FeaTures
n n n
LTC4000 High Voltage High Current Controller for Battery Charging and Power Management DescripTion
The LTC®4000 is a high voltage, high performance controller that converts many externally compensated DC/DC power supplies into full-featured battery chargers. Features of the LTC4000’s battery charger include: accurate (±0.25%) programmable float voltage, selectable timer or current termination, temperature qualified charging using an NTC thermistor, automatic recharge, C/10 trickle charge for deeply discharged cells, bad battery detection and status indicator outputs. The battery charger also includes precision current sensing that allows lower sense voltages for high current applications. The LTC4000 supports intelligent PowerPath control. An external PFET provides low loss reverse current protection. Another external PFET provides low loss charging or discharging of the battery. This second PFET also facilitates an instant-on feature that provides immediate downstream system power even when connected to a heavily discharged or short faulted battery. The LTC4000 is available in a low profile 28-lead 4mm × 5mm QFN and SSOP packages.
L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks and PowerPath is a trademark of Linear Technology Corporation. All other trademarks are the property of their respective owners.
n
n
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Complete High Performance Battery Charger When Paired with a DC/DC Converter Wide Input and Output Voltage Range: 3V to 60V Input Ideal Diode for Low Loss Reverse Blocking and Load Sharing Output Ideal Diode for Low Loss PowerPath™ and Load Sharing with the Battery Instant-On Operation with Heavily Discharged Battery Programmable Input and Charge Current: ±1% Accuracy ±0.25% Accurate Programmable Float Voltage Programmable C/X or Timer Based Charge Termination NTC Input for Temperature Qualified Charging 28-Lead 4mm × 5mm QFN or SSOP Packages
applicaTions
n n n n
High Power Battery Charger Systems High Performance Portable Instruments Industrial Battery Equipped Devices Notebook/Subnotebook Computers
Typical applicaTion
48V to 10.8V at 10A Buck Converter Charger for Three LiFePO4 Cells
15V TO 60V 5m IN LT3845 SHDN VC 14.7k RST CLN IN 1.10M 1µF VM 100k 3.0V ENC CHRG FLT IIMON 10nF 10nF IBMON TMR 0.1µF CL 24.9k CX 22.1k GND BIAS 1µF NTHS0603 N02N1002J LTC4000 ITH CC OUT 100µF 47nF IID IGATE CSP CSN BGATE BAT OFB 127k FBG 133k BFB NTC 10k 1.13M 10.8V FLOAT 10A MAX CHARGE CURRENT 3-CELL LiFePO4 BATTERY PACK
4000 TA01a
Si7135DP
12V, 15A 1.15M 5m
Charge Current and VOUT Profile vs VBAT During a Charge Cycle
12 10 8 VOUT ICHARGE VOUT 11 10.5 10 VOUT (V) 9.5 9 ICHARGE 8.5 8 12
Si7135DP
ICHARGE (A)
6 4 2 0
6
7
8
10 9 VBAT (V)
11
10k
4000 TA01b
4000f
1
LTC4000 absoluTe MaxiMuM raTings
(Note 1)
IN, CLN, IID, CSP, CSN, BAT ....................... –0.3V to 62V IN-CLN, CSP-CSN ............................................–1V to 1V OFB, BFB, FBG ........................................... – 0.3V to 62V FBG ............................................................–1mA to 2mA IGATE ...........Max (VIID, VCSP) – 10V to Max (VIID, VCSP) BGATE .......Max (VBAT, VCSN) – 10V to Max (VBAT, VCSN) ENC, CX, NTC, VM ...................................– 0.3V to VBIAS IL, CL, TMR, IIMON, CC ...........................–0.3V to VBIAS
BIAS .............................................– 0.3V to Min (6V, VIN) IBMON ..................................– 0.3V to Min (VBIAS, VCSP) ITH ............................................................... – 0.3V to 6V CHRG, FLT, RST.......................................... – 0.3V to 62V CHRG, FLT, RST..........................................–1mA to 2mA Operating Junction Temperature Range (Note 2) ................................................................. 125°C Storage Temperature Range .................. – 65°C to 150°C
pin conFiguraTion
TOP VIEW TOP VIEW GND CLN ITH IID CC IN ENC IBMON CX 22 IGATE 21 OFB 20 CSP 29 GND 19 CSN 18 BGATE 17 BAT 16 BFB 15 FBG 9 10 11 12 13 14 TMR FLT CHRG BIAS GND NTC CL TMR GND FLT CHRG BIAS 1 2 3 4 5 6 7 8 9 28 IL 27 IIMON 26 RST 25 VM 24 GND 23 IN 22 CLN 21 CC 20 ITH 19 IID 18 IGATE 17 OFB 16 CSP 15 CSN
28 27 26 25 24 23 VM 1 RST 2 IIMON 3 IL 4 ENC 5 IBMON 6 CX 7 CL 8
NTC 10 FBG 11 BFB 12 BAT 13 BGATE 14
UFD PACKAGE 28-LEAD (4mm × 5mm) PLASTIC QFN TJMAX = 125°C, θJA = 43°C/W, θJC = 4°C/W EXPOSED PAD (PIN 29) IS GND, MUST BE SOLDERED TO PCB
GN PACKAGE 28-LEAD PLASTIC SSOP TJMAX = 125°C, θJA = 80°C/W, θJC = 25°C/W
orDer inForMaTion
LEAD FREE FINISH LTC4000EUFD#PBF LTC4000IUFD#PBF LTC4000EGN#PBF LTC4000IGN#PBF TAPE AND REEL LTC4000EUFD#TRPBF LTC4000IUFD#TRPBF LTC4000EGN#TRPBF LTC4000IGN#TRPBF PART MARKING* 4000 4000 LTC4000GN LTC4000GN PACKAGE DESCRIPTION 28-Lead (4mm × 5mm) Plastic QFN 28-Lead (4mm × 5mm) Plastic QFN 28-Lead Plastic SSOP 28-Lead Plastic SSOP TEMPERATURE RANGE –40°C to 125°C –40°C to 125°C –40°C to 125°C –40°C to 125°C
Consult LTC Marketing for parts specified with wider operating temperature ranges. *The temperature grade is identified by a label on the shipping container. Consult LTC Marketing for information on non-standard lead based finish parts. For more information on lead free part marking, go to: http://www.linear.com/leadfree/ For more information on tape and reel specifications, go to: http://www.linear.com/tapeandreel/
4000f
2
LTC4000 elecTrical characTerisTics
SYMBOL VIN IIN IBAT Shutdown ENC Input Voltage Low ENC Input Voltage High ENC Pull-Up Current ENC Open Circuit Voltage Voltage Regulation VBFB_REG Battery Feedback Voltage
l l l
The l denotes the specifications which apply over the full operating junction temperature range, otherwise specifications are at TA = 25°C. VIN = VCLN = 3V to 60V unless otherwise noted (Notes 2, 3).
PARAMETER Input Supply Operating Range Input Quiescent Operating Current Battery Pin Operating Current Battery Only Quiescent Current VIN ≥ 3V, VCSN = VCSP ≥ VBAT VIN ≥ 0V, VCSN = VCSP ≥ VBAT
l l
CONDITIONS
l
MIN 3
TYP 0.4 50 10
MAX 60 100 20 0.4
UNITS V mA µA μA V V µA V
1.5 –4 –2 2.5 1.136 1.136 ± 0.1 1.193 ± 0.1 100 96.9 82 65 97.6 0.5 86 68 3 1.139 1.147 1.204 400 98.3 90 71 –0.5 1.5 1.133 1.125 1.181
VENC = 0V VENC = Open
l
V V µA V µA Ω % % % % %
BFB Input Current VOFB_REG RFBG VRECHRG(RISE) VRECHRG(HYS) VOUT(INST_ON) VLOBAT VLOBAT(HYS) Current Regulation Ratio of Monitored-Current Voltage to Sense Voltage VOS Sense Voltage Offset CLN Pin Current CSP Pin Current CSN Pin Current IIL ICL ICL_TRKL Pull-Up Current for the Input Current Limit Programming Pin Pull-Up Current for the Charge Current Limit Programming Pin Pull-Up Current for the Charge Current Limit Programming Pin in Trickle Charge Mode Input Current Monitor Resistance to GND Charge Current Monitor Resistance to GND Output Feedback Voltage OFB Input Current Ground Return Feedback Resistance Rising Recharge Battery Threshold Voltage Instant-On Battery Voltage Threshold Falling Low Battery Threshold Voltage Low Battery Threshold Voltage Hysteresis
VBFB = 1.2V
l
VOFB = 1.2V
l
% of VBFB_REG % of VBFB_REG % of VBFB_REG % of VBFB_REG VIN,CLN = 50mV, VIIMON/VIN,CLN VCSP,CSN = 50mV, VIBMON/VCSP,CSN VCSP,CSN = 50mV, VCSP = 60V or VIN,CLN = 50mV, VIN = 60V (Note 4) VIGATE = Open, VIID = 0V VBGATE = Open, VBAT = 0V
l
Recharge Battery Threshold Voltage Hysteresis % of VBFB_REG
l l
l
19
20
21
V/V
–300 ±1 90 45
l l
300
µV µA μA μA
–55 –55 –5.5 40 40
–50 –50 –5.0 90 90 0 1.0
–45 –45 –4.5 140 140 10 1.015
μA μA μA kΩ kΩ mV V
VBFB < VLOBAT
l
A4, A5 Error Amp Offset for the Current Loops VCL = 0.8V, VIL = 0.8V (See Figure 1) Maximum Programmable Current Limit Voltage Range
l l
–10 0.985
4000f
3
LTC4000 elecTrical characTerisTics
SYMBOL PARAMETER CX Pin Pull-Up Current VCX,IBMON(OS) VCX,IBMON(HYS) CX Comparator Offset Voltage, IBMON Falling CX Comparator Hysteresis Voltage TMR Pull-Up Current TMR Pull-Down Current TMR Pin Frequency TMR Threshold for CX Termination tT tT/tBB VNTC(COLD) VNTC(HOT) VNTC(HYS) VNTC(OPEN) RNTC(OPEN) VVM(TH) VVM(HYS) Charge Termination Time CTMR = 0.1μF Ratio of Charge Terminate Time to Bad Battery CTMR = 0.1μF Indicator Time NTC Cold Threshold NTC Hot Threshold NTC Thresholds Hysteresis NTC Open Circuit Voltage NTC Open Circuit Input Resistance VM Input Falling Threshold VM Input Hysteresis VM Input Current IRST,CHRG,FLT(LKG) Open Drain Status Pins Leakage Current VRST,CHRG,FLT(VOL) Open Drain Status Pins Voltage Output Low Input PowerPath Control Input PowerPath Forward Regulation Voltage Input PowerPath Fast Reverse Turn-Off Threshold Voltage Input PowerPath Fast Forward Turn-On Threshold Voltage Input Gate Turn-Off Current Input Gate Turn-On Current IIGATE(FASTOFF) IIGATE(FASTON) VIGATE(ON) Input Gate Fast Turn-Off Current Input Gate Fast Turn-On Current Input Gate Clamp Voltage VIID,CSP, 3V ≤ VCSP ≤ 60V VIID,CSP, 3V ≤ VCSP ≤ 60V, VIGATE = VCSP – 2.5V, ∆IIGATE/∆ VIID,CSP ≥ 100μA/mV VIID,CSP, 3V ≤ VCSP ≤ 60V, VIGATE = VIID – 1.5V, ∆IIGATE/∆ VIID,CSP ≥ 100μA/mV VIID = VCSP, VIGATE = VCSP – 1.5V VCSP = VIID – 20mV, VIGATE = VIID – 1.5V VCSP = VIID + 0.1V, VIGATE = VCSP – 5V VCSP = VIID – 0.1V, VIGATE = VIID – 1.5V IIGATE = 2µA, VIID = 12V to 60V, VCSP = VIID – 0.5V, Measure VIID – VIGATE IIGATE = – 2μA, VIID = 3V to 59.9V, VCSP = VIID + 0.5V, Measure VCSP – VIGATE
l l l l
The l denotes the specifications which apply over the full operating junction temperature range, otherwise specifications are at TA = 25°C. VIN = VCLN = 3V to 60V unless otherwise noted (Notes 2, 3).
