LINER LTC4156 Dual-input power manager Datasheet

LTC4155
Dual-Input Power Manager/
3.5A Li-Ion Battery Charger with
I2C Control and USB OTG
FEATURES
DESCRIPTION
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The LTC®4155 is a 15 watt I2C controlled power manager
with PowerPath™ instant-on operation, high efficiency
switching battery charging and USB compatibility. The
LTC4155 seamlessly manages power distribution from
two 5V sources, such as a USB port and a wall adapter,
to a single-cell rechargeable Lithium-Ion/Polymer battery
and a system load.
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High Efficiency Charger Capable of 3.5A
Charge Current
Monolithic Switching Regulator Makes Optimal
Use of Limited Power and Thermal Budget
Dual-Input Overvoltage Protection Controller
Priority Multiplexing for Multiple Inputs
I2C/SMBus Control and Status Feedback
NTC Thermistor ADC for Temperature Dependent
Charge Algorithms (JEITA)
Instant-On Operation with Low Battery
Battery Ideal Diode Controller for Power
Management
USB On-The-Go Power Delivery to the USB Port
Full Featured Li-Ion/Polymer Battery Charger with
Four Float Voltage Settings
28-Lead 4mm × 5mm QFN Package
APPLICATIONS
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Tablet PCs
Ultra Mobile PCs
Video Media Players
Digital Cameras, GPS, PDAs
Smart Phones
Portable Medical Devices
L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks and
PowerPath and Bat-Track are trademarks of Linear Technology Corporation. All other trademarks
are the property of their respective owners.
The LTC4155’s switching battery charger automatically
limits its input current for USB compatibility, or may
draw up to 3A from a high power wall adapter. The high
efficiency step-down switching charger is designed to
provide maximum power to the application and reduced
heat in high power density applications.
I2C adjustability of input current, charge current, battery
float voltage, charge termination, and many other parameters allows maximum flexibility. I2C status reporting of
key system and charge parameters facilitates intelligent
control decisions. USB On-The-Go support provides 5V
power back to the USB port without any additional components. A dual-input, priority multiplexing, overvoltage
protection circuit guards the LTC4155 from high voltage
damage on the VBUS pin.
The LTC4155 is available in the low profile (0.75mm)
28-lead 4mm × 5mm QFN surface mount package.
TYPICAL APPLICATION
Switching Regulator Efficiency
I2C Controlled High Power Battery Charger/USB Power Manager
VIN
VOUT
CHGSNS
VBUS
10μF
3.6k
3
LTC4155
USBGT
BATSNS
USBSNS
ID
I2C IRQ GND CLPROG2 CLPROG1 PROG VC
1.21k
499Ω
22μF
BATGATE
90
TO
SYSTEM
LOAD
100k
80
EFFICIENCY (%)
1μH
SW
WALLSNS
WALLGT
100
70
60
50
40
30
NTCBIAS
NTC
OVGCAP
20
10
VBAT = 3.9V
0
47nF
0
0.5
1.0 1.5 2.0
2.5
LOAD CURRENT (A)
3.0
3.5
4155 TA01b
4155 TA01a
4155fc
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LTC4155
TABLE OF CONTENTS
Features ............................................................................................................................ 1
Applications ....................................................................................................................... 1
Typical Application ............................................................................................................... 1
Description......................................................................................................................... 1
Absolute Maximum Ratings ..................................................................................................... 3
Order Information ................................................................................................................. 3
Pin Configuration ................................................................................................................. 3
Electrical Characteristics ........................................................................................................ 4
Typical Performance Characteristics .......................................................................................... 9
Pin Functions .....................................................................................................................12
Block Diagram....................................................................................................................15
Timing Diagrams ................................................................................................................16
Operation..........................................................................................................................17
I2C ........................................................................................................................................................................ 17
Applications Information .......................................................................................................40
Typical Applications .............................................................................................................47
Package Description ............................................................................................................51
Typical Application ..............................................................................................................52
Related Parts .....................................................................................................................52
4155fc
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LTC4155
ABSOLUTE MAXIMUM RATINGS
PIN CONFIGURATION
(Notes 1, 2)
VBUS
VBUS
VBUS
SW
SW
TOP VIEW
SCL
VBUS (Transient) t < 1ms, Duty Cycle < 1% ... –0.3V to 7V
VBUS (Steady State), BATSNS, IRQ, NTC...... –0.3V to 6V
DVCC, SDA, SCL (Note 3) ........................–0.3V to VMAX
IWALLSNS, IUSBSNS ............................................... ±20mA
INTCBIAS, IIRQ ..........................................................10mA
ISW, IVOUT, ICHGSNS (Both Pins in Each Case)..............4A
Operating Junction Temperature Range ... –40°C to 125°C
Storage Temperature Range .................. –65°C to 150°C
28 27 26 25 24 23
SDA 1
22 VOUT
DVCC 2
21 VOUT
IRQ 3
20 CHGSNS
29
GND
ID 4
CLPROG1 5
19 CHGSNS
18 PROG
CLPROG2 6
17 BATGATE
WALLSNS 7
16 BATSNS
USBSNS 8
15 NTC
NTCBIAS
VOUTSNS
VC
WALLGT
USBGT
OVGCAP
9 10 11 12 13 14
UFD PACKAGE
28-LEAD (4mm w 5mm) PLASTIC QFN
TJMAX = 125°C, θJA = 43°C/W
EXPOSED PAD (PIN 29) IS GND, MUST BE SOLDERED TO PCB
ORDER INFORMATION
LEAD FREE FINISH
TAPE AND REEL
PART MARKING*
PACKAGE DESCRIPTION
TEMPERATURE RANGE
LTC4155EUFD#PBF
LTC4155EUFD#TRPBF
4155
28-Lead (4mm × 5mm × 0.75mm) Plastic QFN
–40°C to 125°C
LTC4155IUFD#PBF
LTC4155IUFD#TRPBF
4155
28-Lead (4mm × 5mm × 0.75mm) 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.Consult LTC Marketing for information on non-standard lead based finish parts.
For more information on lead free part marking, go to: http://www.linear.com/leadfree/
For more information on tape and reel specifications, go to: http://www.linear.com/tapeandreel/
4155fc
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LTC4155
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the specified operating
junction temperature range, otherwise specifications are at TA ≈ TJ = 25°C (Note 2). VBUS = 5V, BATSNS = 3.7V, DVCC = 3.3V,
RCLPROG1 = RCLPROG2 = 1.21k, RPROG = 499Ω, unless otherwise noted.
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
Switching Battery Charger
l
VBUS
Input Supply Voltage
VBUSREG
Undervoltage Current Reduction
Input Undervoltage Current Limit Enabled
4.30
V
IVBUSQ
Input Quiescent Current
USB Suspend Mode
100mA IVBUS Mode, IVOUT = 0μA, Charger Off
500mA – 3A IVBUS Modes, IVOUT = 0μA, Charger Off
0.060
0.560
17
mA
mA
mA
IBATQ
Battery Drain Current
VBUS > VUVLO, Battery Charger Off, IVOUT = 0μA
VBUS = 0V, IVOUT = 0μA
Storage and Shipment Mode, DVCC = 0V
IVBUSLIM
Total Input Current When Load
Exceeds Power Limit
100mA IVBUS Mode (USB Lo Power) (Default)
500mA IVBUS Mode (USB Hi Power)
600mA IVBUS Mode
700mA IVBUS Mode
800mA IVBUS Mode
900mA IVBUS Mode (USB 3.0)
1.00A IVBUS Mode
1.25A IVBUS Mode
1.50A IVBUS Mode
1.75A IVBUS Mode
2.00A IVBUS Mode
2.25A IVBUS Mode
2.50A IVBUS Mode
2.75A IVBUS Mode
3.00A IVBUS Mode (Default)
2.5mA IVBUS Mode (USB Suspend)
l
l
l
l
l
l
l
4.35
5.5
V
7.0
2.0
0.6
3.0
1.25
μA
μA
μA
65
460
550
650
745
800
950
1150
1425
1650
1900
2050
2350
2550
2800
80
480
570
670
770
850
1000
1230
1500
1750
2000
2175
2475
2725
2950
1.8
100
500
600
700
800
900
1025
1300
1575
1875
2125
2300
2600
2900
3100
2.5
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
4.02
4.07
4.12
4.17
4.05
4.10
4.15
4.20
4.08
4.13
4.18
4.23
V
V
V
V
VFLOAT
BATSNS Regulated Output Voltage
Selected by I2C Control.
Switching Modes
4.05V Setting (Default)
4.10V Setting
4.15V Setting
4.20V Setting
ICHARGE
Regulated Battery Charge Current
Selected by I2C Control
12.50% Charge Current Mode
18.75% Charge Current Mode
25.00% Charge Current Mode
31.25% Charge Current Mode
37.50% Charge Current Mode
43.75% Charge Current Mode
50.00% Charge Current Mode
56.25% Charge Current Mode
62.50% Charge Current Mode
68.75% Charge Current Mode
75.00% Charge Current Mode
81.25% Charge Current Mode
87.50% Charge Current Mode
93.75% Charge Current Mode
100.0% Charge Current Mode (Default)
290
430
590
730
880
1025
1180
1330
1485
1635
1780
1915
2065
2210
2350
315
465
620
770
925
1075
1230
1385
1535
1685
1835
1980
2130
2280
2430
340
500
650
810
970
1125
1280
1440
1585
1735
1890
2045
2195
2350
2500
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
ICHARGE(MAX)
Regulated Battery Charge Current
100.0% Charge Current Mode, RPROG = 340Ω
3.44
3.57
3.70
A
VOUT
PowerPath Regulated Output
Voltage (VBUS Power Available)
Suspend Mode, IVOUT = 1mA
Battery Charger Enabled, Charging, BATSNS ≥ 3.5V
Battery Charger Terminated or Battery Charger
Disabled
4.35
BATSNS
4.35
4.5
V
V
V
VOUT(MIN)
Low Battery Instant-On Output
Voltage (VBUS Power Available)
Battery Charger Enabled, Charging, BATSNS ≤ 3.3V
3.40
3.50
4.5
V
4155fc
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LTC4155
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the specified operating
junction temperature range, otherwise specifications are at TA ≈ TJ = 25°C (Note 2). VBUS = 5V, BATSNS = 3.7V, DVCC = 3.3V,
RCLPROG1 = RCLPROG2 = 1.21k, RPROG = 499Ω, unless otherwise noted.
SYMBOL
PARAMETER
CONDITIONS
IVOUT
VOUT Current Available Before
Loading Battery
2.5mA IVBUS Mode (USB Suspend)
100mA IVBUS Mode, BAT = 3.3V
500mA IVBUS Mode, BAT = 3.3V
600mA IVBUS Mode, BAT = 3.3V
700mA IVBUS Mode, BAT = 3.3V
800mA IVBUS Mode, BAT = 3.3V
900mA IVBUS Mode, BAT = 3.3V
1.00A IVBUS Mode, BAT = 3.3V
1.25A IVBUS Mode, BAT = 3.3V
1.50A IVBUS Mode, BAT = 3.3V
1.75A IVBUS Mode, BAT = 3.3V
2.00A IVBUS Mode, BAT = 3.3V
2.25A IVBUS Mode, BAT = 3.3V
2.50A IVBUS Mode, BAT = 3.3V
2.75A IVBUS Mode, BAT = 3.3V
3.00A IVBUS Mode, BAT = 3.3V
VPROG
PROG Pin Servo Voltage
12.50% Charge Current Mode
18.75% Charge Current Mode
25.00% Charge Current Mode
31.25% Charge Current Mode
37.50% Charge Current Mode
43.75% Charge Current Mode
50.00% Charge Current Mode
56.25% Charge Current Mode
62.50% Charge Current Mode
68.75% Charge Current Mode
75.00% Charge Current Mode
81.25% Charge Current Mode
87.50% Charge Current Mode
93.75% Charge Current Mode
100.0% Charge Current Mode (Default)
VRECHRG
Recharge Battery Threshold
Voltage
Threshold Voltage Relative to VFLOAT
96.6
97.6
98.4
%
tTERMINATE
Safety Timer Termination Period
Selected by I2C Control. Timer
Starts When BATSNS ≥ VFLOAT
1-Hour Mode
2-Hour Mode
4-Hour Mode (Default)
8-Hour Mode
0.95
1.90
3.81
7.63
1.06
2.12
4.24
8.48
1.17
2.33
4.66
9.32
Hours
Hours
Hours
Hours
VLOWBAT
Threshold Voltage
Rising Threshold
Hysteresis
2.65
2.8
130
2.95
V
mV
tBADBAT
Bad Battery Termination Time
BATSNS < (VLOWBAT – ΔVLOWBAT)
0.47
0.53
0.59
Hours
VC/x
Full Capacity Charge Indication
PROG Voltage Selected by I2C
Control
C/10 Mode (ICHARGE = 10%FS) (Default)
C/5 Mode (ICHARGE = 20%FS)
C/20 Mode (ICHARGE = 5%FS)
C/50 Mode (ICHARGE = 2%FS)
110
230
15
50
120
240
24
60
130
250
33
70
mV
mV
mV
mV
hPROG
Ratio of ICHGSNS to PROG Pin
Current
hCLPROG1
(Note 4)
Ratio of Measured VBUS Current to
CLPROG1 Sense Current
CLPROG1 IVBUS Mode
MIN
TYP
MAX
UNITS
1
1.3
76
673
810
944
1093
1200
1397
1728
2072
2411
2700
2846
3154
3408
3657
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
150
225
300
375
450
525
600
675
750
825
900
975
1050
1125
1200
mV
mV
mV
mV
mV
mV
mV
mV
mV
mV
mV
mV
mV
mV
mV
1000
mA/mA
990
mA/mA
4155fc
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LTC4155
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the specified operating
junction temperature range, otherwise specifications are at TA ≈ TJ = 25°C (Note 2). VBUS = 5V, BATSNS = 3.7V, DVCC = 3.3V,
RCLPROG1 = RCLPROG2 = 1.21k, RPROG = 499Ω, unless otherwise noted.
SYMBOL
PARAMETER
CONDITIONS
hCLPROG2
(Note 4)
Ratio of Measured VBUS Current to
CLPROG2 Sense Current
2.5mA IVBUS Mode (USB Suspend)
100mA IVBUS Mode
500mA IVBUS Mode
600mA IVBUS Mode
700mA IVBUS Mode
800mA IVBUS Mode
900mA IVBUS Mode
1.00A IVBUS Mode
1.25A IVBUS Mode
1.50A IVBUS Mode
1.75A IVBUS Mode
2.00A IVBUS Mode
2.25A IVBUS Mode
2.50A IVBUS Mode
2.75A IVBUS Mode
3.00A IVBUS Mode
MIN
TYP
MAX
VCLPROG1
CLPROG1 Servo Voltage in
Current Limit
CLPROG1 IVBUS Mode
1.2
V
VCLPROG2
CLPROG2 Servo Voltage in
Current Limit
2.5mA IVBUS Mode (USB Suspend)
100mA – 3A IVBUS Modes
103
1.2
mV
V
fOSC
Switching Frequency
RPMOS
High Side Switch On Resistance
0.090
Ω
RNMOS
Low Side Switch On Resistance
0.080
Ω
RCHG
Battery Charger Current Sense
Resistance
0.040
Ω
IPEAK
Peak Inductor Current Clamp
6.7
A
2.05
500mA – 3A IVBUS Modes
2.25
UNITS
mA/mA
mA/mA
mA/mA
mA/mA
mA/mA
mA/mA
mA/mA
mA/mA
mA/mA
mA/mA
mA/mA
mA/mA
mA/mA
mA/mA
mA/mA
mA/mA
19
79
466
557
657
758
839
990
1222
1494
1746
1999
2175
2477
2730
2956
2.50
MHz
Step-Up Mode PowerPath Switching Regulator (USB On-The-Go)
VBUS
Output Voltage
0mA ≤ IVBUS ≤ 500mA
VOUT
Input Voltage
IVBUSOTG
Output Current Limit
IVOUTOTGQ
VOUT Quiescent Current
VCLPROG2
Output Current Limit Servo Voltage
VBATSNSUVLO
VBATSNS Undervoltage Lockout
VBATSNS Falling
Hysteresis
tSCFAULT
Short-Circuit Fault Delay
VBUS < 4V
4.75
5.25
2.9
IVBUS = 0mA
2.65
V
V
1.4
A
1.96
mA
1.2
V
2.8
130
2.95
7.2
V
mV
ms
Overvoltage Protection, Priority Multiplexer and Undervoltage Lockout; USB Input Connected to USBSNS Through 3.6k Resistor; WALL Input
Connected to WALLSNS Through 3.6k Resistor
VUVLO
USB Input, Wall Input
Undervoltage Lockout
Rising Threshold
Falling Threshold
Hysteresis
4.05
3.90
4.45
4.25
V
V
mV
425
375
mV
mV
mV
6.3
V
100
VDUVLO
USB Input, Wall Input to BATSNS
Differential Undervoltage Lockout
Rising Threshold
Falling Threshold
Hysteresis
100
50
VOVLO
USB Input, Wall Input Overvoltage
Protection Threshold
Rising Threshold
5.75
VUSBGTACTV
USBGT Output Voltage Active
USBSNS < VUSBOVLO
2 • VUSBSNS
VWALLGTACTV
WALLGT Output Voltage Active
WALLSNS < VWALLOVLO
2 • VWALLSNS
V
VUSBGTPROT
USBGT Output Voltage Protected
USBSNS > VUSBOVLO
0
V
70
6.0
V
4155fc
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LTC4155
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the specified operating
junction temperature range, otherwise specifications are at TA ≈ TJ = 25°C (Note 2). VBUS = 5V, BATSNS = 3.7V, DVCC = 3.3V,
RCLPROG1 = RCLPROG2 = 1.21k, RPROG = 499Ω, unless otherwise noted.
