MAXIM MAX1613EEE

19-4785; Rev 0; 11/98
NUAL
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Bridge-Battery Backup Controllers
for Notebooks
The MAX1612/MAX1613 manage the bridge battery
(sometimes called a hot-swap or auxiliary battery) in
portable systems such as notebook computers. They
feature a step-up DC-DC converter that boosts 2-cell or
3-cell bridge-battery voltages up to the same level as
the main battery. This voltage boosting technique
reduces the number of cells otherwise required for a 6cell plus diode-OR bridging scheme, reducing overall
size and cost. Another key feature is a trickle-charge
timer that minimizes battery damage caused by constant charging and eliminates trickle-charge current
drain on the main battery once the bridge battery is
topped off.
These devices contain a highly flexible collection of
independent circuit blocks that can be wired together
in an autonomous stand-alone configuration or used in
conjunction with a microcontroller. In addition to the
boost converter and charge timer, there is a micropower linear regulator (useful for RTC/CMOS backup as
well as for powering a microcontroller) and a high-precision low-battery detection comparator.
The two devices differ only in the preset linear-regulator
output voltage: +5.0V for the MAX1612 and +3.3V for
the MAX1613. Both devices come in a space-saving
16-pin QSOP package.
Features
♦ Reduce Battery Size and Cost
♦ Four Key Circuit Blocks
Adjustable Boost DC-DC Converter
NiCd/NiMH Trickle Charger
Always-On Linear Regulator (+28V Input)
Low-Battery Detector
♦ Low 18µA Quiescent Current
♦ Selectable Charging/Discharging Rates
♦ Preset Linear-Regulator Voltage
5V (MAX1612)
3.3V (MAX1613)
♦ 4V to 28V Main Input Voltage Range
♦ Internal Switch Boost Converter
♦ Small 16-Pin QSOP Package
Ordering Information
TEMP. RANGE
PIN-PACKAGE
MAX1612EEE
-40°C to +85°C
16 QSOP
MAX1613EEE
-40°C to +85°C
16 QSOP
PART
Applications
Notebook Computers
Portable Equipment
Backup Battery Applications
Typical Operating Circuit
Pin Configuration
TOP VIEW
MAIN BATTERY
OR
WALL
ADAPTER
15 LRO
BBATT 2
DC-DC
OUTPUT
LRI
MAX1612
MAX1613
V+
MAX1630
+3.3V
+5V
APPLICATION
CIRCUIT
DC-DC
CONVERTER
14 PGND
LX 3
LBO 4
BBATT
AUXILIARY
BRIDGE
BATTERY
16 LRI
ISET 1
VCPU
BBON 5
MAX1612
MAX1613
13 CD
12 CC
DCMD 6
11 GND
CCMD 7
10 LBI
9
FULL 8
FB
QSOP
________________________________________________________________ Maxim Integrated Products
1
For free samples & the latest literature: http://www.maxim-ic.com, or phone 1-800-998-8800.
For small orders, phone 1-800-835-8769.
MAX1612/MAX1613
General Description
MAX1612/MAX1613
Bridge-Battery Backup Controllers
for Notebooks
ABSOLUTE MAXIMUM RATINGS
LRI, ISET to GND....................................................-0.3V to +30V
LX to GND ..............................................................-0.3V to +14V
PGND to GND .......................................................-0.3V to +0.3V
BBATT, LRO, CCMD, DCMD, FULL, BBON,
LBO to GND ..........................................................-0.3V to +6V
CC, CD, LBI, FB to GND...........................-0.3V to (VLRO + 0.3V)
FB, LBI, ISET, and BBATT Current......................................50mA