CONDITIONS VCX = 0.1V VCX = 0.1V VTMR = 0V VTMR = 1.5V CTMR = 0.01μF
l l l l l l l
MIN –5.5 0.5
TYP –5.0 10 5 –5.0 5.0
MAX –4.5 25
UNITS µA mV mV μA μA
Charge Termination
400 2.3 3.95 73 33 45
500 2.1 2.9 4 75 35 5 50 300
600 2.5 3.5 4.05 77 37 55
Hz V h h/h % % % % kΩ
VNTC Rising, % of VBIAS VNTC Falling, % of VBIAS % of VBIAS % of VBIAS
l
Voltage Monitoring and Open Drain Status Pins 1.181 1.193 40 VVM = 1.2V VPIN = 60V IPIN = 1mA
l
1.204
V mV µA µA
±0.1 ±1 0.4 0.1 –90 8 –50 20 –20
V mV mV
l
40
80
130
mV
–0.3 0.3 –0.5 0.7 13 15
μA μA mA mA V
Input Gate Off Voltage
l
0.45
0.7
V
4000f
4
LTC4000 elecTrical characTerisTics
SYMBOL PARAMETER Battery Discharge PowerPath Forward Regulation Voltage Battery PowerPath Fast Reverse Turn-Off Threshold Voltage Battery PowerPath Fast Forward Turn-On Threshold Voltage Battery Gate Turn-Off Current Battery PowerPath Control VBAT,CSN, 2.8V ≤ VBAT ≤ 60V VBAT,CSN, 2.8V ≤ VBAT ≤ 60V, Not Charging, VBGATE = VCSN – 2.5V, ∆IBGATE/∆VBAT,CSN ≥ 100μA/mV VBAT,CSN, 2.8V ≤ VCSN ≤ 60V, VBGATE = VBAT – 1.5V, ∆IBGATE/∆ VBAT,CSN ≥ 100μA/mV VBGATE = VCSN – 1.5V, VCSN ≥ VBAT, VOFB < VOUT(INST_ON) and Charging in Progress, or VCSN = VBAT and Not Charging VBGATE = VBAT – 1.5V, VCSN ≥ VBAT, VOFB > VOUT(INST_ON) and Charging in Progress, or VCSN = VBAT – 20mV VCSN = VBAT + 0.1V and Not Charging, VBGATE = VCSN – 5V VCSN = VBAT – 0.1V, VBGATE = VBAT – 1.5V IBGATE = 2μA, VBAT = 12V to 60V, VCSN = VBAT – 0.5V, Measure VBAT – VBGATE
l l l
The l denotes the specifications which apply over the full operating junction temperature range, otherwise specifications are at TA = 25°C. VIN = VCLN = 3V to 60V unless otherwise noted (Notes 2, 3).
CONDITIONS MIN 0.1 –90 TYP 8 –50 MAX 20 –20 UNITS mV mV
l
40
80
130
mV
–0.3
μA
Battery Gate Turn-On Current
0.3
μA
IBGATE(FASTOFF) IBGATE(FASTON) VBGATE(ON)
Battery Gate Fast Turn-Off Current Battery Gate Fast Turn-On Current Battery Gate Clamp Voltage
–0.5 0.7 13 15
mA mA V
Battery Gate Off Voltage
l IBGATE = – 2μA, VBAT = 2.8V to 60V, VCSN = VBAT + 0.5V and not Charging, Measure VCSN – VBGATE
0.45
0.7
V
BIAS Regulator Output and Control Pins VBIAS ∆VBIAS BIAS Output Voltage BIAS Output Voltage Load Regulation BIAS Output Short-Circuit Current Transconductance of Error Amp Open Loop DC Voltage Gain of Error Amp IITH(PULL_UP) IITH(PULL_DOWN) Pull-Up Current on the ITH Pin Pull-Down Current on the ITH Pin Open Loop DC Voltage Gain of ITH Driver No Load IBIAS = – 0.5mA VBIAS = 0V CC = 1V CC = Open VITH = 0V, VCC = 0V VITH = 0.4V, CC = Open ITH = Open
l l
2.4
2.9 –0.5 –12 0.5 80
3.5 –10
V % mA mA/V dB
–6 0.5
–5 1 60
–4
μA mA dB
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: The LTC4000 is tested under conditions such that TJ ≈ TA. The LTC4000E is guaranteed to meet specifications from 0°C to 85°C junction temperature. Specifications over the –40°C to 125°C operating junction temperature range are assured by design, characterization and correlation with statistical process controls. The LTC4000I is guaranteed over the full –40°C to 125°C operating junction temperature range. Note that the maximum ambient temperature consistent with these specifications is
determined by specific operating conditions in conjunction with board layout, the rated package thermal impedance and other environmental factors. The junction temperature (TJ, in °C) is calculated from the ambient temperature (TA, in °C) and power dissipation (PD, in Watts) according to the following formula: TJ = TA + (PD • θJA), where θJA (in °C/W) is the package thermal impedance. Note 3: All currents into pins are positive; all voltages are referenced to GND unless other wise noted. Note 4: These parameters are guaranteed by design and are not 100% tested.
4000f
5
LTC4000 Typical perForMance characTerisTics
Input Quiescent Current and Battery Quiescent Current Over Temperature
1.0 VIN = VBAT = 15V VCSN = 15.5V 100 IIN VBAT = 60V VBAT = 15V IIN/IBAT (mA) 0.1 IBAT (µA) 1 VBAT = 3V
Battery Only Quiescent Current Over Temperature
1.20 1.19 1.18 PIN VOLTAGE (V) 1.17 1.16 1.15 1.14 1.13 1.12 1.11
Battery Float Voltage Feedback, Output Voltage Regulation Feedback and VM Falling Threshold Over Temperature
10
VVM(TH)
VOFB_REG
IBAT
0.1
VBFB_REG
0.01
0 –60 –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C)
4000 G01
0.001 –60 –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C)
4000 G02
1.10 –60 –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C)
4000 G03
Battery Thresholds: Rising Recharge, Instant-On Regulation and Falling Low Battery As a Percentage of Battery Float Feedback Over Temperature
100 95 PERCENT OF VBFB_REG (%) 90 IIL/ICL (µA) 85 80 75 70 65 60 –60 –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C)
4000 G04
IL and CL Pull-Up Current Over Temperature
–45.0 1.015 1.010 –47.5 VIIMON /VIBMON (V) 1.005 1.000 0.995 0.990 –55.0 –60 –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C)
4000 G05
Maximum Programmable Current Limit Voltage Over Temperature
VRECHRG(RISE)
VOUT(INST_ON)
–50.0
VLOBAT
–52.5
0.985 –60 –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C)
4000 G06
Current Sense Offset Voltage Over Temperature
300 200 100 VOS (µV) 0 –100 –200 –300 –60 –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C)
4000 G07
Current Sense Offset Voltage Over Common Mode Voltage Range
300 200 VCX,IBMON (mV) 60
4000 G08
VMAX(IN,CLN) = VMAX(CSP CSN) = 15V ,
VOS (µV)
VOS(CSP CSN) ,
100 0 –100 –200 –300
VOS(CSP CSN) ,
VOS(IN, CSN)
VOS(IN, CSN)
0
10 20 30 40 50 VMAX(IN, CLN) /VMAX(CSP CSN) (V) ,
20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 –60 –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C)
4000 G09
CX Comparator Offset Voltage with VIBMON Falling Over Temperature
4000f
6
LTC4000 Typical perForMance characTerisTics
Charge Termination Time with 0.1µF Timer Capacitor Over Temperature
3.5 3.3 PERCENT OF VBIAS (%) 3.1 TT (h) 2.9 2.7 2.5 2.3 –60 –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C)
4000 G10
NTC Thresholds Over Temperature
80 75 70 65 60 55 50 45 40 35 30 –60 –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C)
4000 G11
PowerPath Forward Voltage Regulation Over Temperature
VNTC(COLD) 14 12 VIID,CSP / VBAT,CSN (mV) 10 8 6 4 2 0 –60 –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C)
4000 G12
VIID = VBAT = 15V VIID = VBAT = 3V
VNTC(OPEN) VNTC(HOT)
VIID = VBAT = 60V
PowerPath Fast Off, Fast On and Forward Regulation Over Temperature
120 90 VIGATE (ON)/VBGATE(ON) (V) VIID,CSP /VBAT,CSN (mV) 60 30 0 –30 –60 –90 –60 –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C)
4000 G13
PowerPath Turn-On Gate Clamp Voltage Over Temperature
14.5 14.0 13.5 13.0 12.5 12.0 11.5 11.0 –60 –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C)
4000 G14
PowerPath Turn-Off Gate Voltage Over Temperature
VMAX(IID,CSP), IGATE/VMAX(BAT,CSN),BGATE (mV) 600 550 500 450 400 350 300 250 200 –60 –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C)
4000 G15
VIID = VBAT = 15V
15.0
VIID = VBAT = 15V
VCSP = VCSN = 15V
BIAS Voltage at 0.5mA Load Over Temperature
3.2 3.1 IITH(PULL-DOWN) (mA) 3.0 VBIAS (V) 2.9 2.8 2.7 2.6 2.5 –60 –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C)
4000 G16
ITH Pull-Down Current Over Temperature
1.5 1.4 VITH = 0.4V 2.5
ITH Pull-Down Current vs VITH
1.2 1.1 1.0 0.9 0.8 0.7 0.6 0.5 –60 –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C)
4000 G17
VIN = 15V VIN = 3V
IITH(PULL-DOWN) (mA)
VIN = 60V
1.3
2.0
1.5
1.0
0.5
0
0
0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 VITH (V)
1
4000 G18
4000f
7
LTC4000 pin FuncTions
(QFN/SSOP)
VM (Pin 1/Pin 25): Voltage Monitor Input. High impedance input to an accurate comparator with a 1.193V threshold (typical). This pin controls the state of the RST output pin. Connect a resistor divider (RVM1, RVM2) between the monitored voltage and GND, with the center tap point connected to this pin. The falling threshold of the monitored voltage is calculated as follows:
ENC (Pin 5/Pin 1): Enable Charging Pin. High impedance digital input pin. Pull this pin above 1.5V to enable charging and below 0.5V to disable charging. Leaving this pin open causes the internal 1µA pull-up current to pull the pin to 2.5V (typical). IBMON (Pin 6/Pin 2): Battery Charge Current Monitor. The voltage on this pin is 20 times (typical) the sense voltage (VCSP,CSN) across the battery current sense resistor (RCS), therefore providing a voltage proportional to the battery charge current. Connect an appropriate capacitor to this pin to obtain a voltage representation of the time-average battery charge current. Short this pin to GND to disable charge current limit feature. CX (Pin 7/Pin 3): Charge Current Termination Programming. Connect the charge current termination programming resistor (RCX) to this pin. This pin is a high impedance input to a comparator and sources 5μA of current. When the voltage on this pin is greater than the charge current monitor voltage (VIBMON), the CHRG pin turns high impedance indicating that the CX threshold is reached. When this occurs, the charge current is immediately terminated if the TMR pin is shorted to the BIAS pin, otherwise charging continues until the charge termination timer expires. The charge current termination value is determined using the following formula: IC / X =
VVM _ RST =
RVM1 + RVM2 • 1.193V RVM2
where RVM2 is the bottom resistor between the VM pin and GND. Tie to the BIAS pin if voltage monitoring function is not used. RST (Pin 2/Pin 26): High Voltage Open Drain Reset Output. When the voltage at the VM pin is below 1.193V, this status pin is pulled low. When driven low, this pin can disable a DC/DC converter when connected to the converter’s enable pin. This pin can also drive an LED to provide a visual status indicator of a monitored voltage. Short this pin to GND when not used. IIMON (Pin 3/Pin 27): Input Current Monitor. The voltage on this pin is 20 times (typical) the sense voltage (VIN,CLN) across the input current sense resistor(RIS), therefore providing a voltage proportional to the input current. Connect an appropriate capacitor to this pin to obtain a voltage representation of the time-average input current. Short this pin to GND to disable input current limit feature. IL (Pin 4/Pin 28): Input Current Limit Programming. Connect the input current programming resistor (RIL) to this pin. This pin sources 50µA of current. The regulation loop compares the voltage on this pin with the input current monitor voltage (VIIMON), and drives the ITH pin accordingly to ensure that the programmed input current limit is not exceeded. The input current limit is determined using the following formula:
(0.25µA • R CX ) − 0.5mV
R CS
Where RCS is the sense resistor connected to the CSP and the CSN pins. Note that if RCX = RCL ≤ 19.1kΩ, where RCL is the charge current programming resistor, then the charge current termination value is one tenth the full charge current, more familiarly known as C/10. Short this pin to GND to disable CX termination.
⎛R ⎞ IILIM = 2.5µA • ⎜ IL ⎟ ⎝ RIS ⎠
where RIS is the sense resistor connected to the IN and the CLN pins. Leave the pin open for the maximum input current limit of 50mV/RIS.