SYMBOL
PARAMETER
CONDITIONS
VWALLGTPROT WALLGT Output Voltage Protected
WALLSNS > VWALLOVLO
VUSBGTLOAD, USBGT, WALLGT Voltage Under
VWALLGTLOAD Load
5V Through 3.6k into WALLSNS, USBSNS,
IUSBGT, IWALLGT = 1μA
MIN
TYP
8.4
MAX
UNITS
0
V
8.9
V
IUSBSNSQ
USBSNS Quiescent Current
VUSBSNS = 5V, VUSBSNS > VWALLSNS
VUSBSNS = 5V, VWALLSNS > VUSBSNS
27
54
μA
μA
IWALLSNSQ
WALLSNS Quiescent Current
VWALLSNS = 5V, VWALLSNS > VUSBSNS
VWALLSNS = 5V, VUSBSNS > VWALLSNS
27
54
μA
μA
tRISE
OVGCAP Time to Reach Regulation COVGCAP = 1nF
1.2
ms
IRQ Pin Characteristics
IIRQ
IRQ Pin Leakage Current
VIRQ = 5V
VIRQ
IRQ Pin Output Low Voltage
IIRQ = 5mA
1
μA
75
100
mV
ID Pin Characteristics
IID
ID Pin Pull-Up Current
VID = 0V
35
55
85
μA
VID_OTG
ID Pin Threshold Voltage
ID Pin Falling
Hysteresis
0.5
0.86
0.2
0.95
V
V
Overtemperature Battery Conditioner
IBATOVERTEMP Overtemp Battery Discharge
Current
Only When Enabled via I2C Control
125
mA
VBATOVERTEMP Overtemp Battery Voltage Target
Only When Enabled via I2C Control
3.85
V
Thermistor Measurement System
κOFFSET
VNTC / VNTCBIAS A/D Lower Range
End
VNTC / VNTCBIAS Ratio Below Which Only 0x00
Is Returned
0.113
V/V
κHIGH
VNTC / VNTCBIAS A/D Upper Range
End
VNTC / VNTCBIAS Ratio Above Which Only 0x7F
Is Returned
0.895
V/V
κSPAN
A/D Span Coefficient
(Decimal Format)
dTOO_COLD
NTCVAL at NTC_TOO_COLD
(Decimal Format)
dTOO_WARM
6.091
6.162
6.191
Warning Threshold
Reset Threshold
102
98
102
98
102
98
Count
Count
NTCVAL at NTC_TOO_WARM
(Decimal Format)
Warning Threshold
Reset Threshold
41
45
41
45
41
45
Count
Count
dHOT_FAULT
NTCVAL at HOT_FAULT
(Decimal Format)
Fault Threshold
Reset Threshold
19
23
19
23
19
23
Count
Count
INTC
NTC Leakage Current
100
nA
–100
mV/V/LSB
Ideal Diode
Forward Voltage Detection
Input Power Available, Battery Charger Off
DVCC
I2C Logic Reference Level
(Note 3)
IDVCCQ
DVCC Current
SCL/SDA = 0kHz
VFWD
15
mV
I2C Port
1.7
VMAX
0.25
μA
V
VDVCC_UVLO
DVCC UVLO
1.0
ADDRESS
I2C Address
0001_001[R/W]b
VIH,SDA,SCL
Input High Threshold
VIL,SDA,SCL
Input Low Threshold
IIH,SDA,SCL
Input Leakage High
70
SDA, SCL = DVCC
–1
V
% DVCC
30
% DVCC
1
μA
4155fc
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LTC4155
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the specified operating
junction temperature range, otherwise specifications are at TA ≈ TJ = 25°C (Note 2). VBUS = 5V, BATSNS = 3.7V, DVCC = 3.3V,
RCLPROG1 = RCLPROG2 = 1.21k, RPROG = 499Ω, unless otherwise noted.
SYMBOL
PARAMETER
CONDITIONS
IIL,SDA,SCL
Input Leakage Low
SDA, SCL = 0V
ISDA = 3mA
MIN
–1
TYP
MAX
1
UNITS
μA
VOL
Digital Output Low (SDA)
fSCL
Clock Operating Frequency
tBUF
Bus Free Time Between STOP and
START Condition
1.3
μs
tHD_SDA
Hold Time After (Repeated) START
Condition
0.6
μs
tSU_SDA
Repeated START Condition Set-Up
Time
0.6
μs
tSU_STO
STOP Condition Time
0.6
μs
tHD_DAT(OUT)
Data Hold Time
tHD_DAT(IN)
Input Data Hold Time
0
ns
tSU_DAT
Data Set-Up Time
100
ns
tLOW
Clock LOW Period
1.3
μs
tHIGH
Clock HIGH Period
0.6
μs
tf
Clock Data Fall Time
20
300
tr
Clock Data Rise Time
20
300
ns
tSP
Spike Suppression Time
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 LTC4155E is tested under pulsed load conditions such that
TJ ≈ TA. The LTC4155E is guaranteed to meet performance 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 LTC4155I is guaranteed over the full –40°C to 125°C operating
junction temperature range. The junction temperature (TJ, in °C) is
0
0.4
V
400
kHz
900
ns
ns
calculated from the ambient temperature (TA, in °C) and power dissipation
(PD, in watts) according to the formula:
TJ = TA + (PD • θJA), where the package thermal impedance
θJA = 43°C/W)
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 resistance and
other environmental factors.
Note 3. VMAX is the maximum of VBUS or BATSNS
Note 4. Total input current is IVBUSQ + VCLPROG/RCLPROG • (hCLPROG + 1).
4155fc
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LTC4155
TYPICAL PERFORMANCE CHARACTERISTICS
TA = 25°C (Note 2). VBUS = 5V, BATSNS = 3.7V,
DVCC = 3.3V, RCLPROG1 = RCLPROG2 = 1.21k, RPROG = 499Ω, unless otherwise noted.
Battery and VBUS Currents
vs VOUT Current
Battery and VBUS Currents
vs VOUT Current
4
0.6
INPUT CURRENT
9
CURRENT (A)
CHARGE CURRENT
0
IBUS
7
2
ICHG
1
0
–0.2
VBUS = 0V
8
CURRENT (μA)
0.4
CURRENT (A)
10
3A INPUT CURRENT LIMIT MODE
3
0.2
Battery Drain Current
vs Temperature
6
5
4
3
SUSPEND MODE (μA)
2
–1
1
–0.4
500mA INPUT CURRENT LIMIT MODE
0.2
0
0.6
0.4
VOUT CURRENT (A)
0.8
0
1.0
1
2
3
VOUT CURRENT (A)
4
4.0
95
3.0
90
2.5
85.0
2.0
POWER LOST
TO BATTERY
1.5
80.0
1.0
POWER LOST
TO VOUT
77.5
12.5% CHARGE
CURRENT MODE
0.3
0.2
0.1
0
2.4
70
1.00
500mA MODE
0.75
0.50
2.7
2.4
2.7
3.0
3.3
3.6
BATTERY VOLTAGE (V)
3.9
4.2
4155 G06
100mA USB Limited Battery
Charge Current vs Battery Voltage
CHARGE CURRENT (mA)
CHARGE CURRENT (A)
0.4
75
900mA MODE
1.25
3.0
3.3
4.2
3.6
3.9
4155 G05
BATTERY VOLTAGE (V)
INCLUDES LOSSES FROM 2w Si7938DP OVP FETS
XFL4020-102ME INDUCTOR AND Si5481DU CHARGER FET
100
0.5
100% CHARGE
CURRENT MODE
2.4
0.7
100% CHARGE
CURRENT MODE
1.50
55
1.0
500mA USB Limited Battery
Charge Current vs Battery Voltage
0.6
VFLOAT = 4.05V
60
0
1.5 2.0 2.5 3.0 3.5
CURRENT (A)
4155 G04
INCLUDES LOSSES FROM 2w Si7938DP OVP FETS
XFL4020-102ME INDUCTOR AND Si5481DU CHARGER FET
0.5
80
1.75
12.5% CHARGE
CURRENT MODE
65
0.5
75.0
0
85
IVOUT = 0A
M = PBAT/PBUS
VFLOAT = 4.2V
VOUT Voltage vs Battery Voltage
4.4
VFLOAT = 4.2V
4.3
IVOUT = 0A, VFLOAT = 4.2V
100% CHARGE
CURRENT MODE
50% CHARGE
CURRENT MODE
12.5% CHARGE
CURRENT MODE
CHARGER DISABLED
4.2
80
VOUT VOLTAGE (V)
EFFICIENCY (%)
3.5
POWER LOST (W)
EFFICIENCY
TO BATTERY
100
EFFICIENCY (%)
EFFICIENCY
TO VOUT
82.5
USB Compliant Load Current
Available Before Discharging
Battery
LOAD CURRENT (A)
Switching Regulator Efficiency
87.5
4155 G03
Battery Charger Total Efficiency
vs Battery Voltage
95.0
90.0
5
4155 G02
4155 G01
92.5
SHIP AND STORE MODE (μA)
0
– 40 –25 –10 5 20 35 50 65 80 95 110 125
TEMPERATURE (°C)
–2
60
40
4.1
4.0
3.9
3.8
3.7
20
3.6
0
3.4
3.5
2.7
3.6
3.3
3.0
BATTERY VOLTAGE (V)
3.9
4.2
4155 G07
2.4
2.7
3.0
3.3
3.6
BATTERY VOLTAGE (V)
3.9
4.2
4155 G08
2.4
2.7
3.0
3.3
3.6
BATTERY VOLTAGE (V)
3.9
4.2
4155 G09
4155fc
9
LTC4155
TYPICAL PERFORMANCE CHARACTERISTICS
TA = 25°C (Note 2). VBUS = 5V, BATSNS = 3.7V,
DVCC = 3.3V, RCLPROG1 = RCLPROG2 = 1.21k, RPROG = 499Ω, unless otherwise noted.
Battery Charger Resistance
vs Temperature
Normalized Float Voltage
vs Temperature
2.29
1.000
55
50
45
40
RESISTANCE INCLUDES VISHAY
SILICONIX Si5481DU EXTERNAL PMOS
–15
35
10
TEMPERATURE (°C)
60
85
0.998
100mA MODE
0.997
0.996
4613 G10
100
2.5
VBUS CURRENT (mA)
NORMALIZED CHARGE CURRENT (%)
3.0
80
60
100% CHARGE
CURRENT MODE
40
2.21
2.19
4155 G12
2.7
3.0
3.3
BATTERY VOLTAGE (V)
VOUT Voltage vs VOUT Current in
USB Suspend Mode
4.4
4.3
4.2
2.0
1.5
MAX
NOT MAX
1.0
4.1
4.0
3.9
3.8
12.5% CHARGE
CURRENT MODE
0.5
0
0
3.6
3.7
2.5
3.0
3.5
4.0
4.5
VBUS VOLTAGE (V)
5.0
4155 G13
3.6
5.5
0
0.5
1.0
2.0
1.5
VOUT CURRENT (mA)
Static DVCC Current
vs DVCC Voltage
2.5
2.5
4155 G15
4155 G14
VBUS Current vs VOUT Current in
USB Suspend Mode
Rising Overvoltage Lockout
Threshold vs Temperature
0.8
6.12
0.7
1.5
1.0
0.6
VBUS VOLTAGE (V)
2.0
DVCC CURRENT (μA)
VBUS CURRENT (mA)
2.23
VBUS Current vs VBUS Voltage
in USB Suspend Mode
120
2.4
2.25
4155 G11
Automatic Charge Current
Reduction vs Battery Voltage
20
2.27
2.17
–40 –25 –10 5 20 35 50 65 80 95 110 125
TEMPERATURE (°C)
0.995
–40 –25 –10 5 20 35 50 65 80 95 110 125
TEMPERATURE (°C)
VOUT VOLTAGE (V)
35
–40
500mA MODE
0.999
OSCILLATOR FREQUENCY (MHz)
NORMALIZED FLOAT VOLTAGE (V)
CHARGER TOTAL RESISTANCE (mΩ)
60
Oscillator Frequency
vs Temperature
0.5
0.4
0.3
6.11
6.10
6.09
0.2
6.08
0.1
0.5
0
0.5
1.5
2.0
1.0
VOUT CURRENT (mA)
2.5
4155 G16
0
0
1
2
3
DVCC VOLTAGE (V)
4
5
4155 G17
6.07
–40 –25 –10 5 20 35 50 65 80 95 110 125
TEMPERATURE (°C)
4155 G18
4155fc
10
LTC4155
TYPICAL PERFORMANCE CHARACTERISTICS
TA = 25°C (Note 2). VBUS = 5V, BATSNS = 3.7V,
DVCC = 3.3V, RCLPROG1 = RCLPROG2 = 1.21k, RPROG = 499Ω, unless otherwise noted.
Undervoltage Lockout Thresholds
vs Temperature
OVP Charge Pump Output
vs Input Voltage
0.20
10
4.30
–45°C
–30°C
–15°C
0°C
15°C
30°C
45°C
60°C
75°C
90°C
105°C
120°C
135°C
DISCHARGE CURRENT (A)
RISING UVLO NOT MAX
4.25
9
USBGT WALLGT (V)
4.20
RISING UVLO MAX
4.15
FALLING UVLO NOT MAX
4.10
4.05
8
7
FALLING UVLO MAX
0.15
0.10
0.05
4.00
–15
10
35
60
85
6
0
3.5
4.0
TEMPERATURE (°C)
4.5
5.0
5.5
INPUT VOLTAGE (V)
6.0
4155 G19
6.5
3.7
3.8
3.9
4.0
BATTERY VOLTAGE (V)
4.1
4.2
4155 G21
CLPROG Voltage vs VBUS Current
1.4
4
SHIP-AND-STORE MODE, DVCC = 0V
SHIP-AND-STORE MODE, DVCC = 3.3V
DVCC = 0V
DVCC = 3.3V
3A INPUT CURRENT LIMIT MODE
1.2
CLPROG VOLTAGE (V)
3
3.6
4155 G20
Battery Drain Current
vs Battery Voltage
BATTERY CURRENT (μA)
2
1
1.0
0.8
0.6
0.4
0.2
0
2.4
0
2.7
3.3
3.6
3.9
3.0
BATTERY VOLTAGE (V)
0
4.2
0.5
1.0 1.5 2.0 2.5
VBUS CURRENT (A)
3.0
CLPROG Voltage vs VOUT Current
1.4
VOUT Voltage vs VOUT Current
4.4
3A INPUT CURRENT LIMIT MODE
3A
MODE
1.2
4.2
1.0
0.8
0.6
0.4
4.0
900mA MODE
3.8
500mA
MODE
VBATSNS = 3.7V
BATTERY CHARGER DISABLED
3.6
0.2
0
0
0.5
2.5
1.0 1.5 2.0
VOUT CURRENT (A)
3.5
4155 G23
4155 G22
VOUT VOLTAGE (V)
3.95
–40
CLPROG VOLTAGE (V)
INPUT UVLO THRESHOLD VOLTAGE (V)
Battery Conditioner Current vs
Battery Voltage and Temperature
3.0
3.5
3.4
0
1
2
3
4
VOUT CURRENT (A)
4155 G24
4155 G33
4155fc
11
LTC4155
PIN FUNCTIONS
SDA (Pin 1): Data Input/Output for the I2C Serial Port.
The I2C input levels are scaled with respect to DVCC for
I2C compliance.
DVCC (Pin 2): Logic Supply for the I2C Serial Port. DVCC
sets the reference level of the SDA and SCL pins for I2C
compliance. It should be connected to the same power
supply used to power the I2C pull-up resistors.
IRQ (Pin 3): Open-Drain Interrupt Output. The IRQ pin
can be used to generate an interrupt due to a variety of
maskable status change events within the LTC4155.
ID (Pin 4): USB A-Device Detection Pin. When wired to a
mini- or micro-USB connector, the ID pin detects when
the “A” side of a mini or micro-USB cable is connected
to the product. If the ID pin is pulled down, and the
LOCKOUT_ID_PIN bit is not set in the I2C port, the switching PowerPath operates in reverse providing USB power
to the VBUS pin from the battery. USB On-The-Go power
can only be delivered from the USB multiplexer path.
CLPROG1 (Pin 5): Primary VBUS Current Limit Programming Pin. A resistor from CLPROG1 to ground determines
the upper limit of the current drawn from the VBUS pin when
CLPROG1 is selected. A precise measure of VBUS current,
hCLPROG1–1, is sent to the CLPROG1 pin. The switching
regulator increases power delivery until CLPROG1 reaches
1.2V. Therefore, the current drawn from VBUS will be
limited to an amount given by the 1.2V reference voltage,
hCLPROG1 and RCLPROG1.
Typically CLPROG1 is used to override the USB compliant
input current control pin, CLPROG2, in applications where
USB compliance is not a requirement. This would be useful for applications that use a dedicated wall adapter and
would rather not be limited to the 500mW start-up value
required by USB specifications. If USB compliance is a
requirement at start-up, CLPROG1 should be connected
to CLPROG2 and a single resistor should be used. See
the CLPROG2 pin description.
In USB noncompliant designs, the user is encouraged to
use an RCLPROG1 value that best suits their application
for start-up current limit. See the Operation section for
more details.
CLPROG2 (Pin 6): Secondary VBUS Current Limit Program Pin. CLPROG2 controls the VBUS current limit when
either selected via I2C command or when CLPROG1 and
CLPROG2 are shorted together. When selected, a resistor
from CLPROG2 to ground determines the upper limit of
the current drawn from the VBUS pin. Like CLPROG1, a
precise fraction of VBUS current, hCLPROG2–1, is sent to the
CLPROG2 pin. The switching regulator increases power
delivery until CLPROG2 reaches 1.2V. Therefore, the current drawn from VBUS will be limited to an amount given
by the 1.2V reference voltage, hCLPROG2 and RCLPROG2.
There are a multitude of ratios for hCLPROG2 available by I2C
control, three of which correspond to the 100mA, 500mA
and 900mA USB specifications. CLPROG2 is also used to
regulate maximum input current in the USB suspend mode
and maximum output current in USB On-The-Go mode.
If CLPROG1 and CLPROG2 are shorted together at the onset
of available input power, the LTC4155 selects CLPROG2 in
the 100mA USB mode to limit input current. This ensures
USB compliance if so desired. For USB compliance in all
modes, the user is encouraged to make RCLPROG2 equal
to the value declared in the Electrical Characteristics.
WALLSNS (Pin 7): Highest Priority Multiplexer Input and
Overvoltage Protection Sense Input. WALLSNS should be
connected through a 3.6k resistor to a high priority input
power connector and one drain of two source-connected
N-channel MOSFET pass transistors. When voltage is
detected on WALLSNS, it draws a small amount of current
to power a charge pump which then provides gate drive to
WALLGT to energize the external transistors. If the input
voltage exceeds VOVLO, WALLGT will be pulled to GND
to disable the pass transistors and protect the LTC4155
from high voltage.
USBSNS (Pin 8): Lowest Priority Multiplexer Input and
Overvoltage Protection Sense Input. USBSNS should be
connected through a 3.6k resistor to a low priority input
power connector and one drain of two source-connected
N-channel MOSFET pass transistors. When voltage is
detected on USBSNS, and no voltage is detected on
WALLSNS, USBSNS draws a small amount of current to
power a charge pump which then provides gate drive to
4155fc
12
LTC4155
PIN FUNCTIONS
USBGT to energize the external transistors. If the input
voltage exceeds VOVLO, USBGT will be pulled to GND to
disable the pass transistors and protect the LTC4155 from
high voltage.
