LTC4007EGN

LTC4007 4A, High Efficiency, Standalone Li-Ion Battery Charger FEATURES ■ ■ ■ ■ ■ ■ ■ ■ ■ ■ ■ DESCRIPTIO ■ ■ Complete Charger Controller for 3- or 4-Cell Lithium-Ion Batteries High Conversion Efficiency: Up to 96% Output Currents Exceeding 4A ± 0.8% Charging Voltage Accuracy Built-In Charge Termination for Li-Ion Batteries AC Adapter Current Limiting Maximizes Charge Rate* Thermistor Input for Temperature Qualified Charging Wide Input Voltage Range: 6V to 28V 0.5V Dropout Voltage; Maximum Duty Cycle: 98% Programmable Charge Current: ± 4% Accuracy Indicator Outputs for Charging, C/10 Current Detection, AC Adapter Present, Low Battery, Input Current Limiting and Faults Charging Current Monitor Output Available in a 24-Pin Narrow SSOP Package The LTC®4007 is a complete constant-current/constantvoltage charger controller for 3- or 4-cell lithium-ion batteries. The PWM controller uses a synchronous, quasiconstant frequency, constant off-time architecture that will not generate audible noise even when using ceramic capacitors. Charging current is programmable to ± 5% accuracy using a programming resistor. Charging current can also be monitored as a voltage across the programming resistor. The output float voltage is pin programmed for cell count (3 cells or 4 cells) and chemistry (4.2V/4.1V). A timer, programmed by an external resistor, sets the total charge time. Charging is automatically restarted when cell voltage falls below 3.9V/cell. LTC4007 includes a thermistor input, which suspends charging if an unsafe temperature condition is detected. If the cell voltage is less than 2.5V, a low-battery indicator asserts and can be used to program a trickle charge current to safely charge depleted batteries. The FAULT pin is also asserted and charging terminates if the low-battery condition persists for more than 1/4 of the total charge time. , LT, LTC and LTM are registered trademarks of Linear Technology Corporation. All other trademarks are the property of their respective owners. Protected by U.S. Patents, including 5723970. APPLICATIO S ■ ■ ■ ■ Notebook Computers Portable Instruments Battery-Backup Systems Standalone Li-Ion Chargers TYPICAL APPLICATIO DCIN 0V TO 28V 12.6V, 4A Li-Ion Battery Charger INPUT SWITCH 0.1µF 4.99k VLOGIC 100k LOBAT ICL ACP SHDN FAULT CHG FLAG 32.4k 100k 100k 3C4C CHEM LOBAT ICL ACP SHDN FAULT CHG FLAG NTC THERMISTOR 10k NTC RT 0.47µF 309k TIMING RESISTOR (~2 HOURS) DCIN INFET CLP 20µF Q1 Q2 10µH 0.025Ω 20µF Li-Ion BATTERY 15nF 0.025Ω SYSTEM LOAD LTC4007 CLN TGATE BGATE PGND CSP BAT PROG ITH GND 6.04k 0.12µF 0.0047µF 26.7k 3.01k 3.01k Q1: Si4431DY Q2: FDC6459 4007 TA01 U CHARGING CURRENT MONITOR U U 4007fa 1 LTC4007 ABSOLUTE MAXIMUM RATINGS (Note 1) PACKAGE/ORDER INFORMATION TOP VIEW DCIN CHG ACP RT FAULT GND 3C4C LOBAT NTC 1 2 3 4 5 6 7 8 9 24 SHDN 23 INFET 22 BGATE 21 PGND 20 TGATE 19 CLN 18 CLP 17 FLAG 16 CHEM 15 BAT 14 CSP 13 ICL Voltage from DCIN, CLP, CLN to GND ....... + 32V/– 0.3V PGND with Respect to GND ................................. ±0.3V CSP, BAT to GND ....................................... +28V/– 0.3V CHEM, 3C4C, RT to GND .............................. +7V/– 0.3V NTC ............................................................ +10V/– 0.3V ACP, SHDN, CHG, FLAG, FAULT, LOBAT, ICL .............................................. + 32V/– 0.3V CLP to CLN ........................................................... ±0.5V Operating Ambient Temperature Range (Note 4) ............................................. – 40°C to 85°C Operating Junction Temperature ......... – 40°C to 125°C Storage Temperature Range ................. – 65°C to 150°C Lead Temperature (Soldering, 10 sec).................. 300°C ITH 10 PROG 11 NC 12 GN PACKAGE 24-LEAD PLASTIC SSOP TJMAX = 125°C, θJA = 90°C/W ORDER PART NUMBER LTC4007EGN Order Options Tape and Reel: Add #TR Lead Free: Add #PBF Lead Free Tape and Reel: Add #TRPBF Lead Free Part Marking: http://www.linear.com/leadfree/ Consult LTC Marketing for parts specified with wider operating temperature ranges. ELECTRICAL CHARACTERISTICS SYMBOL IQ VTOL ITOL PARAMETER DCIN Operating Range Operating Current Charge Voltage Accuracy Charge Current Accuracy (Note 3) The ● denotes specifications which apply over the full operating temperature range (Note 4), otherwise specifications are at TA = 25°C. VDCIN = 20V, VBAT = 12V unless otherwise noted. CONDITIONS Sum of Current from CLP, CLN , DCIN Nominal Values: 12.3V, 12.6V, 16.4V, 16.8V (Note 2) ● VCSP – VBAT Target = 100mV VBAT < 6V, VCSP – VBAT Target = 10mV 6V ≤ VBAT ≤ VLOBAT, VCSP – VBAT Target = 10mV TTOL Shutdown Battery Leakage Current UVLO Undervoltage Lockout Threshold Shutdown Threshold at SHDN SHDN Pin Current Operating Current in Shutdown Current Sense Amplifier, CA1 Input Bias Current Into BAT Pin CMSL CMSH CA1/I1 Input Common Mode Low CA1/I1 Input Common Mode High ● ● ● MIN 6 TYP 3 MAX 28 5 0.8 1.0 4 5 60 35 15 UNITS V mA % % % % % % % µA µA V V µA mA –0.8 –1.0 –4 –5 –60 –35 –15 15 –10 4.2 1 4.7 1.6 – 10 2 Termination