4000f
8
LTC4000 pin FuncTions
(QFN/SSOP)
CL (Pin 8/Pin 4): Charge Current Limit Programming. Connect the charge current programming resistor (RCL) to this pin. This pin sources 50µA of current. The regulation loop compares the voltage on this pin with the charge current monitor voltage (VIBMON), and drives the ITH pin accordingly to ensure that the programmed charge current limit is not exceeded. The charge current limit is determined using the following formula:
of these pins with an LED in series with a resistor to a voltage source to provide a visual status indicator. Short these pins to GND when not used. BIAS (Pin 13/Pin 9): 2.9V Regulator Output. Connect a capacitor of at least 470nF to bypass this 2.9V regulated voltage output. Use this pin to bias the resistor divider to set up the voltage at the NTC pin. NTC (Pin 14/Pin 10): Thermistor Input. Connect a thermistor from NTC to GND, and a corresponding resistor from BIAS to NTC. The voltage level on this pin determines if the battery temperature is safe for charging. The charge current and charge timer are suspended if the thermistor indicates a temperature that is unsafe for charging. Once the temperature returns to the safe region, charging resumes. Leave the pin open or connected to a capacitor to disable the temperature qualified charging function. FBG (Pin 15/Pin 11): Feedback Ground Pin. This is the ground return pin for the resistor dividers connected to the BFB and OFB pins. As soon as the voltage at IN is valid (>3V typical), this pin has a 100Ω resistance to GND. When the voltage at IN is not valid, this pin is disconnected from GND to ensure that the resistor dividers connected to the BFB and OFB pins do not continue to drain the battery when the battery is the only available power source. BFB (Pin 16/Pin 12): Battery Feedback Voltage Pin. This pin is a high impedance input pin used to sense the battery voltage level. In regulation, the battery float voltage loop sets the voltage on this pin to 1.136V (typical). Connect this pin to the center node of a resistor divider between the BAT pin and the FBG pin to set the battery float voltage. The battery float voltage can then be obtained as follows:
VFLOAT = RBFB2 + RBFB1 • 1.136V RBFB2
ICLIM
⎛R ⎞ = 2.5µA • ⎜ CL ⎟ ⎝ RCS ⎠
Where RCS is the sense resistor connected to the CSP and the CSN pins. Leave the pin open for the maximum charge current limit of 50mV/RCS. TMR (Pin 9/Pin 5): Charge Timer. Attach 1nF of external capacitance (CTMR) to GND for each 104 seconds of charge termination time and 26 seconds of bad battery indicator time. Short to GND to prevent bad battery indicator time and charge termination time from expiring – allowing a continuous trickle charge and top off float voltage regulation charge. Short to BIAS to disable bad battery detect and enable C/X charging termination. GND (Pins 10, 28, 29/Pins 6, 24): Device Ground Pins. Connect the ground pins to a suitable PCB copper ground plane for proper electrical operation. The QFN package exposed pad must be soldered to PCB ground for rated thermal performance. FLT, CHRG (Pin 11, Pin 12/Pin 7, Pin 8): Charge Status Indicator Pins. These pins are high voltage open drain pull down pins. The FLT pin pulls down when there is an under or over temperature condition during charging or when the voltage on the BFB pin stays below the low battery threshold during charging for a period longer than the bad battery indicator time. The CHRG pin pulls down during a charging cycle. Please refer to the application information section for details on specific modes indicated by the combination of the states of these two pins. Pull up each
BAT (Pin 17/Pin 13): Battery Pack Connection. Connect the battery to this pin. This pin is the anode of the battery ideal diode driver (the cathode is the CSN pin).
4000f
9
LTC4000 pin FuncTions
(QFN/SSOP)
BGATE (Pin 18/Pin 14): External Battery PMOS Gate Drive Output. When not charging, the BGATE pin drives the external PMOS to behave as an ideal diode from the BAT pin (anode) to the CSN pin (cathode). This allows efficient delivery of any required additional power from the battery to the downstream system connected to the CSN pin. When charging a heavily discharged battery, the BGATE pin is regulated to set the output feedback voltage (OFB pin) to 86% of the battery float voltage (0.974V typical). This allows the instant-on feature, providing an immediate valid voltage level at the output when the LTC4000 is charging a heavily discharged battery. Once the voltage on the OFB pin is above the 0.974V typical value, then the BGATE pin is driven low to ensure an efficient charging path from the CSN pin to the BAT pin. CSN (Pin 19/Pin 15): Charge Current Sense Negative Input and Battery Ideal Diode Cathode. Connect a sense resistor between this pin and the CSP pin. The LTC4000 senses the voltage across this sense resistor and regulates it to a voltage equal to 1/20th (typical) of the voltage set at the CL pin. The maximum regulated sense voltage is 50mV. The CSN pin is also the cathode input of the battery ideal diode driver (the anode input is the BAT pin). Tie this pin to the CSP pin if no charge current limit is desired. Refer to the Applications Information section for complete details. CSP (Pin 20/Pin 16): Charge Current Sense Positive Input and Input Ideal Diode Cathode. Connect a sense resistor between this pin and the CSN pin for charge current sensing and regulation. This input should be tied to CSN to disable the charge current regulation function. This pin is also the cathode of the input ideal diode driver (the anode is the IID pin).
OFB (Pin 21/Pin 17): Output Feedback Voltage Pin. This pin is a high impedance input pin used to sense the output voltage level. In regulation, the output voltage loop sets the voltage on this feedback pin to 1.193V. Connect this pin to the center node of a resistor divider between the CSP pin and the FBG pin to set the output voltage when battery charging is terminated and all the output load current is provided from the input. The output voltage can then be obtained as follows:
VOUT = ROFB2 + ROFB1 • 1.193V ROFB2
When charging a heavily discharged battery (such that VOFB < VOUT(INST_ON)), the battery PowerPath PMOS connected to BGATE is regulated to set the voltage on this feedback pin to 0.974V (approximately 86% of the battery float voltage). The instant-on output voltage is then as follows:
VOUT(INST _ ON) = ROFB2 + ROFB1 • 0.974V ROFB2
IGATE (Pin 22/Pin 18): Input PMOS Gate Drive Output. The IGATE pin drives the external PMOS to behave as an ideal diode from the IID pin (anode) to the CSP pin (cathode). IID (Pin 23/Pin 19): Input Ideal Diode Anode. This pin is the anode of the input ideal diode driver (the cathode is the CSP pin). ITH (Pin 24/Pin 20): High Impedance Control Voltage Pin. When any of the regulation loops (input current, charge current, battery float voltage or the output voltage) indicate that its limit is reached, the ITH pin will sink current (up to 1mA) to regulate that particular loop at the limit. In many applications, this ITH pin is connected to the control/compensation node of a DC/DC converter. Without any external pull-up, the operating voltage range on this pin is GND to 2.5V. With an external pull-up, the voltage on this pin can be pulled up to 6V. Note that the impedance connected to this pin affects the overall loop gain. For details, refer to the Applications Information section.
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LTC4000 pin FuncTions
(QFN/SSOP)
CC (Pin 25/Pin 21): Converter Compensation Pin. Connect an R-C network from this pin to the ITH pin to provide a suitable loop compensation for the converter used. Refer to the Applications Information section for discussion and procedure on choosing an appropriate R-C network for a particular DC/DC converter. CLN (Pin 26/Pin 22): Input Current Sense Negative Input. Connect a sense resistor between this pin and the IN pin. The LTC4000 senses the voltage across this sense resistor and regulates it to a voltage equal to 1/20th (typical) of the voltage set at the IL pin. Tie this pin to the IN pin if no input current limit is desired. Refer to the Applications Information section for complete details.
IN (Pin 27/Pin 23): Input Supply Voltage: 3V to 60V. Supplies power to the internal circuitry and the BIAS pin. Connect the power source to the downstream system and the battery charger to this pin. This pin is also the positive sense pin for the input current limit. Connect a sense resistor between this pin and the CLN pin. Tie this pin to CLN if no input current limit is desired. A local 0.1µF bypass capacitor to ground is recommended on this pin.
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LTC4000 block DiagraM
IN CIN RIS CCLN RC IN VM CLN RST ITH DC/DC CONVERTER CIID CC CC IID IGATE CIBMON IBMON CSP OUT CL SYSTEM LOAD
RVM1 RVM2
1.193V A8 gm = 0.33m
+
8mV
+ –
A1
60k
A9 gm = 0.33m
A2
IIMON 60k A10 50µA RIL IL 1V
INPUT IDEAL DIODE DRIVER
– +
8mV gm A11
LINEAR GATE DRIVER AND VOLTAGE CLAMP ENABLE CHARGING
0.974V BIAS ITH AND CC DRIVER A5
BATTERY IDEAL DIODE AND INSTANT-ON DRIVER BIAS ROFB1 5µA/ 50µA CL RCL OFB
+ –gm –
A4
– gm
+ gm – + – + –
A7
–
1V
IN LDO, BG, REF CBIAS BIAS
OFB 1.193V BFB 1.136V CP6
gm A6
REF
gm
– +
NTC
CP4
NTC FAULT CP3 TOO HOT
LOGIC CP2
–
BIAS
+
10mV BIAS 2µA
–+
OSCILLATOR GND ENC CHRG FLT
4000 BD
Figure 1. LTC4000 Functional Block Diagram
12
–
TOO COLD
+
CP5
– +
–
CP1
CSN
RCS
–
–
+
+
– +
BGATE
0.771V ROFB2 BFB RBFB1
RBFB2 1.109V FBG
BAT CBAT 5µA
+ –
RNTC
CX BATTERY PACK TMR CTMR RCX
R3
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LTC4000 operaTion
Overview The LTC4000 is designed to simplify the conversion of any externally compensated DC/DC converter into a high performance battery charger with PowerPath control. It only requires the DC/DC converter to have a control or external-compensation pin (usually named VC or ITH) whose voltage level varies in a positive monotonic way with its output. The output variable can be either output voltage or output current. For the following discussion, refer to the Block Diagram in Figure 1. The LTC4000 includes four different regulation loops: input current, charge current, battery float voltage and output voltage (A4-A7). Whichever loop requires the lowest voltage on the ITH pin for its regulation controls the external DC/DC converter. The input current regulation loop ensures that the programmed input current limit (using a resistor at IL) is not exceeded at steady state. The charge current regulation loop ensures that the programmed battery charge current limit (using a resistor at CL) is not exceeded. The float voltage regulation loop ensures that the programmed battery stack voltage (using a resistor divider from BAT to FBG via BFB) is not exceeded. The output voltage regulation loop ensures that the programmed system output voltage (using a resistor divider from CSP to FBG via OFB) is not exceeded. The LTC4000 also provides monitoring pins for the input current and charge current at the IIMON and IBMON pins respectively. The LTC4000 features an ideal diode controller at the input from the IID pin to the CSP pin and a PowerPath controller at the output from the BAT pin to the CSN pin. The output PowerPath controller behaves as an ideal diode controller when not charging. When charging, the output PowerPath controller has two modes of operation. If VOFB is greater than VOUT(INST_ON), BGATE is driven low. When VOFB is less than VOUT(INST_ON), a linear regulator implements the instant-on feature. This feature provides regulation of the BGATE pin so that a valid voltage level is immediately available at the output when the LTC4000 is charging an over-discharged, dead or short faulted battery. The state of the ENC pin determines whether charging is enabled. When ENC is grounded, charging is disabled and the battery float voltage loop is disabled. Charging is enabled when the ENC pin is left floating or pulled high (≥1.5V) The LTC4000 offers several user configurable battery charge termination schemes. The TMR pin can be configured for either C/X termination, charge timer termination or no termination. After a particular charge cycle terminates, the LTC4000 features an automatic recharge cycle if the battery voltage drops below 97.6% of the programmed float voltage. Trickle charge mode drops the charge current to one tenth of the normal charge current (programmed using a resistor from the CL pin to GND) when charging into an over discharged or dead battery. When trickle charging, a capacitor on the TMR pin can be used to program a time out period. When this bad battery timer expires and the battery voltage fails to charge above the low battery threshold (VLOBAT), the LTC4000 will terminate charging and indicate a bad battery condition through the status pins (FLT and CHRG). The LTC4000 also includes an NTC pin, which provides temperature qualified charging when connected to an NTC thermistor thermally coupled to the battery pack. To enable this feature, connect the thermistor between the NTC and the GND pins, and a corresponding resistor from the BIAS pin to the NTC pin. The LTC4000 also provides a charging status indicator through the FLT and the CHRG pins. Aside from biasing the thermistor-resistor network, the BIAS pin can also be used for a convenient pull up voltage. This pin is the output of a low dropout voltage regulator that is capable of providing up to 0.5mA of current. The regulated voltage on the BIAS pin is available as soon as the IN pin is within its operating range (≥3V). Input Ideal Diode The input ideal diode feature provides low loss conduction and reverse blocking from the IID pin to the CSP pin. This reverse blocking prevents reverse current from the output (CSP pin) to the input (IID pin) which causes unnecessary drain on the battery and in some cases may result in unexpected DC/DC converter behavior.
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LTC4000 operaTion
The ideal diode behavior is achieved by controlling an external PMOS connected to the IID pin (drain) and the CSP pin (source). The controller (A1) regulates the external PMOS by driving the gate of the PMOS device such that the voltage drop across IID and CSP is 8mV (typical). When the external PMOS ability to deliver a particular current with an 8mV drop across its source and drain is exceeded, the voltage at the gate clamps at VIGATE(ON) and the PMOS behaves like a fixed value resistor (RDS(ON)). Input Current Regulation and Monitoring One of the loops driving the ITH and CC pins is the input current regulation loop (Figure 2). This loop prevents the input current sensed through the input current sense resistor (RIS) from exceeding the programmed input current limit.
