LTC4015
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APPLICATIONS
TYPICAL APPLICATION
FEATURES DESCRIPTION
Multichemistry Buck Battery Charger
Controller with Digital Telemetry System
12VIN 2-Cell Li-Ion 8A Step-Down Battery Charger Controller Step-Down Charger Efficiency and
Coulomb Counter Error vs
Battery Charge Current
L, LT, LTC , LT M, 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 Multichemistry Li-Ion/Polymer, LiFePO4, or Lead-
Acid Battery Charger with Termination
n High Efficiency Synchronous Buck Battery Charger
n Digital Telemetry System Monitors VBAT, IBAT ,
RBAT ,NTC Ratio (Battery Temperature), VIN, IIN,
VSYSTEM, Die Temperature
n Coulomb Counter and Integrated 14-Bit ADC
n Wide Charging Input Voltage Range: 4.5V to 35V
n Wide Battery Voltage Range: Up to 35V
n Input Undervoltage Charge Current Limit Loop
n Maximum Power Point Tracking
n Optional I2C Serial Port Control
n Input Current Limit Prioritizes System Load Output
n Input and Output Ideal Diodes Provide Low Loss
PowerPath™ Operation
n Instant-On Operation with Discharged Battery
n Portable Medical Instruments/Military Equipment
n Industrial Handhelds/Lighting
n Ruggedized Notebook/Tablet Computers
The LTC
®
4015 is a complete synchronous buck controller/
charger with pin-selectable, chemistry specific charging
and termination algorithms.
The LTC4015 can charge Li-Ion/Polymer, LiFePO4, or lead-
acid batteries. Battery charge voltage is pin selectable and
I2C adjustable. Input current limit and charge current can
be accurately programmed with sense resistors and can
be individually adjusted via the I2C serial port. A digital
telemetry system monitors all system power parameters.
Safety timer and current termination algorithms are sup-
ported for lithium chemistry batteries. The LTC4015 also
includes automatic recharge, precharge (Li-Ion) and NTC
thermistor protection. The LTC4015's I2C port allows user
customization of charger algorithms, reading of charger
status information, configuration of the maskable and
programmable alerts, plus use and configuration of the
Coulomb counter.
Available in a 38-Lead 5mm × 7mm QFN package.
CHARGE CURRENT (A)
EFFICIENCY (%)
COULOMB COUNTER ERROR (%)
4015 TA01b
100
90
95
80
85
70
75
60
55
65
50
0.5
0.0
–0.5
–1.0
–1.5
–2.0
0.1 101
EFFICIENCY
QC ERROR
LTC4015
VIN
UVCLFB
µCONTROLLER
V
IN
12V
SMBALERT
DVCC
SCL
SDA
CELLS0
INTVCC CELLS1
CELLS2
CHEM0
CHEM1
RT
VC
CCREFP
CCREFM
EQ
INFET CLP
RSNSI
CLN SYS SYSM5
4015 TA01a
OUTFET
SYS
INTVCC
DRVCC
BOOST
TG
SW
BG
CSPM5
CSP
CSN
RNTCBIAS
RSNSB
BATSENS
NTCBIAS
NTC
LEAD-ACID
EQUALIZE
CHARGE
(PADDLE)
GND
SGND 2P5VCC
MPPT
R
NTC
2-CELL Li-Ion
BATTERY
PACK
T
LTC4015
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TABLE OF CONTENTS
Features ............................................................................................................................ 1
Applications ....................................................................................................................... 1
Typical Application ............................................................................................................... 1
Description......................................................................................................................... 1
Absolute Maximum Ratings ..................................................................................................... 3
Order Information ................................................................................................................. 3
Data Sheet Conventions ......................................................................................................... 3
Pin Configuration ................................................................................................................. 3
Electrical Characteristics ........................................................................................................ 4
Typical Performance Characteristics .........................................................................................10
Pin Functions .....................................................................................................................13
Block Diagram ....................................................................................................................15
I2C Timing Diagram .............................................................................................................16
Operation..........................................................................................................................17
Applications Information .......................................................................................................42
Register Description ............................................................................................................49
DETAILED Register Descriptions ..............................................................................................55
Typical Applications .............................................................................................................72
Package Description ............................................................................................................74
Revision History .................................................................................................................75
Typical Application ..............................................................................................................76
Related Parts .....................................................................................................................76
LTC4015
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PIN CONFIGURATIONABSOLUTE MAXIMUM RATINGS
(Notes 1, 5)
13 14 15 16
TOP VIEW
39
GND
UHF PACKAGE
38-LEAD (5mm × 7mm) PLASTIC QFN
17 18 19
38 37 36 35 34 33 32
24
25
26
27
28
29
30
31
8
7
6
5
4
3
2
1CELLS1
CELLS2
DVCC
SCL
SDA
SMBALERT
SGND
UVCLFB
VC
RT
NTC
NTCBIAS
SYS
SYSM5
OUTFET
INTVCC
DRVCC
BG
BOOST
TG
SW
2P5VCC
MPPT
CSP
CELLS0
CHEM1
CHEM0
VIN
INFET
CLP
CLN
EQ
GND
CSPM5
CCREFM
CCREFP
BATSENS
CSN
23
22
21
20
9
10
11
12
TJMAX = 125°C, θJA = 34°C/W (NOTE 1)
EXPOSED PAD (PIN 39) IS GND, MUST BE SOLDERED TO PCB GND
ORDER INFORMATION
LEAD FREE FINISH TAPE AND REEL PART MARKING* PACKAGE DESCRIPTION TEMPERATURE RANGE
LTC4015EUHF#PBF LTC4015EUHF#TRPBF 4015 38-Lead (5mm × 7mm) Plastic QFN –40°C to 125°C
LTC4015IUHF#PBF LTC4015IUHF#TRPBF 4015 38-Lead (5mm × 7mm) Plastic QFN –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.
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/. Some packages are available in 500 unit reels through
designated sales channels with #TRMPBF suffix.
VIN, CSN ..................................................... 0.3V to 40V
BOOST to SW..............................................0.3 to 5.5V
BATSENS to CSN, CSP to CSN, CLP to CLN, CLP, CLN
to SYS ................................................................±0.3V
DVCC, DRVCC ............................................. 0.3V to 5.5V
CELLSO, CELLS1, CELLS2, CHEM0, CHEM1,
MPPT, EQ ..........................................0.3V to INTVCC
SDA, SCL, SMBALERT .............................. 0.3V to DVCC
IUVCLFB (Note 4) ..................................................±200µA
INTVCC Peak Output Current ................................100mA
Operating Junction Temperature Range
(Notes 2,3) .............................................40 to 125°C
Storage Temperature Range ......................65 to 150°C
DATA SHEET CONVENTIONS
VPINNAME and IPINNAME represents the voltage on a pin
or the pin current; VEQ = EQ Pin Voltage.
Hexadecimal numbers are prefixed with 0x; 0x10 is a
hexadecimal 10
Register symbol names will be capitalized. Symbols
within a register will be lower case;
en_meas_sys_valid_alert is bit 15 in register
EN_LIMIT_ALERTS (0x0D)
LiFePO4 is lithium iron phosphate, Li-Ion is used for
both lithium-ion and lithium-ion polymer
Lithium chemistries refers to LiFePO4 , lithium-ion, and
lithium-ion polymer as a group.
When a register name is used in square brackets, this
means the 16 bit value associated with that register;
For example [VBAT] is the 16 bit ADC measurement
value of the per cell battery voltage.
http://www.linear.com/product/LTC4015#orderinfo
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ELECTRICAL CHARACTERISTICS
SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS
VIN Input Supply Voltage Range Note 8 l3.1 35 V
VBAT Battery Voltage Range Note 8 l35 V
VCHARGE(TOL) Charge Voltage, Regulated Battery per Cell
Tolerance, All Chemistries Li-Ion ,4.2V per Cell; LiFePO4 3.6V per
Cell; Lead-Acid 2.2V per Cell
l–1.25 1.25 %
Regulated Battery Charge Current
Tolerance Full-Scale VCSP–CSN/RSNSB l–2.0 2.0 %
VSYS SYS Pin Voltage Note 8 l3.05 35 V
Quiescent Current IQ = IVIN + ICLP + ICLN + ISYS + ISW + ICSP + ICSN + IBATSENS
Battery Discharge Current (No Input
Supply, Coulomb Counter Disabled) Battery Only, Telemetry Inactive l112 325 µA
Battery Only, Telemetry Active 1% Duty
Cycle
l140 364 µA
Battery Only, Telemetry Active
Continuously 2.84 mA
IQ, Charging Charging, Switcher Suspended 3.00 mA
Charging, VBAT > VCHARGE (Note 7) 4.10 mA
IQ, Ship Mode Ship Mode (VIN = 0) l5 40 µA
IVin VIN Pin Current Battery Only (No Input Supply) –200 200 nA
Charging <140 µA
ISYS SYS Pin Current Battery Only, Telemetry Off 100 µA
Battery Only, Telemetry On 2.75 mA
Charging, VBAT > VCHARGE (Note 7) 3.65 mA
VIN_DUVLO VIN to VBATSENS Differential Undervoltage
(Must Be Satisfied for Charging) Rising Threshold
Hysteresis
l140 200
100 250 mV
mV
VIN_OVLO Input Overvoltage Lockout
(Inhibits Charger) Rising Threshold
Hysteresis
l37.7 38.6
1.4 39.5 V
V
Input Undervoltage Current Limit
VUVCLFB UVCLFB Pin Regulation Range
(8-Bit DAC) VUVCLFB Maximum Code 0xFF
VUVCLFB Minimum Code 0x00
l1188 1200
4.6875 1212 mV
mV
UVCLFB Pin Regulation DAC LSB 4.6875 mV
UVCLFB Pin Leakage Current VUVCLFB = 1.2V l–100 100 nA
Input Current Limit
Regulated Input Current Limit Tolerance Full-Scale VCLP–CLN/RSNSI l–2.0 2.0 %
ICL Input Current Limit Range ICL = (VCLP – CLN)/RSNSI 0.5 – 32 mV/RSNSI
Input Current Limit LSB Step Size 0.5 mV/RSNSI
CLP Input Current VCLP = 12V, VCLP–CLN = 32mV 45 µA
CLN Input Current VCLP = 12V, VCLP–CLN = 32mV –100 100 nA
CLP, CLN Common Mode Range Note 8 4 35 V
The l denotes the specifications which apply over the specified operating
junction temperature range, otherwise specifications are at TA = 25°C. (Note 2), DVCC = 3.3V, UVCLFB = 1.5; CELLS1 = INTVCC; EQ,
MPPT, CELLS0, CELLS2, CHEM0, CHEM1 = 0; RT = 95.3k; RCCREF = 301k, RNTCBIAS = RNTC = 10k; BATSENS = CSN = CSP; DRVCC = INTVCC;
SYS = CLP = CLN. Conditions: Charging; VIN = 12V, SYS = 12V, BATSENS = 7.4V …..Battery Only; VIN = 0V, SYS = 8.4V, BATSENS = 8.4V
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SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS
INTVCC Regulator (SYS is Supply Pin for This Regulator)
VINTVCC Internal Regulator Output Voltage No Load 5 V
Load Regulation IINTVCC = 50 mA 1.5 2.5 %
VINTVCC_CUVLO INTVCC Undervoltage Charger Lockout Rising Threshold
Hysteresis
l4.2 4.3
0.3 4.4 V
V
VINTVCC_TUVLO INTVCC Undervoltage Telemetry System
Lockout Rising Threshold
Hysteresis
l2.75 2.85
0.12 2.95 V
V
DRVCC INPUT (External Supply or Supplied by INTVCC)
VDRVCC DRVCC Supply Voltage 4.3 5.5 V
DRVCC Undervoltage Lockout Rising Threshold
Hysteresis
l4.1 4.2
0.3 4.3 V
V
Battery Charger
(All Chemistries)
ICHARGE Battery Charge Current Range,
Battery Charge Current Resolution VCSP > 2.6V (Note 10) 1 – 32
1mV/RSNSB
mV/RSNSB
Peak Low VCSP Charge Current VCSP < 2.4V 7.0 mV/RSNSB
IBATSENS + ICSP + ICSN Charger Suspended (Telemetry Active)
VIN, VSYS = 12V, VBATSENS = 7.4V
VIN, VSYS = 35V, VBATSENS = 34V (9 Cells)
110
200
µA
µA
Lithium-Ion/Lithium Polymer Battery Charger
Lithium-Ion/Lithium Polymer Programmable, CHEM1, CHEM0 = [LL] (Note 9)
Li-Ion Charge Voltage Max DAC Setting Code 11111 (Note 11) 4.2 V/Cell
Li-Ion Charge Voltage Min DAC Setting Code 00000 (Note 11) 3.8125 V/Cell
Li-Ion Charge Voltage DAC LSB 12.5 mV
Li-Ion Recharge Voltage Percent of Charge Voltage 97.5 %
Charge C/x Termination Setting VCSP–CSN (I2C Termination Option) 3.2 mV
Lithium-Ion/Lithium Polymer Fixed 4.2, 4.1, 4.0 Charge Voltage, CHEM1, CHEM0 = [HH,LZ,ZL] (Note 9)
4.2V Fixed Li-Ion Charge Voltage CHEM1,0 = [H,H] (Note 11) 4.200 V/Cell
4.2V Fixed Li-Ion Recharge Voltage CHEM1,0 = [H,H] 4.095 V/Cell
4.1V Fixed Li-Ion Charge Voltage CHEM1,0 = [L,Z] (Note 11) 4.100 V/Cell
4.1V Fixed Li-Ion Recharge Voltage CHEM1,0 = [L,Z] 4.000 V/Cell
4.0V Fixed Li-Ion Charge Voltage CHEM1,0 = [Z,L] (Note 11) 4.000 V/Cell
4.0V Fixed Li-Ion Recharge Voltage CHEM1,0 = [Z,L] 3.900 V/Cell
Lithium-Ion/Lithium Polymer, CHEM1, CHEM0 = [LL, HH, LZ, ZL] (Note 9)
Low Battery Precharge Threshold Charge Voltage = 4.2V 2.85 V/Cell
Low Battery Precharge Hysteresis Charge Voltage = 4.2V 50 mV/Cell
Low Battery Precharge Current ICHARGE Set to 32 mV/RSNSB 3 mV/RSNSB
Max Charge Time 18.2 hrs
Charge Termination Timer (Default Termination) 4 hrs
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the specified operating
junction temperature range, otherwise specifications are at TA = 25°C. (Note 2), DVCC = 3.3V, UVCLFB = 1.5; CELLS1 = INTVCC; EQ,
MPPT, CELLS0, CELLS2, CHEM0, CHEM1 = 0; RT = 95.3k; RCCREF = 301k, RNTCBIAS = RNTC = 10k; BATSENS = CSN = CSP; DRVCC = INTVCC;
SYS = CLP = CLN. Conditions: Charging; VIN = 12V, SYS = 12V, BATSENS = 7.4V …..Battery Only; VIN = 0V, SYS = 8.4V, BATSENS = 8.4V
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SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS
LiFePO4 Battery Charger
LiFePO4, Programmable, CHEM1,CHEM0 = [LH] (Note 9)
LiFePO4 Charge Voltage Max DAC setting Code 11111 (Note 11) 3.8 V/Cell
LiFePO4 Charge Voltage Min DAC setting Code 00000 (Note 11) 3.4125 V/Cell
LiFePO4 Charge Voltage DAC LSB 12.5 mV
LiFePO4 Recharge Voltage POR Value I2C Programmable 3.35 V/Cell
VLiFePO4-C/x Charge Termination C/x Threshold VCSP-CSN (I2C Programmable) 3.2 mV
LiFePO4 Fixed Standard Charge, Fixed Fast Charge, CHEM1, CHEM0 = [ZH,HZ] (Note 9)
LiFePO4 Fixed Fast Charge Absorb Voltage CHEM1, CHEM0 = [HZ] Only (Note 11) 3.8 V/Cell
LiFePO4 Charge Voltage CHEM1, CHEM0 = [ZH,HZ] (Note 11) 3.6 V/Cell
LiFePO4 Recharge Voltage CHEM1, CHEM0 = [ZH,HZ] (Note 11) 3.35 V/Cell
LiFePO4, CHEM1, CHEM0 = [LH,HZ,ZH] (Note 9)
Max Charge Time 18.2 hrs
VLiFePO4-T(CV) Charge Termination Time 1 hrs
Lead-Acid Battery Charger
Lead-Acid Fixed, CHEM1, CHEM0 = [ZZ] (Note 9)
VLead_Acid_Vcharge Lead-Acid VCHARGE, Equalization
Lead-Acid VCHARGE, Absorption
Lead-Acid VCHARGE, CV
Lead-Acid Temperature Compensation
(Note 11)
(Note 11)
(Note 11)
2.6
2.4
2.2
–3.65
V/Cell
V/Cell
V/Cell
mV/Cell/°C
Lead-Acid Programmable, CHEM1, CHEM0 = [HL] (Note 9)
VLead_Acid_Vcharge Lead-Acid VCHARGE DAC Maximum
Lead-Acid VCHARGE DAC Minimum
Lead-Acid VCHARGE DAC Resolution
Lead-Acid Temperature Comp
Code 111111 (Note 11)
Code 000000 (Note 11)
Temperature Comp Enabled
2.6
2.0
9.5
–3.65
V/Cell
V/Cell
mV
mV/Cell/°C
Thermistor (NTC) BIAS
VNTCBIAS Applied NTC Bias Voltage Internally Switched to 1.2V 1.2 V
INTC NTC Leakage Current –50 50 nA
SYSM5, CSPM5 Regulators
–5VVINM5 VSYS – VSYSM5, VCSP – VCSPM5 No Load 4.8 V
Power Path/Ideal Diode Controllers
VFTO Forward Turn-On Voltage 50 mV
VFR Forward Regulation 15 mV
VRTO Reverse Turn-Off –30 mV
tIF(ON) INFET Turn-On Time INFET – VIN > 3V, CINFET = 3.3nF 550 µs
tIF(OFF) INFET Turn-Off Time INFET – VIN < 1V, CINFET = 3.3nF 2 µs
tOF(ON) OUTFET Turn-On Time VBAT – OUTFET > 3V, COUTFET = 3.3nF 2.3 µs
tOF(OFF) OUTFET Turn-Off Time VBAT – OUTFET < 1V, COUTFET = 3.3nF 1.9 µs
Inductor Current Regulation
ILIM Cycle by Cycle Max Charge Current Note 5 l47 52 57 mV/RSNSB
IREV Reverse Inductor Current l3.8 7.0 10 mV/RSNSB
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the specified operating
junction temperature range, otherwise specifications are at TA = 25°C. (Note 2), DVCC = 3.3V, UVCLFB = 1.5; CELLS1 = INTVCC; EQ,
MPPT, CELLS0, CELLS2, CHEM0, CHEM1 = 0; RT = 95.3k; RCCREF = 301k, RNTCBIAS = RNTC = 10k; BATSENS = CSN = CSP; DRVCC = INTVCC;
SYS = CLP = CLN. Conditions: Charging; VIN = 12V, SYS = 12V, BATSENS = 7.4V …..Battery Only; VIN = 0V, SYS = 8.4V, BATSENS = 8.4V
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SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS
Oscillator
fOSC Switching Frequency RT = 95.3k l475 500 525 kHz
fMAX Maximum Programmable Frequency RT = 47.5k 1 MHz
fMIN Minimum Programmable Frequency RT = 237k 200 kHz
Gate Drivers
RUP-TG TG Pull-Up On-Resistance 2.0 Ω
RDOWN-TG TG Pull-Down On-Resistance 0.5 Ω
RUP-BG BG Pull-Up On-Resistance 2.0 Ω
RDOWN-BG TG Pull-Down On-Resistance 0.5 Ω
tR-TG TG 10% to 90% Rise Time CLOAD = 3.3nF 20 ns
tF-TG TG 90% to 10% Fall Time CLOAD = 3.3nF 10 ns
tR-BG BG 10% to 90% Rise Time CLOAD = 3.3nF 20 ns
tF-BG BG 90% to 10% Fall Time CLOAD = 3.3nF 10 ns
tNO Non-Overlap Time 60 ns
tON(MIN) Minimum On-Time 140 ns
DCMAX Maximum Duty Cycle 98.4 %
VC Error Amplifier
gmTransconductance to VC pin
gm (VCSP–CSM) (Constant-Current)
gm (VBATSENS) (Constant-Voltage Lithium)
gm (VBATSENS) (Constant-Voltage LA)
gm (VUVCLFB) (Input Voltage Regulation)
gm (VCLP–CLM) (Input Current Limiting)
2 Cell; (gm = 1.06 –3 • 2/(7 • Cell Count)
6 Cell; (gm = 1.06 –3 • 3/(7 • Cell Count)
4.10
0.15
0.08
1.06
4.10
mmho
mmho
mmho
mmho
mmho
Telemetry A/D Measurement Subsystem, Battery Only Mode
VERR Measurement Error (Note 6) VIN = 1V
VIN = 35V ±100
±1.5 mV
%
VSYS = 2.5V
VSYS = 35V ±100
±1.5 mV
%
VBAT = 1.75V, 1 Cell Li-Ion
VBAT = 35V, 9 Cell Li-Ion ±50
±1.5 mV
%
VCLP–CLN = 0mV
VCLP–CLN = 32mV ±200
±2.5 µV
%
VCSP–CSN = 0mV
VCSP–CSN = 32mV ±200
±2.5 µV
%
NTC/NTCBIAS = 50%, 75%
NTC/NTCBIAS = 5% ±2
±3.5 %
%
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the specified operating
junction temperature range, otherwise specifications are at TA = 25°C. (Note 2), DVCC = 3.3V, UVCLFB = 1.5; CELLS1 = INTVCC; EQ,
MPPT, CELLS0, CELLS2, CHEM0, CHEM1 = 0; RT = 95.3k; RCCREF = 301k, RNTCBIAS = RNTC = 10k; BATSENS = CSN = CSP; DRVCC = INTVCC;
SYS = CLP = CLN. Conditions: Charging; VIN = 12V, SYS = 12V, BATSENS = 7.4V …..Battery Only; VIN = 0V, SYS = 8.4V, BATSENS = 8.4V
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SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS
Coulomb Counter
VSENSE Sense Voltage Differential Input Range VCSP–CSN ±50 mV
qLSB Charge Measurement Resolution Prescaler M = 512 (Default) 0.017 mVhr
TCE Total Charge Error 10mV ≤ |VSENSE| ≤ 50mV ±1.5 %
10mV ≤ |VSENSE| ≤ 50mV l±2.5 %
VSENSE = 1mV <1.0 %
IQC_CSP IQ Coulomb Counter VSENSE = 30mV, Battery Only 78 μA
CELLS0, CELLS1, CELLS2, CHEM0, CHEM1 Programming Input Pins (Note 9)
VIHPP Input High Threshold INTVCC – VPIN l0.3 V
VILPP Input Low Threshold VPIN l0.3 V
RIZPP Input High-Z Test Resistance Internal 50k/50k Resistor Divider Applied
to Inputs During Chemistry/Cell Read 25
MPPT, EQ Input Pins
MPPT, EQ Input High Threshold l1.1 V
MPPT, EQ Input Low Threshold l0.2 V
MPPT, EQ Pin Leakage Current VEQ, VMPPT = 5V 0 1 µA
SMBALERT Pin Characteristics
ISMBALERT SMBALERT Pin Leakage Current VSMBALERT = 5V 0 1 µA
VSMBALERT SMBALERT Pin Output Low Voltage ISMBALERT = 1mA 65 100 mV
I2C Port, SDA, SCL
DVCC I2C Logic Reference Level 1.6 5.5 V
IDVCCQ DVCC Current SCL/SDA = 0kHz 0 µA
ADDRESS I2C Address 1101_000[R/W]b
VIHI2C Input High Threshold 70 % DVCC
VILI2C Input Low Threshold 30 % DVCC
IIHI2C Input Leakage High –1 1 µA
IILI2C Input Leakage Low –1 1 µA
VOLI2C Digital Output Low (SDA) ISDA = 3mA 0.4 V
FSCL SCL Clock Frequency 400 kHz
tLOW LOW Period of SCL Clock 1.3 µS
tHIGH HIGH Period of SCL Clock 0.6 µS
tBUF Bus Free Time Between Start and Stop
Conditions 1.3 µs
tHD(STA)Hold Time, After (Repeated) Start
Condition 0.6 µs
tSU(STA)Setup Time After a Repeated Start
Condition 0.6 µs
tSU(STO) Stop Condition Set-Up Time 0.6 µs
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the specified operating
junction temperature range, otherwise specifications are at TA = 25°C. (Note 2), DVCC = 3.3V, UVCLFB = 1.5; CELLS1 = INTVCC; EQ,
MPPT, CELLS0, CELLS2, CHEM0, CHEM1 = 0; RT = 95.3k; RCCREF = 301k, RNTCBIAS = RNTC = 10k; BATSENS = CSN = CSP; DRVCC = INTVCC;
SYS = CLP = CLN. Conditions: Charging; VIN = 12V, SYS = 12V, BATSENS = 7.4V …..Battery Only; VIN = 0V, SYS = 8.4V, BATSENS = 8.4V
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SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS
tHD(DAT(OUT)) Output Data Hold Time 0 900 ns
tHD)DAT(IN)) Input Data Hold Time 0 ns
tSU(DAT)Data Set-Up Time 100 ns
tSP Input Spike Suppression Pulse Width 50 ns
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 LTC4015 is tested under pulsed load conditions such that TJ
TA. The LTC4015E 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 LTC4015I is guaranteed
over the –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 formula:
TJ = TA + (PD • θJA)
where θJA = 34°C/W for the UHF package.
Note 3: The LTC4015 includes overtemperature protection that is
intended to protect the device during momentary overload conditions.
The maximum rated junction temperature will be exceeded when this
protection is active. Continuous operation above the specified absolute
maximum operating junction temperature may impair device reliability or
permanently damage the device.
Note 4: UVCLFB is internally clamped above the maximum UVCLFB
regulation point (2.5V at 200µA nominally). Maximum input current must
be limited to 200µA when this clamp is reached.
Note 5: The current limit features of this part are intended to protect the
IC from short term or intermittent fault conditions. Continuous operation
above the maximum specified pin current may result in device degradation
or failure.
Note 6: Measurement error is the magnitude of the difference between the
actual measured value and the ideal value. Error for VCLP-CLN and VCSP-CSN
is expressed in μV, a conversion to an equivalent current may be made by
dividing by the sense resistors, RSNSI and RSNSB, respectively.
Note 7: VCHARGE is the battery charge voltage (or CV, constant-voltage)
target. VBAT is the battery voltage. Dynamic supply current is higher due
to the gate charge being delivered at the switching frequency. See the
Applications Information section.
Note 8: VIN, or VBAT for battery only operation, may be connected to any
suitable DC power source from 2.8V to 35V such that the voltage at VSYS
is high enough to allow INTVCC to support the desired mode of operation.
In order for the telemetry system to operate, INTVCC must exceed the
telemetry undervoltage lockout (VINTVCC_TUVLO). In order for the battery
charger to operate, INTVCC must exceed the charger undervoltage lockout
(VINTVCC_CUVLO). Allowing for 0.3V of drop from VIN to INTVCC, these
modes require a minimum input voltage of 3.1V and 4.35V, respectively.
Additionally the VIN to VBATSENS (VIN_DULVO) differential must also be
satisfied for charging.
Note 9: Chemistry selection is made using the CHEM1 and CHEM0 pins.
These are three-state pins used by the LTC4015 to select of one of nine
chemistry specific charging algorithms. These pins should be hard wired
to GND(L), INTVCC(H), or left open (Z > 1000kΩ).
Note 10: ICHARGE is the battery charge current (or CC, constant-current)
target. ICHG is the charge current when charging.
Note 11: Charge voltage tolerance is VCHARGE(TOL) which is specified at the
beginning of the electrical table. The LTC4015 is not a substitute for pack
protection! The 4015 does not monitor or balance individual cells – the full
stack voltage is divided by number of cells for simplicity only.
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the specified operating
junction temperature range, otherwise specifications are at TA = 25°C. (Note 2), DVCC = 3.3V, UVCLFB = 1.5; CELLS1 = INTVCC; EQ,
MPPT, CELLS0, CELLS2, CHEM0, CHEM1 = 0; RT = 95.3k; RCCREF = 301k, RNTCBIAS = RNTC = 10k; BATSENS = CSN = CSP; DRVCC = INTVCC;
SYS = CLP = CLN. Conditions: Charging; VIN = 12V, SYS = 12V, BATSENS = 7.4V …..Battery Only; VIN = 0V, SYS = 8.4V, BATSENS = 8.4V
LTC4015
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For more information www.linear.com/LTC4015
TYPICAL PERFORMANCE CHARACTERISTICS
VIN (Resistive), MPPT Enabled
Charger On/Off Li-Ion Charging Efficiency vs VIN
Lead-Acid Charging Efficiency
vs ICHARGE
LiFePO4 Charging Efficiency
vs ICHARGE
Charge Voltage (CV Mode)
vs Junction Temperature
VRSNSB Current (CC Mode)
vs Junction Temperature
Lead-Acid Charging Profile
Voltage, Current vs Time
Li-Ion Charging Profile
Voltage, Current vs Time
LiFePO4 Charging Profile
Voltage, Current vs Time
TA = 25°C, application circuit 1 unless
otherwise noted.