LRO Output Current ...........................................................50mA
Continuous Power Dissipation (TA = +70°C)
QSOP (derate 8.30mW/°C above +70°C) .................... 667mW
Operating Temperature Range
MAX1612/MAX1613EEE ...................................-40°C to +85°C
Storage Temperature Range .............................-65°C to +160°C
Lead Temperature (soldering, 10sec) ............................ +300°C
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
ELECTRICAL CHARACTERISTICS
(VLRI = VISET = 20V, CCMD = DCMD = BBON = LRO, VBBATT = 3V, TA = TMIN to TMAX, unless otherwise noted. Typical values are at
TA = +25°C.) (Note 1)
PARAMETER
SYMBOL
Linear-Regulator Input Voltage
Range
VLRI
Linear-Regulator Quiescent
Current
ILRI
Linear-Regulator Output Voltage
Linear-Regulator Output
Undervoltage Lockout
Threshold
VLRO
VUVLO
CONDITIONS
MIN
TYP
MAX
MAX1612
5.7
28
MAX1613
4
28
V BBON ≥ 2V
18
28
V DCMD = 0, R BBON = 1MΩ to GND
(boost converter on)
42
58
0 ≤ ILRO ≤ 10mA
5.7V ≤ VLRI ≤ 28V
(MAX1612)
4.7
5.0
5.3
4V ≤ VLRI ≤ 28V
(MAX1613)
3.1
3.3
3.5
LRO rising hysteresis = 200mV
UNIT
V
µA
V
2.97
V
5
µA
5
µA
1
1.3
V
0.1
5
%
V
2.65
BATTERY CHARGER
ISET Leakage Current
BBATT Leakage Current
Charge-Switch On Voltage
IISET(LEAK)
0.3
VISET = 28V, VBBATT = 0
IBBATT(LEAK) VISET = 0 or 28V, VBBATT = 6V
IISET = 10mA, V CCMD = 0, VBBATT = 2V
-5
0.5
CCMD = GND, IISET = 10mA, VBBATT = 2V,
%loss = [(IISET - IBBATT) / IISET) · 100%
Charge-Switch Loss Current
LOW-BATTERY COMPARATOR
LBI Falling Trip Voltage
VLBTL
1.76
1.8
1.84
LBI Rising Trip Voltage
VLBTH
1.955
2
2.045
V
0.2
10
nA
1
µA
LBI Input Current
LBO, FULL Output Leakage
Current
ILBI
ILBO, IFULL
LBO, FULL Output Voltage Low
LBI Comparator Response Time
2
VLBI = 1.9V
V LBO = VFULL = 5.5V
ISINK = 1mA
tPD
Overdrive = 100mV
0.4
20
_______________________________________________________________________________________
V
µs
Bridge-Battery Backup Controllers
for Notebooks
(VLRI = VISET = 20V, CCMD = DCMD = BBON = LRO, VBBATT = 3V, TA = TMIN to TMAX, unless otherwise noted. Typical values are at
TA = +25°C.) (Note 1)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNIT
DC-DC CONVERTER
FB Trip Point
VFB
FB Input Current
IFB
LX Switch Current Limit
1.95
VFB = 2.1V
IPEAK
LX Off-Leakage
LX On-Resistance
0.580
R BBON = 100kΩ to GND
RDSON
V
10
nA
0.835
1.100
A
VLX = 12V
0.01
10
µA
ILX = 200mA
0.5
1.5
Ω
-0.1
0.2
V
2.1
V
5.65
950
95
1
µA
Hz
Hz
V
%
0.8
V
Voltage that allows a new cycle, defined as
(VBBATT - VLX) (see DC-DC Converter section)
LX Zero Crossing Trip Threshold
2.05
0.15
-0.2
BBON Logic Input Low Voltage
TIMER BLOCK
CC Output Current
CD Oscillator Frequency
CC Oscillator Frequency
ISET Logic Input Low Voltage
CD to CC Current Matching
Logic Input Low Level
VIL
CCMD, DCMD
Logic Input High Level
VIH
CCMD, DCMD
I(CCMD),
I(DCMD)
Logic Input Leakage Current
4.35
600
60
0.4
-1
V CCMD = 0, CC = GND
CCD = 3.3nF
CCC = 33nF
Resets the counter
V DCMD = 0, CD = GND
CDOSC
CCOSC
5.00
758
75.8
2.2
V
1
V CCMD, V DCMD = 0 to VLRO
µA
Note 1: Specifications from 0°C to -40°C are guaranteed by design, not production tested.
Typical Operating Characteristics
(Circuit of Figure 3, TA = +25°C, unless otherwise noted.)
