MAXIM MAX1909

19-2805; Rev 0; 4/03
Multichemistry Battery Charger with Automatic
System Power Selector
Features
♦
♦
♦
♦
♦
♦
♦
♦
♦
♦
♦
♦
±0.5% Accurate Charge Voltage (0°C to +85°C)
±3% Accurate Input Current Limiting
±5% Accurate Charge Current
Programmable Charge Current >4A
Automatic System Power-Source Selection
Analog Inputs Control Charge Current and
Charge Voltage
Monitor Outputs for
Current Drawn from AC Input Source
AC Adapter Present
Up to 17.65V (max) Battery Voltage
Maximum 28V Input Voltage
Greater than 95% Efficiency
Conditioning Charge Safely Charges
Overdischarged Li+ Packs
Charges Any Battery Chemistry: Li+, NiCd, NiMH,
Lead Acid, etc.
Ordering Information
PART
MAX1909ETI
TEMP RANGE
PIN-PACKAGE
-40°C to +85°C
28 Thin QFN
Minimum Operating Circuit
Applications
P3
Notebook and Subnotebook Computers
TO
EXTERNAL LOAD
0.01Ω
AC ADAPTER: INPUT
SRC
Hand-Held Data Terminals
CSSP
Pin Configuration
CSSN
PDS
DHIV
SRC
PDL
P2
27
26
25
23
DHIV
SRC
24
DHI
CSSN
CSSP
PDL
28
PDS
DCIN
TOP VIEW
VCTL
LDO
22
MAX1909 LDO
ICTL
MODE
DCIN
LDO
1
21
2
20
DLOV
DLO
ACIN
3
19
PGND
REF
4
18
CSIP
PKPRES
5
17
CSIN
ACOK
6
16
BATT
MODE
7
15
GND
DLOV
ACIN
VCC
IINP
IINP
REF
CLS
P1
DHI
ACOK
MAX1909
TO
HOST
SYSTEM
LDO
DLO
N1
10µH
PGND
PKPRES
CSIP
9
10
11
12
13
14
IINP
CLS
ICTL
VCTL
CCI
CCV
CCS
0.015Ω
8
THIN QFN
CCV
CCI
CSIN
CCS
REF
BATT
GND
Functional Diagrams appear at end of data sheet.
________________________________________________________________ Maxim Integrated Products
For pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at
1-888-629-4642, or visit Maxim’s website at www.maxim-ic.com.
1
MAX1909
General Description
The MAX1909 highly integrated control IC simplifies
construction of accurate and efficient multichemistry
battery chargers. The MAX1909 uses analog inputs to
control charge current and voltage, and can be programmed by a host microcontroller (µC) or hardwired.
High efficiency is achieved through use of buck topology with synchronous rectification.
The maximum current drawn from the AC adapter is
programmable to avoid overloading the AC adapter
when supplying the load and the battery charger simultaneously. The MAX1909 provides a digital output that
indicates the presence of an AC adapter, and an analog output that monitors the current drawn from the AC
adapter. Based on the presence or absence of the AC
adapter, the MAX1909 automatically selects the appropriate source for supplying power to the system by controlling two external P-channel MOSFETs. Under system
control, the MAX1909 allows the battery to undergo a
relearning or conditioning cycle in which the battery is
completely discharged through the system load and
then recharged.
The MAX1909 is available in a space-saving 28-pin,
5mm ✕ 5mm thin QFN package and operates over the
extended -40°C to +85°C temperature range.
MAX1909
Multichemistry Battery Charger with Automatic
System Power Selector
ABSOLUTE MAXIMUM RATINGS
DCIN, CSSP, CSSN, SRC, ACOK to GND..............-0.3V to +30V
DHIV ........................................................…SRC + 0.3, SRC - 6V
DHI, PDL, PDS to GND ...............................-0.3V to (VSRC + 0.3)
BATT, CSIP, CSIN to GND .....................................-0.3V to +20V
CSIP to CSIN or CSSP to CSSN or PGND to GND ...-0.3V to +0.3V
CCI, CCS, CCV, DLO, IINP, REF,
ACIN to GND ........................................-0.3V to (VLDO + 0.3V)
DLOV, VCTL, ICTL, MODE, CLS, LDO,
PKPRES to GND ...................................................-0.3V to +6V
DLOV to LDO.........................................................-0.3V to +0.3V
DLO to PGND ..........................................-0.3V to (DLOV + 0.3V)
LDO Short-Circuit Current...................................................50mA
Continuous Power Dissipation (TA = +70°C)
28-Pin QFN (derate 20.8mW/°C above +70°C) .........1666mW
Operating Temperature Range ...........................-40°C to +85°C
Junction Temperature ......................................................+150°C
Storage Temperature Range .............................-60°C to +150°C
Lead Temperature (soldering, 10s) .................................+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
(Circuit of Figure 1, VDCIN = VCSSP = VCSSN = 18V, VBATT = VCSIP = VCSIN = 12V, VVCTL = VICTL = 1.8V, MODE = float, ACIN = 0, CLS =
REF, GND = PGND = 0, PKPRES = GND, LDO = DLOV, TA = 0°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
0
3.6
V
VVCTL = 3.6V (3 or 4 cells);
not including VCTL resistor tolerances
-0.8
+0.8
VVCTL = 3.6V/20 (3 or 4 cells); not including
VCTL resistor tolerances
-0.8
+0.8
CHARGE VOLTAGE REGULATION
VCTL Range
Battery Regulation Voltage
Accuracy
VVCTL Default Threshold
VCTL Input Bias Current
%
VVCTL = 3.6V (3 or 4 cells); including VCTL
resistor tolerances of 1%
-1.0
+1.0
VVCTL = VLDO (3 or 4 cells, default
threshold of 4.2V/cell)
-0.5
+0.5
VVCTL rising
4.1
4.3
VVCTL = 3V
0
2.5
VDCIN = 0, VVCTL = 5V
0
12
0
3.6
V
80.63
mV
V
µA
CHARGE-CURRENT REGULATION
ICTL Range
CSIP-to-CSIN Full-Scale CurrentSense Voltage
69.37
VICTL = 3.6V (not including ICTL resistor
tolerances)
-7.5
+7.5
-5
+5
VICTL = 0.9V (not including ICTL resistor
tolerances)
-7.5
+7.5
VICTL = 3.6V x 0.5 (including ICTL resistor
tolerances of 1%)
-7.0
+7.0
VICTL = 3.6V x 0.5 (not including ICTL
resistor tolerances)
Charge-Current Accuracy
VICTL Default Threshold
2
75.00
VICTL = VLDO (default threshold of 45mV)
-5
VICTL rising
4.1
%
+5
4.2
_______________________________________________________________________________________
4.3
V
Multichemistry Battery Charger with Automatic
System Power Selector
(Circuit of Figure 1, VDCIN = VCSSP = VCSSN = 18V, VBATT = VCSIP = VCSIN = 12V, VVCTL = VICTL = 1.8V, MODE = float, ACIN = 0, CLS =
REF, GND = PGND = 0, PKPRES = GND, LDO = DLOV, TA = 0°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
SYMBOL
CONDITIONS
BATT/CSIP/CSIN Input Voltage
Range
MIN
TYP
0
CSIP/CSIN Input Current
MAX
UNITS
19
V
Charging enabled
350
650
Charging disabled; VDCIN = 0 or VICTL = 0
0.1
1
ICTL Power-Down Mode
Threshold Voltage
0.75
ICTL Power-Up Mode Threshold
Voltage
0.85
ICTL Input Bias Current
µA