IN CIN IN CLN A8 gm = 0.33m 60k 50µA RIL 1V IL RIS LOAD CCLN (OPTIONAL) LTC4000
Once the battery voltage is above VLOBAT, the charge current regulation loop begins charging in full power constantcurrent mode. In this case, the programmed full charge current is set with a resistor on the CL pin. Depending on available input power and external load conditions, the battery charger may not be able to charge at the full programmed rate. The external load is always prioritized over the battery charge current. The input current limit programming is always observed, and only additional power is available to charge the battery. When system loads are light, battery charge current is maximized. Once the float voltage is achieved, the battery float voltage regulation loop takes over from the charge current regulation loop and initiates constant voltage charging. In constant voltage charging, charge current slowly declines. Charge termination can be configured with the TMR pin in several ways. If the TMR pin is tied to the BIAS pin, C/X termination is selected. In this case, charging is terminated when constant voltage charging reduces the charge current to the C/X level programmed at the CX pin. Connecting a capacitor to the TMR pin selects the charge timer termination and a charge termination timer is started at the beginning of constant voltage charging. Charging terminates when the termination timer expires. When continuous charging at the float voltage is desired, tie the TMR pin to GND to disable termination. Upon charge termination, the PMOS connected to BGATE behaves as an ideal diode from BAT to CSN. The diode function prevents charge current but provides current to the system load as needed. If the system load can be completely supplied from the input, the battery PMOS turns off. While terminated, if the input current limit is not in regulation, the output voltage regulation loop takes over to ensure that the output voltage at CSP remains in control. The output voltage regulation loop regulates the voltage at the CSP pin such that the output feedback voltage at the OFB pin is 1.193V. If the system load requires more power than is available from the input, the battery ideal diode controller provides supplemental power from the battery. When the battery voltage discharges below 97.1% of the float voltage (VBFB < VRECHRG(FALL)), the automatic recharge feature initiates a new charge cycle.
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A8
+ –
IIMON CIIMON (OPTIONAL) BIAS
CC
+ – –
CC
A4
– +
ITH
RC TO DC/DC
4000 FO2
Figure 2. Input Current Regulation Loop
Battery Charger Overview In addition to the input current regulation loop, the LTC4000 regulates charge current, battery voltage and output voltage. When a battery charge cycle begins, the battery charger first determines if the battery is over-discharged. If the battery feedback voltage is below VLOBAT, an automatic trickle charge feature uses the charge current regulation loop to set the battery charge current to 10% of the programmed full scale value. If the TMR pin is connected to a capacitor or open, the bad battery detection timer is enabled. When this bad battery detection timer expires and the battery voltage is still below VLOBAT, the battery charger automatically terminates and indicates, via the FLT and CHRG pins, that the battery was unresponsive to charge current.
14
LTC4000 operaTion
Charge Current Regulation The first loop involved in a normal charging cycle is the charge current regulation loop (Figure 3). As with the input current regulation loop, this loop also drives the ITH and CC pins. This loop ensures that the charge current sensed through the charge current sense resistor (RCS) does not exceed the programmed full charge current.
CSP CCSP CSP CSN A9 gm = 0.33m 60k BIAS 50µA AT NORMAL 1V 5µA AT TRICKLE CL
4000 FO3
BAT RBFB1 RBFB2 BFB FBG 1.136V
LTC4000
CC CC
+ –
A6
– +
ITH
RC TO DC/DC
4000 FO4
Figure 4. Battery Float Voltage Regulation Loop with FBG
LTC4000
RIS
TO SYSTEM BAT PMOS ROFB1 LTC4000 ROFB2 CSP OFB FBG 1.193V CC CC
+ –
+ –
A7
– +
ITH
RC TO DC/DC
IBMON CIBMON (OPTIONAL)
CC
+ – –
CC
4000 FO5
A5
– +
ITH
RC TO DC/DC
Figure 5. Output Voltage Regulation Loop with FBG
RCL
Battery Instant-On and Ideal Diode The LTC4000 controls the external PMOS connected to the BGATE pin with a controller similar to the input ideal diode controller driving the IGATE pin. When not charging, the PMOS behaves as an ideal diode between the BAT (anode) and the CSN (cathode) pins. The controller (A2) regulates the external PMOS to achieve low loss conduction by driving the gate of the PMOS device such that the voltage drop from the BAT pin to the CSN pin is 8mV. When the ability to deliver a particular current with an 8mV drop across the PMOS source and drain is exceeded, the voltage at the gate clamps at VBGATE(ON) and the PMOS behaves like a fixed value resistor (RDS(ON)). The ideal diode behavior allows the battery to provide current to the load when the input supply is in current limit or the DC/DC converter is slow to react to an immediate load increase at the output. In addition to the ideal diode behavior, BGATE also allows current to flow from the CSN pin to the BAT pin during charging. There are two regions of operation when current is flowing from the CSN pin to the BAT pin. The first is when charging into a battery whose voltage is below the instant-on threshold (VOFB < VOUT(INST_ON)). In this region of operation, the controller regulates the voltage at the CSP pin
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Figure 3. Charge Current Regulation Loop
Battery Voltage Regulation Once the float voltage is reached, the battery voltage regulation loop takes over from the charge current regulation loop (Figure 4). The float voltage level is programmed using the feedback resistor divider between the BAT pin and the FBG pin with the center node connected to the BFB pin. Note that the ground return of the resistor divider is connected to the FBG pin. The FBG pin disconnects the resistor divider load when VIN < 3V to ensure that the float voltage resistor divider does not consume battery current when the battery is the only available power source. For VIN ≥ 3V, the typical resistance from the FBG pin to GND is 100Ω. Output Voltage Regulation When charging terminates and the system load is completely supplied from the input, the PMOS connected to BGATE is turned off. In this scenario, the output voltage regulation loop takes over from the battery float voltage regulation loop (Figure 5). The output voltage regulation loop regulates the voltage at the CSP pin such that the output feedback voltage at the OFB pin is 1.193V.
15
LTC4000 operaTion
to be approximately 86% of the final float voltage level (VOUT(INST_ON)). This feature provides a CSP voltage significantly higher than the battery voltage when charging into a heavily discharged battery. This instant-on feature allows the LTC4000 to provide sufficient voltage at the output (CSP pin), independent of the battery voltage. The second region of operation is when the battery feedback voltage is greater than or equal to the instant-on threshold (VOUT(INST_ON)). In this region, the BGATE pin is driven low and clamped at VBGATE(ON) to allow the PMOS to turn completely on, reducing any power dissipation due to the charge current. Battery Temperature Qualified Charging The battery temperature is measured by placing a negative temperature coefficient (NTC) thermistor close to the battery pack. The comparators CP3 and CP4 implement the temperature detection as shown in the Block Diagram in Figure 1. The rising threshold of CP4 is set at 75% of VBIAS (cold threshold) and the falling threshold of CP3 is set at 35% of VBIAS (hot threshold). When the voltage at the NTC pin is above 75% of VBIAS or below 35% of VBIAS then the LTC4000 pauses any charge cycle in progress. When the voltage at the NTC pin returns to the range of 40% to 70% of VBIAS, charging resumes. When charging is paused, the external charging PMOS turns off and charge current drops to zero. If the LTC4000 is charging in the constant voltage mode and the charge termination timer is enabled, the timer pauses until the thermistor indicates a return to a valid temperature. If the battery charger is in the trickle charge mode and the bad battery detection timer is enabled, the bad battery timer pauses until the thermistor indicates a return to a valid temperature. Input UVLO and Voltage Monitoring The regulated voltage on the BIAS pin is available as soon as VIN ≥ 3V. When VIN ≥ 3V, the FBG pin is pulled low to GND with a typical resistance of 100Ω and the rest of the chip functionality is enabled. When the IN pin is high impedance and a battery is connected to the BAT pin, the BGATE pin is pulled down with a 2μA (typical) current source to hold the battery PMOS gate voltage at VBGATE(ON) below VBAT. This allows the battery to power the output. The total quiescent current consumed by LTC4000 from the battery when IN is not valid is typically ≤ 10µA. Besides the internal input UVLO, the LTC4000 also provides voltage monitoring through the VM pin. The RST pin is pulled low when the voltage on the VM pin falls below 1.193V (typical). On the other hand, when the voltage on the VM pin rises above 1.233V (typical), the RST pin is high impedance. One common use of this voltage monitoring feature is to ensure that the converter is turned off when the voltage at the input is below a certain level. In this case, connect the RST pin to the DC/DC converter chip select or enable pin (see Figure 6).
RIS DC/DC CONVERTER EN RST CP1
IN
IN
RVM1 VM RVM2
IN
CLN
– +
1.193V
LTC4000
4000 FO6
Figure 6. Input Voltage Monitoring with RST Connected to the EN Pin of the DC/DC Converter
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LTC4000 applicaTions inForMaTion
Input Ideal Diode PMOS Selection The input external PMOS is selected based on the expected maximum current, power dissipation and reverse voltage drop. The PMOS must be able to withstand a gate to source voltage greater than VIGATE(ON) (15V maximum) or the maximum regulated voltage at the IID pin, whichever is less. A few appropriate external PMOS for a number of different requirements are shown at Table 1.
Table 1. PMOS
PART NUMBER SiA923EDJ Si9407BDY Si4401BDY Si4435DDY SUD19P06-60 Si7135DP RDS(ON) AT VGS = 10V (Ω) 0.054 0.120 0.014 0.024 0.060 0.004 MAX ID (A) 4.5 4.7 10.5 11.4 18.3 60 MAX VDS (V) MANUFACTURER –20 –60 –40 –30 –60 –30 Vishay Vishay Vishay Vishay Vishay Vishay
The input current through the sense resistor is available for monitoring through the IIMON pin. The voltage on the IIMON pin varies with the current through the sense resistor as follows:
VIIMON = 20 • IRIS • RIS = 20 • ( VIN – VCLN )
The regulation voltage level at the IIMON pin is clamped at 1V with an accurate internal reference. At 1V on the IIMON pin, the input current limit is regulated at the following value:
IILIM(MAX)(A) = 0.050V RIS (Ω)
When this maximum current limit is desired, leave the IL pin open or set it to a voltage >1.05V such that amplifier A4 can regulate the IIMON voltage accurately to the internal reference of 1V. If the input current is noisy, add a filter capacitor to the CLN pin to reduce the AC content. For example, when using a buck DC/DC converter, the use of a CCLN capacitor is strongly recommended. Where the highest accuracy is important, pick the value of CCLN such that the AC content is less than or equal to 50% of the average voltage across the sense resistor. The voltage on the IIMON pin can be filtered further by putting a capacitor on the pin (CIIMON). The voltage on the IIMON pin is also the feedback input to the input current regulation error amplifier. Any capacitor connected to this pin places a pole in the input current regulation loop. Therefore, this filter capacitor should NOT be arbitrarily large as it will slow down the overall compensated loop. For details on loop compensation please refer to the Compensation section.