TIME (MINUTES)
0
50
100
150
200
250
11.0
11.5
12.0
12.5
13.0
13.5
14.0
14.5
15.0
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
BATTERY VOLTAGE (V)
4015 G01
CHARGE VOLTAGE
CHARGE CURRENT
VABSORB = 2.4V/CELL
VCHARGE = 2.2V/CELL
CELLCOUNT = 6
RSNSI = 0.007Ω
RSNSB = 0.010Ω
TIME (MINUTES)
0
15
30
45
60
75
90
105
120
135
7.2
7.4
7.6
7.8
8.0
8.2
8.4
8.6
0
1
2
3
4
5
6
7
8
4015 G02
CHARGE VOLTAGE
CHARGE CURRENT
VCHARGE = 4.2V/CELL
CELLCOUNT = 2
TIME (MINUTES)
0
15
30
45
60
75
90
105
120
135
11.0
11.5
12.0
12.5
13.0
13.5
14.0
14.5
15.0
0
1
2
3
4
5
6
7
8
4015 G03
CHARGE VOLTAGE
CHARGE CURRENT
VCHARGE = 3.6V/CELL
CELLCOUNT = 4
VIN, CHARGER OFF (V)
10
15
20
25
30
35
0
5
10
15
20
25
30
VIN CHARGER ON (V)
4015 G04
VIN, MPPT ENABLED
VIN/2, CHARGER OFF
VBAT + 1V
VIN RESISTANCE 4.5Ω
VCHARGE = 4.2V/CELL
VBAT HELD AT 6.6V
VIN (V)
10
15
20
25
30
80
82
84
86
88
90
92
94
96
4015 G05
ICHARGE = 0.75A
ICHARGE = 4A
ICHARGE = 8A
VBAT HELD AT 7.4V
CELLCOUNT = 2
ICHARGE (A)
0
1
2
3
4
5
6
8
7
70
75
80
85
90
95
100
EFFICIENCY (%)
4015 G06
ICHARGE
VIN = 24V
VBAT HELD AT 12.2V
CELLCOUNT = 6
ICHARGE (A)
0
1
2
3
4
5
6
7
8
84
86
88
90
92
94
96
98
EFFICIENCY (%)
4015 G07
ICHARGE
VIN = 30V
VBAT HELD AT 23.5V
CELLCOUNT = 7
JUNCTION TEMPERATURE (°C)
–50
–30
–10
10
30
50
70
90
110
130
8.370
8.375
8.380
8.385
8.390
8.395
8.400
8.405
4015 G08
ICHARGE = 0
ICHARGE = 100mA
Li-Ion 4.2V/CELL CHARGE VOLTAGE
VIN = 12V
CELLCOUNT = 2
JUNCTION TEMPERATURE (°C)
–50
–30
–10
10
30
50
70
90
110
130
31.86
31.88
31.90
31.92
31.94
31.96
31.98
32.00
32.02
–1.75
–1.50
–1.25
–1.00
–0.75
–0.50
–0.25
0.00
0.25
VRSNSB (V)
VRSNSB ERROR (%)
4015 G09
Li-Ion 4.2V/CELL CHARGE VOLTAGE
VIN = 12.V, VBAT = 8V
CELLCOUNT = 2
FULL-SCALE VRSNSB
ERROR FROM 25°C
LTC4015
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For more information www.linear.com/LTC4015
TYPICAL PERFORMANCE CHARACTERISTICS
RT Oscillator Frequency vs
Junction Temperature
Battery Discharge Current vs
Battery Voltage
Battery Charger Soft-Start
(ICHARGE vs Time)
Gate Drive Non-Overlap
(Transient)
VIN Hot Plug, 0 to 24V, 4-Cell
LiFePO4
Battery Hot Plug, 0 to 11V, 4-Cell
LiFePO4
VRSNSI Charging (ICL Mode) vs
Junction Temperature
UVCLFB Voltage (UVCL Mode) vs
Junction Temperature
Input Current Limiting IIN and
ICHARGE vs System Load
TA = 25°C, application circuit 1 unless
otherwise noted.
JUNCTION TEMPERATURE (°C)
–50
–30
–10
10
30
50
70
90
110
130
1.1965
1.1971
1.1976
1.1982
1.1988
1.1994
1.1999
1.2005
CHARGE VOLTAGE (V)
4015 G11
UVCLFB, FULL-SCALE
Li-Ion 4.2V/CELL VCHARGE
VIN = 12V, VBAT = 7.4V
VIN RESISTANCE 2Ω
CELLCOUNT = 2
SYSTEM LOAD (A)
0
2
4
6
8
10
12
0
4
8
12
16
20
4015 G12
IIN, VIN = 12V
ICHARGE, VIN = 12V
IIN, VIN = 24V
ICHARGE, VIN = 24V
IIN, VIN = 35V
ICHARGE, VIN = 35V
JUNCTION TEMPERATURE (°C)
–50
–30
–10
10
30
50
70
90
110
130
495
496
497
498
499
500
501
502
503
FREQUENCY (Hz)
4015 G13
RT = 95.3k
JUNCTION TEMPERATURE (°C)
–50
–30
–10
10
30
50
70
90
110
130
31.86
31.88
31.90
31.92
31.94
31.96
31.98
32.00
32.02
–1.75
–1.00
–1.25
–1.50
–0.75
–0.50
–0.25
0.00
0.25
VRSNSB (V)
VRSNSI ERROR (%)
4015 G10
VRSNSI
ERROR FROM 25°C
Li-Ion 4.2V/CELL VCHARGE
VIN = 12V, VBAT = 7.4V
SYSTEM LOAD = 7A
CELLCOUNT = 2
BATTERY VOLTAGE (V)
0
5
10
15
20
25
30
35
0
50
100
150
200
250
300
4015 G14
T = –45°C
T = 25°C
T = 60°C
T = 125°C
VIN = 0
COULOMB COUNTER OFF
ICHARGE MAX = 8A
RSNSB = 0.004Ω
2ms/DIV
4015 G15
ICHARGE
2A/DIV
VIN = 12V
VBAT = 7.4V
VSW
2V/DIV
200ns/DIV
4015 G16
TG, BG NON OVERLAP
4015 G17
IIN
VIN
VBAT
IIN
20A/DIV
IBAT
20A/DIV
VIN
5V/DIV
VBAT
5V/DIV
500µs/DIV
IBAT = GREEN
4015 G18
IBAT
IBAT
20A/DIV
VBAT
5V/DIV
VSYS
5V/DIV
VBAT = BLUE
VSYS = RED
200µs/DIV
LTC4015
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For more information www.linear.com/LTC4015
TYPICAL PERFORMANCE CHARACTERISTICS
Coulomb Counter Accuracy vs
VCSP–CSN
Start-Up from 24V VIN Hot Plug,
ICHARGE = 8A (RSNSB = 0.004Ω)
Ship Mode Battery Discharge
Current vs Battery Voltage
MPPT Algorithm Using UVCL DAC
Sweep to Find MPP
VCSP – VCSN (mV)
ERROR (%)
4015 G24
0.5%
0.0%
–0.5%
–1.0%
–1.5%
–2.0%
–2.5%
3.0%
3.5% 0 15 20 25 30 35105
QC ERROR
BATTERY VOLTAGE (V)
0
5
10
15
20
25
30
35
0
5
10
15
20
25
30
35
BATTERY DISCHARGE CURRENT (µA)
4015 G20
T = 125°C
T = 60°C
T = 25°C
T = –45°C
VIN SOURCE IMPEDANCE = 4.4Ω
4015 G21
MAXIMUM ICHARGE FOUND
DURING UVCL DAC SWEEP
VBAT
VIN , AT MAX ICHARGE
FOUND DURING UVCL
DAC SWEEP
VIN, NO
LOAD = 25V
UVCL DAC
SWEEP
VIN
5V/DIV
VBAT
5V/DIV
ICHARGE
2A/DIV
400ms/DIV
4015 G19
IBAT
IIN
VBAT
VIN
VIN
5V/DIV
VBAT
5V/DIV
IIN
5A/DIV
IBAT
5A/DIV
200µs/DIV
LTC4015
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For more information www.linear.com/LTC4015
PIN FUNCTIONS
CELLS1 (Pin 1): Number of Cells Select Pin. Three-state
pin used in combination with CELLS0 and CELLS2 to set
the total number of battery cells.
CELLS2 (Pin 2): Number of Cells Select Pin. Three-state
pin used in combination with CELLS0 and CELLS1 to set
the total number of battery cells.
DVCC (Pin 3): Logic Supply for the I2C Serial Port. DVCC
sets the reference level of the SDA and SCL pins for I2C
compliance. It must be connected to the same power
supply used to power the I2C pull up resistors. If the I2C
port is unused connect this pin to INTVCC, do not float.
SCL (Pin 4): Clock Input for the I2C Serial Port. The
I2C input levels are scaled with respect to DVCC for I2C
compliance. If the I2C port is unused connect this pin to
INTVCC, do not float.
SDA (Pin 5): Data Input/Output for the I2C serial port. The
I2C input levels are scaled with respect to DVCC for I2C
compliance. If the I2C port is unused connect this pin to
INTVCC, do not float.
SMBALERT (Pin 6): Open-Drain Interrupt Request. Pulls
low when something important needs to be reported back
to the system.
SGND (Pin 7): Signal Ground. All small signal components
and compensation should connect to this ground, which
should be connected to PGND at a single point.
UVCLFB (Pin 8): Undervoltage Current Limit Feedback
Pin. UVCLFB can be used to reduce charge current when
the VIN pin reaches a level programmed by the user sup-
plied resistor divider. This feature can be used for power
sources with higher source impedance such as a solar
panel. Maximum charge current is tapered off when this
pin is below 1.2V, at 1.15V the charge current is zero.
UVCLFB is internally clamped to about 2.5V with 200µA
in this pin. Limit the current into this pin to 200µA at
maximum VIN using the thevenin resistance of the input
divider. If the input undervoltage current limit feature is
not desired, connect UVCLFB to 2P5VCC through a 10k
resistor or to VIN through an appropriately sized resistor.
VC (Pin 9): Current Control Threshold and Error Amplifier
Compensation Point. The current comparator threshold
increases with this control voltage. The voltage normally
ranges from 900mV to 2.4V.
RT (Pin 10): Connect a resistor from RT to GND to set
frequency of the switching power supply.
NTC (Pin 11): Thermistor Input. The NTC pin connects
to a negative temperature coefficient thermistor (Type_2)
to monitor the temperature of the battery. The voltage on
this pin is digitized by the analog to digital converter and
is available via the I2C port. The thermistor value is also
used to qualify battery charging. Connect a low drift bias
resistor from NTCBIAS to NTC and a thermistor from NTC
to ground. If NTC functions are unwanted, use a resistor
equal in value to RNTCBIAS instead of a thermistor.
NTCBIAS (Pin 12): NTC Thermistor Bias Output. Connect
a bias resistor between NTCBIAS and NTC, and a thermis-
tor between NTC and GND. The bias resistor should be
equal in value to the nominal value of the thermistor. The
LTC4015 applies 1.2V to this pin during NTC measurement.
EQ (Pin 13): Equalize. Apply a logic signal between 1.5V
and INTVCC (5V) to this pin to allow the 4015 to trigger
lead-acid equalize mode. GND this pin if unused, do not
float.
GND (Pin 14, Exposed Pad Pin 39): Ground. The exposed
pad should be connected by multiple vias directly under
the LTC4015 to a continuous ground plane on the second
layer of the printed circuit board.
CSPM5 (Pin 15): Internal Supply Pin. The VCSPM5 pin
regulates at the higher of ground or approximately
VCSP – 5V. A low impedance multilayer ceramic capacitor
should be connected from VCSP to VCSPM5.
CCREFM (Pin 16): Coulomb Counter Reference Resis-
tor Pin. Leakage on this pin will affect Coulomb counter
accuracy. Connect a 301k, 0.1%, 25ppm resistor from
CCREFM to CCREP.
CCREFP (Pin 17): Coulomb Counter Reference Resis-
tor Pin. CCREFP in conjunction with CCREFM provide a
reference for the Coulomb counter to make an accurate
measure of charge into and out of the battery. CCREFP is
connected internally to CSP with 50Ω. Connect a 301k,
0.1%, 25ppm resistor from CCREFP to CCREM.
LTC4015
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For more information www.linear.com/LTC4015
PIN FUNCTIONS
BATSENS (Pin 18): Battery Voltage Sense Input. For proper
operation, this pin must be connected physically close to
the positive input terminal of the battery.
CSN (Pin 19): Connection Point for the Negative Terminal
of the Charge Current Sense Resistor.
CSP (Pin 20): Connection Point for the Positive Terminal
of the Charge Current Sense Resistor.
MPPT (Pin 21): MPPT Enable Pin. Apply a logic signal
between 1.5V and INTVCC (5V) to this pin to allow the 4015
to enter MPPT mode. MPPT mode can also be entered via
the I2C port. GND this pin if unused, do not float.
2P5VCC (Pin 22): Bypass Pin for the Internal 2.5V Regu-
lator. This regulator provides power to the internal logic
circuitry. Bypass 2P5VCC with a 2.2μF multilayer ceramic
capacitor to GND.
SW (Pin 23): Switch Node. SW pin swings from a diode
drop below ground up to VSYS.
TG (Pin 24): Top Gate Drive. Drives the top N-channel
MOSFET with a voltage swing equal to DRVCC superim-
posed on the switch node voltage VSW.
BOOST (Pin 25): Boosted Floating Top Gate Drive Supply.
The BOOST pin swings from a diode voltage below DRVCC
up to VSYS + DRVCC.
BG (Pin 26): Bottom Gate Drive. Drives the bottom
N-channel MOSFET between DRVCC and ground.
DRVCC (Pin 27): External Supply for Gate Driver. Do not
exceed 5.5V on this pin. If DRVCC is not connected to
INTVCC, INTVCC must be greater than 3V before DRVCC
is applied. If not connected to INTVCC bypass this pin to
ground with a low ESR ceramic capacitor.
INTVCC (Pin 28): Internal 5V Regulator Output. The control
circuits and optionally the gate drivers are powered from
this pin. Bypass this pin to ground with a minimum 4.7µF
low ESR tantalum or ceramic capacitor.
OUTFET (Pin 29): Output Ideal Diode Gate Control Pin for
External P-channel MOSFET.
SYSM5 (Pin 30): Internal Supply Pin. The VSYSM5 pin
regulates at the higher of ground or approximately
VSYS – 5V. A low impedance multilayer ceramic capacitor
should be connected from VSYS to VSYSM5.
SYS (Pin 31): System Input Voltage. Primary power input
to the 4015. This pin powers the internal INTVCC LDO. SYS
is the max of VBAT or VIN. VSYS should be bypassed with
a low impedance multilayer ceramic capacitor, along with
large bulk capacitors.
CLN (Pin 32): Connection Point for the Negative Terminal
of the Input Current Sense Resistor.
CLP (Pin 33): Connection Point for the Positive Terminal
of the Input Current Sense Resistor.
INFET (Pin 34): Input Ideal Diode Gate Control Pin for
External N-channel MOSFET.
VIN (Pin 35): Supply Voltage for the PowerPath Step-down
Switching Charger. VIN may be connected to any suitable
DC power source from 2.8V to 35V such that the voltage at
VSYS is high enough to allow INTVCC to support the desired
mode of operation. In order for the telemetry system to
operate INTVCC must exceed the telemetry undervoltage
lockout. VIN should be bypassed with a low impedance
multilayer ceramic capacitor.
CHEM0 (Pin 36): Chemistry Select Pin. Three-state pin used
in combination with CHEM1 to set the battery chemistry
and charge algorithm.
CHEM1 (Pin 37): Chemistry Select Pin. Three-state pin used
in combination with CHEM0 to set the battery chemistry
and charge algorithm.
CELLS0 (Pin 38): Number of Cells Select Pin. Three-state
pin used in combination with CELLS1 and CELLS2 to set
the total number of battery cells.
LTC4015
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For more information www.linear.com/LTC4015
BLOCK DIAGRAM
CLP
15mV D/A
6-BIT
1.2V FULL-SCALE
D/A
5b LITHIUM CHEMISTRIES
6b LEAD-ACID
37.5
VIN INFET SYSM5 SYS OUTFET
CLN
BATSENS
UVCLFB
VC
DVCC
SCL
SDA
SMBALERT
CHEM1
CHEM0
CELLS2
CELLS1
CELLS0
MPPT
EQ
+
+
D/A
5-BIT
1.2V FULL-SCALE
+
+
+
+
+
D/A
8-BIT
1.2V FULL-SCALE
RT
LOGIC
±1.8V RANGE, SIGNED 16
BITS LSB(1 COUNT) = 3.6V/65535
= 54.9325µV
STEP-DOWN
SWITCHING
CONTROLLER
I2C
–5V LDO
COULOMB
COUNTER
OSCILLATOR
+
CCREFP
CSP
CSPM5
CCREFM
CSN
BOOST
TG
SW
DRVCC
BG
VSYS
NTC
GND
4015 BD
GND
GND (PADDLE)GND
–5V LDO
A/D
VBATSENS /[CELLCOUNT • (7/2)] Li CHEMISTRIES
VBATSENS /[CELLCOUNT • (7/3)] LEAD-ACID
VIN/30
VSYS/30
IBAT (37.5(VCSP – VCSN))
IIN (37.5(VCLP – VCLN))
T_DIE
INTVCC
2P5VCC
NTCBIAS
1.2V
INTVCC
LDO
2.5V LDO
15mV
+
37.5 37.5
IIN
IBAT
NTC
T_DIE
VSYS
VIN
VBAT
11
12
22
28
26
27
23
24
25
19
16
17
20
15
2931303435
33
32
18
8
9
10
3
4
5
6
37
36
2
1
38
21
13
3914
SGND
SGND
7
+
LTC4015
16
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For more information www.linear.com/LTC4015
I2C TIMING DIAGRAM
SDA
SCL
tHD(STA)
tHIGH
tftf
tSU(STO)
tHD(DAT)
tLOW tSU(STA) tHD(STA)
tBUF
START
CONDITION
STOP
CONDITION
REPEATED START
CONDITION
START
CONDITION
tSU(DAT)
4015 TD
tSP
I2C SMBus Legend
S START CONDITION
Sr REPEATED START CONDITION
Rd READ (BIT VALUE OF 1)
Wr WRITE (BIT VALUE OF 0)
A ACKNOWLEDGE
N NACK
P STOP CONDITION
PEC* PACKET ERROR CODE
MASTER TO SLAVE
SLAVE TO MASTER
SMBus WRITE WORD PROTOCOL
S SLAVE ADDRESS Wr A COMMAND CODE A DATA BYTE LOW A DATA BYTE HIGH A P
SMBus WRITE WORD WITH PEC PROTOCOL
S SLAVE ADDRESS Wr A COMMAND CODE A DATA BYTE LOW A DATA BYTE HIGH A PEC* A P
SMBus READ WORD PROTOCOL
S SLAVE ADDRESS Wr A COMMAND CODE A Sr SLAVE ADDRESS Rd A DATA BYTE LOW A DATA BYTE HIGH N P
SMBus READ WORD WITH PEC PROTOCOL
S SLAVE ADDRESS Wr A COMMAND CODE A Sr SLAVE ADDRESS Rd A DATA BYTE LOW A DATA BYTE HIGH A PEC* N P
SMBus ALERT RESPONSE ADDRESS PROTOCOL
S ALERT RESPONSE ADDRESS Rd A DEVICE ADDRESS Rd N P
SMBus ALERT RESPONSE ADDRESS PROTOCOL WITH PEC
S ALERT RESPONSE ADDRESS Rd A DEVICE ADDRESS Rd A PEC* N P
*USE OF PACKET ERROR CHECKING IS OPTIONAL
LTC4015
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For more information www.linear.com/LTC4015
OPERATION
Introduction
The LTC4015 is a Li-Ion/LiFePO4/lead-acid battery charger
utilizing a step-down switching controller. It is designed
to efficiently transfer power from a variety of possible
sources, such as wall adapters and solar panels, to a
battery and system load while minimizing power dissi-
pation and easing thermal budgeting constraints. Since
a switching regulator conserves power, the LTC4015
allows the charge current to exceed the source's output
current, making maximum use of the allowable power for
battery charging without exceeding the source's delivery
specifications. By incorporating input voltage and current
measurement and control systems, the switching charger
interfaces seamlessly to these sources without requiring
application software to monitor and adjust system loads.
By decoupling the system load from the battery and pri-
oritizing power to the system, the instant-on PowerPath
architecture ensures that the system is powered immediately
after VIN is applied, even with a completely dead battery.
Two ideal diode controllers drive external MOSFETs to
provide low loss power paths from VIN and VBAT to the
system. Tw o ideal diodes work with the charger to provide
power from VBAT to the system without back driving VIN.
The ideal diode from VBAT to the system load guarantees
that power is available to the system even if there is insuf-
ficient or absent power from VIN. The ideal diode from VIN
to the system load guarantees neither VBAT or the system
will back drive VIN.
A wide range of input current settings as well as battery
charge current settings are available by software control
and the values of sense resistors RSNSI and RSNSB. A
measurement subsystem periodically monitors and re-
ports system parameters via the I2C serial port. Included
in this subsystem is a Coulomb counter to allow battery
gas gauging.
An interrupt subsystem can be enabled to alert the host
microprocessor of various status change events so that
system parameters can be varied as needed by the system.
Many status change events are maskable for maximum
flexibility.
To eliminate battery drain between manufacture and sale,
a ship-and-store feature reduces the already low battery
drain and optionally disconnects power from downstream
circuitry.
The input undervoltage current loop (UVCL) can be engaged
to help keep the input voltage from decreasing beyond a
minimum voltage when a resistive cable or power limited
supply such as a solar panel is providing input power to
the LTC4015. A maximum power point algorithm using this
control loop has been preprogrammed into the LTC4015
to maximize power extraction from solar panels and other
resistive sources.
Finally, the LTC4015 has a digital subsystem that provides
substantial adjustability so that power levels and status
information can be controlled and monitored via the simple
2-wire I2C serial port.
LTC4015 Digital System Overview
The LTC4015 contains an advanced digital system which
can be optionally accessed using the I2C serial port. The
LTC4015 digital system can be used extensively in the
application or not at all, as dictated by the application
requirements. This data sheet provides extensive details
of the digital functions of the LTC4015, though much of
this detail is not required for simpler applications.
Use of the serial port is completely optional. Even without
use of the serial port, the LTC4015 is a fully functioning high
performance battery charger which is highly configurable
using external components and pin connections. Chem-
istry/algorithm, cell count, charge current, input current
regulation (ICL), VIN undervoltage regulation (UVCL),
maximum power point tracking (MPPT), and switching
charger frequency and compensation are all externally
configurable without using the serial port.
For applications requiring the LTC4015’s advanced digital
features, the serial port provides a means to use the Cou-
lomb counter, read status and ADC telemetry data from
the measurement system, monitor charger operation,
configure charger settings (e.g. charge voltage, charge
current, temperature response, etc), enable/disable/read/
clear alerts, activate low power ship mode, and enable/
disable the battery charger.
Detailed information about the digital system and the serial
port registers, as well as digital system usage examples,
can be found in the section LTC4015 Digital System.
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OPERATION
Power Path Ideal Diode Controllers
The LTC4015 features input and output ideal diode control-
lers. These controllers make up a power path that allows
power to be delivered to the system (VSYS) by either VIN or
VBAT, whichever is greater. The input ideal diode provides
a one way path from VIN to VSYS. The output ideal diode
provides a one way path from VBAT to VSYS.
The ideal diode controllers consist of a precision ampli-
fier that drives the gate of a MOS transistor whenever the
voltage at VSYS is approximately 15mV (VFWD) below the
voltage at VIN or VBAT. Within the amplifier’s linear range,
the small signal resistance of the ideal diode will be quite
low, keeping the forward drop near 15mV. At higher cur-
rent levels, the MOS transistors will be in full conduction.
The input ideal diode controller assumes control of an
external NMOS transistor by modulating the gate voltage
of the NMOS transistor to allow current to flow from VIN
to VSYS while blocking current in the opposite direction to
prevent back driving VIN. Additionally a fastoff comparator
shuts off the NMOS if VIN falls 25mV below VSYS.
The output ideal diode provides a path for VBAT to power
VSYS when VIN is unavailable, while blocking current in the
opposite direction to prevent overcharging of the battery.
The output ideal diode controller controls an external PMOS
transistor by modulating the gate voltage of the PMOS
transistor. In addition to a fast-off comparator the output
ideal diode also has a fast-on comparator that turns on
the external MOSFET when VSYS drops 45mV below VBAT.
When limited power is available to the switching charger
because either the programmed input current limit or input
undervoltage limit is active, charge current will automati-
cally be reduced to prioritize power delivery to the system
load. Note that the LTC4015 only limits charge current,
but does not limit current from the input to the system
load—if the system load alone requires more power than
is available from the input after charge current has been
reduced to zero, VSYS must fall to the battery voltage in
order for the battery to provide supplemental power. Note
that a system load fault can dissipate very large amounts
of power, as the system load current will not be limited
by the ideal diode controllers.
Input Current Regulation (ICL)
The LTC4015 contains a control loop, ICL (input current
limit), that automatically reduces charge current when the
overall average input current reaches a maximum level.
The input current regulation function can only reduce
charge current to zero, it cannot limit the overall input
current which is a function of the load on VSYS.
This level is set by the combination of the current
sense resistor RSNSI from CLP to CLN and either the
default 32mV servo voltage or a value programmed into
IIN_LIMIT_SETTING via the serial port. The maximum
servo voltage that can be programmed is 32mV. The
voltage across the sense resistor divided by its value
determines the target maximum possible input current. A
2mΩ resistor, for example, would have an upper limit of
input current of 16A using a 32mV servo voltage.
Input Undervoltage Regulation (UVCL) and Solar
Panel Maximum Power Point Tracking (MPPT)
The LTC4015 contains a control loop, UVCL (under
voltage current limit) that allows it to tolerate a resistive
connection to the input power source by automatically
reducing charge current as VIN (as observed at the UVCLFB
pin using a VIN voltage divider ) drops to a programmable
level (VIN_UVCL_SETTING). This circuit helps prevent
UVLO oscillations by regulating the input voltage above
the LTC4015’s undervoltage lockout level. The UVCL
function can only reduce charge current to zero, it cannot
limit the overall input current which is also a function of
the load on VSYS.
Optionally, the LTC4015 includes a maximum power
point tracking (MPPT) algorithm to find and track the
VIN_UVCL_SETTING that delivers the maximum charge
current to the battery. If enabled by the MPPT pin or
by the mppt_en_i2c bit via the serial port, the MPPT
algorithm performs a sweep of VIN_UVCL_SETTING
values, measuring battery charge current at each setting.
When the sweep is completed, the LTC4015 applies the
VIN_UVCL_SETTING value corresponding to the maximum
battery charge current (i.e. the maximum power point).
The LTC4015 then tracks small changes in the maximum
power point by slowly dithering the VIN_UVCL_SETTING.
The LTC4015 periodically performs a new sweep of
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OPERATION
VIN_UVCL_SETTING values, applies the new maximum
power point, and resumes dithering at that point. With the
automatic MPPT algorithm enabled, a solar panel can be
used as a suitable power source for charging a battery
and powering a load. The MPPT feature can be enabled
either via the serial port or by connecting the MPPT pin to
the 2P5VCC pin or a suitable GPIO from a microcontroller.
The MPPT algorithm may not work for all solar panel
applications and does not have to be used, alternatively a
solar panel can be used without the MPPT algorithm by
setting the UVCL VIN minimum value to match the optimum
loaded solar panel voltage by selecting the appropriate
VIN_UVCL_SETTING and UVCLFB pin resistor divider.
Serial Port, SMBus and I2C Protocol Compatibility
The LTC4015 uses an SMBus/I2C style 2-wire serial port
for programming and monitoring functions. Using the
serial port, the user may program alerts, set control pa-
rameters and read status data. The timing diagram shows
the relationship of the signals on the bus. The two bus
lines, SDA and SCL, must be HIGH when the bus is not in
use. External pull-up resistors or active loads, such as the
LTC1694 SMBus accelerator, are required on these lines.
The LTC4015 is both a slave receiver and slave transmitter.
It is never a master. The control signals, SDA and SCL, are
scaled internally to the DVCC supply in compliance with
the I2C specification. DVCC must be connected to the same
power supply as the bus pull-up resistors.
Aside from electrical levels and bus speed, the SMBus
specification is generally compatible with the I2C bus
specification, but extends beyond I2C to define and stan-
dardize specific protocol formats for various types of
transactions. The LTC4015 serial port is compatible with
the 400kHz speed and ratiometric input thresholds of the
I2C specification and supports the read word and write
word protocols of the SMBus specification. It has built-in
timing delays to ensure correct operation when addressed
from an I2C compliant master device. It also contains input
filters designed to suppress glitches.
Programmable Alerts and Interrupt Controller
The serial port supports the SMBus SMBALERT proto-
col. An alert can optionally be generated if a monitored
parameter exceeds a programmed limit or if selected bat-
tery charger states or status events occur. This offloads
much of the continuous monitoring from the system’s
microcontroller and onto the LTC4015; reducing bus traffic
and microprocessor load.
The SMBALERT pin is asserted (pulled low) whenever an
enabled alert occurs (see the following tables and register
descriptions). The LTC4015 will de-assert (release) the
SMBALERT pin only after successfully responding to an
SMB alert response address (ARA). The alert response is
an SMB protocol used to respond to an SMBALERT. The
host reads from the alert response address 0001_1001b
(0x19) and each part asserting SMBALERT begins to
respond with its address. The responding parts arbitrate
in such a way that only the part with the lowest address
responds. Only when a part has responded with its address
does it release the SMBALERT signal. If multiple parts
are asserting the SMBALERT signal then multiple reads
from the ARA are needed. Therefore, only a response of
1101_0001b (0xD1) will clear the LTC4015/SMBALERT
signal. Any other response indicates a device with a lower
I2C address also requests attention from the host. For more
information refer to the SMBus specification.
Table 1. Shows a Summary of LTC4015 Limit Alerts. Each Alert
Has an Associated Enable (Mask), Limit, and Bit That Is Set to 1
to Indicate the Enabled Alert Has Occurred.
LIMIT ALERTS
ALERT
ENABLE
BITS
(0x0D)
ALERT
LIMIT SET
POINT
REGISTER
ALERT
REPORTING
BITS (0x36)
Measurement System Valid Alert
(ADC Ready) 15 N/A 15
Reserved 14 N/A N/A
Coulomb Counter Accumulator Low
and High Alert 13, 12 0x10, 0x11 13, 12
Battery Voltage Low and High Alert 11, 10 0x01, 0x02 11, 10
Input Voltage Low and High Alert 9, 8 0x03, 0x04 9, 8
System Voltage Low and High Alert 7, 6 0x05, 0x06 7, 6
Input Current High Alert 5 0x07 5
Battery Current Low Alert 4 0x08 4
Die Temperature High Alert 3 0x09 3
Battery Series Resistance High Alert 2 0x0A 2
NTC Ratio High and Low Alert 1, 0 0x0B, 0x0C 1, 0
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OPERATION
Table 2. Shows a Summary of LTC4015 Charger State Alerts.
Each Alert Has an Associated Enable (or Mask), and Bit That Is
Set to 1 to Indicate the Alert Has Occurred.
CHARGER STATE ALERTS
ALERT ENABLE
BITS (0x0E)
ALERT
REPORTING
BITS (0x37)
Equalize 10 10
Absorb 9 9
Charger Suspended 8 8
Precharge 7 7
CC_CV 6 6
NTC Pause 5 5
Timer Termination 4 4
C/x Termination 3 3
Max Charge Time Fault 2 2
Battery Missing Fault 1 1
Battery Short Fault 0 0
Table 3. Shows a Summary of LTC4015 Charger Status Alerts.
These Alerts Indicate Which Control Loop Is in Control During
Charging. Each Alert Has an Associated Enable (or Mask), and
Bit That Is Set to 1 to Indicate the Alert Has Occurred.
CHARGER STATUS ALERTS
ALERT
ENABLE BITS
(0x0F)
ALERT
REPORTING
BITS (0x38)
UVCL (VIN Undervoltage Charge Current
Limiting) 3 3
ICL (IIN Charge Current Limiting) 2 2
CC (Constant-Current Mode) 1 1
CV (Constant-Voltage Mode) 0 0
Measurement Subsystem
The LTC4015 includes a 14-bit analog-to-digital converter
(ADC) and signal channel multiplexer to monitor several
analog parameters. It can measure the voltages at VIN,
SYS and BATSENS, the current into the SYS node (voltage
across RSNSI), the battery charge current (voltage across
RSNSB), the voltage across the battery pack thermistor,
and its own internal die temperature. After a charge
cycle begins the LTC4015 uses the appropriate analog
parameters to calculate the series resistance of the battery.