DISCHARGE TIME
vs. OUTPUT CURRENT
OSCILLATOR FREQUENCY
vs. CAPACITANCE
VOUT = 5V
VOUT = 7V
40
20
MAX612-03
80
10k
VOUT = 5V
VOUT = 7V
VOUT = 6V
70
EFFICIENCY (%)
80
90
MAX1612-02
100
60
100k
OSCILLATOR FREQUENCY (Hz)
DISCHARGE TIME (MINUTES)
2 CELLS (SANYO N-50AAA)
MAX612-01
120
EFFICIENCY vs. OUTPUT CURRENT
(BBATT = 3.6V)
1k
100
CD
60
50
40
30
CC
10
BBATT = 3.6V
RBBON = 240kΩ
NOTE: DC-DC
CONVERTER
SUPPLIES VLRI
20
10
0
0
5
10
15
20
25
30
OUTPUT CURRENT (mA)
35
40
45
1
0.1
0
1
10
CAPACITANCE (nF)
100
1000
1µ
10µ
100µ
1m
10m
100m
1
OUTPUT CURRENT (A)
_______________________________________________________________________________________
3
MAX1612/MAX1613
ELECTRICAL CHARACTERISTICS (continued)
Typical Operating Characteristics (continued)
(Circuit of Figure 3, TA = +25°C, unless otherwise noted.)
50
40
BBATT = 2.4V
RBBON = 240kΩ
NOTE: DC-DC
CONVERTER
SUPPLIES VLRI
30
20
10
BBATT = 2.4V
60
50
40
30
VOUT = 6V
RBBON = 240kΩ
NOTE: DC-DC
CONVERTER
SUPPLIES VLRI
20
10
0
0
1µ
10µ
100µ
1m
10m
100m
1
1µ
10µ
OUTPUT CURRENT (A)
100µ
1m
10m
100m
40
MAX1613
RBBON = 100kΩ TO GND
30
MAX1612
20
MAX1613
VBBON = VLRO
10
0
0
1
5
10
BBATT LEAKAGE CURRENT
vs. BBATT INPUT VOLTAGE
600
400
200
ILOAD = 5mA
0.5
0
3.31
3.29
-0.5
-1.0
3.27
-1.5
0
3.25
-2.0
5
7
9
11 13 15 17 19 21 23 25
2.0
BBON CURRENT (µA)
2.5
3.0
3.5
4.0
4.5
5.0
5.5
5
10
20
SWITCHING FREQUENCY vs. RBBON
SWITCHING FREQUENCY (kHz)
3.32
3.30
3.28
3.26
3.24
MAX612-11
350
MAX612-10
VLRI = 20V
3.34
15
VLRI (V)
BBATT INPUT VOLTAGE (V)
3.36
VLRO (V)
0
6.0
MAX1613
LRO VOLTAGE vs. LOAD CURRENT
300
250
200
150
3.22
100
3.20
0
2
4
6
8
10 12 14 16 18 20
LOAD CURRENT (mA)
4
30
3.33
1.0
VLRO (V)
BBATT LEAKAGE CURRENT (µA)
800
25
3.35
MAX612-08
1.5
1000
20
MAX1613
LRO VOLTAGE vs. LRI VOLTAGE
2.0
MAX612-07
1200
15
VLRI (V)
OUTPUT CURRENT (A)
PEAK CURRENT vs. BBON CURRENT
MAX612-06
MAX1612
QUIESCENT CURRENT (µA)
70
EFFICIENCY (%)
60
BBATT = 3.6V
80
VOUT = 7V
VOUT = 6V
50
MAX612-05
VOUT = 5V
70
EFFICIENCY (%)
90
MAX612-04
90
80
QUIESCENT CURRENT
vs. LRI VOLTAGE
EFFICIENCY vs. OUTPUT CURRENT
(BBATT = 6V)
MAX612-09
EFFICIENCY vs. OUTPUT CURRENT
(BBATT = 2.4V)
PEAK CURRENT (mA)
MAX1612/MAX1613
Bridge-Battery Backup Controllers
for Notebooks
120
160
200
240
280
320
RBBON (kΩ)
_______________________________________________________________________________________
360
25
30
Bridge-Battery Backup Controllers
for Notebooks
PIN
NAME
FUNCTION
1
ISET
Bridge-Battery Charge-Current Input. Connect a current-setting resistor from this input to a voltage
higher than the bridge battery. Maximum current rating is 10mA. Pulling ISET below 0.4V resets the
internal counter.
2
BBATT
3
LX
4
LBO
5
BBON
Bridge-Battery On Input. When high, the DC-DC converter turns off. When pulled low through an
external resistor, the resistor sets the peak inductor current. The inductor current is approximately
42,000 times the current in the external resistor (RBBON).