V
V
VICTL = 3V
-1
+1
VDCIN = 0V, VICTL = 5V
-1
+1
µA
INPUT CURRENT REGULATION
CSSP-to-CSSN Full-Scale
Current-Sense Voltage
72.75
Input Current-Limit
Accuracy
77.25
VCLS = REF
-3
+3
VCLS = REF x 0.75
-3
+3
VCLS = REF x 0.5
-4
+4
8.0
28
CSSP/CSSN Input Voltage Range
CSSP/CSSN Input Current
75.00
VCSSP = VCSSN = VDCIN > 8.0V
450
730
VDCIN = 0
0.1
1
CLS Input Range
mV
%
V
µA
1.6
REF
V
CLS Input Bias Current
VCLS = 2.0V
-1
+1
µA
IINP Transconductance
VCSSP - VCSSN = 56mV
2.7
3.3
mA/V
VCSSP - VCSSN = 75mV, terminated with
10kΩ
-7.5
+7.5
VCSSP - VCSSN = 56mV, terminated with
10kΩ
-5
+5
VCSSP - VCSSN = 20mV, terminated with
10kΩ
-10
+10
IINP Output Current
VCSSP - VCSSN = 150mV, VIINP = 0V
350
µA
IINP Output Voltage
VCSSP - VCSSN = 150mV, VIINP = float
3.5
V
IINP Accuracy
3.0
%
SUPPLY AND LINEAR REGULATOR
DCIN Input Voltage Range
VDCIN
8.0
DCIN falling
DCIN Undervoltage
Lockout Trip Point
DCIN Quiescent Current
IDCIN
7
28
7.4
DCIN rising
7.5
7.85
8.0V < VDCIN < 28V
2.7
6
V
V
mA
_______________________________________________________________________________________
3
MAX1909
ELECTRICAL CHARACTERISTICS (continued)
MAX1909
Multichemistry Battery Charger with Automatic
System Power Selector
ELECTRICAL CHARACTERISTICS (continued)
(Circuit of Figure 1, VDCIN = VCSSP = VCSSN = 18V, VBATT = VCSIP = VCSIN = 12V, VVCTL = VICTL = 1.8V, MODE = float, ACIN = 0, CLS =
REF, GND = PGND = 0, PKPRES = GND, LDO = DLOV, TA = 0°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
BATT Input Current
SYMBOL
IBATT
CONDITIONS
MIN
TYP
MAX
0.1
1
0.1
1
200
500
5.4
5.55
V
80
115
mV
3.20
4
5.15
V
4.2023
4.2235
4.2447
V
3.1
3.9
V
50
100
150
mV
100
200
300
mV
2.007
2.048
2.089
V
10
20
VBATT = 19V, VDCIN = 0V, or ICTL = 0V
VBATT = 16.8V, VDCIN = 19V, ICTL = 0V
VBATT = 2V to 19V,
VDCIN > VBATT + 0.3V
LDO Output Voltage
8.0V < VDCIN < 28V, no load
LDO Load Regulation
0 < ILDO < 10mA
LDO Undervoltage Lockout Trip
Point
VDCIN = 8.0V
5.25
UNITS
µA
REFERENCE
REF Output Voltage
Ref
REF Undervoltage Lockout Trip
Point
0 < IREF < 500µA
REF falling
TRIP POINTS
BATT POWER_FAIL Threshold
VDCIN - VBATT, VDCIN falling
BATT POWER_FAIL Threshold
Hysteresis
ACIN Threshold
ACIN rising
ACIN Threshold Hysteresis
ACIN Input Bias Current
VACIN = 2.048V
-1
30
mV
+1
µA
ns
SWITCHING REGULATOR
DHI Off-Time
VBATT = 16.0V, VDCIN = 19V, VMODE = 3.6V
360
400
440
DHI Minimum Off-Time
VBATT = 16.0V, VDCIN = 17V, VMODE = 3.6V
260
300
350
ns
5
10
µA
DLOV Supply Current
IDLOV
DLO low
Sense Voltage for Minimum
Discontinuous Mode Ripple
Current
7.5
mV
Cycle-by-Cycle Current-Limit
Sense Voltage
97
mV
Sense Voltage for
Battery Undervoltage Charge
Current
Battery Undervoltage
Threshold
DHIV Output Voltage
BATT = 3.0V per cell
MODE = float (3 cell), V
BATT rising
MODE = DLOV (4 cell), B
VATT rising
With respect to SRC
DHIV Sink Current
3
4.5
6
9.18
9.42
12.235
12.565
-4.5
-5.0
-5.5
10
mV
V
V
mA
DHI On-Resistance Low
DHI = VDHIV, IDHI = -10mA
2
5
Ω
DHI On-Resistance High
DHI = VCSSN, IDHI = 10mA
2
4
Ω
DLO On-Resistance High
VDLOV = 4.5V, IDLO = +100mA
3
7
Ω
DLO On-Resistance Low
VDLOV = 4.5V, IDLO = -100mA
1
3
Ω
4
_______________________________________________________________________________________
Multichemistry Battery Charger with Automatic
System Power Selector
(Circuit of Figure 1, VDCIN = VCSSP = VCSSN = 18V, VBATT = VCSIP = VCSIN = 12V, VVCTL = VICTL = 1.8V, MODE = float, ACIN = 0, CLS =
REF, GND = PGND = 0, PKPRES = GND, LDO = DLOV, TA = 0°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
VCTL = 3.6, VBATT = 16.8V, MODE = LDO
0.0625
0.125
0.2500
VCTL = 3.6, VBATT = 12.6V, MODE = FLOAT
0.0833
0.167
0.3330
UNITS
ERROR AMPLIFIERS
GMV Loop
Transconductance
mA/V
GMI Loop
Transconductance
ICTL = 3.6V, VCSSP - VCSIN = 75mV
0.5
1
2
mA/V
GMS Loop Transconductance
VCLS = 2.048V, VCSSP - VCSSN = 75mV
0.5
1
2
mA/V
CCI/CCS/CCV Clamp Voltage
0.25V < VCCV < 2.0V, 0.25V < VCCI < 2.0V,
0.25V < VCCS < 2.0V
150
300
600
mV
0.8
V
2.0
V
-2
+2
µA
0
28
LOGIC LEVELS
MODE Input Low Voltage
MODE Input Middle Voltage
1.6
MODE Input High Voltage
2.8
MODE Input Bias Current
MODE = 0V or 3.6V
1.8
V
ACOK AND PKPRES
ACOK Input Voltage Range
ACOK Sink Current
VACOK = 0.4V, ACIN = 1.5V
ACOK Leakage Current
VACOK = 28V, ACIN = 2.5V
PKPRES Input Voltage
Range
PKPRES Input Bias Current
PKPRES Battery Removal Detect
Threshold
PKPRES rising
1
V
mA
1
µA
0
LDO
V
-1
+1
90
PKPRES Hysteresis
µA
% of
LDO
1
%
PDS, PDL SWITCH CONTROL
PDS Switch Turn-Off Threshold
VDCIN - VBATT, VDCIN falling
50
100
150
mV
PDS Switch Threshold Hysteresis
VDCIN - VBATT
100
200
300
mV
PDS Output Low Voltage, PDS
Below SRC
IPDS = 0V
8
10
12
V
PDS Turn-On Current
PDS = SRC
6
12
PDS Turn-Off Current
VPDS = VSRC - 2V, VDCIN = 16V
10
50
PDL Switch Turn-On Threshold
VDCIN - VBATT, VDCIN falling
50
100
150
mV
PDL Switch Threshold Hysteresis
VDCIN - VBATT
100
200
300
mV
PDL Turn-On Resistance
PDL = GND
50
100
150
PDL Turn-Off Current
VSRC - VPDL = 1.5V
6
12
SRC Input Bias Current
Delay Time Between PDL and
PDS Transitions
SRC = 19V, DCIN = 0V
mA
mA
1
SRC = 19, VBATT = 16V
2.5
kΩ
mA
450
1000
5
7.5
µA
µs
_______________________________________________________________________________________
5
MAX1909
ELECTRICAL CHARACTERISTICS (continued)
MAX1909
Multichemistry Battery Charger with Automatic
System Power Selector
ELECTRICAL CHARACTERISTICS
(Circuit of Figure 1, VDCIN = VCSSP = VCSSN = 18V, VBATT = VCSIP = VCSIN = 12V, VVCTL = VICTL = 1.8V, MODE = float, ACIN = 0, CLS =
REF, GND = PGND = 0, PKPRES = GND, LDO = DLOV, TA = 0°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
V
CHARGE VOLTAGE REGULATION
VCTL Range
Battery Regulation Voltage
Accuracy
VVCTL Default Threshold
VCTL Input Bias Current
0
3.6
VVCTL = 3.6V (3 or 4 cells); not including
VCTL resistor tolerances
-0.8
+0.8
VVCTL = 3.6V/20 (3 or 4 cells); not including
VCTL resistor tolerances
-0.8
+0.8
VVCTL = 3.6V (3 or 4 cells); including VCTL
resistor tolerances of 1%
-1.0
+1.0
VVCTL = VLDO (3 or 4 cells, default
threshold of 4.2V/cell)
-0.8
+0.8
VVCTL rising
4.1
4.3
VVCTL = 3V
0
2.5
VDCIN = 0V, VVCTL = 5V
0
12
0
3.6
V
69.37
80.63
mV
-7.5
+7.5
-5
+5
VICTL = 0.9V (not including ICTL resistor