To save battery power the measurement system will not
run if the battery is the only source of power, unless the
force_meas_sys_on bit is set.
The converter is automatically multiplexed between all
of the measured channels and its results are stored in
registers accessible via the I2C port.
The seven channels measured by the ADC each take ap-
proximately 1.6ms to measure. The result of the analog-
to-digital conversion is stored in a 16-bit register as a
signed, two’s complement number. The lower two bits
of this number are sub-bits. These bits are ADC outputs
which are too noisy to be reliably used on any single
conversion, however, they may be included if multiple
samples are averaged. The maximum range of the ADC
is ±1.8V, which gives a LSB size of 3.6V/65535 (216 – 1).
Table 4 summarizes the LSB scaling and resultant LSB
size for these ADC measurements.
Table 4. Measurement Subsystem Scaling and LSB Size
ADC LSB (3.6V/65535) = 54.932479 µV
MEASUREMENT
REGISTER
SYMBOL
REGISTER
NUMBER LSB SCALING LSB SIZE UNITS
VBATSENS/Cellcount (Lithium Chemistries) VBAT 0x3A *7/2 192.264 µV
VBATSENS/Cellcount (Lead-Acid) VBAT 0x3A *7/3 128.176 µV
VIN VIN 0x3B *30 1.648 mV
VSYS VSYS 0x3C *30 1.648 mV
VRSNSB (VCSP – VCSN) IBAT 0x3D /37.5 1.465 µV
VRSNSI (VCLP – VCLN) IIN 0x3E /37.5 1.465 µV
Die Temperature (Note 1) DIE_TEMP 0x3F 1 54.932 µV
Note 1: DIE_TEMP is the ADC conversion of a internal PTAT (proportional to absolute temperature) voltage. DIE temperature = (DIE_TEMP – 12010)/45.6
in °C.
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Figure 1. NTC Bias Configuration
4015 F01
RNTCBIAS
NTCBIAS
NTC
T RNTC
THERMISTOR
OPERATION
When input power is absent, the measurement system can
be sampled periodically at reduced battery load using the
following procedure as an example:
a. Write en_meas_sys_valid_alert = 1
b. Write force_meas_sys_on = 1
c. Wait for SMBALERT to go low (typically 20ms from
force_meas_sys_on = 1)
d. Upon SMBALERT going low, perform ARA command. If
there are multiple slave devices, verify that the LTC4015
is asserting the alert.
e. Verify meas_sys_valid_alert = 1
f. Write en_meas_sys_valid_alert = 0
g. Write force_meas_sys_on = 0
h. Read updated measurement system data from the
LTC4015
This procedure can be repeated at desired intervals (for
example, once per second) in order to periodically moni-
tor the system.
Thermistor/NTC Measurement
chosen thermistor at 25°C (r25). NTC_RATIO (0x40) is
available via the serial port, except when the ship mode
feature has been activated.
The LTC4015 measurement system is configured to directly
calculate NTC_RATIO, where:
NTC_RATIO=21845
R
NTC
RNTCBIAS+RNTC
RNTC=RNTCBIAS NTC_RATIO
21845NTC_RATIO
NTC_RATIO has a bit weight of 1/21845 = 4.5777–5/LSB.
For a NTC_RATIO of 0.5, where RNTC = RNTCBIAS, the
value of NTC_RATIO reported by the serial port would be
approximately 10922.
The data in the first two columns in the following table
are from a Vishay NTC thermistor with a R25 of 10k
and β value of 3490k, such as provided by a Vishay
NTCS0402E3103FLT or NTHS0402N02N1002JE. The
NTC_RATIO value is 21845 • [RNTC/( RNTC + RNTCBIAS )],
where RNTCBIAS = R25 = 10k.
TEMPERATURE RNTC NTC_RATIO
10.0 18290 14122
15.0 14867 13059
20.0 12157 11985
25.0 10000 10922
30.0 8272 9889
35.0 6879 8902
40.0 5751 7975
Steps to find NTC resistor temperature given a NTC_RATIO value;
1. Retrieve value for the NTC_RATIO from the LTC4015 via the I2C port
2. Calculate RNTC;
3. Using the calculated RNTC, use NTC resistor manufacturers data to
determine temperature.
Battery temperature is sensed by using an external NTC
(negative temperature coefficient) thermistor, RNTC. RNTC
is normally located in the battery pack. Connect RNTC
between the NTC pin and ground. A bias resistor, RNTCBIAS,
is connected between NTCBIAS and NTC. RNTCBIAS should
be a 1% resistor with a value equal to the value of the
RNTC=RNTCBIAS
NTC_RATIO
21845NTC_RATIO
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OPERATION
ICL, UVCL, ICHARGE and VCHARGE DACS
The LTC4015 has four DAC’s for setting target values of:
1. Maximum battery charge voltage (VCHARGE_
SETTING)
2. Maximum battery charge current (ICHARGE_
TARGET)
3. Minimum input voltage, UVCL (VIN_UVCL_SETTING)
4. Maximum input current (IIN_LIMIT_SETTING)
The user can program the target values only with the I2C
port. The LTC4015 uses the target values as a starting point,
the charging algorithms calculate the actual values to be
applied to the DACs to support functions such as Li-Ion
precharge, absorb and equalize charge voltage adders,
MPPT, lead-acid charge voltage temperature compensa-
tion, and charger soft starting.
The target value register is read/write, the actual value
register is read only. In the case of the UVCL register,
minimum input voltage is scaled by external resistors.
For further information see the Register Description and
Battery Charging sections.
JEITA temperature controlled charging does not use
VCHARGE_SETTING or ICHARGE_TARGET for setting
target values, see JEITA Temperature Controlled Charging
section for further information.
Charging Timers
There are a total of four timers in the LTC4015 used in the
charging algorithms. Timers are 16-bit, and measure time
in seconds. 216 = 65535 seconds or 18.2 hours maximum.
Each timer has current value (read only) and a timeout
value (read/write):
TIMED
PARAMETER
CURRENT
VALUE
TIMEOUT
VALUE
APPLICABLE
CHEMISTRIES
Constant-Voltage
State Time CV_TIMER (0x31) MAX_CV_TIME
(0x1D) Lithium
Chemistries
Maximum Total
Charge Time MAX_CHARGE_
TIMER (0x30) MAX_CHARGE_
TIME (0x1E) Lithium
Chemistries
Maximum
Absorb Charge
Time
ABSORB_TIMER
(0x32) MAX_ABSORB_
TIME (0x2B) LiFeP04,
Lead-Acid
Maximum
Equalize Charge
Time
EQUALIZE_
TIMER (0x33) EQUALIZE_TIME
(0x2D) Lead-Acid
Low Power Ship Mode
The LTC4015 can reduce its already low standby current
to approximatelyA in a special mode designed for
shipment and storage. Ship mode is armed by setting the
ARM_SHIP_MODE register to 0x534D (ASCII for SM) via
the serial port. Note that once armed, ship mode cannot
be disarmed (the ARM_SHIP_MODE register cannot be
cleared once set to 0x534D). Once armed, ship mode takes
The Target and Actual Registers as Well as the DAC Size are Shown Below:
FUNCTION TARGET VALUE REGISTER ACTUAL VALUE REGISTER
NAME
HEX ADDRESS
(SIZE) DEFAULT NAME
HEX ADDRESS
(SIZE) DEFAULT
Input Current Limit IIN_LIMIT_SETTING 0x15(5:0) 0x3F IIN_LIMIT_DAC 0x46(5:0) 0x3F
Battery Charge Voltage VCHARGE_SETTING 0x1B(5:0)10x3F VCHARGE_DAC 0x45(5:0) 0x3F
Minimum Input Voltage
(UVCL) VIN_UVCL_SETTING 0x16(8:0) 0xFF Scaled by External
Resistors
Battery Charge Current ICHARGE_TARGET 0x1A(4:0) 0x1F ICHARGE_DAC 0x44(4:0) 0x1F
1 Lithium chemistries = 5b (4:0), lead-acid chemistry = 6b (5:0)
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OPERATION
effect when the input voltage drops below approximately
1V. Upon return of the input voltage above approximately
1V the LTC4015 wakes from ship mode and all registers
reset to their initial default values. The decision to remain
out of ship mode is latched once the voltage reference is
re-biased and INTVCC is detected as having reached about
4.3V. Upon exiting ship mode, all internal registers are
reset to their default values.
If the application requires that power be cut off from
downstream system circuitry in SHIP MODE, a second
external PMOS can optionally be added as shown in
Figure 2. Unlike normal battery only mode, in ship mode
the SYSM5 pin is driven to the SYS voltage to disable
conduction through the second PMOS. This action cuts
off power to the downstream system, thus minimizing
battery drain between product manufacture and sale. If
the application does not require the battery to be isolated
from downstream devices, significant power savings in
the LTC4015 may still be realized by activating ship mode
without the second PMOS.
Figure 2. Typical Application with Optional PMOS Added for SHIP MODE Cutoff
LTC4015
VIN
UVCLFB
µCONTROLLER
VIN
SMBALERT
DVCC
SCL
SDA
CELLS0
CELLS1
CELLS2
CHEM0
CHEM1
RT
VC
CCREFP
CCREFM
EQ
INFET CLP
RSNS1
CLN SYS SYSM5
4015 F02
OUTFET
SYSTEM
OPTIONAL PMOS ADDED
TO CUT OFF SYSTEM
LOAD IN SHIP MODE
INTVCC
DRVCC
BOOST
TG
SW
BG
2P5VCC
CSPM5
CSP
CSN
RNTCBIAS
RSNSB
BATSENS
NTCBIAS
NTC
CHEMISTRY/
CELL COURT
SELECTION
LEAD-ACID
EQUALIZE
CHARGE
(PADDLE)
GND
SGND MPPT
MPPT
ENABLE
RNTC
BATTERY
PACK
T
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OPERATION
Cells Selection
Number of series cells selection is made using the
CELLS2, CELLS1, and CELLS0 pins. For lithium chem-
istries the LTC4015 allows charging of up to nine series
cells. For lead-acid there are only three valid selections
3, 6 or 12 cells corresponding to 6, 12, and 24V batteries
respectively. Note that number of cells multiplied by their
expected maximum cell voltage during charging cannot
exceed VIN – 200mV. With VIN/VSYS limited to 35V as an
upper bound for VBAT, at nine cells the maximum V/cell
would be 3.89V. In practice the 3.89V/cell will be lower,
due to several factors including; input ideal diode drop
(VINVSYS) and switcher max duty cycle. These pins
should be hard wired to GND(L), INTVCC(H), or left open
(Z). The LTC4015 does not monitor or balance individual
cellsthe full battery stack voltage is divided by number
of cells (V/cell) for simplicity only. The 4015 is not a
substitute for pack protection!
NUMBER OF
CELLS CELLS2 CELLS1 CELLS0
Invalid L L L
1 L L H
2 L H L
3 L H H
4LLZ
5LZL
6 L H Z
7 L Z H
8LZZ
9 H L L
Invalid H L H
Invalid H H L
12* H H H
* Lead-acid only
Chemistry Selection
Chemistry selection is made using the CHEM1 and CHEM0
pins. These are three-state pins used by the LTC4015 to
select of one of nine chemistry specific charging algorithms.
These pins should be hard wired to GND(L), INTVCC(H),
or left open (Z).
CHEMISTRY CHEM1 CHEM0
Li-Ion Programmable L L
Li-Ion 4.2V/Cell Fixed H H
Li-Ion 4.1V/Cell Fixed L Z
Li-Ion 4V/Cell Fixed Z L
LiFePO4 Programmable L H
LiFePO4 Fixed Fast Charge H Z
LiFePO4 Fixed Standard Charge Z H
Lead-Acid Fixed Z Z
Lead-Acid Programmable H L
Li-Ion/LiFePO4 Battery Charging
It is the responsibility of the user of the LTC4015 to
consult with the battery manufacturer to determine the
recommended charging parameters for a particular battery.
Battery allowable temperature range while charging and
any required charging parameter temperature coefficients
also need to be considered.
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OPERATION
Table 5. Li-Ion Charging Parameters
CHARGING
ALGORITHM
ICHARGE_
TARGET
VCHARGE
(PER CELL)
CV TIMER
TERM ENABLE
MAX CV
TIME
C/x TERM
ENABLE
C/x
THRESH JEITA
MAX
CHARGE
TIME
LOW BAT
PRECHARGE
CURRENT
LOW BAT
THRESHOLD
(PER CELL)
Li-Ion
Programmable 32mV/
RSNSB14.201Yes 4 Hours No 10% Y 18 Hrs ~10%22.9V
Li-Ion 4.2V/cell
Fixed 32mV/
RSNSB14.201Yes 4 Hours No Y 18 Hrs ~10%22.9V
Li-Ion 4.1V/cell
Fixed 32mV/
RSNSB14.101Yes 4 Hours No Y 18 Hrs ~10%22.9V
Li-Ion 4V/cell
Fixed 32mV/
RSNSB14.001Yes 4 Hours No Y 18 Hrs ~10%22.9V
Li-Ion/Charging Parameters
Table 5 shows Li-Ion charging parameters. For Li-Ion
programmable, defaults values are shown.
Bold parameters are I2C programmable in Li-Ion
programmable mode only. ICHARGE_TARGET and
VCHARGE_SETTING values are at 25°C if JEITA is en-
abled1. Shown in Figure 3 is an example of a Li-Ion battery
charging profile. Shown in Table 6 are the Li-Ion program-
mable I2C configurable charging parameters.
Table 6. Li-Ion Programmable I2C Configurable Parameters
PROGRAMMABLE MODE
PARAMETER RANGE BITS RESOLUTION
ICHARGE_TARGET11mV to 32mV/
RSNSB
5 1mV/RSNSB
VCHARGE_SETTING13.8125V to
4.2V/Cell 5 12.5mV
MAX_CV_TIME 0 to 65535 16 1 Second
en_jeita 0, 1 1 1 = Enable
en_c_over_x_term 0, 1 1 1 = Enable
C_OVER_X_THRESHOLD 0mV to 32mV/
RSNSB
16 1.465µV/RSNSB
MAX_CHARGE_TIME 0 to 65535 16 1 Second
Notes
1) When JEITA is enabled (en_jeita=1), ICHARGE_TARGET and
VCHARGE_SETTING are controlled by the JEITA temperature controlled
charging algorithm, as described in the descriptions for ICHARGE_
JEITA_n and VCHARGE_JEITA_n.
2) Precharge current is 10% of ICHARGE_TARGET, rounded down to
the next LSB.
Figure 3. Li-Ion 4.2V/Cell Fixed Charging Profile
TIME (hr)
VBAT (VCELL)
ICHG (A)
4015 F03
4.5
4.0
3.0
2.5
2.0
1.5
1.0
0.5
3.5
0
12
9
6
3
0
0 1 4 5 632
VBAT
ICHG
CC_CV/CC
CC_CV/CV
4HOUR CV TIMER
TERMINATION
TEXT INDICATES VALUES REPORTED IN REGISTERS:
CHARGER_STATE/CHARGE_STATUS
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OPERATION
LiFePO4 Charging Parameters
Table 7 shows LiFePO4 charging parameters. For LiFePO4
programmable, defaults values are shown. Bold parameters
are I2C programmable in LiFePO4 programmable mode
only. ICHARGE_TARGET and VCHARGE_SETTING values
Table 7. LiFePO4 Charging Parameters
CHARGING
ALGORITHM
ICHARGE_
TARGET
VABSORB,
MAX_
ABSORB_
TIME IN
MINUTES
VCHARGE
(PER CELL)
CV
TIMER
TERM
MAX CV
TIME C/x TERM
C/x
THRESH JEITA
MAX CHARGE
TIME
LiFePO4 Programmable 32mV/
RSNSB1No Absorb
Phase
3.601Yes 1 Hour No 10% Y 18 Hrs
LiFePO4 Fixed Standard
Charge 32mV/
RSNSB1No Absorb
Phase 3.601Yes 1 Hour No Y 18 Hrs
LiFePO4 Fixed Fast
Charge 32mV/
RSNSB13.8, 15 3.601Yes 1 Hour No 10%
(Absorb) Y 18 Hrs
1: When JEITA is enabled ICHARGE_TARGET and VCHARGE_SETTING are overridden and controlled by the JEITA temperature qualified charging
algorithm.
are at 25°C when JEITA is enabled. Shown in Table 8 are
the LiFePO4 programmable I2C configurable charging
parameters. Shown in Figure 4 is the LiFePO4 fixed fast
charge charging profile.
Table 8. LiFePO4 Programmable I2C Configurable Parameters
PROGRAMMABLE MODE
PARAMETER RANGE BITS RESOLUTION
ICHARGE_TARGET11mV to
32mV/RSNSB
5 1mV/RSNSB
VABSORB_DELTA 0V to 0.4V 5 12.5mV
MAX_ABSORB_TIME 0 to 65535 16 1 Second
VCHARGE_SETTING13.4125V to
3.8V/Cell 5 12.5mV
MAX_CV_TIME 0 to 65535 16 1 Second
en_jeita 0,1 1 1 = Enable
en_c_over_x_term 0,1 1 1 = Enable
C_OVER_X_THRESHOLD 0mV to
32mV/RSNSB
16 1.465µV/
RSNSB
MAX_CHARGE_TIME 0 to 65535 16 1 Second
LiFePO4_RECHARGE_THRESHOLD 0 to 4.2V/Cell 16 192.26µV
Notes
1: When JEITA is enabled ICHARGE_TARGET and VCHARGE_SETTING
are overridden and controlled by the JEITA temperature qualified
charging algorithm.
Figure 4. LiFePO4 Fast Charge Charging Profile
TIME (min)
VBAT (VCELL)
ICHG (A)
4015 F04
4.5
4.0
3.0
2.5
2.0
1.5
1.0
0.5
3.5
0
12
9
6
3
0
0 5 20 25 301510
VBAT
ICHG
ABSORB/CC CC_CV/CV
ABSORB/CV
TEXT INDICATES VALUES REPORTED IN REGISTERS:
CHARGER_STATE/CHARGE_STATUS
CV TIMER TERMINATION
AFTER ONE HOUR IN
CC_CV/CV PHASE
LTC4015
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OPERATION
Li-Ion/LiFePO4 Battery Charger Operation
The LTC4015 provides full featured, inherently safe,
constant-current/constant-voltage Li-Ion/LiFePO4 battery
charging. Features include battery presence detection,
automatic recharge, maximum charge time safety timer,
precharge (Li-Ion only), rapid absorb charge (LiFePO4
only), programmable CV timer and C/x termination, therm-
istor temperature controlled charging, programmable
end-of-charge indication, programmable charge voltage,
programmable charge current, J.E.I.T.A. support, battery
series resistance measurement, detailed status reporting,
and programmable interrupt generation.
LTC4015 Charge Algorithm Overview
The LTC4015 charge algorithms are based on a constant-
current constant-voltage charging (CC-CV)technique. The
battery is charged at a constant-current (CC) until the
battery reaches its charge voltage (VCHARGE) whereupon
the delivered charge current is automatically reduced
to maintain the battery at a constant VCHARGE (CV). The
LTC4015 does not monitor or balance individual cells
the full battery stack voltage is divided by number of cells
(V/cell) for simplicity only. The 4015 is not a substitute
for pack protection!
Under voltage current limiting (UVCL) is used to automati-
cally reduce charge current to help keep VIN from falling
below a minimum voltage. Input current limiting (ICL) is
used to automatically limit charge current to help keep
Input current below a maximum level. However, UVCL
and ICL can only reduce charge current. The total load
current from VIN cannot be limited by the LTC4015 if the
load on the system exceeds the ICL setpoint.
Li-Ion Charge Algorithm Overview
(See Figure 5A for Li-Ion battery charging state diagram)
The charge algorithm begins with a battery detection test
and proceeds to constant-current constant-voltage (CC-
CV) charging. If the Li-Ion battery voltage is very low the
charger will charge at a reduced (precharge) CC rate until
the battery voltage reaches an acceptable level. Then it will
be charged at the full CC rate. CC-CV charging continues
until the charge cycle terminates based on time (default)
or battery current (C/x for Li-Ion programmable option).
LiFePO4 Charge Algorithm (without Absorption
Phase) Overview
(See Figure 5B for LiFePO4 battery charging state diagram)
The charge algorithm begins with a battery detection test
and proceeds to constant-current constant-voltage (CC-
CV) charging. CC-CV charging continues until the charge
cycle terminates based on time in CV mode (default) or
battery current (C/x for LiFePO4 programmable option).
Remaining in constant-voltage mode without termination
is also a LiFePO4 programmable option.
LiFePO4 Charge Algorithm (with Absorption Phase)
Overview
(See Figure 5B for Li-FePO4 battery charging state diagram)
An absorb phase can allow accelerated charging by raising
the charge voltage, which may result in a higher CC rate,
for a portion of the charge cycle. The charge algorithm
begins with a battery detection test and proceeds to CC-CV
charging with a charge voltage of VABSORB, which is an
absorb delta added to VCHARGE. CC-CV absorption charging
continues until the VABSORB is reached and charge current
has dropped below the C/x threshold, or the maximum
absorb phase time has passed. Upon exiting the absorb
phase the charge voltage is reduced from VABSORB to
VCHARGE. CC-CV charging continues until the charge cycle
terminates based on time in CV mode (default) or charge
current (C/x) (LiFePO4 programmable option). Remaining
in constant-voltage mode without termination is also a
LiFePO4 programmable option.
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OPERATION
Figure 5A. Li-Ion Battery Charging State Diagram
CHARGER_
SUSPENDED*
BATTERY
DETECTION
SHORTED
BATTERY
NO BATTERY 30 SECOND
TIME OUT
BAT_MISSING_
FAULT
PRECHARGE
BATTERY VOLTAGE
> 2.9 V/CELL
MAX_CHARGE_TIME_FAULT
MAX_CHARGE_TIME
PASSED
VBAT < 35%
OF VCHARGE
NTC_RATIO
BETWEEN JEITA_T7
AND JEITA_T1
* NOTE: ALL STATES RETURN TO CHARGER SUSPENDED IF ANY OF THE FOLLOWING OCCUR:
A. THE INPUT VOLTAGE VIN FALLS TO WITHIN 100mV OF THE BATSENS PIN VOLTAGE.
B. SUSPEND_CHARGER IS WRITTEN TO 1 VIA THE SERIAL PORT.
C. A SYSTEM FAULT OCCURS (VIN OVERVOLTAGE LOCKOUT, 2P5VCC UNDERVOLTAGE LOCKOUT, INTVCC
UNDERVOLTAGE LOCKOUT, DRVCC UNDERVOLTAGE LOCKOUT. THERMAL SHUTDOWN, MISSING RT
RESISTOR, OR INVALID COMBINATION OF CELLS PINS).
NTC_RATIO
BELOW JEITA_T7
OR ABOVE JEITA_T1
TO NTC
PAUSE
BATTERY VOLTAGE
> 2.85V/CELL
MAX_CHARGE_TIMER STARTS
C_OVER_X_TERM
4015 F05a
MAX_CV_TIME PASSED
WITH BATTERY AT
VCHARGE (CV)
BATTERY AT VCHARGE (CV)
—AND—
ICHG < C_OVER_X_THRESHOLD
—AND—
EN_C_OVER_X_TERM = 1
RECHARGE THRESHOLD
REACHED
RECHARGE THRESHOLD
REACHED
BATTERY
VOLTAGE
STABLE
BATTERY VOLTAGE
< 2.85 VCELL
CC_CV_CHARGE
BAT_SHORT_
FAULT
NTC_PAUSE
NTC_RATIO
OUT OF RANGE
TO BAT_MISSING_
FAULT
RETURN TO PREVIOUS
CHARGE STATE
NTC_RATIO
BELOW JEITA_T7
OR ABOVE JEITA_T1
TO NTC
PAUSE
TIMER_TERM
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OPERATION
Figure 5B. LiFePO4 Battery Charging State Diagram
CHARGER_
SUSPENDED*
BATTERY
DETECTION
SHORTED
BATTERY
NO BATTERY 30 SECOND
TIME OUT
BAT_MISSING_
FAULT
ABSORB
CHARGE
ABSORB_TIME PASSED
—OR—
(ABSORB VOLTAGE REACHED AND
ICHG < C_OVER_X_THRESHOLD)
MAX_CHARGE_TIME_FAULT
MAX_CHARGE_TIME
PASSED
VBAT < 35%
OF VCHARGE
NTC_RATIO
BETWEEN JEITA_T7
AND JEITA_T1
* NOTE: ALL STATES RETURN TO CHARGER SUSPENDED IF ANY OF THE FOLLOWING OCCUR:
A. THE INPUT VOLTAGE VIN FALLS TO WITHIN 100mV OF THE BATSENS PIN VOLTAGE.
B. SUSPEND_CHARGER IS WRITTEN TO 1 VIA THE SERIAL PORT.
C. A SYSTEM FAULT OCCURS (VIN OVERVOLTAGE LOCKOUT, 2P5VCC UNDERVOLTAGE LOCKOUT, INTVCC
UNDERVOLTAGE LOCKOUT, DRVCC UNDERVOLTAGE LOCKOUT. THERMAL SHUTDOWN, MISSING RT
RESISTOR, OR INVALID COMBINATION OF CELLS PINS).
NTC_RATIO
BELOW JEITA_T7
OR ABOVE JEITA_T1
TO NTC
PAUSE
C_OVER_X_TERM
4015 F05a
MAX_CV_TIME PASSED
WITH BATTERY AT
VCHARGE (CV)
—AND—
NOT (MAX_CV_TIME = 0)
BATTERY AT VCHARGE (CV)
—AND—
ICHG < C_OVER_X_THRESHOLD
—AND—
EN_C_OVER_X_TERM = 1
RECHARGE THRESHOLD
REACHED
RECHARGE THRESHOLD
REACHED
BATTERY
VOLTAGE
STABLE
MAX_CHARGE_TIMER STARTS
VABSORB_DELTA > 0
ABSORB_TIMER STARTS
CC_CV_CHARGE
BAT_SHORT_
FAULT
NTC_PAUSE
NTC_RATIO
OUT OF RANGE
TO BAT_MISSING_
FAULT
RETURN TO PREVIOUS
CHARGE STATE
NTC_RATIO
BELOW JEITA_T7
OR ABOVE JEITA_T1
TO NTC
PAUSE
TIMER_TERM
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OPERATION
Battery Detection
The LTC4015 begins a charging cycle by performing a
two to four second battery detection test, during which
a 1mA load is drawn from the battery. If the battery volt-
age remains stable during the battery detection test, the
LTC4015 proceeds with battery charger soft-start. If the
battery voltage does not remain stable, the LTC4015
proceeds with a battery open/short test. The battery is
charged at minimum charge current for one to two seconds.
If the battery voltage as a result of this brief charging is
within a reasonable range the LTC4015 will proceed with
a battery charger soft-start. A battery open fault will also
occur if the NTC resistor is open or has a very high value.
A programmable interrupt can be set to alert the system
if a battery detection fault has occurred.
Battery Charger Soft-Start
The LTC4015 soft starts by ramping ICHARGE_DAC from
0 to ICHARGE_TARGET at a nominal rate of 400µs per
ICHARGE_TARGET LSB. This results in a maximum soft-
start time of 31 • 400µs = 12.4ms.
Maximum Charge Time
The LTC4015, for charging batteries of Lithium chemistries,
provides a maximum charge time safety timer. The MAX_
CHARGE_TIMER starts with the battery charger soft-start
after battery detection. If the total time charging the battery
exceeds MAX_CHARGE_TIME, the charger will enter the
MAX_CHARGE_TIME FAULT state and cease charging.
This fault state can only be exited in normal operation if
the battery voltage is less than 35% of VCHARGE, where
upon a new charge cycle begins and the timer reset.
The timer is reset upon timer or C/x termination. The
MAX_CHARGE_TIME fault state can also be exited as a
result of the input voltage VIN falling to within 100mV of
the BATSENS pin voltage, SUSPEND_CHARGER is written
to a 1 via the serial port or a system fault occurs.
Low Battery/Pre-Charge; Li-Ion
When a Li-Ion battery charge cycle begins, the LTC4015
first determines if the battery is deeply discharged. If
the battery voltage is below 2.85V per cell (VBAT_FILT
below 14822) and BATSENS pin is above 2.6V then the
LTC4015 begins charging by applying a preconditioning
charge equal to ICHARGE_TARGET/10 (rounded down
to the next LSB), and reporting precharge = 1. When the
battery voltage exceeds 2.9V per cell (VBAT_FILT above
15082), the LTC4015 proceeds to the constant-current/
constant-voltage charging phase (cc_cv_charge = 1).
Should the BATSENS pin voltage be lower than 2.4V, the
switching charger operates in constant peak current mode,
where the peak current is 7mV/RSNSB. Exact average cur-
rent value depends on a number of factors including input
voltage, battery voltage and inductance value. When the
BATSENS pin voltage is higher than 2.6V, normal charg-
ing proceeds.
Low Battery; LiFePO4
Low battery for LiFePO4 chemistry is the same as
Li-Ion with the exception that there is no precon-
ditioning charge phase; charge current is set by
ICHARGE_TARGET.
However, if the BATSENS pin voltage is lower than 2.4V,
the switching charger operates in constant peak current
mode, where the peak current is 7mV/RSNSB. Exact average
current value depends on a number of factors including
input voltage, battery voltage and inductance value. When
the BATSENS pin voltage is higher than 2.6V, normal
charging proceeds.
LiFePO4 Absorb Charge
The LTC4015 can optionally perform an accelerated absorb
charge cycle on LiFePO4 batteries. If VABSORB_DELTA
is greater than zero, the LTC4015 begins charging with
an absorb charge phase, and reports absorb_charge = 1
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OPERATION
via the serial port. During absorb charging, the LTC4015
charges at a constant-current ICHG, with a target set by
ICHARGE_TARGET and RSNSB, unless one of the following
conditions occurs:
a) The battery voltage reaches the absorb target voltage
(determined by VCHARGE_SETTING + VABSORB_
DELTA, limited to a maximum of 3.8V/cell), indicated
by constant_voltage=1
b) Input current limit (IIN_LIMIT_SETTING) is reached,
indicated by iin_limit_active=1
c) The UVCLFB pin voltage falls to the undervoltage current
limit (VIN_UVCL_SETTING) ), indicated by vin_uvcl_ac-
tive=1
If either the input current limit or the undervoltage current
limit is activated, the LTC4015 will limit charge current
and will attempt to regulate at the input current or input
voltage limit level, as permitted by the input source and
system load.
LiFePO4 Absorb Phase Ends After Either:
a) MAX_ABSORB_TIME has passed
b) The battery voltage reaches absorb target voltage (as
determined by VCHARGE_SETTING+VABSORB_DELTA,
limited to a maximum of 3.8V/cell), indicated by
constant_voltage=1, and IBAT falls below C_OVER_X_
THRESHOLD. When the absorb phase ends, the LTC4015
proceeds to the CC-CV charging phase.
Constant-Current/Constant-Voltage (CC-CV) Charging
Constant-Current
When the battery voltage is above 2.9V per cell, the
charger will attempt to deliver the programmed charge
current ICHG, as set by ICHARGE_TARGET and RSNSB,
in constant-current mode. Depending on available input
power and external load conditions, the battery charger
may not be able to charge at the full programmed rate. If
input current limit is reached, the system load will always
be prioritized over the battery charge current. Likewise, the
input undervoltage control loop will always be observed
and may limit the power available to charge the battery.