Note that in general the larger the capacitance seen on the IGATE pin, the slower the response of the ideal diode driver. The fast turn off and turn on current is limited to –0.5mA and 0.7mA typical respectively (IIGATE(FASTOFF) and IIGATE(FASTON)). If the driver can not react fast enough to a sudden increase in load current, most of the extra current is delivered through the body diode of the external PMOS. This increases the power dissipation momentarily. It is important to ensure that the PMOS is able to withstand this momentary increase in power dissipation. Input Current Limit Setting and Monitoring The regulated input current limit is set using a resistor at the IL pin according to the following formula:
RIS = VIL 20 • IILIM
where VIL is the voltage on the IL pin. The IL pin is internally pulled up with an accurate current source of 50µA. Therefore an equivalent formula to obtain the input current limit is: RIL = ILIM • RIS R ⇒ IILIM = IL • 2.5µA 2.5µA RIS
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LTC4000 applicaTions inForMaTion
Charge Current Limit Setting and Monitoring The regulated full charge current is set according to the following formula:
RCS VCL = 20 • ICLIM
current regulation loop. For details on the loop compensation, refer to the Compensation section. Battery Float Voltage Programming When the value of RBFB1 is much larger than 100Ω, the final float voltage is determined using the following formula: ⎛V ⎞ RBFB1 = ⎜ FLOAT – 1⎟RBFB2 ⎝ 1.136V ⎠ When higher accuracy is important, a slightly more accurate final float voltage can be determined using the following formula:
where VCL is the voltage on the CL pin. The CL pin is internally pulled up with an accurate current source of 50µA. Therefore, an equivalent formula to obtain the input current limit is: RCL •R I R = CLIM CS ⇒ ICLIM = CL • 2.5µA 2.5µA RCS
The charge current through the sense resistor is available for monitoring through the IBMON pin. The voltage on the IBMON pin varies with the current through the sense resistor as follows:
VIBMON = 20 • IRCS • RCS = 20 • ( VCSP – VCSN )
⎛R ⎞ ⎛R ⎞ +R VFLOAT = ⎜ BFB1 BFB2 • 1.136V ⎟ – ⎜ BFB1 • VFBG ⎟ RBFB2 ⎝ ⎠ ⎝ RBFB2 ⎠
where VFBG is the voltage at the FBG pin during float voltage regulation, which accounts for all the current from all resistor dividers that are connected to this pin (RFBG = 100Ω typical). Low Battery Trickle Charge Programming and Bad Battery Detection When charging into an over-discharged or dead battery (VBFB < VLOBAT), the pull-up current at the CL pin is reduced to 10% of the normal pull-up current. Therefore, the trickle charge current is set using the following formula: RCL = ICLIM(TRKL) • RCS 0.25µA ⇒ ICLIM(TRKL) = 0.25µA • RCL RCS
Similar to the IIMON pin, the regulation voltage level at the IBMON pin is clamped at 1V with an accurate internal reference. At 1V on the IBMON pin, the charge current limit is regulated to the following value:
0.050V ICLIM(MAX)(A) = RCS (Ω)
When this maximum charge current limit is desired, leave the CL pin open or set it to a voltage >1.05V such that amplifier A5 can regulate the IBMON pin voltage accurately to the internal reference of 1V. When the output current waveform of the DC/DC converter or the system load current is noisy, it is recommended that a capacitor is connected to the CSP pin (CCSP). This is to reduce the AC content of the current through the sense resistor (RCS). Where the highest accuracy is important, pick the value of CCSP such that the AC content is less than or equal to 50% of the average voltage across the sense resistor. Similar to the IIMON pin, the voltage on the IBMON pin is filtered further by putting a capacitor on the pin (CIBMON). This filter capacitor should not be arbitrarily large as it will slow down the overall compensated charge
Therefore, when 50µA•RCL is less than 1V, the following relation is true: ICLIM(TRKL) = ICLIM 10
Once the battery voltage rises above the low battery voltage threshold, the charge current level rises from the trickle charge current level to the full charge current level. The LTC4000 also features bad battery detection. This detection is disabled if the TMR pin is grounded or tied to BIAS. However, when a capacitor is connected to the
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LTC4000 applicaTions inForMaTion
TMR pin, a bad battery detection timer is started as soon as trickle charging starts. If at the end of the bad battery detection time the battery voltage is still lower than the low battery threshold, charging is terminated and the part indicates a bad battery condition by pulling the FLT pin low and leaving the CHRG pin high impedance. The bad battery detection time can be programmed according to the following formula:
CTMR (nF) = tBADBAT (h) • 138.5
For example, a typical capacitance of 1nF requires a capacitor greater than 100nF connected to the CX pin to ensure proper C/X termination behavior. If a capacitor is connected to the TMR pin, as soon as the constant voltage charging is achieved, a charge termination timer is started. When the charge termination timer expires, the charge cycle terminates. The total charge termination time can be programmed according to the following formula:
CTMR (nF) = t TERMINATE (h) • 34.6
Note that once a bad battery condition is detected, the condition is latched. In order to re-enable charging, remove the battery and connect a new battery whose voltage causes BFB to rise above the recharge battery threshold (VRECHRG(RISE)). Alternatively toggle the ENC pin or remove and reapply power to IN. C/X Detection, Charge Termination and Automatic Recharge Once the constant voltage charging is reached, there are two ways in which charging can terminate. If the TMR pin is tied to BIAS, the battery charger terminates as soon as the charge current drops to the level programmed by the CX pin. The C/X current termination level is programmed according to the following formula:
RCX = IC/ X • RCS (0.25µA • RCX ) − 0.5mV + 0.5mV ⇒ IC/X = 0.25µA RCS
If the TMR pin is grounded, charging never terminates and the battery voltage is held at the float voltage. Note that regardless of which termination behavior is selected, the CHRG and FLT pins will both assume a high impedance state as soon as the charge current falls below the programmed C/X level. After the charger terminates, the LTC4000 automatically restarts another charge cycle if the battery feedback voltage drops below 97.1% of the programmed final float voltage (VRECHRG(FALL)). When charging restarts, the CHRG pin pulls low and the FLT pin remains high impedance. Output Voltage Regulation Programming The output voltage regulation level is determined using the following formula: ⎛V ⎞ ROFB1 = ⎜ OUT − 1⎟ • ROFB2 ⎝ 1.193 ⎠ As in the battery float voltage calculation, when higher accuracy is important, a slightly more accurate output is determined using the following formula:
where RCS is the charge current sense resistor connected between the CSP and the CSN pins. When the voltage at BFB is higher than the recharge threshold (97.6% of float), the C/X comparator is enabled. In order to ensure proper C/X termination coming out of a paused charging condition, connect a capacitor on the CX pin according to the following formula: CCX = 100CBGATE where CBGATE is the total capacitance connected to the BGATE pin.
⎛R ⎞ ⎞ ⎛R +R VOUT = ⎜ OFB1 OFB2 • 1.193V ⎟ – ⎜ OFB1 • VFBG ⎟ ROFB2 ⎝ ⎠ ⎠ ⎝ ROFB2
where VFBG is the voltage at the FBG pin during output voltage regulation, which accounts for all the current from all resistor dividers that are connected to this pin.
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LTC4000 applicaTions inForMaTion
Battery Instant-On and Ideal Diode External PMOS Consideration The instant-on voltage level is determined using the following formula: ROFB1 + ROFB2 • 0.974V ROFB2 Note that ROFB1 and ROFB2 are the same resistors that program the output voltage regulation level. Therefore, the output voltage regulation level is always 122.5% of the instant-on voltage level. VOUT(INST _ ON) = During instant-on operation, it is critical to consider the charging PMOS power dissipation. When the battery voltage is below the low battery threshold (VLOBAT), the power dissipation in the PMOS can be calculated as follows:
PTRKL = [0.86 • VFLOAT – VBAT ] • ICLIM(TRKL)
On the other hand, when the battery voltage is above the low battery threshold but still below the instant-on threshold, the power dissipation can be calculated as follows:
PINST _ ON = [0.86 • VFLOAT – VBAT ] • ICLIM
where ICLIM is the full scale charge current limit. For example, when charging a 3-cell Lithium Ion battery with a programmed full charged current of 1A, the float voltage is 12.6V, the bad battery voltage level is 8.55V and the instant-on voltage level is 10.8V. During instant-on operation and in the trickle charge mode, the worst case maximum power dissipation in the PMOS is 1.08W. When the battery voltage is above the bad battery voltage level, then the worst case maximum power dissipation is 2.25W. When overheating of the charging PMOS is a concern, it is recommended that the user add a temperature detection circuit that pulls down on the NTC pin. This pauses charging whenever the external PMOS temperature is too high. A sample circuit that performs this temperature detection function is shown in Figure 7.
where ICLIM(TRKL) is the trickle charge current limit.
TO SYSTEM VISHAY CURVE 2 NTC RESISTOR THERMALLY COUPLED WITH CHARGING PMOS RNTC2 M2 R4 = RNTC2 AT 25°C
CSP LTC4000 CSN BGATE BAT RCS
BIAS R3 NTC Li-Ion BATTERY PACK RNTC1 CBIAS 2N7002L 162k
– +
LTC1540
RISING TEMPERATURE THRESHOLD SET AT 90°C 20k
VOLTAGE HYSTERESIS CAN BE PROGRAMMED FOR TEMPERATURE HYSTERESIS 86mV ≈ 10°C
4000 F07
Figure 7. Charging PMOS Overtemperature Detection Circuit Protecting PMOS from Overheating
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Similar to the input external PMOS, the charging external PMOS must be able to withstand a gate to source voltage greater than VBGATE(ON) (15V maximum) or the maximum regulated voltage at the CSP pin, whichever is less. Consider the expected maximum current, power dissipation and instant-on voltage drop when selecting this PMOS. The PMOS suggestions in Table 1 are an appropriate starting point depending on the application. Float Voltage, Output Voltage and Instant-On Voltage Dependencies The formulas for setting the float voltage, output voltage and instant-on voltage are repeated here: VFLOAT = VOUT RBFB1 + RBFB2 • 1.136V RBFB2 +R R = OFB1 OFB2 • 1.193V ROFB2 ROFB1 + ROFB2 • 0.974V ROFB2 In the typical application, VOUT is set higher than VFLOAT to ensure that the battery is charged fully to its intended float voltage. On the other hand, VOUT should not be programmed too high since VOUT(INST_ON), the minimum voltage on CSP depends on the same resistors ROFB1 and , ROFB2 that set VOUT. As noted before, this means that the output voltage regulation level is always 122.5% of the instant-on voltage. The higher the programmed value of VOUT(INST_ON), the larger the operating region when the charger PMOS is driven in the linear region where it is less efficient. If ROFB1 and ROFB2 are set to be equal to RBFB1 and RBFB2 respectively, then the output voltage is set at 105% of the float voltage and the instant-on voltage is set at 86% of the float voltage. Figure 8 shows the range of possible output voltages that can be set for VOUT(INST_ON) and VOUT with respect to VFLOAT to ensure the battery can be fully charged in an ideal scenario. Taking into account possible mismatches between the resistor dividers as well as mismatches in the various regulation loops, VOUT should not be programmed to be less than 105% of VFLOAT to ensure that the battery can be fully charged. This automatically means that the instant-on voltage level should not be programmed to be less than 86% of VFLOAT.
POSSIBLE OUTPUT VOLTAGE RANGE 105% 100% 100% 100% POSSIBLE INSTANT-ON VOLTAGE RANGE MINIMUM PRACTICAL OUTPUT VOLTAGE
VOUT(INST _ ON) =
NOMINAL OUTPUT VOLTAGE NOMINAL FLOAT VOLTAGE
NOMINAL INSTANT-ON VOLTAGE
86%
MINIMUM PRACTICAL INSTANT-ON VOLTAGE 81.6%
75%
4000 F08
Figure 8. Possible Voltage Ranges for VOUT and VOUT(INST_ON) in Ideal Scenario
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Battery Temperature Qualified Charging To use the battery temperature qualified charging feature, connect an NTC thermistor, RNTC, between the NTC pin and the GND pin, and a bias resistor, R3, from the BIAS pin to the NTC pin (Figure 9). Thermistor manufacturer datasheets usually include either a temperature lookup table or a formula relating temperature to the resistor value at that corresponding temperature.
BIAS LTC4000 NTC BAT NTC RESISTOR THERMALLY COUPLED WITH BATTERY PACK RNTC
4000 F09
Notice that with only one degree of freedom (i.e. adjusting the value of R3), the user can only use one of the formulas above to set either the cold or hot threshold but not both. If the value of R3 is set to adjust the cold threshold, the value of the NTC resistor at the hot threshold is then equal to 0.179 • RNTC at cold_threshold. Similarly, if the value of R3 is set to adjust the hot threshold, the value of the NTC resistor at the cold threshold is then equal to 5.571 • RNTC at cold_threshold. Note that changing the value of R3 to be larger than R25 will move both the hot and cold threshold lower and vice versa. For example, using a Vishay Curve 2 thermistor whose nominal value at 25°C is 100k, the user can set the cold temperature to be at 5°C by setting the value of R3 = 75k, which automatically then sets the hot threshold at approximately 50°C. It is possible to adjust the hot and cold threshold independently by introducing another resistor as a second degree of freedom (Figure 10). The resistor RD in effect reduces the sensitivity of the resistance between the NTC pin and ground. Therefore, intuitively this resistor will move the hot threshold to a hotter temperature and the cold threshold to a colder temperature.
BIAS LTC4000 NTC RD BAT NTC RESISTOR THERMALLY COUPLED WITH BATTERY PACK RNTC
4000 F10
R3
CBIAS
Figure 9. NTC Thermistor Connection
In a simple application, R3 is a 1% resistor with a value equal to the value of the chosen NTC thermistor at 25°C (R25). In this simple setup, the LTC4000 will pause charging when the resistance of the NTC thermistor drops to 0.54 times the value of R25. For a Vishay Curve 2 thermistor, this corresponds to approximately 41.5°C. As the temperature drops, the resistance of the NTC thermistor rises. The LTC4000 is also designed to pause charging when the value of the NTC thermistor increases to three times the value of R25. For a Vishay Curve 2 thermistor, this corresponds to approximately –1.5°C. With Vishay Curve 2 thermistor, the hot and cold comparators each have approximately 5°C of hysteresis to prevent oscillation about the trip point. The hot and cold threshold can be adjusted by changing the value of R3. Instead of simply setting R3 to be equal to R25, R3 is set according to one of the following formulas:
R3 = RNTC at cold_ threshold 3
R3
CBIAS
Figure 10. NTC Thermistor Connection with Desensitizing Resistor RD
or
R3 = 1.857 • RNTC at hot _ threshold
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The value of R3 and RD can now be set according to the following formula:
R at cold_ threshold – RNTC at hot _ threshold R3 = NTC 2.461 RD = 0.219 • RNTC at cold_ threshold – 1.219 • RNTC at hot _ threshold
The FLT and CHRG Indicator Pins The FLT and CHRG pins in the LTC4000 provide status indicators. Table 2 summarizes the mapping of the pin states to the part status.
Table 2. FLT and CHRG Status Indicator
FLT 0 1 0 1 CHRG 0 0 1 1 STATUS NTC Over Ranged – Charging Paused Charging Normally Charging Terminated and Bad Battery Detected VIBMON < (VC/X – 10mV)
Note the important caveat that this method can only be used to desensitize the thermal effect on the thermistor and hence push the hot and cold temperature thresholds apart from each other. When using the formulas above, if the user finds that a negative value is needed for RD, the two temperature thresholds selected are too close to each other and a higher sensitivity thermistor is needed. For example, this method can be used to set the hot and cold thresholds independently to 60°C and –5°C. Using a Vishay Curve 2 thermistor whose nominal value at 25°C is 100k, the formula results in R3 = 130k and RD = 41.2k for the closest 1% resistors values. To increase thermal sensitivity such that the valid charging temperature band is much smaller than 40°C, it is possible to put a PTC (positive thermal coefficient) resistor in series with R3 between the BIAS pin and the NTC pin. This PTC resistor also needs to be thermally coupled with the battery. Note that this method increases the number of thermal sensing connections to the battery pack from one wire to three wires. The exact value of the nominal PTC resistor required can be calculated using a similar method as described above, keeping in mind that the threshold at the NTC pin is always 75% and 35% of VBIAS. Leaving the NTC pin floating or connecting it to a capacitor disables all NTC functionality.
where 1 indicates a high impedance state and 0 indicates a low impedance pull-down state. Note that VIBMON < (VCX – 10mV) corresponds to charge termination only if the C/X termination is selected. If the charger timer termination is selected, constant voltage charging may continue for the remaining charger timer period even after the indicator pins indicate that VIBMON < (VCX – 10mV). This is also true when no termination is selected, constant voltage charging will continue even after the indicator pins indicate that VIBMON < (VCX – 10mV). The BIAS Pin For ease of use the LTC4000 provides a low dropout voltage regulator output on the BIAS pin. Designed to provide up to 0.5mA of current at 2.9V, this pin requires at least 470nF of low ESR bypass capacitance for stability. Use the BIAS pin as the pull-up source for the NTC resistor networks, since the internal reference for the NTC circuitry is based on a ratio of the voltage on the BIAS pin. Furthermore, various 100k pull-up resistors can be conveniently connected to the BIAS pin.
