LINER LTC1960CGPBF

LTC1960
Dual Battery Charger/
Selector with SPI Interface
DESCRIPTION
FEATURES
Complete Dual-Battery Charger/Selector System
n Serial SPI Interface Allows External µC Control and
Monitoring
n Simultaneous Dual-Battery Discharge Extends Run
Time by Typically 10%
n Simultaneous Dual-Battery Charging Reduces
Charging Time by Up to 50%
n Automatic PowerPath™ Switching in <10µs
Prevents Power Interruption
n Circuit Breaker Protects Against Overcurrent Faults
n 5% Accurate Adapter Current Limit Maximizes
Charging Rate
n 95% Efficient Synchronous Buck Charger
n Charger Has Low 0.5V Dropout Voltage
n No Audible Noise Generation, Even with Ceramic
Capacitors
n 11-Bit VDAC Delivers 0.8% Voltage Accuracy
n 10-Bit IDAC Delivers 5% Current Accuracy
nV Up to 32V; V
IN
BATT Up to 28V
n Available in 5mm × 7mm 38-Pin QFN and 36-Pin
Narrow SSOP Packages
n
APPLICATIONS
The LTC®1960 is a highly integrated battery charger and
selector intended for portable products using dual smart
batteries. A serial SPI interface allows an external microcontroller to control and monitor status of both batteries.
A proprietary PowerPath architecture supports simultaneous charging or discharging of both batteries. Typical
battery run times are extended by 10%, while charging
times are reduced by up to 50%. The LTC1960 automatically switches between power sources in less than 10µs
to prevent power interruption upon battery or wall adapter
removal.
The synchronous buck battery charger delivers 95% efficiency with only 0.5V dropout voltage, and prevents audible
noise in all operating modes. Patented input current limiting with 5% accuracy charges batteries in the shortest
possible time without overloading the wall adapter.
The LTC1960’s 5mm × 7mm 38-pin QFN and 36-pin narrow SSOP packages allow implementation of a complete
SBS-compliant dual battery system while consuming
minimum PCB area.
L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks and
No RSENSE and PowerPath are trademarks of Linear Technology Corporation. All other
trademarks are the property of their respective owners. Protected by U.S. Patents, including
5481178, 5723970, 6304066, 6580258.
Portable Computers
Portable Instruments
n
n
TYPICAL APPLICATION
Dual vs Sequential Charging
LTC1960 Dual Battery/Selector System Architecture
BATTERY CURRENT (mA)
DC
IN
SYSTEM POWER
LTC1960
MICROCONTROLLER
4
BAT2
BAT1
SMBus
SPI
1960 TA01
3500
3000
2500
2000
1500
1000
500
0
3500
3000
2500
2000
1500
1000
500
0
BAT1
CURRENT
BAT2
CURRENT
SEQUENTIAL
BAT1
CURRENT
BAT2
CURRENT
DUAL
100
MINUTES
0
50
100
150
200
TIME (MINUTES)
250
300
BATTERY TYPE: 10.8V Li-Ion (MOLTECH NI2020)
REQUESTED CURRENT = 3A
REQUESTED VOLTAGE = 12.3V
MAX CHARGER CURRENT = 4.1A
1960 TA01b
1960fb
1
LTC1960
ABSOLUTE MAXIMUM RATINGS
(Note 1)
Voltage from DCIN, SCP, SCN, CLP, VPLUS,
SW to GND.................................................. –0.3V to 32V
Voltage from SCH1, SCH2 to GND.............. –0.3V to 28V
Voltage from BOOST to GND.......................–0.3V to 41V
PGND with Respect to GND....................................±0.3V
CSP, CSN, BAT1, BAT2 to GND....................... –5V to 28V
LOPWR, DCDIV to GND.............................. –0.3V to 10V
SSB, SCK, MOSI, MISO to GND.................... –0.3V to 7V
COMP1 to GND............................................. –0.3V to 5V
Operating Ambient Temperature
Range (Note 7)............................................. 0°C to 70°C
Operating Junction Temperature............. –40°C to 125°C
Storage Temperature.............................. –65°C to 150°C
Lead Temperature (Soldering, 10 sec)
SSOP Only......................................................... 300°C
PIN CONFIGURATION
34 GCH1
SCN
4
33 SCH1
SCP
5
GDCO
GDCO
25 GCH2
3
GDCI
2
BAT1
GB1O
BAT2
TOP VIEW
GB1I
36 SCH2
GB2O
1
GB2I
VPLUS
LOPWR
TOP VIEW
38 37 36 35 34 33 32
VSET 1
31 SCP
32 TGATE
ITH 2
30 SCN
6
31 BOOST
ISET 3
29 BAT1
GDCI
7
30 SW
GND 4
28 BAT2
GB1O
8
29 DCIN
28 VCC
25 COMP1
VSET 13
24 CLP
ITH 14
23 CSP
ISET 15
22 CSN
GND 16
21 MOSI
DCDIV 17
20 MISO
SSB 18
23 GCH1
GND 10
22 SCH1
CSN 11
21 TGATE
20 BOOST
CSP 12
13 14 15 16 17 18 19
19 SCK
SW
LOPWR 12
24 GCH2
MOSI 9
DCIN
26 PGND
VCC
GB2I 11
25 SCH2
MISO 8
BGATE
27 BGATE
PGND
GB2O 10
26 GND
39
SCK 7
CLP
9
27 VPLUS
SSB 6
COMP1
GB1I
DCDIV 5
UHF PACKAGE
38-LEAD (5mm × 7mm) PLASTIC QFN
G PACKAGE
36-LEAD PLASTIC SSOP
TJMAX = 125°C, θJA = 34°C/W
THE EXPOSED PAD (PIN 39) IS GND. MUST BE SOLDERED TO THE PCB
TJMAX = 125°C, θJA = 70°C/W
ORDER INFORMATION
LEAD FREE FINISH
TAPE AND REEL
PART MARKING*
PACKAGE DESCRIPTION
TEMPERATURE RANGE
LTC1960CG#PBF
LTC1960CG#TRPBF
LTC1960CG
36-Lead Plastic SSOP
0°C to 70°C
LTC1960CUHF#PBF
LTC1960CUHF#TRPBF
1960
38-Lead (5mm × 7mm) Plastic QFN
0°C to 70°C
Consult LTC Marketing for parts specified with wider operating temperature ranges.
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/
1960fb
2
LTC1960
ELECTRICAL
CHARACTERISTICS
The
l denotes the specifications which apply over the full operating
temperature range (Note 7), otherwise specifications are at TA = 25°C. VDCIN = 20V, VBAT1 = 12V, VBAT2 = 12V, unless otherwise noted.
SYMBOL PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
DCIN Operating Range
DCIN Selected
6
DCIN Operating Current
Not Charging (DCIN Selected)
Charging (DCIN Selected)
Battery Operating Voltage Range
Battery Selected, PowerPath Function (Note 2)
Battery Drain Current
Battery Selected, Not Charging, VDCIN = 0V
175
µA
VFDC
VFB1
VFB2
VFSCN
VPLUS Diodes Forward Voltage:
DCIN to VPLUS
BAT1 to VPLUS
BAT2 to VPLUS
SCN to VPLUS
IVCC = 10mA
IVCC = 0mA
IVCC = 0mA
IVCC = 0mA
0.8
0.7
0.7
0.7
V
V
V
V
UVLO
Undervoltage Lockout Threshold
VPLUS Ramping Down, Measured at VPLUS
to GND
VPLUS Rising, Measured at VPLUS to GND
Supply and Reference
ICH
UVHYS
UV Lockout Hysteresis
VVCC
VCC Regulator Output Voltage
VLDR
VCC Load Regulation
1
1.3
6
l
28
V
1.5
2
mA
mA
28
V
3
3.5
3.9
5
5.2
5.4
V
0.2
1
%
60
IVCC = 0mA to 10mA
V
mV
Switching Regulator
VTOL
ITOL
Overall Voltage Accuracy
Overall Current Accuracy
5V ≤ VOUT < 25V, (Note 3)
IDAC Value = 3FFHEX
VCSP , VCSN = 12V
fOSC
Regulator Switching Frequency
fDO
Regulator Switching Frequency in Low
Dropout Mode
DCMAX
Regulator Maximum Duty Cycle
IMAX
Maximum Current Sense Threshold
VITH = 2.2V
ISNS
CA1 Input Bias Current
VCSP = VCSN > 5V
CMSL
CAI Input Common Mode Low
CMSH
CAI Input Common Mode High
VCL1
CL1 Turn-On Threshold
TG tr
TG tf
TGATE Transition Time:
TGATE Rise Time
TGATE Fall Time
BG tr
BG tf
l
–0.8
–1
0.8
1
%
%
l
–5
–6
5
6
%
%
345
kHz
Duty Cycle ≥ 99%
255
300
20
25
kHz
99
99.5
%
140
155
190
150
µA
0
V
VDCIN–0.2
95
mV
V
100
105
mV
CLOAD = 3300pF, 10% to 90%
CLOAD = 3300pF, 10% to 90%
50
50
90
90
ns
ns
BGATE Transition Time:
BGATE Rise Time
BGATE Fall Time
CLOAD = 3300pF, 10% to 90%
CLOAD = 3300pF, 10% to 90%
50
40
90
80
ns
ns
VTR
DCDIV/LOPWR Threshold
VDCDIV or VLOPWR Falling
1.19
1.215
V
Trip Points
l
1.166
VTHYS
DCDIV/LOPWR Hysteresis Voltage
VDCDIV or VLOPWR Rising
30
IBVT
DCDIV/LOPWR Input Bias Current
VDCDIV or VLOPWR = 1.19V
20
200
nA
VTSC
Short-Circuit Comparator Threshold
VSCP – VSCN, VCC ≥ 5V
90
100
115
mV
VFTO
Fast PowerPath Turn-Off Threshold
VDCDIV Rising from VCC
6
7
7.9
V
VOVSD
Overvoltage Shutdown Threshold as a Percent
of Programmed Charger Voltage
VSET Rising from 0.8V Until TGATE and
BGATE Stop Switching
l
107
mV
%
1960fb
3
LTC1960
ELECTRICAL
CHARACTERISTICS
The
l denotes the specifications which apply over the full operating
temperature range (Note 7), otherwise specifications are at TA = 25°C. VDCIN = 20V, VBAT1 = 12V, VBAT2 = 12V, unless otherwise noted.