tolerances)
-7.5
+7.5
VICTL = 3.6V x 0.5 (including ICTL resistor
tolerances of 1%)
-7.0
+7.0
VICTL = VLDO (default threshold of 45mV)
-5
+5
VICTL rising
4.3
%
V
µA
CHARGE-CURRENT REGULATION
ICTL Range
CSIP-to-CSIN Full-Scale CurrentSense Voltage
VICTL = 3.6V (not including ICTL resistor
tolerances)
VICTL = 3.6V x 0.5 (not including ICTL
resistor tolerances)
Charge-Current Accuracy
VICTL Default Threshold
BATT/CSIP/CSIN Input Voltage
Range
CSIP/CSIN Input Current
0
Charging enabled
ICTL Power-Down Mode
Threshold Voltage
ICTL Power-Up Mode Threshold
Voltage
%
V
19
V
650
µA
0.75
V
0.85
V
INPUT CURRENT REGULATION
CSSP-to-CSSN Full-Scale
Current-Sense Voltage
6
72.75
_______________________________________________________________________________________
77.25
mV
Multichemistry Battery Charger with Automatic
System Power Selector
(Circuit of Figure 1, VDCIN = VCSSP = VCSSN = 18V, VBATT = VCSIP = VCSIN = 12V, VVCTL = VICTL = 1.8V, MODE = float, ACIN = 0, CLS =
REF, GND = PGND = 0, PKPRES = GND, LDO = DLOV, TA = 0°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
VCLS = REF
-3
+3
VCLS = REF x 0.75
-3
+3
VCLS = REF x 0.5
-4
+4
8.0
28
V
730
µA
1.6
REF
V
VCSSP - VCSSN = 56mV
2.7
3.3
mA/V
VCSSP - VCSSN = 75mV, terminated with
10kΩ
-7.5
+7.5
VCSSP - VCSSN = 56mV, terminated with
10kΩ
-5
+5
VCSSP - VCSSN = 20mV, terminated with
10kΩ
-10
+10
IINP Output Current
VCSSP - VCSSN = 150mV, VIINP = 0V
350
µA
IINP Output Voltage
VCSSP - VCSSN = 150mV, VIINP = float
3.5
V
Input Current-Limit
Accuracy
CSSP/CSSN Input Voltage Range
CSSP/CSSN Input Current
VCSSP = VCSSN = VDCIN > 8.0V
CLS Input Range
IINP Transconductance
IINP Accuracy
%
%
SUPPLY AND LINEAR REGULATOR
DCIN Input Voltage Range
VDCIN
8.0
DCIN falling
DCIN Undervoltage Lockout Trip
Point
DCIN rising
DCIN Quiescent Current
IDCIN
8.0V < VDCIN < 28V
BATT Input Current
IBATT
VBATT = 2V to 19V, VDCIN > VBATT + 0.3V
LDO Output Voltage
8.0V < VDCIN < 28V, no load
LDO Load Regulation
0 < ILDO < 10mA
LDO Undervoltage Lockout Trip
Point
VDCIN = 8.0V
28
7
7.85
V
V
6
mA
500
µA
5.55
V
115
mV
3.2
5.15
V
4.1960
4.2520
V
3.9
V
50
150
mV
100
300
mV
2.007
2.089
V
10
30
mV
5.25
REFERENCE
REF Output Voltage
Ref
REF Undervoltage Lockout Trip
Point
0 < IREF < 500µA
REF falling
TRIP POINTS
BATT POWER_FAIL Threshold
VDCIN - VBATT, VDCIN falling
BATT POWER_FAIL Threshold
Hysteresis
ACIN Threshold
ACIN rising
ACIN Threshold Hysteresis
_______________________________________________________________________________________
7
MAX1909
ELECTRICAL CHARACTERISTICS (continued)
MAX1909
Multichemistry Battery Charger with Automatic
System Power Selector
ELECTRICAL CHARACTERISTICS (continued)
(Circuit of Figure 1, VDCIN = VCSSP = VCSSN = 18V, VBATT = VCSIP = VCSIN = 12V, VVCTL = VICTL = 1.8V, MODE = float, ACIN = 0, CLS =
REF, GND = PGND = 0, PKPRES = GND, LDO = DLOV, TA = 0°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
SYMBOL
CONDITIONS
MIN
DHI Off-Time
VBATT = 16.0V, VDCIN = 19V, VMODE = 3.6V
DHI Minimum Off-Time
VBATT = 16.0V, VDCIN = 17V, VMODE = 3.6V
TYP
MAX
UNITS
360
440
ns
260
350
ns
10
µA
3
6
mV
9.18
9.42
12.235
12.565
-4.5
-5.5
SWITCHING REGULATOR
DLOV Supply Current
Sense Voltage for
Battery Undervoltage Charge
Current
IDLOV
DLO low
BATT = 3.0V per cell
Battery Undervoltage
Threshold
MODE = float (3 cell), VBATT rising
DHIV Output Voltage
With respect to SRC
MODE = DLOV (4 cell), VBATT rising
DHIV Sink Current
10
V
V
mA
DHI On-Resistance Low
DHI = VDHIV, IDHI = -10mA
5
Ω
DHI On-Resistance High
DHI = VCSSN, IDHI = 10mA
4
Ω
DLO On-Resistance High
VDLOV = 4.5V, IDLO = +100mA
7
Ω
DLO On-Resistance Low
VDLOV = 4.5V, IDLO = -100mA
3
Ω
ERROR AMPLIFIERS
GMV Loop Transconductance
VCTL = 3.6, VBATT = 16.8V, MODE = LDO
0.0625
0.2500
VCTL = 3.6, VBATT = 12.6V, MODE = FLOAT
0.0833
0.3330
mA/V
GMI Loop Transconductance
ICTL = 3.6V, VCSSP - VCSIN = 75mV
0.5
2
mA/V
GMS Loop Transconductance
VCLS = 2.048V, VCSSP - VCSSN = 75mV
0.5
2
mA/V
CCI/CCS/CCV Clamp Voltage
0.25V < VCCV < 2.0V, 0.25V < VCCI < 2.0V,
0.25V < VCCS < 2.0V
150
600
mV
0.8
V
2.0
V
LOGIC LEVELS
MODE Input Low Voltage
MODE Input Middle Voltage
1.6
MODE Input High Voltage
2.8
V
ACOK AND PKPRES
ACOK Input Voltage Range
ACOK Sink Current
0
VACOK = 0.4V, ACIN = 1.5V
PKPRES Input Voltage
Range
PKPRES Battery Removal Detect
Threshold
28
1
0
PKPRES rising
90
VDCIN - VBATT, VDCIN falling
50
V
mA
LDO
V
% of
LDO
PDS, PDL SWITCH CONTROL
PDS Switch Turn-Off Threshold
8
_______________________________________________________________________________________
150
mV
Multichemistry Battery Charger with Automatic
System Power Selector
(Circuit of Figure 1, VDCIN = VCSSP = VCSSN = 18V, VBATT = VCSIP = VCSIN = 12V, VVCTL = VICTL = 1.8V, MODE = float, ACIN = 0, CLS =
REF, GND = PGND = 0, PKPRES = GND, LDO = DLOV, TA = 0°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
100
300
mV
8
12
V
PDS Switch Threshold Hysteresis
VDCIN - VBATT
PDS Output Low Voltage, PDS
Below SRC
IPDS = 0V
PDS Turn-On Current
PDS = SRC
6
PDS Turn-Off Current
VPDS = VSRC - 2V, VDCIN = 16V
10
PDL Switch Turn-On Threshold
VDCIN - VBATT, VDCIN falling
50
150
mV
PDL Switch Threshold Hysteresis
VDCIN - VBATT
100
300
mV
PDL Turn-On Resistance
PDL = GND
50
150
kΩ
PDL Turn-Off Current
VSRC - VPDL = 1.5V
6
SRC Input Bias Current
SRC = 19, VBATT = 16V
Delay Time Between PDL and
PDS Transitions
mA
mA
mA
2.5
1000
µA
7.5
µs
Note 1: Guaranteed by design. Not production tested.
Typical Operating Characteristics
(Circuit of Figure 2, VDCIN = 20V, charge current = 3A, 4 Li+ series cells, TA = +25°C, unless otherwise noted.)
BATTERY INSERTION
AND REMOVAL RESPONSE
SYSTEM LOAD TRANSIENT RESPONSE
MAX1909 toc01
MAX1909 toc02
17V
5A
ISYSTEMLOAD
0A
VBATT
16V
VCCV
0A
5A
5A/div
IBATT
IIN
0A
5A IBATT
0A
IIN
0A 5A/div
VCCV
VCCI
VCCI
VCCV
CCS
3V
3V
2V
VCCI, VCCV
1V
CCI
VCCI
0V
500µs/div
2V
VCCI
1V
VCCS
0V
100µs/div
_______________________________________________________________________________________
9
MAX1909
ELECTRICAL CHARACTERISTICS (continued)
Typical Operating Characteristics (continued)
(Circuit of Figure 2, VDCIN = 20V, charge current = 3A, 4 Li+ series cells, TA = +25°C, unless otherwise noted.)
