0.1 VHSP+0.9 V 4 8 Ω PWM driver RDS(on) high VOL IOUT = 10 mA, VCC = 18 V IOUT = 100 mA, VCC = 18 V PWM dri driver er lo low-level le el o output tp t voltage oltage V PWM driver RDS(on) low selector PARAMETER TEST CONDITIONS VACPRES VIT(ACPRES) AC presence detect voltage See Note 9 td(ALMON) ACSEL high to alarm set high in ac fault time delay ACSEL 0.2 V ⇑ 2.4 V td(ALMOFF) ACSEL low to alarm reset low in ac fault time delay SRN = SRP = 8 V, ACSEL 2.4 V ⇓ 0.2 V VBATDEP VNOBAT Battery depletion ALARM trip voltage See Note 8 No battery detect, switch to ACDRV See Note 8 tBATSEL Battery select time (ACSEL low to BATDRV low) VS < BATP, ACSEL 2.4 V ⇓ 0.2 V tACSEL VVS AC select time (ACSEL high to ACDRV low) ACSEL 0.2 V ⇑ 2.4 V VS voltage to enable BATDRV BATP = 1 V AC presence hysteresis VIT(VS) VS voltage hysteresis VS > BATP NOTES: 8. Refer to Table 1 to determine the logic operation of the bq24700 and the bq24701. MIN TYP MAX UNIT 1.165 1.220 1.275 V 40 80 120 mV 5 10 µs 2 10 µs 1.165 1.220 1.275 V 0.87 0.98 1.07 V 0.2 3.0 µs 0.2 3.0 µs 0.96 1.02 V 30 110 mV 9. Maximum ac adapter voltage (VCC) and AC presence detect voltage are 18 V. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 9 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 Terminal Functions TERMINAL NAME NO. I/O DESCRIPTION ACDET 1 I AC or adapter power detection ACDRV 24 O AC or adapter power source selection output ACN 11 I Negative differential input ACP 12 I Positive differential input ACPRES 2 O AC power indicator ACSEL 3 I AC adapter power select ACSET 6 I Adapter current programming voltage ALARM 19 O Depleted battery alarm output BATDEP 4 I Depleted battery level BATDRV 23 O Battery power source select output BATP 13 I Battery charge regulation voltage measurement input to the battery-voltage gm amplifier BATSET 9 I External override to an internal 0.5% precision reference COMP 10 O Inverting input to the PWM comparator ENABLE 8 I Charge enable GND 17 O Supply return and ground reference IBAT 14 O Battery current differential amplifier output PWM 21 O Gate drive output SRN 15 I Negative differential battery current sense amplifier input SRP 16 I Positive differential battery current sense amplifier input SRSET 5 I Battery charge current programming voltage VCC 22 I Operational supply voltage VHSP 20 O Voltage source to drive gates of the external MOSFETs VREF 7 O Precision voltage 5-V, ±0.6% reference VS 18 I System (load) voltage input pin pin assignments ACDET: AC or adapter power detection. This input pin is used to determine the presence of the ac adapter. When the voltage level on the ACDET pin is less than 1.20 V, the bq24700/bq24701 is in sleep mode, the PWM control is disabled, the BATDRV is driven low and the ACDRV is driven high. This feature can be used to automatically select battery as the system’s power source. ACDRV: AC or adapter power source select output. This pin drives an external P-channel MOSFET used to switch to the ac wall-adapter as the system’s power source. When the ACSEL pin is high while the voltage on the ACDET pin is greater than 1.20 V, the output ACDRV pin is driven low (VHSP). This pin is driven high (VCC) when the ACDET is less than 1.20 V. ACN, ACP: Negative and positive differential inputs, respectively for ac-to-dc adapter current sense resistor. ACPRES: This open-drain output pin is used to indicate the presence of ac power. A logic high indicates there is a valid ac input. A low indicates the loss of ac power. ACPRES is high when the voltage level on the ACDET pin is greater than 1.20 V. ACSEL: AC adapter power select. This input selects either the ac adapter or the battery as the power source. A logic high selects ac power, while a logic low selects the battery. 10 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 pin assignments (continued) ACSET: Adapter current programming voltage. This input sets the system current level at which dynamic power management occurs. Adapter currents above this programmed level activate the dynamic power management and proportionally reduce the available power to the battery. ALARM: Depleted battery alarm output. This open-drain pin indicates that a depleted battery condition exists. A pullup on ALARM goes high when the voltage on the BATDEP pin is below 1.20 V. On the bq24700, the ALARM output also activates when the selector inputs do not match the selector state. BATDEP: Depleted battery level. A voltage divider