AD ADP3804JRU-126

=
High Frequency Switch Mode
Li-Ion Battery Charger
ADP3804
Preliminary Technical Data
FEATURES
Li-Ion Battery Charger
Fixed 12,525 V, 12.600 V, or Adjustable Battery
Voltage
High End-of-Charge Voltage Accuracy
ⴞ 0.4% @ +25
+25ⴗⴗ C
ⴞ 0.6% @ 5
5ⴗⴗ C to 55
55ⴗⴗ C
ⴞ 0.75% @ 0
0ⴗⴗ C to 85
85ⴗⴗ C
Programmable Charge Current with
Rail-to-Rail Sensing
System Current Sense with Reverse Input Protection
Softstart Charge Current
Undervoltage Lockout
Boosted Synchronous Drive For External NMOS
Programmable Oscillator Frequency
Oscillator SYNC Pin
Constant Current/Constant Voltage Flag
Trickle Charge
APPLICATIONS
Portable Computers
Fast Chargers
GENERAL DESCRIPTION
The ADP3804 is a complete Li-Ion battery charging IC. The
device combines high output voltage accuracy with constant
current control to simplify the implementation of ConstantCurrent, Constant-Voltage (CCCV) chargers. The ADP3804 is
available in two options. The ADP3804-12.6 guarantees the
final battery voltage to 12.6 V ± 0.6%, the ADP3804-12.5
guarantees 12.525 V ± 0.6% and the ADP3804 is adjustable
using two external resistors to set the battery voltage. The
current sense amplifier has rail-to-rail inputs to accurately
operate under low drop out and short circuit conditions. The
charge current is programmable with a DC voltage on ISET. A
second differential amplifier senses the system current across an
external sense resistor and outputs a linear voltage on the ISYS
pin. The boosted synchronous driver allows the use of two
NMOS transistors for lower system cost.
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FUNCTIONAL BLOCK DIAGRAM
VCC BSTREG
BST
DRVH
SW
DRVL
CS+ CS
PGND
BOOSTED
SYNCHRONOUS
DRIVER
REG
SYS+ SYS
AMP
1
AMP
2
BOOST
REGULATOR
+
SUPPLY
REGULATOR
LIMIT
ISYS
g m1
UVLO
ISET
REF
SD
REFERENCE
+
BIAS
INPUT
DIVIDER
ADP3804-12.6
ADP3804-12.5
VREF
g m2
BAT
VREF
OSCILLATOR
BATTERY
ADJUST
ADJ
ADP3804
AGND
REV. PrI
SYNC
CT
COMP
CCCV
12/5/00
Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices for its
use, nor for any infringements of patents or other rights of third parties
which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Analog Devices.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781/329-4700
World Wide Web Site: http://www.analog.com
Fax: 781/326-8703
© Analog Devices, Inc., 2000
ADP3804–SPECIFICATIONS1 (@ 0ⴗC £ T £ 100ⴗC, VCC =16 V, unless otherwise noted)
A
Parameter
Conditions
Symbol
Min
Typ
Max
Units
TA = +25°C
5°C £ TA £ 55°C
0°C £ TA £ 85°C
0°C £ TA £ 100°C
Part in Operation
Part in Shutdown
VBAT
VBAT
12.550
12.524
12.505
12.474
400
12.6
12.650
12.676
12.695
12.726
V
V
V
V
kW
mA
BATTERY SENSE INPUT
ADP3804-12.6
VBAT
VBAT
VBAT
VBAT
Input Resistance
Input Current
VBAT
VBAT
RBAT
IBAT(SD)
500
0.2
1.0
BATTERY SENSE INPUT
ADP3804-12.5
VBAT
VBAT
VBAT
VBAT
Input Resistance
Input Current
BATTERY SENSE INPUT
ADP3804
VBAT
VBAT
VBAT
Input Current