SYMBOL PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
DACs
IRES
IDAC Resolution
tIP
tILOW
IDAC Pulse Period:
Normal Mode
Low Current Mode
VRES
VDAC Resolution
VSTEP
VDAC Granularity
VOFF
VDAC Offset
tVP
VDAC Pulse Period
Guaranteed Monotonic Above IMAX /16
10
6
Guaranteed Monotonic (5V < VBAT < 25V)
bits
10
50
15
11
bits
16
(Note 6)
mV
0.8
7
µs
ms
V
11
16.5
µs
Charge MUX Switches
tONC
GCH1/GCH2 Turn-On Time
VGCHX – VSCHX > 3V, CLOAD = 3nF
5
10
ms
tONC
GCH1/GCH2 Turn-Off Time
VGCHX – VSCHX < 1V, from Time of VCSN <
VBATX – 30mV, CLOAD = 3nF
3
7
µs
VCON
CH Gate Clamp Voltage
GCH1
GCH2
ILOAD = 1µA
VGCH1 – VSCH1
VGCH2 – VSCH2
5
5
5.8
5.8
7
7
V
V
VCOFF
CH Gate Off Voltage
GCH1
GCH2
ILOAD = 10µA
VGCH1 – VSCH1
VGCH2 – VSCH2
–0.8
–0.8
–0.4
–0.4
0
0
V
V
VTOC
CH Switch Reverse Turn-Off Voltage
VCSN – VBATX, 5V ≤ VBATX ≤ 28V
l
5
20
40
mV
VFC
CH Switch Forward Regulation Voltage
VBATX – VCSN, 5V ≤ VBATX ≤ 28V
l
15
35
60
mV
IOC(SRC)
IOC(SNK)
GCH1/GCH2 Active Regulation:
Max Source Current
Max Sink Current
VGCHX – VSCHX = 1.5V
VCHMIN
BATX Voltage Below Which Charging Is Inhibited (Note 8)
–2
2
3.5
µA
µA
4.7
V
PowerPath Switches
tDLY
Blanking Period After UVLO Trip
Switches Held Off
tPPB
Blanking Period After LOPWR Trip
Switches in 3-Diode Mode
tONPO
GB1O/GB2O/GDCO Turn-On Time
VGS < –3V, from Time of Battery/DC
Removal, or LOPWR Indication
l
5
10
µs
tOFFPO
GB1O/GB2O/GDCO Turn-Off Time
VGS > –1V, from Time of Battery/DC
Removal, or LOPWR Indication
l
3
7
µs
VPONO
Output Gate Clamp Voltage
GB1O
GB2O
GDCO
ILOAD = 1µA
Highest (VBAT1 or VSCP) – VGB1O
Highest (VBAT2 or VSCP) – VGB2O
Highest (VDCIN or VSCP) – VGDCO
6.25
6.25
6.25
7
7
7
V
V
V
VPOFFO
Output Gate Off Voltage
GB1O
GB2O
GDCO
ILOAD = –25µA
Highest (VBAT1 or VSCP) – VGB1O
Highest (VBAT2 or VSCP) – VGB2O
Highest (VDCIN or VSCP) – VGDCO
0.18
0.18
0.18
0.25
0.25
0.25
V
V
V
VTOP
PowerPath Switch Reverse Turn-Off Voltage
VSCP – VBATX or VSCP – VDCIN
6V ≤ VSCP ≤ 28V
l
5
20
60
mV
VFP
PowerPath Switch Forward Regulation Voltage
VBATX – VSCP or VDCIN – VSCP
6V ≤ VSCP ≤ 28V
l
0
25
50
mV
IOP(SRC)
IOP(SNK)
GDCI/GB1I/GB2I Active Regulation
Source Current
Sink Current
(Note 4)
4.75
4.75
4.75
250
ms
1
sec
–4
75
µA
µA
1960fb
4
LTC1960
ELECTRICAL
CHARACTERISTICS
The
l denotes the specifications which apply over the full operating
temperature range (Note 7), otherwise specifications are at TA = 25°C. VDCIN = 20V, VBAT1 = 12V, VBAT2 = 12V, unless otherwise noted.
SYMBOL PARAMETER
tONPI
Gate B1I/B2I/DCI Turn-On Time
CONDITIONS
MIN
TYP
MAX
UNITS
VGS < –3V, CLOAD = 3nF (Note 5)
300
µs
10
µs
tOFFPI
Gate B1I/B2I/DCI Turn-Off Time
VGS > –1V, CLOAD = 3nF (Note 5)
VPONI
Input Gate Clamp Voltage
GB1I
GB2I
GDCI
ILOAD = 1µA
Highest (VBAT1 or VSCP) – VGB1I
Highest (VBAT2 or VSCP) – VGB2I
Highest (VDCIN or VSCP) – VGDCI
VPOFFI
Input Gate Off Voltage
GB1I
GB2I
GDCI
ILOAD = 25µA
Highest (VBAT1 or VSCP) – VGB1I
Highest (VBAT2 or VSCP) – VGB2I
Highest (VDCIN or VSCP) – VGDCI
4.75
4.75
4.75
6.7
6.7
6.7
7.5
7.5
7.5
V
V
V
0.18
0.18
0.18
0.25
0.25
0.25
V
V
V
1
µA
0.8
V
Logic I/O
IIH /IIL
SSB/SCK/MOSI Input High/Low Current
l
VIL
SSB/MOSI/SCK Input Low Voltage
l
VIH
SSB/MOSI/SCK Input High Voltage
l
VOL
MISO Output Low Voltage
IOL = 1.3mA
l
0.4
V
IOFF
MISO Output Off-State Leakage Current
VMISO = 5V
l
2
µA
4.5
sec
–1
2
V
SPI Timing (See Timing Diagram)
TWD
Watch Dog Timer
tSSH
SSB High Time
tCYC
SCK Period
tSH
tSL
l
1.2
2.5
680
ns
2
µs
SCK High Time
680
ns
SCK Low Time
680
ns
tLD
Enable Lead Time
200
ns
tLG
Enable Lag Time
200
ns
tsu
Input Data Set-Up Time
l
100
ns
tH
Input Data Hold Time
l
100
tA
Access Time (From Hi-Z to Data Active on MISO)
l
125
ns
tdis
Disable Time (Hold Time to Hi-Z State on MISO)
l
125
ns
tV
Output Data Valid
l
580
ns
tHO
Output Data Hold
tIr
SCK/MOSI/SSB Rise Time
0.8V to 2V
250
ns
tIf
SCK/MOSI/SSB Fall Time
2V to 0.8V
250
ns
tOf
MISO Fall Time
2V to 0.4V, CL = 200pF
400
ns
CLOAD = 200pF RPULLUP = 4.7k on MISO
CL = 200pF, RPULLUP = 4.7k on MISO
l
l
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. Battery voltage must be adequate to drive gates of PowerPath
P-channel FET switches. This does not affect charging voltage of the
battery, which can be zero volts.
Note 3. See Test Circuit.
Note 4. DCIN, BAT1, BAT2 are held at 12V and GDCI, GB1I, GB2I are
forced to 10.5V. SCP is set at 12.0V to measure source current at GDCI,
l
ns
0
ns
GB1I and GB2I. SCP is set at 11.9V to measure sink current at GDCI, GB1I
and GB2I.
Note 5. Extrapolated from testing with CL = 50pF.
Note 6. VDAC offset is equal to the reference voltage, since
VOUT = VREF(16mV • VDAC(VALUE)/2047 + 1)
Note 7. The LTC1960C is guaranteed to meet specified performance from
0°C to 70°C and is designed, characterized and expected to meet specified
performance at –40°C and 85°C, but is not tested at these extended
temperature limits.
Note 8. Does not apply to low current mode. Refer to “The Current DAC
Block” in the Operation section.