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Setting the Input Voltage Monitoring Resistor Divider The falling threshold voltage level for this monitoring function can be calculated as follows: ⎛V ⎞ RVM1 = ⎜ VM _ RST – 1⎟ • R VM2 ⎝ 1.193V ⎠ where RVM1 and RVM2 form a resistor divider connected between the monitored voltage and GND, with the center tap point connected to the VM pin as shown in Figure 6. The rising threshold voltage level can be calculated similarly. Compensation In order for the LTC4000 to control the external DC/DC converter, it has to be able to overcome the sourcing bias current of the ITH or VC pin of the DC/DC converter. The typical sinking capability of the LTC4000 at the ITH pin is 1mA at 0.4V with a maximum voltage range of 0V to 6V. It is imperative that the local feedback of the DC/DC converter be set up such that during regulation of any of the LTC4000 loops this local loop is out of regulation and sources as much current as possible from its ITH/VC pin. For example for a DC/DC converter regulating its output voltage, it is recommended that the converter feedback divider is programmed to be greater than 110% of the output voltage regulation level programmed at the OFB pin. There are four feedback loops to consider when setting up the compensation for the LTC4000. As mentioned before these loops are: the input current loop, the charge current loop, the float voltage loop and the output voltage loop. All of these loops have an error amp (A4-A7) followed by another amplifier (A10) with the intermediate node driving the CC pin and the output of A10 driving the ITH pin as shown in Figure 11. The most common compensation network of a series capacitor (CC) and resistor (RC) between the CC pin and the ITH pin is shown here. Each of the loops has slightly different dynamics due to differences in the feedback signal path. The analytic description of each of the loops is included in the Appendix section. In most situations, an alternative empirical approach to compensation, as described here, is more practical.
A4-A7 gm4-7 = 0.2m LTC4000 A10 gm10 = 0.1m CC CC RC
+ –
RO4-7
– +
ITH RO10
4000 F11
Figure 11. Error Amplifier Followed by Output Amplifier Driving CC and ITH Pins
Empirical Loop Compensation Based on the five analytical expressions given in the Appendix section, and the transfer function from the ITH pin to the input and output current of the external DC/DC converter, the user can analytically determine the complete loop transfer function of each of the loops. Once these are obtained, it is a matter of analyzing the gain and phase bode plots to ensure that there is enough phase and gain margin at unity crossover with the selected values of RC and CC for all operating conditions. Even though it is clear that an analytical compensation method is possible, sometimes certain complications render this method difficult to tackle. These complications include the lack of easy availability of the switching converter transfer function from the ITH or VC control node to its input or output current, and the variability of parameter values of the components such as the ESR of the output capacitor or the RDS(ON) of the external PFETs. Therefore a simpler and more practical way to compensate the LTC4000 is provided here. This empirical method involves injecting an AC signal into the loop, observing the loop transient response and adjusting the CC and RC values to quickly iterate towards the final values. Much of the detail of this method is derived from Application Note 19 which can be found at www.linear.com using AN19 in the search box. Figure 12 shows the recommended setup to inject an AC-coupled output load variation into the loop. A function generator with 50Ω output impedance is coupled through a 50Ω/1000µF series RC network to the regulator output.
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SWITCHING CONVERTER GND ITH RC CC CLN ITH LTC4000 IN GND BAT BGATE VIN 50 GENERATOR f = 50Hz
4000 F12
1k
10k 0.015µF 1500pF SCOPE GROUND CLIP
A
B
IOUT
50 1W 1000µF (OBSERVE POLARITY)
CC
CSP
CSN
Figure 12. Empirical Loop Compensation Setup
Generator frequency is set at 50Hz. Lower frequencies may cause a blinking scope display and higher frequencies may not allow sufficient settling time for the output transient. Amplitude of the generator output is typically set at 5VP-P to generate a 100mAP-P load variation. For lightly loaded outputs (IOUT < 100mA), this level may be too high for small signal response. If the positive and negative transition settling waveforms are significantly different, amplitude should be reduced. Actual amplitude is not particularly important because it is the shape of the resulting regulator output waveform which indicates loop stability. A 2-pole oscilloscope filter with f = 10kHz is used to block switching frequencies. Regulators without added LC output filters have switching frequency signals at their outputs which may be much higher amplitude than the low frequency settling waveform to be studied. The filter frequency is high enough for most applications to pass the settling waveform with no distortion. Oscilloscope and generator connections should be made exactly as shown in Figure 12 to prevent ground loop errors. The oscilloscope is synced by connecting the channel B probe to the generator output, with the ground clip
of the second probe connected to exactly the same place as channel A ground. The standard 50Ω BNC sync output of the generator should not be used because of ground loop errors. It may also be necessary to isolate either the generator or oscilloscope from its third wire (earth ground) connection in the power plug to prevent ground loop errors in the scope display. These ground loop errors are checked by connecting channel A probe tip to exactly the same point as the probe ground clip. Any reading on channel A indicates a ground loop problem. Once the proper setup is made, finding the optimum values for the frequency compensation network is fairly straightforward. Initially, CC is made large (≥1μF) and RC is made small (≈10k). This nearly always ensures that the regulator will be stable enough to start iteration. Now, if the regulator output waveform is single-pole over damped (see the waveforms in Figure 13), the value of CC is reduced in steps of about 2:1 until the response becomes slightly under damped. Next, RC is increased in steps of 2:1 to introduce a loop zero. This will normally improve damping and allow the value of CC to be further reduced. Shifting back and forth between RC and CC variations will allow one to quickly find optimum values.
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LTC4000 applicaTions inForMaTion
GENERATOR OUTPUT
REGULATOR OUTPUT WITH LARGE CC, SMALL RC
WITH REDUCED CC, SMALL RC EFFECT OF INCREASED RC FURTHER REDUCTION IN CC MAY BE POSSIBLE IMPROPER VALUES WILL CAUSE OSCILLATIONS
problems on startup or short circuit recovery. To guarantee acceptable loop stability under all conditions, the initial values chosen for RC and CC should be checked under all conditions of input voltage and load current. The simplest way of accomplishing this is to apply load currents of minimum, maximum and several points in between. At each load current, input voltage is varied from minimum to maximum while observing the settling waveform. If large temperature variations are expected for the system, stability checks should also be done at the temperature extremes. There can be significant temperature variations in several key component parameters which affect stability; in particular, input and output capacitor value and their ESR, and inductor permeability. The external converter parametric variations also need some consideration especially the transfer function from the ITH/VC pin voltage to the output variable (voltage or current). The LTC4000 parameters that vary with temperature include the transconductance and the output resistance of the error amplifiers (A4-A7). For modest temperature variations, conservative over damping under worst-case room temperature conditions is usually sufficient to guarantee adequate stability at all temperatures. One measure of stability margin is to vary the selected values of both RC and CC by 2:1 in all four possible combinations. If the regulator response remains reasonably well damped under all conditions, the regulator can be considered fairly tolerant of parametric variations. Any tendency towards an under damped (ringing) response indicates that a more conservative compensation may be needed.
4000 F13
Figure 13. Typical Output Transient Response at Various Stability Level
If the regulator response is under damped with the initial large value of CC, RC should be increased immediately before larger values of CC are tried. This will normally bring about the over damped starting condition for further iteration. The optimum values for RC and CC normally means the smallest value for CC and the largest value for RC which still guarantee well damped response, and which result in the largest loop bandwidth and hence loop settling that is as rapid as possible. The reason for this approach is that it minimizes the variations in output voltage caused by input ripple voltage and output load transients. A switching regulator which is grossly over damped will never oscillate, but it may have unacceptably large output transients following sudden changes in input voltage or output loading. It may also suffer from excessive overshoot
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DESIGN EXAMPLE In this design example, the LTC4000 is paired with the LT3845 buck converter to create a 10A, 3-cell LiFePO4 battery charger. The circuit is shown on the front page and is repeated here in Figure 14. • The input voltage monitor falling threshold is set at 14.3V according to the following formula: ⎛ 14.3V ⎞ RVM1 = ⎜ − 1⎟ • 100kΩ ≈ 1.10MΩ ⎝ 1.193V ⎠ • The IL pin is left open such that the voltage on this pin is >1.05V. The regulation voltage on the IIMON pin is clamped at 1.0V with an accurate internal reference. Therefore, the input current limit is set at 10A according to the following formula: • RCL is set at 24.9kΩ such that the voltage at the CL pin is 1.25V. Similar to the IIMON pin, the regulation voltage on the IBMON pin is clamped at 1V with an accurate internal reference. Therefore, the charge current limit is set at 10A according to the following formula: ICLIM(MAX) = 0.050V 0.050V = = 10A RCS 5mΩ
• The trickle charge current level is consequently set at 1.25A, according to the following formula: ICLIM(TRKL) = 0.25µA • 24.9kΩ = 1.25A 5mΩ
• The battery float voltage is set at 10.8V according to the following formula: ⎞ ⎛ 10.8 RBFB1 = ⎜ − 1⎟ • 133kΩ ≈ 1.13MΩ ⎝ 1.136 ⎠ • The bad battery detection time is set at 43 minutes according to the following formula:
CTMR (nF) = tBADBAT (h) • 138.5 = 43 • 138.5 = 100nF 60
R IS =
0.050V = 5mΩ 10A
15V TO 60V
5m
IN
LT3845 SHDN VC 14.7k RST CLN IN ITH
OUT 100µF 47nF CC
Si7135DP
12V, 15A 1.15M 5m Si7135DP
IID IGATE CSP
CSN BGATE BAT OFB 127k FBG 133k BFB NTC 1.13M 10k
1.10M
1µF VM LTC4000
100k
3.0V
ENC CHRG FLT IIMON IBMON 10nF TMR IL 0.1µF
10.8V FLOAT 10A MAX CHARGE CURRENT 3-CELL Li-Ion BATTERY PACK
10nF
CL 22.1k
CX 22.1k
GND BIAS 1µF
10k
NTHS0603 N02N1002J
4000 F14
Figure 14. 48V to 10.8V at 10A Buck Converter Charger for Three LiFePO4 Cells
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• The charge termination time is set at 2.9 hours according to the following formula:
CTMR (nF) = t TERMINATE (h) • 34.6 = 2.9 • 34.6 = 100nF
• The C/X current termination level is programmed at 1A according to the following formula: 0.25µA Note that in this particular solution, the timer termination is selected since a capacitor connects to the TMR pin. Therefore, this C/X current termination level only applies to the CHRG indicator pin. • The output voltage regulation level is set at 12V according to the following formula: ⎞ ⎛ 12 ROFB1 = ⎜ − 1⎟ • 127kΩ ≈ 1.15MΩ ⎝ 1.193 ⎠ • The instant-on voltage level is consequently set at 9.79V according to the following formula: RCX =
• The range of valid temperature for charging is set at –1.5°C to 41.5°C by picking a 10k Vishay Curve 2 NTC thermistor that is thermally coupled to the battery, and connecting this in series with a regular 10k resistor to the BIAS pin. • For compensation, the procedure described in the empirical loop compensation section is followed. As recommended, first a 1µF CC and 10k RC is used, which sets all the loops to be stable. For an example of typical transient responses, the charge current regulation loop when VOFB is regulated to VOUT(INST_ON) is used here. Figure 15 shows the recommended setup to inject a DC-coupled charge current variation into this particular loop. The input to the CL pin is a square wave at 70Hz with the low level set at 120mV and the high level set at 130mV, corresponding to a 1.2A and 1.3A charge current (100mA charge current step). Therefore, in this particular example the trickle charge current regulation stability is examined. Note that the nominal trickle charge current in this example is programmed at 1.25A (RCL = 24.9kΩ).
(1A • 5mΩ) + 0.5mV ≈ 22.1kΩ
VINST _ ON =
1150kΩ + 127kΩ • 0.974V = 9.79V 127kΩ
B A 10k 1500pF 1k 0.015µF LTC4000 CL SQUARE WAVE GENERATOR f = 60Hz
4000 F15
The worst-case power dissipation during instant-on operation can be calculated as follows: • During trickle charging:
PTRKL = [0.86 • VFLOAT – VBAT ] • ICLIM _ TRKL = [0.86 • 10.8] • 1A = 9.3W
IBMON
• And beyond trickle charging:
PINST _ ON = [0.86 • VFLOAT – VBAT ] • ICLIM = [0.86 • 10.8 – 7.33] • 10A = 19.3W
Figure 15. Charge Current Regulation Loop Compensation Setup
Therefore, depending on the layout and heat sink available to the charging PMOS, the suggested PMOS over temperature detection circuit included in Figure 7 may need to be included. For the complete application circuit, please refer to Figure 25.