OSCILLATOR
Maximum Frequency2
Frequency Variation3
CT Charge Current
0% Duty Cycle Threshold
Maximum Duty Cycle Threshold
SYNC Input High
SYNC Input Low
SYNC Input Current
TA = +25°C
5°C £ TA £ 55°C
0°C £ TA £ 85°C
0°C £ TA £ 100°C
Part in Operation
Part in Shutdown
VBAT
VBAT
VBAT
VBAT
RBAT
IBAT(SD)
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TA = +25°C
0°C £ TA £ 85°C
0°C £ TA £ 100°C
VBAT
VBAT
VBAT
CT = 150 pF
12.475
12.450
12.430
12.400
400
2.490
2.481
2.475
12.525
500
0.2
2.500
0.2
fCT
fCT
ICT
1000
215
130
SYNCH
SYNCL
ISYNC
2.0
@ COMP Pin
@ COMP Pin
250
150
1.0
2.5
0.2
12.575
12.600
12.620
12.650
1.0
V
V
V
V
kW
mA
2.510
2.519
2.525
1.0
V
V
V
mA
285
170
0.8
1.0
kHz
kHz
mA
V
V
V
V
mA
GATE DRIVE
On Resistance
Rise, Fall Time
Overlap Protection Delay
SW Bias Current
CURRENT SENSE AMPLIFIER
Input Common-mode Range
Input Differential Mode Range
Input Offset Voltage5
Gain5
Input Bias Current
Input Offset Current
Input Bias Current
SYSTEM CURRENT SENSE6
Input Common Mode Range
Input Differential Range
Input Offset Voltage
Input Bias Current, SYS+
Input Bias Current, SYSVoltage Gain
Output Range
Limit Output Threshold
Limit Output Voltage
6
35
50
10
W
ns
ns
0.2
1.0
µA
IL = 10 mA
CL = 1 nF, DRVL and DRVH
DRVL Falling to DRVH Rising,
DRVH Falling to DRVL Rising
Part in Shutdown, VSW = 12.6 V
RON
tr , tf
tOP
VCS+ and VCS–
VCS4
0 V £ VCS(CM) £ VCC
VCS(CM)
VCS(DM)
VCS(VOS)
0 V £ VCS(CM) £ VCC, Part in Operation
0 V £ VCS(CM) £ VCC
Part in Shutdown
VCS(IB)
VCS(IOS)
SYS+ and SYS-
VSYS(CM)
4.0
VCC+0.3 V
(VSYS+) - (VSYS-)
VSYS(DM)
0
100
2.0
100
50
52
5.0
2.6
0.2
VSYS(DM) = 0 V, VSYS(CM) = 16 V
VSYS(DM) = 0 V, VSYS(CM) = 16 V
10 V £ VSYS(CM) £ VCC + 0.3V
IL = 1 mA7, VSYS(CM) > 6 V
VISYS > VTH(LIMIT), ISINK = 1 mA
–2–
0.0
0.0
VCC+0.3 V
160
1.0
25
50
1.0
0.2
IB(SYS+)
IB(SYS–)
48
VISYS
0
VTH(LIMIT) 2.4
VO(LIMIT)
1.0
50
25
50
2.5
0.1
100
2.0
1.0
mV
mV
V/V
µA
µA
µA
mV
mV
mA
mA
V/V
V
V
V
REV. PrI
ADP3804
Parameter
Conditions
Symbol
0.0 V < VISET £ 4.0 V
VISET = 4.0 V
VISET = 0.50 V,
0.0 V £ VISET £ 4.0 V
VISET/VCS
Min
Typ
Max
Units
–5
–20
25
±1.0
±10
0.2
+5
+20
1.0
V/V
%
%
mA
ISET INPUT
Charge Current Programming
Function
Programming Function Accuracy
ISET Bias Current
ADJ INPUT
VBAT Adjustment
VBAT Adjustment
VBAT Disable Threshold
ADJ Bias Current
BOOST REGULATOR
OUTPUT
Output Voltage
Output Current
ANALOG REGULATOR
OUTPUT
Output Voltage
Output Current
PRECISION REFERENCE
OUTPUT
Output Voltage
Output Current
SHUTDOWN (SD)
ON
OFF
SD Input Current
POWER SUPPLY
ON Supply Current
OFF Supply Current
UVLO Threshold Voltage
UVLO Hysteresis
IB
VADJ = 1 V
VADJ = 4 V
–4.8
+4.8
4.4
–5.0
+5.0
4.6
0.2
–5.2
+5.2
%
%
V
1.0
mA
6.8
3
7.0
5
7.2
V
mA
VREG
5..8
6.0
6.2
V
IREG
3.0
5.0
VREF
IREF
2.475
0.5
2.5
1.1
SDH
SDL
2.0
1.0 V £ VADJ £ 4.0 V
CL = 0.1 mF
VBSTREG
IBSTREG
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CL = 10 nF
No External Loads