LDO LOAD REGULATION
LINE TRANSIENT RESPONSE
0
30V
VDCIN
20V
MAX1909 toc04
MAX1909 toc03
-0.2
LDO OUTPUT ERROR (%)
INDUCTOR CURRENT
200mA/div
3A
VBATT AC-COUPLED
200mV/div
-0.4
-0.6
-0.8
-1.0
-1.2
1.8V
VCCV
1.6V
-1.4
0
500µs/div
1
2
3
4
5
6
7
8
9
10
LDO CURRENT (mA)
REF LOAD REGULATION
-0.04
-0.06
-0.08
-0.10
-0.14
0
10
30
20
200
EFFICIENCY vs. CHARGE CURRENT
600
800
1000
90
88
86
84
82
MAX1909 toc09
450
400
1.5
2.0
CHARGE CURRENT (A)
2.5
3.0
60
3.5
CHARGER
DISABLED
3.0
350
300
250
200
85
2.5
2.0
1.5
150
1.0
100
0.5
0
0
1.0
35
IINP ERROR vs. INPUT CURRENT
50
80
10
4.0
IINP (%)
3 CELLS
0.5
-15
TEMPERATURE (°C)
500
SWITCHING FREQUENCY (kHz)
94
0
-40
SWITCHING FREQUENCY vs. VIN - VBATT
MAX1909 toc08
4 CELLS
96
10
400
REF CURRENT (µA)
100
92
-0.10
-0.20
0
INPUT VOLTAGE (V)
98
-0.05
-0.15
-0.12
-0.10
0
MAX1909 toc10
-0.05
0.05
REF OUTPUT ERROR (%)
0
0.10
MAX1909 toc06
MAX1909 toc05
-0.02
REF OUTPUT ERROR (%)
LDO OUTPUT ERROR (%)
0.05
REF vs. TEMPERATURE
0
MAX1909 toc07
LDO LINE REGULATION
0.10
EFFICIENCY (%)
MAX1909
Multichemistry Battery Charger with Automatic
System Power Selector
0
2
4
6
VIN - VBATT (V)
8
10
0
0.5
1.0
1.5
2.0
2.5
INPUT CURRENT (A)
______________________________________________________________________________________
3.0
3.5
Multichemistry Battery Charger with Automatic
System Power Selector
INPUT CURRENT-LIMIT ACCURACY
vs. SYSTEM LOAD
4
2
0
-2
-4
-6
-8
VBATT = 10V
2
1
VBATT = 16V
VBATT = 12V
0
ICHARGE = 3A
-1
2
1
0
-1
-2
-3
-2
1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0
MAX1909 toc13
VBATT = 13V
3
INPUT CURRENT-LIMIT ACCURACY vs. VCLS
3
INPUT CURRENT-LIMIT ACCURACY (%)
IINP ACCURACY (%)
6
4
INPUT CURRENT-LIMIT ACCURACY (%)
MAX1909 toc11
8
MAX1909 toc12
IINP ACCURACY vs. INPUT CURRENT
0.5
1.0
INPUT CURRENT (A)
1.5
2.0
2.5
3.0
1.5
2.0
2.5
PDL-PDS SWITCHING,
AC ADAPTER INSERTION
3.5
PDS-PDL SWITCHOVER,
WALL ADAPTER REMOVAL
MAX1909 toc14
MAX1909 toc15
20V
VPDS
3.0
VCLS (V)
SYSTEM LOAD (A)
VWALLADAPTER
10V
20V
20V
VSYSTEMLOAD
10V
VPDS
20V
VWALLADAPTER
10V
VSYSTEMLOAD, VPDS
10V
SYSTEM LOAD
VPDL
0V
VPDS
20V
VPDL
20V
VBATT
10V
VPDL
0V
VPDL, VBATT
10V
0V
VPDL
VSYSTEMLOAD
100µs/div
500µs/div
PDS-PDL SWITCHOVER,
BATTERY INSERTION
PDL-PDS SWITCHING,
BATTERY REMOVAL
MAX1909 toc16
20V
VPDS
15V
VSYSTEM
CONDITIONING MODE 10V
WALL ADAPTER = 18V
5V
VPKDET
0V
VPKPRES
15V
VBATT
10V
MAX1909 toc17
20V
VSYSTEM
CONDITIONING MODE 15V
WALL ADAPTER = 18V
10V
VPDS
5V
VPKPRES
0V
VPDL
15V
VBATT
10V
5V V
PDL
5V
0V
50µs/div
0V
10µs/div
______________________________________________________________________________________
11
MAX1909
Typical Operating Characteristics (continued)
(Circuit of Figure 2, VDCIN = 20V, charge current = 3A, 4 Li+ series cells, TA = +25°C, unless otherwise noted.)
Multichemistry Battery Charger with Automatic
System Power Selector
MAX1909
Pin Description
12
PIN
NAME
FUNCTION
1
DCIN
DC Supply Voltage Input. Bypass DCIN with a 1µF capacitor to power ground.
2
LDO
Device Power Supply. Output of the 5.4V linear regulator supplied from DCIN. Bypass with a 1µF capacitor.
3
ACIN
AC Detect Input. This uncommitted comparator input can be used to detect the presence of the charger’s
power source. The comparator’s open-drain output is the ACOK signal.
4
REF
4.2235V Voltage Reference. Bypass with a 1µF capacitor to GND.
5
PKPRES
6
ACOK
AC Detect Output. High-voltage open-drain output is high impedance when ACIN is greater than 2.048V. The
ACOK output remains a high impedance when the MAX1909 is powered down.
7
MODE
Trilevel Input for Setting Number of Cells and Asserting the Conditioning Mode:
MODE = GND; asserts conditioning mode.
MODE = float; charge with 3 times the cell voltage programmed at VCTL.
MODE = LDO; charge with 4 times the cell voltage programmed at VCTL.
8
IINP
Input Current Monitor Output. The current delivered at the IINP output is a scaled-down replica of the system
load current plus the input-referred charge current sensed across CSSP and CSSN inputs. The
transconductance of (CSSP - CSSN) to IINP is 3mA/V.
Pull PKPRES high to disable charging. Used for detecting presence of battery pack. This input can also be
used as a simple shutdown control.
9
CLS
Source Current-Limit Input. Voltage input for setting the current limit of the input source.
10
ICTL
Input for Setting Maximum Output Current
11
VCTL
Input for Setting Maximum Output Voltage
12
CCI
Output Current Regulation Loop Compensation Point. Connect 0.01µF to GND.
13
CCV
Voltage Regulation Loop Compensation Point. Connect 20kΩ in series with 0.01µF to GND.
14
CCS
Input Current Regulation Loop Compensation Point. Use 470pF to GND.
15
GND
Analog Ground
16
BATT
Battery Voltage Feedback Input
17
CSIN
Output Current-Sense Negative Input
18
CSIP
Output Current-Sense Positive Input. Connect a current-sense resistor from CSIP to CSIN.
19
PGND
20
DLO
21
DLOV
Low-Side Driver Supply. Bypass with a 0.1µF capacitor to ground.
22
DHIV
High-Side Driver Supply. Bypass with a 0.1µF capacitor to SRC.
23
DHI
High-Side Power MOSFET Driver Output. Connect to high-side PMOS gate. When the MAX1909 is shut down,
the DHI output is HIGH.
24
SRC
Source Connection for Driver for PDS/PDL Switches. Bypass SRC to power ground with a 1µF capacitor.
25
CSSN
Input Current Sense for Charger (Negative Input).
26
CSSP
Input Current Sense for Charger (Positive Input). Connect a current-sense resistor from CSSP to CSSN.
27
PDS
Power Source PMOS Switch Driver Output. When the MAX1909 is powered down, the PDS output is pulled to
SRC through an internal 1MΩ resistor.
28
PDL
System Load PMOS Switch Driver Output. When the MAX1909 is powered down, the PDL output is pulled to
ground through an internal 100kΩ resistor.
Power Ground
Low-Side Power MOSFET Driver Output. Connect to low-side NMOS gate. When the MAX1909 is shut down,
the DLO output is LOW.
