LINER LT1571

Final Electrical Specifications
LT1571 Series
Constant-Current/
Constant-Voltage Battery Charger
with Preset Voltage and Termination Flag
April 2000
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FEATURES
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DESCRIPTIO
Fast Charging of Li-Ion, NiMH and NiCd Batteries
Simple Charge Current Programming Requires Only
One Low Cost, 1/32W Resistor
High Efficiency Charger with Up to
1.5A Charge Current
Precision 0.6% Internal Voltage Reference
Preset Battery Voltages: 4.1V, 4.2V, 8.2V, 8.4V
500kHz or 200kHz Switching Frequency
Minimizes Charger Size
Low Reverse Battery Drain Current: 5µA
Flag Indicates Li-Ion Charge Completion
5% Typical Charge Current Accuracy
Low Shutdown Current
LT1571-5: 500kHz, Fixed 4.1V or 4.2V
LT1571-1: 200kHz, Adjustable Voltage
LT1571-2: 200kHz, Fixed 8.2V or 8.4V
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APPLICATIO S
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Cellular Phones, PDAs, Notebook Computers,
Portable Instruments
Cradle Chargers for Li-Ion, NiCd, NiMH and
Lead-Acid Rechargeable Batteries
LT1571 can charge batteries ranging from 1V to 20V. A
saturating switch operating at 200kHz (LT1571-1,
LT1571-2) or 500kHz (LT1571-5) gives high efficiency
and small charger size. A logic output (flag) indicates
Li-Ion near full charge when the charge current drops to
20% of the programmed value. The LT1571-1 and
LT1571-2 are in a 28-pin fused lead narrow SSOP power
package. The LT1571-5 is in a 16-pin fused lead narrow
SSOP power package.
, LTC and LT are registered trademarks of Linear Technology Corporation.
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The LT ®1571 PWM battery charger is a simple, efficient
solution to fast-charge rechargeable batteries including
lithium-ion (Li-Ion), nickel-metal-hydride (NiMH) and
nickel-cadmium (NiCd) using constant-current and/or
constant-voltage control. The internal switch is capable
of delivering 1.5A DC current (2A peak current). The
onboard current sense resistor (0.1Ω) allows simple
charge current programming to within 5% accuracy
using a low cost external resistor. The constant-voltage
output can be selected for 4.1V or 4.2V per cell with 0.6%
accuracy.
TYPICAL APPLICATIO
D3
MBRM120T3
VIN
8.2V
TO 20V
D1
MBRM120T3
VCC
CIN*
10µF
VDD
PROG
1µF
100k
SW
LT1571-5
6.19k
D2
MMBD914L
VC
1k
CHARGE
COMPLETE
4.2V
Li-Ion
BATTERY
+
+
COUT***
22µF
L1**
10µH
BOOST
0.33µF
300Ω
C1
0.22µF
SENSE
CAP
FLAG
BAT
SELECT
BAT2
GND
0.1µF
*TOKIN OR MARCON CERAMIC SURFACE MOUNT
**COILTRONICS TP3-100, 10µH, 2.2mm HEIGHT (0.8A CHARGING CURRENT)
COILTRONICS TP1 SERIES, 10µH, 1.8mm HEIGHT (<0.5A CHARGING CURRENT)
***PANASONIC EEFCD1B220
1571 F01
Figure 1. Compact Li-Ion Cellular Phone Charger (0.8A)
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.
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LT1571 Series
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ABSOLUTE
RATI GS
(Note 1)
Supply Voltage (VCC) .............................................. 28V
BOOST Pin Voltage with Respect to VCC ................. 20V
FLAG Pin Voltage ..................................................... VCC
IBAT (Average)........................................................ 1.5A
Switch Current (Peak) .............................................. 2A
Storage Temperature Range ................. – 65°C to 150°C
Operating Ambient
Temperature Range (Note 2) .................. – 40°C to 85°C
Operating Junction
Temperature Range .............................. – 40°C to 125°C
Lead Temperature (Soldering, 10 sec).................. 300°C
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PACKAGE/ORDER I FOR ATIO
TOP VIEW
TOP VIEW
TOP VIEW
**GND 1
16 GND**
1
28 GND**
**GND
1
28 GND**
**GND
2
27 GND**
**GND
2
27 GND**
**GND
3
26 GND**
**GND
3
26 GND**
SW
4
25 GND**
SW
4
25 GND**
SW 2
15 VCC1*
BOOST
5
24 VCC1*
BOOST
5
24 VCC1*
BOOST 3
14 VCC2*
NC
6
23 VCC2*
BAT2
6
23 VCC2*
FLAG
7
22 CAP
FLAG
7
22 CAP
NC
8
21 PROG
SELECT
9
20 VC
BAT2 4
13 CAP
FLAG 5
12 PROG
NC
8
21 PROG
SELECT 6
11 VC
VFB
9
20 VC
SENSE 7
10 BAT
SENSE 10
19 BAT
SENSE 10
19 BAT
**GND 8
9 GND**
**GND 11
18 GND**
**GND 11
18 GND**
**GND 12
17 GND**
**GND 12
17 GND**
**GND 13
16 GND**
**GND 13
16 GND**
**GND 14
15 GND**
**GND 14
15 GND**
GN PACKAGE
16-LEAD NARROW PLASTIC SSOP
TJMAX = 125°C, θJA = 75°C/ W
* VCC1 AND VCC2 SHOULD BE CONNECTED
TOGETHER CLOSE TO THE PINS
** FOUR CORNER PINS ARE FUSED TO
INTERNAL DIE ATTACH PADDLE FOR
HEAT SINKING. CONNECT THESE FOUR
PINS TO EXPANDED PC LANDS FOR
PROPER HEAT SINKING
GN PACKAGE
28-LEAD NARROW PLASTIC SSOP
TJMAX = 125°C, θJA = 40°C/ W
GN PACKAGE
28-LEAD NARROW PLASTIC SSOP
TJMAX = 125°C, θJA = 40°C/ W
* VCC1 AND VCC2 SHOULD BE CONNECTED TOGETHER
CLOSE TO THE PINS
** ALL GND PINS ARE FUSED TO INTERNAL DIE ATTACH
PADDLE FOR HEAT SINKING. CONNECT THESE PINS TO
EXPANDED PC LANDS FOR PROPER HEAT SINKING
40°C/W THERMAL RESISTANCE ASSUMES AN INTERNAL
GROUND PLANE DOUBLING AS A HEAT SPREADER
* VCC1 AND VCC2 SHOULD BE CONNECTED TOGETHER
CLOSE TO THE PINS
** ALL GND PINS ARE FUSED TO INTERNAL DIE ATTACH
PADDLE FOR HEAT SINKING. CONNECT THESE PINS TO
EXPANDED PC LANDS FOR PROPER HEAT SINKING
40°C/W THERMAL RESISTANCE ASSUMES AN INTERNAL
GROUND PLANE DOUBLING AS A HEAT SPREADER
ORDER PART NUMBER
ORDER PART NUMBER
ORDER PART NUMBER
LT1571EGN-5
LT1571EGN-1
LT1571EGN-2
Consult factory for Industrial and Military grade parts.