Power detected on WALLSNS is prioritized over USBSNS.
If power is detected on both WALLSNS and USBSNS, by
default, only WALLGT will receive drive for its pass transistors. See the Operations section for further information
about programmable priority.
USBGT (Pin 9): Overvoltage Protection and Priority Multiplexer Gate Output. Connect USBGT to the gate pins of
two source-connected external N-channel MOSFET pass
transistors. One drain of the transistors should be connected to VBUS and the other drain should be connected
to a low priority DC input connector. In the absence of an
overvoltage condition, this pin is driven from an internal
charge pump capable of creating sufficient overdrive to fully
enhance the pass transistors. If an overvoltage condition
is detected, USBGT is brought rapidly to GND to prevent
damage to the LTC4155. USBGT works in conjunction with
USBSNS to provide this protection. USBGT also works in
conjunction with WALLSNS to determine power source
prioritization. See the Operation section.
OVGCAP (Pin 10): Overvoltage Protection Capacitor
Output. A 0.1μF capacitor should be connected from
OVGCAP to GND. OVGCAP is used to store charge so
that it can be rapidly moved to WALLGT or USBGT. This
feature provides faster power switchover when multiple
inputs are supported by the end product.
WALLGT (Pin 9): Overvoltage Protection and Priority Multiplexer Gate Output. Connect WALLGT to the gate pins of
two source-connected external N-channel MOSFET pass
transistors. One drain of the transistors should be connected to VBUS and the other drain should be connected
to a high priority input connector. In the absence of an
overvoltage condition, this pin is driven from an internal
charge pump capable of creating sufficient gate drive to fully
enhance the pass transistors. If an overvoltage condition
is detected, WALLGT is brought rapidly to GND to prevent
damage to the LTC4155. WALLGT works in conjunction
with WALLSNS to provide this protection. WALLGT also
works in conjunction with USBSNS to determine power
source prioritization. See the Operation section.
VC (Pin 12): Compensation Pin. A 0.047μF ceramic capacitor on this pin compensates the switching regulator
control loops.
VOUTSNS (Pin 13): Output Voltage Sense Input. Connecting
VOUTSNS directly to the VOUT bypass capacitor ensures that
VOUT regulates at the correct level.
NTCBIAS (Pin 14): NTC Thermistor Bias Output. Connect a
bias resistor between NTCBIAS and NTC, and a thermistor
between NTC and GND. The value of the bias resistor should
usually be equal to the nominal value of the thermistor.
NTC (Pin 15): Input to the Negative Temperature Coefficient
Thermistor Monitoring Circuit. The NTC pin connects to
a negative temperature coefficient thermistor, which is
typically copackaged with the battery, to determine if the
battery is too warm or too cold to charge or if the battery
is dangerously hot. If the battery’s temperature is out of
range, charging is paused until the battery temperature reenters the valid range. A low drift bias resistor is required
from NTCBIAS to NTC and a thermistor is required from
NTC to ground. The thermistor’s temperature reading is
continually digitized by an analog to digital converter and
may be read back at any time via the I2C port.
BATSNS (Pin 16): Battery Voltage Sense Input. For proper
operation, this pin must always be connected to the battery.
For fastest charging, connect BATSNS physically close to
the Lithium-Ion cell’s positive terminal. Depending upon
available power and load, a Li-Ion battery connected to
the BATSNS pin will either be charged from VOUT or will
deliver system power to VOUT via the required external
P-channel MOSFET transistor.
BATGATE (Pin 17): Battery Charger and Ideal Diode Amplifier Control Output. This pin controls the gate of an
external P-channel MOSFET transistor used to charge the
Lithium-Ion cell and to provide power to VOUT when the
system load exceeds available input power. The source of
the P-channel MOSFET should be connected to CHGSNS
and the drain should be connected to BATSNS and the
battery.
4155fc
13
LTC4155
PIN FUNCTIONS
PROG (Pin 18): Charge Current Program and Monitor Pin. A
resistor from PROG to GND programs the maximum battery
charge rate. The LTC4155 features I2C programmability
enabling software selection of fifteen charge currents
that are inversely proportional to a single user-supplied
programming resistor.
CHGSNS (Pins 19, 20): Battery Charger Current Sense
Pin. An internal current sense resistor between VOUT
and CHGSNS monitors battery charge current. CHGSNS
should be connected to the source of an external P-channel
MOSFET transistor.
VOUT (Pins 21, 22): Output Voltage of the Switching
PowerPath Controller and Input Voltage of the Battery
Charging System. The majority of the portable product
should be powered from VOUT. The LTC4155 will partition
the available power between the external load on VOUT and
the battery charger. Priority is given to the external load
and any extra power is used to charge the battery. An
ideal diode control function from BATSNS to VOUT ensures
that VOUT is powered even if the load exceeds the allotted
power from VBUS or if the VBUS power source is removed.
VOUT should be bypassed with a low impedance multilayer
ceramic capacitor of at least 22μF.
VBUS (Pins 23, 24, 25): Input Voltage for the PowerPath
Step-Down Switching Regulator and Output Voltage for
the USB On-The-Go Step-Up Switching Regulator. VBUS
may be connected to the USB port of a computer or a DC
output wall adapter or to one or both optional overvoltage protection/multiplexer compound transistors. VBUS
should be bypassed with a low impedance multilayer
ceramic capacitor.
SW (Pins 26, 27): Switching Regulator Power Transmission Pin. The SW pin delivers power from VBUS to VOUT
via the step-down switching regulator and from VOUT to
VBUS via the step-up switching regulator. A 1μH inductor
should be connected from SW to VOUT. See the Applications Information section for a discussion of current rating.
SCL (Pin 28): Clock Input for the I2C Serial Port. The
I2C input levels are scaled with respect to DVCC for I2C
compliance.
GND (Exposed Pad Pin 29): Exposed pad must be soldered
to the PCB to provide a low electrical and thermal impedance connection to the printed circuit board’s ground. A
continuous ground plane on the second layer of a multilayer
printed circuit board is strongly recommended.
4155fc
14
TO WALL
ADAPTOR
TO USB
DVCC
T
VBUS
NTC
NTC
A/D
VOUT
0.9V
NTCBIAS
IRQ
SDA
SCL
DVCC
ID
OVGCAP
WALLSNS
WALLGT
VBUS
VBUS
7
I2C
OV
UV
UV
n
w2
CLPROG1
I2C
PROGRAMMABLE
MASK
USB OTG
–
+
–
+
+
–
OV
+
–
ENABLE
USB OTG
–
+
CLPROG2
SHORT
DETECTOR
VC
END-OF-CHARGE
INDICATION
VFLOAT
D/A
4
2
C/x
D/A
0.15V TO 1.2V
ICHARGE
D/A
4.05V to 4.2V
4.35V
CHARGE CURRENT
CONTROLLER
+
–
VFLOAT
CONTROLLER
VOUT
CONTROLLER
PWM AND
GATE DRIVE
INPUT UNDERVOLTAGE
CURRENT LIMIT CONTOLLER
4.30V
AVERAGE USB
INPUT AND OTG
OUTPUT CURRENT
LIMIT CONTROLLER
1.200V
USB
ON-THE-GO
BOOST
CONTROL
+
–
+
–
+
–
+
–
USBGT
+
–
USBSNS
I2C
I2C
2
I2C
PROG
ENABLE
CHARGER
+
–
3.5V
–
+
BATGATE
CHGSNS
CHGSNS
VOUT
VOUT
VOUTSNS
AUTOMATIC CHARGE
CURRENT REDUCTION
CONTROLLER
BATSNS
IDEAL
DIODE
SW
SW
4155 BD
+
SINGLE-CELL
LITHIUM-ION
25mΩ
EXTERNAL
PMOS
EX: VISHAYSILICONIX
Si548IDU
GREATER
OF BATSNS
OR
3.5V TO
SYSTEM
LOAD
LTC4155
BLOCK DIAGRAM
4155fc
15
LTC4155
TIMING DIAGRAMS
I2C Write Protocol
OPTIONAL
SUB ADDRESS
WRITE ADDRESS
INPUT DATA BYTE
R/W
A7
0
0
0
1
0
0
1
0
SDA
0
0
0
1
0
0
1
0
ACK
SCL
1
2
3
4
5
6
7
8
9
A6
A5
A4
A3
A2
A1
A0
B7
B6
B5
B4
B3
B2
B1
B0
START
STOP
ACK
1
2
3
4
5
6
7
8
9
ACK
1
2
3
4
5
6
7
8
9
4155 TD01
I2C Read Protocol
OUTPUT DATA BYTE
R/ W
READ ADDRESS
A7
0
0
0
1
0
0
1
1
SDA
0
0
0
1
0
0
1
1
ACK
SCL
1
2
3
4
5
6
7
8
9
A6
A5
A4
A3
A2
A1
A0
START
NACK
1
2
3
4
5
6
7
8
9
4155 TD02
Timing Diagram
SDA
tSU, STA
tSU, DAT
tLOW
tHD, STA
tHD, DAT
tBUF
tSU, STO
4155 TD03
SCL
tHIGH
tHD, STA
START
CONDITION
(S)
tr
tSP
tf
REPEATED START
CONDITION
(Sr)
STOP
CONDITION
(P)
START
CONDITION
(S)
4155fc
16
LTC4155
OPERATION
I2C
Table 2. I2C Map
SUB
ADDRESS
REGISTER
ACCESS
REG0
WRITE/
READBACK
0x00
REG1
WRITE/
READBACK
0x01
REG2
WRITE/
READBACK
0x02
REG3
READ
0x03
D7
D6
D5
DISABLE
INPUT
UVCL
ENABLE
BATTERY
CONDITIONER
LOCKOUT
USB OTG ID
PIN
INPUT
PRIORITY
D4
REG5
READ
READ
0x04
USBSNS
GOOD
D1
FLOAT VOLTAGE
ID PIN
DETECTION
STATUS
WALLSNS
GOOD
INPUT
CURRENT
LIMIT
ACTIVE
BOOST
ENABLE
STATUS
C/x DETECTION
THERMISTOR STATUS
INPUT UVCL
OVP ACTIVE OTG FAULT
ACTIVE
0x05
WRITE/
READBACK
ENABLE
ENABLE
CHARGER
FAULT
INTERRUPTS INTERRUPTS
DISARM
SHIP-ANDSTORE
MODE*
WRITE
ARM SHIPAND-STORE
MODE**
BAD CELL
FAULT
0x06
CLEAR
INTERRUPT*
REG7
LOW
BATTERY
STATUS
THERMISTOR
WARNING
THERMISTOR VALUE
REG6
D0
WALL CURRENT LIMIT
CHARGE CURRENT
EXTERNAL
POWER
GOOD
D2
USB CURRENT LIMIT
SAFETY TIMER
CHARGER STATUS
REG4
D3
ENABLE
ENABLE
EXTERNAL
USB OTG
POWER
INTERRUPTS
INTERRUPTS
ENABLE
INPUT
ENABLE
ENABLE
CURRENT INPUT UVCL
USB
LIMIT
INTERRUPTS On-The-Go
INTERRUPTS
0
RESERVED
0x07
0
REQUIRED
0
REQUIRED
0
REQUIRED
0
REQUIRED
0
REQUIRED
0
REQUIRED
0
REQUIRED
0
REQUIRED
*Interrupts are cleared and ship-and-store mode is disarmed during the acknowledge clock cycle following a full data byte written to sub address 0x06.
Reading data from sub address 0x06 has no effect.
**Ship-and-store mode is armed during the acknowledge clock cycle following a full data byte written to sub address 0x07. The data written to sub
address 0x07 is ignored. Reading from sub address 0x07 has no effect and the returned data is undefined, independent of the arming state of
ship-and-store mode.
4155fc
17
LTC4155
OPERATION
Introduction
The LTC4155 is an advanced I2C controlled power manager and Li-Ion/Polymer battery charger designed to
efficiently transfer up to 15W from a variety of sources
while minimizing power dissipation and easing thermal
budgeting constraints. By decoupling VOUT and the battery,
the innovative instant-on PowerPath architecture ensures
that the application is powered immediately after external
voltage is applied, even with a completely dead battery,
by prioritizing power to the application.
Since VOUT and the battery are decoupled, the LTC4155
includes an ideal diode controller. The ideal diode from
the battery to VOUT guarantees that ample power is always
available to VOUT even if there is insufficient or absent
power at VBUS.
The LTC4155 includes a monolithic step-down switching battery charger for USB support, wall adapters and
other 5V sources. By incorporating a unique input current
measurement and control system, the switching charger
interfaces seamlessly to wall adapters and USB ports
without requiring application software to monitor and
adjust system loads. Because power is conserved, the
LTC4155 allows the load current on VOUT to exceed the
current drawn by the USB port or wall adapter, making
maximum use of the allowable power for battery charging
without exceeding the USB or wall adapter power delivery
specifications. A wide range of input current settings as
well as battery charge current settings are available for
selection by I2C.
Using only one inductor, the switching PowerPath can
operate in reverse, boosting the battery voltage to provide
5V power at its input pin for USB On-The-Go applications.
In the USB-OTG mode, the switching regulator supports
USB high power loads up to 500mA. Protection circuits
ensure that the current is limited and ultimately the channel
is shut down if a fault is detected on the USB connector.
To support USB low power mode, the LTC4155 can deliver
power to the external load and charge the battery through
a linear regulator while limiting input current to less than
100mA.
The LTC4155 also features a combination overvoltage
protection circuit /priority multiplexer which prevents
damage to its input caused by accidental application of
high voltage and selects one of two high power input
connectors based on priority.
A thermistor measurement subsystem periodically
monitors and reports the battery’s thermistor value via
the onboard I2C port. The same circuit then reports when
dangerous battery temperatures are reached and can
autonomously pause charging and optionally enable a battery safety conditioner. Refer to Overtemperature Battery
Conditioner in the Operation section for further details.
To minimize battery drain when a device is connected to a
suspended USB port, an LDO from VBUS to VOUT provides
the allowable USB suspend current to the application.
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 system
software. Several status change event categories are
maskable for maximum flexibility.
To eliminate battery drain between manufacture and sale,
a ship-and-store feature reduces the already low battery
standby current to nearly zero and optionally disconnects
power from downstream circuitry.
An input undervoltage amplifier optionally prevents the
input voltage from decreasing below 4.3V when a resistive
cable or current limited supply is providing input power
to the LTC4155.
Finally, the LTC4155 has considerable adjustability built
in so that power levels and status information can be
controlled and monitored via the simple 2-wire I2C port.
Input Current-Limited Step-Down Switching Charger
Power delivery from VBUS to VOUT is controlled by a
2.25MHz constant-frequency step-down switching regulator. The switching regulator reduces output power in
response to one of six regulation loops, including battery
voltage, battery charge current, output voltage, input current, input undervoltage, and external PMOS charger FET
power dissipation. For USB low power (100mA) and USB
suspend (2.5mA) modes, the switching regulator is disabled and power is transmitted through a linear regulator.
4155fc
18
LTC4155
OPERATION
When the battery charger is enabled, the switching regulator will reduce its output power to prevent VBATSNS from
exceeding the programmed battery float voltage, VFLOAT.
The float voltage may be selected from among four possible choices via the I2C interface using bits VFLOAT[1:0].
Refer to Table 12.
Battery Charge Current Regulation and Low Cell Trickle
Charge
The following expression may be used to determine the
battery charge current at any time by sampling the PROG
pin voltage.
IBAT =
VPROG
• 1000
RPROG
This expression may also be used to calculate the required
value of RPROG for any desired charge current. The resistor value required to program default maximum charge
current may be found by substituting VPROG = 1.200 and
solving for RPROG. The other fourteen settings are I2C
selectable using ICHARGE[3:0] and reduce the charge
current in 6.25% steps. The resulting limits may be found
by substituting RPROG and the relevant VPROG servo voltage from Table 11.
The maximum charge current should be set based on the
cell size and maximum charge rate without regard to input
current setting or input power source.
The LTC4155 monitors the voltage across the external
PMOS transistor and automatically reduces the current regulation servo voltage at VPROG to limit power
2.5
1.0
2.0
0.8
1.5
0.6
1.0
0.4
0.5
0.2
0
2.4
2.7
3.0
3.3
3.6
BATTERY VOLTAGE (V)
3.9
PFET DISSIPATION (W)
The switching regulator will also reduce its output power
to limit battery charge current, ICHARGE, to a programmed
maximum value. The battery charge current is programmed
using both a resistor, RPROG, between PROG and ground
to set default maximum charge current plus I2C adjustability to optionally reduce programmed charge current.
The battery charge current loop mirrors a precise fraction
of the battery charge current, IBAT, to the PROG pin, then
reduces switching regulator output power to limit the
resultant voltage, VPROG, to one of fifteen possible servo
reference voltages.
dissipation in the transistor. During normal operation, the
PMOS channel is fully enhanced and power dissipation is
typically under 100mW. Starting when the battery voltage
is below approximately 3.25V, the charge current servo
voltage will be gradually reduced from its I2C programmed
value to a minimum value between 75mV and 100mV when
the battery is below VLOWBAT, typically 2.8V. This charge
current reduction has the combined effect of protecting the
external PMOS transistor from damage due to excessive
heat, while also trickle charging the excessively depleted
cell to maximize battery health and lifetime. Peak power
dissipation in the external PMOS transistor is limited to
approximately 1W. Figure 1 shows the relationship between
battery voltage, charge current and power dissipation.
BATTERY CHARGE CURRENT (A)
Battery Float Voltage Regulation
0
4.2
4155 F01
ICHARGE 100% MODE (2.4A)
PDISS 100% MODE (2.4A)
ICHARGE 50% MODE (1.2A)
PDISS 50% MODE (1.2A)
Figure 1. VOUT Minimum Voltage Regulation
VOUT Voltage Regulation
A third control loop reduces power delivery by the switching regulator in response to the voltage at VOUT, which
has a nonprogrammable servo voltage of 4.35V. When the
battery charger is enabled, VOUT is connected to BATSNS
through the internal charge current sense resistor and
the external PMOS battery FET. The two node voltages
will differ only by the I • R drop through the two devices,
effectively keeping VOUT below its servo point for the
duration of the charge cycle.
The LTC4155 will attempt to prevent VOUT from falling
below approximately 3.5V when the battery is deeply
4155fc
19
LTC4155
OPERATION
discharged. This feature allows instant-on operation
when the low state of charge would otherwise prevent
operation of the system. If the system load plus battery
charger load exceeds the available input power, battery
charge current will be sacrificed to prioritize the system
load and maintain the switching regulator output voltage
while continuing to observe the input current limit. If the
system load alone exceeds the power available from the
input, the output voltage must fall to deliver the additional
current, with supplemental current eventually being supplied by the battery.