network from the battery to BATDEP pin is used to set the battery voltage level at which depletion is indicated by the ALARM pin. See ALARM pin for more details. A battery depletion is detected when BATDEP is less than 1.2 V. A no-battery condition is detected when the battery voltage is < 80% of the depleted threshold. In a no-battery condition, the bq24700 automatically selects ac as the input source. If ENABLE = 1, the PWM remains enabled. BATDRV: Battery power source select output. This pin drives an external P-channel MOSFET used to switch the battery as the system’s power source. When the voltage level on the ACDET pin is less than 1.2 V, the output of the BATDRV pin is driven low, GND. This pin is driven high (VCC) when ACSEL is high and ACDET > 1.2 V. BATP: Battery charge regulation voltage measurement input to the battery-voltage gm amplifier. The voltage on this pin is typically derived from a voltage divider network connected across the battery. In a voltage loop, BATP is regulated to the 1.25 V, ±0.5% precision reference of the battery voltage gm amplifier. BATSET: An external override to an internal precision 0.5% reference. When BATSET is > 0.25 V, the voltage level on the BATSET pin sets the voltage charge level. When BATSET ≤ 0.25 V, an internal 1.25-V, ±0.5% reference is connected to the inverting input of the battery error amplifier. To ensure proper battery voltage regulation with BATSET, BATSET must be > 1.0 V. Simply ground BATSET to use the internal reference. COMP: The inverting input to the PWM comparator and output of the gm amplifiers. A type II compensation network between COMP and GND is recommended. ENABLE: Charge enable. A high on this input pin allows PWM control operation to enable charging while a low on this pin disables and forces the PWM output to a high state. Battery charging is initiated by asserting a logic 1 on the ENABLE pin. NOTE:The ENABLE pin should be asserted high only after ACDET has been asserted high and VREF has been established. When ac is lost, and the bq24700/bq24701 drives ACPRES low, the host must assert the ENABLE low. GND: Supply return and ground reference IBAT: Battery current differential amplifier output. The output of this pin produces a voltage proportional to the battery charge current. This voltage is suitable for driving an ADC input. PWM: Gate drive output pin drives the P-channel MOSFET for PWM control. The PWM control is active when ACPRES, ACSEL, and ENABLE are high. PWM is driven low to VHSP and high to VCC. SRN, SRP: Differential amplifier inputs for battery current sense. These pins feed back the battery charge current for PWM control. SRN is tied to the battery terminal. Care must be taken to keep SRN and SRP below their absolute maximum rating, especially when the battery is removed. Refer to the application section, under ACDET operation, for further detail outlining the various connection configurations which help keep SRN and SRP within safe operating regions. SRSET: Battery charge current programmed voltage. The level on this pin sets the battery charge current limit. VCC: Operational supply voltage. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 11 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 pin assignments (continued) VHSP: The VHSP pin is connected to a 10-µF capacitor (close to the pin) to provide a stable voltage source to drive the gates of the external MOSFETs. VHSP is equal to (0.5 × VCC) for VCC ≥ 15 V and 0 V for VCC < 15 V (refer to Figure 12). An 18-V Zener diode should be placed between VCC and VHSP for VCC > 20 V to prevent MOSFET overstress during start-up. VREF: Bypassed precision voltage 5-V, ±0.6% output. It can be used to set fixed levels on the inverting inputs of any one of the three error amplifiers if desired. The tight tolerance is suitable for charging lithium-ion batteries. A 3.3-µF (or higher) capacitor should be placed close to the pin. VS: System (Load) voltage input pin. The voltage on this pin indicates the system voltage in order to insure a break before make transition when changing from ac power to battery power. The battery is protected from an over-voltage condition by disabling the P-channel MOSFET connected to the BATDRV pin if the voltage at VS is greater than BATP. This function can be eliminated by grounding the VS pin. APPLICATION INFORMATION D1 R5 ADAPTER MBRD640CT 0.025 SUPPLY DPAK 1W 33 µH D05022p–333 Q2 IRFR5305 Q1 IRFR5305 