6
DCMD
Discharge Command Input. When low with CCMD high, the internal timer counts down at a
frequency set by the CD capacitor. When both DCMD and CCMD are low, discharge takes
precedence.
7
CCMD
Charge Command Input. When low with DCMD high, the internal switch from ISET to BBATT is
closed, charging the bridge battery. CCMD is inhibited if DCMD is low. The internal timer counts up
at a frequency set by the CC capacitor.
8
FULL
9
FB
Feedback Input of Step-Up DC-DC Converter. Regulates to 2V. Connect feedback resistors to set
output voltage (Figure 2).
10
LBI
Low-Battery-Detector Input. When LBI falls below 1.8V, LBO goes low and sinks current. When LBI
goes above 2.0V, LBO goes high impedance. Hysteresis is typically 200mV.
11
GND
12
CC
Charge Oscillator Capacitor Input. This capacitor programs the charging oscillator frequency,
which sets the time for the internal counter to reach all 1s. Determine the capacitor value by: CC
(in nF) = 4.3 · charge time (in hours).
13
CD
Discharge Oscillator Capacitor Input. This capacitor sets the discharging oscillator frequency,
which determines the maximum time to decrement the counter from all 1s to all 0s. Calculate the
capacitor value as follows: CD (in nF) = 4.3 · discharge time (in hours).
14
PGND
15
LRO
5V (MAX1612) or 3.3V (MAX1613) Linear-Regulator Output. Bypass to GND with a 1µF capacitor.
Maximum external load current is 10mA.
16
LRI
Linear-Regulator Supply Input
Bridge-Battery Connection. Bridge-battery charger output.
Step-Up DC-DC Converter N-Channel MOSFET Drain. The maximum operating range is 12V.
Open-Drain Low-Battery Detector Output. When VLBI falls below 1.8V, LBO sinks current. When
VLBI rises above 2.0V, LBO becomes high impedance.
Open-Drain Bridge-Battery Full Indicator Output. When the internal timer reaches all 1sec, FULL
goes high impedance.
Ground
Power Ground and Step-Up DC-DC Converter N-Channel MOSFET Source
_______________________________________________________________________________________
5
MAX1612/MAX1613
Pin Description
MAX1612/MAX1613
Bridge-Battery Backup Controllers
for Notebooks
TO MAIN
DC-DC
VMAIN
VCHARGE
L1
RISET
COUT
VBBATT
D1
LRI
LRO
TO EXTERNAL
LOADS
ISET
BBATT
MAX1612
MAX1613
+3.3/+5V
LINEAR REGULATOR
LX
2.0V
REFERENCE
PULSEFREQUENCY
MODULATION
CONTROL
BLOCK
GND
CC
CCC
CD
CCD
CHARGE
OSCILLATOR
R1
N-CHANNEL
PGND
FB
R2
TIMER BLOCK
CHARGE/DISCHARGE
COUNTER
LBI
DISCHARGE
OSCILLATOR
R3
1.8V/2.0V
FULL CCMD DCMD BBON
LBO
RBBON
Figure 1. Functional Diagram
_______________Detailed Description
The MAX1612/MAX1613 manage the bridge battery
(auxiliary battery) in portable systems. These devices
consist of a timer block that monitors the charging
process, a linear regulator for supplying IC power and
external circuitry to the MAX1612/MAX1613, and a DCDC step-up converter that powers the system when the
main battery is removed (Figure 1). The boost DC-DC
converter reduces the number of bridge-battery cells
required to supply the system’s DC-DC converter.
When the main supply is present, the DC-DC converter
is inactive, reducing the drain on the main battery to
only 18µA. However, if the main battery voltage falls (as
detected by the low-battery comparator), the bridge
battery becomes the input source.
6
The MAX1612/MAX1613 have an internal linear regulator set at +5V (MAX1612) or +3.3V (MAX1613). The linear regulator can deliver a load up to 10mA, making it
capable of powering external components such as a
microcontroller (Figure 4). An undervoltage lockout feature disables the device when the input voltage falls
below the operating range, preventing the DC-DC converter from inadvertently powering up.