The LTC4155 can tolerate a resistive connection to the
input power source by automatically reducing power
transmission as the VBUS pin drops to 4.3V preventing a
possible UVLO oscillation. The undervoltage current limit
feature can be disabled by I2C using the DISABLE_INPUT_
UVCL bit. Refer to Table 5.
Input Current Regulation
USB On-The-Go 5V Boost Converter
To meet the maximum load specification of the available
supply (USB/wall adapter), the switching regulator contains
a measurement and control system which ensures that
the average input current is below the level programmed
at the CLPROG1 or CLPROG2 pin and the I2C port. Connecting a single 1% tolerance resistor of the recommended
value to both the CLPROG1 and CLPROG2 pins guarantees
compliance with the 2.5mA, 100mA, 500mA, and 900mA
USB 2.0/3.0 current specifications, while also permitting
other I2C selectable current limits up to 3A. The input
current limit is independently selectable for each of the
two inputs, with the USBILIM[4:0] and WALLILIM[4:0]
bits in the I2C port. The USB input current limit setting
resets to 100mA when power is removed from its respective input. The WALL input current limit setting resets to
100mA when power is removed from both the USB and
WALL inputs. Refer to Alternate Default Input Current Limit
in the Operation section to program a non USB compliant default input current limit for use with wall adapters
or other power sources. Refer to Table 8 for a complete
listing of I2C programmable input current limit settings.
The LTC4155 switching regulator can be operated in
reverse to deliver power from the battery to VBUS while
boosting the VBUS voltage to 5V. This mode can be used
to implement features such as USB On-The-Go without
any additional magnetics or other external components.
If the combined external load plus battery charge current is
large enough to cause the switching power supply to reach
the programmed input current limit, the battery charger
will reduce its charge current by precisely the amount
necessary to enable the external load to be satisfied. Even
if the battery charge current is programmed to exceed
the allowable input power, the specification for average
input current will not be violated; the battery charger will
reduce its current as needed. Furthermore, if the load at
VOUT exceeds the programmed power level from VBUS, the
extra load current will be drawn from the battery via the
ideal diode independent of whether the battery charger is
enabled or disabled.
Input Undervoltage Current Limit
The step-up switching regulator may be enabled in one of
two ways. The LTC4155 can optionally monitor the ID pin of
a USB cable and autonomously start the step-up regulator
when a host-side A/B connector is detected with a grounded
ID pin. The switching regulator may also be enabled
directly with the REQUEST_OTG I2C command. Note that
the step-up regulator will not operate if input power is
present on either the USB or WALL input, or if the battery
voltage is below VLOWBAT, typically 2.8V. The I2C status bits
OTG_ENABLED, LOWBAT and OTG_FAULT can be used to
determine if the step-up converter is running. Refer to ID
Pin Detection in the Operation section for more information
about the autonomous step-up regulator start-up.
The step-up regulator only provides power to the USB input.
It is not possible to provide power to the WALL input. The
I2C PRIORITY setting has no effect on step-up regulator
operation. Refer to Dual-Input Overvoltage Protection and
Undervoltage Lockout in the Operation section for more
information about multiple input operation.
The switching regulator is guaranteed to deliver 500mA
to VBUS and will limit its output current to approximately
1.4A while allowing VBUS to fall when overloaded. If a
short-circuit fault is detected, the channel will be shut
down after approximately 8ms and the problem will be
reported with the I2C status bit OTG_FAULT.
4155fc
20
LTC4155
OPERATION
ID Pin Detection
For USB On-The-Go compatibility, the step-up switching
regulator can optionally start autonomously when the
grounded ID pin in the A side of an On-The-Go cable is
detected.
The ID pin is monitored at all times. Its status is reported
in the I2C bit ID_DETECT, reporting true when the ID pin
is grounded. Optionally, any change in ID_PIN_DETECT
may trigger an interrupt request to notify the system
processor. Unless the I2C LOCKOUT_ID_PIN bit has
been set, ID pin detection will also automatically start the
step-up regulator. Note that LOCKOUT_ID_PIN locks out
automatic start-up, but not monitoring of the ID pin. Also,
the REQUEST_OTG command may be used to enable the
step-up regulator, independent of the state of ID_PIN_
DETECT and LOCKOUT_ID_PIN. Note that the regulator
will not start if input power is already present on either
input. The I2C status bits OTG_ENABLED and OTG_FAULT
can be used to determine if the regulator is running.
The ID pin detection circuit will report a short on the ID
pin for ID pin impedances lower than approximately 24k.
The USB Battery Charging Specification Rev 1.1 added
additional signaling to the ID pin, specifying other possible
ID pin resistances of RID_A, RID_B and RID_C. These
impedances are all larger than the 24k threshold and will
typically not cause an ID pin short detection.
Dual-Input Overvoltage Protection and
Undervoltage Lockout
The LTC4155 can provide overvoltage protection to its
two power inputs with minimal external components, as
shown in Figure 2.
R1
TO WALL
INPUT
TO USB
INPUT
WALLSNS
WALLGT
LTC4155
MN1
MN3
MN2
MN4
R2
VBUS
USBGT
USBSNS
OVGCAP
4155 F02
Figure 2. Dual-Input Overvoltage Protection Multiplexer
The LTC4155 acts as a shunt regulator when the input is
overvoltage, clamping USBSNS or WALLSNS to 6V. Resistors R1 and R2 should be 3.6k and be rated appropriately
for the worst-case power dissipation during an overvoltage
event. The power dissipated in the resistor is given by the
following expression:
PRESISTOR =
(VOVERVOLTAGE − 6V) 2
3.6k
For example, a typical 0201 size resistor would be appropriate for possible overvoltage events up to 19V. An
0402 size resistor would be appropriate up to 20V, an
0603 up to 24V, an 0805 up to 27V, and a 1206 up to 35V.
Additional power derating may be necessary at elevated
ambient temperature. The maximum allowed shunt current into the USBSNS and WALLSNS pins constrains the
upper limit of protection to 77V.
The drain-source voltage rating, VDS, of N-channel FETs
MN1-MN2 must be appropriate for the level of overvoltage protection desired, as the full magnitude of the input
voltage is applied across one of these devices.
The drain-source voltage rating of N-channel FETs MN3MN4 need only be as high as the protection threshold,
typically 6.2V. MN3-MN4 are not required for overvoltage
protection, but are required to block current from circulating
from one input to the other through the unused channel’s
FET body diode. For single-input applications, only a single
power FET is required. Refer to Alternate Input Power
Configurations in the Applications Information section
for implementation details.
Negative voltage protection can be added by reconfiguring
the circuit without adding any additional power transistors.
Refer to Alternate Input Power Configurations in the Applications Information section for implementation details.
For an input (USB or WALL) to be considered a valid
power source, it must satisfy three conditions. First, it
must be above a minimum voltage, VUVLO. Second, it
must be greater than the battery voltage by a minimum of
VDUVLO. Lastly, it must be below the overvoltage protection
threshold voltage, VOVLO. The USBSNS and WALLSNS pins
each draw a small current which causes a voltage offset
between the USB and WALL inputs and the USBSNS and
4155fc
21
LTC4155
OPERATION
WALLSNS pins. The voltage threshold values previously
listed and specified in the Electrical Characteristics table
are valid when each input is connected to its respective
sense pin through a 3.6k resistor.
The status of the USB and WALL inputs is monitored
continuously and reported by I2C, with the option of
generating several interrupts. When all three conditions
previously listed are true, the LTC4155 will report the input
valid by asserting USBSNSGD or WALLSNSGD in the I2C
port. Optionally, if external power interrupts are enabled,
an interrupt request will be generated.
When power is applied simultaneously to both inputs,
the LTC4155 will draw power from the WALL input by
default. If the I2C PRIORITY bit is asserted, the LTC4155
will instead draw power from the USB input when both
inputs are present. The USB On-The-Go step-up regulator
delivers power only to the USB input, and the PRIORITY bit is ignored in this mode. The input current limits
USBILIM[4:0] and WALLILIM[4:0] also reset to 100mA
default mode under different criteria. In all other respects,
the two inputs are identical.
An optional capacitor may be placed between the OVGCAP
pin and GND to minimize input current disruption when
switching from one input to the other while operating at
high power levels. The capacitor must be rated to withstand
at least 13V and should be approximately ten times larger
than the total gate capacitance of the series NMOS power
transistors. Capacitance on this pin can also be used to
slow the gate charging if the application requires controlled
inrush current to any additional input capacitance on the
VBUS pin. If fast switching between input or inrush control
is not necessary, OVGCAP may be left unconnected.
WALLSNS
WALLGT
LTC4155
TO POWER
INPUT
VBUS
R1
If overvoltage protection is not necessary in the application,
connect USBSNS to VBUS with a 3.6k resistor, as shown
in Figure 3. If the USB On-The-Go step-up regulator is
not used in the application, it is also possible to connect
WALLSNS to VBUS through 3.6k and leave USBSNS open.
100mA Linear Battery Charger Mode
The LTC4155 features a mode to support USB low power
operation. Total input current to the LTC4155 is guaranteed
to remain below 100mA in this mode when the recommended resistor is used on the CLPROG2 pin. The stepdown switching regulator does not operate in this mode.
Instead, a linear regulator provides power from VBUS to
VOUT and the battery. The linear battery charger follows
the same constant-current/constant-voltage algorithm as
the switching regulator, but regulates input current rather
than battery charge current. The voltage on the CLPROG2
pin represents the input current in this mode, using the
expression:
IVBUS =
VCLPROG2
• (80)
RCLPROG2
Battery charge current is represented by the voltage on
the PROG pin, but it is not regulated in this mode.
ICHARGE =
VPROG
• (1000)
RPROG
VOUT will generally be very close to the battery voltage when
the battery charger is enabled, except when the battery
voltage is very low, the LTC4155 will increase the impedance between VOUT and BATSNS to facilitate instant-on
operation. If the system load plus battery charge current
exceeds the available input current, battery charge current
will be sacrificed to give priority to the load. If the system
load alone exceeds the available input current, VOUT must
fall to the battery voltage so that the battery may provide
the supplemental current.
The battery will charge to the float voltage specified by
the I2C setting VFLOAT[1:0]. See Table 12.
USBGT
USBSNS
OVGCAP
4155 F03
When the battery charger is disabled or terminated, VOUT
will be regulated to 4.35V.
Figure 3. No Overvoltage Protection
4155fc
22
LTC4155
OPERATION
2.5mA Linear Suspend Mode
The LTC4155 can supply a small amount of current from
VBUS to VOUT to power the system and reduce battery
discharge when the product has access to a suspended
USB port. When the system load current is less than the
current available from the suspended USB port, the voltage at VOUT will be regulated to 4.35V. If the system load
current exceeds USB input current limit, the voltage at
VOUT will fall to the battery voltage and any supplemental
current above that available from the USB port will be
supplied by the battery. CLPROG2 will servo to 103mV
in current limit. Battery charging is disabled in suspend
mode. Either the USB or WALL input may utilize this current
limited suspend mode by programming the appropriate
setting in the respective USBILIM or WALLILIM register.
Ideal Diode and Minimum VOUT Controller
The LTC4155 features an ideal diode controller to ensure
that the system is provided with sufficient power even
when input power is absent or insufficient. This requires
an external PMOS transistor with its source connected
to CHGSNS, gate to BATGATE, and drain to BATSNS. The
controller modulates the gate voltage of the PMOS transistor to allow current to flow from the battery to VOUT to
power the system while blocking current in the opposite
direction to prevent overcharging of the battery.
The ideal diode controller has several modes of operation.
When input power is available and the battery is charging,
the PMOS gate will generally be grounded to maximize
conduction between the switching regulator and the battery
for maximum efficiency. If the battery is deeply discharged,
the LTC4155 will automatically increase the impedance
between the switching regulator and the battery enough
to prevent VOUT from falling below approximately 3.5V.
Power to the system load is always prioritized over battery
charge current. Increasing the impedance between VOUT
and the battery does not necessarily affect the battery
charge current, but it may do so for one of the following
two reasons:
1. The charge current will be limited to prevent excessive
power dissipation in the external PMOS as it becomes
more resistive. Charge current reduction begins when
the voltage across the PMOS reaches approximately
250mV, and can reduce the charge current as low as
8% full scale. Maximum power dissipation in the PMOS
is limited to approximately 1W with RPROG = 499Ω.
2. When limited power is available to the switching regulator because either the programmed input current limit
or input undervoltage current limit is active, charge
current will automatically be reduced to prioritize
power delivery to the system at VOUT. VOUT will be
maintained at 3.5V as long as possible without exceeding the input power limitation. If the system load alone
requires more power than is available from the input
after charge current has been reduced to zero, VOUT
must fall to the battery voltage as the battery begins
providing supplemental power.
When input power is available, but the battery charger is
disabled or charging has terminated, VOUT and the battery are normally disconnected to prevent overcharging
the battery. If the power required by the system should
exceed the power available from the input, either because
of input current limit or input undervoltage current limit,
VOUT will fall to the battery voltage and any additional current required by the load will be supplied by the battery
through the ideal diode.
When input power is unavailable, the ideal diode switches
to a low power mode which maximizes conduction and
power transmission efficiency between VOUT and the battery by grounding the PMOS gate.
Finally, when ship-and-store mode is activated, the ideal
diode is shut down and BATGATE is driven to the battery
voltage to prevent conduction through the PMOS. Note
that with a single FET, conduction to VOUT is still possible
through the body connection diode. Refer to Low Power
Ship-and-Store Mode in the Operation section for more
information about this mode.
4155fc
23
LTC4155
OPERATION
Low Power Ship-and-Store Mode
The LTC4155 can reduce its already low standby current
to approximately 1μA in a special mode designed for
shipment and storage. Unlike normal standby mode, in
this mode the external PMOS gate is driven to the battery
voltage to disable FET conduction through the external
PMOS. This mode may be used to cut off all power to
any downstream load on VOUT to maximize battery life
between product manufacture and sale. Note that the bulk
connection inside the external PMOS will provide a conductive path from the battery to VOUT, independent of the
voltage on its gate. To block conduction to VOUT, typically
two PMOS transistors must be connected in series with
either the sources or drains of each device connected in
the center, as shown in Figure 4. If the application does
not require the battery to be isolated from downstream
devices, significant power savings in the LTC4155 may
still be realized by activating this mode.
Ship-and-store mode is armed following the acknowledge
of any data byte written to sub address 0x07 by the I2C
bus master. The contents of the data byte are ignored, but
the full byte and acknowledge clock cycle must be sent.
Ship-and-store mode is activated as VBUS falls below approximately 1V, or immediately if no input power is present
when the I2C command is issued. VBUS quiescent current
falls to nearly zero when power is removed from the USB
and WALL inputs, resulting in a delay of up to several hours
for VBUS to self-discharge to the 1V activation threshold.
Faster activation may be achieved by connecting a 1M
resistor between VBUS and GND. Reading from sub address 0x07 has no effect on arming or activation and the
returned data is undefined, independent of the arming or
activation state.
CHGSNS
LTC4155
BATGATE
BATSNS
+
Once engaged, ship-and-store mode can be disengaged
by applying power to the USB or WALL input or by writing any full data byte and acknowledge clock cycle to sub
address 0x06 if the I2C bus master is still powered.
I2C Interface
The LTC4155 may communicate with a bus master using
the standard I2C 2-wire interface. 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 current sources,
such as the LTC1694 SMBus accelerator, are required
on these lines. The LTC4155 is both a slave receiver and
slave transmitter. The I2C control signals, SDA and SCL,
are scaled internally to the DVCC supply. DVCC should be
connected to the same power supply as the bus pull-up
resistors.
The I2C port has an undervoltage lockout on the DVCC pin.
When DVCC is below approximately 1V, the I2C serial port
is cleared, the LTC4155 is set to its default configuration,
pending interrupts will be cleared, and future interrupts
will be disabled.
Bus Speed
The I2C port is designed to operate at speeds of up to
400kHz. 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.
START and STOP Conditions
A bus master signals the beginning of communications
by transmitting a START condition. A START condition is
generated by transitioning SDA from HIGH to LOW while
SCL is HIGH. The master may transmit either the slave
write or the slave read address. Once data is written to
the LTC4155, the master may transmit a STOP condition which commands the LTC4155 to act upon its new
command set. A STOP condition is sent by the master by
transitioning SDA from LOW to HIGH while SCL is HIGH.
4155 F04
Figure 4. Ship-and-Store Mode Required Components
to Enforce Downstream (VOUT) Shutdown
24
4155fc
LTC4155
OPERATION
Byte Format
Each frame sent to or received from the LTC4155 must
be eight bits long, followed by an extra clock cycle for the
acknowledge bit. The data should be sent to the LTC4155
most significant bit (MSB) first.
Master and Slave Transmitters and Receivers
Devices connected to an I2C bus may be classified as
either master or slave. A typical bus is composed of one
or more master devices and a number of slave devices.
Some devices are capable of acting as either a master or
a slave, but they may not change roles while a transaction
is in progress.
The transmitter/receiver relationship is distinct from that
of master and slave. The transmitter is responsible for
control of the SDA line during the eight bit data portion
of each frame. The receiver is responsible for control of
SDA during the ninth and final acknowledge clock cycle
of each frame.
All transactions are initiated by the master with a START
or repeat START condition. The master controls the active
(falling) edge of each clock pulse on SCL, regardless of its
status as transmitter or receiver. The slave device never
brings SCL LOW, but may extend the SCL LOW time to
implement clock stretching if necessary. The LTC4155
does not clock stretch and will never hold SCL LOW under
any circumstance.
The master device begins each I2C transaction as the
transmitter and the slave device begins each transaction
as the receiver. For bus write operations, the master acts
as the transmitter and the slave acts as receiver for the
duration of the transaction. For bus read operations, the
master and slave exchange transmit/receive roles following
the address frame for the remainder of the transaction.
Acknowledge
The acknowledge signal (ACK) is used for handshaking
between the transmitter and receiver. When the LTC4155
is written to, it acknowledges its write address as well as
the subsequent data bytes as a slave receiver. When it is
read from, the LTC4155 acknowledges its read address
as a slave receiver. The LTC4155 then changes to a slave
transmitter and the master receiver may optionally acknowledge receipt of the following data byte from the LTC4155.
The acknowledge related clock pulse is always generated by
the bus master. The transmitter (master or slave) releases
the SDA line (HIGH) during the acknowledge clock cycle.
The receiver (slave or master) pulls down the SDA line
during the acknowledge clock pulse so that it is a stable
LOW during the HIGH period of this clock pulse.