100 Ω 220 µF 30 V bq24700PW 100 Ω 11 ACN 12 ACP 1 ACDET ACDRV R1 499 kΩ D1 MBRD640CT DPAK 24 1 µF VBAT R6 0.05 0.5 W 22 PWM 21 TO SYSTEM D4 17 V R7 523 kΩ 4.7 Ω VCC Q3 IRFR5305 12.6 V + C5, C6 22 µF x2 35 V D4 17 V R14 523 kΩ 4.7 µF 100 kΩ R10 20 Ω 8 ENABLE SRP 16 3 ACSEL SRN 15 19 ALARM BATP 13 5 SRSET BATDRV 23 6 ACSET VS 18 2 ACPRES VHSP 20 14 IBAT BATSET 9 7 VREF BATDEP 4 R9 57.6 kΩ R15 57.6 kΩ 10 Ω C3 10µ F B330 100 kΩ B330 J1 20 kΩ 5VREF C7 3.3 µF C8 150 pF 10 VCC 499 kΩ GND C9 4.7 µF D3 18 V 17 VBAT C4 10 µF 35 V 180 pF 76.8 kΩ COMP R13 100 Ω UDG–00138 CHARGE VOLTAGE SETPOINT Figure 1. Typical Notebook Charge Management Application 12 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 APPLICATION INFORMATION dynamic power management The dynamic power management (DPM) feature allows a cost effective choice of an ac wall-adapter that accommodates 90% of the system’s operating-current requirements. It minimizes battery charge time by allocating available power to charge the battery (i.e. IBAT = IADPT – ISYS). If the system plus battery charge current exceeds the adapter current limit, as shown in Figure 2, the DPM feature reduces the battery charge current to maintain an overall input current consumption within user defined power capability of the wall-adapter. As the system’s current requirements decrease, additional current can be directed to the battery, thereby increasing battery charge current and minimizing battery charge time. The DPM feature is inherently designed into the PWM controller by inclusion of the three control loops, battery-charge regulation voltage, battery-charge current, and adapter-charge current, refer to Figure 3. If any of the three user programmed limits are reached, the corresponding control loop commands the PWM controller to reduce duty cycle, thereby reducing the battery charge current. ADAPTER CURRENT LIMIT ADAPTER CURRENT SYSTEM CURRENT BATTERY CHARGE CURRENT NO CHARGE MAXIMUM CHARGE CURRENT DYNAMIC POWER MANAGEMENT MAXIMUM CHARGE CURRENT UDG–00113 Figure 2. Dynamic Power Management ACDET operation The ACDET function senses the loss of adequate adapter power. If the voltage on ACDET drops below the internal 1.2 V reference voltage, a loss of ADAPTER power is declared and the bq24700/bq24701 switches to battery power as the main system power. In addition, the bq24700/bq24701 shuts down its 5-V VREF and enters a low power sleep mode. Under normal operation with a battery present, the low impedance battery node absorbs excess energy stored in the system capacitors (from the higher VADPT voltage) and quickly bring the system voltage down to the battery voltage level. However, in conditions where the battery has been removed or appears high impedance due to battery protector operation, the residual system energy stored in the load capacitors due to the higher VADPT level is directly coupled to the SRN and SRP terminals when the battery switch-over occurs. This presents a problem for VADPT voltages greater than the absolute maximum voltage rating of the SRN and SRP pins. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 13 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 APPLICATION INFORMATION ACDET sense point The ACDET function senses adapter voltage via a resistor divider (refer to the Application Circuit). The location of the ACDET sense node depends on the maximum adapter voltage capability. For operation with VADPT < 18 V, the ACDET sense node can be at the anode of the input blocking diode. Since the VADPT voltage does not exceed the absolute maximum rating of the SRN pin, SRN stays within safe operating range. For operation with VADPT ≥ 18 V, the ACDET sense node should be at the cathode of the input blocking diode. Moving the ACDET sense point to the cathode of the input diode ensures that the bq24700/bq24701 remains active after adapter power is lost until the load capacitors have discharged to a safe level to protect the SRN and SRP pins. In either case, it is assumed that the ACDET level is set for VADPT < 17 V. alternative method Alternatively, the battery select MOSFET and its associated gate drive protection circuitry could be replaced with a Schottky. The Schottky allows the ACDET sense point to be moved to the anode side of the input diode, for VADPT ≥ 18 V, since it blocks the system voltage from the SRN and SRP pins. The bq24700/bq24701 would retain all functionality with fewer components at the expense