1960fb
5
LTC1960
TYPICAL PERFORMANCE CHARACTERISTICS
Battery Drain Current
(BAT1 Selected)
230
CLOAD = 20µF
15 ILOAD = 0.8A
T = 25°C
14 A
220
13
LOAD VOLTAGE (V)
BAT1 CURRENT (µA)
210
200
190
180
10
9
160
7
12
24
18
BAT1 VOLTAGE (V)
14
11
8
6
15
12
170
150
16
16
TA = 25°C
240
LOPWR
THRESHOLD
LOAD VOLTAGE (V)
250
PowerPath Autonomous
Switching
PowerPath Switching
1960 G01
10
12
60
50
40
30
20
10
0.025
0.50
0.10
IOUT (A)
2.5 4.0
1960 G04
8
6
4
OUTPUT CURRENT ERROR (mA)
BAT1 VOLTAGE (V)
12.2
12.1
12.0
11.9
VIN = 20V
VDAC = 12.288V
IDAC = 4000mA
TA = 25°C
11.6
0
1000
2000
3000
CHARGE CURRENT (mA)
4000
1960 G07
LOAD
CONNECTED
4
0
–0.05 0 0.05 0.10 0.15 0.20 0.25 0.30 0.35 0.40
TIME (SEC)
0
–4 –2
LOAD
DISCONNECTED
0
2
500
VDCIN = 20V
100 VBAT1 = 12V
RSNS = 0.025Ω
T = 25°C
80 A
10 12 14 16
1960 G06
VIN = 20V
VBAT1 = 12V
RSNS = 0.025Ω
TA = 25°C
450
60
40
20
0
–20
–40
4 6 8
TIME (ms)
IDAC Low Current Mode
vs Normal Mode
120
11.7
6
1960 G05
12.4
11.8
8
Charging Current Accuracy
12.3
VIN = 20V
VDAC = 12.29V
IDAC = 3000mA
LOAD CURRENT = 1A
TA = 25°C
10
2
Charger Load Regulation
5
1960 G03
BAT1
OUTPUT
2
CHARGING CURRENT (mA)
EFFICIENCY (%)
70
4
Charger Load Dump
14
BAT1 VOLTAGE (V)
CHARGER OUTPUT (V)
80
BAT1
REMOVED
9
12
90
0
10
Charger Start-Up
100
0
11
7 NOTE: LIGHT LOAD TO
EXAGGERATE SWITCHING EVENT
6
0
2
3
–1
1
TIME (SEC)
1960 G02
Charger Efficiency
12
8
6
–50 –40 –30 –20 –10 0 10 20 30 40 50
TIME (µs)
30
13
400
350
300
LOW CURRENT
MODE
250
200
NORMAL
MODE
150
100
50
0
200
400
600
800
IDAC VALUE
1000
1200
1960 G08
0
0
80 160 240 320 400 480
PROGRAMMED CURRENT (mA)
560
1960 G09
1960fb
6
LTC1960
TYPICAL PERFORMANCE CHARACTERISTICS
BATTERY CURRENT (mA)
50
25
0
–25
–50
–75
450
650
850 1050
VDAC VALUE
1250
1450
BAT1
CURRENT
BAT1
CURRENT
BAT2
CURRENT
DUAL
0
50
100
150
200
TIME (MINUTES)
250
2500
15.5
2000
15.0
BAT1
CURRENT
14.5
13.5
300
3000
BAT1
VOLTAGE
16.0
BAT2
CURRENT
14.0
100
MINUTES
3500
BAT2
VOLTAGE
16.5
SEQUENTIAL
Dual vs Sequential Discharge
20
0
40
1500
1000
500
0
100 120 140 160
TIME (MINUTES)
60
80
BAT1 INITIAL CAPACITY = 0%
BAT2 INITIAL CAPACITY = 90%
PROGRAMMED CHARGER CURRENT = 3A
PROGRAMMED CHARGER VOLTAGE = 16.8V
1960 G12
Dual vs Sequential Discharge
15
12.0
BAT1
VOLTAGE
11.0
BAT2
VOLTAGE
12.0
SEQUENTIAL
11.0
10.0
BAT1
VOLTAGE
9.0
0
20
40
BAT2
VOLTAGE
13
9.0
8.0
14
DUAL
BAT2
VOLTAGE
10.0
8.0
17.0
BAT2
CURRENT
BATTERY TYPE: 10.8V Li-Ion (MOLTECH NI2020)
REQUESTED CURRENT = 3A
REQUESTED VOLTAGE = 12.3V
MAX CHARGER CURRENT = 4.1A
1960 G11
1960 G10
BATTERY VOLTAGE (V)
–100
250
3500
3000
2500
2000
1500
1000
500
0
3500
3000
2500
2000
1500
1000
500
0
BATTERY VOLTAGE (V)
75
DCIN = 24V
TA = 25°C
ILOAD = 100mA
BATTERY CURRENT (mA)
OUTPUT VOLTAGE ERROR (mV)
100
Dual Charging Batteries with
Different Charge State
Dual vs Sequential Charging
BATTERY VOLTAGE (V)
Voltage Accuracy
12
BAT1
VOLTAGE
11
10
BAT2
VOLTAGE
15
14
60 80 100 120 140 160 180
TIME (MINUTES)
BATTERY TYPE: 10.8V Li-Ion(MOLTECH NI2020)
LOAD CURRENT = 3A
1960 G13
16
MINUTES
11
10
SEQUENTIAL
BAT1
VOLTAGE
13
12
11
MINUTES
DUAL
0
20
40
60
80
100
TIME (MINUTES)
120
140
BATTERY TYPE: 12V NIMH (MOLTECH NJ1020)
1960 G14
LOAD: 33W
1960fb
7
LTC1960
PIN FUNCTIONS
(G/UHF)
Input Power Related
Battery Charging Related
SCN (Pin 4/Pin 30): PowerPath Current Sensing Negative
Input. This pin should be connected directly to the “bottom”
(output side) of the sense resistor, RSC , in series with the
three PowerPath switch pairs, for detecting short-circuit
current events. Also powers LTC1960 internal circuitry
when all other sources are absent.
VSET (Pin 13/Pin 1): The Tap Point of a Programmable
Resistor Divider Which Provides Battery Voltage Feedback
to the Charger. A capacitor from CSN to VSET and from
VSET to GND provide necessary compensation and filtering
for the voltage loop.
SCP (Pin 5/Pin 31): PowerPath Current Sensing Positive
Input. This pin should be connected directly to the “top”
(switch side) of the sense resistor, RSC , in series with the
three PowerPath switch pairs, for detecting short-circuit
current events.
ITH (Pin 14/Pin 2): The Control Signal of the Inner Loop of
the Current Mode PWM. Higher ITH voltage corresponds to
higher charging current in normal operation. A capacitor
of at least 0.1µF to GND filters out PWM ripple. Typical
full-scale output current is 30µA. Nominal voltage range
for this pin is 0V to 2.4V.
GDCO (Pin 6/Pin 32): DCIN Output Switch Gate Drive.
Together with GDCI, this pin drives the gate of the P-channel
switch in series with the DCIN input switch.
ISET (Pin 15/Pin 3): A capacitor from ISET to ground is
required to filter higher frequency components from the
delta-sigma IDAC.
GDCI (Pin 7/Pin 33): DCIN Input Switch Gate Drive.
Together with GDCO, this pin drives the gate of the
P-channel switch connected to the DCIN input.
CSN (Pin 22/Pin 11): Current Amplifier CA1 Input. Connect this to the common output of the charger MUX
switches.
GB1O (Pin 8/Pin 34): BAT1 Output Switch Gate Drive.
Together with GB1I, this pin drives the gate of the P-channel
switch in series with the BAT1 input switch.
CSP (Pin 23/Pin 12): Current Amplifier CA1 Input. This
pin and the CSN pin measure the voltage across the
sense resistor, RSNS, to provide the instantaneous current signals required for both peak and average current
mode operation.
GB1I (Pin 9/Pin 35): BAT1 Input Switch Gate Drive.
Together with GB1O, this pin drives the gate of the P-channel
switch connected to the BAT1 input.
GB2O (Pin 10/Pin 36): BAT2 Output Switch Gate Drive.
Together with GB2I, this pin drives the gate of the P-channel
switch in series with the BAT2 input switch.
GB2I (Pin 11/Pin 37): BAT2 Input Switch Gate Drive.
Together with GB2O, this pin drives the gate of the P-channel
switch connected to the BAT2 input.
CLP (Pin 24/Pin 13): The Positive Input to the Supply
Current Limiting Amplifier CL1. The threshold is set at
100mV above the voltage at the DCIN pin. When used
to limit supply current, a filter is needed to filter out the
switching noise.
COMP1 (Pin 25/Pin 14): The Compensation Node for the
Amplifier CL1. A capacitor is required from this pin to GND
if input current amplifier CL1 is used. At input adapter
current limit, this node rises to 1V. By forcing COMP1 low,
amplifier CL1 will be defeated (no adapter current limit).
COMP1 can source 10µA.
BGATE (Pin 27/Pin 16): Drives the bottom external MOSFET
of the battery charger buck converter.
SW (Pin 30/Pin 19): PWM switch node connected to source
of the top external MOSFET switch. Used as reference for
top gate driver.
BOOST (Pin 31/Pin 20): Supply to Topside Floating Driver.
The bootstrap capacitor is returned to this pin. Voltage
swing at this pin is from a diode drop below VCC to (DCIN
+ VCC).
1960fb
8
LTC1960
PIN FUNCTIONS
(G/UHF)
TGATE (Pin 32/Pin 21): Drives the top external MOSFET
of the battery charger buck converter.
SCH1 (Pin 33/Pin 22), SCH2 (Pin 36/Pin 25): Charger
MUX N-Channel Switch Source Returns. These two pins
are connected to the sources of the back-to-back switch
pairs, Q3/Q4 and Q9/Q10 (see Typical Application on back
page of data sheet), respectively. A small pull-down current source returns these nodes to 0V when the switches
are turned off.
GCH1 (Pin 34/Pin 23), GCH2 (Pin 35/Pin 24): Charger
MUX N-Channel Switch Gate Drives. These two pins drive
the gates of the back-to-back switch pairs, Q3/Q4 and Q9/
Q10, between the charger output and the two batteries.
External Power Supply Pins
VPLUS (Pin 1/Pin 27): Supply. The VPLUS pin is connected
via four internal diodes to the DCIN, SCN, BAT1, and BAT2
pins. Bypass this pin with a 1µF to 2µF capacitor.
BAT1 (Pin 3/Pin 29), BAT2 (Pin 2/Pin 28): These two
pins are the inputs from the two batteries for power to
the LTC1960 and to provide voltage feedback to the battery charger.
LOPWR (Pin 12/Pin 38): LOPWR Comparator Input from
SCN External Resistor Divider to GND. If the voltage at
LOPWR is lower than the LOPWR comparator threshold,
then system power has failed and power is autonomously
switched to a higher voltage source, if available. See
PowerPath section of LTC1960 operation.
DCDIV (Pin 17/Pin 5): External DC Source Comparator
Input from DCIN External Resistor Divider to GND. If the
voltage at DCDIV is above the DCDIV comparator threshold, then the DC bit is set and the wall adapter power is
considered to be adequate to charge the batteries. If DCDIV
rises more than 1.8V above VCC, then all of the PowerPath
switches are latched off until all power is removed.