When the LTC4155 is read from, it releases the SDA line
after the eighth data bit so that the master may acknowledge receipt of the data. The I2C specification calls for a
not acknowledge (NACK) by the master receiver following
the last data byte during a read transaction. Upon receipt
of the NACK, the slave transmitter is instructed to release
control of the bus. Because the LTC4155 only transmits
one byte of data under any circumstance, a master acknowledging or not acknowledging the data sent by the
LTC4155 has no consequence. The LTC4155 will release
the bus in either case.
Slave Address
The LTC4155 responds to a 7-bit address which has been
factory programmed to 0b0001_001[R/W]. The LSB of
the address byte, known as the read/write bit, should be
0 when writing data to the LTC4155, and 1 when reading
data from it. Considering the address an 8-bit word, then
the write address is 0x12, and the read address is 0x13.
The LTC4155 will acknowledge both its read and write
addresses.
Sub Addressed Access
The LTC4155 has four command registers for control
input and three status registers for status reporting. They
are accessed by the I2C port via a sub addressed pointer
system where each sub address value points to one of
the seven control or status registers within the LTC4155.
The sub address pointer is always the first byte written
immediately following the LTC4155 write address during bus write operations. The sub address pointer value
persists after the bus write operation and will determine
which data byte is returned by the LTC4155 during any
4155fc
25
LTC4155
OPERATION
subsequent bus read operations. The sub address pointer
register is equivalent to the command code byte within
the SMBus write byte and read byte protocols explained
in detail under the SMBus Protocol Compatibility section.
Bus Write Operation
The bus master initiates communication with the LTC4155
with a START condition and the LTC4155’s write address.
If the address matches that of the LTC4155, the LTC4155
returns an acknowledge. The bus master should then deliver
the sub address. The sub address value is transferred to a
special pointer register within the LTC4155 upon the return
of the sub address acknowledge bit by the LTC4155. If the
master wishes to continue the write transaction, it may
then deliver the data byte. The data byte is transferred
to an internal pending data register at the location of the
sub address pointer when the LTC4155 acknowledges the
data byte. The LTC4155 is then ready to receive a new sub
address, optionally repeating the [SUB ADDRESS][DATA]
cycle indefinitely. After the write address, the odd position
bytes always represent a sub address pointer assignment
and the even position bytes always represent data to
be stored at the location referenced by the sub address
pointer. The master may terminate communication with
the LTC4155 after any even or odd number of bytes with
either a repeat START or a STOP condition. If a repeat
START condition is initiated by the master, the LTC4155,
or any other chip on the I2C bus, can then be addressed.
The LTC4155 will remember, but not act on, the last input
of valid data that it received at each sub address location.
This cycle can also continue indefinitely. Once all chips
on the bus have been addressed and sent valid data, a
global STOP can be sent and the LTC4155 will immediately
update all of its command registers with the most recent
pending data that it had previously received. This delayed
execution behavior is compliant with the PMBus group
command protocol.
Bus Read Operation
The LTC4155 contains seven readable registers. Three
are read only and contain status information. Four contain
control information which may be both written and read
back by the bus master.
Only one of the seven sub addressed data registers is accessible during each bus read operation. The data returned
by the LTC4155 is from the data register pointed to by the
contents of the sub address pointer register. The pointer
register contents are determined by the most recent previous bus write operation.
In preparation for a bus read operation, it may be advantageous for a bus master to prematurely terminate a
write transaction with a STOP or repeat START condition
after transmitting only an odd number of bytes. The last
transmitted byte then represents a pointer to the register
of interest for the subsequent bus read operation.
The bus master reads status data from the LTC4155
with a START or repeat START condition followed by the
LTC4155 read address. If the read address matches that
of the LTC4155, the LTC4155 returns an acknowledge.
Following the acknowledgement of its read address, the
LTC4155 returns one bit of status information for each of
the next eight clock cycles from the register selected by
the sub address pointer. Additional clock cycles from the
master after the single data byte has been read will leave
the SDA line high (0xFF transmitted). The LTC4155 will
never acknowledge any bytes during a bus read operation
with the exception of its read address.
To read the same register again, the transaction may be
repeated starting with a START followed by the LTC4155
read address. It is not necessary to rewrite the sub address
pointer register if the sub address has not changed. To read
a different register, a write transaction must be initiated
with a START or repeat START followed by the LTC4155
write address and sub address pointer byte before the
read transaction may be repeated.
When the contents of the sub address pointer register
point to a writeable command register, the data returned
in a bus read operation is the pending command data at
that location if it had been modified since the last STOP
condition. After a STOP condition, all pending data is
copied to the command registers for immediate effect. The
contents of several writeable registers within the LTC4155
are modified upon removal of input power without an I2C
transaction. USBILIM[4:0] and WALLILIM[4:0] default
to either 100mA mode (0x00) or CLPROG1 mode (0x1F)
4155fc
26
LTC4155
OPERATION
as explained in the Alternate Default Input Current Limit
section of Operation. Thus, the contents of these registers
may be different from the last value written by the bus
master, and reading back the contents may be useful to
determine the state of the system.
When the contents of the sub address pointer register
point to a read-only status register, the data returned is a
snapshot of the state of the LTC4155 at a particular instant
in time. If no interrupt requests are pending, the status
data is sampled when the LTC4155 acknowledges its read
address, just before the LTC4155 begins data transmission during a bus read operation. When an unmasked
interrupt event takes place, the IRQ pin is driven low and
data is latched in the three read-only status registers at
that moment. Any subsequent read operation from any
status registers will return this frozen data to facilitate
determination of the cause of the interrupt request. After
the bus master clears the LTC4155 interrupt request, the
status latches are cleared. Bus read operations will then
again return either a snapshot of the data at the read address acknowledge, or at the time of the next interrupt
assertion, whichever comes first.
SMBus Protocol Compatibility
The SMBus specification is generally compatible with the
I2C bus specification, but extends beyond I2C to define and
standardize specific protocol formats for various types of
transactions. The LTC4155 I2C interface is fully compatible
with four of the protocols defined by the SMBus specification. All control and status features of the LTC4155
can be accessed using the SMBus protocols, although if
high bus utilization is a concern, certain operations can
be accomplished more efficiently by I2C bus operations
that do not adhere to any of the SMBus defined protocols.
SMBus Write Byte Protocol
1
7
S
SLAVE
ADDRESS
1
1
WR A
8
1
8
1
1
COMMAND
CODE
A
DATA BYTE
A
P
The SMBus write byte protocol can be used to modify the
contents of any single control register in the LTC4155. The
transaction is initiated by the bus master with a START
condition. The SMBus slave address corresponds to the
LTC4155 write address, which is 0x09 when interpreted
as a 7-bit word (0b 000 1001), followed by WR (value
0b0). The LTC4155 will acknowledge its write address. The
SMBus command code corresponds to the sub address
pointer value and will be written to the sub address pointer
register in the LTC4155. Only the register locations with
write access (0x00 to 0x02, 0x06 to 0x07) are meaningful
values for the sub address pointer when using this protocol.
The LTC4155 will acknowledge the SMBus command code
byte. The SMBus data byte corresponds to the command
data to be written to the location pointed to by the sub
address pointer register. The LTC4155 will acknowledge
the SMBus data byte. The STOP condition at the end of the
sequence will force an update to the command registers,
causing the new command data to take immediate effect.
SMBus Read Byte Protocol
1
S
7
1 1
8
1 1
7
1 1
8
1 1
SLAVE WR A COMMAND A Sr SLAVE RD A DATA A P
ADDRESS
CODE
ADDRESS
BYTE
The SMBus read byte protocol can be used to read the
contents of any one of the seven control or status registers with one bus transaction. The transaction is initiated
by the bus master with a START condition. The SMBus
slave address corresponds to the LTC4155 write address,
which is 0x09 when interpreted as a 7-bit word (0b 000
1001), followed by WR (value 0b0). The LTC4155 will
acknowledge its write address. The SMBus command
code corresponds to the sub address pointer value and
will be written to the sub address pointer register in the
LTC4155. The LTC4155 will acknowledge the SMBus
command code byte. The master then issues a repeat
START condition, followed by the LTC4155 slave address
(0x09) and RD (0b1). The LTC4155 will acknowledge
its read address. At this time the bus master becomes
a receiver while continuing to clock SCL. The LTC4155
becomes a slave transmitter and controls SDA to place
data on the bus. Following the single data byte, the bus
master has the option of transmitting either an ACK or
a NACK bit. According to the I2C specification, a master
must transmit a NACK at the end of a read transaction to
instruct the slave to terminate data transmission. Because
the LTC4155 terminates data transmission after one byte
in all cases, whether the bus master transmits an ACK or
4155fc
27
LTC4155
OPERATION
a NACK is irrelevant. Finally, a STOP condition returns the
bus to the idle state.
SMBus Send Byte Protocol
1
7
S
SLAVE ADDRESS
1
1
WR A
8
1
1
DATA BYTE
A
P
The SMBus send byte protocol can be used to modify
the contents of the sub address pointer register without
modifying the contents of any control registers. It has utility when preparing to later read status information from
the LTC4155 using the SMBus receive byte protocol. The
transaction is initiated by the bus master with a START
condition. The SMBus slave address corresponds to the
LTC4155 write address, which is 0x09 when interpreted as
a 7-bit word (0b 000 1001) followed by WR (value 0b0).
The LTC4155 will acknowledge its write address. The
SMBus data byte corresponds to the sub address pointer
value and will be written to the sub address pointer register
in the LTC4155. Note that the data byte in this protocol
is analogous to the command code in the write byte and
read byte protocols. The LTC4155 will acknowledge the
SMBus data byte. Finally, a STOP condition returns the
bus to the idle state.
SMBus Receive Byte Protocol
1
7
S
SLAVE ADDRESS
1
1
RD A
8
1
1
DATA BYTE
A
P
The SMBus receive byte protocol can be used to read
the contents of the command or status register already
selected by the sub address pointer register. This protocol
is incapable of modifying the contents of the sub address
pointer register, but may be useful to poll a single status
register repeatedly with much less bus overhead than the
other SMBus protocols. The sub address pointer register
can be modified by any of the SMBus write byte, read
byte or send byte protocols and the register contents
will persist until they are modified again by one of these
three protocols.
The receive byte transaction is initiated by the bus master
with a START condition. The SMBus slave address corre-
sponds to the LTC4155 read address, which is 0x09 when
interpreted as a 7-bit word (0b 000 1001), followed by
RD (value 0b1). The LTC4155 will acknowledge its read
address. At this time the bus master becomes a receiver
while continuing to clock SCL. The LTC4155 becomes a
slave transmitter and controls SDA to place data on the
bus. Following the single data byte, the bus master has
the option of transmitting either an ACK or a NACK bit.
According to the I2C specification, a master must transmit a NACK at the end of a read transaction to instruct
the slave to terminate data transmission. Because the
LTC4155 terminates data transmission after one byte in
all cases, whether the bus master transmits an ACK or a
NACK is irrelevant. Finally, a STOP condition returns the
bus to the idle state.
Programmable Interrupt Controller
The LTC4155 can optionally generate active LOW, leveltriggered interrupt requests on the IRQ pin in response
to a number of status change or fault events. The three
available bytes of status information are also frozen at
the time the interrupt is triggered to aid in determining
the cause of a transient interrupt. The contents of the
four writeable command registers are never frozen by
interrupts. The interrupt trigger events are grouped into
six individually maskable categories corresponding to
battery charger status, faults, input power detection, USB
On-The-Go, input current limit and input undervoltage current limit. The interrupt mask register (IMR) is located at
sub address location 0x06, with the six most significant
bits representing the mask programming. Refer to Table 3.
Table 4 lists the status triggers for each interrupt category.
Upon power-up, all interrupts default to disabled (masked).
Each interrupt category may be enabled by writing a “1”
to the appropriate position in the IMR. Any data written to
sub address 0x06 also has the side effect of clearing the
pending interrupt upon the acknowledge bit of the data
(third) byte. Clearing the interrupt releases the IRQ pin
and resumes status reporting of live data until the next
interrupt. If no change to the interrupt mask is desired, the
bus master must rewrite the previous data to sub address
0x06 to clear an interrupt request.
4155fc
28
LTC4155
OPERATION
Table 8, where the 500mA and 900mA settings also correspond to USB compatible current limits. If input power is
removed and reapplied, the LTC4155 will once again default
to 100mA mode until commanded to do otherwise by I2C.
Table 3. Interrupt Mask Register
INTERRUPT MASK REGISTER (IMR)
SUB ADDRESS
0x06
DIRECTION
REG6
Write/Clear Interrupt, Read
D7
ENABLE_CHARGER_INT
D6
D5
D4
D3
D2
D1
D0
1
ENABLE_FAULT_INT
1
ENABLE_EXTPWR_INT
1
ENABLE_OTG_INT
1
ENABLE_AT_ILIM_INT
1
ENABLE_INPUT_UVCL_INT
The resistor should be sized using the following equation:
1
RCLPROG1 =
Table 4. Interrupt Trigger Sources
MASK CATEGORY
If the 100mA USB default current limit is insufficient for
the application and USB compliance is not necessary, an
alternate non-USB compliant default input current may
be programmed with a second resistor on the CLPROG1
pin, as shown in Figure 6.
STATUS TRIGGERS
STATUS
REGISTERS
ENABLE_CHARGER_INT
CHARGER_STATUS[2:0]
0x03
ENABLE_FAULT_INT
OVP_ACTIVE
BAD_CELL
OTG_FAULT
NTC_HOT_FAULT
0x03
0x04
ENABLE_EXTPWR_INT
USBSNS_GOOD
WALLSNS_GOOD
EXT_PWR_GOOD
0x04
ENABLE_OTG_INT
OTG_ENABLED
ID_PIN_DETECT
0x03
ENABLE_AT_ILIM_INT
AT_INPUT_ILIM
0x04
ENABLE_INPUT_UVCL_INT
INPUT_UVCL_ACTIVE
0x04
Alternate Default Input Current Limit
For USB compatible operation, connect both the CLPROG1
and CLPROG2 pins to a single 1.21k 1% resistor, as
shown in Figure 5. When input power is applied, the
LTC4155 will default to the 100mA input current limit
mode. The I2C bus master may then subsequently change
the input current limit to any of the other modes listed in
1.200V
• (991)
IVBUSLIM – IVBUSQ
(
)
When input power is applied, the LTC4155 will default
to the current limit set by the resistor connected to the
CLPROG1 pin. The I2C bus master may then subsequently
change the input current limit to any of the other modes
listed in Table 8, which require a second 1.21k programming resistor on the CLPROG2 pin. The I2C master may
also change back to the default input current limit at any
time by setting the appropriate USBILIM or WALLILIM
bits to the CLPROG1 mode. If input power is removed
and reapplied at any time, the LTC4155 will again default
to the CLPROG1 custom input current limit.
The contents of USBILIM[4:0] and WALLILIM[4:0] always
contain the currently selected input current modes, which
may be different from the data last written by the I2C bus
master if input power was subsequently removed or was
not present. The I2C bus master can read the above two
registers at any time to determine the active input current
limit mode.
LTC4155
LTC4155
CLPROG1
CLPROG1
CLPROG2
CLPROG2
4155 F06
4155 F05
R1
Figure 5. USB Default Input Current Limit
R2
Figure 6. Non-USB Default Input Current Limit
4155fc
29
LTC4155
OPERATION
Battery Charger Operation
The LTC4155 contains a fully featured constant-current/
constant-voltage Li-Ion/Li-Polymer battery charger with
automatic recharge, bad cell detection, trickle charge,
programmable safety timer, thermistor temperature
qualified charging, programmable end-of-charge indication, programmable float voltage, programmable charge
current, detailed I2C status reporting, and programmable
interrupt generation.
Precharge/Low Battery
The upper limit of charge current is programmed by the
combination of a resistor from PROG to ground and the
PROG servo voltage value set in the I2C port. The maximum
charge current will be given by the following expression:
ICHARGE =
VPROG
• 1000
RPROG
VPROG can be set by the I2C port and ranges from 150mV
to 1.2V in 75mV steps. The default value of VPROG is 1.2V.
VPROG is controlled by bits ICHARGE[3:0] located at sub
address 0x02. See Table 11.
When a battery charge cycle begins, the battery charger
first determines if the battery is deeply discharged. If the
battery voltage is below VTRKL, typically 2.8V, the LTC4155
will report the LOWBAT condition via I2C (see Table 18).
If the low battery voltage persists for more than one-half
hour, the battery charger automatically terminates and
indicates via the I2C port that the battery was unresponsive. When the battery voltage is low, charge current is
reduced, both to protect the battery and to prevent excessive power dissipation in the external PMOS transistor.
Figure 1 shows the relationship between battery voltage
and charge current reduction. When input power (USB
or WALL) is unavailable, the I2C LOWBAT indication will
always be true, independent of the actual state of charge
of the battery and can be disregarded.
Recall, however, that in some cases the actual battery
charge current, IBAT, will be lower than the programmed
current, ICHARGE, due to limited input power available and
prioritization of the system load drawn from VOUT. RPROG
should be set to match the capacity of the battery without
regard to input power limitations.
Constant-Current
Constant-Voltage
When the battery voltage is above approximately 3.3V, the
charger will attempt to deliver the programmed charge current in constant-current mode. Depending on available input
power and external load conditions, the battery charger
may or may not be able to charge at the full programmed
rate. The external load will always be prioritized over the
battery charge current. Likewise, the USB and WALL input
current limit programming will always be observed and
only additional power will be available to charge the battery. When system loads are light, battery charge current
will be maximized.
Once the battery terminal voltage reaches the preset float
voltage, the battery charger will hold the voltage steady
and the charge current will decrease naturally toward
zero. Four voltage settings are available for final float
voltage selection via the I2C port using bits VFLOAT[1:0]
(Table 12). For applications that require as much run time
as possible, the 4.200V setting can be selected. For applications that seek to reduce battery aging or tolerate wider
temperature extremes, the LTC4155 features alternate
voltage settings as low as 4.050V.
In either the constant-current or constant-voltage charging
modes, the voltage at the PROG pin will be proportional
to the actual charge current delivered to the battery. The
charge current can be determined at any time by monitoring
the PROG pin voltage and using the following relationship:
IBAT =
VPROG
• 1000
RPROG
4155fc
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LTC4155
OPERATION
Full Capacity Charge Indication (C/x)
Automatic Recharge
Since the PROG pin always represents the actual charge
current flowing, even in the constant-voltage phase of
charging, the PROG pin voltage represents the battery’s
state-of-charge during that phase. The LTC4155 has a
full capacity charge indication comparator on the PROG
pin which reports its results via the I2C port. Selection
levels for the C/x comparator of 24mV, 60mV, 120mV
and 240mV are available by I2C control bits CXSET[1:0]
(Table 13). Recall that the PROG pin servo voltage can be
programmed between 150mV to 1.2V. If the 1.2V servo
setting represents the full-charge rate of the battery (1C),
then the 120mV C/x setting would be equivalent to C/10.