The MAX1612/MAX1613 feature an internal counter
intended to track the charging and discharging
process. The counter tracks the charge on the bridge
battery, allowing trickle charge to terminate when the
maximum charge is achieved. The charging rate is
determined by current through the ISET switch, and
limited by the switch’s maximum current specification
as well as by the bridge cell’s charging capability. As
_______________________________________________________________________________________
Bridge-Battery Backup Controllers
for Notebooks
LRO
MAX1612
MAX1613
1M
BBON
MICROCONTROLLER
250k
GND
I/O
2N7002
Figure 2. Reducing BBON Noise Sensitivity
specifications vary, the counter frequency can be
adjusted to accommodate these variances by adjusting
CCC. Similarly, the discharging oscillator frequency can
be adjusted with the CCD capacitor. However, the rate
of bridge battery discharge depends on the DC-DC
converter’s load. Decrementing the charge/discharge
counter is used only to estimate the remaining charge
on the bridge battery. The counter increments (or
decrements) based on CCMD and DCMD logic states.
Note that the net charge must exceed the net discharge to compensate for charging efficiency losses.
Figure 3 shows a typical stand-alone application (see
Design Procedure for details). It reduces the need for
an external microcontroller to manage these functions.
However, if the design requires greater flexibility, a
microcontroller can be used as shown in Figure 4.
DC-DC Converter
The DC-DC step-up converter is a pulse-frequency
modulated (PFM) type. The on-time is determined by
the time it takes for the inductor current to ramp up to
the peak current limit (set via RBBON), which in turn is
determined by the bridge battery voltage and the
inductor value. With light load or no load, the converter
is forced to operate in discontinuous-conduction mode
(where the inductor current decays to zero with each
cycle) by a comparator that monitors the LX voltage
waveform. The converter will not start a new cycle until
the voltage at LX goes below the battery voltage. At full
load, the converter operates at the crossover point
between continuous and discontinuous mode. This
“edge of continuous” algorithm results in the minimum
possible physical size for the inductor. At light loads,
the devices pulse infrequently to maintain output regulation (VFB ≥ 2V). Note that the LX comparator requires
the DC-DC output voltage to be set at least 0.6V above
the maximum bridge battery voltage.
During the discharging process, drive DCMD low in
order to begin decrementing the counter. When the
counter is full, FULL is high. As soon as the counter
decrements just two counts, the FULL pin sinks current,
indicating that the battery is no longer full. The counter
only indicates the relative portion of the charge remaining. The incrementing and decrementing rate depends
on the maximum charge and discharge times set forth
by charging and discharging rates (see the following
equations for CC and CD). Note that the actual discharging is caused by the input current of the step-up
DC-DC converter loading down the bridge battery,
which is controlled via BBON rather than by DCMD.
The CC and CD capacitor values determine the
upcount and downcount rates by controlling the discharging oscillator frequency. Determine the maximum
charge and discharge times as follows:
CCC (nF) = 4.3 · tHRS
CCD (nF) = 4.3 · tHRS
where CCC is the charging capacitor, CCD is the discharging capacitor and tHRS is the maximum time in
hours for the process. Choose values that allow for
losses in the battery charging and discharging
process, such as battery charging inefficiencies, errors
in charging current value caused by variable main battery voltages, leakage currents, and losses in the
device’s internal switch. For charging, use the standard
charge rate recommended by the battery manufacturer. The maximum charging current is restricted to
the battery specifications. Consult the battery manufacturer’s specifications. Do not set the charging
current above 10mA.
_______________________________________________________________________________________
7
MAX1612/MAX1613
Timer Block
The MAX1612/MAX1613 have an internal charge/discharge counter that keeps track of the bridge-battery
charging/discharging process. When CCMD is low and
DCMD is high, the internal counter increments until the
FULL pin goes high, indicating that the counter has
reached all 1s. The maximum counter value is 221.
Additional pulses from the CC oscillator will not cause
the counter to wrap around. In the stand-alone application (Figure 3), terminate the charging process automatically by connecting FULL to CCMD. In a microcontroller application, pull CCMD high. The counter
only specifies the maximum time for full charging; it
does not control the actual rate of charging. CCMD
controls the charging switch, and the resistor at ISET
sets the charging rate.