Timer Accuracy RRT = 270k DCIN = 0V SHDN = 3V DCIN Rising, VBAT = 0 ● ● ● ● ● 35 10 5.5 2.5 3 VSHDN = 0V, Sum of Current from CLP, CLN, DCIN 11.67 0 VCLN – 0.2 2 U W U U WW W µA V V 4007fa LTC4007 ELECTRICAL CHARACTERISTICS SYMBOL ITMAX ITREV PARAMETER Maximum Current Sense Threshold (VCSP – VBAT) Reverse Current Threshold (VCSP – VBAT) Transconductance Source Current Sink Current Current Limit Amplifier Transconductance VCLP ICLP Current Limit Threshold CLP Input Bias Current Transconductance Sink Current OVSD Overvoltage Shutdown Threshold as a Percent of Programmed Charger Voltage DCIN Detection Threshold (VDCIN – VCLN) Forward Regulation Voltage (VDCIN – VCLN) Reverse Voltage Turn-Off Voltage (VDCIN – VCLN) INFET “On” Clamping Voltage (VDCIN – VINFET) INFET “Off” Clamping Voltage (VDCIN – VINFET) Thermistor NTCVR Reference Voltage During Sample Time High Threshold Low Threshold Thermistor Disable Current Indicator Outputs (ACP, CHG, FLAG, LOBAT, ICL, FAULT C10TOL LBTOL FLAG (C/10) Accuracy LOBAT Threshold Accuracy Current Comparators ICMP and IREV The ● denotes specifications which apply over the full operating temperature range (Note 4), otherwise specifications are at TA = 25°C. VDCIN = 20V, VBAT = 12V unless otherwise noted. CONDITIONS VITH = 2.5V ● MIN 140 TYP 165 –30 1 MAX 200 UNITS mV mV mmho µA µA mmho Current Sense Amplifier, CA2 Measured at ITH, VITH = 1.4V Measured at ITH, VITH = 1.4V – 40 40 1.4 ● 93 100 100 1 107 mV nA mmho µA Voltage Error Amplifier, EA Measured at ITH, VITH = 1.4V ● 36 102 107 110 % Input P-Channel FET Driver (INFET) DCIN Voltage Ramping Up from VCLN – 0.1V DCIN Voltage Ramping Down IINFET = 1µA IINFET = – 25µA 4.5 VNTC Rising VNTC Falling VNTC ≤ 10V Voltage Falling at PROG 3C4C = 0V, CHEM = 0V 3C4C = 0V, CHEM = Open 3C4C = Open, CHEM = 0V 3C4C = Open, CHEM = Open 3C4C = 0V, CHEM = 0V 3C4C = 0V, CHEM = Open 3C4C = Open, CHEM = 0V 3C4C = Open, CHEM = Open ● ● ● ● ● ● ● ● ● ● ● ● ● ● ● 0 0.17 25 0.25 50 6.5 0.25 V mV mV V V V – 60 5 – 25 5.8 NTCVR • 0.48 NTCVR • 0.115 NTCVR • 0.5 NTCVR • 0.125 NTCVR • 0.52 NTCVR • 0.135 10 V V µA V V V V V V V V V mV 0.375 7.10 7.27 9.46 9.70 11.13 11.40 14.84 15.20 83 0.397 7.32 7.50 9.76 10 11.42 11.70 15.23 15.60 93 0.420 7.52 7.71 10.10 10.28 11.65 11.94 15.54 15.92 1O5 RESTART Threshold Accuracy ICL Threshold Accuracy 4007fa 3 LTC4007 ELECTRICAL CHARACTERISTICS SYMBOL VOL VOH IOFF IPO PARAMETER Low Logic Level of ACP, CHG, FLAG, LOBAT, ICL, FAULT High Logic Level of CHG, LOBAT, ICL Off State Leakage Current of ACP, FLAG, FAULT Pull-Up Current on CHG, LOBAT, ICL Timer Defeat Threshold at CHG Programming Inputs (CHEM and 3C4C) VIH VIL IPI Oscillator fOSC fMIN DCMAX Regulator Switching Frequency Regulator Switching Frequency in Drop Out Regulator Maximum Duty Cycle VTGATE High (VCLN – VTGATE) VBGATE High VTGATE Low (VCLN – VTGATE) VBGATE Low TGTR TGTF BGTR BGTF TGATE Transition Time TGATE Rise Time TGATE Fall Time BGATE Transition Time BGATE Rise Time BGATE Fall Time VTGATE at Shutdown (VCLN – VTGATE) VBGATE at Shutdown High Logic Level Low Logic Level Pull-Up Current The ● denotes specifications which apply over the full operating temperature range (Note 4), otherwise specifications are at TA = 25°C. VDCIN = 20V, VBAT = 12V unless otherwise noted. CONDITIONS IOL = 100µA IOH = –1µA VOH = 3V V = 0V 1 ● ● ● ● MIN TYP MAX 0.5 UNITS V V 2.7 –1 –10 1 µA µA V 3.3 1 – 14 255 300 25 99 50 4.5 4.5 5.6 5.6 10 10 50 50 50 40 40 110 100 90 80 100 100 345 V V µA kHz kHz % mV V V mV ns ns ns ns mV mV V = 0V Duty Cycle ≥ 98% VCSP = VBAT ITGATE = – 1mA CLOAD = 3000pF CLOAD = 3000pF IBGATE = 1mA CLOAD = 3000pF, 10% to 90% CLOAD = 3000pF, 10% to 90% CLOAD = 3000pF, 10% to 90% CLOAD = 3000pF, 10% to 90% ITGATE = –1µA, DCIN = 0V, CLN = 12V IBGATE = 1µA, DCIN = 0V, CLN = 12V 20 98 Gate Drivers (TGATE, BGATE) Note 1: Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. Exposure to any Absolute Maximum Rating condition for extended periods may affect device reliability and lifetime. Note 2: See Test Circuit. Note 3: Does not include tolerance of current sense resistor or current programming resistor. Note 4: The LTC4007E is guaranteed to meet performance specifications from 0°C to 70°C. Specifications over the –40°C to 85°C operating temperature range are assured by design, characterization and correlation with statistical process controls. 