LINER LTC4001EUF-1-PBF

LTC4001-1
2A Synchronous
Buck Li-Ion Charger
FEATURES
DESCRIPTION
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The LTC®4001-1 is a 2A Li-Ion battery charger intended for
5V wall adapters. It utilizes a 1.5MHz synchronous buck
converter topology to reduce power dissipation during
charging. Low power dissipation, an internal MOSFET and
sense resistor allow a physically small charger that can be
embedded in a wide range of handheld applications. The
LTC4001-1 includes complete charge termination circuitry,
automatic recharge and a ±1% 4.1V float voltage. Input
short-circuit protection is included so no blocking diode
is required.
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Low Power Dissipation
2A Maximum Charge Current
No External MOSFETs, Sense Resistor or
Blocking Diode Required
Remote Sensing at Battery Terminals
Programmable Charge Termination Timer
Preset 4.1V Float Voltage with ±0.5% Accuracy
4.1V Float Voltage Improves Battery Life and High
Temperature Safety Margin
Programmable Charge Current Detection/
Termination
Automatic Recharge
Thermistor Input for Temperature Qualified
Charging
Compatible with Current Limited Wall Adapters
Low Profile 16-Lead (4mm × 4mm) QFN Package
APPLICATIONS
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Handheld Battery-Powered Devices
Handheld Computers
Charging Docks and Cradles
Digital Cameras
Smart Phones
This 4.1V version of the standard LTC4001 is intended
for applications which will be operated or stored above
approximately 60°C. Under these conditions, the reduced
float voltage will trade-off initial cell capacity for the benefit
of increased capacity retention over the life of the battery. A
reduced float voltage also minimizes swelling in prismatic
and polymer cells, and avoids open CID (pressure fuse)
in cylindrical cells.
Battery charge current, charge timeout and end-of-charge
indication parameters are set with external components.
Additional features include shorted cell detection, temperature qualified charging and overvoltage protection. The
LTC4001-1 is available in a low profile (0.75mm) 16-lead
(4mm × 4mm) QFN package.
L, LT, LTC and LTM are registered trademarks of Linear Technology Corporation. All other
trademarks are the property of their respective owners.
TYPICAL APPLICATION
Power Loss vs VBAT
Charging (PWM Mode)
2A Single Cell Li-Ion Battery Charger
1.5μH
SENSE
BATSENS
BAT
VINSENSE
PVIN
VIN
4.5V TO 5.5V
10μF
10μF
+
4.1V
Li-Ion
PGND
CHRG
LTC4001-1
NTC
FAULT
EN
0.22μF
274Ω
1.00
0.75
0.50
0.25
VIN = 5V
2A CHARGER
0
SS GNDSENS
PROG IDET TIMER
TOTAL APPLICATION CIRCUIT POWER
DISSIPATION (W)
SW
1.25
3
3.25
3.75
3.5
VBAT (V)
4
4.25
40011 TA01b
0.1μF
40011 TA01a
40011fa
1
LTC4001-1
ABSOLUTE MAXIMUM RATINGS
PIN CONFIGURATION
(Note 1)
SS
TIMER
BATSENS
IDET
TOP VIEW
PVIN, VINSENSE
t < 1ms, DC < 1% .................................... –0.3V to 7V
Steady State............................................. –0.3V to 6V
SW, SENSE, BAT, BATSENS, SS, FAULT, CHRG, EN, NTC,
PROG, IDET, TIMER Voltage ........................ – 0.3V to 6V
Operating Temperature Range (Note 3) .. –40°C to 85°C
Operating Junction Temperature
(Note 5) ................................................ –40°C to 125°C
Storage Temperature Range.................. –65°C to 125°C
16 15 14 13
BAT 1
12 PROG
SENSE 2
11 NTC
17
PGND 3
10 FAULT
GNDSENS 4
VINSENSE
5
6
7
8
SW
EN
CHRG
PVIN
9
UF PACKAGE
16-LEAD (4mm × 4mm) PLASTIC QFN
TJMAX = 125°C, θJA = 37°C/W
EXPOSED PAD (PIN 17) IS GND, MUST BE SOLDERED TO PCB
ORDER INFORMATION
LEAD FREE FINISH
TAPE AND REEL
PART MARKING
PACKAGE DESCRIPTION
TEMPERATURE RANGE
LTC4001EUF-1#PBF
LTC4001EUF-1#TRPBF
40011
16-Lead (4mm × 4mm) Plastic QFN
–40°C to 85°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/
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VIN = 5V, VEN = 0V, RPROG = 549Ω, RIDET = 549Ω, unless otherwise
specified.
SYMBOL PARAMETER
VIN
Supply Voltage
CONDITIONS
MIN
(Note 2)
TYP
4
5.5
PVIN Connected to VINSENSE, PROG and IDET
Pins Open, Charger On
IIN
Shutdown, EN = VIN
VFLOAT
VBAT Regulated Float Voltage
Measured from BATSENS to GNDSENS
IBAT
Current Mode Charge Current
RPROG = 549Ω, VBAT = 3.5V
RPROG = 1.10k, VBAT = 3.5V
Shutdown, EN = VIN
●
MAX
mA
50
μA
4.059
4.079
4.1
4.1
4.141
4.121
V
V
1.8
0.9
2
1
2.2
1.1
±5
A
A
μA
mA
ITRIKL
Trickle Charge Current
VBAT = 2V
35
50
65
Trickle Charge Threshold
VBAT Rising
VBAT Falling
3.05
2.85
3.1
3.0
3.20
3.05
2.7
VUVL
VIN Undervoltage Lockout Voltage
VIN Rising, Measured from VINSENSE to GNDSENS
VIN Undervoltage Lockout
Hysteresis
Measured from VINSENSE to GNDSENS
VASD
Automatic Shutdown Threshold
Voltage
VINSENSE – VBATSENS Rising (Turn-On), VBATSENSE = 4V
VINSENSE – VBATSENS Falling (Turn-Off), VBATSENSE = 4V
V
2
VTRIKL
ΔVUVL
UNITS
2.82
100
200
15
250
30
V
V
V
mV
300
60
mV
mV
40011fa
2
LTC4001-1
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VIN = 5V, VEN = 0V, RPROG = 549Ω, RIDET = 549Ω, unless otherwise
specified.