DCIN (Pin 29/Pin 18): Supply. External DC power source.
A 1µF bypass capacitor should be connected to this pin as
close as possible. No series resistance is allowed, since
the adapter current limit comparator input is also this pin.
Internal Power Supply Pins
GND (Pin 16/Pin 4, Pin 10, Pin 26, Pin 39): Ground for
Low Power Circuitry.
PGND (Pin 26/Pin 15): High Current Ground Return for
BGATE Driver.
VCC (Pin 28/Pin 17): Internal Regulator Output. Bypass
this output with at least a 2µF to 4.7µF capacitor. Do not
use this regulator output to supply more than 1mA to
external circuitry.
Digital Interface Pins
SSB (Pin 18/Pin 6): SPI Slave Select Input. Active low.
TTL levels. This signal is low when clocking data to/from
the LTC1960.
SCK (Pin 19/Pin 7): Serial SPI Clock. TTL levels.
MISO (Pin 20/Pin 8): SPI Master-In-Slave-Out Output,
Open Drain. Serial data is transmitted from the LTC1960,
when SSB is low, on the falling edge of SCK. TTL levels.
A 4.7k pull-up resistor is recommended.
MOSI (Pin 21/Pin 9): SPI Master-Out-Slave-In Input. Serial
data is transmitted to the LTC1960, when SSB is low, on
the rising edge of SCK. TTL levels.
GND (Exposed Pad Pin 39, UHF Package Only): Ground.
Must be soldered to the PCB ground for rated thermal
performance.
A capacitor from DCDIV to GND is recommended to prevent
noise-induced false emergency turn-off conditions from
being detected. Refer to “Fast PowerPath Turn-Off” in the
Operation section and the Typical Application on the back
page of this data sheet.
1960fb
9
LTC1960
(LTC1960CG Pin Numbers Shown)
CHARGE
PUMP
SWB2
DRIVER
6
SWDC
DRIVER
100mV
SHORT CIRCUIT
AC_PRESENT
ON
SELECTOR
CONTROLLER
ON
+
–
SCH2 36
7
5 SCP
100Ω
4 SCN
17 DCDIV
12 LOPWR
–
GCH2 35
GDCI GDCO
+
SCH1 33
SWB1
DRIVER
10
+
–
GCH1 34
11
–
DCIN
GB2I GB2O
8
+
9
–
GB1I GB1O
+
BLOCK DIAGRAM
1.19V
CSN
21 MOSI
BAT1
3
BAT2
2
CHARGE
400k
20 MISO
SPI
INTERFACE
CHGMON
19 SCK
18 SSB
11
1
11-BIT ∆Σ
VOLTAGE DAC
VCC
REGULATOR
0.86V
DCIN 29
CSP-CSN
3kΩ
0V
+
–
OSCILLATOR
0.8V
3k
EA
CA1
TON
gm = 1.4m
PWM
LOGIC
SW 30
R
÷15
ICMP
CHARGE
VCC
0.8V
–+
–
IREV
PGND 26
–
BGATE 27
40mV
+
gm = 0.4m
+
+
CL1
Ω
–
100mV
–
CLP 24
22 CSN
BUFFERED ITH
+
TGATE 32
CA2
S
23 CSP
–
Q
+
BOOST 31
DCIN
3k
Ω
+
LOW DROP
DETECT
+
gm = 1.4m
Ω
VSET 13
BGATE
15 ISET
10-BIT ∆Σ
CURRENT DAC
–
VCC 28
GND 16
SCN
–
VPLUS
25
COMP1
14
ITH
0.75V
CHGMON
CLAMP
1960 BD
1960fb
10
LTC1960
TEST CIRCUIT
VREF
+
EA
CHGMON
BAT1
BAT2
–
VSW
ITH
VSET
+
–
0.5V
1960 TC01
TIMING DIAGRAM
SPI Timing Diagram
SSB
tLD
tCYC
tLG
tSSH
SCK
tH
tsu
MOSI
tSH
BIT 7
tA
MISO
tSL
BIT 0
tV
SLAVE
BIT 7 OUT
tHO
tdis
SLAVE
BIT 0 OUT
1960 TD01
1960fb
11
LTC1960
OPERATION
(Refer to Block Diagram and Typical Application)
OVERVIEW
The LTC1960 is composed of a battery charger controller,
charge MUX controller, PowerPath controller, SPI interface, a 10-bit current DAC (IDAC) and 11-bit voltage DAC
(VDAC). When coupled with a low cost microprocessor, it
forms a complete battery charger/selector system for two
batteries. The battery charger is programmed for voltage
and current, and the charging battery is selected via the
SPI interface. Charging can be accomplished only if the
voltage at DCDIV indicates that sufficient voltage is available from the input power source, usually an AC adapter.
The charge MUX, which selects the battery to be charged,
is capable of charging both batteries simultaneously by
selecting both batteries for charging. The charge MUX
switch drivers are configured to allow charger current to
share between the two batteries and to prevent current
from flowing in a reverse direction in the switch. The
amount of current that each battery receives will depend
upon the relative capacity of each battery and the battery
voltage. This can result in significantly shorter charging
times (up to 50% for Li-Ion batteries) than sequential
charging of each battery. In order to continue charging,
the CHARGE_BAT information must be updated more
frequently than the internal watchdog timer.
The PowerPath controller selects which of the pairs of
PFET switches, input and output, will provide power to
the system load. The selection is accomplished over
the SPI interface. If the system voltage drops below the
threshold set by the LOPWR resistor divider, then all of
the output side PFETs are turned on quickly and power
is taken from the highest voltage source available at the
DCIN, BAT1 or BAT2 inputs. The input side PFETs act as
diodes in this mode and power is taken from the source
with the highest voltage. The input side PowerPath switch
driver that is delivering power then closes its input switch
to reduce the power dissipation in the PFET bulk diode. In
effect, this system provides diode -like behavior from the
FET switches, without the attendant high power dissipation from diodes. The microprocessor is informed of this
3-diode mode status when it polls the PowerPath status
register via the SPI interface. The microprocessor can then
assess which power source is capable of providing power,
and program the PowerPath switches accordingly. Since
high speed PowerPath switching at LOPWR trip points
is handled autonomously, there is no need for real-time
microprocessor resources to accomplish this task.
Simultaneous discharge of both batteries is accomplished
by simply programming both batteries for discharge into
the system load. The switch drivers prevent reverse current
flow in the switches and automatically discharge both batteries into the load, sharing current according to the relative
capacity of the batteries. Simultaneous dual discharge can
increase battery operating time by approximately 10%
by reducing losses in the switches and reducing internal
losses associated with high discharge rates.
SPI Interface
The SPI interface is used to write to the internal PowerPath
registers, the charger control registers, the current DAC,
and the voltage DAC. The SPI is also able to read internal
status registers. There are two types of SPI write commands. The first write command is a 1-byte command used
to load PowerPath and charger control bits. The second
write command is a 2-byte command used to load the
DACs. The SPI read command is a 2-byte command. In
order to ensure the integrity of the SPI communication,
the last bit received by the SPI is echoed back over the
MISO output after the next falling SCK. The data format
is set up so that the master has the option of aborting a
write if the returned MISO bit is not as expected.
1960fb
12
LTC1960
OPERATION
1-Byte SPI Write Format:
bit 7........byte 1..........bit 0
MOSI
D0 D1 D2 X A0 A1 A2 0
MISO
X D0 D1 D2 X A0 A1 A2
Charger Write Address:
A[2:0] = b111
Charger Write Data:
D2 = X
D1 = CHARGE_BAT2
D0 = CHARGE_BAT1
PowerPath Write Address:
A[2:0] = b110
PowerPath Write Data:
D2 = POWER_BY_DC
D1 = POWER_BY_BAT2
D0 = POWER_BY_BAT1
2-Byte SPI Write Format:
bit 7........byte 1..........bit 0
bit 7..........byte 2............bit 0
MOSI
D0 D1 D2 D3 D4 D5 D6 1
D7 D8 D9 D10 A0 A1 A2 0
MISO
X D0 D1 D2 D3 D4 D5 D6
1 D7 D8 D9 D10 A0 A1 A2
IDAC Write Address:
A[2:0] = b000
IDAC Data Bits D9-D0:
IDAC value data (MSB-LSB)
IDAC Data Bit D10 :
Normal mode = 0, low current mode = 1 (Dual battery charging is disabled)
VDAC Write Address:
A[2:0] = b001
VDAC Data Bits D10-D0:
VDAC value (MSB-LSB)
Subsequent SPI communication is inhibited until after the addressed DAC is finished loading. It is recommended that
the master transmit all zeros until MISO goes low. This handshaking procedure is illustrated in Figure 1.
SSB
BYTE 1
BYTE 2
SCK
MOSI
MISO
1960 F01
Figure 1. SPI Write to VDAC of Data = b101_0101_0101
1960fb
13
LTC1960
OPERATION
2-Byte SPI Read Format:
bit 7........byte 1.......bit 0
bit 7........byte 2............bit 0
MOSI
0 0 0 0 A0 A1 A2 0
0 0 0 0 A0 A1 A2 1
MISO
X 0 0 0 0 A0 A1 A2
X FA LP DC PF CH X
Status Address:
A[2:0] = b010
Status Read Data:
LP = LOW_POWER (Low power comparator output)
DC = DCDIV (DCDIV comparator output)
PF = POWER_FAIL (Set if selected power supply failed to hold up system power after three tries)
CH = CHARGING (One or more batteries are being charged)
FA = FAULT. This bit is set for any of the following conditions:
X
1) The LTC1960 is still in power-on reset.
2) The LTC1960 has detected a short circuit and has shut down power and charging.
3) The system has asserted a fast off using DCDIV.