When system loads permit, battery charge current will
be maximized.
The upper limit of charge current ICHG is programmed
by the combination of the current sense resistor (RSNSB)
from CSP to CSN and a servo voltage of 32mV or a value
programmed via the serial port (see register descriptions
for ICHARGE_TARGET and icharge_jeita_n). The voltage
across RSNSB divided by its value determines the maximum
possible charge current. The maximum servo voltage that
can be programmed is 32mV. A 4mΩ resistor, for example,
would have an upper limit charge current of 8A.
Independent of whether or not the charge current loop is
controlling the switching charger, the voltage across the
RSNSB will represent the actual charge current delivered to
the battery. The voltage across RSNSB is measured by the
LTC4015’s onboard measurement system and is available
via the serial port in register IBAT.
RSNSB should be set based on the maximum charge
current of the battery without regard to source or load
limitations from any other control loop. The multiple
control loop architecture of the LTC4015 will correct for
any discrepancies, always sorting out the optimal transfer
of power to the battery.
Battery Series Resistance (BSR) Measurement
The LTC4015 can optionally measure the series resistance
of the battery. If run_bsr is set to 1 the LTC4015 momentarily
suspends the battery charger and calculates the battery
series resistance by dividing the change (charging vs
charger suspended) in battery voltage by the change in
charge current (ICHARGE_BSR). The per cell resistance
value is reported in the BSR register and the change in
charge current is reported in the ICHARGE_BSR register
via the serial port. The LTC4015 resets run_bsr to 0 after
the BSR measurement is complete. The battery series
resistance value is proportional to the charge current
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OPERATION
sense resistor, RSNSB, and can be computed in Ω from
BSR RSNSB/500. Note that the resistance reported in the
BSR register must be multiplied by the total number of
cells to calculate total battery series resistance. The higher
ICHARGE_BSR (charge current) when a BSR measurement
is requested, the more accurate the BSR measurement will
be. Very low values of ICHARGE_BSR may significantly
impact the accuracy of the BSR measurement. Setting
run_bsr to a 1 will not turn the charger on, if the charger
is suspended or in a termination state, setting run_bsr =
1 results in the BSR measurement request being queued
and run after the soft-start of the next charge cycle.
Battery Charge Voltage Regulation, Constant-Voltage
Once the BATSENS voltage reaches the preset charge volt-
age, the switching charger will reduce its output power,
holding the battery voltage steady. The charge current
will decrease naturally toward zero providing inherently
safe operation by preventing the battery from being over-
charged. Multiple charge voltage settings are available for
final charge voltage selection via the serial port. While
charge voltage trade-offs can be made to preserve battery
life or maximize capacity, it is not possible for the LTC4015
to be set to a charge voltage that is dangerously high or
inconsistent with the battery’s chemistry.
Li-Ion LiFePO4 Full Capacity Charge Indication (C/x)
and Charger Termination
The battery charge cycle will terminate at the expiration
of a built-in programmable CV termination safety timer
(CV_TIMER). When the voltage on the battery reaches the
programmed charge voltage, the safety timer is started.
After the safety timer expires, charging of the battery will
discontinue and no more current will be delivered. The
safety timer’s default expiration time may be altered via the
serial port. For Li-Ion cells the timer termination feature
cannot be disabled. For LiFePO4 cells, timer termination
can be disabled by setting MAX_CV_TIME to zero, in this
case, if C/x termination is not enabled, charging will not
terminate. C/x termination cannot be enabled in fixed
chemistry algorithms.
In addition, by monitoring the charge current and other
states of the system, the LTC4015 determines when the
battery has reached a given state of charge. Specifically,
programmable C/x detection in constant-voltage mode
determines when the charge current has naturally dropped
to a given fraction of its full-scale current. If C/x termination
is enabled the charge cycle will end when C/x is reached,
or when then safety timer expires, whichever occurs first.
C/x termination is disabled by default. The LTC4015 can
optionally be configured via the serial port to generate an
interrupt and terminate charging when the C/x threshold
is reached.
The LTC4015 terminates charging by disabling the switch-
ing controller, when this occurs the SW node goes HI Z.
Li-Ion LiFePO4 Automatic Recharge
After the battery charger terminates, it will remain off,
drawing only a small amount of current from the battery.
If the portable product remains in this state long enough,
the battery will eventually self discharge. To ensure that
the battery is always topped off, a new charge cycle will
automatically begin when the battery voltage falls below
approximately 97.5% of the programmed charge voltage
for Li-Ion and 3.35V/cell for LiFePO4(3.35V/cell is the
default for LiFePO4_RECHARGE_THRESHOLD in LiFePO4
programmable mode). The termination safety timer will also
reset back to zero. A new charge cycle will also be initiated
if input power is cycled or if the charger is momentarily
disabled using the serial port (suspend_charger set to 1,
then set to 0).
J.E.I.T.A. Temperature Controlled Charging
For lithium chemistries, a measurement and control
system has been included to enable compliance with the
Japan Electronics and Information Technology Industries
Association guidelines on battery charging. Specifically
a very flexible multi-point temperature-voltage-current
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OPERATION
profile can be programmed into the LTC4015 to ensure
that optimum charging parameters as a function of
temperature are always used. Figure 6 illustrates an
example of the JEITA system available in the LTC4015.
There are seven distinct temperature regions programmed
by the six temperature set points JEITA_T1-JEITA_T6. For
each of the temperature regions, the charge current and
charge voltage can be programmed within the limits set
by VCSP–CSN/RSNSB (ICHARGE) and battery charge voltage
(VCHARGE) for a selected chemistry code.
When JEITA is enabled, charge current is controlled by
ICHARGE_DAC, which in turn is set by icharge_jeita_n of
the applicable JEITA region. Writing ICHARGE_TARGET
has no effect, as it will be overwritten by JEITA. Likewise
VCHARGE is controlled by VCHARGE_DAC which in turn
is set by vcharge_jeita_n of the applicable JEITA region.
The LTC4015 provides temperature controlled charging if
a grounded thermistor and a bias resistor are connected
to the NTCBIAS and NTC pins. Charging is paused if the
temperature rises above a programmable upper limit or
falls below a programmable lower limit.
If the application does not require temperature controlled
charging then the thermistor should be replaced with
a resistor of equal value to bias resistor RNTCBIAS, for
example, 10kΩ.
Figure 6. Default JEITA Temperature Profile, Showing
Values for Li-Ion Fixed 4.2V
TEMPERATURE (°C)
VBAT (VCELL)
CHARGE CURRENT (mV/RSENSE)
4015 F06
4.5
T1 T2 T3 T5T4 T6
4.0
3.0
2.5
2.0
1.5
1.0
0.5
3.5
0
45
40
30
25
20
15
10
05
35
0
0 10 40 50 603020
CHARGE VOLTAGE
CHARGE CURRENT
The values for the JEITA registers are shown in the tables
below. The bold values in the tables are programmable
when using Li-Ion programmable or LiFePO4 program-
mable chemistry selections.
The JEITA_Tn registers determine the NTC_RATIO values
for the breakpoints between regions. The corresponding
temperature values assume a thermistor β value of 3490k,
such as provided by a Vishay NTCS0402E3103FLT or
NTHS0402N02N1002JE. For other thermistors, one or
two inexpensive low temperature coefficient resistors can
generally be added to the circuit to adjust the thermistor’s
biasing (see the section NTC Resistor in Applications
Information for details).
Table Illustrates the JEITA Values That Can Be Programmed Via the Serial Port.
REGION 1 REGION 2 REGION 3 REGION 4 REGION 5 REGION 6 REGION 7
JEITA_T1 JEITA_T2 JEITA_T3 JEITA_T4 JEITA_T5 JEITA_T6
CHARGER
OFF icharge_jeita_2 icharge_jeita_3 icharge_jeita_4 icharge_jeita_5 icharge_jeita_6 CHARGER
OFF
vcharge_jeita_2 vcharge_jeita_3 vcharge_jeita_4 vcharge_jeita_5 vcharge_jeita_6
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Table Default Values for JEITA Parameters
REGION 1 REGION 2 REGION 3 REGION 4 REGION 5 REGION 6 REGION 7
JEITA_T1 = JEITA_T2 = JEITA_T3 = JEITA_T4 = JEITA_T5 = JEITA_T6 =
0x3F00 (0°C) 0x372A (10°C) 0x1F27 (40°C) 0x1BCC (45°C) 0x18B9 (50°C) 0x136D (60°C)
CHARGER
OFF icharge_jeita_2 icharge_jeita_3 icharge_jeita_4 icharge_jeita_5 icharge_jeita_6 CHARGER
OFF
vcharge_jeita_2 vcharge_jeita_3 vcharge_jeita_4 vcharge_jeita_5 vcharge_jeita_6
Li-Ion Programmable
CHARGER
OFF 16mV/RSNSB 32mV/RSNSB 32mV/RSNSB 16mV/RSNSB 16mV/RSNSB CHARGER
OFF
4.20V 4.20V 4.10V 4.10V 4.05V
Li-Ion Fixed 4.2V
CHARGER
OFF 16mV/RSNSB 32mV/RSNSB 32mV/RSNSB 16mV/RSNSB 16mV/RSNSB CHARGER
OFF
4.20V 4.20V 4.10V 4.10V 4.05V
Li-Ion Fixed 4.1V
CHARGER
OFF 16mV/RSNSB 32mV/RSNSB 32mV/RSNSB 16mV/RSNSB 16mV/RSNSB CHARGER
OFF
4.10V 4.10V 4.00V 4.00V 3.95V
Li-Ion Fixed 4.0V
CHARGER
OFF 16mV/RSNSB 32mV/RSNSB 32mV/RSNSB 16mV/RSNSB 16mV/RSNSB CHARGER
OFF
4.00V 4.00V 3.90V 3.90V 3.85V
LiFePO4 Programmable
CHARGER
OFF 16mV/RSNSB 32mV/RSNSB 32mV/RSNSB 16mV/RSNSB 16mV/RSNSB CHARGER
OFF
3.60V 3.60V 3.50V 3.50V 3.45V
LiFePO4 Fixed Fast and Fixed Standard Charge
CHARGER
OFF 16mV/RSNSB 32mV/RSNSB 32mV/RSNSB 16mV/RSNSB 16mV/RSNSB CHARGER
OFF
3.60V 3.60V 3.50V 3.50V 3.45V
OPERATION
Lead-Acid Battery Charging
It is the responsibility of the user of the LTC4015 to
consult with the battery manufacturer to determine the
recommended charging parameters for a particular battery.
Battery allowable temperature range while charging and
any required charging parameter temperature coefficients
also need to be considered.
An example of charging profile (battery voltage and cur-
rent vs. time) for a lead-acid battery is shown in Figure 7.
Lead-Acid Charging Parameters
Following is a table of lead-acid charging parameters.
For lead-acid programmable, default values are shown.
Bold parameters are programmable via the serial port in
lead-acid programmable mode only. All voltages are per
cell at 25°C.
Figure 7. Example Charging Profile for a Lead-Acid Battery
TIME (hrs)
CC-CV/CV
ABSORB/CV
ABSORB/CC
(ALSO CALLED
BULK CHARGING) TEXT INDICATES VALUES REPORTED IN REGISTERS:
CHARGER_STATE/CHARGE_STATUS
EQUALIZE/CC
EQUALIZE/CV
VBAT (VCELL)
ICHG (A)
4015 F07
3.0
2.5
2.0
1.5
1.0
0.5
0
12
8
6
4
2
10
0
0 1 32 TEQ+2TEQ TEQ+4
VBAT
ICHG
CC-CV/CV
LTC4015
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OPERATION
Undervoltage current limiting (UVCL) is used to automati-
cally reduce charge current to help keep VIN from falling
below a minimum voltage. Input current limiting (ICL) is
used to automatically limit charge current to help keep
input current below a maximum level. However, UVCL
and ICL can only reduce charge current. The total load
current from VIN cannot be limited by the LTC4015 if the
load on SYS exceeds the ICL setpoint.
Figure 8. Lead-Acid Battery Charging State Diagram
Lead-Acid Charging Parameters
CHARGING
ALGORITHM
ICHARGE_
TARGET
ABSORB
C_OVER_X_
THRESHOLD
VEQUALIZE,
EQUALIZE TIME
(MINUTES)
VABSORB, MAX
ABSORB TIME
(MINUTES)
END
ABSORB
ON C/x
VCHARGE
(PER CELL)
mV/C
TEMPCO
TEMPCO
ENABLED
Lead-Acid Fixed 32mV/RSNSB 3.2mV/RSNSB 2.60, 60 2.40, 90 Yes 2.20 –3.65 Yes
Lead-Acid
Programmable 32mV/RSNSB 3.2mV/RSNSB 2.60,60 2.40, 90 Yes 2.20 –3.65 Yes
PROGRAMMABLE MODE
PARAMETER RANGE BITS RESOLUTION
ICHARGE_TARGET 1mV to 32mV/
RSNSB
5 1mV/RSNSB
VCHARGE_SETTING 2V to 2.6V/Cell 6 9.523mV
VABSORB_DELTA 0V to 0.6V/Cell 6 9.523mV
VEQUALIZE_DELTA 0V to 0.6V/Cell 6 9.523mV
MAX_ABSORB_TIME 0 to 65535 16 1 Second
EQUALIZE_TIME 0 to 65535 16 1 Second
en_lead_acid_temp_comp 0, 1 1 1 = Enable
C_OVER_X_THRESHOLD10mV to 32mV/
RSNSB
16 1.465µV/
RSNSB
Notes
1: In lead-acid mode C_OVER_XTHRESHOLD is used only to terminate
the absorb charge phase.
Lead-Acid Battery Charger Operation
The LTC4015 provides full featured, inherently safe,
constant-current/constant-voltage lead-acid battery
charging with battery presence detection, equalization,
absorb, bad battery detection, thermistor based charge
voltage temperature compensation, programmable charge
voltage, programmable charge current, battery series
resistance measurement, detailed status reporting, and
programmable interrupt generation.
LTC4015 Charge Algorithm Overview
The LTC4015 charge algorithms are based on a constant-
current constant-voltage charging (CC-CV) technique. The
battery is charged at a constant-current (CC) until the
battery reaches its charge voltage (VCHARGE) whereupon
the delivered charge current is automatically reduced
to maintain the battery at a constant VCHARGE (CV).The
LTC4015 does not monitor or balance individual cells
the full battery stack voltage is divided by number of cells
(V/cell) for simplicity only. The 4015 is not a substitute
for pack protection!
Lead Acid Charge Algorithm Overview
(See Figure 8 for lead-acid battery charging state diagram)
The charge algorithm begins with a battery detection test,
then proceeds to CC-CV charging with a charge voltage
CHARGER_
SUSPENDED*
BATTERY
DETECTION
NO BATTERY
SHORTED
BATTERY
BAT_SHORT_
FAULT
* NOTE: ALL STATES RETURN TO CHARGER SUSPENDED IF ANY OF THE FOLLOWING OCCUR:
A. THE INPUT VOLTAGE V
IN FALLS TO WITHIN 100mV OF THE BATSENS PIN VOLTAGE.
B. SUSPEND_CHARGER IS WRITTEN TO 1 VIA THE SERIAL PORT.
C. A SYSTEM FAULT OCCURS (V
IN OVERVOLTAGE LOCKOUT, 2P5VCC UNDERVOLTAGE LOCKOUT, INTVCC
UNDERVOLTAGE LOCKOUT, DRV
CC UNDERVOLTAGE LOCKOUT. THERMAL SHUTDOWN, MISSING RT
RESISTOR, OR INVALID COMBINATION OF CELLS PINS).
ABSORB_TIME PASSED
WITH BATTERY AT
ABSORB VOLTAGE
—OR—
(BATTERY AT ABSORB VOLTAGE
AND ICHG <
C_OVER_X_THRESHOLD)
4015 F08
BATTERY
VOLTAGE
STABLE
EQ PIN RISING
EDGE DETECTED
EQUALIZE_TIME
PASSED
—OR—
EQ PIN FALLING
EDGE DETECTED
ABSORB_CHARGE
CC_CV_CHARGE EQUALIZE_
CHARGE
BAT_MISSING_
FAULT 30 SECOND
TIMEOUT
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OPERATION
of VABSORB, which is an absorb delta added to VCHARGE.
Following constant-current bulk charging, constant-voltage
absorption charging continues until VABSORB is reached
and charge current has dropped below the C/x threshold,
or the battery absorb charge voltage is reached and the
maximum absorb phase time has passed. If neither of
the criteria for exiting the absorb charge phase is met
then CC-CV charging with VABSORB charge voltage can
continue indefinitely. Upon exiting the absorb phase the
charge voltage absorb delta is set to zero and CC-CV float
charging continues indefinitely.
Upon exiting the absorb phase an equalization charge can
be performed upon user request.
Lead Acid Equalization Charge
The equalization charge voltage, VEQUALIZE, can be signifi-
cantly higher than the absorption voltage. This aggressive
overcharging of the battery can equalize acid concentrations
throughout the battery and remove electrode sulfation that
may have formed during low charge conditions. Equal-
ization can restore battery capacity, but it can also result
in battery heating, overcharging of some or all cells and
the loss of electrolyte which can lead to battery damage.
Equalization is typically not performed with sealed batter-
ies because they are usually not re-wettable in the event
of electrolyte loss. Due to its aggressive nature, specific
equalization frequency, voltage and time duration should
be obtained from the battery manufacturer.
Battery Detection
The LTC4015 begins a charging cycle by performing a
two to four second battery detection test, during which
a 1mA load is drawn from the battery. If the battery volt-
age remains stable during the battery detection test, the
LTC4015 proceeds with battery charger soft-start. If the
battery voltage does not remain stable, the LTC4015
proceeds with a battery open/short test. The battery is
charged at minimum charge current for one to two seconds.
If the battery voltage as a result of this brief charging is
within a reasonable range the LTC4015 will proceed with
a battery charger soft-start. A battery open fault will also
occur if the NTC resistor is open or has a very high value.
A programmable interrupt can be set to alert the system
if a battery detection fault has occurred.
Battery Charger Soft-Start
The LTC4015 softs starts by ramping ICHARGE_DAC from
minimum to ICHARGE_TARGET at a nominal rate of 400µS
per ICHARGE_TARGET LSB. This results in a maximum
soft-start time of 31 • 400µS = 12.4mS.
Low Battery
If the BATSENS pin voltage is lower than 2.4V, the switching
charger operates in constant peak current mode, where the
peak current is 7mV/RSNSB. Exact average current value
depends on a number of factors including input voltage,
battery voltage and inductance value. When the BATSENS
pin voltage is higher than 2.6V, normal charging proceeds.
Absorb Charge
The LTC4015 begins lead-acid battery charging with an
absorb charge phase, and reports absorb_charge = 1 via the
serial port. During absorb charging, the LTC4015 charges at a
constant-current ICHG, with a target set by ICHARGE_TARGET
and RSNSB, unless one of the following conditions occurs:
a) The battery voltage reaches the absorb target
voltage (VABSORB)(determined by VCHARGE_
SETTING+VABSORB_DELTA, limited to a maximum
of 2.6V/cell), indicated by constant_voltage=1
b) Input current limit (IIN_LIMIT_SETTING) is reached,
indicated by iin_limit_active=1
c) The UVCLFB pin voltage falls to the undervoltage current
limit (VIN_UVCL_SETTING), indicated by vin_uvcl_ac-
tive=1
If either the input current limit or the input undervoltage
current limit is activated, the LTC4015 will limit charge
current and will attempt to regulate at the input current
limit or input undervoltage limit, as permitted by the input
source and system load.
Absorb phase ends after the battery voltage reaches VABSORB
and either ABSORB_TIMER reaches MAX_ABSORB_TIME
or IBAT falls below C_OVER_X_THRESHOLD. When the
absorb phase ends, the LTC4015 proceeds to constant-
current/constant-voltage (CC-CV) charge phase.
Constant-Current/Constant-Voltage (CC-CV) Charge:
In CC-CV charging phase, the LTC4015 prevents the
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OPERATION
battery voltage from falling below the charge voltage level,
as determined by VCHARGE_SETTING, unless one of the
following conditions occurs:
a) The battery charge current ICHG reaches the target set
by ICHARGE_TARGET, indicated by constant_current=1
b) Input current limit (IIN_LIMIT_SETTING) is reached,
indicated by iin_limit_active=1
c) The UVCLFB pin voltage falls to the undervoltage current
limit (VIN_UVCL_SETTING), indicated by vin_uvcl_ac-
tive = 1
If either the input current limit or the input undervoltage
current limit is activated, the LTC4015 will limit charge
current and will attempt to regulate at the input current
limit or input undervoltage limit, as permitted by the input
source and system load. There is no termination in the
charging algorithm for lead-acid; the charger will remain
in CV mode as long as input power is available.
Equalization Charge:
If a rising edge is detected on the EQ pin (as reported by the
equalize_req bit), the LTC4015 will perform an equalization
charge when the charge voltage is reached (constant-
voltage = 1) in constant-current/constant-voltage (CC-CV)
charge phase. In equalization charging phase, the LTC4015
charges the battery at a constant-current ICHG, with a target
set by ICHARGE_TARGET and RSNSB, unless one of the
following conditions occurs:
(a) The battery voltage reaches the equalization
target voltage (as determined by VCHARGE_
SETTING+VEQUALIZE_DELTA, limited to a maximum
of 2.6V/cell), indicated by constant_voltage=1,
(b) Input current limit (IIN_LIMIT_SETTING) is reached,
indicated by iin_limit_active=1,or
(c) The UVCLFB pin voltage falls to the undervoltage current
limit (VIN_UVCL_SETTING), indicated by vin_uvcl_ac-
tive=1.
If either the input current limit or the input undervoltage
current limit is activated, the LTC4015 will limit charge
current and will attempt to regulate at the input current
limit or input undervoltage limit, as permitted by the input
source and system load. Equalize charge phase runs until
EQUALIZE_TIMER reaches EQUALIZE_TIME, at which time
the LTC4015 returns to constant-current/constant-voltage
(CC-CV) charge phase.
The EQ pin is rising edge triggered, it must remain high
through the duration of the equalize phase. The EQ pin
must be de-asserted and re-asserted to begin another
equalization charge.
VIN Input Power Removal/SUSPEND_CHARGER/
System Fault Response
If, at any time, the input voltage on the VIN pin falls to within
100mV of the BATSENS pin voltage, or suspend_charger is
written to 1 via the serial port, or if a system fault condition
occurs (VIN overvoltage, low 2P5VCC voltage, low INTVCC
voltage, low DRVCC voltage, thermal shutdown, missing RT
resistor, or invalid combination of CELLS pins), the LTC4015
suspends charging and reports charger_suspended = 1.
Battery Series Resistance (BSR) Measurement
The LTC4015 can optionally measure the series resistance of
the battery. If run_bsr is set to 1 the LTC4015 momentarily
suspends the battery charger and calculates the battery
series resistance. The per cell resistance value is reported in
the BSR register and the change in charge current is reported
in the ICHARGE_BSR register via the serial port. The battery
series resistance value is proportional to the charge current
sense resistor, RSNSB, and can be computed in Ω from
BSR x RSNSB/750. Note that the resistance reported in the
BSR register must be multiplied by the total number of
cells to calculate total battery series resistance. The higher
ICHARGE_BSR (charge current) when a BSR measurement
is requested, the more accurate the BSR measurement will
be. Very low values of ICHARGE_BSR may significantly
impact the accuracy of the BSR measurement. Setting
run_bsr to a 1 will not turn the charger on, if the charger
is suspended or in a termination state. Setting run_bsr =
1 results in the BSR measurement request being queued
and run after the soft-start of the next charge cycle.
Lead-Acid Temperature Compensated Charging (en_
lead_acid_temp_comp=1)
The LTC4015 uses a –3.65 mV/°C per cell VCHARGE
temperature compensation when using a thermistor with a
β value of 3490K similar to a Vishay NTCS0402E3103FLT
or NTHS0402N02N1002JE thermistor. When en_lead_
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Figure 9. Lead-Acid Temperature Profile
TEMPERATURE (°C)
CHARGE VOLTAGE (VCELL)
4015 F09
2.7
2.6
2.5
2.4
2.3
2.2
1.9
2.1
2.0
–50 1007550250–25 150125
CC–CV EQUALIZE
ABSORB
OPERATION
acid_temp_comp=1, the registers VCHARGE_SETTING,
VABSORB_DELTA, and VEQUALIZE_DELTA control the
25°C value of VCHARGE_DAC. At other temperatures, the
value of VCHARGE_DAC is adjusted based on NTC_RATIO,
to produce the temperature profile shown in Figure 9. In
effect, the temperature profile is shifted up or down by
increasing or decreasing the values of VCHARGE_SETTING,
VABSORB_DELTA, and VEQUALIZE_DELTA, but the slope
of the temperature compensation response is not directly
programmable.
Table Default Lead-Acid Temperature Compensation
PARAMETER:
REGISTERS THAT DETERMINE 25°C
VALUE:
DEFAULT
VALUE AT
25°C (VOLTS/
CELL)
VEQUALIZE VCHARGE_SETTING+VEQUALIZE_DELTA 2.6
VABSORB VCHARGE_SETTING+VABSORB_DELTA 2.4
VCHARGE VCHARGE_SETTING 2.2
Coulomb Counter
The LTC4015 features an integrated Coulomb counter
for battery state of charge monitoring. Charge is the time
integral of current. The Coulomb counter is disabled
by default, and can be enabled only via the I2C port
(en_qcount).
There are several I2C accessible registers associated with
the Coulomb counter. The LO and HI alerts listed below
can be disabled. See register map and detailed register
descriptions for details.
en_qcount 1-Bit Enable Coulomb Counter (0x14, Bit 2)
en_qcount_lo_alert 1-Bit Enable Coulomb Counter Low Alert.
(0xOD Bit 13)
en_qcount_hi_alert 1-Bit Enable Coulomb Counter High Alert.
(0xOD Bit 12)
QCOUNT 16-Bits Coulomb Counter Accumulator Value
(0x13)
QCOUNT_LO_
ALERT_LIMIT 16-Bits Coulomb Counter Accumulator Low Alert
Limit. (0x10)
QCOUNT_HI_
ALERT_LIMIT 16-Bits Coulomb Counter Accumulator High Alert
Limit. (0x11)
QCOUNT_
PRESCALE_FACTOR 16-Bits Coulomb Counter Prescale Factor. (0x12)
The LTC4015 does not directly sense battery current, but
instead senses VCSP–CSN developed across RSNSB. This
voltage is divided by the value of RSNSB to calculate cur-
rent. The Coulomb counter integrates VCSP–CSN to infer
charge. The differential voltage across RSNSB is applied to
a voltage to the frequency converter (V-to-F). When the
integrator portion of the V-to-F output ramps to the CCREFP
or CCREFM level, switches S1, S2, S3 and S4 toggle to
reverse the ramp direction. By observing the state of the
switches and the ramp direction, polarity is determined.
The frequency of this ticking is directly proportional to
VCSP-CSN. The coulomb counter V-to-F transfer function is:
fTICK = KQC • VCSP – CSN
The LTC4015 limits lead-acid charge voltage to 2V to 2.6V/
cell regardless of battery temperature in CC-CV, Absorb
and equalize modes. VABSORB_DELTA is an adder to
VCHARGE_SETTING in absorb mode. VEQUALIZE_DELTA
is an adder to VCHARGE_SETTING in equalize mode.
At 25°C the default charge voltage is 2.2 V/cell. Using –3.65
mV/°C per cell, VCHARGE will reach its minimum of 2.0V/
cell at a temperature of 80°C. Similarly, VCHARGE reaches
its maximum of 2.6V/cell at a temperature of –85°C.
The default VABSORB_DELTA value is 0x15 (21 decimal).
This translates to an absorb voltage of 2.4V/cell at 25°C.
The default VEQUALIZE_DELTA value is 0x2A (42 decimal).
This translates to an equalize voltage of 2.6V/cell at 25°C.
Temperature compensation is active over a NTC_RATIO
range of 21437 to 912, which corresponds to an ap-
proximate temperature range of –55°C to 135°C
using a thermistor with a β value of 3490K such as the
Vishay NTCS0402E3103FLT or NTHS0402N02N1002JE.
See Figure 9.
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OPERATION
Where KQC = 8333.33Hz/V
fTICK is then divided by a prescaler (QCOUNT_PRESCALE_
FACTOR) that is programmable from 1 to 65535 (default of
512). The prescaler effectively increases integration time
by a factor equal to QCOUNT_PRESCALE_FACTOR. At
each under or overflow of the prescaler, the accumulated
voltage register (QCOUNT) is incremented or decremented
one count. The value of accumulated voltage is read via
the I2C interface.
To achieve the specified precision of the Coulomb counter
the differential voltage VCSP–CSN must stay within ±50mV.
For differential input signals up to ±300mV the Coulomb
counter will remain functional but the precision of the
Coulomb counter is not guaranteed.
The value of external sense resistor, RSNSB, influences
the gain of the Coulomb counter. A larger sense resistor
gives a larger differential voltage for the same current
which results in more precise Coulomb counting. Thus
the amount of charge represented by the least significant
bit (qLSB) of the accumulated charge is given by:
qLSB=
QCOUNT_PRESCALE_FACTOR
KQCRSNSB
qLSB units are in coulombs (Amp-seconds)
where:
K
QC
= 8333.33Hz/V
QCOUNT_PRESCAL_FACTOR = value of the
prescaler
RSNSB is in
If the value of QCOUNT reaches 0 or 65535, the value
saturates. QCOUNT does not wrap.
As long as input power is applied and the battery charger
is enabled, the LTC4015 will allow lead-acid batteries to
remain in a CV state indefinitely. As the battery slowly
discharges itself internally, the LTC4015 replenishes the
lost charge, and this charge is accumulated by the Coulomb
counter. After a long period of time, the Coulomb counter
accumulated charge due to battery self discharge current
while the charger is in CV mode could cause significant
errors relative to the actual SOC of the battery.
Coulomb Counter Applications
The following examples demonstrate simple applications of
the LTC4015 Coulomb counter function. For more advanced
applications, including calibration of state-of-charge based
on temperature, please contact Linear Technology Applica-
tions Engineering for more information.
EXAMPLE: Setting QCOUNT_PRESCALE_FACTOR and
initializing and calibrating QCOUNT: Charging two Li-Ion
3.5Ah batteries in parallel at 6.4A total
Total capacity = 7.0 Ah = 7.0A • 3600sec = 25200C
Constant-current charging at 6.4A requires RSNSB =
32mV/6.4A = 5mΩ
The maximum value of the QCOUNT register is 65535.