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**GND
LT1571 Series
ELECTRICAL CHARACTERISTICS
The ● denotes specifications which apply over the full operating temperature range, otherwise specifications are TA = 25°C.
VCC = 16V (LT1571-1, LT1571-2), VCC = 10V (LT1571-5), VBAT = 8V (LT1571-1,LT1571-2), VBAT = 4V (LT1571-5), maximum operating
VCC = VMAX = 26V, no load on any outputs unless otherwise noted. (Note 6)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
5.2
7
mA
1.0
1.07
1.09
1.65
125
130
A
A
A
mA
mA
1.0
1.07
A
5
15
µA
Overall
Supply Current
VPROG = 2.7V
DC Battery Charging Current, IBAT
8V ≤ VCC ≤ 26V, 0V ≤ VBAT ≤ 20V (LT1571-1)
RPROG = 4.93k
RPROG = 4.93k, TJ < 0°C
RPROG = 3.28k
RPROG = 49.3k
RPROG = 49.3k, TJ < 0°C
●
●
●
●
0.93
0.91
1.35
75
70
VCC = 26V, VBAT = 20V (LT1571-1)
RPROG = 4.93k
●
0.93
VBAT ≤ 20V, 0°C ≤ TJ ≤ 70°C (LT1571-1)
●
1.5
100
Shutdown
Auto Shutdown, Reverse Current from Battery
(When Adapter in Figure 1 Circuit is Removed)
Shutdown Threshold at VC Pin
When VCC is Connected
Shutdown Supply Current
40
VC ≤ 40mV
80
mV
0.15
0.3
mA
2.465
2.465
2.465
2.480
2.489
2.480
V
V
V
Reference
Reference Voltage (LT1571-1)
RPROG = 4.93k. Measured at VFB, with VA
Supplying IPROG and Switch Off
8V ≤ VCC ≤ 26V, 0°C ≤ TJ ≤ 70°C
8V ≤ VCC ≤ 26V, 0°C ≤ TJ ≤ 125°C
8V ≤ VCC ≤ 26V, TJ < 0°C (Note 5)
●
●
●
2.446
2.441
2.430
RPROG = 4.93k. Measured at BAT2 Pin
TJ = 25°C
8V ≤ VCC ≤ 26V, 0°C ≤ TJ ≤ 125°C
●
–1
1
%
%
–40
40
%
6
µA
0.20
0.085
0.28
0.13
A
A
4
4.5
V
V
Preset Battery Voltage
LT1571-2: 8.2V/8.4V
LT1571-5: 4.1V/4.2V
Voltage Setting Resistors Tolerance (R4, R5)
Absolute Value, Not Matching
BAT2 Pin Input Current (LT1571-2, LT1571-5)
VBAT2 = VPRESET – 1V
0.5
●
Charge Completion Flag (Comparator E6)
Charge Completion Threshold (Note 8)
RPROG = 4.93k
RPROG = 4.93k, RCAP = 65.6k
0.14
0.05
Threshold on CAP Pin
Low-to-High Threshold
High-to-Low Threshold
0.6
FLAG (Open Collector) Output Low
VCAP = 4.5V, IFLAG ≤ 1mA
●
0.3
V
FLAG Pin Leakage Current
VCAP = 0.6V, VCC = 26V
●
3
µA
Voltage Amplifier VA
Transconductance
Output Current from 100µA to 500µA
0.3
Output Source Current
VPROG = VREF, VFB = VREF + 10mV
VFB Input Bias Current (LT1571-1)
At 0.75mA Output Current
●
Minimum Input Operating Voltage
Undervoltage Lockout
●
Boost Pin Current
VCC – VBOOST ≤ 20V
20V < VCC – VBOOST ≤ 26V
2V ≤ VBOOST – VCC ≤ 8V (Switch ON)
8V < VBOOST – VCC ≤ 20V (Switch ON) (LT1571-1)
●
●
●
●
0.6
2.5
±3
±15
7
7.8
V
0.10
0.25
6
8
20
30
11
14
µA
µA
mA
mA
1.3
mho
mA
nA
Overall
6.2
3
LT1571 Series
ELECTRICAL CHARACTERISTICS
The ● denotes specifications which apply over the full operating temperature range, otherwise specifications are TA = 25°C.