MAX1612/MAX1613
Bridge-Battery Backup Controllers
for Notebooks
BRIDGE
BATTERY
MAIN
BATTERY
100µF
22µH
MBR0530
BBATT
ALWAYS-ON
OUTPUT
+5V/3.3V
LX
22µF
LRO
PGND
1µF
SYSTEM
DC-DC
(MAX1630)
470k
470k
FULL
MAX1612
MAX1613
2.2k
ISET
0.33µF
CCMD
442k
LBO
FB
160k
DCMD
20k
BBON
CC
LBI
CD
GND
200k
4.7nF
68nF
Figure 3. Stand-Alone Application
The counter block can be used to estimate the charge
remaining in the battery. For example, if the maximum
expected charge time is 14 hours (CCC = 60nF) and
the maximum expected discharge time is about 2 hours
(CCD = 8.6nF), the battery reaches full charge in 14
hours with the FULL pin going high. If the bridge battery must supply the load for 1 hour, the counter will
decrement down to about half full. Recharging the battery will now require only 7 hours to reach all 1s in the
counter, signaling with FULL going high.
If both DCMD and CCMD are pulled low simultaneously, the counter defaults to the discharge mode. When
the bridge battery is supplying the circuit, it is considered to be in discharge mode (Table 1).
Charge Current Selection (ISET)
A resistor between ISET and a voltage higher than the
bridge battery sets the charging rate. The switch is
open when CCMD is high and is turned on when
CCMD is pulled low (assuming DCMD is high). If the
voltage at ISET falls below 0.4V, the internal counter
resets to all 0s. The internal high-voltage switch has a
8
typical on-state voltage drop of 1V (Figure 1).
Therefore, the charge current equals:
IISET = [ (VCHARGE - VBBATT ) - 1V] / RISET
Linear-Regulator Output (LRO)
The linear-regulator output, LRO, is set at +5.0V for the
MAX1612 and at +3.3V for the MAX1613, with a tolerance of ±6%. For powering external circuitry such as
the microcontroller shown in Figure 4, LRO is guaranteed to deliver up to 10mA while maintaining regulation.
If the voltage at the linear-regulator input falls below the
operating range, an undervoltage-lockout feature shuts
down the entire device.
Table 1. CCMD, DCMD Truth Table
DCMD
CCMD
COUNTER
ISET SWITCH
0
0
Count Down
Off
0
1
Count Down
Off
1
0
Count Up
On
1
1
No Count
Off
_______________________________________________________________________________________
Bridge-Battery Backup Controllers
for Notebooks
MAIN
BATTERY
47µF
15µH
MBR0530
BBATT
LX
20µF
LRO
PGND
1µF
VCC
470k
MAX1612/MAX1613
BRIDGE
BATTERY
470k
MICROCONTROLLER
I/O
LBO
I/O
FULL
I/O
BBON
SYSTEM
DC-DC
(MAX1630)
2.4k
MAX1612
MAX1613
ISET
0.33µF
750k
FB
250k
I/O
DCMD
I/O
CCMD
CC
I/O
35.2k
LBI
CD
GND
479.1k
2N7002*
0.01µF
0.1µF
*OPTIONAL, TO RESET COUNTER
Figure 4. Microcontroller-Based Application
Low-Battery Comparator (LBI, LBO)
The MAX1612/MAX1613 feature a low-battery comparator with a factory-preset 1.8V threshold. This comparator is intended to monitor the main high-voltage
battery. As the voltage falls below 1.8V, the open-drain
LBO output sinks current. With 200mV of hysteresis, the
output will not go high until VLBI exceeds 2.0V. LBO
can easily be connected to BBON to start the DC-DC
converter when VLBI < 1.8V (stand-alone application,
Figure 3). Figure 4 shows an application using a microcontroller, where LBO alerts the microcontroller to the
falling voltage and pulls BBON low through an external
resistor to start the DC-DC converter while also pulling
DCMD low to start the counter.
BBON Control Input
The BBON input serves two functions: setting the peak
LX switch current, and enabling the DC-DC converter.
The control signal is normally applied to RBBON rather
than at the pin itself. The peak LX switch current is
directly proportional to and 42,000 times greater than
the current through R BBON (see Typical Operating
Characteristics). The BBON pin is internally regulated
to 2V, so that when the control input is forced low, the
voltage across RBBON is 2V.
When driving BBON from external logic, ensure the low
state has minimal noise. Otherwise, drive RBBON with
an N-channel FET whose source is returned directly to
GND (Figure 2).
Applications Information
Design Procedure
The following section refers to the Functional Diagram
of Figure 1.