Note: All other values of A[2:0] are reserved and must not be used.
A status read is illustrated in Figure 2.
SSB
BYTE 1
BYTE 2
SCK
MOSI
MISO
1960 F02
Figure 2. SPI Read of FA = 0, LP = 0, DC = 1, PF = 0, and CH = 1
1960fb
14
LTC1960
OPERATION
Battery Charger Controller
The LTC1960 charger controller uses a constant off-time,
current mode step-down architecture. During normal
operation, the top MOSFET is turned on each cycle when
the oscillator sets the SR latch and turned off when the
main current comparator ICMP resets the SR latch. While
the top MOSFET is off, the bottom MOSFET is turned on
until either the inductor current reverses, as indicated by
current comparator IREV, or the beginning of the next
cycle. The oscillator uses the equation:
1 (VDCIN − VCSN )
t OFF =
•
VDCIN
f
OSC
to set the bottom MOSFET on time. The peak inductor
current at which ICMP resets the SR latch is controlled
by the voltage on ITH. ITH is in turn controlled by several
loops, depending upon the situation at hand. The average
current control loop converts the voltage between CSP and
CSN to a representative current. Error amp CA2 compares
this current against the desired current requested by the
IDAC at the ISET pin and adjusts ITH until the IDAC value
is satisfied. The BAT1/BAT2 MUX provides the selected
battery voltage at CHGMON, which is divided down to the
VSET pin by the VDAC resistor divider and is used by error
amp EA to decrease ITH if the VSET voltage is above the 0.8V
reference. The amplifier CL1 monitors and limits the input
current, normally from the AC adapter, to a preset level
(100mV/RCL). At input current limit, CL1 will decrease the
ITH voltage and thus reduce battery charging current.
An overvoltage comparator, 0V, guards against transient
overshoots (>7%). In this case, the top MOSFET is turned
off until the overvoltage condition is cleared. This feature
is useful for batteries which “load dump” themselves by
opening their protection switch to perform functions such
as calibration or pulse mode charging.
Charging is inhibited for battery voltages below the minimum charging threshold, VCHMIN. Charging is not inhibited
when the low current mode of the IDAC is selected.
The top MOSFET driver is powered from a floating bootstrap capacitor CB. This capacitor is normally recharged
from VCC through an external diode when the top MOSFET
is turned off. A 2µF to 4.7µF capacitor across VCC to GND
is required to provide a low dynamic impedance to charge
the boost capacitor. It is also required for stability and
power-on reset purposes.
As VIN decreases towards the selected battery voltage,
the converter will attempt to turn on the top MOSFET
continuously (“dropout’’). A dropout timer detects this
condition and forces the top MOSFET to turn off, and the
bottom MOSFET on, for about 200ns at 40µs intervals to
recharge the bootstrap capacitor.
Charge MUX Switches
The equivalent circuit of a charge MUX switch driver is
shown in Figure 3. If the charger controller is not enabled,
the charge MUX drivers will drive the gate and source of
the series-connected MOSFETs to a low voltage and the
switch is off. When the charger controller is on, the charge
MUX driver will keep the MOSFETs off until the voltage at
CSN rises at least 35mV above the battery voltage. GCH1
is then driven with an error amplifier EAC until the voltage between BAT1 and CSN satisfies the error amplifier
or until GCH1 is clamped by the internal Zener diode.
The time required to close the switch could be quite long
(many ms) due to the small currents output by the error
amp and depending upon the size of the MOSFET switch.
If the voltage at CSN decreases below VBAT1 – 20mV, a
comparator CC quickly turns off the MOSFETs to prevent
reverse current from flowing in the switches. In essence,
this system performs as a low forward voltage diode.
Operation is identical for BAT2.
DCIN + 10V
(CHARGE PUMPED)
TO
BATTERY
1
FROM
CHARGER
BAT1
CSN
–
35mV
GCH1
EAC
+
SCH1
+
20mV
Q3
CC
10k
–
OFF
Q4
1960 F03
Figure 3. Charge MUX Switch Driver Equivalent Circuit
1960fb
15
LTC1960
OPERATION
Dual Charging
Note that the charge MUX switch drivers will operate
together to allow both batteries to be charged simultaneously. If both charge MUX switch drivers are enabled,
only the battery with the lowest voltage will be charged
until its voltage rises to equal the higher voltage battery.
The charge current will then share between the batteries
according to the capacity of each battery.
If both batteries are selected for charging, only batteries
with voltages above VCHMIN are allowed to charge. Dual
charging is not allowed when the low current mode of
the IDAC is selected. If dual charging is enabled when
the IDAC enters low current mode, then only BAT1 will
be charged.
voltages present at the input/output. When the output
PFET turns on, the voltage at SCP will be pulled up to a
diode drop below the source voltage by the bulk diode of
the input PFET. If the source voltage is more than 25mV
above SCP, EAP will drive the gate of the input PFET low
until the input PFET turns on and reduces the voltage
across the input/output to the EAP set point, or until the
Zener clamp engages to limit the voltage applied to the
input PFET. If the source voltage drops more than 20mV
below SCP, then comparator CP turns on SWP to quickly
prevent large reverse current in the switch. This operation
mimics a diode with a low forward voltage drop.
20mV
CP
+
Charger Start-Up
When the charger controller is enabled by the SPI Interface
block, the charger output CSN will ramp from 0V until it
exceeds the selected battery voltage. The clamp error amp
is used to prevent the charger output from exceeding the
selected battery voltage by more than 0.7V during the
start-up transient while the charge MUX switches, have
yet to close. Once the charge MUX switches have closed,
the clamp releases ITH to allow control by another loop.
OFF
–
FROM
BATTERY
1
BAT1
SWP
–
GB1I
Q7
EAP
SCP
+
25mV
GB1O
Q8
OFF
PowerPath Controller
The PowerPath switches are turned on and off via the SPI
interface, in any combination. The external P-MOSFETs
are usually connected as an input switch and an output
switch. The output switch PFET is connected in series with
the input PFET and the positive side of the short-circuit
sensing resistor, RSC. The input switch is connected in
series between the power source and the output PFET.
The PowerPath switch driver equivalent circuit is shown
in Figure 4. The output PFET is driven high and low by the
output side driver controlling pin GXXO, the PFET is either
on or off. The gate of the input PFET is driven by an error
amplifier which monitors the voltage between the input
power source (BAT1 in this case) and SCP. If the switch
is turned off, the two outputs are driven to the higher of
the two voltages present across the input/output terminals
of the switch. When the switch is instructed to turn on,
the output side driver immediately drives the gate of the
output PFET approximately 6V below the highest of the
16
RSC
CL
TO
LOAD
1960 F04
Figure 4. PowerPath Driver Equivalent Circuit
Autonomous PowerPath Switching
The LOPWR comparator monitors the voltage at the
load through the resistor divider from pin SCN. If any
POWER_BY bit is set and the LOPWR comparator trips,
then all of the switches are turned on (3-diode mode) by
the PowerPath controller to ensure that the system is
powered from the source with the highest voltage. The
PowerPath controller waits approximately 1 second, to
allow power to stabilize, and then reverts to the previous
PowerPath switch configuration. A power-fail counter is
incremented to indicate that a failure has occurred. If the
power-fail counter equals a value of 3, then the PowerPath
controller sets the switches to 3-diode mode and the PF
1960fb
LTC1960
OPERATION
bit is set in the status register. This is a three-strikes-andyou’re-out process which is intended to debounce the
PowerPath PF indicator. The power-fail counter is reset
by a PowerPath SPI write.
Short-Circuit Protection
Short-circuit protection operates in both a current mode
and a voltage mode. If the voltage between SCP and SCN
exceeds the short-circuit comparator threshold VTSC for
more than 15ms, then all of the PowerPath switches are
turned off and the FAULT bit (FA) is set. Similarly, if the
voltage at SCN falls below 3V for more than 15ms, then
all of the PowerPath switches are turned off and the FA bit
is set. The FA bit is reset by removing all power sources
and allowing the voltage at VPLUS to fall below the UVLO
threshold. If the FA bit is set, charging is disabled until
VPLUS exceeds the UVLO threshold and charging is requested via the SPI interface.
When a hard short-circuit occurs, it might pull all of the
power sources down to near 0V potentials. The capacitors
on VCC and VPLUS must be large enough to keep the circuit
operating correctly during the 15ms short-circuit event.
The charger will stop within a few microseconds leaving
a small current which must be provided by the capacitor
on VPLUS. The recommended minimum values (1µF on
VPLUS and 2µF on VCC, including tolerances) should keep
the LTC1960 operating above the UVLO trip voltage long
enough to perform the short-circuit function when the
input voltages are greater than 8V. Increasing the capacitor across VCC to 4.7µF will allow operation down to the
recommended 6V minimum.
Fast PowerPath Turn-Off
All of the PowerPath switches can be forced off by setting the DCDIV pin to a voltage between 8V and 10V. This
will have the same effect as a short-circuit event. The PF
status bit will also be set. DCDIV must be less than 5V
and VPLUS must decrease below the UVLO threshold to
re-enable the PowerPath switches.
Power-Up Strategy
All three PowerPath switches are turned on after VPLUS
exceeds the UVLO threshold for more than 250ms. This
delay is to prevent oscillation from a turn-on transient
near the UVLO threshold.
The Voltage DAC Block
The voltage DAC (VDAC) is a delta-sigma modulator
which controls the effective value of an internal resistor,
RVSET = 7.2k, used to program the maximum charger
voltage. Figure 5 is a simplified diagram of the VDAC
operation. The charger monitor MUX is connected to the
appropriate battery indicated by the CHARGE_BATx bit.
The delta-sigma modulator and switch SWV convert the
VDAC value, received via SPI communication, to a variable resistance equal to (11/8)RVSET/(VDAC(VALUE)/2047).