of lower battery efficiency and a higher drop-out voltage. battery charger operation The bq24700/bq24701 fixed-frequency, PWM controller is designed to provide closed-loop control of battery charge-current (ICH) based on three parameters, battery-float voltage (VBAT), battery-charge current, and adapter charge current (IADPT). The bq24700/bq24701 is designed primarily for control of a buck converter using a high side P-channel MOSFET device (SW, refer to Figure 3). The three control parameters are voltage programmable through resistor dividers from the bq24700/bq24701 precision 5-V reference, an external or internal precision reference, or directly via a DAC interface from a keyboard controller. Adapter and battery-charge current information is sensed and fed back to two transconductance (gm ) amplifiers via low-value-sense resistors in series with the adapter and battery respectively. Battery voltage information is sensed through an external resistor divider and fed back from the battery to a third gm amplifier. NOTE:The ENABLE pin should be asserted high only after ACDET has been asserted high and VREF has been established. When ac is lost, and the bq24700/bq24701 drives ACPRES low, the host must assert the ENABLE low. 14 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 APPLICATION INFORMATION SW ISW + VADPT VBAT CLK OSC RAMP ENABLE S Q R Q LATCH OUT VCC LEVEL SHIFT 5V 100 µA PWM COMPARATOR PWM DRIVE 21 PWM VHSP FROM ENABLE LOGIC COMP 10 + 13 BATP ZCOMP ENABLE BATTERY VOLTAGE + 1.25 V BATTERY CHARGE CURRENT ADP CURRENT gm AMPLIFIERS UDG–00114 Figure 3. PWM Controller Block Diagram PWM operation The three open collector gm amplifiers are tied to the COMP pin (refer to Figure 3), which is internally biased up by a 100-µA constant current source. The voltage on the COMP pin is the control voltage (VC) for the PWM comparator. The PWM comparator compares VC to the sawtooth ramp of the internally fixed 300-kHz oscillator to provide duty cycle information for the PWM drive. The PWM drive is level-shifted to provide adequate gate voltage levels for the external P-channel MOSFET. Refer to PWM selector switch gate drive section for gate drive voltage levels. softstart Softstart is provided to ensure an orderly start-up when the PWM is enabled. When the PWM controller is disabled (ENABLE = Low), the 100-µA current source pullup is disabled and the COMP pin is actively pulled down to GND. Disabling the 100-µA pullup reduces current drain when the PWM is disabled. When the bq24700/bq24701 PWM is enabled (ENABLE = High), the COMP pin is released and the 100-µA pullup is enabled (refer to Figure 3). The voltage on the COMP pin increases as the pullup charges the external compensation network connected to the COMP pin. As the voltage on the COMP pin increases the PWM duty cycle increases linearly as shown in Figure 4. NOTE:The ENABLE pin should be asserted high only after ACDET has been asserted high and VREF has been established. When ac is lost, and the bq24700/bq24701 drives ACPRES low, the host must assert the ENABLE low. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 15 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 APPLICATION INFORMATION PERCENT DUTY CYCLE vs COMPENSATION VOLTAGE 100 90 Percent Duty Cycle – % 80 70 60 50 40 30 20 10 0 1.2 1.7 2.2 2.7 3.2 VCOMP – Compensation Voltage – V Figure 4 As any one of the three controlling loops approaches the programmed limit, the gm amplifier begins to shunt current away from the COMP pin. The rate of voltage rise on the COMP pin slows due to the decrease in total current out of the pin, decreasing the rate of duty cycle increase. When the loop has reached the programmed limit the gm amplifier shunts the entire bias current (100 µA) and the duty cycle remains fixed. If any of the control parameters tries to exceed the programmed limit, the gm amplifier shunts additional current from the COMP pin, further reducing the PWM duty cycle until the offending parameter is brought into check. 