To prevent over ranging QCOUNT, the highest allowed
value of qLSB is 25200C/65535 = 0.385C
Using:
qLSB=
QCOUNT_PRESCALE_FACTOR
KQCRSNSB
RSNSB
CSP S1
CCREFM
4015 F10
CCREFP
CONTROL
LOGIC
POLARITY
DETECTION
S2
S3
S4
CHARGER
BATTERY
CSN
GND
IBAT
+
+
+
+
PRESCALAR
M
TO
LTC4015
LOGIC/
SERIAL PORT
Figure 10. Coulomb Counter Section of the LTC4015
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OPERATION
In order to achieve a qLSB of at least 0.385C, QCOUNT_
PRESCALE_FACTOR must be at least qLSB • (KQC
RSNSB) = 0.385 • (8333.33 • 0.005). Doubling (to allow
for margin) and rounding to the nearest integer gives
QCOUNT_PRESCALE_FACTOR = 32.
The initial state of charge (SOC) of the battery is known
to be approximately 25%. Given that the QCOUNT_
PRESCALE_FACTOR = 32 has now been set for ap-
proximately twice the capacity of the battery, the desired
valid range of QCOUNT is from 16384 (to represent 0%
SOC) to 49152 (to represent 100% SOC). The value of
QCOUNT is thus initialized to (32768 • 0.25) + 16384
= 24576 to represent the approximate 25% initial SOC.
In this case, the SOC of the battery at any time can be
calculated as 100% • (QCOUNT–16384)/32768.
Upon the first termination (c_over_x_term=1 or
timer_term=1), the battery is known to be very near
100% SOC, so the value of QCOUNT can be calibrated
accordingly. For example, if the initial state of charge
was actually 23% instead of the expected 25%, termina-
tion will occur when QCOUNT is approximately 49806.
Upon the first termination, the value of QCOUNT is over
written to 49152 to calibrate QCOUNT to the true SOC
of the battery.
EXAMPLE: Coulomb Counter Charge Termination
The Coulomb counter alert limits can be used to imple-
ment a maximum state of charge termination algorithm.
The following example demonstrates such a procedure:
1) Set the Coulomb counter register (QCOUNT) to the
battery's initial state of charge, and set QCOUNT_
PRESCALE_FACTOR based on the battery capacity, as
indicated in the example above.
2) Set QCOUNT_HI_ALERT_LIMIT to the desired maximum
state of charge of the battery (e.g. QCOUNT_HI_ALERT_
LIMIT = 49152)
3) Set en_qcount_hi_alert=1
4) If the battery charges enough that QCOUNT exceeds
QCOUNT_HI_ALERT_LIMIT, the LTC4015 will issue
an SMBALERT and set qcount_hi_alert=1. After
completing the alert response algorithm and verifying
that the LTC4015 is issuing qcount_hi_alert=1, set
suspend_charger=1 to stop the battery from charging.
At this time, write QCOUNT_LO_ALERT_LIMIT to a
lower level corresponding to a recharge threshold
(e.g. QCOUNT_LO_ALERT_LIMIT = 0.95 • QCOUNT_
HI_ALERT_LIMIT) and set en_qcount_lo_alert=1 and
en_qcount_hi_alert=0.
5) When the battery discharges enough that QCOUNT falls
below QCOUNT_LO_ALERT_LIMIT, the LTC4015 will
issue an SMBALERT and set qcount_lo_alert=1. After
completing the alert response algorithm and verifying
that the LTC4015 is issuing qcount_lo_alert=1, set
en_qcount_lo_alert=0, en_qcount_hi_alert=1, and
suspend_charger=0 to allow the battery to charge again.
Step Down Switching Charger Controller
The LTC4015’s primary power path is a fully synchronous
step down switching charger controller. Due to its all NMOS
design, a diode and capacitor are required to provide high
side boosted drive. Taking error signals from four control
loops simultaneously, the feedback paths are externally
compensated with a RC network connected to the VC pin.
The switching controller is designed to charge single or
multiple batteries. Normal charging proceeds at a constant-
current until the batteries reach their target voltage. The
maximum charge current is determined by the value of
the sense resistor, RSNSB, used in series with the inductor.
The charge current loop servos the voltage across RSNSB
to the value determined by ICHARGE_DAC.
When charging is enabled an internal soft-start will ramp
up the charge current from zero to ICHARGE_TARGET.
Both the battery voltage and charge current can be read
back over I2C. The LTC4015 provides constant power
charging by limiting input current drawn by the switching
controller. The input current limit will reduce charge
current to limit the voltage across the input sense resistor,
RSNSI, to IIN_LIMIT_SETTING. If the combined system
load plus battery charge current is large enough to cause
the switching controller to reach the programmed input
current limit, the input current limit loop will reduce the
charge current. Even if the charge current is programmed
to exceed the allowable input current, the input current
will not be violated; the charger will reduce its current
as needed. The input current can be read back over I2C.
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DRVCC
The bottom gate driver is powered from the DRVCC pin.
DRVCC is normally connected to the INTVCC pin. An external
LDO or DC/DC converter can also be used to power the
top and bottom gate driver to minimize power dissipa-
tion inside the IC. The use of a DC/DC for DRVCC can also
minimize power dissipation in general.
INTVCC/DRVCC and IC Power Dissipation
The LTC4015 features an internal PMOS low dropout linear
regulator (LDO) that supplies power to INTVCC from VSYS.
INTVCC powers the gate drivers (when DRVCC is connected
to INTVCC) and much of the LTC4015’s internal circuitry.
The INTVCC LDO regulates the voltage at the INTVCC pin
to 5V. The LDO can supply a maximum current of 50mA
and must be bypassed to ground with a ceramic capacitor
with a minimum value of 4.7μF. If DRVCC is not connected
to INTVCC, it should have at least a 2.2μF ceramic or low
ESR electrolytic capacitor. No matter what type of bulk
capacitor is used on DRVCC, an additional 0.1μF ceramic
capacitor placed directly adjacent to the DRVCC pin and
GND is highly recommended. Good bypassing is needed
to supply the high transient currents required by the
MOSFET gate drivers. High input voltage applications in
which large MOSFETs are being driven at high frequencies
may cause the maximum junction temperature rating for
the LTC4015 to be exceeded. The DRVCC current, which
is dominated by the gate charge current, is supplied by
the INTVCC LDO. Power dissipation for the IC in this case
is highest and is approximately equal to (VSYS) • (IQ + IG),
where IQ is the non-switching quiescent current of ~4mA
and IG is gate charge current. The junction temperature can
be estimated by using the equations given in Note 2 of the
Electrical Characteristics. For example, the IG supplied by
the INTVCC LDO is limited to less than 42mA from a 35V
supply in the QFN package at a 70°C ambient temperature:
TJ = 70°C + (35V)(4mA + 42mA)(34°C/W) = 125°C
To prevent the maximum junction temperature from being
exceeded, the DRVCC current must be checked while oper-
ating in continuous conduction mode at maximum VSYS.
The power dissipation in the IC is significantly reduced if
DRVCC is powered from an external LDO. In this case the
power dissipation in the IC is equal to power dissipation
due to IQ and the power dissipated in the gate drivers,
(VDRVCC) • (IG). Assuming the external DRVCC LDO out-
put is 5V and is supplying 42mA to the gate drivers, the
junction temperature rises to only 82°C:
TJ = 70°C + [(35V)(4mA)+(5V)(42mA)](34°C/W)
= 82°C
If DRVCC is powered from an external LDO, the LDO should
be powered from VSYS and its output must be less than
5.5V. In this case, DRVCC should not be tied to INTVCC.
Sequencing is also important, if DRVCC is not tied to INTVCC,
DRVCC should not be applied until INTVCC has reached 3V
to ensure the gate drivers are held off.
Die Temperature Sensor
The LTC4015 has an integrated die temperature sensor. It
is monitored by the ADC and is digitized to the DIE_TEMP
register. An alarm may be set on die temperature by setting
the DIE_TEMP_LO_ALERT_LIMIT and/or DIE_TEMP_HI_
ALERT_LIMIT registers and enabling the alarms in the
EN_LIMIT_ALERTS register.
INTVCC and DRVCC UVLO
Internal undervoltage lockout circuits monitor both the
INTVCC and DRVCC pins. The switching controller is kept
off until INTVCC rises above 4.3V and DRVCC is above
4.2V. Hysteresis on the UVLOs turn off the controller if
either INTVCC falls below 4V or DRVCC falls below 3.9V.
Charging is not enabled until VIN is 200mV above the bat-
tery voltage. Charging is disabled when VIN falls to within
100mV of the battery voltage.
Input Overvoltage Protection
The LTC4015 has overvoltage detection on its input. If
VIN exceeds 38.6V, the switching controller will hold both
switches off. The controller will resume switching if VIN
falls below 37.2V.
OPERATION
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NTC Resistor Selection
APPLICATIONS INFORMATION
mately mimic the profile of a thermistor β value of 3490k
over the range –40 to 125°C, resulting in less thanC
of error (typical) for the lead-acid temperature charging
profile (see Lead-Acid Temperature Compensated Charg-
ing), which in turn results in a battery voltage error of less
than 20mV/cell over temperature.
Setting the RT Resistor
A resistor on the RT pin sets the LTC4015’s step down
regulator switching frequency. To keep the inductor size
down and ensure optimum efficiency and stability the
LTC4015 switching frequency can be optimized (see In-
ductor Selection section). An RT value of 95.3k resistor
sets the frequency to 500kHz:
fOSC(MHz) =
47.65
R
T
(kΩ)
Setting Input and Charge Currents
As mentioned previously, maximum average charge current
is determined by the value of the sense resistor RSNSB,
connected between CSP and CSN, which is in series with
the inductor. The maximum average input current is de-
termined by the resistance RSNSI, connected between the
CLP and CLN pins. The input and charge current loops
servo the voltages across their respective sense resistors
to a maximum of 32mV. Therefore the maximum input
and charge average currents are:
IIN(MAX)=
32mV
RSNSI
ICHG(MAX)=
32mV
RSNSB
Compensation
The input current, charge current, VBAT voltage and UVCL
voltage loops all require a 6.8nF to 14.7nF capacitor from
the VC node to ground.
When using the MPPT feature with resistive sources in
excess of 0.5Ω, the required VC capacitor (CVC) may be
in the 100's of nF, with an additional series resistor in the
100Ω to 1000Ω range. If a series R is used, a smaller
cap, CVC/10, should be placed directly from VC to ground.
With minor modifications to the thermistor bias network,
it is possible to adjust the effective temperature profile
of the thermistor. Note that this technique can generally
only reduce the slope of the temperature profile—it is
not possible to increase the sensitivity of the thermistor.
The temperature based charging characteristics of the
LTC4015 are based on the ADC reading NTC_RATIO. For
the alternate thermistor bias network shown in Figure 11,
the value of NTC_RATIO is determined by:
NTC_RATIO=21845
R
NTCEFF
R
NTCBIAS
+R
NTCEFF
The values of RNTCBIAS, RPARALLEL, and RSERIES can be
selected in order to achieve a desired temperature profile
for NTC_RATIO. Note that thermistor temperature profiles
are highly nonlinear; consult manufacturers’ documenta-
tion for data on a specific thermistor. Two examples are
included here as a demonstration
Example 1: For a lithium chemistry battery with a 100
Vishay NTHS0402N01N1003J NTC thermistor, using
RNTCBIAS =100kΩ, RPARALLEL = 2MΩ, and RSERIES = 5
will approximately mimic the profile of a thermistor β value
of 3490k over the rangeC to 60°C, resulting in less than
1°C of error (typical) for the default JEITA temperature
thresholds (defined by JEITA_Tn, see JEITA Temperature
Controlled Charging). This error is significantly less than
the error tolerance of most thermistors.
Example 2: For a lead-acid battery with a 100Vishay
NTHS0402N01N1003J NTC thermistor, using RNTCBIAS =
95kΩ, RPARALLEL = 5MΩ, and RSERIES = 2will approxi-
Figure. 11
4015 F11
RNTCBIAS
RSERIES
RPARALLEL
NTCBIAS
NTC
T RNTC
THERMISTOR
RNTCEFF =1
1
RPARALLEL
+1
RNTC +RSERIES
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APPLICATIONS INFORMATION
If testing is to be done with a electronic load in constant-
current mode, care must be taken if using CC mode that
instability may occur. A few milli Farads on VBAT, with
enough series R (e.g. ESR) to give a zero around 1kHz
range can help in this situation.
Inductor Selection
The operating frequency and inductor selection are interre-
lated. Higher operating frequencies allow the use of smaller
inductor and capacitor values but generally also results in
lower efficiency because of MOSFET switching and gate
charge losses. In addition, the effect of inductor value
on ripple current must also be considered. The inductor
ripple current decreases with higher inductance or higher
frequency and increases with higher VIN. Accepting larger
values of ripple current allows the use of low inductances,
but results in higher output voltage ripple and greater core
losses. For the LTC4015, the best overall performance will
be attained if the inductor is chosen to be:
L=
V
BAT
1– V
BAT
/ V
IN(MAX)
( )
0.25 fICHG(MAX)
Where VBAT is the highest BATSENS voltage, VIN(MAX) is
the maximum input voltage, ICHG(MAX) is the maximum
regulated charge current and fSW is the switching fre-
quency. Using these equations, the inductor ripple will be
at most 25% of ICHG(MAX). Once the value for L is known,
the type of inductor core must be selected. Ferrite cores
are recommended for their very low core loss. Selection
criteria should concentrate on minimizing copper loss and
preventing saturation. Ferrite core material saturates hard,
which means that inductance collapses abruptly when the
peak design current is exceeded. This causes an abrupt
increase in inductor ripple current and consequent out-
put voltage ripple. Do not allow the core to saturate! The
saturation current for the inductor should be at least 60%
higher than the maximum regulated current, ICHG(MAX).
CSYS and CBAT Capacitance
The specification for CSYS will be determined by the desired
ripple voltage:
∆VSYS =VBAT
VSYS
1– VBAT
VSYS
ICHG(MAX)
CSYS fSW+ICHG(MAX) ESRCSYS
In continuous mode, the source current of the top MOSFET
is a square wave of duty cycle (VBAT/VSYS). To prevent
large voltage transients, a low ESR capacitor sized for
the maximum RMS current must be used. The maximum
RMS capacitor current is given by:
IRMS =ICHG(MAX) VBAT
VSYS
VSYS
VBAT
1
This formula has a maximum at VSYS = 2 VBAT, where
IRMS = ICHG(MAX)/2. This simple worst-case condition
is commonly used for design because even significant
deviations do not offer much relief. Medium voltage (20V
to 35V) ceramic, tantalum, OS-CON and switcher rated
electrolytic capacitors can be used as input capacitors.
Sanyo OS-CON SVP, SVPD series; Sanyo POSCAP TQC
series or aluminum electrolytic capacitors from Panasonic
WA series or Cornel Dublilier SPV series, in parallel with
a couple of high performance ceramic capacitors, can be
used as an effective means of achieving low ESR and high
bulk capacitance.
The purpose of the VBAT capacitor is to filter the induc-
tor current ripple as well as to stabilize the charger if the
battery is not present or has high BSR. The VBAT ripple
(ΔVBAT) is approximated by:
ΔVBAT = ΔIP-P 1
8CBAT fSW +ESRCBAT
Where fSW is the operating frequency, CBAT is the ca-
pacitance on VBAT and ΔIP-P is the ripple current in the
inductor. The output ripple is highest at maximum input
voltage since ΔIP-P increases with input voltage.
Power MOSFET Selection
Two external power MOSFETs must be selected for the
LTC4015’s synchronous controller: one N-channel MOS-
FET for the top switch and one N-channel MOSFET for
the bottom switch. The selection criteria of the external
N-channel power MOSFETs include maximum drain-
source voltage (VDSS), threshold voltage, on-resistance
(RDS(ON)), reverse transfer capacitance (CRSS), total gate
charge (QG) and maximum continuous drain current.
VDSS should be selected to be higher than the maxi-
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mum input supply voltage (including transient) for both
MOSFETs. The peak-to-peak drive levels are set by the
DRVCC voltage. Logic-level threshold MOSFETs must be
used because DRVCC is powered from either INTVCC (5V)
or an external LDO whose output voltage must be less than
5.5V. MOSFET power losses are determined by RDS(ON)
and CRSS and QG.
The conduction loss at maximum charge current for the
top MOSFET switches are:
P
COND(TOP) =
V
BAT
VSYS ICHG(MAX)2RDS(ON)
1+δΔT
( )
P
COND(BOT) =1 VBAT
V
SYS
ICHG(MAX)2RDS(ON)
1+δΔT
( )
The term (1+ δΔT) is generally given for a MOSFET in the
form of a normalized RDS(ON) vs Temperature curve, but δ =
0.005/°C can be used as an approximation for low voltage
MOSFETs. Both MOSFET switches have conduction loss .
However, transition loss occurs only in the top MOSFET
in step-down converter. This loss is proportional to VSYS2
and can be considerably larger in high voltage applications
(VSYS > 20V). The maximum transition loss is:
PTRAN = k/2 • (VSYS)2 • ICHG(MAX) • CRSS • fSW
where k is related to the drive current during the Miller
plateau and is approximately equal to one.
Choosing a high side MOSFET that has a higher RDS(ON)
and lower CRSS can minimize overall losses; by reducing
transition losses more than the corresponding conduction
loss increase.
Another power loss related to switching MOSFET selection
is the power lost to driving the gates. The total gate charge,
QG, must be charged and discharged each switching cycle.
The power is lost to the internal LDO and gate drivers within
the LTC4015. The power lost due to charging the gates is:
PG = (QGTOP + QGBOT) • fSW • VSYS
Schottky Diode Selection
Optional Schottky diodes can be placed in parallel with the
top and bottom MOSFET switches. These diodes clamp
SW during the non-overlap times between conduction of
the top and bottom MOSFET switches. This prevents the
body diodes of the MOSFET switches from turning on,
storing charge during the non-overlap time and requir-
ing a reverse recovery period that could cost as much as
3% in efficiency at high VIN. One or both diodes can be
omitted if the efficiency loss can be tolerated. The diode
can be rated for about one-half to one-fifth of the full load
current since it is on for only a fraction of the duty cycle.
Larger diodes result in additional switching losses due to
their larger junction capacitance. In order for the diodes
to be effective, the inductance between them and the top
and bottom MOSFETs must be as small as possible. This
mandates that these components be placed next to each
other on the same layer of the PC board.
Top MOSFET Driver Supply (CB, DB)
An external bootstrap capacitor, CB, connected to the
BOOST pin supplies the gate drive voltage for the top
MOSFET. Capacitor CB in Figure 12 is charged though
external diode, DB, from DRVCC when the SW pin is low.
The value of the bootstrap capacitor, CB, needs to be
20 times that of the total input capacitance of the top
MOSFET. The bypass capacitor on DRVCC should be at
least 10 times the value of CB.
APPLICATIONS INFORMATION
Figure 12. Bootstrap Capacitor/Diode and DRVCC Connections
4015 F12
BOOST
SW
DRVCC
0.1µF > 2.2µF
DB
CB
INTVCC
LTC4015
1µF
With the top MOSFET on, the boost voltage is above the
system supply rail: VBOOST = VSYS + VDRVCC.
The reverse break down of the external diode, DB, must
be greater than VSYS(MAX) + VDRVCC(MAX).
DB can be either a Schottky diode or a fast switching PN
diode. Care must be taken to not exceed the maximum
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BOOST-SW voltage of 5.5V which may be possible with a
Schottky under certain conditions, particularly if the step
down charger is operating asynchronously. Fast switching
PN diodes are recommended due to their low leakage and
junction capacitance.
Minimum On-Time Considerations
Minimum on-time, tON(MIN), is the smallest time dura-
tion that the LTC4015 is capable of turning on the top
MOSFET. It is determined by internal timing delays and
the gate charge required to turn on the top MOSFET. The
minimum on-time for the LTC4015 is approximately 85ns.
Low duty cycle applications may approach this minimum
on-time limit. If the duty cycle falls below what can be
accommodated by the minimum on-time, the controller
will begin to skip cycles. The VBAT voltage will continue
to be regulated, but the ripple voltage and current will
increase. If cycling skipping is undesirable care should
be taken to ensure that:
V
BAT
V
SYS
f
SW
> tON(MIN) = 85ns
Ideal Diode MOSFET Selection
An external N-channel MOSFET is required for the input
ideal diode and a P-channel MOSFET for output ideal diode.
Important parameters for the selection of these MOSFETs
are the maximum drain-source voltage, VDSS, gate thresh-
old voltage and on-resistance (RDS(ON)). When the input is
grounded the battery stack voltage is applied across the input
ideal diode MOSFET. When VBAT is at 0V, the input voltage
is applied across the output ideal diode MOSFET. Therefore,
the VDSS of the input ideal diode MOSFET must withstand
the maximum voltage on VBAT while the VDSS of output ideal
diode MOSFET must withstand the highest voltage on VIN.
The gate drive for both ideal diodes is 5V. This requires the
use of logic-level threshold P and N-channel MOSFETs. As a
general rule, select MOSFETs with a low enough RDS(ON) to
obtain the desired VDS while operating at full load current.
The LTC4015 will regulate the forward voltage drop across
the input and output ideal diode MOSFETs at 15mV if RDS(ON)
is low enough. The required RDS(ON) can be calculated by
dividing 15mV by the load current in amps.
Achieving forward regulation will minimize power loss and
heat dissipation, but it is not a necessity. If a forward volt-
age drop of more than 15mV is acceptable then a smaller
MOSFET can be used, but must be sized compatible with
the higher power dissipation. Care should be taken to
ensure that the power dissipated is never allowed to rise
above the manufacturer’s recommended maximum level.
UVCLFB Resistor Divider Selection
The LTC4015 input undervoltage current limit (UVCL)
function regulates voltage at the UVCLFB pin based on the
value programmed in the VIN_UVCL_SETTING register.
Do not write to the VIN_UVCL_SETTING register when
MPPT is enabled.
If MPPT is enabled, the UVCLFB input voltage resistor
divider must be set to 10k and 294k for the bottom and
top resistors, respectively. Resistor tolerance should be
±1% or better.
These resistor values result in a gain of 30.4 from the UVCLB
pin to VIN. The 1.2V maximum servo level at UVCLFB would
require the minimum VIN at the maximum servo voltage
to be greater than 1.2V • 30.4 = 36.48V, which is above
the LTC4015’s maximum VIN. This is necessary to allow
the MPPT algorithm to search across the entire VIN range.
If maximum power point tracking (MPPT) is not enabled,
the default undervoltage setting of VIN_UVCL_SETTING
= 0xFF sets the UVCLFB undervoltage servo level to 1.2V.
In this case, the input voltage resistor divider should be
chosen such that UVCLFB = 1.2V when VIN is slightly above
the higher of 4.3V or VBAT(MAX), to prevent undervoltage
lockout (UVLO). For example, for a two cell Li-Ion
application, the bottom and top resistors in the UVCLFB
divider could be chosen as 75k and 470k, respectively,
which sets the input undervoltage regulation limit at 8.72V.
Note that when MPPT is disabled, and the MPPT UVCLFB
10k and 294k resistor divider values are used, the default
VIN_UVCL_SETTING of 1.2V will result in the LTC4015
not charging the battery.
The undervoltage regulation feature can be disabled. The
UVCLFB pin is clamped, the clamp begins to engage at
2V nominally. Care must be taken to keep switching noise
from coupling on to the UVCLFB pin, a capacitor to signal
GND may be required.
APPLICATIONS INFORMATION
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1. Connect UVCLFB to 2P5VCC through a 10k resistor. This
method results in an additional 25µA to 50µA battery
current drain when VIN < VBAT as the 2P5VCC LDO is
powered by VBAT is this condition.
2. Alternatively, the UVCLFB pin can be tied to VIN through
an appropriately sized resistor which keeps the pin cur-
rent below 200µA. This method results in zero battery
current draw when VIN < VBAT. The 294k MPPT UVCLFB
divider top resistor would meet this requirement.
When a UVCLFB input voltage resistor divider is present,
if maximum power point tracking is disabled, input
undervoltage regulation can be prevented by setting
VIN_UVCL_SETTING to its lowest value (0x00).
UVCL and MPPT When Available Input Power is Low
The LTC4015 battery charger function requires a minimum
amount of current to operate, which varies depending on the
application (switching MOSFET selection, compensation,
etc). If the maximum input current available from the VIN
supply is above 2mA to 3mA but below the minimum level
required to operate the charger (generally approximately
in the range 5mA to 20mA) then the battery may
actually be discharged slightly by the charger. Under
these conditions—for example, a very dimly lit (but not
completely dark) solar panelthe worst-case battery drain
current is generally less than 10mA, and persists only as
long as the available input current from the VIN source
remains in this range. If the available input current falls to
below 2mA to 3mA, then the battery discharge returns to
near normal battery only mode levels. As such, if the input
source is a solar panel, this battery drain will generally
be short-lived and infrequent enough (for example, for a
brief period shortly before sunrise and after sunset) as to
be insignificant. However, if this drain is a concern, it can
be mitigated by disabling the charger (setting suspend_
charger=1) whenever ICHG falls below 1% of full-scale
(IBAT <= 218), and retrying (writing suspend_charger=0)
periodically (e.g. every 60 seconds). Optionally, this retry
can be limited to only occur when VIN is above a known
good threshold.
PCB Layout Considerations
When laying out the printed circuit board, the following
guidelines should be used to ensure proper operation of
the IC. Check the following in your layout:
1. Keep M1, M2, D1, D2 and CSYS close together. The high
dI/dt loop formed by the MOSFETs, Schottky diodes and
CSYS shown in Figure 13 should have short wide traces
to minimize high frequency noise and voltage stress
from inductive ringing. Surface mount components are
preferred to reduce parasitic inductances from component
leads. Connect the drain of the top MOSFET and cathode
of the top diode directly to the positive terminal of CSYS.
Connect the source of the bottom MOSFET and anode of
the bottom diode directly to the negative terminal of CSYS.
This capacitor provides the AC current to the MOSFETs.
2. GND is referenced to the negative terminal of the VBAT
decoupling capacitor. The negative terminal of CSYS
should be as close as possible to negative terminal of
CBAT by placing the capacitors next to each other and
away from the switching loop described above. The
combined IC ground pin/paddle and the ground return
of CINTVCC and CDRVCC must return to the combined
negative terminals of CSYS and CBAT.
3. Effective grounding techniques are critical for success-
ful DC/DC converter layouts. Orient power components
such that switching current paths in the ground plane do
not cross through the GND pin and exposed pad on the
backside of the LTC4015. Switch path currents can be
controlled by orienting the MOSFET switches, Schottky
diodes, the inductor, and VSYS and VBAT decoupling
capacitors in close proximity to each other.
4. Route CSP and CSN sense lines together, keep them
short. Place a 1nF ceramic capacitor across CSP-CSN
as close as possible to the LTC4015. Filter components
should be placed near the part and not near sense
resistor. Ensure accurate current sensing with Kelvin
connections at the sense resistors. See Figure 14.
5. Route CLP and CLN sense lines together, keep them
short. Filter components should be placed near the part
and not near sense resistor. Ensure accurate current
sensing with Kelvin connections at the sense resistors.
See Figure 15.
APPLICATIONS INFORMATION
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6. Locate the DRVCC and BOOST decoupling capacitors
in close proximity to the IC. These capacitors carry the
MOSFET drivers’ high peak currents. An additional 0.1μF
ceramic capacitor placed immediately next to the DRVCC
pin can help improve noise performance substantially.
7. Locate the small signal components away from high
frequency switching nodes (BOOST, SW, TG, and BG). All
of these nodes have very large and fast moving signals
and therefore should be kept on the output side of the
LTC4015.
APPLICATIONS INFORMATION
8. The input ideal diode senses the voltage between VIN
and VCLP. VIN should be connected near the source of
the input ideal diode MOSFET. VCLP is used for Kelvin
sensing the input current. Place the input current sense
resistor, RSNSI, near the input ideal diode MOSFET with
a short, wide trace to minimize resistance between the
drain of the ideal diode MOSFET and RSNSI.
9. The output ideal diode senses the voltage between VSYS
and VCSP. VSYS should be connected near the source of
the output ideal diode MOSFET. VCSP is used for Kelvin
sensing the charge current. Place the output ideal diode
near the charge current sense resistor, RSNSB, with a
short, wide trace to minimize resistance between the
drain of the ideal diode MOSFET and RSNSB.
LTC4015 Digital System
This section provides a detailed explanation of the func-
tions of the LTC4015 digital system available via the serial
port registers.
LTC4015 Digital System Usage Examples 1, 2
The following usage examples describe applications which
demonstrate a range of functionality available with the
LTC4015 system. Note that these examples represent only
a small fraction of the LTC4015’s full digital functionality.
LTC4015 Digital System Usage Example 1: Coulomb
counter and Low Limit Alert Only
Upon initial power up with an embedded battery in a known
state of charge, the serial port master writes the LTC4015
bit en_qcount=1, enabling the Coulomb counter. Register
QCOUNT is initialized to reflect the known state of charge,
QCOUNT_PRESCALE_FACTOR is written for optimum
range and resolution, QCOUNT_LO_ALERT_LIMIT is
written to a value known to correspond to a critical low
state of charge, and en_qcount_lo_alert is written to 1.
If the state of charge falls below the level defined by
QCOUNT_LO_ALERT_LIMIT, the LTC4015 pulls down
the SMBALERT pin. The serial port master performs an
alert response algorithm (ARA) which confirms that the
LTC4015 is the source of the alert and causes the LTC4015
to release the SMBALERT pin. The master then reads the
VSYS VBAT
CSYS
D1
D2
L1 RSNSC
MN1
MN2
4015 F13
CBAT
BAT1
BAT2
HIGH
FREQUENCY
CIRCULATING
PATH
RSNSC
OR
RSNSI
TO CSP
OR
CLP
TO CSN
OR
CLN 4015 F15
RSNSC
OR
RSNSI
TO CSP
OR
CLP
TO CSN
OR
CLN 4015 F14
Figure 13. High Speed Switching Path
Figure 14. Kelvin Current Sensing
Figure 15. Kelvin Current Sensing
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LIMIT_ALERTS register to confirm that qcount_lo_alert is
true. The master then initiates appropriate system action
(e.g. emergency power down, user warning, etc).
See the sections Coulomb Counter, Programmable Inter-
rupt Controller, and Detailed Register Descriptions for
more details.
LTC4015 Digital System Usage Example 2: Custom Bat-
tery Charger Settings for a Lead-Acid Battery Pack with
Battery Overtemperature Alert.
The LTC4015 CHEM1 and CHEM0 pins are strapped to
select the chemistry algorithm. Upon initial power-up,
the serial port master writes suspend_charger=1, then
writes VCHARGE_SETTING, VABSORB_DELTA, MAX_
ABSORB_TIME, VEQUALIZE_DELTA, and EQUALIZE_TIME
based on the battery manufacturer’s recommendation for
charge voltage and time. The master writes NTC_RATIO_
LO_ALERT_LIMIT to the value of NTC_RATIO which
corresponds to the maximum safe charging temperature
for the battery pack and NTC thermistor, and writes
en_ntc_ratio_lo_alert = 1. The master then re-enables
the battery charger by writing suspend_charger=0. At
regular long intervals (for example, every 30 days) the
master optionally initiates an equalization charge by as-
serting the EQ pin.