4007fa 4 LTC4007 TYPICAL PERFOR A CE CHARACTERISTICS INFET Response Time to Reverse Current 0.10 Vgs OF PFET (2V/DIV) Vgs = 0 0.05 OUTPUT VOLTAGE ERROR (%) 0 –0.05 VOUT ERROR (%) –0.10 –0.15 –0.20 –0.25 –0.30 Id (REVERSE) OF PFET (5A/DIV) Id = 0A 1.25µs/DIV TEST PERFORMED ON DEMOBOARD VCHARGE = 12.6V VIN = 15VDC CHARGER = ON PFET = 1/2 Si4925DY ICHARGE = BAT >BAT >BAT SHDN LOW LOW LOW LOW LOW ACP** LOW HIGH HIGH HIGH HIGH LOBAT LOW LOW HIGH HIGH X FLAG** FAULT** HIGH HIGH* HIGH HIGH* X HIGH HIGH* HIGH* HIGH* LOW (from NTC) HIGH LOW HIGH ICL LOW HIGH* HIGH* LOW HIGH TIMER STATE Reset Running Running Running Paused CHG** HIGH LOW LOW LOW LOW Shut down by SHDN pin Terminated by low-battery fault (Note 1) Timer is reset when FLAG goes low, then terminates after 1/4 T Terminated by expired timer Timer defeated Shut down by undervoltage lockout *Most probable condition X = Don’t care, ** Open-drain output HIGH = OPEN with pull-up Note 1: If a depleted battery is inserted while the charger is in this state, the charger must be reset to initiate charging. a low forward voltage drop from drain to source. If the voltage between DCIN and CLN drops to less than 25mV, the input FET is turned off slowly. If the voltage between DCIN and CLN is ever less than – 25mV, then the input FET is turned off in less than 10µs to prevent significant reverse current from flowing in the input FET. In this condition, the ACP pin is driven low and the charger is disabled. Battery Charger Controller The LTC4007 charger controller uses a constant off-time, current mode step-down architecture. During normal operation, the top MOSFET is turned on each cycle when the oscillator sets the SR latch and turned off when the main current comparator ICMP resets the SR latch. While the top MOSFET is off, the bottom MOSFET is turned on until either the inductor current trips the current comparator 10 U X >BAT >BAT HIGH LOW LOW X HIGH HIGH X LOW HIGH HIGH HIGH* LOW LOW LOW LOW Reset >T/4 >T/4 after FLAG = LOW >T HIGH HIGH (Faulted) HIGH (Waiting for Restart) HIGH (Waiting for Restart Forced LOW HIGH* >BAT LOW HIGH HIGH HIGH HIGH LOW X >BAT + 7% of programmed value). In this case, both MOSFETs are turned off until the overvoltage condition is cleared. This feature is useful for batteries which “load dump” themselves by opening their protection switch to perform functions such as calibration or pulse mode charging. PWM Watchdog Timer There is a watchdog timer that observes the activity on the BGATE and TGATE pins. If TGATE stops switching for more than 40µs, the watchdog activates and turns off the top MOSFET for about 400ns. The watchdog engages to prevent very low frequency operation in dropout—a potential source of audible noise when using ceramic input and output capacitors. Charger Start-Up When the charger is enabled, it will not begin switching until the ITH voltage exceeds a threshold that assures initial current will be positive. This threshold is 5% to 15% of the maximum programmed current. After the charger begins switching, the various loops will control the current at a level that is higher or lower than the initial current. The duration of this transient condition depends upon the loop compensation, but is typically less than 100µs. Thermistor Detection The thermistor detection circuit is shown in Figure 3. It requires an external resistor and capacitor in order to function properly. The thermistor detector performs a sample-and-hold function. An internal clock, whose frequency is determined by 4007fa 1.19V 100 4007 F02 11 LTC4007 OPERATIO the timing resistor connected to RT, keeps switch S1 closed to sample the thermistor: tSAMPLE = 127.5 • 20 • RRT • 17.5pF = 13.8ms, for RRT = 309k The external RC network is driven to approximately 4.5V and settles to a final value across the thermistor of: VRTH(FINAL) = 4.5V • RTH RTH + R9 This voltage is stored by C7. Then the switch is opened for a short period of time to read the voltage across the thermistor. LTC4007 12 U tHOLD = 10 • RRT • 17.5pF = 54µs, for RRT = 309k When the tHOLD interval ends the result of the thermistor testing is stored in the D flip-flop (DFF). If the voltage at NTC is within the limits provided by the resistor divider feeding the comparators, then the NOR gate output will be low and the DFF will set TBAD to zero and charging will continue. If the voltage at NTC is outside of the resistor divider limits, then the DFF will set TBAD to one, the charger will be shut down, FAULT pin is set low and the timer will be suspended until TBAD returns to zero (see Figure 4). CLK R9 32.4k 9 RTH 10k NTC C7 0.47µF – NTC S1 + ~4.5V 60k + – – + 15k D C 4007 F03 45k Q TBAD Figure 3 CLK (NOT TO SCALE) tHOLD tSAMPLE VOLTAGE ACROSS THERMISTOR VNTC COMPARATOR HIGH LIMIT COMPARATOR LOW LIMIT 4007 F04 Figure 4 4007fa LTC4007 APPLICATIO S I FOR ATIO Battery Detection It is generally not good practice to connect a battery while the charger is running. The timer is in an unknown state and the charger could provide a large surge current into the battery for a brief time. The Figure 5 circuit keeps the charger shut down and the timer reset while a battery is not connected. ADAPTER POWER LTC4007 1 DCIN SWITCH CLOSED WHEN BATTERY CONNECTED 24 SHDN 4007 F05 Figure 5 Charger Current Programming The basic formula for charging current is: ICHARGE(MAX) = VREF = 1.19V VREF • 3.01kΩ / RPROG – 0.035V RSENSE This leaves two degrees of freedom: RSENSE and RPROG. The 3.01k input resistors must not be altered since internal currents and voltages are trimmed for this value. Pick RSENSE by setting the average voltage between CSP and BAT to be close to 100mV during maximum charger current. Then RPROG can