VCC = 16V (LT1571-1, LT1571-2), VCC = 10V (LT1571-5), VBAT = 8V (LT1571-1,LT1571-2), VBAT = 4V (LT1571-5), maximum operating
VCC = VMAX = 26V, no load on any outputs unless otherwise noted. (Note 6)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
0.3
0.5
2.0
Ω
Ω
Switch
Switch ON Resistance
ISW = 1.5A, VBOOST – VSW ≥ 2V
ISW = 1A, VBOOST – VSW < 2V (Unboosted)
∆IBOOST/∆ISW During Switch ON
VBOOST = (VCC + 8V), ISW ≤ 1A
20
35
mA/A
Switch OFF Leakage Current
VSW = 0V, VCC ≤ 20V
VSW = 0V, 20V < VCC ≤ 26V
2
4
100
200
µA
µA
VCC – 2
V
Maximum VBAT with Switch ON
●
●
●
Minimum IPROG for Switch ON
Minimum IPROG for Switch OFF
●
1
4
1
2.4
27
µA
mA
Current Sense Amplifier Inputs (SENSE, BAT)
Sense Resistance (RS1)
0.08
0.12
Ω
Total Resistance from SENSE to BAT (Note 3)
0.2
0.25
Ω
– 200
700
– 375
1300
5
µA
µA
µA
180
440
200
500
220
550
kHz
kHz
●
●
●
●
170
160
425
400
200
230
230
575
575
kHz
kHz
kHz
kHz
●
87
90
77
93
81
125
210
BAT Bias Current (Note 4)
VC < 0.3V
VC > 0.6V
VC < 40mV
●
Oscillator
Switching Frequency
LT1571-1, LT1571-2
LT1571-5
Switching Frequency Tolerance
All Conditions of VCC, Temperature,
LT1571-1, LT1571-2
LT1571-1, LT1571-2, TJ < 0°C
LT1571-5
LT1571-5, TJ < 0°C
Maximum Duty Cycle
LT1571-1, LT1571-2
LT1571-1, LT1571-2, TA = 25°C (Note 7)
LT1571-5
●
500
%
%
%
Current Amplifier (CA2)
Transconductance
VC = 1V, IVC = ±1µA
Maximum VC for Switch OFF
IVC Current (Out of Pin)
●
VC ≥ 0.6V
0.2V < VC < 0.45V
VC < 40mV (Shutdown)
Note 1: Absolute Maximum Ratings are those values beyond which the life
of a device may be impaired.
Note 2: The LT1571 is guaranteed to meet performance specifications
from 0°C to 70°C. Specifications over the – 40°C to 85°C operating
temperature range are assured by design, characterization and correlation
with statistical process controls.
Note 3: Sense resistor RS1 and package bond wires.
Note 4: Current (≈ 700µA) flows into the pins during normal operation and
also when an external shutdown signal on the VC pin is greater than 0.3V.
Current decreases to ≈ 200µA and flows out of the pins when external
shutdown holds the VC pin below 0.3V but above shutdown threshold.
Current drops to near zero when input voltage collapses. See External
Shutdown in Applications Information section.
4
550
µmho
0.6
V
100
3
300
µA
mA
µA
Note 5: A linear interpolation can be used for reference voltage
specification between 0°C and – 40°C.
Note 6: Maximum allowable ambient temperature may be limited by power
dissipation. Parts may not necessarily be operated simultaneously at
maximum power dissipation and maximum ambient temperature.
Temperature rise calculations must be done as shown in the Applications
Information section to ensure that maximum junction temperature does
not exceed the 125°C limit. With high power dissipation, maximum
ambient temperature may be less than 70°C.
Note 7: 91% maximum duty cycle is guaranteed by design if VBAT or VX
(see Figure 7 in Application Information) is kept between 3V and 5V.
Note 8: See “Lithium-Ion Charging Completion” in the Applications
Information section.
LT1571 Series
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GND: Ground Pin.
SW: NPN Power Switch Emitter. The Schottky catch diode
must be placed with very short lead length in close
proximity to SW pin and GND.
VCC1, VCC2: Input Supply. For good bypass, a low ESR
capacitor of 10µF or higher is required, with the lead length
kept to a minimum. VCC should be between 8V and 26V
and at least 2V higher than VBAT for VBAT less than 10V, and
2.5V higher than VBAT for VBAT greater than 10V. Undervoltage lockout starts and switching stops when VCC goes
below 7V (typical). Note that there is an internal parasitic
diode from SW pin to VCC pin. Do not force VCC below SW
by more than 0.7V with battery present. All VCC pins
should be shorted together close to the pins.
BOOST: This pin is used to bootstrap and drive the NPN
switch to a low on-voltage for low power dissipation. VBOOST
= VCC + VBAT when switch is on. For less power dissipation
use VBOOST = 3V to 6V (see Applications Information).
SENSE: Current Amplifier CA1 Input. Sensing can be at
either terminal of the battery. Note that current sense
resistor RS1 (0.08Ω) is between SENSE and BAT pins.
BAT: Current Amplifier CA1 Input.
BAT2 (LT1571-2, LT1571-5): This pin is used to connect
the battery to the internal preset voltage setting resistor.
An internal switch disconnects the internal divider from
the battery when the device is in shutdown or when input
power is disconnected. This disconnect function
eliminates current drain due to the resistor divider. This
pin should be connected to the positive node of the
battery if the internal preset divider is used. Otherwise
this pin should be grounded. Maximum voltage on this
pin is 20V.
PROG: This pin is for programming the charge current
and for system loop compensation. Charge current is
regulated to 2000× the current drawn from the PROG
pin. During normal operation, VPROG stays close to
2.465V. If it is shorted to GND, switching will stop. When
a microprocessor-controlled DAC is used to program
charge current, it must be capable of sinking current at a
compliance up to 2.465V.