If the thermistor temperature ever exceeds the level
corresponding to NTC_RATIO_LO_ALERT_LIMIT, the
LTC4015 pulls down the SMBALERT pin. The serial port
master then performs an ARA which confirms that the
LTC4015 is the source of the alert and causes the LTC4015
APPLICATIONS INFORMATION
to release the SMBALERT pin. The master reads the
LIMIT_ALERTS register to confirm that ntc_ratio_lo_alert
is true. The master then writes suspend_charger=1 to
disable the battery charger.
Optionally, in order to detect when the battery temperature
has returned to a safe level for charging, the master writes
NTC_RATIO_HI_ALERT_LIMIT to a value corresponding
toC below the maximum safe charging temperature of
the battery, and writes en_ntc_ratio_hi_alert=1. When the
thermistor temperature falls below this level, the LTC4015
generates a new SMBALERT for ntc_ratio_hi_alert=1,
which is again confirmed by the master. The master then
disables the alert by writing en_ntc_ratio_hi_alert=0,
clears ntc_ratio_lo_alert (by writing a 0 to that bit), then
re-enables the charger by writing suspend_charger=0.
See the sections Lead-Acid Battery Charge Algorithm,
Programmable Interrupt Controller, and Detailed Register
Descriptions for more details.
LTC4015 Digital System Usage Example 3: Battery
Charger State Monitoring
The serial port master writes en_charger_suspended_
alert=1 to generate an alert if the battery charger is ever
disabled (e.g. due to the removal of VIN input power). If
VIN input power is removed, the LTC4015 pulls down the
SMBALERT pin and sets the charger_suspended bit to 1.
After performing an ARA, the serial port master directs the
system to minimize battery drain (e.g. dimming displays,
powering down unnecessary functions, etc).
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REGISTER DESCRIPTION
Serial Port Register Map. All bits are active high. Registers are unsigned except where noted. All registers contain 16 bits. Unused
register bits as well as registers 0x17, 0x18, 0x49 are reserved and should not be written.
SYMBOL
SUB
ADDR R/W
ACTIVE
BITS DESCRIPTION DEFAULT PAGE
VBAT_LO_ALERT_LIMIT 0x01 R/W 15:0 Battery voltage low alert limit, signed, same format as VBAT (0x3A) 0x0000 55
VBAT_HI_ALERT_LIMIT 0x02 R/W 15:0 Battery voltage high alert limit, signed, same format as VBAT (0x3A) 0x0000 55
VIN_LO_ALERT_LIMIT 0x03 R/W 15:0 Input voltage low alert limit, signed, same format as VIN (0x3B) 0x0000 55
VIN_HI_ALERT_LIMIT 0x04 R/W 15:0 Input voltage high alert limit, signed, same format as VIN (0x3B) 0x0000 55
VSYS_LO_ALERT_LIMIT 0x05 R/W 15:0 Output voltage low alert limit, signed, same format as VSYS (0x3C) 0x0000 55
VSYS_HI_ALERT_LIMIT 0x06 R/W 15:0 Output voltage high alert limit, signed, same format as VSYS (0x3C) 0x0000 55
IIN_HI_ALERT_LIMIT 0x07 R/W 15:0 Input current high alert limit, signed, same format as IIN (0x3D) 0x0000 55
IBAT_LO_ALERT_LIMIT 0x08 R/W 15:0 Charge current low alert limit, signed, same format as IBAT (0x3E) 0x0000 55
DIE_TEMP_HI_ALERT_LIMIT 0x09 R/W 15:0 Die temperature high alert limit, signed, same format as DIE_TEMP (0x3F) 0x0000 55
BSR_HI_ALERT_LIMIT 0x0A R/W 15:0 Battery series resistance high alert limit, signed, same format as BSR
(0x41) 0x0000 55
NTC_RATIO_HI_ALERT_LIMIT 0x0B R/W 15:0 Thermistor ratio high (cold battery) alert limit, signed, same format as
NTC_RATIO (0x40) 0x0000 55
NTC_RATIO_LO_ALERT_LIMIT 0x0C R/W 15:0 Thermistor ratio low (hot battery) alert limit, signed, same format as
NTC_RATIO (0x40) 0x0000 55
EN_LIMIT_ALERTS 0x0D R/W 15:0 Enable limit monitoring and alert notification via SMBALERT 0x0000 56
en_meas_sys_valid_alert 0x0D R/W 15 enable meas_sys_valid_alert (0x36) 0 56
0x0D R/W 14 RESERVED 0
en_qcount_low_alert 0x0D R/W 13 enable qcount_low_alert (0x36) 0 56
en_qcount_high_alert 0x0D R/W 12 enable qcount_high_alert (0x36) 0 56
en_vbat_lo_alert 0x0D R/W 11 enable vbat_lo_alert (0x36) 0 56
en_vbat_hi_alert 0x0D R/W 10 enable vbat_hi_alert (0x36) 0 56
en_vin_lo_alert 0x0D R/W 9 enable vin_lo_alert (0x36) 0 56
en_vin_hi_alert 0x0D R/W 8 enable vin_hi_alert (0x36) 0 56
en_vsys_lo_alert 0x0D R/W 7 enable vsys_lo_alert (0x36) 0 56
en_vsys_hi_alert 0x0D R/W 6 enable vsys_hi_alert (0x36) 0 56
en_iin_hi_alert 0x0D R/W 5 enable iin_hi_alert (0x36) 0 56
en_ibat_lo_alert 0x0D R/W 4 enable ibat_lo_alert (0x36) 0 57
en_die_temp_hi_alert 0x0D R/W 3 enable_die_temp_hi_alert (0x36) 0 57
en_bsr_hi_alert 0x0D R/W 2 enable bsr_hi_alert (0x36) 0 57
en_ntc_ratio_hi_alert 0x0D R/W 1 enable ntc_ratio_hi alert (cold battery; 0x36) 0 57
en_ntc_ratio_lo_alert 0x0D R/W 0 enable ntc_ratio_lo_alert (hot battery; 0x36) 0 57
EN_CHARGER_STATE_ALERTS 0x0E R/W 15:0 Enable charger state alert notification via SMBALERT 0x0000 57
en_equalize_charge_alert 0x0E R/W 10 enable lead-acid equalize_charge_ alert (0x37) 0 57
en_absorb_charge_alert 0x0E R/W 9 enable absorb_charge_alert (0x37) 0 57
en_charger_suspended_alert 0x0E R/W 8 enable charger_suspended_alert (0x37) 0 57
en_precharge_alert 0x0E R/W 7 enable precharge_alert (0x37) 0 57
en_cc_cv_charge_alert 0x0E R/W 6 enable cc_cv_charge_alert (0x37) 057
LTC4015
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REGISTER DESCRIPTION
SYMBOL
SUB
ADDR R/W
ACTIVE
BITS DESCRIPTION DEFAULT PAGE
en_ntc_pause_alert 0x0E R/W 5 enable ntc_pause_alert (0x37) 0 58
en_timer_term_alert 0x0E R/W 4 enable timer_term_alert (0x37) 0 58
en_c_over_x_term_alert 0x0E R/W 3 enable c_over_x_term alert (0x37) 0 58
en_max_charge_time_fault_alert 0x0E R/W 2 enable max_charge_time_fault alert (0x37) 0 58
en_bat_missing_fault_alert 0x0E R/W 1 enable bat_missing_fault alert (0x37) 0 58
en_bat_short_fault_alert 0x0E R/W 0 enable bat_short_fault alert (0x37) 0 58
EN_CHARGE_STATUS_ALERTS 0x0F R/W 15:0 Enable charge status alert notification via SMBALERT 0x0000 58
en_vin_uvcl_active_alert 0x0F R/W 3 enable vin_uvcl_active_alert (VIN undervoltage current limit; 0x38) 0 58
en_iin_limit_active_alert 0x0F R/W 2 enable iin_limit_active_alert (IIN current limit; 0x38) 0 58
en_constant_current_alert 0x0F R/W 1 enable constant_current_alert (0x38) 0 58
en_constant_voltage_alert 0x0F R/W 0 enable constant_voltage_alert (0x38) 0 58
QCOUNT_LO_ALERT_LIMIT 0x10 R/W 15:0 Coulomb counter QCOUNT low alert limit, same format as QCOUNT (0x13) 0x0000 59
QCOUNT_HI_ALERT_LIMIT 0x11 R/W 15:0 Coulomb counter QCOUNT high alert limit, same format as QCOUNT
(0x13) 0x0000 59
QCOUNT_PRESCALE_FACTOR 0x12 R/W 15:0 Coulomb counter prescale factor 0x0200 59
QCOUNT 0x13 R/W 15:0 Coulomb counter value 0x8000 59
CONFIG_BITS 0x14 R/W 15:0 Configuration Settings 0x0000 59
suspend_charger 0x14 R/W 8 suspend battery charger operation 0 59
run_bsr 0x14 R/W 5 perform a battery series resistance measurement 0 59
force_meas_sys_on 0x14 R/W 4 force measurement system to operate 059
mppt_en_i2c 0x14 R/W 3 enable maximum power point tracking 059
en_qcount 0x14 R/W 2 enable coulomb counter 059
IIN_LIMIT_SETTING 0x15 R/W 5:0 Input current limit setting = (IIN_LIMIT_SETTING + 1) • 500µV / RSNSI 0x3F 60
VIN_UVCL_SETTING 0x16 R/W 7:0 UVCLFB input undervoltage limit = (VIN_UVCL_SETTING + 1) • 4.6875mV 0xFF 60
RESERVED 0x17
RESERVED 0x18
ARM_SHIP_MODE 0x19 R/W 15:0 Write 0x534D to arm ship mode. Once armed, ship mode cannot be
disarmed. 0x0000 60
ICHARGE_TARGET 0x1A R/W24:0 Maximum charge current target = (ICHARGE_TARGET + 1) • 1mV/RSNSB See Note 1 60
VCHARGE_SETTING 0x1B R/W25:0 Charge voltage target. See detailed description for equations. See Note 1 60
C_OVER_X_THRESHOLD 0x1C R/W215:0 Tw o’s complement Low IBAT threshold for C/x termination See Note 1 61
MAX_CV_TIME 0x1D R/W215:0 Time in seconds with battery charger in the CV state before timer
termination occurs (lithium chemistries only) See Note 1 62
MAX_CHARGE_TIME 0x1E R/W215:0 Time in seconds before a max_charge_time fault is declared. Set to zero
to disable max_charge_time fault See Note 1 62
JEITA_T1 0x1F R/W215:0 Value of NTC_RATIO for transition between JEITA regions 2 and 1 (off) 0x3F00 62
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REGISTER DESCRIPTION
SYMBOL
SUB
ADDR R/W
ACTIVE
BITS DESCRIPTION DEFAULT PAGE
JEITA_T2 0x20 R/W215:0 Value of NTC_RATIO for transition between JEITA regions 3 and 2 0x372A 62
JEITA_T3 0x21 R/W215:0 Value of NTC_RATIO for transition between JEITA regions 4 and 3 0x1F27 62
JEITA_T4 0x22 R/W215:0 Value of NTC_RATIO for transition between JEITA regions 5 and 4 0x1BCC 62
JEITA_T5 0x23 R/W215:0 Value of NTC_RATIO for transition between JEITA regions 6 and 5 0x18B9 62
JEITA_T6 0x24 R/W215:0 Value of NTC_RATIO for transition between JEITA regions 7 (off) and 6 0x136D 62
VCHARGE_JEITA_6_5 0x25 R/W29:0 VCHARGE values for JEITA temperature regions 6 and 5 See Note 1 62
vcharge_jeita_6 9:5 63
vcharge_jeita_5 4:0 63
VCHARGE_JEITA_4_3_2 0x26 R/W214:0 VCHARGE values for JEITA temperature regions 4, 3, and 2 See Note 1 62
vcharge_jeita_4 14:10 63
vcharge_jeita_3 9:5 63
vcharge_jeita_2 4:0 63
ICHARGE_JEITA_6_5 0x27 R/W29:0 ICHARGE_TARGET values for JEITA temperature regions 6 and 5 0x01EF 63
icharge_jeita_6 9:5 0x0F 63
icharge_jeita_5 4:0 0x0F 63
ICHARGE_JEITA_4_3_2 0x28 R/W214:0 ICHARGE_TARGET value for JEITA temperature regions 4, 3, and 2 0x7FEF 63
icharge_jeita_4 14:10 0x1F 63
icharge_jeita_3 9:5 0x1F 63
icharge_jeita_2 4:0 0x0F 63
CHARGER_CONFIG_BITS 0x29 R/W22:0 Battery charger configuration settings, bits 15:3 are reserved. See Note 1 63
en_c_over_x_term 2 enable C/x termination See Note 1 63
en_lead_acid_temp_comp 1 enable lead-acid charge voltage temperature compensation See Note 1 63
en_jeita 0 enable jeita temperature profile See Note 1 63
VABSORB_DELTA 0x2A R/W25:0 LiFePO4/lead-acid absorb voltage adder, bits 15:6 are reserved. See Note 1 61
MAX_ABSORB_TIME 0x2B R/W215:0 Maximum time for LiFePO4/lead-acid absorb charge See Note 1 62
VEQUALIZE_DELTA 0x2C R/W25:0 Lead-acid equalize charge voltage adder, bits 15:6 are reserved. 0x002A 61
EQUALIZE_TIME 0x2D R/W215:0 Lead-acid equalization time 0x0E10 62
LIFEP04_RECHARGE_THRESHOLD 0x2E R/W 15:0 LiFeP04 recharge threshold 0x4410 62
RESERVED 0x2F
MAX_CHARGE_TIMER 0x30 R 15:0 For lithium chemistries, indicates the time (in sec) that the battery has
been charging 64
CV_TIMER 0x31 R 15:0 For lithium chemistries, indicates the time (in sec) that the battery has
been in constant-voltage regulation 64
ABSORB_TIMER 0x32 R 15:0 For LiFePO4 and lead-acid batteries, indicates the time (in sec) that the
battery has been in absorb phase 64
EQUALIZE_TIMER 0x33 R 15:0 For lead-acid batteries, indicates the time (in sec) that the battery has
been in EQUALIZE phase 64
LTC4015
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REGISTER DESCRIPTIONS
SYMBOL
SUB
ADDR R/W
ACTIVE
BITS DESCRIPTION DEFAULT PAGE
CHARGER_STATE 0x34 R 15:0 Real time battery charger state indicator. Individual bits are mutually
exclusive. Bits 15:11 are reserved. 64
equalize_charge 10 indicates battery charger is in lead-acid equalization charge state 64
absorb_charge 9 indicates battery charger is in absorb charge state 64
charger_suspended 8 indicates battery charger is in charger suspended state 64
precharge 7 indicates battery charger is in precondition charge state 64
cc_cv_charge 6 indicates battery charger is in constant-current constant-voltage state 64
ntc_pause 5 indicates battery charger is in thermistor pause state 65
timer_term 4 indicates battery charger is in timer termination state 65
c_over_x_term 3 indicates battery charger is in C/x termination state 65
max_charge_time_fault 2 indicates battery charger is in max_charge_time_fault state 65
bat_missing_fault 1 indicates battery charger is in missing battery fault state 65
bat_short_fault 0 indicates battery charger is in shorted battery fault state 65
CHARGE_STATUS 0x35 R 15:0 Charge status indicator. Individual bits are mutually exclusive. Only
active in charging states. 65
vin_uvcl_active 3 indicates the input undervoltage control loop is actively controlling
power delivery based on VIN_UVCL_SETTING (0x16) 65
iin_limit_active 2 indicates the input current limit control loop is actively controlling
power delivery based on IIN_LIMIT_DAC (0x46) 65
constant_current 1 indicates the charge current control loop is actively controlling
power delivery based on ICHARGE_DAC (0x44) 65
constant_voltage 0 indicates the battery voltage control loop is actively controlling power
delivery based on VCHARGE_DAC (0x45) 65
LIMIT_ALERTS 0x36 R 15:0 Limit alert register.
Individual bits are enabled by EN_LIMIT_ALERTS (0x0D).
Writing 0 to any bit clears that alert.
Once set, alert bits remain high until cleared or disabled.
65
meas_sys_valid_alert 15 indicates that measurement system results have become valid. 66
qcount_lo_alert 13 indicates QCOUNT has fallen below QCOUNT_LO_ALERT_LIMIT (0x10) 66
qcount_hi_alert 12 indicates QCOUNT has exceeded QCOUNT_HI_ALERT_LIMIT (0x11) 66
vbat_lo_alert 11 indicates VBAT has fallen below VBAT_LO_ALERT_LIMIT (0x01) 66
vbat_hi_alert 10 indicates VBAT has exceeded VBAT_HI_ALERT_LIMIT (0x02) 66
vin_lo_alert 9 indicates VIN has fallen below VIN_LO_ALERT_LIMIT (0x03) 66
vin_hi_alert 8 indicates VIN has exceeded VIN_HI_ALERT_LIMIT (0x04) 66
vsys_lo_alert 7 indicates VSYS has fallen below VSYS_LO_ALERT_LIMIT (0x05) 66
vsys_hi_alert 6 indicates VSYS has exceeded VIN_HI_ALERT_LIMIT (0x06) 66
iin_hi_alert 5 indicates IIN has exceeded IIN_HI_ALERT_LIMIT (0x07) 66
ibat_lo_alert 4 indicates IBAT has fallen below IBAT_LO_ALERT_LIMIT (0x08) 66
die_temp_hi_alert 3 indicates DIE_TEMP has exceeded DIE_TEMP_HI_ALERT_LIMIT (0x09) 67
bsr_hi_alert 2 indicates BSR has exceeded BSR_HI_ALERT_LIMIT (0x0A) 67
LTC4015
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REGISTER DESCRIPTIONS
SYMBOL
SUB
ADDR R/W
ACTIVE
BITS DESCRIPTION DEFAULT PAGE
ntc_ratio_hi_alert 1 indicates NTC_RATIO has exceeded NTC_RATIO_HI_ALERT_LIMIT
(cold battery; 0x0B) 67
ntc_ratio_lo_alert 0 indicates NTC_RATIO has exceeded NTC_RATIO_LO_ALERT_LIMIT
(hot battery; 0x0C) 67
CHARGER_STATE_ALERTS 0x37 R 15:0 Charger state alert register.
Individual bits are enabled by EN_CHARGER_STATE_ALERTS (0x0E).
Writing 0 to any bit clears that alert.
Once set, alert bits remain high until cleared or disabled.
67
equalize_charge_alert 10 alert indicates charger has entered lead-acid equalize_charge state (0x34) 67
absorb_charge_alert 9 alert indicates charger has entered absorb_charge state (0x34) 67
charger_suspended_alert 8 alert indicates charger has entered charger_suspended(off) state (0x34) 67
precharge_alert 7 alert indicates charger has entered precharge charge state (0x34) 67
cc_cv_charge_alert 6 alert indicates charger has entered cc_cv_charge state (constant-current
constant-voltage; 0x34) 67
ntc_pause_alert 5 alert indicates charger has entered ntc_pause state (0x34) 67
timer_term_alert 4 alert indicates charger has entered timer_term state (0x34) 67
c_over_x_term_alert 3 alert indicates charger has entered c_over_x term state
(C/x termination; 0x34) 67
max_charge_time_fault_alert 2 alert indicates charger has entered max_charge_time_fault state (0x34) 68
bat_missing_fault_alert 1 alert indicates charger has entered bat_missing_fault state (0x34) 68
bat_short_fault_alert 0 alert indicates charger has entered bat_short_fault state (0x34) 68
CHARGE_STATUS_ALERTS 0x38 R 5:0 Alerts that CHARGE_STATUS indicators have occurred
Individual bits are enabled by EN_CHARGE_STATUS_ALERTS (0x0F)
Writing 0 to any bit clears that alert.
Once set, alert bits remain high until cleared or disabled.
68
vin_uvcl_active_alert 3 alert indicates vin_uvcl_active state entered (VIN undervoltage current
limit, 0x35) 68
iin_limit_active_alert 2 alert indicates iin_limit_active state entered (VIN current limit; 0x35) 68
constant_current_alert 1 alert indicates constant_current state entered (0x35) 68
constant_voltage_alert 0 alert indicates constant_voltage state entered (0x35) 68
SYSTEM_STATUS 0x39 R 15:0 Real time system status indicator bits 68
charger_enabled 13 indicates that the battery charger is active 68
mppt_en_pin 11 indicates the mppt_en pin is set to enable maximum power point
tracking 68
equalize_req 10 indicates a rising edge has been detected at the EQ pin, and an lead-acid
equalize charge is queued 68
drvcc_good 9 indicates DRVCC voltage is above switching charger undervoltage
lockout level (4.3V typical) 69
cell_count_error 8 indicates an invalid combination of CELLS pin settings 69
ok_to_charge 6 indicates all system conditions are met to allow battery charger
operation 69
no_rt 5 indicates no resistor has been detected at the rt pin 69
thermal_shutdown 4 indicates die temperature is greater than thermal shutdown level
(160°C typical) 69
LTC4015
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SYMBOL
SUB
ADDR R/W
ACTIVE
BITS DESCRIPTION DEFAULT PAGE
vin_ovlo 3 indicates vin voltage is greater than overvoltage lockout level
(38.6V typical) 69
vin_gt_vbat 2 indicates vin voltage is sufficiently greater than batsens for switching
charger operation (200mV typical) 69
intvcc_gt_4p3v 1 indicates INTVCC voltage is above switching charger undervoltage
lockout level (4.3V typ) 69
intvcc_gt_2p8v 0 indicates INTVCC voltage is greater than measurement system lockout
level (2.8V typical) 69
VBAT 0x3A R 15:0 Tw o’s complement ADC measurement result for the BATSENS pin.
VBATSENS/cellcount = [VBAT] • 192.264µV for lithium chemistries.
VBATSENS/cellcount = [VBAT] • 128.176µV for lead-acid. 69
VIN 0x3B R 15:0 Two ’s complement ADC measurement result for VIN.
VVIN = [VIN] • 1.648mV 69
VSYS 0x3C R 15:0 Tw o’s complement ADC measurement result for VSYS.
VSYS = [VSYS] • 1.648mV 69
IBAT 0x3D R 15:0 Tw o’s complement ADC measurement result for (VCSP – VCSN). Charge
current (into the battery) is represented as a positive number. Battery
current = [IBAT] • 1.46487µV/RSNSB
69
IIN 0x3E R 15:0 Tw o ’s complement ADC measurement result for (VCLP – VCLN). Input
current = [IIN] • 1.46487µV/RSNSI 70
DIE_TEMP 0x3F R 15:0 Tw o’s complement ADC measurement result for die temperature.
Temperature = (DIE_TEMP – 12010)/45.6°C 70
NTC_RATIO 0x40 R 15:0 Tw o’s complement ADC measurement result for NTC thermistor ratio.
RNTC = NTC_RATIO • RNTCBIAS/(21845.0 – NTC_RATIO) 70
BSR 0x41 R 15:0 Calculated battery series resistance.
For lithium chemistries, series resistance/cellcount = BSR • RSNSB/500.0
For lead-acid chemistries, series resistance/cellcount = BSR • RSNSB/750.0 70
JEITA_REGION 0x42 R 2:0 JEITA temperature region of the NTC thermistor (Li Only). Active only
when EN_JEITA=1 70
CHEM_CELLS 0x43 R 11:0 Readout of CHEM and CELLS pin settings 70
chem 11:8 programmed battery chemistry 70
reserved 7:4 Reserved
cell_count_pins 3:0 cell count as set by CELLS pins 70
ICHARGE_DAC 0x44 R 4:0 Charge current control DAC control bits 71
VCHARGE_DAC 0x45 R 5:0 Charge voltage control DAC control bits 71
IIN_LIMIT_DAC 0x46 R 5:0 Input current limit control DAC control word 71
VBAT_FILT 0x47 R 15:0 Digitally filtered two’s complement ADC measurement result for battery
voltage 71
ICHARGE_BSR 0x48 R 15:0 This 16-bit two's complement word is the value of IBAT (0x3D) used in
calculating BSR. 71
RESERVED 0x49
MEAS_SYS_VALID 0x4A R 0 Measurement valid bit, bit 0 is a 1 when the telemetry(ADC) system is
ready 71
Notes:
1. Some defaults are chemistry dependant. See the detailed register descriptions for more information.
2. Charger setting registers (sub-addresses 0x1A through 0x2D) are only writable if the CHEM pins are configured for a programmable chemistry option.
If the CHEM pins are configured for a fixed chemistry option, the charger setting registers are read only.
REGISTER DESCRIPTIONS
LTC4015
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DETAILED REGISTER DESCRIPTIONS
VBAT_LO_ALERT_LIMIT (Sub-Address 0x01, Bits 15:0, R/W),
VBAT_HI_ALERT_LIMIT (Sub-Address 0x02, Bits 15:0, R/W)
These 16-bit words set upper and lower limits that can be used to trigger an SMBALERT based on the BATSENS pin
voltage out of range. The values use the same two’s complement format as VBAT. For lithium chemistries, BATSENS/
cellcount voltage HI/LO alert limit = [VBAT_xx_ALERT_LIMIT] • 192.264µV. For lead-acid batteries, BATSENS/cellcount
voltage HI/LO alert limit = [VBAT_xx_ALERT_LIMIT] • 128.176µV
VIN_LO_ALERT_LIMIT (Sub-Address 0x03, Bits 15:0, R/W),
VIN_HI_ALERT_LIMIT (Sub-Address 0x04, Bits 15:0, R/W)
These 16-bit words set upper and lower limits that can be used to trigger an SMBALERT based on input voltage at
the VIN pin out of range. The values use the same two’s complement format as VIN. Input voltage HI/LO alert limit =
[VIN_xx_ALERT_LIMIT] • 1.648mV.
VSYS_LO_ALERT_LIMIT (Sub-Address 0x05, Bits 15:0, R/W),
VSYS_HI_ALERT_LIMIT (Sub-Address 0x06, Bits 15:0, R/W)
These 16-bit words set upper and lower limits that can be used to trigger an SMBALERT based on system voltage at
the SYS pin out of range. The values use the same two’s complement format as VSYS. System voltage HI/LO alert
limit = [VSYS_xx_ALERT_LIMIT] • 1.648mV.
IIN_HI_ALERT_LIMIT (Sub-Address 0x07, Bits 15:0, R/W)
This 16-bit word sets an upper limit that can be used to trigger an SMBALERT based on input current above a certain
value. IIN_HI_ALERT_LIMIT uses the same two’s complement format as IIN. Input current high alert limit = [IIN_HI_
ALERT_LIMIT] • 1.46487µV/RSNSI.
IBAT_LO_ALERT_LIMIT (Sub-Address 0x08, Bits 15:0, R/W)
This 16-bit word sets an upper limit that can be used to trigger an SMBALERT based on charge current below a certain
value. IBAT_LO_ALERT_LIMIT uses the same two’s complement format as IBAT with battery discharge current being
negative. Battery current low alert limit = [IBAT_LO_ALERT_LIMIT] • 1.46487µV/RSNSB.
DIE_TEMP_HI_ALERT_LIMIT (Sub-Address 0x09, Bits 15:0, R/W)
This 16-bit word sets an upper limit that can be used to trigger an SMBALERT based on high die temperature. DIE_
TEMP_HI_ALERT_LIMIT uses the same two’s complement format as DIE_TEMP. LTC4015 temperature = (DIE_TEMP
– 12010)/45.6°C
BSR_HI_ALERT_LIMIT (Sub-Address 0x0A, Bits 15:0, R/W)
This 16-bit word sets an upper limit that can be used to trigger an SMBALERT based on high battery series resistance.
BSR_HI_ALERT_LIMIT uses the same format as BSR. The battery series resistance is a function of RSNSB, and can be
computed as Ω/cellcount = [BSR/500] • RSNSB (lithium chemistries), or Ω/cellcount = [BSR/750] • RSNSB (lead-acid).
NTC_RATIO_HI_ALERT_LIMIT (Sub-Address 0x0B, Bits 15:0,R/W),
NTC_RATIO_LO_ALERT_LIMIT (Sub-Address 0x0C, Bits 15:0, R/W)
These 16-bit words set upper and lower limits that can be used to trigger an SMBALERT based on thermistor value out
of range. The values use the same two’s complement format as NTC_RATIO. The thermistor value can be determined
by the expression RNTC = RNTCBIAS • NTC_RATIO/(21,845 – NTC_RATIO). Recall that the thermistor has a negative
temperature coefficient so higher temperatures correspond to lower NTC_RATIO readings and vice-versa. Thus,
NTC_RATIO_HI_ALERT_LIMIT sets an upper alert limit for the value of NTC_RATIO which corresponds to a low (cold)
temperature for the thermistor, and NTC_RATIO_LO_ALERT_LIMIT sets a lower alert limit for the value of NTC_RATIO
which corresponds to a high (hot) temperature for the thermistor.
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DETAILED REGISTER DESCRIPTIONS
EN_LIMIT_ALERTS (Sub-Address 0x0D, Bits 15:0, R/W)
This register consists of individual limit alert enable bits. These bits enable monitoring and notification of limit excursions
via SMBALERT and the LIMIT_ALERTS (0x36) register. See the section Programmable Alerts and Interrupt Controller
for more information.
en_meas_sys_valid_alert (Sub-Address 0x0D, Bit 15, R/W)
To achieve high measurement accuracy, the measurement system in the LTC4015 has a nominal warm up time of
approximately 12ms. Setting this alert enable bit causes an SMBALERT when the measurement system indicates
its results are valid. Note that the LTC4015 switching charger will not operate until the measurement system warm
up period has passed, regardless of the state of en_meas_sys_valid_alert.
en_qcount_lo_alert (Sub-Address 0x0D, Bit 13, R/W)
Setting this enable bit causes an SMBALERT when QCOUNT has fallen below QCOUNT_LO_ALERT_LIMIT. qcount_
lo_alert is set to 1 by the LTC4015 if the alert occurs.
en_qcount_hi_alert (Sub-Address 0x0D, Bit 12, R/W)
Setting this enable bit causes an SMBALERT when QCOUNT has exceeded QCOUNT_HI_ALERT_LIMIT. qcount_hi_alert
is set to 1 by the LTC4015 if the alert occurs.
en_vbat_lo_alert (Sub-Address 0x0D, Bit 11, R/W)
Setting this enable bit causes an SMBALERT when VBAT has fallen below VBAT_LO_ALERT_LIMIT. vbat_lo_alert
is set to 1 by the LTC4015 if the alert occurs.
en_vbat_hi_alert (Sub-Address 0x0D, Bit 10, R/W)
Setting this enable bit causes an SMBALERT when VBAT has exceeded VBAT_HI_ALERT_LIMIT. vbat_hi_alert is
set to 1 by the LTC4015 if the alert occurs.
en_vin_lo_alert (Sub-Address 0x0D, Bit 9, R/W)
Setting this enable bit causes an SMBALERT when VIN has fallen below VIN_LO_ALERT_LIMIT. vin_lo_alert is set
to 1 by the LTC4015 if the alert occurs.
en_vin_hi_alert (Sub-Address 0x0D, Bit 8, R/W)
Setting this enable bit causes an SMBALERT when VIN has exceeded VIN_HI_ALERT_LIMIT. vin_hi_alert is set to
1 by the LTC4015 if the alert occurs.
en_vsys_lo_alert (Sub-Address 0x0D, Bit 7, R/W)
Setting this enable bit causes an SMBALERT when VSYS has fallen below VSYS_LO_ALERT_LIMIT. vsys_lo_alert
is set to 1 by the LTC4015 if the alert occurs.
en_vsys_hi_alert (Sub-Address 0x0D, Bit 6, R/W)
Setting this enable bit causes an SMBALERT when VSYS has exceeded VSYS_HI_ALERT_LIMIT. vsys_hi_alert is
set to 1 by the LTC4015 if the alert occurs.
en_iin_hi_alert (Sub-Address 0x0D, Bit 5, R/W)
Setting this enable bit causes an SMBALERT when IIN has exceeded IIN_HI_ALERT_LIMIT. iin_hi_alert is set to 1
by the LTC4015 if the alert occurs.