be determined by solving the above equation for RPROG. RPROG = VREF • 3.01kΩ RSENSE • ICHARGE(MAX) + 0.035V RSENSE (Ω) 1% 0.100 0.050 0.033 0.025 RSENSE (W) 0.25 0.25 0.5 0.5 RPROG (kΩ) 1% 26.7 26.7 26.7 26.7 Table 2. Recommended RSNS and RPROG Resistor Values IMAX (A) 1.0 2.0 3.0 4.0 U LTC4007 PROG 11 RZ 102k RPROG 5V 0V Q1 2N7002 4007 F06 W UU CPROG Figure 6. PWM Current Programming Charging current can be programmed by pulse width modulating RPROG with a switch Q1 to RPROG at a frequency higher than a few kHz (Figure 6). CPROG must be increased to reduce the ripple caused by the RPROG switching. The compensation capacitor at ITH will probably need to be increased also to improve stability and prevent large overshoot currents during start-up conditions. Charging current will be proportional to the duty cycle of the switch with full current at 100% duty cycle and zero current when Q1 is off. Maintaining C/10 Accuracy The C/10 comparator threshold that drives the FLAG pin has a fixed threshold of approximately VPROG = 400mV. This threshold works well when RPROG is 26.7k, but will not yield a 10% charging current indication if RPROG is a different value. There are situations where a standard value of RSENSE will not allow the desired value of charging current when using the preferred RPROG value. In these cases, where the full-scale voltage across RSENSE is within ±20mV of the 100mV full-scale target, the input resistors connected to CSP and BAT can be adjusted to provide the desired maximum programming current as well as the correct FLAG trip point. For example, the desired max charging current is 2.5A but the best RSENSE value is 0.033Ω. In this case, the voltage across RSENSE at maximum charging current is only 82.5mV, normally RPROG would be 30.1k but the nominal FLAG trip point is only 5% of maximum charging current. If the input resistors are reduced by the same amount as 4007fa 13 LTC4007 APPLICATIO S I FOR ATIO the full-scale voltage is reduced then, R4 = R5 = 2.49k and RPROG = 26.7k, the maximum charging current is still 2.5A but the FLAG trip point is maintained at 10% of full scale. There are other effects to consider. The voltage across the current comparator is scaled to obtain the same values as the 100mV sense voltage target, but the input referred sense voltage is reduced, causing some careful consideration of the ripple current. Input referred maximum comparator threshold is 117mV, which is the same ratio of 1.4x the DC target. Input referred IREV threshold is scaled back to –24mV. The current at which the switcher starts will be reduced as well so there is some risk of boost activity. These concerns can be addressed by using a slightly larger inductor to compensate for the reduction of tolerance to ripple current. Charger Voltage Programming Pins CHEM and C3C4 are used to program the charger final output voltage. The CHEM pin programs Li-Ion battery chemistry for 4.1V/cell (low) or 4.2V/cell (high). The C3C4 pin selects either 3 series cells (low) or 4 series cells (high). It is recommended that these pins be shorted to ground (logic low) or left open (logic high) to effect the desired logic level. Use open-collector or open-drain outputs when interfacing to the CHEM and 3C4C pins from a logic control circuit. Table 3. Charger Voltage Programming VFINAL (V) 12.3 12.6 16.4 16.8 3C4C LOW LOW HIGH HIGH CHEM LOW HIGH LOW HIGH tTIMER (MINUTES) Setting the Timer Resistor The charger termination timer is designed for a range of 1hour to 3 hour with a ±15% uncertainty. The timer is programmed by the resistor RRT using the following equation: tTIMER = 10 • 227 • RRT • 17.5pF (seconds) 14 U 200 180 160 140 120 100 80 60 40 20 0 100 150 200 250 300 350 400 450 500 RRT (kΩ) 4007 F07 W UU Figure 7. tTIMER vs RRT It is important to keep the parasitic capacitance on the RT pin to a minimum. The trace connecting RT to RRT should be as short as possible. Soft-Start The LTC4007 is soft started by the 0.12µF capacitor on the ITH pin. On start-up, ITH pin voltage will rise quickly to 0.5V, then ramp up at a rate set by the internal 40µA pullup current and the external capacitor. Battery charging current starts ramping up when ITH voltage reaches 0.8V and full current is achieved with ITH at 2V. With a 0.12µF capacitor, time to reach full charge current is about 2ms and it is assumed that input voltage to the charger will reach full value in less than 2ms. The capacitor can be increased up to 1µF if longer input start-up times are needed. Input and Output Capacitors The input capacitor (C2) is assumed to absorb all input switching ripple current in the converter, so it must have adequate ripple current rating. Worst-case RMS ripple current will be equal to one half of output charging current. Actual capacitance value is not critical. Solid tantalum low ESR capacitors have high ripple current rating in a relatively small surface mount package, but caution must be 4007fa LTC4007 APPLICATIO S I FOR ATIO used when tantalum capacitors are used for