No External Loads
Turn On
Turn Off
ISYON
ISYOFF
VUVLO
5.75
0.1
mA
2.525
V
mA
0.2
0.8
1.0
V
V
mA
8.0
2.0
6.0
0.3
10
10
6.25
0.5
mA
mA
V
V
0.1
external
0.4
V
V
3.0
10
µA
CCCV OUTPUT
Output Voltage Low
Output Voltage High
OUTPUT REVERSE
LEAKAGE PROTECTION
Leakage Current
Constant Current Mode8, VISET = 2.5 V,
ISINK = 100 µA
Constant Voltage Mode9, VISET = 2.5 V
VCC = Floating, VBAT = 12.6 V
1
IDISCH
All limits at temperature extremes are guaranteed via correlation using standard Statistical Quality Control (SQC) methods.
Guaranteed by design, not tested in production.
If SYNC function is used, then fSYNC must be greater than fCT, but less than 120% of fCT.
4
VCS = (VCS+) – (VCS–).
5
Accuracy guaranteed by ISET INPUT, Programming Function Accuracy specification.
6
System current sense is active during shutdown.
7
Load current is supplied through SYS+ pin.
8
VBAT < 95% of final or VCS > 80% of ISET programmed value.
9
VBAT ³ 95% of final and VCS £ 80% of ISET programmed value.
2
3
Specifications subject to change without notice.
REV. PrI
–3–
ADP3804
PIN FUNCTION DESCRIPTIONS
ABSOLUTE MAXIMUM RATINGS*
Input Voltage (VCC to GND) . . . . . . . . . . . –0.3 V to +25 V
BAT, CS+, CS– to GND . . . . . . . . . . . . –0.3 V to VCC+0.3 V
SYS+, SYS– to GND . . . . . . . . . . . . . . . . . . . . –25 V to +25 V
BST to PGND . . . . . . . . . . . . . . . . . . . . . . . –0.3 V to +30 V
BST to SW . . . . . . . . . . . . . . . . . . . . . . . . . . . –0.3 V to +8 V
SW to PGND . . . . . . . . . . . . . . . . . . . . . . . . . . –4 V to +25 V
DRVL to PGND . . . . . . . . . . . . . . . . . . . . . . . –0.3 V to +8 V
ISET, ADJ, CCCV, SD, SYNC, CT,
LIMIT, ISYS TO GND . . . . . . . . . . . . . . . . –0.3 V to +10 V
COMP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –0.3 V to +3 V
GND to PGND . . . . . . . . . . . . . . . . . . . . . . . –0.3 V to +0.3 V
Operating Ambient Temperature Range . . . . . . 0°C to 100°C
q JA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 115°C/W
Operating Junction Temperature Range . . . . . 0°C to +125°C
Storage Temperature Range . . . . . . . . . . . . –65°C to +150°C
Lead Temperature Range (Soldering 10 sec) . . . . . . +300°C
Pin
Number
NOTES
*This is a stress rating only and functional operation of the device at these or any
other conditions above those indicated in the operation section of this specification is not implied. Exposure to absolute maximum rating conditions for
extended periods may affect device reliability.
qJA is specified for worst case conditions with device soldered on a circuit board.
Battery
Voltage
ADP3804JRU
Adjustable
ADP3804JRU-12.5
12.525 V
ADP3804JRU-12.6
12.600 V
Package
Description
Package
Option
TSSOP-24
RU-24
TSSOP-24
RU-24
TSSOP-24
RU-24
PIN CONFIGURATION
24 Lead TSSOP
VCC 1
SYS– 2
SYS+ 3
24 SW
ADP3804
22 BST
TOP VIEW 21 BSTREG
LIMIT 5 (Not to Scale) 20 DRVL
CT 6
SYNC 7
19 PGND
Supply Voltage.