SYMBOL PARAMETER
fOSC
CONDITIONS
Oscillator Frequency
D
Maximum Duty Factor
RPFET
RDS(ON) of P-Channel MOSFET
RNFET
RDS(ON) of N-Channel MOSFET
tTIMER
Timer Accuracy
VEN
Enable Input Threshold Voltage
VEN Rising
MIN
TYP
MAX
1.3
1.5
1.7
100
Measured from PVIN to SW
UNITS
MHz
%
127
mΩ
Measured from SW to PGND
121
mΩ
CTIMER = 0.22μF
±10
%
0.6
0.8
1
ΔVEN
Enable Input Hysteresis
VPROG
PROG Pin Voltage
RPROG = 549Ω
1.213
V
VIDET
IDET Pin Voltage
RIDET = 549Ω
1.213
V
IIDET
IDET Threshold
RIDET = 549Ω
150
200
250
mA
ICHRG
CHRG Pin Weak Pull-Down
Current
VCHRG = 1V
15
30
50
μA
VCHRG
CHRG Pin Output Low Voltage
ICHRG = 5mA
0.2
0.4
V
VOL
FAULT Pin Output Low Voltage
1mA Load
0.4
V
VOH
FAULT Pin Output High Voltage
1mA Load
4.6
VFLOAT – VRECHRG VBAT Falling
50
VRECHRG Recharge Battery Threshold
Voltage
100
V
mV
V
100
135
mV
tRB
Recharge Filter Time Constant
tRECHRG
Recharge Time
Percent of Total Charge Time
50
%
tTRIKL
Low-Battery Trickle Charge Time
Percent of Total Charge Time, VBAT < 2.8V,
Measured Using BATSENS and GNDSENS Pins
25
%
ISS
Soft-Start Ramp Current
VBAT < VFLOAT – 100mV, VBAT Across BATSENS
and GNDSENS Pins
VCOLD
NTC Pin Cold Temperature Fault
Threshold
From NTC to GNDSENS Pin
Rising Threshold
Falling Threshold
0.74 VINSENSE
0.72 VINSENSE
V
V
NTC Pin Hot Temperature Fault
Threshold
From NTC to GNDSENS Pin
Falling Threshold
Rising Threshold
0.29 VINSENSE
0.30 VINSENSE
V
V
VDIS
NTC Disable Threshold (Falling)
From NTC to GNDSENS Pin
ΔVDIS
NTC Disable Hysteresis
From NTC to GNDSENS Pin
VHOT
4
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: Operation with current limited wall adapters is allowed down to the
undervoltage lockout threshold.
Note 3: The LTC4001E-1 is guaranteed to meet performance specifications from 0°C to 85°C. Specifications over the – 40°C to 85°C operating
temperature range are assured by design, characterization and correlation
with statistical process controls.
6
0.015 •
VINSENSE
ms
12.8
0.02 •
VINSENSE
16
μA
0.025 •
VINSENSE
V
0.01 •
VINSENSE
V
Note 4: TJ is calculated from the ambient temperature TA and power dissipation PD according to the following formula:
TJ = TA + (PD • 37°C/W)
Note 5: This IC includes overtemperature protection that is intended to
protect the device during momentary overload. Junction temperature will
exceed 125°C when overtemperature protection is active. Continuous
operation above the specified maximum operating junction temperature
my impair device reliability.
40011fa
3
LTC4001-1
TYPICAL PERFORMANCE CHARACTERISTICS
Oscillator Frequency
vs Temperature
FREQUENCY VARIATION FROM 25°C (%)
0.75
PERCENT VARIATION (%)
0.8
VBAT = 3.2V
VSS = 1V
0.50
0.25
0
–0.25
–0.50
–0.75
–1.00
3.5
3
4
5
4.5
VIN (V)
1.25
VIN = 5V
VBAT = 3.2V
VSS = 1V
0.6
0.4
0.2
0
40011 G01
0.50
0.25
0
500
1500
1000
IBAT = 2A
2000
IBAT (mA)
40011 G03
Output Charging Characteristic
Showing Constant Current and
Constant Voltage Operation
PROG Pin Characteristic
(VPROG vs IPROG)
2.0
VIN = 5V
1.2
1.2
1.0
IBAT = 1.5A
0.8
0.6
0.6
IBAT = 1A
0.4
IBAT = 500mA
0.2
0.4
1.0
0.5
0.2
0
4.25
0.8
1.5
VBAT = 4V
IBAT (A)
VBAT = 3.2V
VBAT = 3.5V
VBAT = 3.7V
1.0
VPROG (V)
TOTAL APPLICATION CIRCUIT POWER
DISSIPATION (W)
VBAT = 4V
0.75
40011 G02
Dissipation of Figure 8 Circuit
vs VIN
1.4
VIN = 5V
VBAT = 4V
1.00
–0.2
–50 –30 –10 10 30 50 70 90 110 130 150
TEMPERATURE (°C)
6
5.5
Dissipation of Figure 8 Circuit
vs IBAT
TOTAL APPLICATION CIRCUIT POWER
DISSIPATION (W)
Oscillator Frequency vs VIN
1.00
(TA = 25°C unless otherwise noted)
0
4.5
4.75
5
5
0
5.5
5.25
10
15
0
20
0
0.5
1
1.5
IPROG (mA)
VIN (V)
40011 G05
40011 G04
2 2.5
VBAT (V)
3
3.5
4
40011 G06
VFLOAT and Recharge Battery
Threshold Voltage vs Temperature
Trickle Charge Current vs VBAT
55
FLOAT AND RECHARGE VOLTAGES (V)
4.2
VIN = 5.5V
VIN = 5V
IBAT (mA)
50
VIN = 4V
VIN = 4.5V
45
40
0
0.5
1
1.5
VBAT (V)
2
2.5
3
40011 G07
VFLOAT
4.1
VRECHARGE
(VBAT FALLING)
4.0
3.9
–50 –30 –10 10 30 50 70 90 110 130 150
TEMPERATURE (°C)
40011 G08
40011fa
4
LTC4001-1
TYPICAL PERFORMANCE CHARACTERISTICS
CHRG Pin Temperature Fault
Behavior (Detail)
IDET Threshold vs RIDET for
RPROG = 549Ω
Soft-Start (PWM Mode)
400
INPUT
CURRENT (IIN)
0.5A/DIV
350
300
IDET (mA)
0
INDUCTOR
CURRENT (IL)
0.5A/DIV
0
SOFT-START
VOLTAGE (VSS)
1V/DIV 0
EN PIN (VEN)
5V/DIV 0
CHRG
1V/DIV
250
200
150
100
VBAT = 3.5V
VIN = 5V
2ms/DIV
40011 G09
TIME (20μs/DIV)
50
40011 G11
0
300 400 500 600 700 800 900 1000 1100 1200
RIDET (Ω)
40011 G10
PIN FUNCTIONS
BAT (Pin 1): Battery Charger Output Terminal. Connect a
10μF ceramic chip capacitor between BAT and PGND to
keep the ripple voltage small.