input or output bypass. High input surge currents can be created when the adapter is hot-plugged to the charger or when a battery is connected to the charger. Solid tantalum capacitors have a known failure mechanism when subjected to very high turn-on surge currents. Only Kemet T495 series of “Surge Robust” low ESR tantalums are rated for high surge conditions such as battery to ground. The relatively high ESR of an aluminum electrolytic for C1, located at the AC adapter input terminal, is helpful in reducing ringing during the hot-plug event. Refer to AN88 for more information. Highest possible voltage rating on the capacitor will minimize problems. Consult with the manufacturer before use. Alternatives include new high capacity ceramic (at least 20µF) from Tokin, United Chemi-Con/Marcon, et al. Other alternative capacitors include OS-CON capacitors from Sanyo. The output capacitor (C3) is also assumed to absorb output switching current ripple. The general formula for capacitor current is: ⎛ ⎞ V 0.29(VBAT )⎜ 1 – BAT ⎟ ⎝ VDCIN ⎠ = (L1)( f) IRMS For example: VDCIN = 19V, VBAT = 12.6V, L1 = 10µH, and f = 300kHz, IRMS = 0.41A. EMI considerations usually make it desirable to minimize ripple current in the battery leads, and beads or inductors may be added to increase battery impedance at the 300kHz switching frequency. Switching ripple current splits between the battery and the output capacitor depending on the ESR of the output capacitor and the battery impedance. If the ESR of C3 is 0.2Ω and the battery impedance U is raised to 4Ω with a bead or inductor, only 5% of the current ripple will flow in the battery. Inductor Selection Higher operating frequencies allow the use of smaller inductor and capacitor values. A higher frequency generally results in lower efficiency because of MOSFET gate charge losses. In addition, the effect of inductor value on ripple current and low current operation must also be considered. The inductor ripple current ∆IL decreases with higher frequency and increases with higher VIN. ∆IL = ⎛V⎞ 1 VOUT ⎜ 1– OUT ⎟ ( f)(L) ⎝ VIN ⎠ W UU Accepting larger values of ∆IL allows the use of low inductances, but results in higher output voltage ripple and greater core losses. A reasonable starting point for setting ripple current is ∆IL = 0.4(IMAX). In no case should ∆IL exceed 0.6(IMAX) due to limits imposed by IREV and CA1. Remember the maximum ∆IL occurs at the maximum input voltage. In practice 10µH is the lowest value recommended for use. Lower charger currents generally call for larger inductor values. Use Table 4 as a guide for selecting the correct inductor value for your application. Table 4 MAX AVERAGE CURRENT (A) 1 1 2 2 3 3 4 4 INPUT VOLTAGE (V) ≤ 20 >20 ≤ 20 >20 ≤ 20 >20 ≤ 20 >20 MINIMUM INDUCTOR VALUE (µH) 40 ± 20% 56 ± 20% 20 ± 20% 30 ± 20% 15 ± 20% 20 ± 20% 10 ± 20% 15 ± 20% 4007fa 15 LTC4007 APPLICATIO S I FOR ATIO Charger Switching Power MOSFET and Diode Selection Two external power MOSFETs must be selected for use with the charger: a P-channel MOSFET for the top (main) switch and an N-channel MOSFET for the bottom (synchronous) switch. The peak-to-peak gate drive levels are set internally. This voltage is typically 6V. Consequently, logic-level threshold MOSFETs must be used. Pay close attention to the BVDSS specification for the MOSFETs as well; many of the logic level MOSFETs are limited to 30V or less. Selection criteria for the power MOSFETs include the “ON” resistance RDS(ON), total gate capacitance QG, reverse transfer capacitance CRSS, input voltage and maximum output current. The charger is operating in continuous mode at moderate to high currents so the duty cycles for the top and bottom MOSFETs are given by: Main Switch Duty Cycle = VOUT/VIN Synchronous Switch Duty Cycle = (VIN – VOUT)/VIN. The MOSFET power dissipations at maximum output current are given by: PMAIN = VOUT/VIN(IMAX)2(1 + δ∆T)RDS(ON) + k(VIN)2(IMAX)(CRSS)(fOSC) PSYNC = (VIN – VOUT)/VIN(IMAX)2(1 + δ∆T)RDS(ON) Where δ∆T is the temperature dependency of RDS(ON) and k is a constant inversely related to the gate drive current. Both MOSFETs have I2R losses while the PMAIN equation includes an additional term for transition losses, which are highest at high input voltages. For VIN < 20V the high current efficiency generally improves with larger MOSFETs, while for VIN > 20V the transition losses rapidly increase to the point that the use of a higher RDS(ON) device with lower CRSS actually provides higher efficiency. The synchronous MOSFET losses are greatest at high input voltage or during a short circuit when the duty cycle in this 16 U switch in nearly 100%. The term (1 + δ∆T) is generally given for a MOSFET in the form of a normalized RDS(ON) vs temperature curve, but δ = 0.005/°C can be used as an approximation for low voltage MOSFETs. CRSS = QGD/∆VDS is usually specified in the MOSFET characteristics. The constant k = 2 can be used to estimate the contributions of the two terms in the main switch dissipation equation. If the charger is to