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With CC = 1µF RC = 10k at VIN = 20V, VBAT = 7V, VCSP , regulated at 9.8V and a 0.2A output load condition at CSP the transient response for a 100mA charge current , step observed at IBMON is shown in Figure 16.
15 10 VIBMON (mV) 5mV/DIV 5 VIBMON (mV) 5mV/DIV –5 5 0 5ms/DIV 10 15 20 25
4000 F16
The transient response now indicates an overall under damped system. As noted in the empirical loop compensation section, the value of RC is now increased iteratively until RC = 20k. The transient response of the same loop with CC = 22nF and RC = 20k is shown in Figure 18.
15 10 5 0 –5 –10 –15 –20 –15 –10 –5 5 0 5ms/DIV 10 15 20 25
0 –5 –10 –15 –20 –15 –10
Figure 16. Transient Response of Charge Current Regulation Loop Observed at IBMON When VOFB is Regulated to VOUT(INST_ON) with CC = 1µF RC = 10k for a 100mA Charge Current Step ,
4000 F18
The transient response shows a small overshoot with slow settling indicating a fast minor loop within a well damped overall loop. Therefore, the value of CC is reduced itera. tively until CC = 22nF The transient response of the same loop with CC = 22nF and RC = 10k is shown in Figure 17.
15 10 VIBMON (mV) 5mV/DIV 5 0 –5 –10 –15 –20 –15 –10 –5 5 0 5ms/DIV 10 15 20 25
Figure 18. Transient Response of Charge Current Regulation Loop Observed at IBMON When VOFB is Regulated to VOUT(INST_ON) with CC = 22nF RC = 20k for a 100mA Charge Current Step ,
Note that the transient response is close to optimum with some overshoot and fast settling. If after iteratively increasing the value of RC, the transient response again indicates an over damped system, the step of reducing CC can be repeated. These steps of reducing CC followed by increasing RC can be repeated continuously until one arrives at a stable loop with the smallest value of CC and the largest value of RC. In this particular example, these values are found to be CC = 22nF and RC = 20kΩ. After arriving at these final values of RC and CC, the stability margin is checked by varying the values of both RC and CC by 2:1 in all four possible combinations. After which the setup condition is varied, including varying the input voltage level and the output load level and the transient response is checked at these different setup conditions. Once the desired responses on all different conditions are obtained, the values of RC and CC are noted.
4000 F17
Figure 17. Transient Response of Charge Current Regulation Loop Observed at IBMON When VOFB is Regulated to VOUT(INST_ON) with CC = 22nF RC = 10k for a 100mA Charge Current Step ,
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This same procedure is then repeated for the other four loops: the input current regulation, the output voltage regulation, the battery float voltage regulation and finally the charge current regulation when VOFB > VOUT(INST_ON). Note that the resulting optimum values for each of the loops may differ slightly. The final values of CC and RC are then selected by combining the results and ensuring the most conservative response for all the loops. This usually entails picking the largest value of CC and the smallest value of RC based on the results obtained for all the loops. In this particular example, the value of CC is finally set to 47nF and RC = 14.7kΩ. BOARD LAYOUT CONSIDERATIONS In the majority of applications, the most important parameter of the system is the battery float voltage. Therefore, the user needs to be extra careful when placing and routing the feedback resistor RBFB1 and RBFB2. In particular, the battery sense line connected to RBFB1 and the ground return line for the LTC4000 must be Kelvined back to where the battery output and the battery ground are located respectively. Figure 19 shows this Kelvin sense configuration. For accurate current sensing, the sense lines from RIS and RCS (Figure 19) must be Kelvined back all the way to the sense resistors terminals. The two sense lines of each resistor must also be routed close together and away from noise sources to minimize error. Furthermore, current filtering capacitors should be placed strategically to ensure that very little AC current is flowing through these sense resistors as mentioned in the applications section. The decoupling capacitors CIN and CBIAS must be placed as close to the LTC4000 as possible. This allows as short a route as possible from CIN to the IN and GND pins, as well as from CBIAS to the BIAS and GND pins. In a typical application, the LTC4000 is paired with an external DC/DC converter. The operation of this converter often involves high dV/dt switching voltage as well as high currents. Isolate these switching voltages and currents from the LTC4000 section of the board as much as possible by using good board layout practices. These include separating noisy power and signal grounds, having a good low impedance ground plane, shielding whenever necessary, and routing sensitive signals as short as possible and away from noisy sections of the board.
SWITCHING CONVERTER GND ITH RC CC ITH CLN RIS IN LTC4000 CC IID IGATE CSP RCS CSN BGATE BAT RBFB1 VIN GND BFB RBFB2 FBG
SYSTEM LOAD
4000 F19
Figure 19. Kelvin Sense Lines Configuration for LTC4000
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APPENDIX—THE LOOP TRANSFER FUNCTIONS When a series resistor (RC) and capacitor (CC) is used as the compensation network as shown in Figure 11, the transfer function from the input of A4-A7 to the ITH pin is simply as follows: The Input Current Regulation Loop The feedback signal for the input current regulation loop is the sense voltage across the input current sense resistor (RIS). This voltage is amplified by a factor of 20 and compared to the voltage on the IL pin by the transconductance error amplifier (A4). This amplifier then drives the output transconductance amplifier (A10) to appropriately adjust the voltage on the ITH pin driving the external DC/DC converter to regulate the input current across the sense resistor (RIS). This loop is shown in detail in Figure 20. The simplified loop transmission is:
⎤ ⎡⎛ 1⎞ CCs + 1⎥ ⎢ ⎜RC – ⎟ gm10 ⎠ VITH ⎥ ⎢⎝ (s) = gm4-7 ⎥ ⎢ RO4-7 • CCs VFB ⎥ ⎢ ⎦ ⎣
where gm4-7 is the transconductance of error amplifier A4A7, typically 0.5mA/V; gm10 is the output amplifier (A10) transconductance, RO4-7 is the output impedance of the error amplifier, typically 50mΩ; and RO10 is the effective output impedance of the output amplifier, typically 10mΩ with the ITH pin open circuit. Note this simplification is valid when gm10 • RO10 • RO4-7 • CC = AV10 • RO4-7 • CC is much larger than any other poles or zeroes in the system. Typically AV10 • RO4-7 = 5 • 1010 with the ITH pin open circuit. The exact value of gm10 and RO10 depends on the pull-up current and impedance connected to the ITH pin respectively. In most applications, compensation of the loops involves picking the right values of RC and CC. Aside from picking the values of RC and CC, the value of gm10 may also be adjusted. The value of gm10 can be adjusted higher by increasing the pull-up current into the ITH pin and its value can be approximated as:
gm10 I + 5µA = ITH 50mV
⎤ ⎡⎛ 1⎞ ⎢ ⎜RC – ⎟ CCs + 1⎥ gm10 ⎠ ⎝ ⎥• LIC (s) = gm4 ⎢ ⎥ ⎢ CCs ⎥ ⎢ ⎦ ⎣ ⎤ ⎡ 20R (R2 IS CIIMON s + 1) ⎥ • Gmip (s) ⎢ ⎢ (R1+ R2) CIIMONs + 1 ⎥ ⎦ ⎣
where Gmip(s) is the transfer function from VITH to the input current of the external DC/DC converter.
IN CIN IN R2 20k CLN A8 gm8 = 0.33m R1 60k 50µA 1V IL RIL
4000 F20
RIS
IIN
LTC4000
+ –
IIMON CIIMON
BIAS
A4 gm4 = 0.5m
CC A10 gm10 = 0.1m CC RC
The higher the value of gm10, the smaller the lower limit of the value of RC would be. This lower limit is to prevent the presence of the right half plane zero. Even though all the loops share this transfer function from the error amplifier input to the ITH pin, each of the loops has a slightly different dynamic due to differences in the feedback signal path.
+ – –
RO4
– +
RO10
ITH
Figure 20. Simplified Linear Model of the Input Current Regulation Loop
4000f
31
LTC4000 applicaTions inForMaTion
The Output Voltage Regulation Loop The feedback signal for the output voltage regulation loop is the voltage on the OFB pin, which is connected to the center node of the resistor divider between the output voltage (connected to CSP) and the FBG pin. This voltage is compared to an internal reference (1.193V typical) by the transconductance error amplifier A7. This amplifier then drives the output transconductance amplifier (A10) to appropriately adjust the voltage on the ITH pin driving the external DC/DC converter to regulate the output voltage observed by the OFB pin. This loop is shown in detail in Figure 21.
LTC4000 A10 gm10 = 0.1m CC CC ITH RO10 CSP OFB ROFB1 RC INPUT
The Battery Float Voltage Regulation Loop The battery float voltage regulation loop is very similar to the output float voltage regulation loop. Instead of observing the voltage at the OFB pin, the battery float voltage regulation loop observes the voltage at the BFB pin. One significant difference is that while the value of RL in the output voltage loop can vary significantly, the output resistance of the battery float voltage loop is a small constant value approximately equal to the sum of the on-resistance of the external PFET (RDS(ON)) and the series internal resistance of the battery (RBAT). This approximation is valid for any efficient system such that most of the output power from the battery is delivered to the system load and not dissipated on the battery internal resistance or the charging PFET on-resistance. For a typical system, minimum RL is at least five times larger than RDS(ON) + RBAT and RBFB is at least 106 times larger than RBAT. Figure 22 shows the detail of the battery float voltage regulation loop.
LTC4000 A10 gm10 = 0.1m CC CC ITH RO10 BAT BFB RBFB1 RCS RDS(ON) RBFB2 FBG RBAT RC INPUT
– +
+ –
Gmop(s) LOAD CL RL
A7 gm7 = 0.5m
RO7
+ –
1.193V FBG
ROFB2
INTERNALLY PULLED HIGH
4000 F21
– +
+ –
Gmop(s) LOAD CL RL
Figure 21. Simplified Linear Model of the Output Voltage Regulation Loop
A7 gm6 = 0.5m
The simplified loop transmission is as follows:
⎡⎛ ⎤ 1⎞ ⎢ ⎜R C – ⎟ CCs + 1⎥ gm10 ⎠ ⎝ ⎥• L OV (s) = gm7 ⎢ ⎢ ⎥ CCs ⎢ ⎥ ⎣ ⎦ ⎡R ⎤⎡ ⎤ RL OFB2 • ⎢ ⎥⎢ ⎥ • Gmo p (s) ⎣ R OFB ⎦ ⎣ RL • CL s + 1⎦
RO6
+ –
1.136V
INTERNALLY PULLED HIGH
4000 F22
Figure 22. Simplified Linear Model of the Battery Float Voltage Regulation Loop
where Gmop(s) is the transfer function from VITH to the output current of the external DC/DC converter, and ROFB = ROFB1 + ROFB2.
4000f
32
LTC4000 applicaTions inForMaTion
In Figure 22 the battery is approximated to be a signal ground in series with the internal battery resistance RBAT. Therefore, the simplified loop transmission is as follows: The Battery Charge Current Regulation Loop when VOFB > VOUT(INST_ON) In this operating region, the external charging PFET’s gate is driven low and clamped at VBGATE(ON). The detail of this loop is shown in Figure 23. The simplified loop transmission is:
⎤ ⎡⎛ 1⎞ ⎢ ⎜RC – ⎟ CCs + 1⎥ gm10 ⎠ ⎝ ⎥• LBV (s) = gm6 ⎢ ⎥ ⎢ CCs ⎥ ⎢ ⎦ ⎣ ⎡RBFB2 ⎤ ⎡ ⎤ RLB ⎢ ⎥•⎢ ⎥ • Gmop (s) ⎣ RBFB ⎦ ⎣RLB • CL s + 1⎦
where Gmop(s) is the transfer function from VITH to the output current of the external DC/DC converter, RBFB = RBFB1 + RBFB2, and RLB = RL//(RDS(ON) + RCS + RBAT) represents the effective output resistance from the LOAD node to GND. The Battery Charge Current Regulation Loop This final regulation loop combines certain dynamic characteristics that are found in all the other three loops. The feedback signal for this charge current regulation loop is the sense voltage across the charge current sense resistor (RCS). This voltage is amplified by a factor of 20 and compared to the voltage on the CL pin by the transconductance error amplifier (A5). In a familiar fashion, this amplifier drives the output transconductance amplifier (A10) to appropriately adjust the voltage on the ITH pin driving the external DC/DC converter to regulate the input current across the sense resistor (RCS). Due to the presence of the instant-on feature, description of the charge current regulation loop has to be divided into two separate operating regions. These regions of operation depend on whether the voltage on the OFB pin is higher or lower than the instant-on threshold (VOUT(INST_ON)).
⎤ ⎡⎛ 1⎞ ⎢ ⎜RC – ⎟ CCs + 1⎥ gm10 ⎠ ⎝ ⎥• LCC (s) = gm5 ⎢ ⎥ ⎢ CCs ⎥ ⎢ ⎦ ⎣ ⎡ (R2 • CIBMONs + 1) ⎤ RL 20RCS • ⎢ • ⎥• ⎥ ⎢ ⎣ (R1+ R2) CIBMONs + 1⎦ Rf + RL ⎤ ⎡ 1 ⎥ • Gmop (s) ⎢ ⎢ (RL Rf ) CL s + 1⎥ ⎦ ⎣
where Gmop(s) is the transfer function from VITH to the output current of the external DC/DC converter, Rf = RCS + RDS(ON) + RBAT, and RL//Rf represents the effective resistance value resulting from the parallel combination of RL and Rf.