SENSE (Pin 2): Internal Sense Resistor. Connect to external inductor.
PGND (Pin 3): Power Ground.
GNDSENS (Pin 4): Ground Sense. Connect this pin to the
negative battery terminal. GNDSENS provides a Kelvin
connection for PGND and must be connected to PGND
schematically.
SW (Pin 5): Switch Node Connection. This pin connects
to the drains of the internal main and synchronous power
MOSFET switches. Connect to external inductor.
off and a 30μA current source is connected from CHRG to
ground. (This signal is latched and is reset by initiating a
new charge cycle.) When the timer runs out or the input
supply is removed, the current source will be disconnected
and the CHRG pin is forced to a high impedance state. A
temperature fault causes this pin to blink.
PVIN (Pin 8): Positive Supply Voltage Input. This pin connects to the power devices inside the chip. VIN ranges
from 4V to 5.5V for normal operation. Operation down to
the undervoltage lockout threshold is allowed with current limited wall adapters. Decouple with a 10μF or larger
surface mounted ceramic capacitor.
EN (Pin 6): Enable Input Pin. Pulling the EN pin high
places the LTC4001-1 into a low power state where the
BAT drain current drops to less than 3μA and the supply
current is reduced to less than 50μA. For normal operation, pull the pin low.
VINSENSE (Pin 9): Positive Supply Sense Input. This pin
connects to the inputs of all input comparators (UVL, VIN
to VBAT). It also supplies power to the controller portion
of this chip. When the BATSENS pin rises to within 30mV
of VINSENSE, the LTC4001-1 enters sleep mode, dropping
IIN to 50μA. Tie this pin directly to the terminal of the PVIN
decoupling capacitor.
CHRG (Pin 7): Open-Drain Charge Status Output. When the
battery is being charged, CHRG is pulled low by an internal
N-channel MOSFET. When the charge current drops below
the IDET threshold (set by the RIDET programming resistor)
for more than 5milliseconds, the N-channel MOSFET turns
FAULT (Pin 10): Battery Fault. This pin is a logic high if
a shorted battery is detected or if a temperature fault is
detected. A temperature fault occurs with the temperature
monitor circuit enabled and the thermistor temperature is
either below 0°C or above 50°C (typical).
40011fa
5
LTC4001-1
PIN FUNCTIONS
NTC (Pin 11): Input to the NTC (Negative Temperature
Coefficient) Thermistor Temperature Monitoring Circuit.
Under normal operation, tie a thermistor from the NTC pin
to the GNDSENS pin and a resistor of equal value from
NTC to VIN. When the voltage on this pin is above 0.74VIN
(Cold, 0°C) or below 0.29VIN (Hot, 50°C), charging is
disabled and the CHRG pin blinks. When the voltage on
NTC comes back between 0.74VIN and 0.29VIN, the timer
continues where it left off and charging resumes. There is
approximately 3°C of temperature hysteresis associated
with each of the input comparators. If the NTC function
is not used connect the NTC pin to GNDSENS. This will
disable all of the NTC functions. NTC should never be
pulled above VIN.
PROG (Pin 12): Charge Current Program. The RPROG
resistor connects from this pin to GNDSENS, setting the
current:
1.110k
RPROG =
IBAT(AMPS)
where IBAT is the high rate battery charging current.
IDET (Pin 13): Charge Rate Detection Threshold. Connecting a resistor, RIDET to GNDSENS programs the charge rate
detection threshold. If RIDET = RPROG, CHRG provides an
IBAT/10 indication. For other thresholds see the Applications Information section.
SS (Pin 14): Soft-Start/Compensation. Provides soft-start
function and compensation for the float voltage control
loop and compensation for the charge current control
loop. Tie a soft-start/compensation capacitor between
this pin and GNDSENS.
TIMER (Pin 15): Timer Capacitor. The timer period is set
by placing a capacitor, CTIMER, to GNDSENS. Set CTIMER
to:
CTIMER = Time (Hrs) • 0.0733 (μF)
where time is the desired charging time.
Connect this pin to IDET to disable the timer. Connect this
pin to GNDSENS to end battery charging when IBAT drops
below the IDET charge rate threshold.
BATSENS (Pin 16): Battery Sense Input. An internal resistor
divider sets the final float voltage at this pin. The resistor
divider is disconnected in sleep mode or when
EN = H to reduce the battery drain current. Connect this
pin to the positive battery terminal.
Exposed Pad (Pin 17): Ground. This pin must be soldered
to the PCB ground (PGND) for electrical contact and rated
thermal performance.