16 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 APPLICATION INFORMATION I CH (avg) I CH PWM V S V C CLK UDG–00115 Figure 5. Typical PWM Waveforms in a Buck Converter (Including Startup) setting the battery charge regulation voltage The battery charge regulation voltage is programmed through the BATSET pin, if the internal 1.25-V precision reference is not used. The BATSET input is a high-impedance input that is driven by either a keyboard controller DAC or via a resistor divider from a precision reference (see Figure 6). The battery voltage is fed back to the gm amplifier through a resistor divider network. The battery charge regulation voltage can be defined as: V BATTERY + (R1 ) R2) V R2 BATSET V (1) The overall accuracy of the battery charge regulation voltage is a function of the bypassed 5-V reference voltage tolerance as well as the tolerances on R1 and R2. The precision voltage reference has a 0.5% tolerance making it suitable for the tight battery voltage requirements of Li-ion batteries. Tolerance resistors of 0.1% are recommended for R1 and R2 as well as any resistors used to set BATSET. The bq24700/bq24701 provides the capability of using an internal precision voltage reference (1.25 Vdc) through the use of a multiplexing scheme, refer to Figure 6, on the BATSET pin. When BATSET voltage is less than 0.25 V, an internal 1.25-V, 0.5% reference is switched in and the BATSET pin is switched out from the gm amplifier input. When the BATSET voltage is greater than 0.25 V, the BATSET pin voltage is switched in to the input of the gm amplifier and the 1.25 V voltage reference is switched out. NOTE:The minumum recommended BATSET is 1.0 V, if BATSET is used to set the voltage loop. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 17 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 APPLICATION INFORMATION VBAT BATP COMP 13 gm AMPLIFIER 9 + BATSET 10 1.25 V 0.25 V 1.25 V VBAT (a) VBATSET < 0.25 V R1 VREF = 5 V COMP BATP 13 gm AMPLIFIER 9 + R2 1.25 V 10 BATSET 0.25 V 1.25 V (b) VBATSET > 0.25 V UDG–00116 Figure 6. Battery Error Amplifier Input Multiplexing Scheme programming the battery charge current The battery charge current is programmed via a voltage on the SRSET pin. This voltage can be derived from a resistor divider from the 5-V VREF or by means of an DAC. The voltage is converted to a current source that is used to develop a voltage drop across an internal offset resistor at one input of the SR gm amplifier. The charge current is then a function of this voltage drop and the sense resistor (RS), refer to Figure 7. 18 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 APPLICATION INFORMATION RS COMP 10 SRP 2 kΩ 16 + VREF SRN 15 SRSET 5 + 50 kΩ UDG–00117 Figure 7. Battery Charge Current Input Threshold Function The battery charge current can be defined as: I V + SRSET BAT 25 R S (2) where VSRSET is the programming voltage on the SRSET pin. VSRSET maximum is 2.5 V. programming the adapter current Like the battery charge current described previously, the adapter current is programmed via a voltage on the ACSET pin. That voltage can either be from an external resistor divider from the 5-V VREF or from an external DAC. The adapter current is defined as: I ADPT + V ACSET 25 R S2 (3) component selection MOSFET selection MOSFET selection depends on several factors, namely, gate-source voltage, input voltage and input current. The MOSFET must be a P-channel device capable of handling at least 20-V gate-to-source with a drain-source breakdown of VBV~ VIN+1V. The average input current can be approximated by: I (avg) ^ IN ǒVO I Ǔ O V IN 1.2 A (4) POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 19 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 APPLICATION INFORMATION The RMS current through the MOSFET is defined as: I (RMS) + I (avg) IN IN ǸD1 A RMS (5) Schottky rectifier (freewheeling) The freewheeling Schottky rectifier must also be selected to withstand the input voltage, VIN. The average current can be approximated from: I (avg) + I D1 O (1 * D) A (6) choosing an inductance Low inductance values result in a steep current ramp or slope. Steeper current slopes result in the converter operating in the discontinuous mode at a higher power level. Steeper current slopes also result in higher output ripple current, which may require a higher number, or more expensive capacitors to filter the higher ripple current. In addition, the higher ripple current results in an error in the sensed battery current particularly at lower charging currents. It is recommended that the ripple current not exceed 20% to 30% of full scale dc current. L+ ǒVIN * VBATǓ fs 0.2 I V BAT V IN FS (7) Too large an inductor value results in the current waveform of Q1 and D1 in Figure 8 approximating a squarewave with an almost flat current slope on the step. In this case, the inductor is usually