SYS–
Negative System Current Sense
Input.
3
SYS+
Positive System Current Sense
Input.
4
ISYS
System Current Sense Output.
5
LIMIT
System Current Sense Limit Output.
6
CT
Oscillator Timing Capacitor.
7
SYNC
Oscillator Synchronization Pin.
8
REG
6.0 V Analog Regulator Output.
9
REF
2.5 V Precision Reference Output.
10
SD
Shutdown Control Input.
11
COMP
External Compensation Node.
12
CCCV
Constant Current/Constant Voltage
Output.
13
AGND
Analog Ground.
14
BAT
Battery Sense Input. 2.5 V for
ADP3804, 12.525 V for ADP380412.5 or 12.6 V for ADP3804-12.6
15
ADJ
Battery Voltage Adjust Input.
16
ISET
Charge Current Program Input.
17
CS–
Negative Current Sense Input.
18
CS+
Positive Current Sense Input.
19
PGND
Power Ground.
20
DRVL
Low Drive Output switches between REG and PGND.
21
BSTREG
7.0 V Regulator Output for Boost.
22
BST
Floating Bootstrap Supply for
DRVH.
23
DRVH
High Drive Output switches between SW and BST.
24
SW
Buck Switching Node Reference for
DRVH.
18 CS+
8
17 CS–
REF 9
16 ISET
SD 10
15 ADJ
COMP 11
14 BAT
CCCV 12
13 AGND
REG
VCC
2
23 DRVH
ISYS 4
Function
1
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ORDERING GUIDE
Model
Mnemonic
CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily
accumulate on the human body and test equipment and can discharge without detection. Although the
device features proprietary ESD protection circuitry, permanent damage may occur on devices
subjected to high energy electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance degradation or loss of functionality.
–4–
REV. PrI
ADP3804
RSS1
10mΩ
Q1
IRF7807
VIN
R13
10Ω
50mΩ
22µH
C16 +
Q2
IRF7807D2 220µF
+
C15
220µF
R3
249Ω
VCC
0.1µF
DRVH
BST
SW
DRVL
PGND
BSTREG
7.0V
C10
0.1µF
SD
R1
10Ω
R2
10Ω
C1
470nF
CS-
CS+
BOOSTED
SYNCHRONOUS
DRIVER
VREF + VREG
UVLO
BIAS
R4
249Ω
C13
22nF
C9
C14
2.2µF
SYSTEM
DC/DC
RCS
L1
BATTERY
12.6V
C2
470nF
SYS+
ISYS
SYS-
+
AMP
2
+
AMP
1
LIMIT
VREF
2.5V
ISET
g m1
LOGIC
CONTROL
CCCV
*R11
412k
0.1%
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PR ECH TA
T DA
ADP3804-12.6
BAT
*R12
102k
0.1%
SD
g m2
OSCILLATOR
**R7
100k
ADP3804
ADP3804-12.5
VREF
AGND
REG
6.0V
REF
2.5V
SYNC
C7
200pF
CT
C6
200pF
COMP
C8
1µF
ADJ
R8
56Ω
C17
100nF
R5
6.81kΩ
R6
7.5kΩ
* ADP3804-12.6: R11 = SHORT, R12 = OPEN
** R7, OPEN IF CCCV FUNCTION IS NOT USED
Figure 1. Typical Application
THEORY OF OPERATION
The ADP3804 combines a boosted synchronous switching
driver with programmable current control and accurate final
battery voltage control in a Constant Current, Constant Voltage (CCCV) Li-Ion battery charger. High accuracy voltage
control is needed to safely charge Li-Ion batteries, which are
typically specified at 4.2 V ± 1% per cell. For a typical notebook computer battery pack, three cells are in series giving a
total voltage of 12.6 V. The ADP3804 is available in three
versions, a fixed 12.525 V output, a fixed 12.6 V output and an
adjustable output. The adjustable output is useful for charging
batteries with slightly different chemistry that result in a final
battery voltage slightly higher or lower than 4.2 V/ cell.
amount of heat generated in the charger, but also to stay within
the power limits of the AC adapter. With the addition of a
boosted high side driver, the ADP3804 drives two external
power NMOS transistors for a simple, lower cost power stage.