40011fa
6
11
15
10
7
6
14
NTC
TIMER
FAULT
CHRG
EN
SS
+
PWM ON
RD
Q
+
DRIVER
CHIP OVER TEMP
CONNECT
OVERVOLTAGE
CHIP
OVERTEMP
COMPARATOR
SS LOW
PROG SHORTED
DISCHARGE SS
LOGIC
LOW CURRENT
VIN GOOD
RECHARGE
SHUTDOWN
S
TFAULT
TIMER
FAULT
CHRG
EN
TRICKLE ON
NTC
COMPARATOR
SS
RAMP
PWM
COMPARATOR
OVERCURRENT
CLK
–
OSCILLATOR
PROG SHORT
COMPARATOR
1.2V
+
–
–
LOW BATTERY
5
+
1.1V
+
–
17
GND
PROG
ERROR
AMP
13
IDET
CURRENT
REVERSAL
COMPARATOR
2
50mA
SOFT-START
COPMPARATOR
– +
CHARGE CURRENT
ERROR AMP
– +
IDET
COMPARATOR
+ –
OVERCURRENT
COMPARATOR
PROG
12
SENSE
+
–
PGND SW
1
150mV
+
–
UNDERVOLTAGE
COMPARATOR
BAT
9
LOW-BATTERY
COMPARATOR
– +
SHUTDOWN
COMPARATOR
VINSENSE
RECHARGE
COMPARATOR
FLOAT VOLTAGE
ERROR AMP
VOLTAGE
REFERENCE
+
–
BATTERY
OVERVOLTAGE
COMPARATOR
+
–
3
+
–
PVIN
+
–
–
8
1.2V
4
40011 BD
GNDSENS
BATSENS
16
LTC4001-1
BLOCK DIAGRAM
40011fa
7
LTC4001-1
OPERATION
The LTC4001-1 is a constant current, constant voltage
Li-Ion battery charger based on a synchronous buck
architecture. Low power dissipation makes continuous
high rate (2A) battery charging practical. The battery DC
charge current is programmed by a resistor RPROG (or a
DAC output current) at the PROG pin. The final battery
float voltage is internally set to 4.1V.
A negative temperature coefficient (NTC) thermistor located
close to the battery pack can be used to monitor battery
temperature and suspend charging when battery temperature is outside the 0°C to 50°C window. A temperature fault
drives the FAULT pin high and makes the CHRG pin blink.
When the input voltage (VIN) is present, the charger can
be shut down by pulling the EN pin up.
Charging begins when the VIN voltage rises above the
UVLO level (approximately 2.75V), VIN is 250mV greater
than the battery voltage and EN is low. At the beginning
of the charge cycle, if the battery voltage is less than the
trickle charge threshold, 3V, the charger goes into trickle
charge mode and delivers approximately 50mA to the battery using a linear charger. If the battery voltage stays low
for more than one quarter of the charge time, the battery
is considered faulty, the charge cycle is terminated and
the FAULT pin produces a logic high output.
IDET Blanking
When the battery voltage exceeds the trickle charge
threshold, the low rate linear charger is turned off and the
high rate PWM charger ramps up (based on the SS pin
capacitance) reaching its full-scale constant current (set
via the PROG pin). When the battery approaches the float
voltage, the charge current will start to decrease. When
the charge current drops below the charge rate detection threshold (set via the IDET pin) for more than 5ms,
an internal comparator turns off the internal pull-down
N-channel MOSFET at the CHRG pin, and connects a weak
current source (30μA typical) to ground to indicate a near
end-of-charge condition.
Total charge time is set by an external capacitor connected
to the timer pin. After timeout occurs, the charge cycle is
terminated and the CHRG pin is forced to a high impedance
state. To restart the charge cycle, remove and reapply the
input voltage, or momentarily shut the charger down via
the EN pin. Also, a new charge cycle will begin if the battery voltage drops below the recharge threshold voltage
(100mV below the float voltage). A recharge cycle lasts
only one-half of the normal charge time.
The IDET comparator provides an end-of-charge indication
by sensing when battery charge current is less than the
IDET threshold. To prevent a false end-of-charge indication
from occurring during soft-start, this comparator is blanked
until the battery voltage approaches the float voltage.
Automatic Battery Recharge
After the charge cycle is completed and if both the battery
and the input power supply (wall adapter) are still connected, a new charge cycle will begin if the battery voltage
drops below 4V due to self-discharge or external loading.
This will keep the battery near maximum capacity at all
times without manually restarting the charge cycle.
In some applications such as battery charging in GPRS
cellphones, large load current transients may cause battery
voltage to momentarily drop below the recharge threshold.
To prevent these transients from initiating a recharge cycle
when it is not needed, the output of the recharge comparator is digitally qualified. Only if the battery voltage stays
below the recharge threshold for at least 4ms will battery
recharging occur. (GPRS qualification is available even if
timeout is disabled.)
Undervoltage Lockout and Automatic Shutdown
Internal undervoltage lockout circuits monitor VIN and
keep the charger circuits shut down until VIN rises above
the undervoltage lockout threshold (3V). The UVLO has
a built-in hysteresis of 100mV. Furthermore, to protect
against reverse current, the charger also shuts down if
VIN is less than VBAT. If automatic shutdown is tripped,
VIN must increase to more than 250mV above VBAT to
allow charging.
40011fa
8
LTC4001-1
OPERATION
Overvoltage, Chip Overtemperature and Short-Circuit
Current Protection
The LTC4001-1 includes overvoltage, chip overtemperature
and several varieties of short-circuit protection.
A comparator turns off both chargers (high rate and
trickle) if battery voltage exceeds the float voltage by approximately 5%. This may occur in situations where the
battery is accidentally disconnected while battery charging
is underway.
A comparator continuously monitors on-chip temperature
and will shut off the battery charger when chip temperature
exceeds approximately 160°C. Battery charging will be
enabled again when temperature drops to approximately
150°C.
Short-circuit protection is provided in several different
ways. First, a hard short on the battery terminals will
cause the charge to enter trickle charge mode, limiting
charge current to the trickle charge current (typically
50mA). Second, PWM charging is prevented if the high
rate charge current is programmed far above the 2A
maximum recommended charge current (via the PROG
pin). Third, an overcurrent comparator monitors the peak
inductor current.
40011fa
9
LTC4001-1
APPLICATIONS INFORMATION
Soft-Start and Compensation Capacitor Selection
The IDET threshold (a charge current threshold used to
determine when the battery is nearly fully charged) is
programmed in much the same way as the PROG pin,
except that the IDET threshold is 91.5 times the current
delivered by the IDET pin. This current is usually set with
an external resistor from IDET to ground, but it may also
be set with a current output DAC. The voltage on the PROG
pin is nominally 1.213V.