Step 1: Select the output voltage and maximum output
current for the boost DC-DC converter. Generally,
choose an output voltage high enough to run the main
system’s buck DC-DC converters. Assuming the maximum battery capacity is 50mAh (Sanyo 1.2V N-50AAA),
the following equations can help the design process:
IPEAK = 2 · IOUT · (VOUT + VD) / (VBBATT - VRDSON)
IIN = 0.5 · IPEAK
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9
MAX1612/MAX1613
Bridge-Battery Backup Controllers
for Notebooks
where IPEAK is the peak current, IOUT is the load current, VBBATT is the bridge-battery voltage, VD is the forward drop across D1, VOUT is the output voltage, IIN is
average current provided by the bridge battery, and
VRDS(ON) is the voltage drop across the internal Nchannel power transistor at LX (typically 0.5V). A larger
number of cells reduces the I PEAK and, in effect,
reduces the discharge current, thereby extending the
discharge time. The same is true for decreasing the
output voltage or output current. For example, choose
the following values: IOUT = 100mA, VOUT = 5V, and
VBBATT = 2V (two cells). Using the minimum voltage of
1V for each cell, Table 2 summarizes some common
values.
Step 2: To avoid saturation, choose an inductor (L) with
a peak current rating above the IPEAK calculated in
Step 1. Use low series resistance (≤ 200mΩ), to optimize efficiency. In this example, a 15µH inductor is
used. See Table 4 for a list of component suppliers.
The “edge-of-continuous” DC-DC algorithm causes the
inductor value to fall out of the peak current equation.
Therefore, the exact inductor value chosen is not critical to the design. However, the switching frequency is
inversely proportional to inductance, so trade-offs of
switching losses versus physical inductor size can be
made by adjusting the inductor value.
f=
 (VBBATT − VRDSON ) (VOUT − VBBATT − VD ) 


L(IPEAK ) 
(VOUT − VRDSON − VD )

Table 2. Summary of Common Values for
Designing with the MAX1612/MAX1613
VOUT VBBATT AVERAGE
(V)
(V)
IPEAK (mA)
IIN
(mA)
MINIMUM
DISCHARGE TIME
(MINUTES)
10
6
2
600
300
5
2
500
250
12
4.5
2
450
225
13.2
6
3
400
200
15
5
3
333
167
18
4.5
3
300
150
20
6
4
300
150
20
5
4
250
125
24
Note: In this table, IOUT = 100mA and battery capacity = 50mAh.
Table 3. Component List
INDUCTORS
CAPACITORS
RECTIFIERS BATTERY
Sumida CD43
or CD54 series
Sprague 595D
series, AVX
TPS series
Motorola
MBR0530,
NIEC
EC10QS03L
1
where f is the switching frequency, VOUT is the output
voltage, VRDSON is the voltage across the internal MOSFET switch, VD is the forward voltage of D1, IPEAK is the
peak current, and VBBATT is the bridge battery voltage.
The maximum practical switching frequency is 400kHz.
Step 3: Choose the charging (CCC) and discharging
(CCD) timing capacitors. These capacitors set the frequency that the counter increments/decrements.
CCC (nF) = 4.3 · expected charge time (in hours)
CCD (nF) = 4.3 · expected discharge time (in hours)
For instance, using a charge time of 16 hours and a discharge time of one hour, CCC = 68nF and CCD = 4.3nF.
(Consult battery manufacturers’ specifications for standard charging information, which generally compensates for battery inefficiencies.)
Step 4: Using the peak current calculated in Step 1,
calculate the series resistor (RBBON) as follows:
R BBON = (V BBON · 42,000) / IPEAK
Table 4. Component Suppliers
SUPPLIER
PHONE
FAX
AVX
USA: 207-287-5111
USA: 207-283-1941
Motorola
USA: 408-749-0510
800-521-6274
NIEC
USA: 805-867-2555
Japan: 81-3-3494-7411
USA: 805-867-2556
Japan: 81-3-3494-7414
Sanyo
USA: 619-661-6835
Japan: 81-7-2070-6306
USA: 619-661-1055
Japan: 81-7-2070-1174
Sumida
USA: 708-956-0666
Japan: 81-3-3607-5111
USA: 708-956-0702
Japan: 81-3-3607-5144
—
Step 5: Resistors R1, R2, and R3 set the DC-DC converter’s output voltage and the low-battery comparator
trip value. The sum of R1, R2, and R3 must be less than
2MΩ, to minimize leakage errors. Choose resistor R1 =
750kΩ for the example. Calculate R2 and R3 as follows:
R2 = [ VOUT (R3) - 2 (R1) - 2 (R3) ] / (2 - VOUT )
R3 = (R1 + R2) / [ (VTRIP / 1.8) - 1]
where V BBON = 2V (internally regulated).