much larger than necessary, which may result in an efficiency loss (higher DCR) and an area penalty. selecting an output capacitor For this application the output capacitor is used primarily to shunt the output ripple current away from the battery. The output capacitor should be sized to handle the full output ripple current as defined as: I c (RMS) + ǒVIN * VBATǓ fs L D Ǹ12 (8) selecting an input capacitor The input capacitor is used to shunt the converter ripple current on the input lines. The capacitor(s) must have a ripple curent (RMS) rating of: I 20 RMS +I V IN(avg) IN V O Ǹ ǒ V Ǔ V IN 1 * IN V V O O A POST OFFICE BOX 655303 RMS (9) • DALLAS, TEXAS 75265 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 APPLICATION INFORMATION compensating the loop For the bq24700/bq24701 used as a buck converter, the best method of compensation is to use a Type II compensation network from the output of the transconductance amplifiers (COMP pin) to ground (GND) as shown in Figure 8. A Type II compensation adds a pole-zero pair and an addition pole at dc. 100 µA COMP gm AMPLIFIER + 10 RCOMP CP CZ + gm AMPLIFIER + gm AMPLIFIER bq24700 UDG–00118 Figure 8. Type II Compensation Network The Type II compensation network places a zero at F +1 Z 2 p R p R COMP C Z Hz (10) and a pole at F +1 P 2 COMP C P Hz (11) For this battery charger application the following component values: CZ = 4.7 µF, CP = 150 pF, and RCOMP = 100Ω, provides a closed loop response with more than sufficient phase margin. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 21 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 APPLICATION INFORMATION selector operation The bq24700/bq24701 allows the host controller to manually select the battery as the system’s main power source, without having to remove adapter power. This allows battery conditioning through smart battery learn cycles. In addition, the bq24700/bq24701 supports autonomous supply selection during fault conditions on either supply. The selector function uses low RDS(on) P-channel MOSFETs for reduced voltage drops and longer battery run times. Note: Selection of battery power whether manual or automatic results in the suspension of battery charging. ADAPTER SELECT SWITCH ADAPTER INPUT SYSTEM LOAD (bq24700) PWM BATTERY CHARGER BAT ACDRV (bq24700) 24 BATTERY SELECTOR BATDRV CONTROL 23 BATTERY SELECT SWITCH UDG–00119 Figure 9. Selector Control Switches autonomous selection operation Adapter voltage information is sensed at the ACDET pin via a resistor divider from the adapter input (refer to ACDET operation section). The voltage on the ACDET pin is compared to an internally fixed threshold. An ACDET voltage less than the set threshold is considered as a loss of adapter power regardless of the actual voltage at the adapter input. Information concerning the status of adapter power is fed back to the host controller through ACPRES. The presence of adapter power is indicated by ACPRES being set high. A loss of adapter power is indicated by ACPRES going low regardless of which power source is powering the system. During a loss of adapter power, the bq24700/bq24701 obtains operating power from the battery through the body diode of the P-channel battery select MOSFET. Under a loss of adapter power, ACPRES (normally high) goes low, if adapter power is selected to power the system, the bq24700/bq24701 automatically switches over to battery power by commanding ACDRV high and BATDRV low and ALARM goes high. During the switch transition period, battery power is supplied to the load via the body diode of the battery select P-channel MOSFET. When adapter power is restored, the bq24700/bq24701 configures the selector switches according to the state of signals; ACSEL, and ACPRES. If the ACSEL pin is left high when ac power is restored, the bq24700/bq24701 automatically switches back to ac power and the ALARM pin goes low. To remain on battery power after ac power is restored, the ACSEL pin must be brought low. Conversely, if the battery is removed while the system is running on battery power and adapter power is present, the bq24700/bq24701 automatically switches over to adapter power by commanding BATDRV high and ACDRV low. Note: For the bq24700 any fault condition that results in the selector MOSFET switches not matching their programmed states is indicated by the ALARM pin going high. Please refer to Battery Depletion Detection Section for more information on the ALARM discrete. 