The LTC4001-1 has a low current trickle charger and a
PWM-based high current charger. Soft-start is used whenever the high rate charger is initially turned on, preventing
high start-up current. Soft-start ramp rate is set by the
internal 12.8μA pull-up current and an external capacitor.
The control range on the SS pin is approximately 0.3V
to 1.6V. With a 0.1μF capacitor, the time to ramp up to
maximum duty cycle is approximately 10ms.
For 200mA IDET current (corresponding to C/10 for a
2AHr battery):
The external capacitor on the SS pin also sets the compensation for the current control loop and the float voltage control
loop. A minimum capacitance of 10nF is required.
RIDET =
Charge Current and IDET Programming
1.10kΩ programs approximately 100mA and 274Ω approximately 400mA.
The LTC4001-1 has two different charge modes. If the
battery is severely depleted (battery voltage less than
2.9V) a 50mA trickle current is initially used. If the battery
voltage is greater than the trickle charge threshold, high
rate charging is used.
For applications where IDET is set to one tenth of the high
rate charge current, and slightly poorer charger current
and IDET threshold accuracy is acceptable, the PROG and
IDET pins may be tied together and a single resistor, R1,
can program both (Figure 1).
This higher charge current is programmable and is approximately 915 times the current delivered by the PROG
pin. This current is usually set with an external resistor
from PROG to GNDSENS, but it may also be set with a
current output DAC connected to the PROG pin. The voltage on the PROG pin is nominally 1.213V.
R1=
457.5 • 1.213
ICHARGE
and
IDET =
For 2A charge current:
RPROG =
91.5 • 1.213V
554.9
0.2A
ICHARGE
10
915 • 1.213V
554.9
2A
LTC4001-1
PROG
IDET
R1
274Ω FOR 2A
GNDSENS
40011 F01
Figure 1. Programming Charge Current and
IDET Threshold with a Single Resistor
40011fa
10
LTC4001-1
APPLICATIONS INFORMATION
The equations for calculating R1 (used in single resistor
programming) differ from the equations for calculating
RPROG and RIDET (2-resistor programming) and reflect
the fact that the current from both the IDET and PROG
pins must flow through a single resistor R1 when a single
programming resistor is used.
pin low through the 390k resistor. When charging stops,
the CHRG pin changes to a high impedance state and the
390k resistor will then pull the pin high to indicate charging has stopped.
CHRG Status Output Pin
Battery charging may be terminated several different ways,
depending on the connections made to the TIMER pin. For
time-based termination, connect a capacitor between the
TIMER pin and GNDSENS (CTIMER = Time(Hrs) 0.0733μF).
Charging may be terminated when charge current drops
below the IDET threshold by tying TIMER to GNDSENS.
Finally, charge termination may be defeated by tying TIMER
to IDET. In this case, an external device can terminate
charging by pulling the EN pin high.
When a charge cycle starts, the CHRG pin is pulled to
ground by an internal N-channel MOSFET which is capable
of driving an LED. When the charge current drops below
the end-of-charge (IDET) threshold for at least 4ms,
and the battery voltage is close to the float voltage, the
N-channel MOSFET turns off and a weak 30μA current
source to ground is connected to the CHRG pin. This
weak pull-down remains until the charge cycle ends. After
charging ends, the pin will become high impedance. By
using two different value resistors, a microprocessor can
detect three states from this pin (charging, end-of-charge
and charging stopped). See Figure 2.
To detect the charge mode, force the digital output pin,
OUT, high and measure the voltage on the CHRG pin. The
N-channel MOSFET will pull the pin low even with a 2k
pull-up resistor. Once the charge current drops below
the end-of-charge threshold, the N-channel MOSFET is
turned off and a 30μA current source is connected to the
CHRG pin. The IN pin will then be pulled high by the 2k
resistor connected to OUT. Now force the OUT pin into
a high impedance state, the current source will pull the
Charge Termination
Battery Temperature Detection
When battery temperature is out of range (either too hot
or too cold) charging is temporarily halted and the FAULT
pin is driven high. In addition, if the battery is still charging at a high rate (greater than the IDET current) when a
temperature fault occurs, the CHRG pin NMOS turns on
and off at approximately 50kHz, alternating between a
high and low duty factor at an approximate rate of 1.5Hz
(Figure 3). This provides a low rate visual indication (1.5Hz)
when driving an LED from the CHRG pin while providing
a fast temperature fault indication (20μs typical) to a microprocessor by tying the CHRG pin to an interrupt line.
Serrations within this pulse are typically 500ns wide.
VDD
VIN
LTC4001-1
CHRG
R1
390k R2
2k
μPROCESSOR
OUT
IN
40011 F02
20μs
40011 F03
667ms
Figure 2. Microprocessor Interface
Figure 3. CHRG Temperature Fault Waveform
40011fa
11
LTC4001-1
APPLICATIONS INFORMATION
The battery temperature is measured by placing a negative
temperature coefficient (NTC) thermistor close to the battery pack. To use this feature, connect the NTC thermistor,
RNTC, between the NTC pin and GNDSENS and the resistor,
RNOM, from the NTC pin to VINSENSE. RNOM should be a 1%
resistor with a value equal to the value of the chosen NTC
thermistor at 25°C. The LTC4001-1 goes into hold mode
when the resistance, RHOT, of the NTC thermistor drops to
0.41 times the value of RNOM. For instance for RNTC = 10k.
(The value for a Vishay NTHS0603N02N1002J thermistor
at 25°C) hold occurs at approximately 4.1k, which occurs
at 50°C. The hold mode freezes the timer and stops the
charge cycle until the thermistor indicates a return to a
valid temperature. As the temperature drops, the resistance
of the NTC thermistor rises. The LTC4001-1 is designed to
go into hold mode when the value of the NTC thermistor
increases to 2.82 times the value of RNOM. This resistance
is RCOLD. For the Vishay 10k thermistor, this value is 28.2k,
which corresponds to approximately 0°C. The hot and cold
comparators each have approximately 3°C of hysteresis
to prevent oscillation about the trip point. Grounding the
NTC pin disables the NTC function.