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DETAILED REGISTER DESCRIPTIONS
en_ibat_lo_alert (Sub-Address 0x0D, Bit 4, R/W)
Setting this enable bit causes an SMBALERT when IBAT has fallen below IBAT_LO_ALERT_LIMIT. ibat_lo_alert is
set to 1 by the LTC4015 if the alert occurs.
en_die_temp_hi_alert (Sub-Address 0x0D, Bit 3, R/W)
Setting this enable bit causes an SMBALERT when DIE_TEMP has exceeded DIE_TEMP_HI_ALERT_LIMIT. die_
temp_hi_alert is set to 1 by the LTC4015 if the alert occurs.
en_bsr_hi_alert (Sub-Address 0x0D, Bit 2, R/W)
Setting this enable bit causes an SMBALERT when BSR has exceeded BSR_HI_ALERT_LIMIT. bsr_hi_alert is set
to 1 by the LTC4015 if the alert occurs.
en_ntc_ratio_hi_alert (Sub-Address 0x0D, Bit 1, R/W)
Setting this enable bit causes an SMBALERT when NTC_RATIO has exceeded NTC_RATIO_HI_ALERT_LIMIT (cold
battery). Recall that the thermistor has a negative temperature coefficient so higher temperatures correspond to
lower NTC_RATIO readings and vice-versa. ntc_ratio_hi_alert is set to 1 by the LTC4015 if the alert occurs.
en_ntc_ratio_lo_alert (Sub-Address 0x0D, Bit 0, R/W)
Setting this enable bit causes an SMBALERT when NTC_RATIO has fallen below NTC_RATIO_LO_ALERT_LIMIT
(hot battery). Recall that the thermistor has a negative temperature coefficient so higher temperatures correspond
to lower NTC_RATIO readings and vice-versa. ntc_ratio_lo_alert is set to 1 by the LTC4015 if the alert occurs.
EN_CHARGER_STATE_ALERTS (Sub-Address 0x0E, Bits 10:0, R/W)
This register consists of individual charger state alert enable bits, which enable notification via SMBALERT based on
the phase of a battery charge cycle. See the CHARGER_STATE (0x37) register details and the sections Battery Charger
Algorithms and Programmable Alerts and Interrupt Controller for more information.
en_equalize_charge_alert (Sub-Address 0x0E, Bit 10, R/W)
Setting this enable bit causes an SMBALERT when the LTC4015 is in the equalize phase of a battery charge cycle
(equalize_charge=1, applies to lead-acid chemistries only).
en_absorb_charge_alert (Sub-Address 0x0E, Bit 9, R/W)
Setting this enable bit causes an SMBALERT when the LTC4015 is in the absorb phase of a battery charge cycle
(absorb_charge=1, applies to LiFePO4 and lead-acid chemistries only).
en_charger_suspended_alert (Sub-Address 0x0E, Bit 8, R/W)
Setting this enable bit causes an SMBALERT when the LTC4015 charger is suspended (charger_suspended=1).
en_precharge_alert (Sub-Address 0x0E, Bit 7, R/W)
Setting this enable bit causes an SMBALERT when the LTC4015 is in precondition charge phase of a battery charge
cycle (precharge=1) due to the battery being below the low battery threshold of 2.9V/cell (applies to Li-Ion chem-
istries only).
en_cc_cv_charge_alert (Sub-Address 0x0E, Bit 6, R/W)
Setting this enable bit causes an SMBALERT when the LTC4015 is in the CC-CV phase of a battery charge cycle
(cc_cv_charge=1).
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DETAILED REGISTER DESCRIPTIONS
en_ntc_pause_alert (Sub-Address 0x0E, Bit 5, R/W)
Setting this enable bit causes an SMBALERT when the LTC4015 is in thermistor pause state (ntc_pause=1) due
to NTC_RATIO out of range as set by the JEITA_T1 and JEITA_T6 values. See the section J.E.I.T.A. Temperature
Qualified Charging (applies to lithium chemistries only).
en_timer_term_alert (Sub-Address 0x0E, Bit 4, R/W)
Setting this enable bit causes an SMBALERT when the LTC4015 is in timer termination state (timer_term=1) due to
battery being at VCHARGE for more than MAX_CHARGE_TIME (applies to lithium chemistries only).
en_c_over_x_term_alert (Sub-Address 0x0E, Bit 3, R/W)
Setting this enable bit causes an SMBALERT when the LTC4015 is in C/x termination state (c_over_x_term=1) due
to IBAT dropping below C_OVER_X_THRESHOLD (applies to lithium chemistries only).
en_max_charge_time_fault_alert (Sub-Address 0x0E, Bit 2, R/W)
Setting this enable bit causes an SMBALERT when the LTC4015 is in max charge time fault (max_charge_time_
fault = 1) due to MAX_CHARGE_TIMER exceeding MAX_CHARGE_TIME during a charge cycle (applies to lithium
chemistries only).
en_bat_missing_fault_alert (Sub-Address 0x0E, Bit 1, R/W)
Setting this enable bit causes an SMBALERT if the LTC4015 is in battery missing fault state (bat_missing_fault=1)
due to no battery detected.
en_bat_short_fault_alert (Sub-Address 0x0E, Bit 0, R/W)
Setting this enable bit causes an SMBALERT if the LTC4015 is in shorted battery fault state (bat_short_fault=1) be-
cause the battery was determined to be shorted during the battery detection phase at the beginning of a charge cycle.
EN_CHARGE_STATUS_ALERTS (Sub-Address 0x0F, Bits 3:0, R/W)
This register consists of individual charge status alert enable bits, which enable notification via SMBALERT based on
the status of the battery charge current control circuitry. See the CHARGE_STATUS register details and the section
Programmable Alerts and Interrupt Controller for more information.
en_vin_uvcl_active_alert (Sub-Address 0x0F, Bit 3, R/W)
Setting this enable bit causes an SMBALERT when the UVCL undervoltage current limit regulation loop of the
LTC4015 is in control of the switching CHARGER current delivery (vin_uvcl_active=1).
en_iin_limit_active_alert (Sub-Address 0x0F, Bit 2, R/W)
Setting this enable bit causes an SMBALERT when the input current regulation loop of the LTC4015 is in control of
the switching CHARGER current delivery (iin_limit_active=1).
en_constant_current_alert (Sub-Address 0x0F, Bit 1, R/W)
Setting this enable bit causes an SMBALERT when the battery charge current regulation loop of the LTC4015 is in
control of the switching CHARGER current delivery (constant_current=1).
en_constant_voltage_alert (Sub-Address 0x0F, Bit 0, R/W)
Setting this enable bit causes an SMBALERT when the battery voltage regulation loop of the LTC4015 is in control
of the switching CHARGER current delivery (constant_voltage=1).
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DETAILED REGISTER DESCRIPTIONS
QCOUNT_LO_ALERT_LIMIT (Sub-Address 0x10, Bits 15:0, R/W)
QCOUNT_HI_ALERT_LIMIT (Sub-Address 0x11, Bits 15:0, R/W)
These 16-bit words set and lower and upper limits on QCOUNT that can be used to trigger an SMBALERT when QCOUNT
falls below QCOUNT_LO_ALERT_LIMIT, or QCOUNT exceeds QCOUNT_HI_ALERT_LIMIT. The values use the same
format as QCOUNT.
QCOUNT_PRESCALE_FACTOR (Sub-Address 0x12, Bits 15:0, R/W)
This 16-bit word along with RSNSB is used to set the qLSB value of Coulomb counter accumulator, QCOUNT.
qLSB=
QCOUNT_PRESCALE_FACTOR
8333.33R
SNSB
A s(COULOMBS)
QCOUNT (Sub-Address 0x13, Bits 15:0, R/W)
This 16-bit word reports the current value of Coulomb counter accumulator, QCOUNT. This register can be written to
represent a known state of charge of the battery.
qLSB=
QCOUNT_PRESCALE_FACTOR
8333.33R
SNSB
A s(COULOMBS)
CONFIG_BITS (Sub-Address 0x14, Bits 8:0, R/W)
This register consists of individual system configuration bits which control various features of the LTC4015.
suspend_charger (Sub-Address 0x14, Bit 8, R/W)
Setting this bit causes battery charging to be suspended, and forces charger_suspended=1. A new battery charge
cycle can be forced by setting and then resetting suspend_charger.
run_bsr (Sub-Address 0x14, Bit 5, R/W)
Setting this bit causes a single battery series resistance (BSR) measurement to be made by the LTC4015. Once
the series resistance measurement is complete, the LTC4015 resets the run_bsr bit to 0, and the result is reported
as BSR. ICHARGE_BSR is the value of IBAT that was used in the BSR calculation. See the section Battery Series
Resistance Measurement.
force_meas_sys_on (Sub-Address 0x14, Bit 4, R/W)
Setting this bit causes the A/D measurement system to operate at all times, including when input power is unavailable
(vin_gt_vbat=0). This feature is disabled by default in order to reduce battery-only load current. Setting this bit has
the advantage of maintaining up-to-date system data, but will increase battery drain.
When input power is absent, the measurement system can be sampled periodically to reduce quiescent current.
See the Measurement Subsystem description for details.
mppt_en_i2c (Sub-Address 0x14, Bit 3, R/W)
Setting this bit causes the maximum power point tracking algorithm to run when the switching charger is active.
The maximum power point algorithm uses the UVCL regulation loop to seek the optimum power point for resistive
sources such as a solar panel. See the section maximum power point tracking for more information. The maximum
power point algorithm can also be enabled by connecting the MPPT pin to the 2P5VCC pin. The mppt_en_i2c bit
is logically ORed with the MPPT pin. To disable MPPT both the mppt_en_i2c bit and the MPPT pin must be low.
en_qcount (Sub-Address 0x14, Bit 2, R/W)
Setting this bit enables the LTC4015 Coulomb counter. This feature is disabled by default to reduce quiescent current.
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DETAILED REGISTER DESCRIPTIONS
IIN_LIMIT_SETTING (Sub-Address 0x15, Bits 5:0, R/W)
These 6 bits control the target input current limit setting. The input current will be regulated to a maximum value given
by (IIN_LIMIT_SETTING + 1) • 500µV/RSNSI.
VIN_UVCL_SETTING (Sub-Address 0x16, Bits 7:0, R/W)
These 8 bits control the UVCLFB regulation loop servo voltage. The UVCLFB regulation voltage is given by (VIN_UVCL_
SETTING + 1) • 4.6875mV. By default, this register is set to full-scale (0xFF), corresponding to 1.2V at UVCLFB pin. If
enabled, the maximum power point tracking (MPPT) algorithm directly manipulates VIN_UVCL_SETTING.
ARM_SHIP_MODE (Sub-Address 0x19, Bits 15:0, R/W)
Setting this register to 0x534D (ASCII for SM) arms LTC4015’s low power ship mode. The only allowed values for
this register are 0x0000 and 0x534D, and once armed, ship mode cannot be disarmed (writing ARM_SHIP_MODE=0
does not disarm ship mode). Ship mode does not take effect until VIN drops below approximately 1V. See the section
Low Power Ship Mode.
CHARGER SETTING REGISTER DESCRIPTIONS (Sub-Addresses 0x1A through 0x2E)
Registers which control the primary charging parameters, such as charge voltage and charge current are only writ-
able when the CHEMn pins are configured for a programmable chemistry algorithm (Li-Ion-Prog, LiFePO4-Prog, or
Lead-Acid-Prog). If the CHEMn pins are configured for a fixed chemistry algorithm (Li-Ion-Fixed-4.2, Li-Ion-Fixed-4.1,
Li-Ion-fixed-4.0, LiFePO4-Fixed-3.6, LiFePO4-Fixed-3.8/3.6, or Lead-Acid-Fixed) the LTC4015 ignores writes to these
registers. See the section Chemistry Selection for more information about configuring the CHEMn pins.
ICHARGE_TARGET (Sub-Address 0x1A, bits 4:0, Fixed: R, Programmable: R/W)
This register controls the target charge current regulation servo level for lead-acid batteries or if en_jeita=0 for lithium
chemistries. For lithium chemistries, if en_jeita=1 (default) ICHARGE_TARGET is controlled by ICHARGE_JEITA_n
(see the section JEITA Temperature Controlled Charging). The charge current regulation servo level is generally given
by (ICHARGE_TARGET + 1) × 1mV/RSNSB, except during Li-Ion precondition charge phase when the charge current
regulation servo level is reduced by approximately a factor of 10 (rounded down to an increment of 1mV/RSNSB).
VCHARGE_SETTING (Sub-Address 0x1B, bits 5:0, Fixed: R, Programmable: R/W)
This register controls the charge voltage regulation servo level. The LTC4015 does not monitor or balance individual
cellsthe full battery stack voltage is divided by number of cells (V/cell) for simplicity only. The 4015 is not a substitute
for pack protection!
For Li-Ion batteries, only the lower five bits (4:0) are active, and the charge voltage level is given by (VCHARGE_
SETTING/80.0 + 3.8125)V/cell. If en_jeita=1, VCHARGE_SETTING is controlled by vcharge_jeita_n (see the section
JEITA Temperature Qualified Charging). To maintain inherent over charge protection, the maximum Li-Ion charge
voltage level is 4.2V/cell.
For LiFePO4 batteries, only the lower five bits (4:0) are active, and the charge voltage level is given by (VCHARGE_
SETTING/80.0 + 3.4125)V/cell. If en_jeita=1, VCHARGE_SETTING is controlled by vcharge_jeita_n (see the section
JEITA Temperature Qualified Charging). To maintain inherent over-charge protection, the maximum LiFePO4 charge
voltage level is 3.8V/cell.
For lead-acid batteries, if en_lead_acid_temp_comp=1, the charge voltage level is given by (VCHARGE_SETTING/105.0
+ 2.0)V/cell at 25°C when a thermistor with a β value of 3490k is used. See the section Lead-Acid Temperature
Compensated Charging for more information. If en_lead_acid_temp_comp=1, the value of VCHARGE_SETTING is
limited to a maximum setting of 35, which corresponds to 2.333V/cell. If en_lead_acid_temp_comp=0, the charge
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DETAILED REGISTER DESCRIPTIONS
voltage level is given by (VCHARGE_SETTING/105.0 + 2.0)V/cell, regardless of temperature. To maintain inherent over
charge protection, the maximum lead-acid charge voltage level is 2.6 V/cell.
VABSORB_DELTA (Sub-Address 0x2A, bits 5:0, Fixed: R, Programmable: R/W)
This register controls the absorb adder voltage for LiFePO4 and lead-acid batteries in absorb charge phase. The absorb
charge phase battery voltage servo level is based on the sum of the absorb adder voltage and the charge voltage level.
For Li-Ion batteries, VABSORB_DELTA is ignored.
For LiFePO4 batteries, only the lower five bits (4:0) are active, and the absorb voltage level is given by (VABSORB_DELTA
+ VCHARGE_SETTING)/80 + 3.4125 V/cell, limited to a maximum of 3.8 V/cell. Setting VABSORB_DELTA=0 disables
the absorb phase. See the section LiFePO4 Absorb Charge for more information.
For lead-acid batteries, if en_lead_acid_temp_comp=1, the absorb voltage level is given by (VABSORB_DELTA +
VCHARGE_SETTING)/105.0 + 2.0V/cell at 25°C when a thermistor with a β value of 3490k is used. See the section
Lead-Acid Temperature Compensated Charging for more information. If en_lead_acid_temp_comp=0, the absorb
voltage level is given by (VABSORB_DELTA + VCHARGE_SETTING)/105.0 + 2.0V/cell, regardless of temperature. To
maintain inherent over charge protection, the maximum lead-acid absorb voltage level is 2.6 V/cell.
VEQUALIZE_DELTA (Sub-Address 0x2C, Bits 5:0, Fixed: R, Programmable: R/W)
These six bits control the equalize adder voltage for lead-acid batteries in equalize charge phase. The equalize charge
phase battery voltage servo level is based on the sum of the equalize adder voltage and the vcharge level.
For lead-acid batteries, if en_lead_acid_temp_comp=1, the equalize voltage level is given by (VEQUALIZE_DELTA +
VCHARGE_SETTING) / 105.0 + 2.0 V/cell at 25°C when a typical curve two thermistor is used. See the section Lead-Acid
Temperature Compensated Charging for more information. If en_lead_acid_temp_comp=0, the equalize voltage level
is given by ((VEQUALIZE_DELTA + VCHARGE_SETTING)/105.0 + 2.0)V/cell, regardless of temperature. To maintain
inherent over charge protection, the maximum lead-acid equalize voltage level is 2.6V/cell.
For lithium chemistries, VEQUALIZE_DELTA is ignored.
C_OVER_X_THRESHOLD (Sub-Address 0x1C, Bits 15:0, Fixed: R, Programmable: R/W)
This 16-bit word sets the IBAT value used to qualify C/x detection for charge phase termination/transition. C_OVER_X_
THRESHOLD uses the same format as IBAT, and the C/x current level is given by C_OVER_X_THRESHOLD/(RSNSB
• 21845.0/0.032V). The default value for C_OVER_X_THRESHOLD is 2184, which corresponds to 10% (3.2mV) of a
32mV/ RSNSB full-scale charge current. C/x detection is disabled if C_OVER_X_THRESHOLD is set to zero.
For Li-Ion batteries, if en_c_over_x_term=1 (0 by default), C/x charge termination occurs after the battery reaches the
charge voltage level and IBAT drops below C_OVER_X_THRESHOLD. See the section C/x Termination.
For LiFePO4 batteries, if en_c_over_x_term=1 (0 by default), C/x charge termination occurs after the battery reaches
vcharge level and IBAT drops below C_OVER_X_THRESHOLD during CC-CV charge phase. See the section C/x Termination.
If the optional LiFePO4 absorb charge phase is employed and if C_OVER_X_THRESHOLD is set to a non-zero value,
the absorb phase ends if the battery voltage reaches absorb level and IBAT drops below C_OVER_X_THRESHOLD,
and CC-CV phase begins. See the section LiFePO4 Absorb Charge.
For lead-acid batteries, if C_OVER_X_THRESHOLD is non-zero, absorb charge phase ends after the battery voltage
reaches absorb level and IBAT drops below C_OVER_X_THRESHOLD, and the CC-CV charge phase continues indefinitely.
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DETAILED REGISTER DESCRIPTIONS
MAX_CV_TIME (Sub-Address 0x1D, Bits 15:0, Fixed: R, Programmable: R/W)
For lithium chemistries, this 16-bit word sets the termination time limit at one second per count. If the charger is in
the CV state for MAX_CV_TIME seconds, timer termination occurs. The actual timer value is reported in CV_TIMER.
See the section Timer Termination for more information. The default setting is four hours (14,400) for Li- Ion batteries
and one hour (3,600) for LiFePO4 batteries. For lead-acid batteries, MAX_CV_TIME is ignored.
MAX_ABSORB_TIME (Sub-Address 0x2B, Bits 15:0, Fixed: R, Programmable: R/W)
For LiFePO4 and lead-acid batteries, this 16-bit word sets an upper limit on the time (at one second per count) that
the battery can be in the absorb charge phase. The actual timer value is reported in ABSORB_TIMER. See the sections
LiFePO4 Absorb Charge and Lead-Acid Absorb Charge. For Li-Ion batteries, MAX_ABSORB_TIME is ignored.
EQUALIZE_TIME (Sub-Address 0x2D, Bits 15:0, Fixed: R, Programmable: R/W)
For lead-acid batteries, this 16-bit word sets the time (at one second per count) for the equalization charge phase. For
lead-acid batteries, the default setting is 3600 seconds. See the section Lead-Acid Equalization Charge. For lithium
chemistries, EQUALIZE_TIME is ignored.
MAX_CHARGE_TIME (Sub-Address 0x1E, Bits 15:0, Fixed: R, Programmable: R/W)
For lithium chemistries, this 16-bit word sets the max_charge_time fault detection time at one second per count. The
default setting is 18.2 hours (65535). If the MAX_CHARGE_TIMER exceeds MAX_CHARGE_TIME during charging, a
max charge time fault occurs. See the section Max Charge Time Fault for more information. For lead-acid batteries,
MAX_CHARGE_TIME is ignored.
LIFEP04_RECHARGE_THRESHOLD (Sub-Address 0x2E, Bits 15:0, Fixed: R, Programmable: R/W)
In LiFePO4 programmable mode only, this 16 bit two's complement word sets the recharge threshold, where the
recharge threshold/cell = [LiFePO4_RECHARGE_THRESHOLD] • 192.264µV. Default is 0x4410 which is 3.35V/cell.
JEITA_Tn (Sub-Address 0x1F Through 0x24, Bits 15:0, Fixed: R, Programmable: R/W)
(n = 1,2,3,4,5,6)
For lithium chemistries, these six 16-bit words set the JEITA temperature region break points T1 – T6, and have the
same format as NTC_RATIO. The temperatures are based on the thermistor reading from the measurement system.
Recall that the thermistor has a negative temperature coefficient so JEITA_T1, representing colder temperatures, will
have the highest value and JEITA_T6, representing warmer temperatures, will have the lowest value. See the section
JEITA Temperature Qualified Charging. JEITA_Tn are ignored for lead-acid batteries or if en_jeita=0.
Programming of JEITA Values
REGION 1 REGION 2 REGION 3 REGION 4 REGION 5 REGION 6 REGION 7
[JEITA_T1] [JEITA_T2] [JEITA_T3 ] [JEITA_T4] [JEITA_T5] [JEITA_T6]
CHARGER
OFF icharge_jeita_2 icharge_jeita_3 icharge_jeita_4 icharge_jeita_5 icharge_jeita_6 CHARGER
OFF
vcharge_jeita_2 vcharge_jeita_3 vcharge_jeita_4 vcharge_jeita_5 vcharge_jeita_6
VCHARGE_JEITA_6_5 (Sub-Address 0x25, Bits 9:0, Fixed: R, Programmable: R/W),
VCHARGE_JEITA_4_3_2 (Sub-Address 0x26, Bits 14:0, Fixed: R, Programmable: R/W)
For lithium chemistries, these two registers contain the charge voltage settings to be used in the JEITA voltage vs
temperature profile. VCHARGE_JEITA_6_5 contains two bit packed values, vcharge_jeita_6 (bits 9:5) and vcharge_jeita_5
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DETAILED REGISTER DESCRIPTIONS
(bits 4:0). VCHARGE_JEITA_4_3_2 contains three bit packed values, vcharge_jeita_4 (bits 14:10), vcharge_jeita_3
(bits 9:5), and vcharge_jeita_2 (bits 4:0). These registers are ignored for lead-acid batteries or if en_jeita=0.
vcharge_jeita_n (n = 2,3,4,5,6)
These five 5-bit values set the VCHARGE_SETTING values to be used in each of the JEITA voltage vs temperature
regions. There are no defined charge voltages for regions 1 and 7 because battery charging is paused in these
regions. See the JEITA Temperature Qualified Charging section.
Programming of JEITA Values
REGION 1 REGION 2 REGION 3 REGION 4 REGION 5 REGION 6 REGION 7
[JEITA_T1] [JEITA_T2] [JEITA_T3 ] [JEITA_T4] [JEITA_T5] [JEITA_T6]
CHARGER
OFF icharge_jeita_2 icharge_jeita_3 icharge_jeita_4 icharge_jeita_5 icharge_jeita_6 CHARGER
OFF
vcharge_jeita_2 vcharge_jeita_3 vcharge_jeita_4 vcharge_jeita_5 vcharge_jeita_6
ICHARGE_JEITA_6_5 (Sub-Address 0x27, Bits 9:0, Fixed: R, Programmable: R/W),
ICHARGE_JEITA_4_3_2 (Sub-Address 0x28, Bits 14:0, Fixed: R, Programmable: R/W)
For lithium chemistries, these two registers contain the charge current settings to be used in the JEITA current vs
temperature profile. ICHARGE_JEITA_6_5 contains two bit packed values, icharge_jeita_6 (bits 9:5) and icharge_jeita_5
(bits 4:0). ICHARGE_JEITA_4_3_2 contains three bit packed values, icharge_jeita_4 (bits 14:10), icharge_jeita_3 (bits
9:5), and icharge_jeita_2 (bits 4:0). These registers are ignored for lead-acid batteries or if en_jeita=0.
icharge_jeita_n (n = 2,3,4,5,6)
These five 5-bit values set the ICHARGE_TARGET values to be used in each of the JEITA current vs temperature
regions. There are no defined charge currents for regions 1 and 7 because battery charging is paused in these
regions. See the JEITA Temperature Qualified Charging section.
Programming of JEITA Values
REGION 1 REGION 2 REGION 3 REGION 4 REGION 5 REGION 6 REGION 7
[JEITA_T1] [JEITA_T2] [JEITA_T3 ] [JEITA_T4] [JEITA_T5] [JEITA_T6]
CHARGER
OFF icharge_jeita_2 icharge_jeita_3 icharge_jeita_4 icharge_jeita_5 icharge_jeita_6 CHARGER
OFF
vcharge_jeita_2 vcharge_jeita_3 vcharge_jeita_4 vcharge_jeita_5 vcharge_jeita_6
CHARGER_CONFIG_BITS (Sub-Address 0x29, Bits 2:0, Fixed: R, Programmable: R/W)
This register consists of individual battery charger configuration bits which enable specific battery charger functions.
en_c_over_x_term (Sub-Address 0x29, Bit 2, Fixed: R, Programmable: R/W)
For lithium chemistries, setting this bit enables C/x charge termination, in conjunction with C_OVER_X_THRESHOLD.
For lead-acid batteries, en_c_over_x_term is ignored. Default is 0.
en_lead_acid_temp_comp (Sub-Address 0x29, Bit 1, Fixed: R, Programmable: R/W)
For lead-acid batteries, setting this bit enables temperature compensated charge voltage levels as detailed in the
Lead-Acid Temperature Compensated Charging section. Default is 1 for lead-acid batteries. For lithium chemistries,
en_lead_acid_temp_comp is ignored.
en_jeita (Sub-Address 0x29, Bit 0, Fixed: R, Programmable: R/W)
For lithium chemistries, setting this bit enables the JEITA temperature qualified algorithm as detailed in the JEITA
Temperature Qualified Charging section. The charging parameters are set by JEITA_Tn, vcharge_jeita_n, and
icharge_jeita _n. Default is 1 for lithium chemistries. For lead-acid batteries, en_jeita is ignored.
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DETAILED REGISTER DESCRIPTIONS
READOUTS, STATUS, AND ALERTS (Sub-Addresses 0x34 through 0x46)
MAX_CHARGE_TIMER (Sub-Address 0x30, Bits 15:0, R)
For lithium chemistries, this 16-bit word indicates the time (in seconds) that the battery has been charging. See the
MAX_CHARGE_TIME register description and the section Maximum Charge Time for more information. For lead-acid
batteries, MAX_CHARGE_TIMER is not used.
CV_TIMER (Sub-Address 0x31, Bits 10:0, R)
For lithium chemistries, this 16-bit word indicates the time (in seconds) that the battery has been in constant-voltage
regulation. See the MAX_CV_TIME register description and the section Timer Termination for more information. For
lead-acid batteries, CV_TIMER is not used.
ABSORB_TIMER (Sub-Address 0x32, Bits 10:0, R)
For LiFePO4 and lead-acid batteries, this 16-bit word indicates the time (in seconds) that the battery has been in absorb
phase. See the MAX_ABSORB_TIME register description and the sections LiFePO4 Absorb Charge and Lead-Acid
Absorb Charge for more information. For Li-Ion batteries, ABSORB_TIMER is not used.
EQUALIZE_TIMER (Sub-Address 0x33, Bits 15:0, Fixed: R, Programmable: R/W)
For lead-acid batteries, this 16-bit word indicates the time (in seconds) that the battery has been in equalization
charge phase. See the EQUALIZE_TIME register description and the section Lead-Acid Equalization Charge. For lithium
chemistries, EQUALIZE_TIMER is not used.
CHARGER_STATE (Sub-Address 0x34, Bits 10:0, R)
This register consists of individual battery charger state indicator bits. Individual bits are mutually exclusive (a maximum
of one bit is asserted at any given time). See the section Battery Charger Algorithms for more information regarding
the charger states.
equalize_charge (Sub-Address 0x34, Bit 10, R)
This bit indicates that the LTC4015 is in the equalize phase of a battery charge cycle (applies to lead-acid chemis-
tries only).
absorb_charge (Sub-Address 0x34, Bit 9, R)
This bit indicates that the LTC4015 is in the absorb phase of a battery charge cycle (applies to LiFePO4 and lead-
acid chemistries only).
charger_suspended (Sub-Address 0x34, Bit 8, R)
This bit indicates that the LTC4015 charger is suspended, due to any of the following conditions occurring: (a) the
input voltage on the VIN pin falls below or within 100mV of the BATSENS pin voltage, (b) suspend_charger is writ-
ten to 1 via the serial port, or (c) a system fault condition occurs (VIN overvoltage, 2P5VCC undervoltage, INTVCC
undervoltage, DRVCC undervoltage, thermal shutdown, missing RT resistor, or invalid combination of CELLS pins).
precharge (Sub-Address 0x34, Bit 7, R)
This bit indicates that the LTC4015 is in the precondition charge phase of a battery charge cycle due to the battery
being below the low battery threshold of 2.9V/cell (applies to Li-Ion chemistries only).
cc_cv_charge (Sub-Address 0x34, Bit 6, R)
This bit indicates that the LTC4015 is in the CC-CV phase of a battery charge cycle.
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DETAILED REGISTER DESCRIPTIONS
ntc_pause (Sub-Address 0x34, Bit 5, R)
This bit indicates that the LTC4015 is in thermistor pause state due to NTC_RATIO out of range as set by the JEITA_Tn
values. See the section JEITA Temperature Qualified Charging (applies to lithium chemistries only).
timer_term (Sub-Address 0x34, Bit 4, R)
This bit indicates that the LTC4015 is in timer termination state due to battery being at the vcharge voltage for more
than MAX_CV_TIME (applies to lithium chemistries only).
c_over_x_term (Sub-Address 0x34, Bit 3, R)
This bit indicates that the LTC4015 is in C/x termination state due to IBAT dropping below C_OVER_X_THRESHOLD
(applies to lithium chemistries only).
max_charge_time_fault (Sub-Address 0x34, Bit 2, R)
This bit indicates that the LTC4015 is in max charge time fault state due to MAX_CHARGE_TIMER exceeding
MAX_CHARGE_TIME during a charge cycle (applies to lithium chemistries only).
bat_missing_fault (Sub-Address 0x34, Bit 1, R)
This bit indicates that the LTC4015 is in battery missing fault state due to no battery detected.
bat_short_fault (Sub-Address 0x34, Bit 0, R)
This bit indicates that the LTC4015 is in battery short fault state due to a shorted battery detected.