______________________________________________________________________________________
Multichemistry Battery Charger with Automatic
System Power Selector
RS1
0.01Ω
MAX1909
P3
AC ADAPTER
TO
SYSTEM LOAD
C1
22µF
SRC
OUTPUT VOLTAGE: 12.6V
C22
1µF
CHARGE I LIMIT: 3.0A
CSSP
D4
R6
590kΩ
1%
CSSN
PDS
C17
0.1µF
SRC
R7
196kΩ
1%
DCIN
C5
1µF
MAX1909
PDL
LDO
VCTL
R4
100kΩ
LDO
DHIV
ICTL
OUTPUT
DLOV
ACIN
P2
C13
1µF
R13
33Ω
C16
1µF
MODE
VCC
P1
(INPUT I LIMIT: 7.5A)
R8
1MΩ
REF
DHI
CLS
ACOK
DLO
TO
HOST
SYSTEM
LDO
N1
L1
10µH
PGND
R9
10kΩ
CSIP
RS2
0.015Ω
PKPRES
CCV
CCI
R5
10kΩ
C11
0.1µF
CCS
C9
0.01µF
CSIN
BATT
GND
REF
C10
0.01µF
BATT +
C4
22µF
C12
1µF
BATTERY
TEMP
GND
BATT PGND
GND
Figure 1. Typical Operating Circuit Demonstrating Hardwired Control
______________________________________________________________________________________
13
MAX1909
Multichemistry Battery Charger with Automatic
System Power Selector
P3
P4
RS1
0.01Ω
AC ADAPTER
TO
SYSTEM LOAD
C1
22µF
SRC
OUTPUT VOLTAGE: 16.8V
D5
C15
1µF
D4
R6
590kΩ
1%
CSSP
CSSN
PDS
C17
0.1µF
SRC
R7
196kΩ
1%
DHIV
DCIN
C5
1µF
MAX1909
LDO
D/A OUTPUT
PDL
LDO
VCTL
P2
C13
1µF
ICTL
OPEN-DRAIN
DLOV
OUTPUTS
MODE
ACIN
VCC
C16
1µF
P1
R8
1MΩ
DHI
ACOK
INPUT
OUTPUT
PKPRES
A/D INPUT
C14
0.1µF
R9
10kΩ
(INPUT I LIMIT: 7.5A)
REF
DLO
CSIP
R19, R20
10kΩ
RS2
0.015Ω
C11
0.1µF
LDO
CSIN
BATT
CCI
R21
10kΩ
CCS
C9
0.01µF
L1
10µH
PGND
CLS
CCV
HOST
N1
IINP
R5
10kΩ
AVDD/REF
R13
33Ω
C10
0.01µF
GND
REF
BATT +
C4
22µF
SMART
BATTERY
C12
1µF
SCL
SCL
SDA
SDA
TEMP
GND
BATT PGND
GND
Figure 2. Smart-Battery Charger Circuit Demonstrating Operation with a Host Microcontroller
14
______________________________________________________________________________________
Multichemistry Battery Charger with Automatic
System Power Selector
MAX1909
DCIN
PKPRES
LDO
PACK_ON
RDY
5.4V
LINEAR
REGULATOR
0.9 * LDO
4.2235V
REFERENCE
ICTLOK
GND
ACIN
ACOK
CHG
LOGIC
0.8V
REF
BATT
2.048V
SRDY
DRIVER
DCIN
GND
SRC
PDS
CHG
CCS
SRC-10V DRIVER
PDL
CLS
MODE
100kΩ
GMS
CSSP
SWITCH LOGIC
LEVEL
SHIFTER
CSSN
CSIP
LEVEL
SHIFTER
CSIN
Gm
IINP
SRC
GMI
DRIVER
ICTL
DHI
CCI
DHIV
BATT
LVC
BATT_UV
3.1V/CELL
MODE
CELL SELECT
LOGIC AND
BATTERY VOLTAGEDIVIDER
DC-TO-DC
CONVERTER
GMV
CCV
DLOV
REF
DRIVER
R
DLO
9R
VCTL
MAX1909
PGND
R
Figure 3. Functional Diagram
______________________________________________________________________________________
15
MAX1909
Multichemistry Battery Charger with Automatic
System Power Selector
Detailed Description
The MAX1909 includes all of the functions necessary to
charge Li+, NiMH, and NiCd batteries. A high-efficiency synchronous-rectified step-down DC-to-DC converter is used to implement a precision constant-current,
constant-voltage charger with input current limiting. The
DC-to-DC converter uses external P-channel/N-channel
MOSFETs as the buck switch and synchronous rectifier
to convert the input voltage to the required charge current and voltage. The charge current and input currentlimit sense amplifiers have low-input-referred offset
errors and can use small-value sense resistors. The
MAX1909 features a voltage-regulation loop (CCV) and
two current-regulation loops (CCI and CCS). The CCV
voltage-regulation loop monitors BATT to ensure that its
voltage never exceeds the voltage set by VCTL. The
CCI battery current-regulation loop monitors current
delivered to BATT to ensure that it never exceeds the
current limit set by ICTL. A third loop (CCS) takes control and reduces the charge current when the sum of
the system load and the input-referred charge current
exceeds the power source current limit set by CLS.
Tying CLS to the reference voltage provides a 7.5A
input current limit with a 10mΩ sense resistor.
The ICTL, VCTL, and CLS analog inputs set the charge
current, charge voltage, and input current limit, respectively. For standard applications, internal set points for
ICTL and VCTL provide a 3A charge current using a
15mΩ sense resistor and a 4.2V per-cell charge voltage. The variable for controlling the number of cells is
set with the MODE input. The PKPRES input is used for
battery-pack detection, and provides shutdown control
from a logic signal or external thermistor.
Based on the presence or absence of the AC adapter,
the MAX1909 automatically provides an open-drain logic
output signal ACOK and selects the appropriate source
for supplying power to the system. A P-channel load
switch controlled from the PDL output and a similar Pchannel source switch controlled from the PDS output are
used to implement this function. Using the MODE control
input, the MAX1909 can be programmed to perform a
relearning, or conditioning, cycle in which the battery is
isolated from the charger and completely discharged
through the system load. When the battery reaches 100%
depth of discharge, it is recharged to full capacity.
The circuit shown in Figure 1 demonstrates a simple
hardwired application, while Figure 2 shows a typical
application for smart-battery systems with variable
charge current and source switch configuration that supports battery conditioning. Smart-battery systems typically use a host µC to achieve this added functionality.
16
Setting the Charge Voltage
The MAX1909 uses a high-accuracy voltage regulator
for charge voltage. The VCTL input adjusts the battery
output voltage. In default mode (VCTL = LDO), the
overall accuracy of the charge voltage is ±0.5%. VCTL
is allowed to vary from 0 to 3.6V, which provides a 10%
adjustment range of the battery voltage. Limiting the
adjustment range reduces the sensitivity of the charge
voltage to external resistor tolerances from ±2% to
±0.2%. The overall accuracy of the charge voltage is
better than ±1% when using ±1% resistors to divide
down the reference to establish VCTL. The per-cell battery termination voltage is a function of the battery
chemistry and construction. Consult the battery manufacturer to determine this voltage. The battery voltage is
calculated by the equation:

− 1.8V  
V
VBATT = CELL VREF +  VCTL



9.52

where VREF = 4.2235V, and CELL is the number of cells
selected with the MAX1909’s trilevel MODE control
input. When MODE is tied to the LDO output, CELL = 4.
When MODE is left floating, CELL = 3. When MODE is
tied to ground, the charger enters conditioning mode,
which is used to isolate the battery from the charger
and discharge it through the system load. See the
Conditioning Mode section. The internal error amplifier
(GMV) maintains voltage regulation (See Figure 3 for
Functional Diagram). The voltage-error amplifier is
compensated at CCV. The component values shown in
Figures 1 and 2 provide suitable performance for most
applications. Individual compensation of the voltage
regulation and current-regulation loops allow for optimal compensation. See the Compensation section.
Setting the Charge Current
The voltage on the ICTL input sets the maximum
voltage across current-sense resistor RS2, which in turn
determines the charge current. The full-scale differential voltage between CSIP and CSIN is 75mV; thus, for a
0.015Ω sense resistor, the maximum charge current is
5A. In default mode (ICTL = LDO), the sense voltage is
45mV with an overall accuracy of ±5%. The charge current is programmed with ICTL using the equation:
ICHG =
0.075 VICTL
×
RS2
3.6V
The input range for ICTL is 0.9V to 3.6V. The charger
shuts down if ICTL is forced below 0.8V (typ). When
choosing current-sense resistor RS2, note that it must
have a sufficient power rating to handle the full-load
______________________________________________________________________________________
Multichemistry Battery Charger with Automatic
System Power Selector
Setting the Input Current Limit
The total input current, from a wall cube or other DC
source, is the sum of the system supply current and the
current required by the charger. The MAX1909 reduces
the source current by decreasing the charge current
when the input current exceeds the set input current
limit. This technique does not truly limit the input current.
As the system supply current rises, the available charge
current drops proportionally to zero. Thereafter, the total
input current can increase without limit.
An internal amplifier compares the differential voltage
between CSSP and CSSN to a scaled voltage set with
the CLS input. VCLS can be driven directly or set with a
resistive voltage-divider between REF and GND.
Connect CLS to REF to set the input current-limit sense
voltage to the maximum value of 75mV. Calculate the
input current as follows:
IIN =
0.075 VCLS
×
RS1 VREF
V CLS determines the reference voltage of the GMS
error amplifier. Sense resistor RS1 sets the maximum
allowable source current. Once the input current limit is
reached, the charge current is decreased linearly until
the input current is below the desired threshold.
Duty cycle affects the accuracy of the input current
limit. AC load current also affects accuracy (see
Typical Operating Characteristics). Refer to the
MAX1909 EV kit data sheet for more details on reducing the effects of switching noise.