Thermistors
The LTC4001-1 NTC trip points were designed to work with
thermistors whose resistance temperature characteristics
follow Vishay Dale’s “R-T Curve 2.” However, any thermistor whose ratio of RCOLD to RHOT is about 7 will also work
(Vishay Dale R-T Curve 2 shows a ratio of RCOLD to RHOT
of 2.815/0.4086 = 6.89).
Power conscious designs may want to use thermistors
whose room temperature value is greater than 10k. Vishay
Dale has a number of values of thermistor from 10k to 100k
that follow the “R-T Curve 1.” Using these as indicated
in the NTC Thermistor section will give temperature trip
points of approximately 3°C and 47°C, a delta of 44°C. This
delta in temperature can be moved in either direction by
changing the value of RNOM with respect to RNTC. Increasing
RNOM will move the trip points to higher temperatures. To
calculate RNOM for a shift to lower temperature for example,
use the following equation:
R
RNOM = COLD • RNTC at 25°C
2.815
where RCOLD is the resistance ratio of RNTC at the desired
cold temperature trip point. If you want to shift the trip points
to higher temperatures use the following equation:
RNOM =
RHOT
•R
at 25°C
0.4086 NTC
where RHOT is the resistance ratio of RNTC at the desired
hot temperature trip point.
Here is an example using a 100k R-T Curve 1 thermistor
from Vishay Dale. The difference between trip points is
44°C, from before, and we want the cold trip point to be
0°C, which would put the hot trip point at 44°C. The RNOM
needed is calculated as follows:
RCOLD
•R
at 25°C
2.815 NTC
3.266
• 100k = 116k
=
2.815
RNOM =
The nearest 1% value for RNOM is 115k. This is the value
used to bias the NTC thermistor to get cold and hot trip
points of approximately 0°C and 44°C respectively. To
extend the delta between the cold and hot trip points a
resistor, R1, can be added in series with RNTC (see Figure 4).
The values of the resistors are calculated as follows:
R
–R
RNOM = COLD HOT
2.815 – 0.4086
0.4086
• (RCOLD – RHOT ) – RHOT
R1=
2.815 – 0.4086
40011fa
12
LTC4001-1
APPLICATIONS INFORMATION
VINSENSE
9
LTC4001-1 NTC BLOCK
0.74 • VINSENSE
RNOM
121k
–
TOO COLD
NTC
+
11
R1
13.3k
–
TOO HOT
RNTC
100k
0.29 • VINSENSE
+
+
0.02 • VINSENSE
NTC ENABLE
–
GNDSENS
4
40011 F04
Figure 4. Extending the Delta Temperature
where RNOM is the value of the bias resistor, RHOT and
RCOLD are the values of RNTC at the desired temperature
trip points. Continuing the example from before with a
desired hot trip point of 50°C:
RCOLD – RHOT 100k • ( 3.2636 – 0.3602)
=
2.815 – 0.4086
2.815 – 0.4086
= 120.8k, 121k is nearest 1%
RNOM =
0.4086
R1= 100k • • ( 3.266 – 0.3602) – 0.3602
2.815 – 0.4086
= 13.3k, 13.3k is nearest 1%
The final solution is as shown if Figure 4 where RNOM =
121k, R1 = 13.3k and RNTC = 100k at 25°C.
Input and Output Capacitors
The LTC4001-1 uses a synchronous buck regulator to
provide high battery charging current. A 10μF chip ceramic
capacitor is recommended for both the input and output
capacitors because it provides low ESR and ESL and can
handle the high RMS ripple currents. However, some
high Q capacitors may produce high transients due to
self-resonance under some start-up conditions, such as
connecting the charger input to a hot power source. For
more information, refer to Application Note 88.
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 1.5MHz
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 the output capacitor is 0.1Ω and the battery
impedance is raised to 2Ω with a bead or inductor, only
5% of the ripple current will flow in the battery. Similar
techniques may also be applied to minimize EMI from
the input leads.
40011fa
13
LTC4001-1
APPLICATIONS INFORMATION
Inductor Selection
Remote Sensing
A high (1.5MHz) operating frequency was chosen for the
buck switcher in order to minimize the size of the inductor.
However, take care to use inductors with low core losses
at this frequency. A good choice is the IHLP-2525AH-01
from Vishay Dale.
For highest float voltage accuracy, tie GNDSENS and
BATSENS directly to the battery terminals. In a similar fashion, tie BAT and PGND directly to the battery terminals. This
eliminates IR drops in the GNDSENS and BATSENS lines
by preventing charge current from flowing in them.
To calculate the inductor ripple current:
Operation with a Current Limited Wall Adapter
IL =
VBAT
VIN
L•f
2
VBAT –
where VBAT is the battery voltage, VIN is the input voltage,
L is the inductance and f is the PWM oscillator frequency
(typically 1.5MHz). Maximum inductor ripple current occurs at maximum VIN and VBAT = VIN/2.
Peak inductor current will be:
IPK = IBAT + 0.5 • ΔIL
where IBAT is the maximum battery charging current.
When sizing the inductor make sure that the peak current
will not exceed the saturation current of the inductors.
Also, ΔIL should never exceed 0.4(IBAT) as this may interfere with proper operation of the output short-circuit
protection comparator. 1.5μH provides reasonable inductor
ripple current in a typical application. With 1.5μH and 2A
charge current:
2.85V 2
5.5V = 0.61A
IL =
P-P
1.5μH • 1.5MHz
2.85V –
and
IPK = 2.31A
Wall adapters with or without current limiting may be used
with the LTC4001-1, however, lowest power dissipation
battery charging occurs with a current limited wall adapter.
To use this feature, the wall adapter must limit at a current
smaller than the high rate charge current programmed
into the LTC4001-1. For example, if the LTC4001-1 is
programmed to charge at 2A, the wall adapter current
limit must be less than 2A.