operate in low dropout mode or with a high duty cycle greater than 85%, then the topside P-channel efficiency generally improves with a larger MOSFET. Using asymmetrical MOSFETs may achieve cost savings or efficiency gains. The Schottky diode D1, shown in the Typical Application on the back page, conducts during the dead-time between the conduction of the two power MOSFETs. This prevents the body diode of the bottom MOSFET from turning on and storing charge during the dead-time, which could cost as much as 1% in efficiency. A 1A Schottky is generally a good size for 4A regulators due to the relatively small average current. Larger diodes can result in additional transition losses due to their larger junction capacitance. The diode may be omitted if the efficiency loss can be tolerated. Calculating IC Power Dissipation The power dissipation of the LTC4007 is dependent upon the gate charge of the top and bottom MOSFETs (QG1 & QG2 respectively) The gate charge is determined from the manufacturer’s data sheet and is dependent upon both the gate voltage swing and the drain voltage swing of the MOSFET. Use 6V for the gate voltage swing and VDCIN for the drain voltage swing. PD = VDCIN • (fOSC (QG1 + QG2) + IQ) Example: VDCIN = 19V, fOSC = 345kHz, QG1 = QG2 = 15nC, IQ = 5mA PD = 292mW 4007fa W UU LTC4007 APPLICATIO S I FOR ATIO Adapter Limiting An important feature of the LTC4007 is the ability to automatically adjust charging current to a level which avoids overloading the wall adapter. This allows the product to operate at the same time that batteries are being charged without complex load management algorithms. Additionally, batteries will automatically be charged at the maximum possible rate of which the adapter is capable. This feature is created by sensing total adapter output current and adjusting charging current downward if a preset adapter current limit is exceeded. True analog control is used, with closed-loop feedback ensuring that adapter load current remains within limits. Amplifier CL1 in Figure 8 senses the voltage across RCL, connected between the CLP and CLN pins. When this voltage exceeds 100mV, the amplifier will override programmed charging current to limit adapter current to 100mV/RCL. A lowpass filter formed by 5kΩ and 15nF is required to eliminate switching noise. If the current limit is not used, CLP should be connected to DCIN. Note that the ICL pin will be asserted when the voltage across RCL is 93mV, before the adapter limit regulation threshold. LTC4007 100mV – CL1 + CLP 18 15nF 5k AC ADAPTER INPUT VIN + CLN 19 100mV ADAPTER CURRENT LIMIT RCL* + CIN *RCL = Figure 8. Adapter Current Limiting Setting Input Current Limit To set the input current limit, you need to know the minimum wall adapter current rating. Subtract 7% for the U input current limit tolerance and use that current to determine the resistor value. RCL = 100mV/ILIM ILIM = Adapter Min Current – (Adapter Min Current • 7%) Table 5. Common RCL Resistor Values ADAPTER RATING (A) 1.5 1.8 2 2.3 2.5 2.7 3 RCL VALUE* (Ω) 1% 0.06 0.05 0.045 0.039 0.036 0.033 0.03 RCL POWER DISSIPATION (W) 0.135 0.162 0.18 0.206 0.225 0.241 0.27 RCL POWER RATING (W) 0.25 0.25 0.25 0.25 0.5 0.5 0.5 * Values shown above are rounded to nearest standard value. W UU As is often the case, the wall adapter will usually have at least a +10% current limit margin and many times one can simply set the adapter current limit value to the actual adapter rating (see Table 5). Designing the Thermistor Network There are several networks that will yield the desired function of voltage vs temperature needed for proper operation of the thermistor. The simplest of these is the voltage divider shown in Figure 9. Unfortunately, since the HIGH/LOW comparator thresholds are fixed internally, there is only one thermistor type that can be used in this network; the thermistor must have a HIGH/LOW resistance ratio of 1:7. If this happy circumstance is true for you, then simply set R9 = RTH(LOW). LTC4007 NTC 9 C7 RTH 4007 F09 4007 F08 R9 Figure 9. Voltage Divider Thermistor Network 4007fa 17 LTC4007 APPLICATIO S I FOR ATIO LTC4007 NTC 9 C7 R9A RTH 4007 F10 R9 Figure 10. General Thermistor Network If you are using a thermistor that doesn’t have a 1:7 HIGH/ LOW ratio, or you wish to set the HIGH/LOW limits to different temperatures, then the more generic network in Figure 10 should work. Once the thermistor, RTH, has been selected and the thermistor value is known at the temperature limits, then resistors R9 and R9A are given by: For NTC thermistors: R9 = 6 RTH(LOW) • RTH(HIGH)/(RTH(LOW) – RTH(HIGH)) R9A = 6 RTH(LOW) • RTH(HIGH)/(RTH(LOW) – 7 • RTH(HIGH)) Where RTH(LOW) > 7 • RTH(HIGH) For PTC thermistors: R9 = 6 RTH(LOW) • RTH(HIGH)/(RTH(HIGH) – RTH(LOW)) R9A = 6 RTH(LOW) • RTH(HIGH)/(RTH(HIGH) – 7 • RTH(LOW)) Where RTH(HIGH) > 7 • RTH(LOW) Example #1: 10kΩ NTC with custom limits TLOW = 0°C, THIGH = 50°C RTH = 10k at 25°C, RTH(LOW) = 32.582k at 0°C RTH(HIGH) = 3.635k at 50°C R9 = 24.55k → 24.3k (nearest 1% value) R9A = 99.6k → 100k (nearest 1% value) 18 U Example #2: 100kΩ NTC TLOW = 5°C, THIGH = 50°C RTH = 100k at 25°C, RTH(LOW) = 272.05k at 5°C RTH(HIGH) = 33.195k at 50°C R9 = 226.9k → 226k (nearest 1% value) R9A = 1.365M → 1.37M (nearest 1% value) Example #3: 22kΩ PTC TLOW = 0°C, THIGH = 50°C RTH = 22k at 25°C, RTH(LOW) = 6.53k at 0°C RTH(HIGH) = 61.4k at 50°C R9 = 43.9k → 44.2k (nearest 1% value) R9A = 154k Sizing the Thermistor Hold Capacitor During the hold interval, C7 must hold the voltage across the thermistor relatively constant to avoid false readings. A reasonable amount of ripple on NTC during the hold interval is about 10mV to 15mV. Therefore, the value of C7 is given by: C7 = tHOLD/(R9/7 • –ln(1 – 8 • 15mV/4.5V)) = 10 • RRT • 17.5pF/(R9/7 • – ln(1 – 8 • 15mV/4.5V) Example: R9 = 24.3k RRT = 309k (~2 hour timer) C7 = 0.57µF → 0.56µF (nearest value) 4007fa W UU LTC4007 APPLICATIO S I FOR ATIO Disabling the Thermistor Function If the thermistor is not needed, connecting a resistor between DCIN and NTC will disable it. The resistor should be sized to provide at least 10µA with the minimum voltage applied to DCIN and 10V at NTC. Do not exceed 30µA. Generally, a 301k resistor will work for DCIN less than 15V. A 499k resistor is recommended for DCIN between 15V and 24V. Conditioning Depleted Batteries Severely depleted batteries, with less than 2.5V/cell, should be conditioned with a trickle charge to prevent possible damage. This trickle charge is typically 10% of the 1C rate of the battery. The LTC4007 can automatically trickle charge depleted batteries using the circuit in Figure 11. If the battery voltage is less than 2.5V/cell (2.44V/cell if CHEM is low) then the LOBAT indicator will be low and Q4 is off. This programs the charging current with RPROG = R6 + R14. Charging current is approximately 300mA. When the cell voltage becomes greater than 2.5V the LOBAT indicator goes high, Q4 shorts out R13, then RPROG = R6. Charging current is then equal to 3A. PCB Layout Considerations For maximum efficiency, the switch node rise and fall times should be minimized. To prevent magnetic and electrical field radiation and high frequency resonant problems, proper layout of the components connected to the IC is essential (see Figure 12). Here is a PCB layout priority list for proper layout. Layout the PCB using this specific order. U 1. Input capacitors need to be placed as close as possible to switching FET’s supply and ground connections. Shortest copper trace connections possible. These parts must be on the same layer of copper. Vias must not be used to make this connection. 2. The control IC needs to be close to the switching FET’s gate terminals. Keep the gate drive signals short for a clean FET drive. This includes IC supply pins that connect to the switching FET source pins. The IC can be placed on the opposite side of the PCB relative to above. 3. Place inductor input as close as possible to switching FET’s output connection. Minimize the surface area of this trace. Make the trace width the minimum amount needed to support current—no copper fills or pours. Avoid running the connection using multiple layers in parallel. Minimize capacitance from this node to any other trace or plane. 4. Place the output current sense resistor right next to the inductor output but oriented such that the IC’s current sense feedback traces going to resistor are not long. The feedback traces need to be routed together as a single pair on the same layer at any given time with smallest trace spacing possible. Locate any filter component on these traces next to the IC and not at the sense resistor location. 5. Place output capacitors next to the sense resistor output and ground. 6. Output capacitor ground connections need to feed into same copper that connects to the input capacitor ground before tying back into system ground. 4007fa W UU 19 LTC4007 APPLICATIO S I FOR ATIO General Rules 7. Connection of switching ground to system ground or internal ground plane should be single point. If the system has an internal system ground plane, a good way to do this is to cluster vias into a single star point to make the connection. 8. Route analog ground as a trace tied back to IC ground (analog ground pin if present) before connecting to any other ground. Avoid using the system ground plane. CAD trick: make analog ground a separate ground net and use a 0Ω resistor to tie analog ground to system ground. 9. A good rule of thumb for via count for a given high current path is to use 0.5A per via. Be consistent. 20 U 10. If possible, place all the parts listed above on the same PCB layer. 11. Copper fills or pours are good for all power connections except as noted above in Rule 3. You can also use copper planes on multiple layers in parallel too—this helps with thermal management and lower trace inductance improving EMI performance further. 