The ADP3804 also provides an uncommitted current sense
amplifier. This amplifier provides an analog output pin for
monitoring the current through an external sense resistor. The
amplifier can be used anywhere in the system that high side
current sensing is needed.
Charge Current Control
AMP1 in Figure 1 has a differential input to amplify the voltage
drop across an external sense resistor RCS. The input common
mode range is from ground to VCC allowing current control in
short circuit and low drop-out conditions. The gain of AMP1 is
internally set to 25 V/V for low voltage drop across the sense
resistor. During CC mode, gm1 forces the voltage at the output
of AMP1 to be equal to the external voltage at the ISET pin.
By choosing RCS and VISET appropriately, a wide range of
charge currents can be programmed:
Another requirement for safely charging Li-Ion batteries is
accurate control of the charge current. The actual charge current depends on the number of cells in parallel within the battery pack. Typically this is in the range of 2 A to 3 A. The
ADP3804 provides flexibility in programming the charge current over a wide range. An external resistor is used to sense the
charge current and this voltage is compared to a DC input
voltage. This programmability allows the current to be changed
during charging. For example, the charge current can be reduced for trickle charging.
ICHARGE =
The synchronous driver provides high efficiency when charging
at high currents. Efficiency is important mainly to reduce the
REV. PrI
–5–
VISET
25 ×RCS
(1)
ADP3804
approximately 200 nsec to ensure that the boost capacitor is
always charged. This off time sets the maximum duty cycle.
For example, a 200 kHz frequency (5 µsec period) gives a
maximum duty cycle of 96%.
Typical values of RCS are in the range from 25 mW to 50 mW,
and the input range of ISET is from 0 V to 4 V. If, for example,
a 2 A charger is required, then RCS could be set to 50 mW and
VISET = 2.5 V. The power dissipation in RCS should be kept
below 500 mW. In this example, the power is a maximum of
200 mW. Once RCS has been chosen, the charge current can be
adjusted during operation with VISET. Lowering VISET to
125 mV gives a charge current of 100 mA for trickle charging.
Components R3, R4, and C13 provide high frequency filtering
for the current sense signal.
The oscillator frequency is set by the external capacitor at the
CT pin and the internal current source of 150 µA according to
the following formula:
fOSC =
Final Battery Voltage Control
7V Boost Regulator
The driver stage is powered by the internal 7V boost regulator,
which is available at the BSTREG pin. Because the switching
currents are supplied by this regulator, decoupling must be
added. A 0.1 µF capacitor should be placed close to the
ADP3804, with the ground side connected close to the power
ground pin, PGND. This supply is not recommended for use
externally due to high switching noise.
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Amplifier gm2 compares the battery voltage to the internal reference voltage of 2.5 V. In the case of the ADP3804-12.5 and
ADP3804-12.6, an internal resistor divider sets the final battery
voltage to 12.6 V. In contrast, the ADP3804 requires external,
precision resistors. The divider ratio should be set to divide the
desired final voltage down to 2.5 V at the BAT pin:
Boosted Synchronous Driver
The PWM comparator controls the state of the synchronous
driver. A high output from the PWM comparator forces DRVH
on and DRVL off. The drivers have an ON resistance of approximately 5 W for fast rise and fall times when driving external MOSFETs. Furthermore, the boosted drive allows an
external NMOS transistor for the main switch instead of a
PMOS. A boost diode is internally connected between
BSTREG and BST, and a boost capacitor of 0.1 µF must be
added externally between BST and SW. The voltage between
BST and SW is typically 6 V.