To understand operation with a current limited wall adapter,
assume battery voltage, VBAT, is initially below VTRIKL, the
trickle charge threshold (Figure 5). Battery charging begins
at approximately 50mA, well below the wall adapter current
limit so the voltage into the LTC4001-1 (VIN) is the wall
adapter’s rated output voltage (VADAPTER). Battery voltage
rises eventually reaching VTRIKL. The linear charger shuts
off, the PWM (high rate) charger turns on and a softstart cycle begins. Battery charging current rises during
the soft-start cycle causing a corresponding increase in
wall adapter load current. When the wall adapter reaches
current limit, the wall adapter output voltage collapses
and the LTC4001-1 PWM charger duty cycle ramps up to
100% (the topside PMOS switch in the LTC4001-1 buck
regulator stays on continuously). As the battery voltage
approaches VFLOAT, the float voltage error amplifier commands the PWM charger to deliver less than ILIMIT. The
wall adapter exits current limit and the VIN jumps back up
40011fa
14
LTC4001-1
APPLICATIONS INFORMATION
LINEAR CHARGING
VADAPTER
WALL ADAPTER IN CURRENT LIMIT
PWM
CHARGING
VBAT + VDROP
VIN
ILIMIT
IBAT
ITRICKLE
40011 F05
VTRIKL
VFLOAT
VBAT
Figure 5. Charging Characteristic
to VADAPTER. Battery charging current continues to drop
as the VBAT rises, dropping to zero at VFLOAT. Because the
voltage drop in the LTC4001-1 is very low when charge
current is highest, power dissipation is also very low.
Thermal Calculations (PWM and Trickle Charging)
The LTC4001-1 operates as a linear charger when conditioning (trickle) charging a battery and operates as a high rate
buck battery charger at all other times. Power dissipation
should be determined for both operating modes.
For linear charger mode:
PD = (VIN – VBAT) • ITRIKL + VIN • IIN
where IIN is VIN current consumed by the IC.
Worst-case dissipation occurs for VBAT = 0, maximum
VIN, and maximum quiescent and trickle charge current.
For example with 5.5V maximum input voltage and 65mA
worst case trickle charge current, and 2mA worst case
chip quiescent current:
PD = (5.5 – 0) • 65mA + 5.5 • 2mA = 368.5mW
LTC4001-1 power dissipation is very low if a current
limited wall adapter is used and allowed to enter current
limit. When the wall adapter is in current limit, the voltage
drop across the LTC4001-1 charger is:
VDROP = ILIMIT • RPFET
where ILIMIT is the wall adapter current limit and RPFET is
the on resistance of the topside PMOS switch.
The total LTC4001-1 power dissipation during current
limited charging is:
PD = (VBAT + VDROP) • (IIN + IP) + VDROP • ILIMIT
where IIN is the chip quiescent current and IP is total current flowing through the IDET and PROG programming
pins. Maximum dissipation in this mode occurs with the
highest VBAT that keeps the wall adapter in current limit
(which is very close to VFLOAT), highest quiescent current
IIN, highest PMOS on resistance RPFET, highest ILIMIT and
highest programming current IP.
Assume the LTC4001-1 is programmed for 2A charging and
200mA IDET and that a 1.5A wall adapter is being used:
ILIMIT = 1500mA, RPFET = 127mΩ, IIN = 2mA, IP = 4mA
and VBAT ≈ VFLOAT = 4.141V
then:
VDROP = 1500mA • 127mΩ = 190.5mV
and:
PD = (4.141V + 0.1905V) • (2mA + 4mA) + 0.1905V
• 1500mA = 312mW
Power dissipation in buck battery charger mode may be
estimated from the dissipation curves given in the Typical
Performance Characteristics section of the data sheet.
This will slightly overestimate chip power dissipation
because it assumes all loss, including loss from external
components, occurs within the chip.
40011fa
15
LTC4001-1
APPLICATIONS INFORMATION
Insert the highest power dissipation figure into the following
equation to determine maximum junction temperature:
TJ = TA + (PD • 37°C/W)
The LTC4001-1 includes chip overtemperature protection.
If junction temperature exceeds 160°C (typical), the chip
will stop battery charging until chip temperature drops
below 150°C.
Using the LTC4001-1 in Applications Without a Battery
The LTC4001-1 is normally used in end products that only
operate with the battery attached (Figure 6). Under these
conditions the battery is available to supply load transient
currents. For indefinite operation with a powered wall
adapter there are only two requirements—that the average current drawn by the load is less than the high rate
charge current, and that VBAT stays above the trickle charge
threshold when the load is initially turned on and during
other load transients. When making this determination
take into account battery impedance. If battery voltage
is less than the trickle charge threshold, the system load
may be turned off until VBAT is high enough to meet these
conditions.
The situation changes dramatically with the battery removed (Figure 7). Since the battery is absent, VBAT begins
at zero when a powered wall adapter is first connected to
the battery charger. With a maximum load less than the
LTC4001-1 trickle charge current, battery voltage will ramp
WALL
ADAPTER
up until VBAT crosses the trickle charge threshold. When this
occurs, the LTC4001-1 switches over from trickle charge
to high rate (PWM) charge mode but initially delivers zero
current (because the soft-start pin is at zero). Battery voltage drops as a result of the system load, crossing below
the trickle charge threshold. The charger re-enters trickle
charge mode and the battery voltage ramps up again until
the battery charger re-enters high rate mode.
The soft-start voltage is slightly higher this time around
(than in the previous PWM cycle). Every successive time
that the charger enters high rate (PWM) charge mode,
the soft-start pin is at a slightly higher voltage. Eventually
high rate charge mode begins with a soft-start voltage that
causes the PWM charger to provide more current than the
system load demands, and VBAT rapidly rises until the float
voltage is reached.
For battery-less operation, system load current should be
restricted to less than the worst case trickle charge current
(preferably less than 30mA) when VBAT is less than 3.15V
(through an undervoltage lockout or other means). Above
VBAT = 3.15V, system load current less than or equal to the
high rate charge current is allowed. If operation without
a battery is required, additional low-ESR output filtering
improves start-up and other load transients. Battery-less
start-up is also improved if a 10k resistor is placed in
series with the soft-start capacitor.