VC: This is the inner loop control signal of the current mode
PWM. Switching starts at 0.9V. In normal operation, a
higher VC corresponds to a higher charge current. A
capacitor of at least 0.1µF to GND filters out noise and
controls the rate of soft-start. To shut down switching, pull
this pin below 0.6V. Typical current out of this pin is 60µA.
When VC is pulled below 40mV, LT1571 supply current
drops to typical 150µA.
SELECT (LT1571-2, LT1571-5): This pin is used to select
the preset battery voltage. For the LT1571-2, leave this pin
open for 8.2V and ground it for 8.4V. For the LT1571-5,
leave this pin open for 4.1V and ground it for 4.2V. For
other battery voltages, use the adjustable LT1571-1.
VFB (LT1571-1): This is the input to the amplifier VA (see
Block Diagram) with a threshold of 2.465V. Typical input
current is about 3nA. When charging batteries, VA monitors the battery voltage and reduces charging current
when battery voltage reaches the preset value. If it is not
used (constant-current only mode), the VFB pin should be
grounded.
CAP: A 0.1µF capacitor from CAP to ground is needed to
filter the sampled charge current signal. This filtered
signal is used to set the FLAG pin when the charge current
drops to 20% of the programmed maximum charge current. This threshold level can be set as low as 7.5% of the
programmed maximum charge current by adding a resistor on the CAP pin.
FLAG: This pin is an open-collector output that is used to
indicate end of charge. The FLAG pin is driven low when
the charge current drops below a certain percentage of the
programmed charge current as explained in the CAP pin
function. A pull-up resistor is required if this function is
used. This pin is capable of sinking at least 1mA. Maximum voltage on this pin is VCC.
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LT1571 Series
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BLOCK DIAGRA
80mV
+
+
–
VC
SHUTDOWN
0.2V
BAT
+
VCC
+VIN
200kHz/500kHz
OSCILLATOR
+
–
D2
BOOST
S
–
VCC
+
C1
QSW
R
R
L1
SW
+
GND
D1
1.5V
–
PWM
C1
–
+
SLOPE
COMPENSATION
R2
SENSE
+
B1
+
VBAT
IBAT
CA1
–
R1 IPROG = 500µA/A
1k IBAT
RS1
BAT
IBAT
BATTERY
R3
+
IPROG
A11
–
BAT2
(LT1571-2,
LT1571-5
ONLY)
–
VC
CA2
+
75k
IVA
4
IVA
CAP
–
E6
VFB
(LT1571-1
ONLY)
+
VA
IPROG
+
FLAG
R7
VREF
VREF
2.465V
R6
11k
R5
2k
+
R4
SELECT
(LT1571-2,
LT1571-5
ONLY)
–
4V
PROG
NOTES: LT1571-2: R4 = 7.1k, R7 = 30.24k
LT1571-5: R4 = 3.33k, R7 = 8.62k
LT1571-1: 200kHz, VFB PIN FOR ADJUSTABLE
BATTERY VOLTAGE (VFB PIN IS NOT INTERNALLY
CONNECTED TO THE RESISTORS)
LT1571-2: 200kHz, PRESET 8.2V CELL
(SELECT PIN OPEN) OR 8.4V (SELECT PIN GROUNDED)
LT1571-5: 500KHz, PRESET 4.1V CELL
(SEECT PIN OPEN) OR 4.2V (SELECT PIN GROUNDED)
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RPROG
VBAT
 2.465V 
IBAT = 
 • 2000
 RPROG 
CPROG
1571 BD
LT1571 Series
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OPERATIO
The LT1571 is a current mode PWM step-down (buck)
charger. The battery charge current is programmed by a
resistor RPROG (or a DAC output current) at the PROG pin
(see Block Diagram). Amplifier CA1 converts the charge
current through RS1 to a much lower current IPROG (500µA/
A) fed into the PROG pin. Amplifier CA2 compares the
output of CA1 with the programmed current and drives the
PWM loop to force them to be equal. High DC accuracy is
achieved with averaging capacitor CPROG. Note that IPROG
has both AC and DC components. IPROG goes through R1
and generates a ramp signal that is fed to the PWM control
comparator C1 through buffer B1 and level shift resistors
R2 and R3, forming the current mode inner loop. The
BOOST pin drives the NPN switch (QSW) into saturation
and reduces power loss. For batteries like lithium-ion that
require both constant-current and constant-voltage charging, the 0.5%, 2.465V reference and the amplifier VA
reduce the charge current when battery voltage reaches
the preset level. For NiMH and NiCd, VA can be used for
overvoltage protection. When input voltage is removed,
the VCC pin drops to 0.7V below the battery voltage forcing
the charger into a low-battery drain (5µA typical) sleep
mode. To shut down the charger, simply pull the VC pin low
with a transistor.
Comparator E6 monitors the charge level and signals
through the FLAG pin when charging is in voltage mode
and the charge current has reduced to 20% or less. This
charge complete signal can be used to start a timer for
charging termination.
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APPLICATIO S I FOR ATIO
Input and Output Capacitors
In the charger circuits in Figures 1 and 2, 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 the output charge current. Actual
capacitance value is not critical. Solid tantalum capacitors
such as the AVX TPS and Sprague 593D series have high
ripple current rating in a relatively small surface mount
package, but caution must be used when tantalum capacitors are used for input bypass. High input surge currents
are possible when the adapter is hot-plugged to the
charger and solid tantalum capacitors have a known
failure mechanism when subjected to very high turn-on
surge currents. Selecting a high voltage rating on the
capacitor will minimize problems. Consult with the manufacturer before use. Alternatives include new high capacity
ceramic capacitors from Tokin or United Chemi-Con/
MARCON, et al. OS-CON can also be used.