When choosing the current-sense resistor RS1, carefully calculate its power rating. Take into account variations in the system’s load current and the overall
accuracy of the sense amplifier. Note that the voltage
drop across RS1 contributes additional power loss,
which reduces efficiency.
System currents normally fluctuate as portions of the
system are powered up or put to sleep. Without input
current regulation, the input source must be able to
deliver the maximum system current and the maximum
charger input current. By using the input current-limit
circuit, the output current capability of the AC wall
adapter can be lowered, reducing system cost.
Current Measurement
The MAX1909 includes an input current monitor IINP.
The current delivered at the IINP output is a scaleddown replica of the system load current plus the inputreferred charge current that is sensed across CSSP
and CSSN inputs. The output voltage range is 0 to 3V.
The voltage of IINP is proportional to the output current
according to the following equation:
VIINP = ISOURCE ✕ RS1 ✕ GIINP ✕ R9
where ISOURCE is the DC current supplied by the AC
adapter power, GIINP is the transconductance of IINP
(3mA/V typ), and R9 is the resistor connected between
IINP and ground.
Leave the IINP pin unconnected if not used.
LDO Regulator
LDO provides a 5.4V supply derived from DCIN and
can deliver up to 10mA of extra load current. The lowside MOSFET driver is powered by DLOV, which must
be connected to LDO as shown in Figure 1. LDO also
supplies the 4.2235V reference (REF) and most of the
control circuitry. Bypass LDO with a 1µF capacitor.
Shutdown and Charge Inhibit (PKPRES)
When the AC adapter is removed, the MAX1909 shuts
down to a low-power state that does not significantly
load the battery. Under these conditions, a maximum of
6µA is drawn from the battery through the combined
load of the SRC, CSSP, CSSN, CSIP, CSIN, and BATT
inputs. The charger enters this low-power state when
DCIN falls below the undervoltage lockout (UVLO)
threshold of 7V. The PDS switch turns off, the PDL
switch turns on, and the system runs from the battery.
The body diode of the PDL switch prevents the voltage
on the power source output from collapsing.
Charging can also be inhibited by driving the pack
detection input (PKPRES) high, which suspends switching and pulls CCI, CCS, and CCV to ground. The PDS
and PDL drivers, LDO, input current monitor, and control logic (ACOK) all remain active in this state.
Approximately 3mA of supply current is drawn from the
AC adapter and 3µA (max) is drawn from the battery to
support these functions. The threshold voltage of
PKPRES is 90% of VLDO (typ), with hysteresis of 1%
VLDO to prevent erratic transitions.
In smart-battery systems, PKPRES is usually driven
from a voltage-divider formed with a low-value resistor
or PTC thermistor inside the battery back and a local
resistive pullup. This arrangement automatically detects
the presence of a battery. A PTC thermistor can be
used to shut down the MAX1909 when the battery pack
is hot (see the Thermal Charge Qualification section).
______________________________________________________________________________________
17
MAX1909
current. The sense resistor’s I2R power loss reduces
charger efficiency. Adjusting ICTL to drop the voltage
across the current-sense resistor improves efficiency,
but may degrade accuracy due to the current-sense
amplifier’s input offset error. The charge-current error
amplifier (GMI) is compensated at the CCI pin. See the
Compensation section.
MAX1909
Multichemistry Battery Charger with Automatic
System Power Selector
A third method for inhibiting charging is to force ICTL
below 0.8V (typ). Approximately 3mA of supply current
is drawn from the AC adapter and 3µA is drawn from
the battery when the MAX1909 is in this state.
AC Adapter Detection and
Power-Source Selection
The MAX1909 includes a hysteretic comparator that
detects the presence of an AC power adapter and
automatically delivers power to the system load from
the appropriate available power source. When the
adapter is present, the open-drain ACOK output
becomes a high impedance. The switch threshold at
ACIN is 2.048V. Use a resistive voltage-divider from the
adapter’s output to the ACIN pin to set the appropriate
detection threshold. When charging, the battery is isolated from the system load with the P-channel PDL
switch, which is biased off. When the adapter is absent,
the drives to the switches change state in a fast breakbefore-make sequence. PDL begins to turn on 7.5µs
after PDS begins to turn off.
The threshold for selecting between the PDL and PDS
switches is set based on the voltage difference
between the DCIN and the BATT pins. If this voltage
difference drops below 100mV, the PDS is switched off
and PDL is switched on. Under these conditions, the
MAX1909 is completely powered down. The PDL switch
is kept on with a 100kΩ pulldown resistor when the
charger is powered down through ICTL, PKPRES, or
the AC adapter is removed.
The drivers for PDL and PDS are fully integrated. The
positive bias inputs for the drivers connect to the SRC
pin and the negative bias inputs connect to a negative
regulator referenced to SRC. With this arrangement, the
drivers can swing from SRC to approximately 10V
below SRC.
Conditioning Mode
The MAX1909 can be programmed to perform a conditioning cycle to calibrate the battery’s fuel gauge. This
cycle consists of isolating the battery from the charger
and discharging it through the system load. When the
battery reaches 100% depth of discharge, it is then
recharged. Driving the MODE pin low places the
MAX1909 in conditioning mode, which stops the charger from switching, turns the PDS switch off, and turns
the PDL switch on.
To utilize the conditioning mode function, the configuration of the PDS switch must be changed to two sourceconnected FETs to prevent the AC adapter from supplying current to the system through the MOSFET’s
18
body diode. See Figure 2. The SRC pin must be connected to the common source node of the back-to-back
FETs to properly drive the MOSFETs.
It is essential to alert the user that the system
is performing a conditioning cycle. If the user terminates the cycle prematurely, the battery can be discharged even though the system was running off AC
adapter for a substantial period of time. If the AC
adapter is in fact removed during conditioning, the
MAX1909 keeps the PDL switch on and the charger
remains off as it would in normal operation.
If the battery is removed during conditioning mode, the
PKPRES control overrides conditioning mode. When
MODE is grounded and PKPRES goes high, the PDS
switch starts turning on within 7.5µs and the system is
powered from the AC adapter.
DC-to-DC Converter
The MAX1909 employs a buck regulator with a PMOS
high-side switch and a low-side NMOS synchronous
rectifier. The MAX1909 features a pseudo-fixed-frequency, cycle-by-cycle current-mode control scheme.
The off-time is dependent upon VDCIN, VBATT, and a
time constant, with a minimum t OFF of 300ns. The
MAX1909 can also operate in discontinuous conduction
for improved light-load efficiency. The operation of the
DC-to-DC controller is determined by the following four
comparators as shown in Figure 4:
• CCMP: Compares the control point (lowest voltage
clamp (LVC)) against the charge current (CSI). The
high-side MOSFET on-time is terminated if the CCMP
output is high.
• IMIN: Compares the control point (LVC) against
0.15V (typ). If IMIN output is low, then a new cycle
cannot begin. This comparator determines whether
the regulator operates in discontinuous mode.
• IMAX: Compares the charge current (CSI) to the
internally fixed cycle-by-cycle current limit. The
current-sense voltage limit is 97mV. With RS2 =
0.015Ω,this corresponds to 6A. The high-side
MOSFET on-time is terminated if the IMAX output is
high and a new cycle cannot begin until IMAX goes
low. IMAX protects against sudden overcurrent
faults.
• ZCMP: Compares the charge current (CSI) to 333mA
(RS2 = 0.015Ω). The current-sense voltage threshold
is 5mV. If ZCMP output is high, then both MOSFETs
are turned off. The ZCMP comparator terminates the
switch on-time in discontinuous mode.
______________________________________________________________________________________
Multichemistry Battery Charger with Automatic
System Power Selector
MAX1909
AC ADAPTER
CSSP
CSSN
MAX1909
DHI
CSS
20X
DHI
IMAX
1.94V
R
Q
S
Q
COMP
DLO
DLO
IMIN
0.15V
TOFF
ZCMP
0.1V
LVC
CLS
GMS
ICTL
CSIP
LVC
GMI
CSI
20X
CSIN
VCTL
GMV
CCV
CCI
CCS
BATT
COUT
RCCV
CCV
CCI
CCS
Figure 4. DC-to-DC Converter Functional Diagram
______________________________________________________________________________________
19
MAX1909
Multichemistry Battery Charger with Automatic
System Power Selector
CCV, CCI, CCS, and LVC Control Blocks
The MAX1909 controls charge voltage (CCV control
loop), charge current (CCI control loop), or input
current (CCS control loop), depending on the operating
conditions. The three control loops, CCV, CCI, and CCS,
are brought together internally at the LVC amplifier. The
output of the LVC amplifier is the feedback control
signal for the DC-to-DC controller. The minimum
voltage at CCV, CCI, or CCS appears at the output of
the LVC amplifier and clamps the other two control
loops to within 0.3V above the control point. Clamping
the other two control loops close to the lowest control
loop ensures fast transition with minimal overshoot
when switching between different control loops (see the
Compensation section).