22 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 APPLICATION INFORMATION smart learn cycles when adapter power is present Smart learn cycles can be conducted when adapter power is present by asserting and maintaining the ACSEL pin low. The adapter power can be reselected at the end of the learn cycle by a setting ACSEL to a logic high, provided that adapter power is present. Battery charging is suspended while selected as the system power source. When selecting the battery as the system primary power source, the adapter power select MOSFET turns off, in a break-before-make fashion, before the battery select MOSFET turns on. To ensure that this happens under all load conditions, the system voltage (load voltage) can be monitored through a resistor divider on the VS pin. This function provides protection against switching over to battery power if the adapter selector switch were shorted and adapter power present. This function can be eliminated by grounding the VS pin. During the transition period from battery to adapter or adapter to battery, power is supplied to the system through the body diode of the battery select switch. battery depletion detection The bq24700/bq24701 provides the host controller with a battery depletion discrete, the ALARM pin, to alert the host when a depleted battery condition occurs. The battery depletion level is set by the voltage applied to the BATDEP pin through a voltage divider network. The ALARM output asserts high and remains high as long as the battery deplete condition exists regardless of the power source selected. For the bq24700, the host controller must take appropriate action during a battery deplete condition to select the proper power source. The bq24700 remains on the selected power source. The bq24700, however, automatically reverts over to adapter power, provided the adapter is present, during a deep discharge state. The battery is considered as being in a deep discharge state when the battery voltage is less than (0.8 × depleted level). The bq24701 automatically switches back to adapter power if a battery deplete condition exists, provided that the adapter is present. Feature sets for the bq24700 and bq24701 are detailed in Table 1. Table 1. Available Options Condition –40 C TA 85 C Selector Operation bq24700PW bq24701PW Battery as Power Source Battery removal Automatically selects ac Automatically selects ac Battery reinserted Selection based on selector inputs Battery is selected when ac is removed AC removal Automatically selects battery Automatically selects battery AC reinserted Selection based on selector inputs Selection based on selector inputs Battery as power source Sends ALARM signal Automatically selects ac Sends ALARM signal AC as power source Sends ALARM signal Sends ALARM signal Depleted battery condition Depleted battery condition ac as Power Source Depleted Battery Condition ALARM Signal Active Selector inputs do not match selector outputs POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 23 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 APPLICATION INFORMATION selector/ALARM timing example The selector and ALARM timing example in Figure 10 illustrates the battery conditioning support. NOTE:For manual selection of wall power as the main power source, both the ACPRES and ACSEL signals must be a logic high. ACPRES ACSEL ACDRV BATDRV ALARM BATTERY DEPLETE CONDITION bq24701 ONLY UDG–00122 ACSEL (ACPRES) tBATSEL ACDRV tACSEL BATDRV BATDEP< 1 V t ACSEL BATDRV tBATSEL ACDRV UDG–00120 Figure 10. Battery Selector and ALARM Timing Diagram 24 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 APPLICATION INFORMATION PWM selector switch gate drive Because the external P-channel MOSFETs (as well as the internal MOSFETs) have a maximum gate-source voltage limitation of 20 V, the input voltage, VCC, cannot be used directly to drive the MOSFET gate under all input conditions. To provide safe MOSFET-gate-drive at input voltages of less than 20 V, an intermediate gate drive voltage rail was established (VSHP). As shown in Figure 11, VSHP has a stepped profile. For VCC voltages of less than 15 V, VSHP = 0 and the full VCC voltage is used to drive the MOSFET gate. At input voltages of greater than 15 V, VSHP steps to approximately one-half the VCC voltage. This ensures adequate enhancement voltage across all operating conditions. The gate drive voltage, Vgs, vs VCC for the