The output capacitor COUT is also assumed to absorb
output switching ripple current. The general formula for
capacitor ripple current is:
 V 
0.29(VBAT ) 1 − BAT 

VCC 
IRMS =
(L1)( f)
For example, with VCC = 16V, VBAT = 8.4V, L1 = 33µH and
f = 200kHz, IRMS = 0.18A.
EMI considerations usually make it desirable to minimize
ripple current in the battery leads. Beads or inductors can
be added to increase battery impedance at the 200kHz
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 of inductor, only 5% of the
ripple current will flow into the battery.
Soft-Start
The LT1571 is soft-started by the 0.3µF capacitor on VC
pin. On start-up, the VC pin voltage will rise quickly to 0.5V,
then ramp at a rate set by the internal 45µA pull-up current
and the external capacitor. Charge current starts ramping
up when the VC pin voltage reaches 0.9V and full current
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LT1571 Series
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APPLICATIO S I FOR ATIO
is achieved with VC at 1.1V. With a 0.3µF capacitor, the
time to reach full charge current is about 9ms and it is
assumed that input voltage to the charger will reach full
value in less than 3ms. Capacitance can be increased up to
1µF if longer input start-up times are needed.
The lockout voltage will be VIN = VZ + 1V.
In any switching regulator, conventional time-based soft
starting can be defeated if the input voltage rises much
slower than the time-out period. This happens because the
switching regulators in the battery charger and the computer power supply are typically supplying a fixed amount
of power to the load. If the input voltage comes up slowly
compared to the soft-start time, the regulators will try to
deliver full power to the load when the input voltage is still
well below its final value. If the adapter is current limited,
it cannot deliver full power at reduced output voltages and
the possibility exists for a quasi “latch” state where the
adapter output stays in a current limited state at reduced
output voltage. For instance, if maximum charger plus
computer load power is 20W, a 24V adapter might be
current limited at 1A. If adapter voltage is less than (20W/1A
= 20V) when full power is drawn, the adapter voltage will be
pulled down by the constant 20W load until it reaches a lower
stable state where the switching regulators can no longer
supply full load. This situation can be prevented by utilizing
undervoltage lockout, set higher than the minimum adapter
voltage where full power can be achieved.
Charge Current Programming
A fixed undervoltage lockout of 7V is built into the LT1571.
A higher lockout voltage can be implemented with a Zener
diode D2 (see Figure 2).
For example, for a 24V adapter to start charging at 22VIN,
choose VZ = 21V. When VIN is less than 22V, D1 keeps VC
low and charger off.
The basic formula for charge current is (see Block
Diagram):
 2.465V 
IBAT = (IPROG)(2000) = 
 (2000)
 R PROG 
where RPROG is the total resistance from PROG pin to
ground.
For example, 1A charge current is needed.
RPROG =
(2.465V)(2000) = 4.93k
1A
Charge current can also be programmed by pulse width
modulating IPROG with a switch Q1 to RPROG at a frequency
higher than a few kHz (Figure 3). Charge current will be
proportional to the duty cycle of Q1 with full current at
100% duty cycle.
When a microprocessor DAC output is used to control
charge current, it must be capable of sinking current
at a compliance up to 2.5V if connected directly to the
PROG pin.
LT1571
PROG
D3
300Ω
VIN
D2
VZ
D1
1N4148
VC
2k
RPROG
4.64k
VCC
LT1571
GND
1571 F02
Figure 2. Undervoltage Lockout
8
5V
0V
CPROG
1µF
Q1
VN2222
PWM
IBAT = (DC)(1A)
1571 F03
Figure 3. PWM Current Programming
LT1571 Series
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Lithium-Ion Charging
The circuit in Figure 4 uses the 28-pin LT1571-2 to charge
lithium-ion batteries at a constant 1A until the battery
voltage reaches 8.4V preset battery voltage. The charger
will then automatically go into a constant-voltage mode
with current decreasing to near zero over time as the
battery reaches full charge.
Lithium-Ion Charge Completion
Some battery manufacturers recommend termination of
constant-voltage float mode after charge current has
dropped below a specified level (typically around 10% to
20% of the full current) and a further time-out period of 30
minutes to 90 minutes has elapsed. Check with manufacturer for details. The LT1571 provides a signal at the FLAG
pin when the charger is in voltage mode and charge
current has reduced to approximately 20% of full current.
Note that full current is (2.465V × 2000)/RPROG. Comparator E6 in the Block Diagram compares the charge current
sample IPROG to the output current IVA voltage amplifier
VA. When the charge current drops to 20% of full current,
IPROG will be equal to 0.25 IVA and the open-collector
output VFLAG will go low. This signal can be used to start
an external timer or to terminate the charge. When this
feature is used, a capacitor of at least 0.1µF is required at
CAP pin to filter out the switching noise and a pull-up
resistor is also needed at FLAG pin.
Charge Termination Flag Threshold Setting
The charge termination flag threshold can be reduced
from the default 20% level to as low as 7.5% of the
programmed full charge current. This is done by adding a
resistor RCAP from the CAP pin to ground (see Figure 5).
The formula for selecting the RCAP resistor is:
Threshold = 0.20 – (1.331)
or
RCAP =
(1.331)RPROG
0.20 – Threshold
RPROG is the charge current setting resistor.