Continuous Conduction Mode
With sufficient battery current loading, the MAX1909’s
inductor current never reaches zero, which is defined
as continuous conduction mode. If the BATT voltage is
within the following range:
3.1V ✕ (number of cells) < VBATT < (0.88 ✕ VDCIN)
The regulator is not in dropout and switches at fNOM =
400kHz. The controller starts a new cycle by turning on
the high-side P-channel MOSFET and turning off the
low-side N-channel MOSFET. When the charge current
is greater than the control point (LVC), CCMP goes high
and the off-time is started. The off-time turns off the
high-side P-channel MOSFET and turns on the low-side
N-channel MOSFET. The operating frequency is governed by the off-time and is dependent upon VDCIN
and VBATT. The off-time is set by the following equation:
t OFF =
1 VCSSN − VBATT
fNOM
VCSSN
where fNOM = 400kHz:
V
×t
where IRIPPLE = BATT OFF
L
1
t ON + t OFF
These equations describe the controller’s pseudo-fixedfrequency performance over the most common operating conditions.
20
Discontinuous Conduction
The MAX1909 enters discontinuous conduction mode
when the output of the LVC control point falls below
0.15V. For RS2 = 0.015Ω, this corresponds to 0.5A:
0.15V
IMIN =
= 0.5A
20 × RS2
where RS2 = 0.015Ω.
In discontinuous mode, a new cycle is not started until
the LVC voltage rises above 0.15V. Discontinuous
mode operation can occur during conditioning charge
of overdischarged battery packs, when the charge current has been reduced sufficiently by the CCS control
loop, or when the charger is in constant voltage mode
with a nearly full battery pack.
Compensation
L × IRIPPLE
t ON =
VCSSN − VBATT
f=
At the end of the fixed off-time, the controller can initiate
a new cycle if the control point (LVC) is greater than
0.15V (IMIN = high) and the peak charge current is less
than the cycle-by-cycle limit (IMAX = low). If the charge
current exceeds IMAX, the on-time is terminated by the
IMAX comparator.
If during the off-time the inductor current goes to zero,
ZCMP = high, both the high- and low-side MOSFETs
are turned off until another cycle is ready to begin. This
condition is discontinuous conduction. See the
Discontinuous Conduction section.
There is a minimum 0.3ms off-time when the (VDCIN VBATT) differential becomes too small. If VBATT ≥ 0.88 x
V DCIN , then the threshold for minimum off-time is
reached and the tOFF is fixed at 0.3ms. The switching
frequency in this mode varies according to the equation:
1
f=
L × IRIPPLE
+ 0.3µs
(VCSSN − VBATT )
The charge voltage, charge current, and input currentlimit regulation loops are compensated separately and
independently at the CCV, CCI, and CCS pins.
CCV Loop Compensation
The simplified schematic in Figure 5 is sufficient to
describe the operation of the MAX1909 when the
voltage loop (CCV) is in control. The required compensation network is a pole-zero pair formed with CCV and
RCV. The pole is necessary to roll off the voltage loop’s
response at low frequency. The zero is necessary to
compensate the pole formed by the output capacitor and
the load. RESR is the equivalent series resistance (ESR)
of the charger output capacitor (COUT). RL is the equivalent charger output load, where RL = ∆VBATT / ∆ICHG.
______________________________________________________________________________________
Multichemistry Battery Charger with Automatic
System Power Selector
RL
RCV
ROGMV × (1+ sCCV × RCV )
(1+ sCOUT × RL )
RESR
RL
COUT
GMV
where ACSI = 20, and RS2 = 0.015Ω in the Typical
Application Circuits, so GMOUT = 3.33A/V.
The loop transfer function is:
LTF = GMOUT ×
BATT
GMOUT
CCV
1
GMOUT =
A CSI × RS2
MAX1909
The equivalent output impedance of the GMV amplifier,
R OGMV , is greater than 10MΩ. The voltage loop
transconductance (GMV = ICCV/VBATT) depends on the
MODE input, which determines the number of cells. GMV
= 0.125mA/mV for 4 cells and GMV = 0.167mA/mV for 3
cells. The DC-to-DC converter transconductance is
dependent upon the charge current-sense resistor RS2:
(1+ sCCV × ROGMV )
GMV (1+ sCOUT × RESR )
×
The poles and zeros of the voltage-loop transfer function are listed from lowest frequency to highest frequency in Table 1.
Near crossover, C CV has a much lower impedance
than ROGMV. Since CCV is in parallel with ROGMV, CCV
dominates the parallel impedance near crossover.
Additionally, RCV has a much higher impedance than
CCV and dominates the series combination of RCV and
CCV, so:
ROGMV
REF
CCV
Figure 5. CCV Loop Diagram
ROGMV × (1+ sCCV × RCV )
(1+ sCCV × ROGMV )
≅ RCV
COUT also has a much lower impedance than RL near
crossover, so the parallel impedance is mostly capacitive and:
1
RL
≅
1
+
×
sC
R
sC
(
OUT
L)
OUT
If RESR is small enough, its associated output zero has
a negligible effect near crossover and the loop-transfer
function can be simplified as follows:
Table 1. Poles and Zeros of the Voltage-Loop Transfer Function
NO.
1
NAME
CALCULATION
fP _ CV =
CCV pole
2πROGMV × CCV
1
fZ _ CV =
2πRCV × CCV
2
CCV zero
3
Output pole
4
1
Output zero
fP _ OUT =
1
2πRL × COUT
1
fZ _ OUT =
2πRESR × COUT
DESCRIPTION
Lowest frequency pole created by CCV and GMV’s finite output
resistance. Since ROGMV is very large and not well controlled, the
exact value for the pole frequency is also not well controlled
(ROGMV > 10MΩ).
Voltage-loop compensation zero. If this zero is at the same
frequency or lower than the output pole fP_OUT, then the loop
transfer function approximates a single pole response near the
crossover frequency. Choose CCV to place this zero at least one
decade below crossover to ensure adequate phase margin.
Output pole formed with the effective load resistance RL and the
output capacitance COUT. RL influences the DC gain but does not
affect the stability of the system or the crossover frequency.
Output ESR Zero. This zero can keep the loop from crossing unity
gain if fZ_OUT is less than the desired crossover frequency;
therefore, choose a capacitor with an ESR zero greater than the
crossover frequency.
______________________________________________________________________________________
21
where CCV ≥ 4nF (assuming 4 cells and 4A maximum
charge current).
Figure 6 shows the Bode plot of the voltage-loop frequency response using the values calculated above.
RCV
LTF = GMOUT ×
GMV
sCOUT
Setting the LTF = 1 to solve for the unity gain frequency
yields:
fCO _ CV = GMOUT × GMV 

RCV

2π
×
C

OUT 
For stability, choose a crossover frequency lower than
1/10th of the switching frequency. Choosing a
crossover frequency of 30kHz and solving for R CV
using the component values listed in Figure 1 yields:
MODE = VCC (4 cells)
GMV = 0.125µA/mV
COUT = 22µF
VBATT = 16.8V
LTF = GMOUT × A CSI × RS2 × GMI
fCO_CV = 30kHz
2π × COUT × fCO _ CV
= 10kΩ
GMV × GMOUT
the loop transfer function simplifies to:
To ensure that the compensation zero adequately cancels the output pole, select fZ_CV ≤ fP_OUT:
CCV ≥ (RL/RCV) COUT
80
ROGMI
1+ sROGMI × CCI
This describes a single pole system. Since:
1
GMOUT =
A CSI × RS2
fOSC = 400kHz
RCV =
CCI Loop Compensation
The simplified schematic in Figure 7 is sufficient to
describe the operation of the MAX1909 when the battery current loop (CCI) is in control. Since the output
capacitor’s impedance has little effect on the response
of the current loop, only a single pole is required to
compensate this loop. ACSI is the internal gain of the
current-sense amplifier. RS2 is the charge currentsense resistor, RS2 = 15mΩ. ROGMI is the equivalent
output impedance of the GMI amplifier, which is greater
than 10MΩ. GMI is the charge current amplifier
transconductance = 1µA/mV. GMOUT is the DC-to-DC
converter transconductance = 3.3A/V.