10
Sanyo
N-50AAA
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Bridge-Battery Backup Controllers
for Notebooks
MANUFACTURER
AND PART
INDUCTANCE
(µH)
RESISTANCE
(Ω)
RATED CURRENT
(A)
HEIGHT
(mm)
Sumida CD43-8R2
8.2
0.132
1.26
3.2
Sumida CD43-150
15
0.235
0.92
3.2
Sumida CD54-100
10
0.100
1.44
4.5
Sumida CD54-150
15
0.140
1.30
4.5
Sumida CD54-220
22
0.180
1.11
4.5
where VOUT is the DC-DC converter’s output voltage
and VTRIP is the voltage level the main battery must fall
below to trip the low-battery comparator. For example,
for a +5V boost DC-DC output, a 4.75V main battery
trip level is feasible. For this case, R1 = 750kΩ, R2 =
26kΩ, and R3 = 474kΩ.
Step 6: Select a resistor value to set the charging current. The resistor value at ISET limits the current
through the switch for bridge-battery charging. There is
a voltage drop across the high-voltage switch (see
Electrical Characteristics) with a typical value of 1V.
The maximum charge current through the internal highvoltage switch is 10mA.
RISET = (VCHARGE - VSWITCH - VBBATT) / ICHARGE
where V CHARGE is the charging supply voltage,
VSWITCH is the drop across the high-voltage internal
switch, V BBATT is the bridge battery voltage, and
ICHARGE is the charge current (in amperes).
Stand-Alone Application
To reduce cost and save space, the MAX1612/
MAX1613 can be operated in a stand-alone configuration, which eliminates the need for a microcontroller. A
stand-alone configuration could also reduce the workload of an existing microcontroller in the system, thus
allowing these unused I/Os to be used for other applications.
Figure 3 shows the MAX1612/MAX1613 operating without the microcontroller by using the low-battery detector to monitor the main battery. If the main battery is too
low, LBO pulls BBON and DCMD low to start the DCDC step-up converter and allow the bridge battery to
discharge. If the bridge battery requires charging,
FULL pulls CCMD low to start the battery charging
process. If both CCMD and DCMD are low, discharging takes precedence and the bridge battery keeps the
boost DC-DC converter active.
Microcontroller-Based Application
The MAX1612/MAX1613 are also suited to operate in a
microcontroller-based system. A microcontroller-based
application provides more flexibility by allowing for separate, independent control of the charging process, the
DC-DC converter, and the counter. Independent control can be beneficial in situations where other subsystems are operating, so that automatic switchover of
power might create some timing issues. If necessary, a
microcontroller can be used to reset the counter by taking ISET low. Another advantage of a microcontrollerbased system is the ability to stop charging the bridge
battery during a fault condition.
Figure 4 shows an example of how the MAX1612/
MAX1613 can be interfaced to a MAX1630 to deliver
the input voltage to the main DC-DC converter. In this
example, the microcontroller monitors the main battery’s status and switches over to the bridge battery
when V MAIN falls below a specified trip level (see
Design Procedure). When VMAIN falls below the LBI
threshold, LBO goes low. This signals the microcontroller, via an I/O, to switch over to the bridge battery as
the input source to the system main DC-DC converter.
In this application, the microcontroller also initiates the
bridge-battery charging process. When CCMD goes
low with DCMD high, the battery is charged through the
internal switch. The counter increments until it overflows
and FULL goes high, indicating a full charge. The
microcontroller I/O can read and write the appropriate
states to control the execution and timing of the entire
process.
If the main DC-DC is supplied by the main source, the
MAX1612/MAX1613’s step-up converter turns off, minimizing power consumption. The device typically draws
only 18µA of quiescent current under this condition.
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11
MAX1612/MAX1613
Table 5. Surface-Mount Inductor Information
Chip Information
TRANSISTOR COUNT: 3543
Package Information
QSOP.EPS
MAX1612/MAX1613
Bridge-Battery Backup Controllers
for Notebooks
12
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