Likewise, the 240mV C/x setting would represent C/5, the
24mV setting C/50 and the 60mV C/20. C/x indication is
masked unless the battery charger is in constant-voltage
mode to prevent false indication caused by limited input
power.
After the battery charger terminates, it will remain off,
drawing only single microamperes 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 VRECHRG (typically 97.6% of the programmed
VFLOAT). The termination safety timer will also reset back
to zero. To prevent brief excursions below VRECHRG from
resetting the safety timer, the battery voltage must be
below VRECHRG for more than 2.5ms. A new charge cycle
will also be initiated if input (USB or WALL) power is
cycled or if the charger is momentarily disabled using the
I2C port. The flow chart in Figure 7 represents the battery
charger’s algorithm.
Charge Termination
The battery charge cycle is terminated either at the expiration of a built-in programmable termination safety timer, or
optionally at the full capacity charge indication (C/x). When
the voltage on the battery reaches the user-programmed
float voltage, the safety timer is started and the C/x comparator is enabled. 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
of four hours may be altered from one to eight hours in
four settings using the I2C bit TIMER[1:0] (Table 10). The
eight hour timer termination setting will also terminate the
charge cycle before the expiration of the eight hour timer
when the battery charge current falls to the programmed
full capacity (C/x) charge indication threshold.
NTC Thermistor Monitor
The LTC4155 includes a 7-bit expanded scale analog to
digital converter (ADC) to monitor the battery temperature
using an external negative temperature coefficient (NTC)
thermistor placed close to the battery pack. To use this
feature, connect the thermistor, RNTC, between the NTC pin
and ground, and a bias resistor, RBIAS, between NTCBIAS
and NTC, as shown in Figure 8. RBIAS should be a 1%
resistor with a value equal to the value of the chosen NTC
thermistor at 25°C (r25).
The thermistor measurement result is available via I2C port
status reporting, except when the ship-and-store feature
has been activated. When not in ship-and-store mode, the
thermistor is automatically measured approximately every
2.4 seconds. The thermistor measurement result available to the I2C port is updated at the end of each sample
period. The low duty cycle of thermistor bias reduces
4155fc
31
LTC4155
OPERATION
POWER AVAILABLE
CLEAR LOW BATTERY
AND SAFETY TIMERS
NTC OUT-OF-RANGE
YES
PAUSE SAFETY TIMER
NO
INDICATE NTC FAULT
VBAT < 2.8V
TRICKLE CHARGE (8%)
VBAT > VFLOAT – J
VBAT
2.8V < VBAT < VFLOAT – J
INDICATE LOW CELL VOLTAGE
CHARGE AT
CONSTANT CURRENT
CHARGE AT
FIXED VOLTAGE
RUN LOW BATTERY TIMER
PAUSE SAFETY TIMER
RUN SAFETY TIMER
TIMER > 30 MINUTES
INDICATE
CONSTANT CURRENT
SAFETY TIMER
EXPIRED
NO
NO
YES
YES
IBAT < C/x
STOP CHARGING
NO
STOP CHARGING
INDICATE CONSTANT
VOLTAGE, I > C/x
VBAT RISING
THROUGH VRECHRG
INDICATE BATTERY FAULT
YES
YES
INDICATE CHARGING
STOPPED
INDICATE CONSTANT
VOLTAGE, I < C/x
NO
VBAT > 2.8V
YES
NO
BAT FALLING
THROUGH VRECHRG
YES
VBAT < VRECHRG
NO
NO
YES
TIMER IN 8 HOUR C/x MODE
NO
YES
4155 F07
Figure 7. Battery Charger Flow Chart
LTC4155
NTCBIAS
RBIAS
NTC
T RNTC
4155 F08
Figure 8. Standard Thermistor Network
4155fc
32
LTC4155
OPERATION
thermistor current, and its associated battery drain by a
factor of 2000 from its DC value. A typical network using
a 10k thermistor causes 115nA of battery drain. A 100k
thermistor would reduce this drain to 11.5nA.
To improve measurement resolution over the temperature
range of interest, the full-scale range of the analog-todigital converter is restricted to the range 0.113 to 0.895
NTCBIAS. The NTC ADC result can be interpreted as follows:
αT ≡
• NTCVAL + κOFFSET
rT
κ
= SPAN
r25 1− κSPAN • NTCVAL – κOFFSET
where NTCVAL is the decimal representation of the
NTCVAL[6:0] status report in the range [0-127], ADC constant κSPAN = 0.006162, ADC constant κOFFSET = 0.1127,
rT is the resistance of the thermistor at temperature T,
and αT is the resistance ratio of the thermistor at the two
temperatures T and 25°C.
Thermistor manufacturer data sheets will either provide a
temperature lookup table relating αT to T, or will supply a
curve fit parameter β which can be used with the following equations to determine the thermistor temperature:
T=
T=
β
ln (α Τ ) +
β
T0
β
⎛ κSPAN • NTCVAL + κOFFSET ⎞ β
ln ⎜
⎟+
⎝ 1− κSPAN • NTCVAL – κOFFSET ⎠ T0
where:
T = Temperature result expressed in Kelvin
T0 = Thermistor model nominal temperature, expressed
in Kelvin. Typically 298.15K (25°C + 273.15°C)
β = Thermistor model material constant, expressed in
Kelvin.
In addition to thermistor value reporting, the LTC4155
automatically pauses battery charging if the thermistor
reading falls outside of limits corresponding to the
range 0°C to 40°C for a Vishay curve 2 thermistor. The
NTC_TOO_COLD and NTC_TOO_WARM conditions
are encoded in the I2C status report NTCSTAT[1:0].
CHARGER_STATUS[2:0] will also report temperature
warnings and faults when the battery charger is enabled.
See Table 14 and Table 17. Optionally, a charger status
interrupt request may be generated when the thermistor
reading enters or exits this temperature range.
If the temperature reading is above a limit corresponding
to 60°C for a Vishay curve 2 thermistor, an optional
NTC_HOT_FAULT interrupt may be generated. In addition,
the overtemperature battery conditioner may be enabled
by I2C to minimize the time that the battery is exposed
simultaneously to high temperature and high voltage.
Refer to the Overtemperature Battery Conditioner section
for more detail.
The NTC_TOO_COLD temperature indication is triggered
when NTCVAL rises to decimal result 102. This corresponds to a αCOLD,WARNING = 2.86 and 0°C for a Vishay
curve 2 thermistor. The low temperature indication is
cleared when the NTCVAL falls to decimal result 98. This
corresponds to αCOLD,RESET = 2.53 and 2°C for a Vishay
curve 2 thermistor.
The NTC_TOO_WARM temperature indication is triggered
when NTCVAL falls to decimal result 41. This corresponds
to αWARM,WARNING = 0.576 and 40°C for a Vishay curve 2
thermistor. The high temperature indication is cleared
when NTCVAL rises to decimal result 45. This corresponds
to αWARM,RESET = 0.639 and 37°C for a Vishay curve 2
thermistor.
The NTC_HOT_FAULT temperature indication is triggered
when NTCVAL falls to decimal result 19. This corresponds to αCRITICAL,FAULT = 0.298 and 60°C for a Vishay
4155fc
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LTC4155
OPERATION
curve 2 thermistor. The critically hot temperature indication is cleared when NTCVAL rises to decimal result 23.
This corresponds to αCRITICAL,RESET = 0.341 and 55.5°C
for a Vishay curve 2 thermistor.
It is possible to modify the thermistor bias network to
adjust either one or two of the above temperature thresholds. Because of the limited degrees of freedom in the
bias network, the remaining temperature threshold(s) will
then be constrained by the chosen network and thermistor
properties. See Alternate NTC Thermistors and Biasing in
the Applications Information section for implementation
details.
Overtemperature Battery Conditioner
Since Li-Ion batteries deteriorate with full voltage and
high temperature, the LTC4155 contains an automatic
battery conditioner circuit that reduces the battery voltage if both high temperature and high voltage are present
simultaneously.
Recall that battery charging is inhibited if the thermistor
temperature reaches 40°C. If the thermistor temperature
climbs above 60°C, and the battery conditioner circuit
is enabled, an internal load of approximately 125mA is
applied to BATSNS. Once the battery voltage drops to
3.9V, or the thermistor reading drops below 55.5°C, the
internal load is disabled. Battery charging resumes once
the thermistor temperature drops below 37°C.
When activated via the I2C port, the battery conditioner
operates whether or not external power is available,
charging has terminated or charging has been disabled
by I2C control. The battery conditioner is controlled by
the EN_BAT_CONDITIONER bit located at I2C sub address
0x00 (Table 6).
Note that this circuit can dissipate significant power inside
the LTC4155. To prevent an excessive temperature rise of
the LTC4155, the LTC4155 reduces discharge current as
needed to prevent a junction temperature rise above 120°C.
4155fc
34
LTC4155
OPERATION
Table 8. Input Current Limit Settings
Table 5. Input Undervoltage Current Limit Control
INPUT UNDERVOLTAGE CURRENT LIMIT CONTROL
SUB ADDRESS
0x00
REG0
DISABLE_INPUT_UVCL
DIRECTION
Write and Readback
D7
Enabled*
0
Disabled
1
D6
D5
D4
D3
D2
D1
D0
*Default setting
Table 6. Overtemperature Battery Conditioner
OVERTEMPERATURE BATTERY CONDITIONER
0x00
EN_BAT_CONDITIONER
DIRECTION
EN_CONDITIONER
REG0
Write and Readback
D7
Disabled*
Enabled Above
60°C
D6
D5
D4
D3
D2
D1
D0
Wall Input Current Limit WALLILIM[4:0]
D7
D6
D5
D4
D3
D2
D1
D0
100mA Max
(USB Low Power)*
0
0
0
0
0
500mA Max
(USB High Power)
0
0
0
0
1
600mA Max
0
0
0
1
0
700mA Max
0
0
0
1
1
800mA Max
0
0
1
0
0
900mA Max
(USB 3.0)
0
0
1
0
1
0
1
1
0
1250mA Typical
0
0
1
1
1
1
1500mA Typical
0
1
0
0
0
1750mA Typical
0
1
0
0
1
2000mA Typical
0
1
0
1
0
2250mA Typical
0
1
0
1
1
2500mA Typical
0
1
1
0
0
2750mA Typical
0
1
1
0
1
3000mA Typical
0
1
1
1
0
2.5mA Max
(USB Suspend)
0
1
1
1
1
SELECT
CLPROG1**
1
1
1
1
1
0x00
REG0
LOCKOUT_ID_PIN
DIRECTION
Write and Readback
D7
WALLILIM
USBILIM
Write and Readback
0
USB On-The-Go ID PIN AUTONOMOUS START-UP
D6
D5
Autonomous
Start-Up Allowed*
0
Autonomous
Start-Up Disabled
1
*Default setting
USB Input Current Limit USBILIM[4.0]
0x01
1000mA Typical
Table 7. USB On-The-Go ID Pin Autonomous Start-Up
LOCKOUT_ID_PIN
0x00
SUB ADDRESS
0
*Default setting
SUB ADDRESS
REG0, REG1
SUB ADDRESS
DIRECTION
DISABLE_INPUT_
UVCL
SUB ADDRESS
INPUT CURRENT LIMIT SETTINGS
D4
D3
D2
D1
D0
*Default setting CLPROG1 and CLPROG2 shorted. Refer to the Input
Current Regulation section for information when this register is
modified by the LTC4155.
**Default setting two CLPROG resistors. Refer to the Input Current
Regulation section for information when this register is modified by
the LTC4155.
Table 9. Input Connector Priority Swap
INPUT CONNECTOR PRIORITY SWAP
SUB ADDRESS
REG1
0x01
PRIORITY
DIRECTION
Write and Readback
PRIORITY
D7
Wall Input
Prioritized*
0
USB Input
Prioritized
1
D6
D5
D4
D3
D2
D1
D0
*Default setting
4155fc
35
LTC4155
OPERATION
Table 10. Battery Charger Safety Timer
Table 12. Battery Charger Float Voltage
BATTERY CHARGER SAFETY TIMER
SUB ADDRESS
REG1
0x01
TIMER[1:0]
DIRECTION
SUB ADDRESS
D7
D6
D5
0
0
4 Hr*
D4
D3
REG2
0x02
VFLOAT[1:0]
DIRECTION
Write and Readback
TIMER[1:0]
Battery Charger Float Voltage
D2
D1
D0
Write and Readback
BATTERY
VOLTAGE (V)
D3
D2
4.05*
D7
D6
D5
D4
0
0
4.10
0
1
8 Hr or C/x
Indication
0
1
1 Hr
1
0
4.15
1
0
2 Hr
1
1
4.20
1
1
*Default setting.
*Default setting.
Table 11. Battery Charger Current Limit
Table 13. Full Capacity Charge Indication Threshold
BATTERY CHARGER CURRENT LIMIT
SUB ADDRESS
REG2
0x02
D7
D6
D5
D4
D3
D2
0x02
D1
D0
D0
REG2
CXSET[1:0]
DIRECTION
Write and Readback
FULL-SCALE VPROG
CURRENT SERVO
(%)
(V)
FULL CAPACITY CHARGE INDICATION THRESHOLD
SUB ADDRESS
ICHARGE[3.0]
DIRECTION
D1
Write and Readback
FULL-SCALE VPROG
CURRENT THRESHOLD
(%)
(V)
D1
D0
10*
0.120*
D7
D6
D5
D4
D3
D2
0
0
Charger
Disabled
0.000
0
0
0
0
20
0.240
0
1
12.50
0.150
0
0
0
1
2
0.024
1
0
18.75
0.225
0
0
1
0
5
0.060
1
1
25.00
0.300
0
0
1
1
31.25
0.375
0
1
0
0
37.50
0.450
0
1
0
1
43.75
0.525
0
1
1
0
Table 14. Battery Charger Status Report
50.00
0.600
0
1
1
1
BATTERY CHARGER STATUS REPORT
56.25
0.675
1
0
0
0
SUB ADDRESS
62.50
0.750
1
0
0
1
DIRECTION
BATTERY CHARGER
STATUS
D7
D6
D5
Charger Off
0
0
0
Low Battery Voltage
0
0
1
Constant Current
0
1
0
Constant Voltage,
VPROG>VC/X
0
1
1
Constant Voltage,
VPROG<VC/X
1
0
0
NTC TOO WARM,
Charging Paused
1
0
1
NTC TOO COLD,
Charging Paused
1
1
0
NTC HOT FAULT,
Charging Paused
1
1
1
68.75
0.825
1
0
1
0
75.00
0.900
1
0
1
1
81.25
0.975
1
1
0
0
87.50
1.050
1
1
0
1
93.75
1.125
1
1
1
0
100.00*
1.200*
1
1
1
1
*Default setting.
*Default setting.
REG3
0x03
CHARGER_STATUS[2:0]
Read
D4
D3
D2
D1
D0
4155fc
36
LTC4155
OPERATION
Table 15. USB On-The-Go ID Pin Detection
Table 19. External Power (Wall or USB) Available
USB On-The-Go ID PIN DETECTION
SUB ADDRESS
REG3
0x03
ID_PIN_DETECT
DIRECTION
ID PIN STATUS
EXTERNAL POWER (WALL OR USB) AVAILABLE
SUB ADDRESS
Read
D7
D6
D5
No Detection
D4
EXT_PWR_GOOD
DIRECTION
D3
D2
D1
D0
0
ID Pin Shorted to
GND*
0x04
1
*LOCKOUT_ID_PIN has no effect on pin detection.
POWER AVAILABLE
STATUS
REG4
Read
D7
Battery Power
Only
0
External Power
Available*
1
D6
D5
D4
D3
D2
D1
D0
*Never true when On-The-Go step-up converter is active.
Table 16. USB On-The-Go Enabled Status
USB On-The-Go ENABLED STATUS
SUB ADDRESS
REG3
0x03
OTG_ENABLED
DIRECTION
USB INPUT VOLTAGE VALID
Read
STEP-UP REGULATOR
STATUS
D7
D6
D5
D4
SUB ADDRESS
D3
D2
D1
D0
0
Step-Up Switching
Regulator Active
1
NTC THERMISTOR STATUS REPORT
NTCSTAT[1:0]
DIRECTION
D7
D6
USBSNS Voltage
Invalid
0
USBSNS Voltage
Valid*
1
D5
D4
D3
D2
D1
D0
Table 21. WALL Input Voltage Valid
Read
D6
Read
REG3
0x03
D7
USBSNS_GOOD
*Will be true with applied input voltage within valid range or On-The-Go
in regulation.
Table 17. NTC Thermistor Status Report
NTC THERMISTOR
STATUS
REG4
0x04
DIRECTION
USBSNS STATUS
Step-Up Switching
Regulator Inactive
SUB ADDRESS
Table 20. USB Input Voltage Valid
D5
D4
WALL INPUT VOLTAGE VALID
D3
D2
D1
0
0
NTC Normal
NTC_TOO_COLD
0
1
NTC_TOO_WARM
1
0
NTC_HOT_FAULT
1
1
D0
SUB ADDRESS
REG4
0x04
WALLSNS_GOOD
DIRECTION
WALLSNS STATUS
Read
D7
D6
D5
WALLSNS Voltage
Invalid
0
WALLSNS Voltage
Valid
1
D4
D3
D2
D1
D0
Table 18. Low Battery Detection
LOW BATTERY DETECTION
SUB ADDRESS
REG3
0x03
LOWBAT
DIRECTION
BATTERY VOLTAGE
STATUS
INPUT CURRENT LIMIT STATUS
Read
D7
D6
D5
D4
D3
Table 22. Input Current Limit Status
SUB ADDRESS
D2
D1
D0
REG4
0x04
AT_INPUT_ILIM
DIRECTION
INPUT CURRENT
LIMIT STATUS
Read
Normal
0
Low Cell Voltage*
1
Input Current Limit Inactive
0
*Low cell voltage is only meaningful when input (WALL or USB) power
is available and the battery charger is enabled, or when automatic or
manual enable of the step-up regulator has been requested.