In regulation, VSET is servo driven to the 0.8V reference
voltage, VREF .
Therefore, programmed voltage is:
VBATx = (8/11) VREF 405.3k/7.2k • (VDAC(VALUE)/2047)
+ VREF = 32,752mV • (VDAC(VALUE)/2047) + 0.8V
Note that the reference voltage must be subtracted from
the VDAC value in order to obtain the correct output voltage. This value is VREF /16mV = 50 (32HEX).
Capacitors CB1 and CB2 are used to average the voltage
present at the VSET pin as well as provide a zero in the
voltage loop to help stability and transient response time
to voltage variations. See the Applications Information
section.
CHGMON
BAT1
BAT2
CB2
CSN
RVF
405.3k
VSET
–
TO
ITH
EA
CB1
VREF
RVSET
7.2k
SWV
+
∆Σ
MODULATOR
11
DAC
VALUE
(11 BITS)
1960 F05
Figure 5. Voltage DAC Operation
1960fb
17
LTC1960
OPERATION
The Current DAC Block
When the low current mode bit (D10) is set to 1, the current
DAC enters a different mode of operation. The current DAC
output is pulse-width modulated with a high frequency clock
having a duty cycle value of 1/8. Therefore, the maximum
output current provided by the charger is IMAX/8. The
delta-sigma output gates this low duty cycle signal on
and off. The delta-sigma shift registers are then clocked
at a slower rate, about 40ms/bit, so that the charger has
time to settle to the IMAX/8 value. The resulting average
charging current is equal to 1/8 of the current programmed
in normal mode. Dual battery charging is disabled in low
current mode. If both batteries are selected for charging,
then only BAT1 will charge.
The current DAC is a delta-sigma modulator which controls
the effective value of an internal resistor, RSET  = 18.77k,
used to program the maximum charger current. Figure 6 is
a simplified diagram of the DAC operation. The delta-sigma
modulator and switch convert the IDAC value, received
via SPI communication, to a variable resistance equal to
1.25RSET /(IDAC(VALUE)/1023). In regulation, ISET is servo
driven to the 0.8V reference voltage, VREF , and the current from RSET is matched against a current derived from
the voltage between pins CSP and CSN. This current is
(VCSP – VCSN)/3k.
Therefore, programmed current is:
I AVG =
 IDAC(VALUE) 
VREF • 3k
•
(1.25R SNS R SET ) 
1023 
(VCSP – VCSN)
3kΩ
(FROM CA1 AMPLIFIER)
ISET
+
CSET
RSET
18.77k
VREF
TO
ITH
–
∆Σ
MODULATOR
10
DAC
VALUE
(10 BITS)
1960 F06
Figure 6. Current DAC Operation
AVERAGE CHARGER CURRENT
IMAX/8
0
1960 F07
~40ms
Figure 7. Charging Current Waveform in Low Current Mode
1960fb
18
LTC1960
APPLICATIONS INFORMATION
Automatic Current Sharing
In a dual parallel charge configuration, the LTC1960 does
not actually control the current flowing into each individual
battery. The capacity, or amp-hour rating, of each battery
determines how the charger current is shared. This automatic steering of current is what allows both batteries to
reach their full capacity points at the same time. In other
words, given all other things equal, charge termination
will happen simultaneously.
A battery can be modeled as a huge capacitor and hence
governed by the same laws.
I = C • (dV/dT), where:
I = The current flowing through the capacitor
C = Capacity rating of battery (using amp-hour value
instead of capacitance)
dV = Change in voltage
dt = Change in time
The equivalent model of a set or parallel batteries is a
set of parallel capacitors. Since they are in parallel, the
change in voltage over change in time is the same for both
batteries 1 and 2.
dV
dV
=
dt BAT1 dt BAT2
From here we can simplify.
IBAT1/CBAT1 = dV/dt = IBAT2/CBAT2
IBAT2 = IBAT1 CBAT2/CBAT1
At this point you can see that the current divides as the
ratio of the two batteries capacity ratings. The sum of the
current into both batteries is the same as the current being
supply by the charger. This is independent of the mode of
the charger (CC or CV).
it is actual physical capacity rating at the time of charge.
Capacity rating will change with age and use and hence
the current sharing ratios can change over time.
In dual charge mode, the charger uses feedback from the
BAT2 input to determine charger output voltage. When
charging batteries with significantly different initial states of
charge (i.e., one almost full, the other almost depleted), the
full battery will get a much lower current. This will cause a
voltage difference across the charge MUX switches, which
may cause the BAT1 voltage to exceed the programmed
voltage. Using MOSFETs in the charge MUX with lower
RDS(ON) will alleviate this problem.
Adapter Limiting
An important feature of the LTC1960 is the ability to automatically adjust charging current to a level which avoids
overloading the wall adapter. This allows the product to
operate at the same time that batteries are being charged
without complex load management algorithms. Additionally, batteries will automatically be charged at the maximum
possible rate of which the adapter is capable.
This feature is created by sensing total adapter output current and adjusting charging current downward if a preset
adapter current limit is exceeded. True analog control is
used, with closed loop feedback ensuring that adapter
load current remains within limits. Amplifier CL1 in Figure
8 senses the voltage across RCL, connected between the
CLP and DCIN pins. When this voltage exceeds 100mV,
the amplifier will override programmed charging current
to limit adapter current to 100mV/RCL. A lowpass filter
formed by 5kΩ and 0.1µF is required to eliminate switching noise. If the current limit is not used, CLP should be
connected to DCIN.
100mV
–
ICHRG = IBAT1 + IBAT2
+
5kΩ
+
RCL*
DCIN
IBAT2 = ICHRG CBAT2/(CBAT1 + CBAT2)
Please note that the actual observed current sharing will
vary from manufactures claimed capacity ratings since
0.1µF
CL1
From here we solve for the actual current for each battery.
IBAT1 = ICHRG CBAT1/(CBAT1 + CBAT2)
CLP
+
*RCL =
100mV
ADAPTER CURRENT LIMIT
CIN
AC ADAPTER
INPUT
VIN
11960 F08
Figure 8. Adapter Current Limiting
1960fb
19
LTC1960
APPLICATIONS INFORMATION
Watchdog Timer
Charging will begin when either CHARGE_BAT1 or
CHARGE_BAT2 bits are set in the charger register (address: 111). Charging will stop if the charger register is
not updated prior to the expiration of the watchdog timer.
Simply repeating the same data transmission to the charger
register at a rate higher than once per second will ensure
that charging will continue uninterrupted.
Extending System to More Than Two Batteries
The LTC1960 can be extended to manage systems with more
than three sources of power. Contact Linear Technology
Applications Engineering for more information.
Charging Depleted Batteries
Some batteries contain internal protection switches that
disconnect a load if the battery voltage falls below what
is considered a reasonable minimum. In this case, the
charger may not start because the voltage at the battery
terminal is less than 5V. The low current mode of the IDAC
must be used in this case to condition the battery. In low
current mode, there is no minimum voltage requirement
(but dual charging is not allowed). Usually, the battery will
detect that it is being charged and then close its protection switch, which will allow the IDAC to switch to normal
mode. Smart batteries require that charging current not
exceed 100mA until valid charging voltage and charging
current parameters are transmitted via the SMBus. The
low current IDAC mode is ideal for this purpose.
Starting Charge with Dissimilar Batteries in Dual
Charge Mode
When charging batteries of different charger termination
voltages, the charger should be started using the following procedure:
Step 1. Select only the lowest termination voltage battery for charging, and set the charger to its charging
parameters.
Step 2. When the battery current is flowing into that battery, change to dual charging mode (without stopping the
charger) and set the appropriate charging parameters for
this dual charger condition.
If this procedure is not followed, and BAT2 is significantly
higher voltage than BAT1, the charger could refuse to
charge either battery.
Charge Termination Issues
Batteries with constant-current charging and voltage-based
charger termination might experience problems with reductions of charger current caused by adapter limiting. It
is recommended that input limiting feature be defeated in
such cases. Consult the battery manufacturer for information on how your battery terminates charging.
Setting Output Current Limit
The full-scale output current setting of the IDAC will produce
VMAX = 102.3mV between CSP and CSN. To set the fullscale current of the DAC simply divide VMAX by RSNS.
This is expressed by the following equation:
RSNS = 0.1023/IMAX
Table 1. Recommended RSNS Resistor Values
IMAX (A)
RSNS (Ω) 1%
RSNS (W)
1.023
0.100
0.25
2.046
0.050
0.25
4.092
0.025
0.5
8.184
0.012
1
Use resistors with low ESL.
Inductor Selection
Higher operating frequencies allow the use of smaller
inductor and capacitor values. A higher frequency generally results in lower efficiency because of MOSFET gate
charge losses. In addition, the effect of inductor value
on ripple current and low current operation must also be
considered. The inductor ripple current ∆IL decreases with
higher frequency and increases with higher VIN.
∆IL =


1
V
VOUT  1− OUT 
VIN 

( f )(L )
Accepting larger values of ∆IL allows the use of low
inductances, but results in higher output voltage ripple
and greater core losses. A reasonable starting point for
setting ripple current is ∆IL = 0.4(IMAX). In no case should
1960fb
20
LTC1960
APPLICATIONS INFORMATION
∆IL exceed 0.6(IMAX) due to limits imposed by IREV and
CA1. Remember the maximum ∆IL occurs at the maximum input voltage. In practice, 10µH is the lowest value
recommended for use.
Charger Switching Power MOSFET and Diode
Selection
Two external power MOSFETs must be selected for use with
the LTC1960 charger: An N-channel MOSFET for the top
(main) switch and an N-channel MOSFET for the bottom
(synchronous) switch.
The peak-to-peak gate drive levels are set by the VCC voltage. This voltage is typically 5.2V. Consequently, logic-level
threshold MOSFETs must be used. Pay close attention to
the BVDSS specification for the MOSFETs as well; many of
the logic-level MOSFETs are limited to 30V or less.