LT1571
CAP
1571 F05
Figure 5. Reducing Charge Termination Threshold
D3
MBRM120T3
SW
L1**
33µH
RCAP
0.1µF
D1
MBRM120T3
C1
0.22µF
VCC
PROG
D2
MMBD914L
1µF
0.3µF
SENSE
VC
4.93k
100k
300Ω
1k
CAP
0.1µF
VIN
11V
TO 26V
CIN*
10µF
LT1571-2
BOOST
RPROG
RCAP
SELECT
FLAG
BAT
GND
BAT2
+
COUT
22µF
TANT
NOTE: COMPLETE LITHIUM-ION CHARGER, NO TERMINATION REQUIRED
* TOKIN OR MARCON CERAMIC SURFACE MOUNT
** COILTRONICS CTX33-2
+
8.4V
1571 F04
Figure 4. 200kHz Charging Lithium Batteries (Efficiency at 1A > 87%)
9
LT1571 Series
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For example, if 10% threshold is needed for the 1A charger
(see Figure 4), then with RPROG = 4.93k:
RCAP =
1.331 • 4.93k
= 65.6k
0.20 – 0.10
Because of low level errors, as the threshold level is
reduced, the accuracy is also reduced. It is not recommended to program a level less than 7.5%.
Preset Battery Voltage Settings
The LT1571-2 operates at 200kHz and is preset for 8.2V
battery voltage with SELECT pin floating and 8.4V with
SELECT pin grounded.
The LT1571-5 operates at 500kHz and is preset for 4.1V
battery voltage with SELECT pin floating and 4.2V with
SELECT pin grounded.
BAT2 pin is for Kelvin sensing the battery voltage and
should be connected to the battery.
Other Battery Voltage Settings
For battery voltages other than the preset voltages, the
LT1571-1 should be used. It operates at 200kHz and the
battery voltage is programmed with R3 and R4 divider at
VFB pin (Figure 6).
VBAT
VFB
(R4)(VBAT − 2.465)
External Shutdown
The LT1571 can be externally shut down by pulling the VC
pin low with an open-drain N-FET, such as 2N7002. The VC
pin should be pulled below 0.6V to stop switching. When
VC is pulled below 40mV, LT1571 supply current drops to
typical 150µA.
Removing input power to the charger puts the LT1571 into
a sleep mode and draws only 5µA from the battery.
Nickel-Cadmium and Nickel-Metal-Hydride Charging
The circuit in Figure 7 uses the LT1571-1 to charge NiCd
or NiMH batteries up to 20V with charge currents of 0.5A
when Q1 is on and 50mA when Q1 is off.
For a 2-level charger, R1 and R2 are found from:
IBAT =
R4
1571 F06
Figure 6. Programming Other Battery Voltages
Current through the R3/R4 divider is set at a compromise
value of 25µA to minimize battery drain when the charger
is off. The VFB pin input current of 3nA contributes very
little output voltage error and can be neglected.
With divider current set at 25µA, R4 = 2.465/25µA = 100k
and,
2.465
Lithium-ion batteries typically require float voltage accuracy of 1% to 2%. Accuracy of the LT1571-1 VFB voltage
is ±0.5% at 25°C and ±1% over full temperature. This
leads to the possibility that very accurate (0.1%) resistors
might be needed for R3 and R4. Actually, the temperature
of the LT1571-1 rarely exceeds 50°C in float mode
because charge currents have tapered off to a low level, so
0.25% resistors normally provide the required level of
overall accuracy.
R3
LT1571-1
10
R3 =
(2000)(2.465)
R PROG
(2.465)(2000)
R1 =
ILOW
R2 =
(2.465)(2000 )
IHI − ILOW
All battery chargers with fast-charge rates require some
means to detect full charge in the battery and terminate the
high charge current. NiCd batteries are typically charged at
high current until the battery temperature begins to increase or until the battery voltage reaches a peak and
begins to decrease (– dV/dt). This is an indication of near
full charge. The charge current is then reduced to a much
LT1571 Series
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D3
1N5819
C1
D1
0.22µF 1N5819
SW
VCC
CIN*
10µF
BOOST PROG
L1**
33µH
D2
1N914
300Ω
0.1µF
VC
R1
100k
R2
11k
1k
Q1
VN2222
IBAT
SENSE
* TOKIN OR MARCON CERAMIC
SURFACE MOUNT
** COILTRONICS CTX33-2
BAT
+
PBIAS = (3.5mA )(VIN) + 1.5mA(VBAT )
2
VBAT )
(
+
VIN
1µF
LT1571-1
GND
VIN
(WALL ADAPTER)
COUT
22µF
TANT
+
2V TO
20V
ON: IBAT = 0.5A
OFF: IBAT = 0.05A
1571 F07
[7.5mA + (0.012)(IBAT )]
BAT 
(IBAT )(VBAT )2  1+ V30


PDRIVER =
55(VIN)
2
IBAT ) (RSW )(VBAT )
(
+ ( tOL )(VIN)(IBAT )( f)
PSW =
V
IN
PSENSE = (0.18Ω)(IBAT )
2
Figure 7. Charging NiMH or NiCd Batteries with
Constant Current (Efficiency at 0.5A ≈ 90%)
lower value and maintained as a constant trickle charge.
An intermediate “top off” current may also be used for a
fixed time period to reduce total charge time.
NiMH batteries are similar in chemistry to NiCd but have
two differences related to charging. First, the inflection
characteristic in battery voltage as full charge is
approached is not nearly as pronounced. This makes it
more difficult to use – dV/dt as an indicator of full charge,
and an increase in temperature is more often used with a
temperature sensor located in the battery pack. Secondly,
constant trickle charge may not be recommended. Instead, a moderate level of current is used on a pulse basis
(≈ 1% to 5% duty cycle) with the time-averaged value
substituting for a constant low trickle.
Thermal Calculations
If the LT1571 is used for charge currents above 0.4A, a
thermal calculation should be done to ensure that junction
temperature will not exceed 125°C. Power dissipation in
the IC is caused by bias and driver current, switch resistance, switch transition losses and the current sense
resistor. The following equations show that maximum
practical charge current for the 16-pin SSOP package
(75° C/W thermal resistance) is about 1.2A for an 8.4V
battery and 1.4A for a 4.2V battery. This assumes a 60°C
maximum ambient temperature. The 28-pin SSOP, with a
thermal resistance of 40°C/W, can provide a full 1.5A
charge current in many situations.