12. For best current programming accuracy provide a Kelvin connection from RSENSE to CSP and BAT. See Figure 12 as an example. It is important to keep the parasitic capacitance on the RT, CSP and BAT pins to a minimum. The traces connecting these pins to their respective resistors should be as short as possible. 4007fa W UU LTC4007 APPLICATIO S I FOR ATIO U Q3 INPUT SWITCH C1 0.1µF * R10 100k LOBAT ICL ACP SHDN FAULT CHG FLAG R9 32.4k 1% R11 100k R12 100k * 3C4C CHEM LOBAT ICL ACP SHDN FAULT CHG FLAG NTC C7 0.47µF RT 309k 1% RT DCIN INFET CLP C4 15nF R1 4.99k 1% RCL 0.033Ω 1% C2 20µF Q1 Q2 R4 3.01k 1% R5 3.01k 1% MONITOR (CHARGING CURRENT MONITOR) RSENSE 0.033Ω 1% BAT D1 C3 20µF SYSTEM LOAD L1 15µH 3A R7 6.04k 1% C6 0.12µF C5 0.0047µF R14 52.3k 1% R6 26.7k 1% Q4 *PIN OPEN D1: MBRM140T3 Q1: Si4431ADY Q2: FDC645N Q4: 2N7002 OR BSS138 4007 F11 DCIN 0V TO 20V 3A VLOGIC THERMISTOR TIMING RESISTOR (~2 HOURS) Figure 11. Circuit Application (16.8V/3A) to Automatically Trickle Charge Depleted Batteries W UU LTC4007 CLN TGATE BGATE PGND CSP BAT PROG ITH GND 4007fa 21 LTC4007 APPLICATIO S I FOR ATIO U SWITCH NODE L1 VBAT HIGH FREQUENCY CIRCULATING PATH D1 C3 BAT 4007 F12 VIN 22 W UU C2 Figure 12. High Speed Switching Path DIRECTION OF CHARGING CURRENT RSENSE 4007 F13 CSP BAT Figure 13. Kelvin Sensing of Charging Current 4007fa LTC4007 PACKAGE DESCRIPTION GN Package 24-Lead Plastic SSOP (Narrow .150 Inch) (Reference LTC DWG # 05-08-1641) .337 – .344* (8.560 – 8.738) 24 23 22 21 20 19 18 17 16 15 1413 .045 ± .005 .254 MIN .0165 ± .0015 RECOMMENDED SOLDER PAD LAYOUT .0075 – .0098 (0.19 – 0.25) 0° – 8° TYP .016 – .050 (0.406 – 1.270) NOTE: 1. CONTROLLING DIMENSION: INCHES INCHES 2. DIMENSIONS ARE IN (MILLIMETERS) 3. DRAWING NOT TO SCALE *DIMENSION DOES NOT INCLUDE MOLD FLASH. MOLD FLASH SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE **DIMENSION DOES NOT INCLUDE INTERLEAD FLASH. INTERLEAD FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE Information furnished by Linear Technology Corporation is believed to be accurate and reliable. However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights. U .033 (0.838) REF .229 – .244 (5.817 – 6.198) .150 – .165 .150 – .157** (3.810 – 3.988) 1 .0250 BSC 23 4 56 7 8 9 10 11 12 .015 ± .004 × 45° (0.38 ± 0.10) .0532 – .0688 (1.35 – 1.75) .004 – .0098 (0.102 – 0.249) .008 – .012 (0.203 – 0.305) TYP .0250 (0.635) BSC GN24 (SSOP) 0204 4007fa 23 LTC4007 TYPICAL APPLICATIO DCIN 0V TO 20V 3A VLOGIC R10 100k LOBAT ICL ACP SHDN FAULT CHG FLAG R9 32.4k 1% R11 100k R12 100k * THERMISTOR 10k NTC C7 0.47µF RRT 309k 1% TIMING RESISTOR (~2 HOURS) RELATED PARTS PART NUMBER LT®1511 LT1513 LT1571 LTC1628-PG LTC1709 LTC1729 LT1769 LTC1778 LTC1960 LTC3711 LTC4006 2A Switching Battery Charger Wide Operating Range, No RSENSE Synchronous Step-Down Controller Dual Battery Charger/Selector with SPI Interface No RSENSETM Synchronous Step-Down Controller with VID Small, High Efficiency, Fixed Voltage, Lithium-Ion Battery Charger High Efficiency, Programmable Voltage/Current Battery Charger Constant-Current/Constant-Voltage Switching Regulator, Input Current Limiting Maximizes Charge Current 2% to 90% Duty Cycle at 200kHz, Stable with Ceramic COUT Simultaneous Charge or Discharge of Two Batteries, DAC Programmable Current and Voltage, Input Current Limiting Maximizes Charge Current 3.5V ≤ VIN ≤ 36V, 0.925V ≤ VOUT ≤ 2V, for Transmeta, AMD and Intel Mobile Processors Constant-Current/Constant-Voltage Switching Regulator with Termination Timer, AC Adapter Current Limit and Thermistor Sensor in a Small 16-Pin Package Constant-Current/Constant-Voltage Switching Regulator, Resistor Voltage/ Current Programming, AC Adapter Current Limit and Thermistor Sensor 4007fa DESCRIPTION Constant-Current/Constant-Voltage 3A Battery Charger with Input Current Limiting SEPIC Constant- or Programmable-Current/ Constant-Voltage Battery Charger 1.5A Switching Charger 2-Phase, Dual Synchronous Step-Down Controller 2-Phase, Dual Synchronous Step-Down Controller with VID LTC4008 No RSENSE is a trademark of Linear Technology Corporation. 24 Linear Technology Corporation (408) 432-1900 ● FAX: (408) 434-0507 ● 1630 McCarthy Blvd., Milpitas, CA 95035-7417 www.linear.com U 12.6V, 4A Li-Ion Battery Charger Q3 INPUT SWITCH C1 0.1µF 3C4C CHEM LOBAT ICL ACP SHDN FAULT CHG FLAG NTC RT DCIN INFET CLP C4 15nF R1 4.99k 1% RCL 0.033Ω 1% C2 20µF Q1 Q2 R4 3.01k 1% R5 3.01k 1% R7 6.04k 1% C6 0.12µF C5 0.0047µF RPROG 26.7k 1% CHARGING CURRENT MONITOR *PIN OPEN D1: MBRS130T3 Q1: Si4431ADY Q2: FDC645N 4007 TA02 SYSTEM LOAD RSENSE L1 0.025Ω 10µH 4A 1% BAT D1 C3 20µF LTC4007 CLN TGATE BGATE PGND CSP BAT PROG ITH GND COMMENTS High Efficiency Current Mode PWM with 4A Internal Switch Charger Input Voltage May Be Higher, Equal to or Lower Than Battery Voltage; Charges Any Number of Cells Up to 20V, 500kHz Switching Frequency 1- or 2-Cell Li-Ion, 500kHz or 200kHz Switching Frequency, Termination Flag Minimizes CIN and COUT, Power Good Output, 3.5V ≤ VIN ≤ 36V Up to 42A Output, Minimum CIN and COUT, Uses Smallest Components for Intel and AMD Processors LT 0606 REV A • PRINTED IN USA © LINEAR TECHNOLOGY CORPORATION 2003