Selection criteria for the power MOSFETs include the onresistance RDS(ON), reverse transfer capacitance CRSS,
input voltage and maximum output current. The LTC1960
charger is always operating in continuous mode so the duty
cycles for the top and bottom MOSFETs are given by:
Main Switch Duty Cycle = VOUT /VIN
Synchronous Switch Duty Cycle = (VIN – VOUT)/VIN
The MOSFET power dissipations at maximum output
current are given by:
PMAIN = VOUT/VIN(IMAX)2(1 + d∆T)RDS(ON) + k(VIN)2
(IMAX)(CRSS)(f)
PSYNC = (VIN – VOUT)/VIN(IMAX)2(1 + d∆T) RDS(ON)
Where d∆T is the temperature dependency of RDS(ON) and
k is a constant inversely related to the gate drive current.
Both MOSFETs have I2R losses while the topside N-channel
equation includes an additional term for transition losses,
which are highest at high input voltages. For VIN < 20V,
the high current efficiency generally improves with larger
MOSFETs, while for VIN > 20V the transition losses rapidly
increase to the point that the use of a higher RDS(ON) device
with lower CRSS actually provides higher efficiency. The
synchronous MOSFET losses are greatest at high input
voltage or during a short-circuit when the duty cycle in this
switch is nearly 100%. The term (1 + d∆T) is generally
given for a MOSFET in the form of a normalized RDS(ON)
vs Temperature curve, but d = 0.005/°C can be used as
an approximation for low voltage MOSFETs. CRSS is usually specified in the MOSFET characteristics. The constant
k = 1.7 can be used to estimate the contributions of the
two terms in the main switch dissipation equation.
If the LTC1960 charger is to operate in low dropout mode
or with a high duty cycle greater than 85%, then the topside N-channel efficiency generally improves with a larger
MOSFET. Using asymmetrical MOSFETs may achieve cost
savings or efficiency gains.
The Schottky diode D1, shown in the Typical Application
on the back page, conducts during the dead-time between
the conduction of the two power MOSFETs. This prevents
the body diode of the bottom MOSFET from turning on and
storing charge during the dead-time, which could cost as
much as 1% in efficiency. A 1A Schottky is generally a good
size for 4A regulators due to the relatively small average
current. Larger diodes can result in additional transition
losses due to their larger junction capacitance. The diode
may be omitted if the efficiency loss can be tolerated.
Calculating IC Power Dissipation
The power dissipation of the LTC1960 is dependent upon the
gate charge of QTG and QBG (refer to Typical Application).
The gate charge is determined from the manufacturer’s
data sheet and is dependent upon both the gate voltage
swing and the drain voltage swing of the FET.
PD = (VDCIN – VVCC) • [fOSC(QTG + QBG) + IVCC]
+ VDCIN • IDCIN
Example: VVCC = 5.2V, VDCIN = 19V, fOSC = 345kHz,
QG2 = QG3 = 15nC, IVCC = 0mA.
PD = 165mW
1960fb
21
LTC1960
APPLICATIONS INFORMATION
VSET/ISET Capacitors
Capacitor C7 is used to filter the delta-sigma modulation
frequency components to a level which is essentially DC.
Acceptable voltage ripple at ISET is about 10mVP-P . Since
the period of the delta-sigma switch closure, T∆∑ , is about
10µs and the internal IDAC resistor, RSET , is 18.77k, the
ripple voltage can be approximated by:
∆VISET
V
•T
= REF ∆ ∑
R SET • C7
Then the equation to extract C7 is:
C7 =
VREF • T∆ ∑
∆VISET • R SET
= 0.8/0.01/18.77k(10µs) @ 0.043µF
In order to prevent overshoot during start-up transients,
the time constant associated with C7 must be shorter than
the time constant of C5 at the ITH pin. If C7 is increased
to improve ripple rejection, then C5 should be increased
proportionally and charger response time to average current variation will degrade.
Capacitor CB1 and CB2 are used to filter the VDAC deltasigma modulation frequency components to a level which
is essentially DC. CB2 is the primary filter capacitor and
CB1 is used to provide a zero in the response to cancel
the pole associated with CB2. Acceptable voltage ripple
at VSET is about 10mVP-P . Since the period of the deltasigma switch closure, T∆∑ , is about 11µs and the internal
VDAC resistor, RVSET , is 7.2kΩ, the ripple voltage can be
approximated by:
VREF • T∆ ∑
∆VVSET =
R VSET (CB1 || CB2 )
Then the equation to extract CB1 || CB2 is:
CB1 || CB2 =
VREF • T∆ ∑
R VSET ∆VVSET
CB2 should be 10× to 20× CB1 to divide the ripple voltage
present at the charger output. Therefore CB1 = 0.01µF and
CB2 = 0.1µF are good starting values. In order to prevent
overshoot during start-up transients the time constant associated with CB2 must be shorter than the time constant
of C5 at the ITH pin. If CB2 is increased to improve ripple
rejection, then C5 should be increased proportionally and
charger response time to voltage variation will degrade.
Input and Output Capacitors
In the 4A Lithium Battery Charger (Typical Application
section), the input capacitor (CIN) is assumed to absorb all
input switching ripple current in the converter, so it must
have adequate ripple current rating. Worst-case RMS ripple
current will be equal to one-half of output charging current.
Actual capacitance value is not critical. Solid tantalum,
low ESR capacitors have a high ripple current rating in a
relatively small surface mount package, but caution must
be used when tantalum capacitors are used for input or
output bypass. High input surge currents can be created
when the adapter is hot-plugged to the charger or when a
battery is connected to the charger. Solid tantalum capacitors have a known failure mechanism when subjected to
very high turn-on surge currents. Only Kemet T495 series
of “surge robust” low ESR tantalums are rated for high
surge conditions such as battery to ground.
The relatively high ESR of an aluminum electrolytic for
C15, located at the AC adapter input terminal, is helpful
in reducing ringing during the hot-plug event.
Highest possible voltage rating on the capacitor will
minimize problems. Consult with the manufacturer before
use. Alternatives include new high capacity ceramic (at
least 20µF) from Tokin, United Chemi-Con/Marcon, et al.
Other alternative capacitors include OSCON capacitors
from Sanyo.
The output capacitor (COUT) is also assumed to absorb
output switching current ripple. The general formula for
capacitor current is:
IRMS


V
0.29(VBAT )  1− BAT 
VDCIN 

=
(L1)(f)
For example:
VDCIN = 19V, VBAT = 12.6V, L1 = 10µH, and f = 300kHz,
IRMS = 0.41A.
1960fb
22
LTC1960
APPLICATIONS INFORMATION
EMI considerations usually make it desirable to minimize
ripple current in the battery leads, and beads or inductors
may be added to increase battery impedance at the 300kHz
switching frequency. Switching ripple current splits between the battery and the output capacitor depending on
the ESR of the output capacitor and the battery impedance.
If the ESR of COUT is 0.2Ω and the battery impedance is
raised to 4Ω with a bead or inductor, only 5% of the current ripple will flow in the battery.
PowerPath and Charge MUX MOSFET Selection
Three pairs of P-channel MOSFETs must be used with
the wall adapter and the two battery discharge paths. Two
pairs of N-channel MOSFETs must be used with the battery
charge path. The nominal gate drive levels are set by the
clamp drive voltage of their respective control circuitry.
This voltage is typically 6.25V. Consequently, logic-level
threshold MOSFETs must be used. Pay close attention to
the BVDSS specification for the MOSFETs as well; many of
the logic-level MOSFETs are limited to 30V or less.
Selection criteria for the power MOSFETs include the
on-resistance RDS(ON), input voltage and maximum output current. For the N-channel charge path, the maximum
current is the maximum programmed current to be used.
For the P-channel discharge path maximum current typically occurs at end of life of the battery when using only
one battery. The upper limit of RDS(ON) value is a function of
the actual power dissipation capability of a given MOSFET
package that must take into account the PCB layout. As a
starting point, without knowing what the PCB dissipation
capability would be, derate the package power rating by
a factor of two.
R DS(ON)MAX =
P MOSFET
2 (IMAX )
2
If you are using a dual MOSFET package with both MOSFETs in series, you must cut the package power rating in
half again and recalculate.
R DS(ON)MAX =
P MOSFETDUAL
4 (IMAX )
2
If you use identical MOSFETs for both battery paths, voltage
drops will track over a wide current range. The LTC1960
linear 25mV CV drop regulation will not occur until the
current has dropped below:
ILINEARMAX =
25mV
2 RDS(ON)MAX
However, if you try to use the above equation to determine
RDS(ON) to force linear mode at full current, the MOSFET
RDS(ON) value becomes unreasonably low for MOSFETs
available at this time. The need for the LTC1960 voltage
drop regulation only comes into play for parallel battery
configurations that terminate charge or discharge using
voltage. At first this seems to be a problem, but there are
several factors helping out:
1.When batteries are in parallel current sharing, the current
flow through any one battery is less than if it is running
standalone.
2. Most batteries that charge in constant-voltage mode,
such as Li-Ion, charge terminate at a current value of
C/10 or less which is well within the linear operation
range of the MOSFETs.
3. Voltage tracking for the discharge process does not
need such precise voltage tracking values.
The LTC1960 has two transient conditions that force the
discharge path P-channel MOSFETs to have two additional
parameters to consider. The parameters are gate charge
QGATE and single pulse power capability.
When the LTC1960 senses a LOW_POWER event, all
the P-channel MOSFETs are turned on simultaneously
to allow voltage recovery due to a loss of a given power
source. However, there is a delay in the time it takes to
turn on all the MOSFETs. Slow MOSFETs will require more
bulk capacitance to hold up all the system’s power supply function during the transition and fast MOSFET will
require less bulk capacitance. The transition speed of a
MOSFET to an on or off state is a direct function of the
MOSFET gate charge.