RSW = Switch ON resistance ≈ 0.35Ω
tOL = Effective switch overlap time ≈ 10ns
f = 200kHz (500kHz for LT1571-5)
Example: VIN = 15V, VBAT = 8.4V, IBAT = 1.2A;
PBIAS = (3.5mA )(VIN) + 1.5mA(VBAT )
2
VBAT )
(
+
VIN
[7.5mA + (0.012)(IBAT )]
BAT 
(IBAT )(VBAT )2  1+ V30


PDRIVER =
55(VIN)
2
IBAT ) (RSW )(VBAT )
(
+ ( tOL )(VIN)(IBAT )( f)
PSW =
V
IN
PSENSE = (0.18Ω)(IBAT )
2
Total power in the IC is:
0.17 + 0.13 + 0.32+ 0.26 = 0.88W
Temperature rise will be (0.88W)(40°C/W) = 35°C. This
assumes that the LT1571 is properly heat sunk by connecting all fused ground pins to the expanded traces and
that the PC board has a backside or internal plane for heat
spreading.
The PDRIVER term can be reduced by connecting the boost
diode D2 to a lower system voltage (lower than VBAT)
11
LT1571 Series
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APPLICATIO S I FOR ATIO
instead of VBAT (see Figure 8). The optimum boost voltage
(VX) is from 3V to 6V.
SW
BOOST
L1
Then,
(IBAT )(VBAT )(VX) 1+ V30X 
PDRIVER =
55(VIN)
D2
SENSE
VX
3V TO 6V
IVX
Total board area becomes an important factor when the
area of the board drops below about 20 square inches. The
graph in Figure 9 shows thermal resistance vs board area
for 2-layer and 4-layer boards. Note that 4-layer boards
have significantly lower thermal resistance, but both types
show a rapid increase for reduced board areas. Figure 10
shows actual measured lead temperature for chargers
operating at full current. Battery voltage and input voltage
will affect device power dissipation, so the data sheet
power calculations must be used to extrapolate these
readings to other situations.
Vias should be used to connect board layers together.
Planes under the charger area can be cut away from the
rest of the board and connected with vias to form both a
low thermal resistance system and to act as a ground
plane for reduced EMI.
THERMAL RESISTANCE (°C/W)
PDRIVER 0.045W
=
= 14mA
3.3V
VX
55
50
2-LAYER BOARD
45
4-LAYER BOARD
40
35
GN16, MEASURED FROM AIR AMBIENT
TO DIE USING COPPER LANDS AS
SHOWN ON DATA SHEET
30
25
0
Maximum duty cycle for the LT1571-1/LT1571-2 is typically 90% but this may be too low for some applications.
For example, if an 18V ±3% adapter is used to charge ten
NiMH cells, the charger must put out approximately 15V.
A total of 1.6V is lost in the input diode, switch resistance,
inductor resistance and parasitics so the required duty
12
5
20
15
25
10
BOARD AREA (IN2)
30
35
1571 F09
Figure 9. LT1571 Thermal Resistance
90
NOTE: PEAK DIE TEMPERATURE WILL BE
ABOUT 10°C HIGHER THAN LEAD TEMPERATURE AT 1.3A CHARGING CURRENT
80
70
2-LAYER BOARD
60
4-LAYER BOARD
50
ICHRG = 1.3A
VIN = 16V
VBAT = 8.4V
VBOOST = VBAT
TA = 25°C
40
30
20
0
Higher Duty Cycle
10µF
60
LEAD TEMPERATURE (°C)
The average IVX required is:
1571 F08
+
Figure 8. Lower VBOOST
For example, VX = 3.3V,
.3V 
(1.2A)(8.4V)(3.3V) 1+ 330


PDRIVER =
= 0.045W
55(15V )
LT1571
C1
5
20
15
25
10
BOARD AREA (IN2)
30
35
1571 F10
Figure 10. LT1571 Lead Temperature
cycle is 15/16.4 = 91.4%. The duty cycle can be extended
to 93% by restricting boost voltage to 5V instead of using
VBAT as is normally done. This lower boost voltage VX (see
Figure 8) also reduces power dissipation in the LT1571.
LT1571 Series
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Lower Dropout Voltage
Layout Considerations
For even lower dropout and/or reducing heat on the
board, the input diode D3 can be replaced with a FET (see
Figure 11). Connect a P-channel FET in place of the input
diode with its gate connected to the battery (SENSE pin)
causing the FET to turn off when the input voltage goes
low. The problem is that the gate must be pumped low so
that the FET is fully turned on even when the input is only
a volt or two above the battery voltage. Also there is a turnoff speed issue. The FET should turn off instantly when the
input is dead shorted to avoid large current surges from
the battery back through the charger into the FET. Gate
capacitance slows turn off, so a small P-FET (Q2) discharges the gate capacitance quickly in the event of an
input short. The body diode of Q2 creates the necessary
pumping action to keep the gate of Q1 low during normal
operation.
Switch rise and fall times are under 10ns for maximum
efficiency. To minimize radiation, the catch diode, SW pin
and input bypass capacitor leads should be kept as short
as possible. A ground plane should be used under the
switching circuitry to prevent interplane coupling and to
act as a thermal spreading path. All ground pins should be
connected to expand traces for low thermal resistance.
The fast-switching high current ground path including the
switch, catch diode and input capacitor should be kept
very short. Catch diode and input capacitor should be
close to the chip and terminated to the same point. This
path contains nanosecond rise and fall times with several
amps of current. The other paths contain only DC and /or
200kHz or 500kHz triwave and are less critical. Figure 12
indicates the high speed, high current switching path.