Input Current Limit Active
1
D7
D6 D5
D4
D3
D2
D1
D0
4155fc
37
LTC4155
OPERATION
Table 23. Input Undervoltage Current Limit (Brownout) Status
Table 27. NTC Analog-to-Digital Converter Result
INPUT UNDERVOLTAGE CURRENT LIMIT
(BROWNOUT) STATUS
NTC ANALOG-TO-DIGITAL CONVERTER RESULT
SUB ADDRESS
0x04
REG4
INPUT_UVCL_ACTIVE
DIRECTION
D7
D6
D5
D4
D3
Input UVCL Inactive
0
Input UVCL Active
1
D2
D1
D0
REG4
OVP_ACTIVE
DIRECTION
INPUT OVERVOLTAGE
D6
D5
D7
D6
D5
D4
D3
D2
D1
NTCVAL[6:0]*
d
d
d
d
d
d
d
D4
D3
NTC TEMPERATURE OUT OF RANGE FOR
BATTERY CHARGING
SUB ADDRESS
Read
D7
Read
NTC CONVERSION
RESULT
D0
Table 28. NTC Temperature Out of Range for Battery Charging
OVERVOLTAGE PROTECTION FAULT
0x04
NTCVAL[6:0]
See NTC Thermistor Monitor in Operation section to convert ADC result
to temperature.
Table 24. Overvoltage Protection Fault
SUB ADDRESS
0x05
DIRECTION
Read
INPUT UNDERVOLTAGE
CURRENT LIMIT STATUS
SUB ADDRESS
REG5
D2
No Fault
0
Input (USB or WALL)
Overvoltage
1
D1
D0
0x05
REG5
NTC_WARNING
DIRECTION
Read
NTC TEMP RANGE
D7
D6
D5
D4
D3
D2
D1
D0
Temperature Normal
0
Too Warm or Too
Cold to Charge
1
Table 25. USB On-The-Go Step-Up Regulator Fault Shutdown
USB On-The-Go STEP-UP REGULATOR FAULT SHUTDOWN
SUB ADDRESS
0x04
SUB ADDRESS
Read
D7
D6
D5
D4
D3
D2
D1
0
Regulator Over
Current Shutdown
1
D0
BATTERY UNRESPONSIVE TO CHARGING
0x04
REG4
BAD_CELL
DIRECTION
INTERRUPT
ENABLE STATUS
REG6
ENABLE_CHARGER_INT
Write and Readback
D7
Charger Interrupts
Disabled*
0
Charger Interrupts
Enabled
1
D6
D5
D4
D3
D2
D1
D0
*Default.
Table 26. Battery Unresponsive to Charging
BATTERY STATUS
0x06
DIRECTION
No Fault
SUB ADDRESS
Table 29. Battery Charger Interrupt Mask
BATTERY CHARGER INTERRUPT MASK
OTG_FAULT
DIRECTION
STEP-UP
REGULATOR STATUS
REG4
Interrupt triggered by any change in CHARGER_STATUS[2:0].Any data
written to sub address 0x06 has side effect of clearing any pending
interrupt request.
Read
D7
D6
D5
D4
D3
D2
D1
D0
No Fault
0
Low Cell Voltage
Timeout
1
4155fc
38
LTC4155
OPERATION
Table 30. Fault Interrupt Mask
Table 32. USB On-The-Go Interrupt Mask
FAULT INTERRUPT MASK
SUB ADDRESS
REG6
0x06
ENABLE_FAULT_INT
DIRECTION
SUB ADDRESS
Write and Readback
INTERRUPT ENABLE
STATUS
D7
D6
D5
D4
D3
D2
USB On-The-Go INTERRUPT MASK
0x06
ENABLE_OTG_INT
DIRECTION
D1
D0
INTERRUPT ENABLE
STATUS
REG6
Write and Readback
D7
D6
D5
D4
Fault Interrupts
Disabled*
0
USB On-The-Go
Interrupts Disabled*
0
Fault Interrupts
Enabled
1
USB On-The-Go
Interrupts Enabled
1
D3
D2
D1
D0
*Default.
*Default.
Interrupt triggered by any change in OVP_ACTIVE, BAD_CELL, OTG_
FAULT or NTC_HOT_FAULT. Any data written to sub address 0x06 has
side effect of clearing any pending interrupt request.
Interrupt triggered by any change in EN_BOOST, ID_DETECT. Any data
written to sub address 0x06 has side effect of clearing any pending
interrupt request.
Table 31. External Power Available Interrupt Mask
Table 33. Input Current Limit Interrupt Mask
EXTERNAL POWER AVAILABLE INTERRUPT MASK
SUB ADDRESS
0x06
ENABLE_EXTPWR_INT
DIRECTION
INTERRUPT
ENABLE STATUS
REG6
SUB ADDRESS
Write and Readback
D7
D6
D5
External Power
Interrupts
Disabled*
0
External Power
Interrupts Enabled
1
D4
D3
D2
INPUT CURRENT LIMIT INTERRUPT MASK
0x06
ENABLE_AT_ILIM_INT
DIRECTION
D1
*Default.
Interrupt triggered by any change in USBSNSGD, WALLSNSGD, or
EXTPWRGD. Any data written to sub address 0x06 has side effect of
clearing any pending interrupt request.
D0
INTERRUPT
ENABLE STATUS
REG6
Write and Readback
D7
D6
D5
D4
D3
Input Current Limit
Interrupts Disabled*
0
Input Current Limit
Interrupts Enabled
1
D2
D1
D0
*Default.
Interrupt triggered by any change in AT_INPUT_ILIM. Any data written
to sub address 0x06 has side effect of clearing any pending interrupt
request.
4155fc
39
LTC4155
OPERATION
Table 34. Input Undervoltage Current Limit (Brownout
Detection) Interrupt Mask
INPUT UNDERVOLTAGE CURRENT LIMIT (BROWNOUT
DETECTION) INTERRUPT MASK
SUB ADDRESS
0x06
DIRECTION
INTERRUPT ENABLE
STATUS
D7
D6
Table 35. USB On-The-Go Step-Up Voltage Converter
Manual Activation
REG6
USB On-The-Go STEP-UP VOLTAGE CONVERTER MANUAL
ACTIVATION
ENABLE_INPUT_UVCL_INT
SUB ADDRESS
Write and Readback
DIRECTION
D5
D4
D3
D2
Input Undervoltage
Current Limit
Interrupts Disabled*
0
Input Undervoltage
Current Limit
Interrupts Enabled
1
D1
D0
0x06
REG6
REQUEST_OTG
Write and Readback
STEP-UP
REGULATOR
ACTIVATION
D7
D6
D5
D4
D3
D2
D1
Step-Up Regulator
Activation Automatic or Disabled*
0
Enable Step-Up
Voltage Regulator
1
D0
*Default.
*Default.
Interrupt triggered by any change in INPUT_UVCL_ACTIVE. Any data
written to sub address 0x06 has side effect of clearing any pending
interrupt request.
Regulator cannot be activated if voltage is applied to either the USB or
WALL inputs. Automatic activation controlled by LOCKOUT_ID_PIN. Any
data written to sub address 0x06 has side effect of clearing any pending
interrupt request.
APPLICATIONS INFORMATION
Alternate NTC Thermistors and Biasing
The LTC4155 provides temperature qualified charging if a
grounded thermistor and a bias resistor are connected to the
NTC pin. Charging is paused if the temperature rises above
an NTC_TOO_HOT limit or falls below an NTC_TOO_COLD
limit. By using a Vishay curve 2 thermistor and a bias resistor whose value is equal to the room temperature resistance
of the thermistor (r25), the upper and lower temperatures are preprogrammed to approximately 40°C and
0°C, respectively. The NTC_HOT_FAULT threshold which
optionally generates an interrupt and/or enables the
overtemperature battery conditioner is preprogrammed
to approximately 60°C.
With minor modifications to the thermistor bias network
as shown in Figure 9, it is possible to adjust either one or
two of the three temperature thresholds with the constraint
that it is usually not possible to move the temperature
thresholds closer together. Intuitively, this would require
increased temperature sensitivity from the thermistor.
LTC4155
NTCBIAS
RBIAS
NTC
RTEMP_RANGE
T RNTC
4155 F09
Figure 9. Alternate NTC Bias Network
In the explanation below, the following notation is used.
r25
NTC thermistor value at 25°C.
RBIAS
Low drift bias resistor, connected between the
NTCBIAS and NTC pins.
4155fc
40
LTC4155
APPLICATIONS INFORMATION
RTEMP_RANGE
Optional dilution resistor, connected in series with
the thermistor.
r
αT ≡ T
r25
Thermistor resistance ratio at any temperature T relative
to its reference temperature.
α TOO _ COLD ≡
rTOO _ COLD
r25
Thermistor resistance ratio at desired NTC_TOO_COLD
threshold temperature relative to its reference
temperature.
α TOO _ WARM ≡
rTOO _ WARM
r25
Thermistor resistance ratio at desired NTC_TOO_WARM
threshold temperature relative to its reference
temperature.
αHOT _ FAULT
r
≡ HOT _ FAULT
r25
Thermistor resistance ratio at desired NTC_HOT_FAULT
threshold temperature relative to its reference temperature.
R
αBIAS ≡ BIAS
r25
Ratio of low drift bias resistor to r25.
α TEMP _ RANGE ≡
RTEMP _ RANGE
r25
Ratio of optional low drift dilution resistor to r25.
Note that r25, rT, rTOO_COLD, rTOO_WARM, and rHOT_FAULT
and are all resistance values of the thermistor at different
temperatures, while RBIAS and RTEMP_RANGE are actual
low drift resistors.
In all of the following calculations, it will be necessary to
determine the thermistor’s αT at various temperatures.
This parameter is dependent only upon the material properties of the thermistor. αT for a given thermistor and
temperature may be found in one of two ways. Thermistor
manufacturers often provide a lookup table relating αT to
temperature in their data sheets. For any temperature T,
αT may be referenced directly.
The second way to obtain αT for any T requires the use
of a modeling equation and a material constant specific
to the thermistor:
αT
⎡⎛ 1 ⎞ ⎛ 1 ⎞⎤
β⎢⎜ ⎟−⎜⎜ ⎟⎟⎥
⎝ T ⎠ ⎝ T0 ⎠⎥⎦
= e ⎢⎣
where:
e = Natural logarithm base, approximately 2.71828
T = Temperature of interest, expressed in Kelvin
T0 = Thermistor model nominal temperature, expressed
in Kelvin. Typically 298.15K (25°C + 273.15°C)
β = Model material constant, expressed in Kelvin. This
model is a curve fit at T0 and a second temperature. β is
close to 4000K for most thermistors. Higher β results in
increased temperature sensitivity at the expense of reduced
linearity over a wide temperature range
Simple Alternate Thermistor Bias Network
By simply adjusting the bias resistor, RBIAS, and omitting
the optional RTEMP_RANGE, one of the three temperature
thresholds may be adjusted. The other two temperature
comparator thresholds will be determined by the choice
of the first temperature threshold and the NTCVAL
thresholds fixed in the LTC4155. Increasing RBIAS above
r25 shifts all three temperature thresholds colder while
simultaneously slightly compressing the temperature span
between thresholds. Likewise, decreasing RBIAS below
r25 shifts all three temperature thresholds warmer while
simultaneously slightly expanding the temperature span
between thresholds. To program a single temperature
threshold, obtain the value of either α TOO_COLD,
αTOO_WARM or αHOT_FAULT for the chosen temperature
threshold using one of the aforementioned methods and
4155fc
41
LTC4155
APPLICATIONS INFORMATION
substitute into the appropriate following equation to calculate the value αBIAS and then RBIAS.
αBIAS = 0.34917 • αTOO_COLD
To specify TTOO_COLD and TTOO_WARM, then calculate
THOT_FAULT:
αBIAS = 1.73735 • αTOO_WARM
αTEMP_RANGE = 0.25153 • αTOO_COLD – 1.25153
• αTOO_WARM
αBIAS = 3.35249 • αHOT_FAULT
RTEMP_RANGE = αTEMP_RANGE • r25
RBIAS = αBIAS • r25
αBIAS = 0.43699 • (αTOO_COLD – αTOO_WARM)
With αBIAS for the newly programmed temperature
threshold now determined, the other two dependent temperature thresholds may be found by substituting αBIAS
into the remaining two equations. The following equation
may be used to convert any other NTC ADC result (NTCVAL)
back to a resistance ratio by substituting the κSPAN and
κOFFSET values found in the Electrical Characteristics table.
RBIAS = αBIAS • r25
⎡ κ
• NTCVAL + κOFFSET ⎤
α T = ⎢ SPAN
⎥αBIAS
⎣ 1− κSPAN • NTCVAL – κOFFSET ⎦
αT may then be used to determine the temperature using
either the lookup table provided by the thermistor manufacturer or the curve fit model:
β
T=
ln (α T )+
β
T0
Advanced Alternate Thermistor Bias Network
If an adjustment to RBIAS does not yield an acceptable span
between temperature thresholds, a second low drift bias
resistor may be added to the bias network between the
NTC pin and the top of the thermistor. This resistor has
the net effect of diluting the high thermal sensitivity of the
thermistor with low drift resistance. The result is reduced
thermal gain and a wider temperature span between the
preprogrammed voltage thresholds of the LTC4155. Using
this additional resistor, two of the three temperature
comparator thresholds may be adjusted. The remaining
threshold is constrained by the limited degrees of freedom
of the bias network. After determining the αT values for
the two temperature thresholds of interest, the following
equations may be used to determine αBIAS, αTEMP_RANGE,
and the third constrained temperature threshold dependent
on the choice of bias network and the thermistor.
With the bias network determined, the overconstrained
threshold may then be calculated:
αHOT_FAULT = 0.29829 • αBIAS – αTEMP_RANGE
To specify TTOO_COLD and THOT_FAULT, then calculate
TTOO_WARM:
αTEMP_RANGE = 0.11626 • αTOO_COLD – 1.11626
• αHOT_FAULT
RTEMP_RANGE = αTEMP_RANGE • r25
αBIAS = 0.38976 • (αTOO_COLD – αHOT_FAULT)
RBIAS = αBIAS • r25
With the bias network determined, the overconstrained
threshold may then be calculated:
αTOO_WARM = 0.57559 • αBIAS – αTEMP_RANGE
To specify TTOO_WARM and THOT_FAULT, then calculate
TTOO_COLD:
αTEMP_RANGE = 1.07566 • αTOO_WARM – 2.07566
• αHOT_FAULT
RTEMP_RANGE = αTEMP_RANGE • r25
αBIAS = 3.60615 • (αTOO_WARM – αHOT_FAULT)
RBIAS = αBIAS • r25
With the bias network determined, the overconstrained
threshold may then be calculated:
αTOO_COLD = 2.863946 • αBIAS – αTEMP_RANGE
It is possible to obtain a negative result for RTEMP_RANGE
which is not physically realizable using the previous equations. A negative result indicates that the two chosen temperature thresholds are too close in temperature and require
more thermal sensitivity than the thermistor can provide.
4155fc
42
LTC4155
APPLICATIONS INFORMATION
⎡ κ
• NTCVAL + κOFFSET ⎤
α T = ⎢ SPAN
⎥αBIAS − α TEMP_ RANGE
⎣ 1− κSPAN • NTCVAL – κOFFSET ⎦
T=
β
⎛⎡ κ
⎞ β
• NTCVAL + κOFFSET ⎤
ln ⎜⎢ SPAN
⎥αBIAS − α TEMP_ RANGE ⎟ +
⎝⎣ 1− κSPAN • NTCVAL – κOFFSET ⎦
⎠ T0
The generalized form of the NTC equations provided in
the Operations section are included above to facilitate
interpretation of the thermistor analog to digital converter
results using the custom bias network. If only RBIAS was
modified, let αTEMP_RANGE = 0.
Choosing the Input Multiplexer/Overvoltage
Protection MOSFETs
The LTC4155 contains an internal charge pump voltage
doubler to drive N-channel MOSFETS via the USBGT and
WALLGT pins. The gate-source voltage available to drive
the input multiplexer/protection FETS is approximately
equal to the input voltage, typically 4V to 6V. To ensure
that the FET channels are sufficiently enhanced to provide
a low resistance conduction path, the FET threshold voltage should be less than approximately 2.5V. Total gate
leakage current should be below 1μA to guarantee ample
charge pump output voltage. The gate oxide breakdown
voltage should be higher than 7V. The FET RDS(ON) will
negatively impact the switching regulator and battery
charger efficiency at high current levels. With two protection FETs in series (MN1 and MN3, MN2 and MN4), the
total resistance is the sum of the individual RDS(ON)s. This
combined resistance should be negligible compared to the
typical 80mΩ to 90mΩ resistance of the LTC4155 internal
switches for maximum performance. The drain breakdown
voltage of devices MN1 and MN2 must be appropriate for
the level of overvoltage protection desired. The drains will
be exposed to the full magnitude of applied input voltage.
The drains of devices MN3 and MN4 are exposed only to
the operating voltage range of the LTC4155. Therefore
the drain breakdown voltage of devices MN3 and MN4
should be rated for at least 7V. Table 36 lists several suitable N-channel transistors. Transistors with lower BVDSS
may be appropriate for devices MN3 and MN4 if reverse
protection is not required. Note that resistors R1 and R2
must also be sized appropriately for power dissipation
based on the level of overvoltage protection desired, as
explained in the Operation section.
Table 36. Recommended N-Channel Input Multiplexer MOSFETs
MANUFACTURER
Fairchild
Fairchild
Vishay
PART
NUMBER
FDMC8651
FDMC8030
Si7938DP
R1
TO WALL
INPUT
TO USB
INPUT
RDS(ON)
(mΩ)
4.3
10.7
5.6
VT (V)
1.1
2.8
2.5
BVDSS (V)
30
40
40
WALLSNS
WALLGT
LTC4155
MN1
MN3
MN2
MN4
R2
VBUS
USBGT
USBSNS
OVGCAP
4155 F10
Figure 10. Dual-Input Overvoltage Protection
Alternate Input Power Configurations
For applications requiring only a single input, the external
circuit required for overvoltage protection is considerably
simplified. Only a single N-channel MOSFET and resistor
are required for positive voltage protection, as shown in
Figure 11, and OVGCAP may be left unconnected. Applications using the USB On-The-Go step-up regulator should
connect R1 to USBSNS and the gate of MN1 to USBGT.
Applications not using USB On-The-Go may use either the
USBSNS/USBGT pins or the WALLSNS/WALLGT pins. The
unused pins may be left unconnected.
For dual-input applications requiring reverse-voltage
protection, no additional power transistors are required.
The circuit in Figure 12 provides positive protection up to
4155fc
43
LTC4155
APPLICATIONS INFORMATION
the drain breakdown voltage rating of MN3 and MN4 and
negative protection down to the drain breakdown voltage rating of MN1 and MN2. Q1 and Q2 are small-signal
transistors to protect the gate oxides of MN1 and MN2.