(2)
These resistors should be high impedance to limit the battery
leakage current. Alternatively, an external NMOS can be added
in series with R12 to turn off during shutdown. In the case of
the ADP3804-12.5 and ADP3804-12.6, an internal MOSFET
disconnects the internal divider to reduce the leakage current
into BAT to less than 1 µA during shutdown. If the ADP380412.5 or ADP3804-12.6 is used, then R11 should be shorted
and R12 open. The reference and internal resistor divider are
referenced to the AGND pin, which should be connected close
to the negative terminal of the battery to minimize sensing
errors.
The DRVL pin switches between BSTREG and PGND. The 7
V output of BSTREG drives the external NMOS with high
VGS to lower the ON resistance. PGND should be connected
close to the source pin of the external synchronous NMOS.
When DRVL is high, this turns on the lower NMOS and pulls
the SW node to ground. At this point, the boost capacitor is
charged up through the internal boost diode. When the PWM
switches high, DRVL is turned off and DRVH turns on.
DRVH switches between BST and SW. When DRVH is on,
the SW pin is pulled up to the input supply (typically 16 V),
and BST rises above this voltage by approximately 6 V.
Final Battery Voltage Adjust
The ADJ pin provides an analog input to adjust the final battery voltage by ± 5%. Figure 2 shows the control curve for this
amplifier. Above the threshold voltage of 4.6 V, the amplifier is
turned off. Thus, to disable this function, ADJ should be connected to REG. In the linear range between 1 V and 4 V, the
percentage change in VBAT is a function VADJ as follows:
DVBAT % = 100 ×
(4)
A 200 pF capacitor sets the frequency to 250 kHz. The frequency can also be synchronized to an external oscillator by
applying a square wave input on SYNC. The SYNC function is
designed to allow only increases in the oscillator frequency.
The fSYNC should be no more than 20% higher than fOSC. The
duty cycle of the SYNC input is not important and can be
anywhere between 5% and 95%.
As the battery approaches its final voltage, the ADP3804
switches from CC mode to CV mode. The change is achieved
by the common output node of gm1 and gm2. Only one of the
two outputs controls the voltage at the COMP pin. Both amplifiers can only pull down on COMP, such that when either
amplifier has a positive differential input voltage, its output is
not active. For example, when the battery voltage, VBAT, is low,
gm2 does not control VCOMP. When the battery voltage reaches
the desired final voltage, gm2 takes control of the loop, and the
charge current is reduced.
R11 VBATTERY
=
-1
R12
2.5V
150mA
2 × CT × 1.5V
VADJ - 2.5V
30
Overlap protection is included in the driver to ensure that both
external MOSFETs are not on at the same time. When DRVH
turns off the upper MOSFET, the SW node goes low due to
the inductor current. The ADP3804 monitors the SW voltage,
and turns on DRVL when SW goes below 1 V. If, under low
current loads, the SW voltage does not drop below 1 V, DRVL
will turn on after time-out of 200 nsec. When DRVL turns off,
an internal timer adds a delay of 50 nsec before turning DRVH
on.
(3)
This percent change is the same for the ADP3804 (2.5 V output) and the ADP3804-12.6.
Oscillator and PWM
The oscillator generates a triangle waveform between 1 V and
2.5 V, which is compared to the voltage at the COMP pin,
setting the duty cycle of the driver stage. When VCOMP is below
1 V, the duty cycle is zero. Above 2.5 V, the duty cycle reaches
its maximum. The ADP3804 forces a minimum off time of
–6–
REV. PrI
ADP3804
2.5 V Precision Reference
UVLO
The voltage at the BAT pin is compared to an internal precision, low temperature drift reference of 2.5 V. The reference is
available externally at the REF pin. This pin should be bypassed with a 100 pF capacitor to the analog ground pin,
AGND. The reference can be used as a precision voltage externally. However, the current draw should not be greater than
100 µA, and no noisy, switching type loads should be connected.
Under-Voltage Lock-Out, UVLO, is included in the ADP3804
to ensure proper start-up. As VCC rises above 1 V, the reference and regulators will track VCC until they reach their final
voltages. However, the rest of the circuitry is held off by the
UVLO comparator. The UVLO comparator monitors both
regulators to ensure that they are above 5 V before turning on
the main charger circuitry. This occurs when VCC reaches 6 V.