Q
t = GATE
IDRIVE
1960fb
23
LTC1960
APPLICATIONS INFORMATION
IDRIVE is the fixed drive current into the gate from the
LTC1960 and “t” is the time it takes to move that charge
to a new state and change the MOSFET conduction mode.
Hence, time is directly related to QGATE. Since QGATE
goes up with MOSFETs of lower RDS(ON), choosing such
MOSFETs has a counterproductive increase in gate charge
making the MOSFET slower. Please note that the LTC1960
recovery time specification only refers to the time it takes
for the voltage to recover to the level just prior to the
LOW_POWER event as opposed to full voltage.
The single pulse current rating of the MOSFET is important
when a short-circuit takes place. The MOSFET must survive
a 15ms overload. MOSFETs of lower RDS(ON) or MOSFETs
that use more powerful thermal packages will have a high
power surge rating. Using too small of a pulse rating will
allow the MOSFET to blow to the open-circuit condition
instantly like a fuse. Typically there is no outward sign of
failure because it happens so fast. Please measure the
surge current for all discharge power paths under worse
case conditions and consult the MOSFET data sheet for
the limitations. Voltage sources with the highest voltage
and the most bulk capacitance are often the biggest risk.
Specifically the MOSFETs in the wall adapter path with wall
adapters of high voltage, large bulk capacitance and low
resistance DC cables between the adapter and device are
the most common failures. Remember to only use the real
wall adapter with a production DC power cord when performing the wall adapter path test. The use of a laboratory
power supply is unrealistic for this test and will force you
to over specify the MOSFET ratings. A battery pack usually has enough series resistance to limit the peak current
or are too low in voltage to create enough instantaneous
power to damage their respective PowerPath MOSFETs.
The highest frequency switching loop has the highest
layout priority. For best results, avoid using vias in this
loop and keep the entire high frequency loop on a single
external PCB layer. If you must, use multiple vias to keep
the impedance down (see Figure 9).
SWITCH NODE
L1
VBAT
VIN
CIN
HIGH
FREQUENCY
CIRCULATING
PATH
1. Keep the highest frequency loop path as small and
tight as possible. This includes the bypass capacitors,
with the higher frequency capacitors being closer to
the noise source than the lower frequency capacitors.
24
COUT
BAT
1960 F09
Figure 9. High Speed Switching Path
2. Run long power traces in parallel. Best results are
achieved if you run each trace on separate PCB layer one
on top of the other for maximum capacitance coupling
and common mode noise rejection.
3. If possible, use a ground plane under the switcher
circuitry to minimize capacitive interplane noise coupling.
4. Keep signal or analog ground separate. Tie this analog
ground back to the power supply at the output ground
using a single point connection.
5. For best current programming accuracy provide a Kelvin
connection from RSENSE to CSP and CSN. See Figure  10
as an example.
DIRECTION OF CHARGING CURRENT
PCB Layout Considerations
For maximum efficiency, the switch node rise and fall
time is kept as short as possible. To prevent magnetic
and electrical field radiation and high frequency resonant
problems, proper layout of the components connected to
the IC is essential.
D1
RSNS
1960 F10
CSP
CSN
Figure 10. Kelvin Sensing of Charging Current
1960fb
LTC1960
PACKAGE DESCRIPTION
G Package
36-Lead Plastic SSOP (5.3mm)
(Reference LTC DWG # 05-08-1640)
12.50 – 13.10*
(.492 – .516)
1.25 ±0.12
7.8 – 8.2
36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 19
5.3 – 5.7
0.42 ±0.03
7.40 – 8.20
(.291 – .323)
0.65 BSC
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18
RECOMMENDED SOLDER PAD LAYOUT
2.0
(.079)
MAX
5.00 – 5.60**
(.197 – .221)
0° – 8°
0.09 – 0.25
(.0035 – .010)
0.55 – 0.95
(.022 – .037)
NOTE:
1. CONTROLLING DIMENSION: MILLIMETERS
MILLIMETERS
2. DIMENSIONS ARE IN
(INCHES)
0.65
(.0256)
BSC
0.22 – 0.38
(.009 – .015)
TYP
0.05
(.002)
MIN
G36 SSOP 0204
3. DRAWING NOT TO SCALE
*DIMENSIONS DO NOT INCLUDE MOLD FLASH. MOLD FLASH
SHALL NOT EXCEED .152mm (.006") PER SIDE
**DIMENSIONS DO NOT INCLUDE INTERLEAD FLASH. INTERLEAD
FLASH SHALL NOT EXCEED .254mm (.010") PER SIDE
1960fb
25
LTC1960
PACKAGE DESCRIPTION
UHF Package
38-Lead Plastic QFN (5mm × 7mm)
(Reference LTC DWG # 05-08-1701 Rev C)
0.70 ± 0.05
5.50 ± 0.05
5.15 ± 0.05
4.10 ± 0.05
3.00 REF
3.15 ± 0.05
PACKAGE
OUTLINE
0.25 ± 0.05
0.50 BSC
5.5 REF
6.10 ± 0.05
7.50 ± 0.05
RECOMMENDED SOLDER PAD LAYOUT
APPLY SOLDER MASK TO AREAS THAT ARE NOT SOLDERED
5.00 ± 0.10
0.75 ± 0.05
PIN 1 NOTCH
R = 0.30 TYP OR
0.35 × 45° CHAMFER
3.00 REF
37
0.00 – 0.05
38
0.40 ±0.10
PIN 1
TOP MARK
(SEE NOTE 6)
1
2
5.15 ± 0.10
5.50 REF
7.00 ± 0.10
3.15 ± 0.10
(UH) QFN REF C 1107
0.200 REF 0.25 ± 0.05
0.50 BSC
R = 0.125
TYP
R = 0.10
TYP
BOTTOM VIEW—EXPOSED PAD
NOTE:
1. DRAWING CONFORMS TO JEDEC PACKAGE
OUTLINE M0-220 VARIATION WHKD
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 0.20mm ON ANY SIDE
5. EXPOSED PAD SHALL BE SOLDER PLATED
6. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION
ON THE TOP AND BOTTOM OF PACKAGE
1960fb
26
LTC1960
REVISION HISTORY
(Revision history begins at Rev B)
REV
DATE
DESCRIPTION
PAGE NUMBER
B
04/11
Updated Absolute Maximum Ratings section
Added Note 8
2
5
Updated Pin Functions
8, 9
Updated equation in “The Current DAC Block” section
18
Updated equation in “Calculating IC Power Dissipation” section
21
Updated Typical Application
28
1960fb
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.
27
LTC1960
TYPICAL APPLICATION
(LTC1960CG Pin Numbers Shown)
Dual Battery Selector and 4A Charger
PowerPath MUX
BAT2
BAT1
VIN
R1
5.1k
1%
4.7k
R4
14k
1%
MISO
SCK
MOSI
SSB
R5
1k
1%
100Ω
C1
0.1µF
VDD
C9
100pF
C2
1µF
C6
1µF
RCL
0.03
R7
49.9k
1%
C3
0.01µF
C8
0.1µF
24
29
3
2
20
19
21
18
17
25
35
36
34
33
13
28
16
LTC1960
CLP
DCIN
BAT1
BAT2
MISO
SCK
MOSI
SSB
DCDIV
COMP1
GCH2
SCH2
GCH1
SCH1
VSET
VCC
GND
Q1, Q2, Q5, Q6, Q7, Q8: Si4925DY
Q3, Q4, Q9, Q10, QTG, QBG: FDS6912A
D1: MBR130T3
D2: CMDSH-3 TYPE
D3, D4: BAT54A TYPE
VPLUS
GDCI
GDCO
GB1I
GB1O
GB2I
GB2O
SCP
SCN
LOPWR
CSN
CSP
ITH
ISET
SW
BOOST
TGATE
BGATE
PGND
BAT2
D3
1
7
6
9
8
11
10
5
4
12
22
23
14
15
30
31
32
27
26
Q6
Q7
Q2
Q5
Q8
RSC
0.02Ω
R9
3.3k
1%
C7
0.1µF
D2
C5
0.15µF
CIN
20µF
25V
RSNS
0.025Ω
1%
QBG
CB1
0.01µF
CL
20µF
25V
L1
10µH
4A
C4
0.1µF
C6
2µF
LOAD
R2
649k
1%
R3
100k
1%
QTG
BAT1
D4
R11
1k
CB2
0.1µF
Q1
COUT
20µF 25V
CHARGE MUX
Q9
D1
R6
100Ω
Q4
Q10
Q3
1960 TA02
RELATED PARTS
PART NUMBER DESCRIPTION
COMMENTS
LT1505
Up to 97% Efficiency; AC Adapter Current Limit
High Efficiency Battery Charger
LTC1628-PG
2-Phase, Dual Synchronous Step-Down Controller
Minimizes CIN and COUT ; Power Good Output; 3.5V ≤ VIN ≤ 36V
LTC1709
2-Phase, Dual Synchronous Step-Down Controller
with VID
Up to 42A Output; Minimum CIN and COUT ; Uses Smallest Components for Intel
and AMD Processors
LTC3711
No RSENSE™ Synchronous Step-Down Controller
with VID
3.5V ≤ VIN ≤ 36V; 0.925V ≤ VOUT ≤ 2V; for Transmeta, AMD and Intel Mobile
Processors
LTC1759
SMBus Controlled Smart Battery Charger
Synchronous Operation for High Efficiency; Integrated SMBus Accelerator;
AC Adapter Current Limit
LT1769
2A Battery Charger
Constant-Current/Constant-Voltage Switching Regulator; Input Current Limiting
Maximizes Charge Current
1960fb
28 Linear Technology Corporation
LT 0411 REV B • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com
 LINEAR TECHNOLOGY CORPORATION 2001