PWM, and ac selector P-channel MOSFETs are shown in Figure 11. MOSFET GATE DRIVE VOLTAGE vs INPUT VOLTAGE Vgs – Gate Drive – V 15 10 7.5 PWM ACDRV 4 ACDRV and PWM 0 0 4 7 10 15 20 VCC – Input Voltage – V 25 30 Figure 11 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 25 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 TYPICAL CHARACTERISTICS ERROR AMPLIFIER REFERENCE vs JUNCTION TEMPERATURE BYPASSED 5-V REFERENCE vs JUNCTION TEMPERATURE 5.06 5.05 1.248 VREF – 5-V Reference –V REF2 – Error Amplifier Reference –V 1.250 1.246 1.244 5.04 5.03 5.02 5.01 1.242 5.00 1.240 –40 –20 0 20 40 60 80 TJ – Junction Temperature – _C 4.99 –40 100 –20 Figure 12 0 20 40 60 80 TJ – Junction Temperature – C 100 Figure 13 TOTAL SLEEP CURRENT vs JUNCTION TEMPERATURE OSCILLATOR FREQUENCY vs JUNCTION TEMPERATURE 25 300 295 20 f – Oscillator Frequency –kHz ISLEEP – Battery Sleep Current –µA VBATTERY = 18 V 15 10 290 285 280 275 5 270 0 –40 –20 0 20 40 60 TJ – Junction Temperature – C 80 100 265 –40 –20 Figure 14 26 0 20 40 60 80 TJ – Junction Temperature – C Figure 15 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 100 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 TYPICAL CHARACTERISTICS BATTERY CURRENT SET ACCURACY vs BATTERY CURRENT SET VOLTAGE AC CURRENT SET ACCURACY vs AC CURRENT SET VOLTAGE 20 25 SRSET Full Scale = 2.5 V = Max Programmed Current TJ = 25°C AC Current Set Accuracy –% Battery Current Set Accuracy –% 25 15 10 5 0 ACSET Full Scale = 2.5 V = Max Programmed Current TJ = 25°C 20 15 10 5 0 0.25 0.50 0.75 1.00 1.25 1.50 1.75 2.00 2.25 2.50 0.25 0.50 0.75 1.00 1.25 1.50 1.75 2.00 2.25 2.50 VACSET – AC Current Set Voltage – V VSRSET – Battery Current Set Voltage – V Figure 16 Figure 17 BATTERY IBAT READBACK vs (SRP–SRN) VOLTAGE HALF SUPPLY REGULATOR VOLTAGE vs INPUT VOLTAGE 15.0 TJ = 25°C 12.5 20 VHSP – Half Supply –V IBAT – Current Readback –% 25 15 10 5 10.0 7.5 5.0 2.5 0 25 50 75 100 (SRP–SRN) – Battery Current Sense Voltage – mV 0 6 Figure 18 10 14 18 22 VCC – Input Voltage – V 26 30 Figure 19 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 27 SLUS452B – APRIL 2001 – REVISED NOVEMBER 2002 PARAMETER MEASUREMENT INFORMATION VCC = 12 V CL = 1 nF TJ = 25_C VCC = 20 V CL = 1 nF TJ = 25_C Figure 20. PWMB Rise and Fall Times Figure 21. PWMB Rise and Fall Times BATDRV BATDRV VCC = 12 V TJ = 25_C ACDRV VCC = 20 V TJ = 25_C ACDRV ACSEL ACSEL Figure 22. Power Source Select Output Break Before Make 28 POST OFFICE BOX 655303 Figure 23. Power Source Select Output Break Before Make • DALLAS, TEXAS 75265 PACKAGE OPTION ADDENDUM www.ti.com 27-May-2005 PACKAGING INFORMATION Orderable Device Status (1) Package Type Package Drawing Pins Package Eco Plan (2) Qty BQ24700PW NRND TSSOP PW 24 BQ24700PWR NRND TSSOP PW 24 BQ24701PW NRND TSSOP PW 24 BQ24701PWR NRND TSSOP PW 24 70 Lead/Ball Finish MSL Peak Temp (3) Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR 2000 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR 2000 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR 60 (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) Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS) or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability information and additional product content details. TBD: The Pb-Free/Green conversion plan has not been defined. Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes. Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material) (3) MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature. Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals. TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release. In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis. Addendum-Page 1 MECHANICAL DATA MTSS001C – JANUARY 1995 – REVISED FEBRUARY 1999 PW (R-PDSO-G**) PLASTIC SMALL-OUTLINE PACKAGE 14 PINS SHOWN 0,30 0,19 0,65 14 0,10 M 8 0,15 NOM 4,50 4,30 6,60 6,20 Gage Plane 0,25 1 7 0°– 8° A 0,75 0,50 Seating Plane 0,15 0,05 1,20 MAX PINS ** 0,10 8 14 16 20 24 28 A MAX 3,10 5,10 5,10 6,60 7,90 9,80 A MIN 2,90 4,90 4,90 6,40 7,70 9,60 DIM 4040064/F 01/97 NOTES: A. B. C. D. All linear dimensions are in millimeters. This drawing is subject to change without notice. Body dimensions do not include mold flash or protrusion not to exceed 0,15. Falls within JEDEC MO-153 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 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. 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