CHARGE_STATUS (Sub-Address 0x35, Bits 3:0, R)
This register consists of individual status bits which indicate status of the battery charge current control circuitry.
Individual bits are mutually exclusive (a maximum of one bit is asserted at any given time).
vin_uvcl_active (Sub-Address 0x35, Bit 3, R)
This bit indicates that the UVCLFB pin of the undervoltage current limit loop of the LTC4015 is in control of the
switching charger current delivery based on VIN_UVCL_SETTING.
iin_limit_active (Sub-Address 0x35, Bit 2, R)
This bit indicates that the input current regulation loop of the LTC4015 is in control of the switching charger current
delivery based on IIN_LIMIT_SETTING.
constant_current (Sub-Address 0x35, Bit 1, R)
This bit indicates that the battery charge current regulation loop of the LTC4015 is in control of the switching
charger current delivery based on ICHARGE_DAC.
constant_voltage (Sub-Address 0x35, Bit 0, R)
This bit indicates that the battery voltage regulation loop of the LTC4015 is in control of the switching charger
current delivery based on VCHARGE_DAC.
LIMIT_ALERTS (Sub-Address 0x36, Bits 15:0, R/Clear)
This register consists of individual alert bits which can optionally indicate that limit excursions have caused an SMBALERT
to occur. The LTC4015 checks for new limits excursions at the end of every A/D measurement system cycle (approximately
6.5ms), and LIMIT_ALERTS is updated accordingly. Individual alert bits are enabled by EN_LIMIT_ALERTS.
Once asserted, alert bits remain high until disabled or cleared. Writing a 0 to any bit clears that alert. If an enabled
alert is cleared and the alerting condition remains, a new alert is triggered immediately. When a new alert occurs, the
LTC4015 pulls down the SMBALERT pin and holds it low until it completes a response to an alert response algorithm
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DETAILED REGISTER DESCRIPTIONS
(ARA). See the section Programmable Alerts and Interrupt Controller for more information regarding the SMBALERT
and ARA functions.
meas_sys_valid_alert (Sub-Address 0x36, Bit 15, R/Clear)
To achieve high measurement accuracy, the measurement system in the LTC4015 has a typical warm up time of
approximately 12ms. If en_meas_sys_valid_alert=1, the meas_sys_valid_alert bit indicates that an SMBALERT has
occurred because the warm-up period has passed and the A/D measurement system results are valid. This can be
particularly useful in battery only mode for periodic sampling of the measurement system; see force_meas_sys_on
for more information.
qcount_lo_alert (Sub-Address 0x36, Bit 13, R/Clear)
If en_qcount_lo_alert=1, this bit indicates that an SMBALERT has occurred because QCOUNT has fallen below
QCOUNT_LO_ALERT_LIMIT.
qcount_hi_alert (Sub-Address 0x36, Bit 12, R/Clear)
If en_qcount_hi_alert=1, this bit indicates that an SMBALERT has occurred because QCOUNT has exceeded
QCOUNT_HI_ALERT_LIMIT.
vbat_lo_alert (Sub-Address 0x36, Bit 11, R/Clear)
If en_vbat_lo_alert =1, this bit indicates that an SMBALERT has occurred because VBAT has fallen below VBAT_
LO_ALERT_LIMIT.
vbat_hi_alert (Sub-Address 0x36, Bit 10, R/Clear)
If en_vbat_hi_alert =1, this bit indicates that an SMBALERT has occurred because VBAT has exceeded VBAT_HI_
ALERT_LIMIT.
vin_lo_alert (Sub-Address 0x36, Bit 9, R/Clear)
If en_vin_lo_alert =1, this bit indicates that an SMBALERT has occurred because VIN has fallen below VIN_LO_
ALERT_LIMIT.
vin_hi_alert (Sub-Address 0x36, Bit 8, R/Clear)
If en_vin_hi_alert =1, this bit indicates that an SMBALERT has occurred because VIN has exceeded VIN_HI_ALERT_
LIMIT.
vsys_lo_alert (Sub-Address 0x36, Bit 7, R/Clear)
If en_vsys_lo_alert =1, this bit indicates that an SMBALERT has occurred because VSYS has fallen below VSYS_
LO_ALERT_LIMIT.
vsys_hi_alert (Sub-Address 0x36, Bit 6, R/Clear)
If en_vsys_hi_alert =1, this bit indicates that an SMBALERT has occurred because VSYS has exceeded VSYS_HI_
ALERT_LIMIT.
iin_hi_alert (Sub-Address 0x36, Bit 5, R/Clear)
If en_iin_hi_alert =1, this bit indicates that an SMBALERT has occurred because IIN has exceeded IIN_HI_ALERT_LIMIT.
ibat_lo_alert (Sub-Address 0x36, Bit 4, R/Clear)
If en_ibat_lo_alert =1, this bit indicates that an SMBALERT has occurred because IBAT has fallen below IBAT_LO_
ALERT_LIMIT.
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DETAILED REGISTER DESCRIPTIONS
die_temp_hi_alert (Sub-Address 0x36, Bit 3, R/Clear)
If en_die_temp_hi_alert =1, this bit indicates that an SMBALERT has occurred because DIE_TEMP has exceeded
DIE_TEMP_HI_ALERT_LIMIT.
bsr_hi_alert (Sub-Address 0x36, Bit 2, R/Clear)
If en_bsr_hi_alert =1, this bit indicates that an SMBALERT has occurred because BSR has exceeded BSR_HI_
ALERT_LIMIT.
ntc_ratio_hi_alert (Sub-Address 0x36, Bit 1, R/Clear)
If en_ntc_ratio_hi_alert =1, this bit indicates that an SMBALERT has occurred because NTC_RATIO has exceeded
NTC_RATIO_HI_ALERT_LIMIT (cold battery).
ntc_ratio_lo_alert (Sub-Address 0x36, Bit 0, R/Clear)
If en_ntc_ratio_hi_alert =1, this bit indicates that an SMBALERT has occurred because NTC_RATIO has fallen below
NTC_RATIO_LO_ALERT_LIMIT (hot battery)
CHARGER_STATE_ALERTS (Sub-Address 0x37, Bits 10:0, R/Clear)
This register consists of individual battery charger state alert bits. Individual alert bits will be asserted if the individual
alert has been enabled and the transition into that state occurs.
Once asserted, alert bits remain high until disabled or cleared. Writing a 0 to any bit clears that alert. If an enabled
alert is cleared and the alerting condition remains, a new alert is triggered immediately. When a new alert occurs, the
LTC4015 pulls down the SMBALERT pin and holds it low until an alert response algorithm (ARA) is completed. See the
section Programmable Alerts and Interrupt Controller for more information regarding the SMBALERT and ARA functions.
equalize_charge_alert (Sub-Address 0x37, Bit 10, R/Clear)
If en_equalize_charge_alert=1, this bit indicates that an SMBALERT has occurred due to the occurrence of equalize_
charge (applies to lead-acid chemistries only).
absorb_charge_alert (Sub-Address 0x37, Bit 9, R/Clear)
If en_absorb_charge_alert=1, this bit indicates that an SMBALERT has occurred due to the occurrence of absorb_
charge (applies to LiFePO4 and lead-acid chemistries only).
charger_suspended_alert (Sub-Address 0x37, Bit 8, R/Clear)
If en_charger_suspended_alert=1, this bit indicates that an SMBALERT has occurred due to the occurrence of
charger_suspended.
precharge_alert (Sub-Address 0x37, Bit 7, R/Clear)
If en_precharge _alert=1, this bit indicates that an SMBALERT has occurred due to the occurrence of precharge.
cc_cv_charge_alert (Sub-Address 0x37, Bit 6, R/Clear)
If en_cc_cv_charge _alert=1, this bit indicates that an SMBALERT has occurred due to the occurrence of cc_cv_charge.
ntc_pause_alert (Sub-Address 0x37, Bit 5, R/Clear)
If en_ntc_pause_alert=1, this bit indicates that an SMBALERT has occurred due to the occurrence of ntc_pause.
timer_term_alert (Sub-Address 0x37, Bit 4, R/Clear)
If en_timer_term_alert=1, this bit indicates that an SMBALERT has occurred due to the occurrence of timer_term.
c_over_x_term_alert (Sub-Address 0x37, Bit 3, R/Clear)
If en_c_over_x_term_alert=1, this bit indicates that an SMBALERT has occurred due to the occurrence of c_over_x_term.
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DETAILED REGISTER DESCRIPTIONS
max_charge_time_fault_alert (Sub-Address 0x37, Bit 2, R/Clear)
If en_max_charge_time_fault_alert=1, this bit indicates that an SMBALERT has occurred due to the occurrence of
a max_charge_time_fault.
bat_missing_fault_alert (Sub-Address 0x37, Bit 1, R/Clear)
If en_bat_missing_fault_alert=1, this bit indicates that an SMBALERT has occurred due to the occurrence of
bat_missing_fault.
bat_short_fault_alert (Sub-Address 0x37, Bit 0, R/Clear)
If en_bat_short_fault_alert=1, this bit indicates that an SMBALERT has occurred due to the occurrence of bat_
short_fault.
CHARGE_STATUS_ALERTS (Sub-Address 0x38, Bits 3:0, R/Clear)
This register consists of individual battery charger charge status alert bits. Individual alert bits will be asserted if the
individual alert has been enabled and the transition into that state occurs.
Once asserted, alert bits remain high until disabled or cleared. Writing a 0 to any bit clears that alert. If an enabled
alert is cleared and the alerting condition remains, a new alert is triggered immediately. When a new alert occurs, the
LTC4015 pulls down the SMBALERT pin and holds it low until an alert response algorithm (ARA) is completed. See the
section Programmable Alerts and Interrupt Controller for more information regarding the SMBALERT and ARA functions.
vin_uvcl_active_alert (Sub-Address 0x38, Bit 3, R/Clear)
If en_vin_uvcl_active_alert=1, this bit indicates that an SMBALERT has occurred because the UVCL undervolt-
age current limit regulation loop of the LTC4015 has taken control of the switching regulator charger delivery
(vin_uvcl_active=1).
iin_limit_active_alert (Sub-Address 0x38, Bit 2, R/Clear)
If en_iin_limit_active_alert=1, this bit indicates that an SMBALERT has occurred because the input current regulation
loop of the LTC4015 has taken control of the switching regulator charger delivery (iin_limit_active=1).
constant_current_alert (Sub-Address 0x38, Bit 1, R/Clear)
If en_constant_current_alert=1, this bit indicates that an SMBALERT has occurred because the battery charge current
regulation loop of the LTC4015 has taken control of the switching charger current delivery (constant_current=1).
constant_voltage_alert (Sub-Address 0x38, Bit 0, R/Clear)
If en_constant_voltage_alert=1, this bit indicates that an SMBALERT has occurred because the battery voltage
regulation loop of the LTC4015 has taken control of the switching charger current delivery (constant_voltage=1).
SYSTEM_STATUS (Sub-Address 0x39, Bits 13:0, R)
This register consists of individual real-time status bits which indicate various system conditions.
charger_enabled (Sub-Address 0x39, Bit 13, R)
This bit indicates that the LTC4015 is actively charging a battery.
mppt_en_pin (Sub-Address 0x39, Bit 11, R)
This bit indicates that the external MPPT pin is detected as being high and maximum power point tracking is enabled.
equalize_req (Sub-Address 0x39, Bit 10, R)
This bit indicates that a rising edge has been detected at the EQ pin and a lead-acid equalization charge is running
or is queued to run. See Lead-Acid Equalization Charge.
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DETAILED REGISTER DESCRIPTIONS
drvcc_good (Sub-Address 0x39, Bit 9, R)
This bit indicates that the DRVCC pin voltage is above the DRVCC undervoltage lockout level (4.3V typical).
cell_count_error (Sub-Address 0x39, Bit 8, R)
This bit indicates that an invalid combination of CELLS pin settings have been detected.
ok_to_charge (Sub-Address 0x39, Bit 6, R)
This bit indicates that all system conditions are met to allow battery charging operation.
no_rt (Sub-Address 0x39, Bit 5, R)
This bit indicates that no frequency setting resistor is detected on the RT pin. The RT pin impedance detection circuit
will typically indicate a missing RT resistor for values above 1.4MΩ.
thermal_shutdown (Sub-address 0x39, Bit 4, R)
This bit indicates that the LTC4015 is in thermal shutdown protection due to an excessively high die temperature
(typically 160°C and above).
vin_ovlo (Sub-address 0x39, Bit 3, R)
This bit indicates that the LTC4015 is in input voltage shutdown protection due to an input voltage above its protec-
tion shutdown threshold of approximately 38.6V (typical).
vin_gt_vbat (Sub-Address 0x39, Bit 2, R)
This bit indicates that the VIN pin input voltage is sufficiently above the BATSENS battery voltage to allow charging
operation (typically +200mV).
intvcc_gt_4p3v (Sub-Address 0x39, Bit 1, R)
This bit indicates that the INTVCC voltage is above the switching charger undervoltage lockout threshold value of
4.3V (typical).
intvcc_gt2p8v (Sub-Address 0x39, Bit 0, R)
This bit indicates that the INTVCC pin voltage is above the measurement system undervoltage lockout threshold
value of 2.8V (typical).
VBAT (Sub-Address 0x3A, Bits 15:0, R)
This 16-bit two’s complement word indicates the A/D measurement result for the BATSENS pin.
VBATSENS/cellcount = [VBAT] • 192.264µV for lithium chemistries.
VBATSENS/cellcount = [VBAT] • 128.176µV for lead-acid.
VIN (Sub-Address 0x3B, Bits 15:0, R)
This 16-bit two’s complement word indicates the A/D measurement result for the VIN pin voltage divided by 30. Input
voltage, VVIN = [VIN] • 1.648mV
VSYS (Sub-Address 0x3C, Bits 15:0, R)
This 16-bit two’s complement word indicates the A/D measurement result for the SYS pin voltage divided by 30. System
voltage, VSYS = [VSYS] • 1.648mV
IBAT (Sub-Address 0x3D, Bits 15:0, R)
This 16-bit word indicates the A/D measurement of 37.5 • (VCSPVCSN) at the CSP, CSN pins. Negative values are
represented in two’s complement notation and indicate current flowing out of (discharging) the battery. Battery current
= [IBAT] • 1.46487µV/RSNSB
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DETAILED REGISTER DESCRIPTIONS
IIN (Sub-Address 0x3E, Bits 15:0, R)
This 16-bit word indicates the A/D measurement of 37.5 • (VCLPVCLN) at the CLP, CLN pins. Input current = [IIN] •
1.46487µV/RSNSI
DIE_TEMP (Sub-Address 0x3F, Bits 15:0, R)
This 16-bit two’s complement word indicates the A/D measurement result for LTC4015 die temperature. LTC4015
temperature = (DIE_TEMP – 12010)/45.6°C
NTC_RATIO (Sub-Address 0x40, Bits 15:0, R)
This 16-bit two’s complement word indicates the A/D measurement result for RNTC/(RNTC + RNTCBIAS). The thermistor
value can be determined by the expression RNTC = RNTCBIAS • NTC_RATIO/(21,845.0 – NTC_RATIO). Recall that the
thermistor has a negative temperature coefficient so higher temperatures correspond to lower NTC_RATIO readings
and vice-versa.
BSR (Sub-Address 0x41, Bits 15:0, R)
This 16-bit word indicates the calculated per cell battery series resistance. The battery series resistance is proportional
to the battery charge current setting resistor, RSNSB, and can be computed in Ω from [BSR/500] • RSNSB for lithium
chemistries, or [BSR/750] • RSNSB for lead-acid chemistries. Multiply this value by the total number of cells to calculate
total battery series resistance. ICHARGE_BSR is the value of IBAT used in the BSR calculation.
JEITA_ REGION (Sub-Address 0x42, Bits 2:0, R)
For lithium chemistries, this register indicates the JEITA battery temperature region as determined by the A/D
measurement result NTC_RATIO and the values of the JEITA_Tn registers. Recall that the thermistor has a negative
temperature coefficient so higher temperatures make lower NTC_RATIO readings and vice-versa. See the section JEITA
Temperature Qualified Charging for a diagram of the temperature regions.
CHEM_AND_CELLS (Sub-Address 0x43, Bits 11:0, R)
This register indicates the state of the CHEMn and CELLSn pins. See the sections Chemistry Selection and Cells Selec-
tion for more information on defining the pin states.
chem (Sub-Address 0x43, Bits 11:8, R)
These four bits indicate the chemistry algorithm set by the CHEMn pins, as shown in the following table. For ad-
ditional safety, these bits can be checked during test and/or by the application software to ensure that LTC4015 is
connected properly on the circuit board.
chem: CHEM1,CHEM0: Chemistry Algorithm:
0x0 L, L Li-Ion Programmable
0x1 H, H Li-Ion Fixed 4.2V/cell
0x2 L, Z Li-Ion Fixed 4.1V/cell
0x3 Z, L Li-Ion Fixed 4.0V/cell
0x4 L, H LiFePO4 Programmable
0x5 H, Z LiFePO4 Fixed Fast Charge
0x6 Z, H LiFePO4 Fixed 3.6V/cell
0x7 Z, Z Lead-Acid Fixed
0x8 H, L Lead-Acid Programmable
cells (Sub-Address 0x43, Bits 3:0, R)
These four bits indicate the battery cell count set by the CELLSn pins. For additional safety, these bits can be checked
during test and/or by the application software to ensure that LTC4015 is connected properly on the circuit board.
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ICHARGE_DAC (Sub-Address 0x44, Bits 4:0, R)
This register represents the actual charge current setting applied to the charge current reference DAC. ICHARGE_DAC
is ramped up/down to implement digital soft-start/stop. The LTC4015 sets the value of ICHARGE_DAC based on
battery chemistry, charger state (CHARGER_STATE), thermistor reading (NTC_RATIO), and charger settings including
ICHARGE_TARGET, ijeita_n, and TJEITA_n. Recall that the charge current is regulated by controlling the voltage across
an external current sense resistor RSNSB. The servo voltage is given by (ICHARGE_DAC + 1) • 1mV. The charge current
servo level is thus given by (ICHARGE_DAC + 1) • 1mV/RSNSB.
VCHARGE_DAC (Sub-Address 0x45, Bits 5:0, R)
This register represents the actual target battery voltage setting applied to the charge voltage reference DAC. The
LTC4015 sets the value of VCHARGE_DAC based on battery chemistry, charger state (CHARGER_STATE), thermistor
reading (NTC_RATIO), and charger settings including VCHARGE_SETTING, vjeita_n, TJEITA_n, VABSORB_DELTA,
VEQUALIZE_DELTA,en_jeita, and en_lead_acid_temp_comp. See also JEITA Temperature Qualified Charging and
Lead-Acid Temperature Compensated Charging.
IIN_LIMIT_DAC (Sub-Address 0x46, Bits 5:0, R)
This register represents the actual input current limit setting applied to the input current limit reference DAC. This
register follows IIN_LIMIT_SETTING.
VBAT_FILT (Sub-Address 0x47, Bits 15:0, R)
Digitally filtered two’s complement ADC measurement result for battery voltage.
ICHARGE_BSR (Sub-Address 0x48, Bits 15:0, R)
This 16-bit two's complement word is the value of IBAT (0x3D) used in calculating BSR.
TELEMETRY_VALID (Sub-Address 0x4A, Bit 0, R)
This bit being set to 1 indicates the output of the LTC4015's telemetry system is valid.
DETAILED REGISTER DESCRIPTIONS
NUMBER OF
CELLS CELLS2 CELLS1 CELLS0
Invalid L L L
1 L L H
2 L H L
3 L H H
4LLZ
5LZL
6 L H Z
7 L Z H
8LZZ
9 H L L
Invalid H L H
Invalid H H L
12* H H H
*Lead-acid only
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TYPICAL APPLICATIONS
Application Circuit 1: Li-Ion Battery Charger, 2 = Cell, 8A (Typical Performance Characteristics)
LTC4015
VIN
UVCLFB
µCONTROLLER
INTVCC
V
IN
4.5V TO 35V
SMBALERT
DVCC
SCL
SDA
10µF
10k
±1%
64.9k
±1% 10k
CELLS0
CELLS1
CELLS2
CHEM0
CHEM1
CCREFP
CCREFM
SGND
100nFRCCREF
RT
VC
INFET CLP
R
SNSI
M3
1nF
CLN SYS SYSM5
4015 TA02
OUTFET
SYSTEM
INTVCC
D1
M2
M4
M1
L1
10µH
DRVCC
BOOST
TG
SW
BG
CSPM5
CSP
CSN
RSNSB
RNTCBIAS
BATSENS
NTCBIAS
NTC
EQ
MPPT
F 330nF 100nF 10µF
10µF
10µF C1
0.47µF
330nF
1nF
RT
10nF
(PADDLE)
GND
RT: 95.3k ±1%
RCCREF: 301kΩ, 0.1%, 25ppm/C°, SUSUMU, RG1608P-3013-B-TS
RSNSI: 3mΩ, SUSUMU, KRL3216T4-M-R003-F
RSNSB: 4mΩ, SUSUMU, KRL3216T4-M-R004-F
RNTCBIAS: 10k ±1%
RNTC: VISHAY NTCS0402E3103FLT
L1: 10µH, COIL CRAFT XAL8080_103ME OR WÜRTH ELEKTRONIK 7443321000
M1, M2: FAIRCHILD FDMC8030 (DUAL)
M3: FAIRCHILD FDMC8327L
M4: VISHAY Si7611DN
D1: DIODES INC 1N4448HLP
C1: 120µF 40V, 40HVH120M
2P5VCC
10µF
R
NTC
BATTERY
PACK
T
10µF
100pF
2.2nF
200Ω
220nF 2.2µF
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TYPICAL APPLICATIONS
Solar Lead-Acid Battery Charger, 6-Cell 10.7A
LTC4015
VIN
UVCLFB
µCONTROLLER
INTVCC
V
IN
SOLAR
PANEL
SMBALERT
DVCC
SCL
SDA
10µF
10k
2.2nF294k
±1%
10k
±1%
CELLS0
CELLS1
CELLS2
CHEM0
CHEM1
CCREFP
CCREFM
100nFRCCREF
RT
VC
INFET CLP
R
SNSI
M3
1nF
CLN SYS SYSM5
4015 TA03
OUTFET
SYSTEM
INTVCC
D1
L1, 10µH
DRVCC
BOOST
TG
SW
BG
2P5VCC
CSPM5
CSP
CSN
RSNSB
RNTCBIAS
BATSENS
NTCBIAS
NTC
EQ
MPPT
F 330nF 100nF 10µF
10µF
M4
M2
M1
10µF C1
CB
0.47µF
2.2µF
330nF
1nF
RT
10nF
(PADDLE)
GND
RT: 95.3k ±1%
RCCREF: 301kΩ, ±0.1%, 25ppm/C°, SUSUMU RG1608P-3013-B-T5
RSNSI: 3mΩ, VISHAY WSK06123L000FEA (10.7A INPUT CURRENT LIMIT)
RSNSB: 3mΩ, VISHAY WSK06123L000FEA
RNTCBIAS: 10k ±1%
R
NTC
: VISHAY NTCS0402E3103FLT
L1: 10µH, COIL CRAFT XAL1010_103ME OR WÜRTH ELEKTRONIK 7443321000
M1, M2: FAIRCHILD FDMC8030 (DUAL)
M3: FAIRCHILD FDMC8327L
M4: VISHAY Si7611DN
D1: DIODES INC 1N4448HLP
C1: 120µF 40V, 40HVH120M
10µF
10µF
R
NTC
BATTERY
PACK
T
100pF
200Ω
220nF
SGND
LTC4015
74
4015fb
For more information www.linear.com/LTC4015
PACKAGE DESCRIPTION
Please refer to http://www.linear.com/product/LTC4015#packaging for the most recent package drawings.
5.00 ±0.10
NOTE:
1. DRAWING CONFORMS TO JEDEC PACKAGE
OUTLINE M0-220 VARIATION WHKD
2. DRAWING NOT TO SCALE
3. ALL DIMENSIONS ARE IN MILLIMETERS
PIN 1
TOP MARK
(SEE NOTE 6)
37
1
2
38
BOTTOM VIEW—EXPOSED PAD
5.50 REF 5.15 ±0.10
7.00 ±0.10
0.75 ±0.05
R = 0.125
TYP R = 0.10
TYP
0.25 ±0.05
(UH) QFN REF C 1107
0.50 BSC
0.200 REF
0.00 – 0.05
RECOMMENDED SOLDER PAD LAYOUT
APPLY SOLDER MASK TO AREAS THAT ARE NOT SOLDERED
3.00 REF
3.15 ±0.10
0.40 ±0.10
0.70 ±0.05
0.50 BSC
5.5 REF
3.00 REF 3.15 ±0.05
4.10 ±0.05
5.50 ±0.05 5.15 ±0.05
6.10 ±0.05
7.50 ±0.05
0.25 ±0.05
PACKAGE
OUTLINE
4. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE
MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.20mm 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
PIN 1 NOTCH
R = 0.30 TYP OR
0.35 × 45° CHAMFER
UHF Package
38-Lead Plastic QFN (5mm × 7mm)
(Reference LTC DWG # 05-08-1701 Rev C)
LTC4015
75
4015fb
For more information www.linear.com/LTC4015
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 representa-
tion that the interconnection of its circuits as described herein will not infringe on existing patent rights.
REVISION HISTORY
REV DATE DESCRIPTION PAGE NUMBER
A 02/16 Add a bullet in the Data Sheet Conventions section.
Add Range to VIN and VBAT in the Parameter section.
Add text to Note 11.
Add text to NTC (Pin 11).
Add text to Cells Selection section.
Add text to end of 2nd paragraph on the left.
Edit last paragraph on the left.
Add text to the 1st paragraph in the LTC4015 Charge Algorithm Overview section. Add (per cell) to the bottom table.
Edit IRMS equation.
Add text to 4th and 5th paragraph on the right.
Add text to the mppt_en_i2c section.
Add text to 1st paragraph of VCHARGE_SETTING section.
Edit schematic in Typical Applications section. Add LTC3300-1, LTC3305 and delete LT3651 and LTC4012 in Related
Parts section.
3
4
9
13
24
27
34
35
44
46
61
62
76
B 04/17 Update Typical Application schematic.
Change VSYS = 35V.
Modify Note 4.
Modify UVCLFB (Pin 8) section.
Correct Chemo to (Pin 36).
Update Block Diagram.
Update I2C Timing Diagram
Update Table 7.
Modify Maximum Charge Time section.
Update Li-Ion LiFePo4 section.
Update Table under Operation section.
Update Figure 8 and Lead-Acid Charging Parameters table.
Update Figure 9.
Modify equation KQC = 8333.33Hz/V.
Modify Coulomb Counter Applications section.
Modify UVCLFB Resistor Divider Selection section.
Update Typical Applications schematics.
1
7
9
13
14
15
16
26
30
32
34
35
38
39
39
45, 46
72, 73
LTC4015
76
4015fb
For more information www.linear.com/LTC4015
LINEAR TECHNOLOGY CORPORATION 2015
LT 0417 REV B • PRINTED IN USA
www.linear.com/LTC4015
RELATED PARTS
TYPICAL APPLICATION
PART NUMBER DESCRIPTION COMMENTS
LT3652/LT3652HV Power Tracking 2A Buck Battery
Charger Input Supply Voltage Regulation Loop for Peak Power Tracking in (MPPT) Solar Applications,
Standalone, 4.95V ≤VIN ≤ 32V (40V Abs Max), 1MHz Timer or C/10 Termination, 3mm ×
3mm DFN-12 Package and MSOP-12 Packages, LT3652HV Version Up to VIN = 34V
LTC4020 55V Buck-Boost Multi-Chemistry
Battery Charger Constant-Current/Constant-Voltage Buck-Boost Switching Controller Regulator Charger,
5mm × 7mm QFN-38 Package
LTC4121/
LTC4121-4.2 Multi-Chemistry Buck Battery Charger Constant-Current/Constant-Voltage 400mA Monolithic Buck Switching Regulator Charger,
4.4V ≤ VIN ≤ 40V, 3mm × 3mm QFN-16 Package
LTC4155 Dual Input Power Manager/3.5A Li-Ion
Battery Charger High Efficiency, Monolithic Switching Regulator, 4mm × 5mm QFN-28 Package
LTC3300-1 High Efficiency Bidirectional Multicell
Battery Balancer Bidirectional Synchronous Flyback Balancing of Up to Six Li-Ion or LiFePO4 Cells in Series.
Up to 10A Balancing Current (Set by External Components). Bidirectional Architecture
Minimizes Balancing Time and Power Dissipation. Up to 92% Charge Transfer Efficiency.
7mm × 7mm QFN-48 and 7mm × 7mm LQFP-48 Packages
LTC3305 Lead-Acid Battery Balancer Single IC Balances Up to Four 12V Lead-Acid Batteries in Series. Stand Alone Operation
Requires No External µP or Control Circuitry. Thermally Enhanced TSSOP-36 Package
Solar Lead-Acid Battery Charger, 6-Cell 10.7A, System Fed from Battery
LTC4015
VIN
UVCLFB
µCONTROLLER
INTVCC
V
IN
SOLAR
PANEL
SMBALERT
DVCC
SCL
SDA
10µF
10k
2.2nF294k
±1%
10k
±1%
CELLS0
CELLS1
CELLS2
CHEM0
CHEM1
CCREFP
CCREFM
100nFRCCREF
RT
VC
INFET CLP
R
SNSI
M3
1nF
CLN SYS SYSM5
4015 TA04
OUTFET
SYSTEM
INTVCC
D1
L1, 10µH
DRVCC
BOOST
TG
SW
BG
2P5VCC
CSPM5
CSP
CSN
RSNSB
RNTCBIAS
BATSENS
NTCBIAS
NTC
EQ
MPPT
F 330nF 100nF 10µF
10µF
M4
M2
M1
10µF C1
CB
0.47µF
2.2µF
330nF
1nF
RT
10nF
(PADDLE)
GND
RT: 95.3k ±1%
RCCREF: 301kΩ, ±0.1%, 25ppm/C°, SUSUMU RG1608P-3013-B-T5
RSNSI: 3mΩ, VISHAY WSK06123L000FEA (10.7A INPUT CURRENT LIMIT)
RSNSB: 3mΩ, VISHAY WSK06123L000FEA
RNTCBIAS: 10k ±1%
R
NTC
: VISHAY NTCS0402E3103FLT
L1: 10µH, COIL CRAFT XAL1010_103ME OR WÜRTH ELEKTRONIK 7443321000
M1, M2: FAIRCHILD FDMC8030 (DUAL)
M3: FAIRCHILD FDMC8327L
M4: VISHAY Si7611DN
D1: DIODES INC 1N4448HLP
C1: 120µF 40V, 40HVH120M
10µF
10µF
R
NTC
BATTERY
PACK
T
100pF
200Ω
220nF
SGND