Monitoring the regulator outputs makes sure that the charger
circuitry and driver stage have sufficient voltage to operate
normally. The UVLO comparator includes 300 mV of hysteresis to prevent oscillations near the threshold.
6 V Regulator
The 6 V regulator supplies power to most of the analog circuitry on the ADP3804. This regulator should be bypassed to
AGND with a 10 nF capacitor. This reference has a 3 mA
source capability to power external loads if needed.
Startup Sequence
During a startup from either SD going high or VCC exceeding
the UVLO threshold, the ADP3804 initiates a soft-start sequence. The soft-start timing is set by the compensation capacitor at the COMP pin and an internal 40 µA source.
Initially, both DRVH and DRVL are held low until VCOMP
reaches 1 V. This delay time is set by:
CCCV
An open drain output is available to signal when the ADP3804
switches from CC to CV charging. An external pull-up resistor
of 100 kW to REG or other pull-up voltage is required for this
function. If the CCCV signal is not needed, the pin should be
left open. The CCCV function uses two comparators to monitor the battery voltage and the charge current. In order for the
CCCV pin to go high, signaling CV mode, the battery voltage
must be higher than 95% of its final value, and the current
must be less than 80% of its programmed value. If the battery
voltage is less than 95% then CCCV will be low regardless of
the actual current flowing. This is to prevent a false output
during startup when the current is low.
System Current Sense
Y
R
A
N L
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C
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E
PR ECH TA
T DA
t DELAY =
(5)
For a 1 µF COMP capacitor, tDELAY is 25 msec. After this
initial delay, DRVL is turned on first for one period to give the
boost capacitor time to charge up. The duty cycle then ramps
up to its final value with the same ramp rate given for tDELAY.
For example, if VIN is 16 V and the battery is 10 V when charging is started, the duty cycle will be approximately 65%, corresponding to a VCOMP of ~2 V. The time for the duty cycle to
ramp from 0% at VCOMP = 1 V to 65% at VCOMP = 2 V is approximately 25 msec.
An uncommitted differential amplifier is provided for additional high side current sensing. This amplifier, AMP2, has a
fixed gain of 50 V/V from the SYS+ and SYS- pins to the analog output at ISYS. ISYS has a 1 µA source capability to drive
an external load. The common mode range of the input pins is
from 4 V to VCC. This amplifier is the only part of the
ADP3804 that remains active during shutdown. The power to
this block is derived from the bias current on the SYS+ and
SYS- pins.
Loop Feed Forward
As the startup sequence discussion shows, the response time at
COMP is slowed by the large compensation capacitor. To
speed up the response, two comparators can quickly feed forward around the normal control loop and pull the COMP node
to ground to limit any over shoot in either short circuit or overvoltage conditions. The over-voltage comparator has a trip
point set to 20% higher than the final battery voltage. The
over-current comparator threshold is set to 200 mV across the
CS pins, which is 25% above the maximum programmable
threshold. When these comparators are tripped, a normal softstart sequence is initiated. This will give 0% duty cycle with
DRVH off and DRVL on. The over-voltage comparator is
valuable when the battery is removed during charging. In this
case, the current in the inductor causes the output voltage to
spike up, and the comparator limits the maximum voltage.
Neither of these comparators affect the loop under normal
charging conditions.
A separate comparator is included to provide a flag when the
voltage at ISYS rises above 2.5 V. The open drain output is
capable of sinking 1 µA when the threshold is exceeded. This
comparator is turned off during shutdown to conserve power.
Shutdown
A high impedance CMOS logic input is provided to turn off the
ADP3804. When the voltage on SD is less than 0.8 V, the
ADP3804 is placed in low power shutdown. With the exception
of the system current sense amplifier, AMP2, all other circuitry
is turned off. The reference and regulators are pulled to ground
during shutdown and all switching is stopped. During this
state, the supply current is less than 10 µA. Also, the BAT,
CS+, CS-, and SW pins go to high impedance to minimize
current drain from the battery.
REV. PrI
CCOMP - 1V
40mA
–7–