Figure 13 shows critical path layout.
Q1
VIN
+
VCC
SWITCH NODE
SW
Q2
RX
50k
D1
L1
LT1571
C3
VBAT
BOOST
L1
D2
SENSE
VX
3V TO 6V
Q1: Si4435DY
Q2: TP0610L
CIN
VIN
BAT
CX
10µF
VBAT
HIGH
FREQUENCY
CIRCULATING
PATH
COUT
BAT
+
HIGH DUTY CYCLE
CONNECTION
1571 F12
1571 F11
Figure 11. Replacing the Input Diode
Figure 12. High Speed Switching Path
GND
LT1571-5
D1
L1
GND
GND
SW
VCC2
BOOST
VCC1
BAT2
CAP
FLAG
PROG
SELECT
VC
SENSE
BAT
GND
GND
CIN
1571 F13
Figure 13. Critical Electrical and Thermal Path Layer for LT1571-5
13
LT1571 Series
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PACKAGE DESCRIPTIO
Dimensions in inches (millimeters) unless otherwise noted.
GN Package
16-Lead Plastic SSOP (Narrow 0.150)
(LTC DWG # 05-08-1641)
0.189 – 0.196*
(4.801 – 4.978)
16 15 14 13 12 11 10 9
0.229 – 0.244
(5.817 – 6.198)
0.150 – 0.157**
(3.810 – 3.988)
1
0.015 ± 0.004
× 45°
(0.38 ± 0.10)
0.007 – 0.0098
(0.178 – 0.249)
0.053 – 0.068
(1.351 – 1.727)
2 3
4
5 6
7
8
0.004 – 0.0098
(0.102 – 0.249)
0° – 8° TYP
0.016 – 0.050
(0.406 – 1.270)
* DIMENSION DOES NOT INCLUDE MOLD FLASH. MOLD FLASH
SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE
** DIMENSION DOES NOT INCLUDE INTERLEAD FLASH. INTERLEAD
FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE
14
0.009
(0.229)
REF
0.008 – 0.012
(0.203 – 0.305)
0.0250
(0.635)
BSC
GN16 (SSOP) 1098
LT1571 Series
U
PACKAGE DESCRIPTIO
Dimensions in inches (millimeters) unless otherwise noted.
GN Package
28-Lead Plastic SSOP (Narrow 0.150)
(LTC DWG # 05-08-1641)
0.386 – 0.393*
(9.804 – 9.982)
28 27 26 25 24 23 22 21 20 19 18 17 1615
0.229 – 0.244
(5.817 – 6.198)
0.150 – 0.157**
(3.810 – 3.988)
1
0.015 ± 0.004
× 45°
(0.38 ± 0.10)
0.0075 – 0.0098
(0.191 – 0.249)
0.033
(0.838)
REF
2 3
4
5 6
7
8
0.053 – 0.069
(1.351 – 1.748)
9 10 11 12 13 14
0.004 – 0.009
(0.102 – 0.249)
0° – 8° TYP
0.016 – 0.050
(0.406 – 1.270)
* DIMENSION DOES NOT INCLUDE MOLD FLASH. MOLD FLASH
SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE
** DIMENSION DOES NOT INCLUDE INTERLEAD FLASH. INTERLEAD
FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE
0.008 – 0.012
(0.203 – 0.305)
0.0250
(0.635)
BSC
GN28 (SSOP) 1098
15
LT1571 Series
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
LT1505
High Current Constant-Current/Constant-Voltage
Battery Charger Controller with Input Current Limit
High Efficiency Synchronous Buck Topology, Uses External N-Channel
FETs. Includes Preset Battery Voltages and Input Current Limiting
LT1510
200kHz Constant-Current/Constant-Voltage Battery Charger
Up to 2A Charge Current for Li-Ion, NiCd, NiMH or Lead Acid Batteries
LT1510-5
500kHz Constant-Current/Constant-Voltage Battery Charger
Up to 2A Charge Current for Li-Ion, NiCd, NiMH or Lead Acid Batteries
LT1511
200kHz Constant-Current/Constant-Voltage Battery Charger
with Input Current Limit
Up to 3A Charge Current for Li-Ion, NiCd, NiMH or Lead Acid Batteries
LT1512
500kHz SEPIC Constant-Current/Constant-Voltage
Battery Charger
Up to 1.5A Charge Current for Li-Ion, NiCd, NiMH or Lead-Acid
Batteries. Input Voltage Can be Higher or Lower Than Battery Voltage.
2A Internal Switch
LT1513
500kHz SEPIC Constant-Current/Constant-Voltage
Battery Charger
Up to 2A Charge Current for Li-Ion, NiCd, NiMH or Lead-Acid
Batteries. Input Voltage Can be Higher or Lower Than Battery Voltage.
3A Internal Switch
LTC®1729
Li-Ion Battery Charger Termination Controller
Can Be Used with Battery Chargers to Provide Charge Termination,
Preset Voltages, C/10 Charge Detection and Timer Functions
LTC1731
Linear Constant-Current/Constant-Voltage Charger Controller
Simple Charger Uses External FET. Features Preset Voltages, C/10
Charge Detection and Programmable Timer
LTC1759
SMBus Controlled Constant-Current/Constant-Voltage Smart
Battery Charger Controller
LT1505 Charger Functionality with SMBus
LT1769
200kHz Constant-Current/Constant-Voltage Battery Charger
with Input Current Limit
Up to 2A Charge Current for Li-Ion, NiCd, NiMH or Lead-Acid Batteries
16
Linear Technology Corporation
1571i LT/TP 0400 4K • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408)432-1900 ● FAX: (408) 434-0507 ● www.linear-tech.com
 LINEAR TECHNOLOGY CORPORATION 2000