RC CC
RO10
ITH A10 gm10 = 0.1m
CC
LTC4000
INPUT
+ –
– +
RO5 A5 gm5 = 0.5m A8 gm8 = 0.33m
Gmop(s)
CSP RCS
CL
RL
+ – –
BIAS 1V 50µA/ 5µA R1 60k CL RCL
R2 20k
+ –
CSN
RDS(ON) IBMON CIBMON BAT
4000 F23
RBAT
Figure 23. Simplified Linear Model of the Charge Current Regulation Loop with the External Charging PFET Driven On
4000f
33
LTC4000 applicaTions inForMaTion
The Battery Charge Current Regulation Loop when VOFB is Regulated to VOUT(INST_ON) When the battery voltage is below the instant-on level, the external charging PFET is driven linearly to regulate the voltage at the output (connected to the CSP pin). The output voltage is regulated such that the voltage at the OFB pin is equal to the instant-on threshold (VOUT(INST_ON)). If this external PFET regulation is fast compared to the unity crossover frequency of the battery charge current regulation loop, then the voltage at the output can be considered a small signal ground. However, in the LTC4000 the external PFET regulation is purposely made slow to allow for a broader selection of possible PFETs to be used. Therefore, the linear model of the PFET has to be included in the analysis of the charge current regulation loop. The detail of this loop is shown in Figure 24.
RC CC
The simplified loop transmission is:
⎡⎛ ⎤ 1⎞ ⎢ ⎜R C – ⎟ CCs + 1⎥ gm10 ⎠ ⎝ ⎥• L CC2 (s) = gm5 ⎢ ⎢ ⎥ CCs ⎢ ⎥ ⎣ ⎦ ⎡ (R2 • C ⎤ IBMONs + 1) 20R CS • ⎢ ⎥• ⎢ (R1 + R2 ) CIBMONs + 1⎥ ⎣ ⎦ ⎡ ⎤ 1 •⎢ ⎥• R fIDC + RL ⎣ (RL R fIDC ) CL s + 1⎦ ⎢ ⎥ RL ⎡ ⎤ Cg ⎢ ⎥ s+1 gmEXT ⎢ ⎥ • Gmo p (s) ⎢⎛R + R ⎥ ⎞ Cg BAT CS ⎢⎜ s + 1⎥ ⎟ ⎢ ⎥ ⎣ ⎝ R fIDC ⎠ gmEXT ⎦
RO10
ITH A10 gm10 = 0.1m
CC
LTC4000
INPUT
+ –
Gmop(s)
RO5
where Gmop(s) is the transfer function from VITH to the output current of the external DC/DC converter, gmEXT is the small signal transconductance of the output PFET, RflDC = RCS + 1/gmEXT + RBAT and RL//RflDC represents the effective resistance value resulting from the parallel combination of RL and RflDC.
RL
– +
A5 gm5 = 0.5m A8 gm8 = 0.33m
CSP RCS
CL
+ – –
BIAS 1V 50µA/ 5µA R1 60k CL RCL
R2 20k
+ –
CSN Cg
1 gmEXT RBAT
IBMON CIBMON
BAT
4000 F24
Figure 24. Simplified Linear Model of the Charge Current Regulation Loop with the External Charging PFET Linearly Regulated
4000f
34
LTC4000 Typical applicaTions
VIN 15V TO 60V 10A MAX 5m 2.2µF 47µF VIN TG SW CSS 1.5nF BURST_EN SYNC SGND LT3845A fSET 49.9k SENSE+ SHDN VC SENSE 14.7k RST CLN IN 1.10M 1µF VM 100k BZX84C3VO ENC CHRG FLT IIMON 10nF 10nF IBMON IL CL 24.9k TMR 0.1µF CX GND BIAS 22.1k 1µF 162k 10k V+ OUT LTC4000 BAT OFB 127k FBG 133k BFB NTC 1.13M ITH CC
–
BSC123NO8NS3
WÜRTH ELEKTRONIC 74435561100 10µH B160 3m 33µF ×3
Si7135DP
BG BSC123NO8NS3 0.1µF BOOST BAS521 VCC 1µF VFB 16.2k 182k
VOUT 12V, 15A
1.15M 1N4148
5m NTHS0603 N02N1002J IID IGATE CSP CSN BGATE 10nF Si7135DP
47nF
10k IN+ IN–
RNTC 2N7002L
3-CELL LiFePO4 BATTERY PACK NTHS0603 N02N1002J
20k
LTC1540 HYST REF V– GND
38.3k
1M
4000 F25
Figure 25. 48V to 10.8V at 10A Buck Converter 3-Cell LiFePO4 Battery Charger with 2.9h Termination Timer, 1.25A Trickle Charge Current and Charging PFET Thermal Protection
4000f
35
LTC4000 Typical applicaTions
VIN 6V TO 18V 15A MAX 3.3mΩ 150µF 22µF ×4 2.5mΩ PA1494.362NL 3.3µH 10Ω 10Ω SENSE+ INTVCC PLLINMODE 100k 4.7µF RUN SS 0.1µF FREQ GND INTVCC PGOOD LTC3786 1nF INTVCC
BSC027N04
SENSE– BOOST 0.1µF SW BG BSC027N04 BAS140W 22µF ×5 150µF
Si7135DP
VOUT 22V, 5A
1.87M
TG VBIAS VFB ITH 28.7k 22nF 12.1k
232k
10m
RST CLN IN 383k 1µF VM 100k ENC CHRG FLT IIMON 10nF 10nF IBMON IL CL
ITH
CC
IID
IGATE CSP CSN BGATE
10nF
Si7135DP
LTC4000
BAT OFB 107k FBG 107k BFB NTC
4000 F26
1.87M 5-CELL Li-Ion BATTERY PACK TENERGY SSIP PACK 30104
CX 10µF
GND BIAS
TMR
10k
22.1k
22.1k 1µF NTHS0603 N02N1002J
RNTC
Figure 26. 6V to 21V at 5A Boost Converter 5-Cell Li-Ion Battery Charger with C/10 Termination and 0.55A Trickle Charge Current
4000f
36
VIN 18V TO 72V
TR1 PA1277NL 20m
SiA923EDJ
VOUT
2.2µF ×2 MMBTA42 VCC 681Ω 309k 150k 1µF FDC2512 VCC GATE ISENSE LTC3805-5 0.04 13.6k ITH SYNC GND FB OC BAS516 ISO1 PS2801-1-K CC 24.9k BAS516 ITH RST FLT CHRG ENC FBG NTC IIMON IBMON IL CL 10nF 10nF TMR 100nF CX GND BIAS 10k RNTC LTC4000 BAT OFB 115k BFB 115k 309k 75k 47nF BGATE 10nF 1.5k VCC VOUT 3.01k CSP 150pF
VM IN CLN IID IGATE
221k
•
100µF ×3 PDS1040 100k 1µF
VSYS 4.4V, 2.5A
•
BAS516
Typical applicaTions
PDZ6.8B 6.8V
•
68Ω
221k
RUN
15.8k
25mΩ CSN SiA923EDJ
SSFLT
0.1µF
FS
SINGLE-CELL Li-Ion BATTERY PACK
22.1k
22.1k
1µF
NTHS0603 N02N1002J
4000 F27
Figure 27. 18V to 72VIN to 4.2V at 2.0A Isolated Flyback Single-Cell Li-Ion Battery Charger with 2.9h Timer Termination and 0.22A Trickle Charge Current
LTC4000
37
4000f
LTC4000 package DescripTion
(Reference LTC DWG # 05-08-1712 Rev B)
UFD Package 28-Lead Plastic QFN (4mm × 5mm)
0.70 ± 0.05
4.50 ± 0.05 3.10 ± 0.05 2.50 REF 2.65 ± 0.05 3.65 ± 0.05
PACKAGE OUTLINE
0.25 ± 0.05 0.50 BSC 3.50 REF 4.10 ± 0.05 5.50 ± 0.05 RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS APPLY SOLDER MASK TO AREAS THAT ARE NOT SOLDERED 4.00 ± 0.10 (2 SIDES) PIN 1 TOP MARK (NOTE 6) 0.75 ± 0.05 R = 0.05 TYP PIN 1 NOTCH R = 0.20 OR 0.35 × 45° CHAMFER 27 28 0.40 ± 0.10 1 2 5.00 ± 0.10 (2 SIDES)
2.50 REF R = 0.115 TYP
3.50 REF 3.65 ± 0.10 2.65 ± 0.10
(UFD28) QFN 0506 REV B
0.200 REF 0.00 – 0.05
0.25 ± 0.05 0.50 BSC BOTTOM VIEW—EXPOSED PAD
NOTE: 1. DRAWING PROPOSED TO BE MADE A JEDEC PACKAGE OUTLINE MO-220 VARIATION (WXXX-X). 2. DRAWING NOT TO SCALE 3. ALL DIMENSIONS ARE IN MILLIMETERS 4. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.15mm ON ANY SIDE 5. EXPOSED PAD SHALL BE SOLDER PLATED 6. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION ON THE TOP AND BOTTOM OF PACKAGE
4000f
38
LTC4000 package DescripTion
GN Package 28-Lead Plastic SSOP (Narrow .150 Inch)
(Reference LTC DWG # 05-08-1641)
.045 ± .005
.386 – .393* (9.804 – 9.982) 28 27 26 25 24 23 22 21 20 19 18 17 1615
.033 (0.838) REF
.254 MIN
.150 – .165
.229 – .244 (5.817 – 6.198)
.150 – .157** (3.810 – 3.988)
.0165 ± .0015 RECOMMENDED SOLDER PAD LAYOUT
.0250 BSC
1
.0532 – .0688 (1.35 – 1.75)
23
4
56
7
8
9 10 11 12 13 14
.004 – .0098 (0.102 – 0.249)
.015 ± .004 × 45° (0.38 ± 0.10)
.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)
.008 – .012 (0.203 – 0.305) TYP
.0250 (0.635) BSC
GN28 (SSOP) 0204
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
4000f
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.
39
LTC4000 Typical applicaTion
5.6 390pF IHLP6767GZ ER4R7M01 4.7µH 3.6 1800pF B240A Q5 Q3 0.22µF 0.01 330µF ×2 Si7135DP VOUT 15V, 5A B240A VIN 6V TO 36V 12.5A MAX 4m 270µF 0.22µF Q2 Q4
0.01 1.24k TG1 SW1 1.24k SW2 TG2 BOOST2 INTVCC
3.3µF ×5
BG1 SENSE+ SENSE– BG2
22µF ×2
BOOST1 DFLS160 INTVCC VIN 1µF VINSNS
DFLS160
10µF MODE/PLLIN LTC3789 100k IOSENSE+ IOSENSE– VOUTSNS EXTVCC VFB ITH SS SGND 0.01µF 10m 14.7k RST CLN IN ITH CC 100nF IID IGATE CSP CSN BGATE 10nF BAT OFB 26.7k FBG 118k IL CL 18.2k TMR 0.1µF CX 22.1k GND BIAS 10k BFB NTC
4000 F28
PGOOD
309k
121k FREQ ILIM RUN PGND1
BZT52C5V6 154k 10µF 8.06k
Si7135DP
365k
1µF VM LTC4000
100k
BZX84C3VO
ENC CHRG FLT IIMON 10nF 10nF IBMON
Q2: SiR422DP Q3: SiR496DP Q4: SiR4840BDY Q5: SiR496DP
1.37M RNTC 4-CELL LiFePO4 BATTERY PACK NTHS0603 N02N1002J
1µF
Figure 28. 6V to 36VIN to 14.4V at 4.5A Buck Boost Converter 4-Cell LiFePO4 Battery Charger with 2.9h Timer Termination and 0.45A Trickle Charge Current
relaTeD parTs
PART NUMBER LTC3789 LT3845 LT3650 LT3651 LT3652/LT3652HV LTC4009 LTC4012 LT3741 DESCRIPTION High Efficiency, Synchronous, 4 Switch Buck-Boost Controller High Voltage Synchronous Current Mode Step-Down Controller with Adjustable Operating Frequency High Voltage 2A Monolithic Li-Ion Battery Charger High Voltage 4A Monolithic Li-Ion Battery Charger Power Tracking 2A Battery Chargers High Efficiency, Multi-Chemistry Battery Charger High Power, Constant Current, Constant Voltage, Step-Down Controller COMMENTS Improved LTC3780 with More Features For Medium/High Power, High Efficiency Supplies 3mm × 3mm DFN-12 and MSOP-12 Packages 4A Synchronous Version of LT3650 Family Multi-Chemistry, Onboard Termination Low Cost Version of LTC4008, 4mm × 4mm QFN-20 Thermally Enhanced 4mm × 4mm QFN and 20-Pin TSSOP
4000f LT 0411 • PRINTED IN USA
High Efficiency, Multi-Chemistry Battery Charger with PowerPath Control Similar to LTC4009 Adding PowerPath Control
40 Linear Technology Corporation
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com
LINEAR TECHNOLOGY CORPORATION 2011