LTC4001-1
BATTERY
CHARGER
SYSTEM
LOAD
40011 F06
+
Li-Ion
BATTERY
Figure 6. Typical Application
40011fa
16
LTC4001-1
APPLICATIONS INFORMATION
VBAT (V)
4
3
2
1
0
0
2
4
6
8
10
12
14
TIME (ms)
16
18
20
22
24
0
2
4
6
8
10
12
14
TIME (ms)
16
18
20
22
24
0
2
4
6
8
10
12
14
TIME (ms)
16
18
20
22
VSS (mV)
500
250
0
PWM
CHARGE
TRICKLE
CHARGE
24
40011 F07
Figure 7. Battery-Less Start-Up
40011fa
17
LTC4001-1
APPLICATIONS INFORMATION
Layout Considerations
With the exception of the input and output filter capacitors (which should be connected to PGND) all other
components that return to ground should be connected
to GNDSENS.
Switch rise and fall times are kept under 5ns for maximum
efficiency. To minimize radiation, the SW pin and input
bypass capacitor leads (between PVIN and PGND) should
be kept as short as possible. A ground plane should be
used under the switching circuitry to prevent interplane
coupling. The Exposed Pad must be connected to the
ground plane for proper power dissipation. The other paths
contain only DC and/or 1.5MHz tri-wave ripple current and
are less critical.
Recommended Components Manufacturers
For a list of recommend component manufacturers, contact
the Linear Technology application department.
L1
1.5μH
SW
VIN
4.5V TO 5.5V
R1
10k
C1
R2 10μF
1k D1
LED
SENSE
BATSENS
BAT
VINSENSE
PVIN
C4
10μF
PGND
+
2AHr
4.1V
Li-Ion
LTC4001-1
CHRG
NTC
TO μP
FROM μP
R3
10k
AT 25°C
FAULT
EN
PROG IDET
R4
549Ω
C2
0.22μF
R5
549Ω
TIMER SS
GNDSENS
C3
0.1μF
40011 F08
L1: VISHAY DALE IHLP-2525AH-01
R3: NTC VISHAY DALE NTHS0603N02N1002J
Figure 8. 2A Li-Ion Battery Charger with 3Hr Timer, Temperature
Qualification, Soft-Start, Remote Sensing and C/10 Indication
40011fa
18
LTC4001-1
PACKAGE DESCRIPTION
UF Package
16-Lead Plastic QFN (4mm × 4mm)
(Reference LTC DWG # 05-08-1692)
0.72 ±0.05
4.35 ± 0.05
2.15 ± 0.05
2.90 ± 0.05 (4 SIDES)
PACKAGE OUTLINE
0.30 ±0.05
0.65 BSC
RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS
BOTTOM VIEW—EXPOSED PAD
4.00 ± 0.10
(4 SIDES)
R = 0.115
TYP
0.75 ± 0.05
15
PIN 1 NOTCH R = 0.20 TYP
OR 0.35 × 45° CHAMFER
16
0.55 ± 0.20
PIN 1
TOP MARK
(NOTE 6)
1
2.15 ± 0.10
(4-SIDES)
2
(UF16) QFN 10-04
0.200 REF
0.00 – 0.05
0.30 ± 0.05
0.65 BSC
NOTE:
1. DRAWING CONFORMS TO JEDEC PACKAGE OUTLINE MO-220 VARIATION (WGGC)
2. DRAWING NOT TO SCALE
3. ALL DIMENSIONS ARE IN MILLIMETERS
4. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE
MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.15mm ON ANY SIDE
5. EXPOSED PAD SHALL BE SOLDER PLATED
6. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION
ON THE TOP AND BOTTOM OF PACKAGE
40011fa
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.
19
LTC4001-1
RELATED PARTS
PART NUMBER DESCRIPTION
®
COMMENTS
LT 1511
3A Constant-Current/Constant-Voltage Battery
Charger
High Efficiency, Minimum External Components to Fast Charge Lithium, NIMH
and NiCd Batteries, 24-Lead SO Package
LT1513
SEPIC Constant or Programmable Current/Constant- Charger Input Voltage May Be Higher, Equal to or Lower Than Battery Voltage,
Voltage Battery Charger
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LT1571
1.5A Switching Charger
1- or 2-Cell Li-Ion, 500kHz or 200kHz Switching Frequency, Termination Flag,
16- and 28-Lead SSOP Packages
LTC1729
Li-Ion Battery Charger Termination Controller
Trickle Charge Preconditioning, Temperature Charge Qualification,
Time or Charge Current Termination, Automatic Charger and Battery Detection,
and Status Output, MS8 and SO-8 Packages
LT1769
2A Switching Charger
Constant-Current/Constant-Voltage Switching Regulator, Input Current Limiting
Maximizes Charge Current, 20-Lead TSSOP and 28-Lead SSOP Packages
LTC4001
Monolithic 2A Switchmode Synchronous Li-Ion
Battery Charger
4.2V Float Voltage, Standalone, 4V ≤ VIN ≤ 5.5V, 6VMAX, 7V Transient,
1.5MHz, Efficiency > 90%, 4mm × 4mm QFN-16 Package
LTC4002
Standalone Li-Ion Switch Mode Battery Charger
Complete Charger for 1- or 2-Cell Li-Ion Batteries, Onboard Timer Termination,
Up to 4A Charge Current, 10-Lead DFN and SO-8 Packages
LTC4006
Small, High Efficiency, Fixed Voltage Li-Ion Battery
Charger with Termination
Complete Charger for 2-, 3- or 4-Cell Li-Ion Batteries, AC Adapter
Current Limit and Thermistor Sensor, 16-Lead Narrow SSOP Package
LTC4007
High Efficiency, Programmable Voltage Battery
Charger with Termination
Complete Charger for 3- or 4-Cell Li-Ion Batteries, AC Adapter Current Limit,
Thermistor Sensor and Indicator Outputs, 24-Lead SSOP Package
LTC4008
4A, High Efficiency, Multi-Chemistry Battery Charger Complete Charger for 2- to 6-Cell Li-Ion Batteries or 4- to 18-Cell Nickel
Batteries, Up to 96% Efficiency, 20-Lead SSOP Package
40011fa
20 Linear Technology Corporation
LT 1207 REV A • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 ● FAX: (408) 434-0507
●
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© LINEAR TECHNOLOGY CORPORATION 2007