Note that it is necessary to orient the N-channel MOSFETs
with the drain connections common and the source/body
connections to the input connector and the VBUS pin.
level, but the inductor current will increase rapidly to the
LTC4155’s peak current clamp as incremental inductance
tends toward zero. If an overload condition persists with
a small inductor, it is possible that the inductor could be
damaged by its own resistive temperature rise.
The inductor core should be made from a material such as
ferrite, suitable for switching at 2.25MHz without excessive
hysteretic losses. Table 37 lists several suitable inductors.
WALLSNS
Table 37. Recommended Inductors
WALLGT
RDC IMAX PACKAGE
MANUFACTURER
PART NUMBER
(mΩ) (A)
(mm)
Vishay
IHLP2525AHE-B1ROMO1 17.5 7 6.5 × 6.9 × 3.2
Coilcraft
XFL4020-102ME
10.8 5.4 4 × 4 × 2.1
TDK
TDKLTF5022T1R2N4R2-LF 21 4.2 5 × 5.2 × 2.2
IMAX is the lower of the typical 30% saturation current and self-heating
current specifications.
LTC4155
MN1
TO POWER
INPUT
VBUS
USBGT
R1
USBSNS
OVGCAP
4155 F11
Figure 11. Single-Input Overvoltage Protection
Q3
Q1
R5
47k
R1 3.6k
WALLSNS
R3 5M
TO WALL
INPUT
Choosing the Battery Charger MOSFETs
WALLGT
LTC4155
TO USB
INPUT
MN1
MN3
MN2
MN4
VBUS
R4 5M
R2 3.6k
USBGT
USBSNS
Q4
Q2
R6
47k
OVGCAP
C1
OPT
0.01μF
4155 F12
Figure 12. Dual-Input Positive and Negative Voltage Protection
Choosing the Inductor
The LTC4155 is designed to operate with a 1μH inductor,
with core saturation, winding resistance, and thermal
rise characteristics appropriate for the application’s peak
currents. The inductor current ripple magnitude is approximately 400mA under normal conditions, resulting
in a peak inductor current 200mA higher than the average output current of the switching regulator. The average output current of the step-down regulator is higher
than the average input current by the ratio VBUS /VOUT,
neglecting efficiency losses. The LTC4155 can tolerate
transient excursions beyond the inductor’s core saturation
The LTC4155 requires a single external P-channel MOSFET connected between the CHGSNS and BATSNS pins
to conduct battery charge and ideal diode currents. The
threshold voltage magnitude should be less than approximately 2.5V. (The P-channel threshold might be expressed
as a negative number, VGS(th), or as a positive number
VSG(th)). Gate leakage current should be below 500nA.
Drain voltage breakdown and gate oxide breakdown voltages should both be above 5V in magnitude. The LTC4155
contributes approximately 40mΩ resistance in the current
sense circuitry in series with the battery charger FET.
Channel resistance, RDS(ON), should be small relative to
the 40mΩ for maximum efficiency both charging the battery and delivering power from the battery to the system
load. Table 38 lists several suitable P-channel transistors.
Optionally, a second P-channel MOSFET may be connected in series with the first if the application requires
that power be cut off from any downstream devices on
VOUT in low power ship-and-store mode. Further details
about low power ship-and-store mode may be found in
the Operation section. The requirements for the second
device are the same as those enumerated above, with the
caveats that total gate leakage current is the sum of the
individual leakage currents and total RDS(ON) is the sum
of the individual RDS(ON)s.
4155fc
44
LTC4155
APPLICATIONS INFORMATION
Table 38. Recommended P-Channel Battery Charger MOSFETs
MANUFACTURER
Fairchild
Vishay
Vishay
PART
NUMBER
FDMC510P
Si7123DN
Si5481DU
RDS(ON)
(mΩ)
7.6
11.2
24
VT (V)
–0.5
–1
–1
BVDSS (V)
–20
–20
–20
present in the application. Using similar operating conditions as the application, the user must measure, or request
from the vendor, the actual capacitance to determine if the
selected capacitor meets the minimum capacitance that
the application requires.
VBUS and VOUT Bypass Capacitors
Programming the Input and Battery Charge
Current Limits
The style and value of the capacitors used with the LTC4155
determine several important parameters such as regulator
control loop stability and input voltage ripple. Because
the LTC4155 uses a step-down switching power supply
from VBUS to VOUT, its input current waveform contains
high frequency components. It is strongly recommended
that a low equivalent series resistance (ESR) multilayer
ceramic capacitor be used to bypass VBUS. Tantalum and
aluminum capacitors are not recommended because of
their high ESR. The value of the capacitor on VBUS directly
controls the amount of input ripple for a given load current.
Increasing the size of this capacitor will reduce the input
ripple. The USB specification allows a maximum of 10μF
to be connected directly across the USB power bus. If the
overvoltage protection circuit is used to protect VBUS, then
its soft-starting nature can be exploited and a larger VBUS
capacitor can be used if desired. If one or both of the input
channels are never used for USB, additional capacitance
placed upstream of the overvoltage protection NMOS devices can absorb significant high frequency current ripple.
The LTC4155 features independent resistor programmability of the input current limit and battery charge current
limit to facilitate optimal charging from a wide variety of
input power sources. The battery charge current should
be programmed based on the size of the battery and its
associated safe charging rate. Typically this rate is close
to “1C”, or equal to the current which would discharge
the battery in one hour. For example, a 2000mAH battery
would be charged with no more than 2A. With the fullscale (default) charge current programmed with a resistor
between PROG and GND, all other I2C selectable charge
current settings are lower and may be appropriate for custom charge algorithms at extreme temperature or battery
voltage. If the battery charge current limit requires more
power than is available from the selected input current limit,
the input current limit will be enforced and the battery will
charge with less than the programmed current. Thus, the
battery charger should be programmed optimally for the
battery without concern for the input source.
To prevent large VOUT voltage steps during transient load
conditions, it is also recommended that a ceramic capacitor
be used to bypass VOUT. The output capacitor is used in
the compensation of the switching regulator. At least 22μF
with low ESR are required on VOUT. Additional capacitance
will improve load transient performance and stability.
Multilayer ceramic chip capacitors typically have exceptional ESR performance. MLCCs combined with a tight
board layout and an unbroken ground plane will yield very
good performance and low EMI emissions.
The actual in-circuit capacitance of a ceramic capacitor
should be measured with a small AC signal and DC bias,
as is expected in-circuit. Many vendors specify the capacitance versus voltage with a 1VRMS AC test signal and, as
a result, overstate the capacitance that the capacitor will
Resistive Inputs and Test Equipment
Care must be exercised in the laboratory while evaluating the LTC4155 with inline ammeters. The combined
resistance of the internal current sense resistor and fuse
of many meters can be 0.5Ω or more. At currents of 3A
to 4A, it is possible to drop several volts across the meter,
possibly resulting in unusual voltage readings or artificially
high switch duty cycles.
A resistive connection to the source of input power can
be particularly troublesome. With the undervoltage current limit feature enabled, the switching regulator output
power will be automatically reduced to prevent VBUS from
falling below 4.3V. This feature greatly improves tolerance
of resistive input power sources (from either undersized
wiring and connectors or test equipment) and facilitates
4155fc
45
LTC4155
APPLICATIONS INFORMATION
stable behavior, but if engaged, it will result in much less
power delivery to the system load and battery, depending
on the magnitude of input resistance.
ground plane from this capacitor’s ground return to the
inductor, input capacitor, and LTC4155 Exposed Pad will
reduce output voltage ripple.
If the undervoltage current limit feature is disabled and the
input power source is resistive, the voltage will continue
to fall through the falling undervoltage lockout threshold,
eventually shutting down that input channel and resetting
its input current limit back to the default setting. When
the input voltage recovers, the channel will restart in the
default current limit setting.
High frequency currents, such as the input current on the
LTC4155, tend to find their way on the ground plane along
a mirror path directly beneath the incident path on the top
of the board. If there are slits or cuts in the ground plane
due to other traces on that layer, the current will be forced
to go around the slits. If high frequency currents are not
allowed to flow back through their natural least-area path,
excessive voltage will build up and radiated emissions will
occur (see Figure 13). There should be a group of vias
directly under the grounded backside leading directly
down to an internal ground plane. To minimize parasitic
inductance, the ground plane should be as close as possible to the top plane of the PC board (layer 2).
Board Layout Considerations
The Exposed Pad on the backside of the LTC4155 package
must be securely soldered to the PC board ground. This
is the primary ground pin in the package, and it serves as
the return path for both the control circuitry and the synchronous rectifier. Furthermore, due to its high frequency
switching circuitry, it is imperative that the input capacitor
be as close to the LTC4155 as possible, and that there
be an unbroken ground plane under the LTC4155 and its
external input bypass capacitors. Additionally, minimizing
the area between the SW pin trace and inductor will limit
high frequency radiated energy.
The BATGATE pin has limited drive current. Care must be
taken to minimize leakage to adjacent PC board traces,
which may significantly compromise the 15mV ideal diode forward voltage. To minimize leakage, the trace can
be guarded on the PC board by surrounding it with VOUT
connected metal, which should generally be less than 1V
higher than BATGATE.
The output capacitor carries the inductor ripple current.
While not as critical as the input capacitor, an unbroken
4155 F13
Figure 13. Higher Frequency Ground Currents Follow Their
Incident Path. Slices in the Ground Plane Cause High Voltage
and Increased Emissions
4155fc
46
LTC4155
TYPICAL APPLICATIONS
Single Input USB Default Current Limit with Minimum Component Count
7
WALLSNS
11
SW
WALLGT
VOUTSNS
VOUT
23, 24, 25
VBUS
C3
10μF
LTC4155
9
R1
3.6k
CHGSNS
8
TO μC
TO μC
21, 22
17
USBSNS
16
BATSNS
14
NTCBIAS
6
29
2.4A
LIMIT
15
PROG
12
18
C1
0.047μF
R2
1.21k
MP1
R4
100k
NTC
TO
SYSTEM
LOAD
19, 20
BATGATE
5
C2
22μF
13
USBGT
4
ID
3 1, 2, 28 2
I C
3
IRQ
10
OVGCAP
CLPROG1 CLPROG2 GND VC
L1
1μH
26, 27
R3
499Ω
4155 TA02
L1: COILCRAFT XFL4020-102ME
MP1: VISHAY Si5481DU-T1-GE3
Single Input Overvoltage Protection with USB 100mA Default Input Current Limit and 5°C/46°C/67°C Thermistor Thresholds
7
11
WALLSNS
SW
WALLGT
VOUTSNS
VOUT
C3
10μF
MN1
23, 24, 25
9
R1 3.6k
8
4
TO μC
TO μC
3 1, 2, 28
3
10
VBUS
CHGSNS
LTC4155
26, 27
21, 22
17
USBSNS
16
BATSNS
14
NTCBIAS
I2C
MP1
R4
8k
OVGCAP
CLPROG1 CLPROG2 GND VC
5
R2
1.21k
6
29
NTC
TO
SYSTEM
LOAD
19, 20
BATGATE
IRQ
C2
22μF
13
USBGT
ID
L1
1μH
15
1.8A
LIMIT
PROG
12
C1
0.047μF
18
R3
665Ω
4155 TA03
L1: COILCRAFT XFL4020-102ME
MN1: Si4430BDY
MP1: VISHAY Si5481DU-T1-GE3
PACK NTC: VISHAY NTCS0402E3103FLT
4155fc
47
LTC4155
TYPICAL APPLICATIONS
Single Input Over/Reverse Protection, USB Default Input Current Limit and –3°C/44°C/66°C Thermistor Thresholds
7
11
WALLSNS
SW
WALLGT
VOUTSNS
VOUT
C3
10μF
MN1A
MN1B
23, 24, 25
R1
5M
9
R4 3.6k
8
4
Q1B
Q1A
R3 47k
TO μC
TO μC
3 1, 2, 28
3
10
VBUS
CHGSNS
LTC4155
26, 27
21, 22
19, 20
17
BATGATE
USBSNS
16
BATSNS
14
NTCBIAS
I2C
MP1
R6
11.5k
IRQ
OVGCAP
CLPROG1 CLPROG2 GND VC
5
R4
1.21k
6
29
NTC
PROG
12
C1
0.047μF
18
TO
SYSTEM
C2
LOAD
22μF
13
USBGT
ID
L1
1μH
15
1.2A
LIMIT
R7
1k
R5
1k
4155 TA04
L1: COILCRAFT XFL4020-102ME
MN1: FAIRCHILD FDMC8030
MP1: VISHAY Si5481DU-T1-GE3
PACK NTC: VISHAY NTCS0402E3103FLT
Q1: DIODES/ZETEX MMDT3904-7-F
4155fc
48
LTC4155
TYPICAL APPLICATIONS
Dual-Input Over/Undervoltage Protection with 100mA USB Default Current Limit
Q1A
R1
47k
R2
3.6k
Q1B
R3 5M
7
11
WALLSNS
SW
WALLGT
VOUTSNS
VOUT
MN1A
C3 10μF MN1B
MN2A
MN2B
23, 24, 25
R4 5M
9
R5 3.6k
8
4
Q2B
Q2A
R6 47k
TO μC
TO μC
3 1, 2, 28
3
10
L1: COILCRAFT XFL4020-102ME
MN1, MN2: FAIRCHILD FDMC8030
MP1: VISHAY Si5481DU-T1-GE3
Q1, Q2: DIODES/ZETEX MMDT3904-7-F
VBUS
CHGSNS
LTC4155
26, 27
21, 22
17
USBSNS
16
BATSNS
14
NTCBIAS
I2C
MP1
R9
100k
OVGCAP
CLPROG1 CLPROG2 GND VC
5
R7
1.21k
6
29
NTC
TO
SYSTEM
LOAD
19, 20
BATGATE
IRQ
C2
22μF
13
USBGT
ID
L1
1μH
15
2.4A
LIMIT
PROG
12
C1
0.047μF
18
R8
499Ω
4155 TA05
4155fc
49
LTC4155
PACKAGE DESCRIPTION
Please refer to http://www.linear.com/designtools/packaging/ for the most recent package drawings.
UFD Package
28-Lead Plastic QFN (4mm w 5mm)
(Reference LTC DWG # 05-08-1712 Rev B)
0.70 t0.05
4.50 t0.05
3.10 t0.05
2.50 REF
2.65 t0.05
3.65 t0.05
PACKAGE OUTLINE
0.25 t0.05
0.50 BSC
3.50 REF
4.10 t0.05
5.50 t0.05
RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS
APPLY SOLDER MASK TO AREAS THAT ARE NOT SOLDERED
4.00 t0.10
(2 SIDES)
0.75 t0.05
R = 0.05
TYP
PIN 1 NOTCH
R = 0.20 OR 0.35
w 45s CHAMFER
2.50 REF
R = 0.115
TYP
27
28
0.40 t0.10
PIN 1
TOP MARK
(NOTE 6)
1
2
5.00 t0.10
(2 SIDES)
3.50 REF
3.65 t0.10
2.65 t0.10
(UFD28) QFN 0506 REV B
0.200 REF
0.00 – 0.05
0.25 t0.05
0.50 BSC
BOTTOM VIEW—EXPOSED PAD
NOTE:
1. DRAWING PROPOSED TO BE MADE A JEDEC PACKAGE OUTLINE MO-220 VARIATION (WXXX-X).
2. DRAWING NOT TO SCALE
3. ALL DIMENSIONS ARE IN MILLIMETERS
4. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE
MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.15mm ON ANY SIDE
5. EXPOSED PAD SHALL BE SOLDER PLATED
6. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION
ON THE TOP AND BOTTOM OF PACKAGE
4155fc
50
LTC4155
REVISION HISTORY
REV
DATE
DESCRIPTION
PAGE NUMBER
A
2/12
Updated Typical Application circuit
1
Clarified Electrical Characteristics specs and conditions
4, 5, 6, 7
Revised Typical Performance Characteristics graphs
9, 10, 11
Clarified I2C Operation table
17
Changed output current limit callout
20
Revised equations
22
Clarified ship-and-store mode operation
Changed Typical Applications circuits and notes
24
48, 49, 52
B
3/12
Corrected resistor Equation
29
C
5/12
Modified hCLPROG1 typical value
5
Modified RCLPROG1 equation
29
Clarified input current limit settings note in Table 8
35
4155fc
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights.
51
LTC4155
TYPICAL APPLICATION
Dual-Input Overvoltage Protection with 1.21A Default Input Current Limit and Output Voltage Disconnect
R1
3.6k
7
11
WALLSNS
SW
WALLGT
VOUTSNS
VOUT
26, 27
L1
1μH
C3
22μF
13
21, 22
TO
SYSTEM
LOAD
MN1A C4 10μF MN1B
23, 24, 25
MN2A
MN2B
VBUS
CHGSNS
19, 20
MP1
9
R2 3.6k
8
4
TO μC
3 1, 2, 28
3
TO μC
10
L1: COILCRAFT XFL4020-102ME
MN1, MN2: FAIRCHILD FDMC8030
MP1, MP2: VISHAY, Si5481DU-T1-GE3
LTC4155
17
USBGT
BATGATE
USBSNS
16
BATSNS
14
NTCBIAS
ID
I2C
R6
100k
IRQ
OVGCAP
CLPROG1 CLPROG2 GND VC
C1
0.01μF
MP2
5
R3
1k
6
R4
1.21k
29
NTC
15
3.52A
LIMIT
PROG
12
C2
0.047μF
18
R5
340Ω
4155 TA06
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
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High Efficiency Charger Capable of 3.5A Charge Current, Monolithic
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LTC4089-5
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DFN-22 Package
LTC4098/LTC4098-1
USB-Compatible Switchmode Power Manager
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66V OVP. 1.5A Max Charge Current from Wall, 600mA Charge Current from
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from Wall, 600mA Charge Current from USB, 3mm × 4mm QFN-20 Package
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Switchmode Power Manager with OVP and
USB-OTG
USB-OTG 5V Output, Overvoltage Protection, Maximizes Available Power
from USB Port, Bat-Track, Instant-On Operation, 1.5A Max Charge Current
from Wall, 600mA Charge Current from USB, 3mm × 4mm QFN-20 Package
LTC4098-3.6
USB-Compatible Switchmode LiFePO4 Power
Manager with OVP
3.6V VFLOAT for LiFePO4 Cells; 66V OVP. 1.5A Max Charge Current from
Wall, 600mA Charge Current from USB, 3mm × 4mm QFN-20 Package
4155fc
52 Linear Technology Corporation
LT 0512 REV C • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com
© LINEAR TECHNOLOGY CORPORATION 2011