The loop transfer function is given by:
RL = 0.2Ω
GMOUT = 3.33A/V
LTF = GMI
ROGMI
1+ sROGMI × CCI
0
CSIP
60
CSIN
GMOUT
40
-45
20
0
-90
-20
GMI
-40
1
10
CSI
CCI
MAG
PHASE
0.1
PHASE (DEGREES)
RS2
MAGNITUDE (dB)
MAX1909
Multichemistry Battery Charger with Automatic
System Power Selector
100
1k
10k
100k
-135
1M
CCI
ROGMI
FREQUENCY (Hz)
Figure 6. CCV Loop Response
22
ICTL
Figure 7. CCI Loop Diagram
______________________________________________________________________________________
Multichemistry Battery Charger with Automatic
System Power Selector
MAX1909
The crossover frequency is given by:
ADAPTER
INPUT
GMI
fCO _ CI =
2πCCI
CSSP
CLS
For stability, choose a crossover frequency lower than
1/10th of the switching frequency:
CCI = GMI / (2π fO_CI)
RS1
CSSN
GMS
Choosing a crossover frequency of 30kHz and using
the component values listed in Figure 1 yields CCI >
5.4nF. Values for CCI greater than 10 times the minimum value may slow down the current-loop response
excessively. Figure 8 shows the Bode plot of the current-loop frequency response using the values calculated above.
CCS Loop Compensation
The simplified schematic in Figure 9 is sufficient to
describe the operation of the MAX1909 when the input
current-limit loop (CCS) is in control. Since the output
capacitor’s impedance has little effect on the response
of the input current-limit loop, only a single pole is
required to compensate this loop. ACSS is the internal
gain of the current-sense amplifier. RS1 is the input current-sense resistor; RS1 = 10mΩ in the Typical
Applications Circuits. ROGMS is the equivalent output
impedance of the GMS amplifier, which is greater than
10MΩ. GMS is the charge-current amplifier transconductance = 1µA/mV. GMIN is the DC-to-DC converter’s
input-referred transconductance = (1/D) GM OUT =
(1/D) 3.3A/V.
CSS
CCS
GMIN
CCS
ROGMS
SYSTEM
LOAD
Figure 9. CCS Loop Diagram
The loop transfer function is given by:
LTF = GMIN × A CSS × RS1× GMS
ROGMS
1+ sROGMS × CCS
Since:
GMIN =
1
A CSS × RS1
the loop transfer function simplifies to:
LTF = GMS
ROGMS
1+ sROGMS × CCS
The crossover frequency is given by:
100
60
40
-45
20
0
-20
-40
0.1
10
1k
FREQUENCY (Hz)
Figure 8. CCI Loop Response
100k
-90
10M
PHASE (DEGREES)
MAG
PHASE
80
MAGNITUDE (dB)
fCO _ CS =
0
GMS
2πCCS
For stability, choose a crossover frequency lower than
1/10th the switching frequency:
CCS = GMS / (2π fCO_CS)
Choosing a crossover frequency of 30kHz and using
the component values listed in Figure 1 yields CCS >
5.4nF. Values for CCI greater than 10 times the minimum value may slow down the current-loop response
excessively. Figure 10 shows the Bode plot of the input
current-limit loop frequency response using the values
calculated above.
MOSFET Drivers
The DHI and DLO outputs are optimized for driving
moderately sized power MOSFETs. The MOSFET drive
______________________________________________________________________________________
23
100
0
MAG
PHASE
MAGNITUDE (dB)
80
60
40
-45
20
PHASE (DEGREES)
MAX1909
Multichemistry Battery Charger with Automatic
System Power Selector
0
-20
-40
0.1
10
1k
100k
-90
10M
FREQUENCY (Hz)
Figure 10. CCS Loop Response
capability is the same for both the low-side and highside switches. This is consistent with the variable duty
factor that occurs in the notebook computer environment where the battery voltage changes over a wide
range. An adaptive dead-time circuit monitors the DLO
output and prevents the high-side FET from turning on
until DLO is fully off. There must be a low-resistance,
low-inductance path from the DLO driver to the MOSFET gate for the adaptive dead-time circuit to work
properly. Otherwise, the sense circuitry in the MAX1909
interprets the MOSFET gate as “off” while there is still
charge left on the gate. Use very short, wide traces
measuring 10 squares to 20 squares or less (1.25mm to
2.5mm wide if the MOSFET is 25mm from the device).
Unlike the DLO output, the DHI output uses a fixeddelay 50ns time to prevent the low-side FET from turning on until DHI is fully off. The same layout
considerations should be used for routing the DHI signal to the high-side FET.
Since the transition time for a P-channel switch can be
much longer than an N-channel switch, the dead time
prior to the high-side PMOS turning on is more pronounced than in other synchronous step-down regulators, which use high-side N-channel switches. On the
high-to-low transition, the voltage on the inductor’s
“switched” terminal flies below ground until the low-side
switch turns on. A similar dead-time spike occurs on
the opposite low-to-high transition. Depending upon the
magnitude of the load current, these spikes usually
have a minor impact on efficiency.
The high-side driver (DHI) swings from SRC to 5V
below SRC and typically sources 0.9A and sinks 0.5A
24
from the gate of the P-channel FET. The internal pulldown transistors that drive DHI high are robust, with a
2.0Ω (typ) on-resistance.
The low-side driver (DLO) swings from DLOV to ground
and typically sources 0.5A and sinks 0.9A from the gate
of the N-channel FET. The internal pulldown transistors
that drive DLO low are robust, with a 1.0Ω (typ) onresistance. This helps prevent DLO from being pulled
up when the high-side switch turns on, due to capacitive coupling from the drain to the gate of the low-side
MOSFET. This places some restrictions on the FETs
that can be used. Using a low-side FET with smaller
gate-to-drain capacitance can prevent these problems.
Table 2. Recommended Components
REFERENCE QTY
DESCRIPTION
2
22µF ±20%, 35V E-size low-ESR
tantalum capacitors
AVX TPSE226M035R0300
Kemet T495X226M035AS
2
1µF ±10%, 25V, X7R ceramic capacitors
(1206)
Murata GRM31MR71E105K
Taiyo Yuden TMK316BJ105KL
TDK C3216X7R1E105K
2
0.01µF ±10%, 25V, X7R ceramic
capacitors (0402)
Murata GRP155R71E103K
TDK C1005X7R1E103K
3
0.1µF ±10%, 25V, X7R ceramic
capacitors (0603)
Murata GRM188R71E104K
TDK C1608X7R1E104K
3
1µF ±10%, 6.3V, X5R ceramic
capacitors (0603)
Murata GRM188R60J105K
Taiyo Yuden JMK107BJ105KA
TDK C1608X5R1A105K
D4
1
Schottky diode, 0.5A, 30V SOD-123
Diodes Inc. B0530W
General Semiconductor MBR0530
ON Semiconductor MBR0530
D5
1
25V ±1% zener diode
CMDZ5253B
L1
1
10µH, 4.4A inductor
Sumida CDRH104R-100NC
TOKO 919AS-100M
C1, C4
C5, C15
C9, C10
C11, C14,
C17
C12, C13,
C16
______________________________________________________________________________________
Multichemistry Battery Charger with Automatic
System Power Selector
REFERENCE QTY
DESCRIPTION
N1/P1
1
Dual N- and P-channel MOSFETs, 7A,
30V and -5A, -30V, 8-pin SO, MOSFET
Fairchild FDS8958A or
Single N-channel MOSFETs, +13.5A,
+30V FDS6670S and
Single P-channel MOSFETs, -13.5A,
-30V FDS66709Z
P2, P3, P4
3
Single, P-channel, -11A, -30V, 8-pin SO
MOSFETs
Fairchild FDS6675
R4
1
100kΩ, ±5% resistor (0603)
R5, R9, R21
2
10kΩ ±1% resistors (0603)
R6
1
590kΩ ±1% resistor 0603
R7
1
196kΩ ±1% resistor 0603
R8
1
1MΩ ±5% resistor (0603)
R11
1
1kΩ ±5% resistor (0603)
R16
1
33Ω ±5% resistor (0603)
R19, R20
2
10kΩ ±5% resistors (0603)
RS1
1
0.01Ω ±1%, 0.5W sense resistor (2010)
Vishay Dale WSL2010 0.010 1.0%
IRC LRC-LR2010-01-R010-F
RS2
1
0.015Ω ±1%, 0.5W sense resistor (2010)
Vishay Dale WSL2010 0.015 1.0%
IRC LRC-LR2010-01-R015-F
U1
1
MAX1909ETI (28-pin thin QFN-EP)
Design Procedure
Table 2 lists the recommended components and refers
to the circuit of Figure 2. The following sections
describe how to select these components.
MOSFET Selection
MOSFETs P2 and P3 (Figure 1) provide power to the
system load when the AC adapter is inserted. These
devices may have modest switching speeds, but must
be able to deliver the maximum input current as set by
RS1. As always, care should be taken not to exceed
the device’s maximum voltage ratings or the maximum
operating temperature.
The P-channel/N-channel MOSFETs (P1, N1) are the
switching devices for the buck controller. The guidelines for these devices focus on the challenge of
obtaining high load-current capability when using highvoltage (>20V) AC adapters. Low-current applications
usually require less attention. The high-side MOSFET
(P1) must be able to dissipate the resistive losses plus
the switching losses at both V DCIN(MIN) and
VDCIN(MAX).
Ideally, the losses at V DCIN(MIN) should be roughly
equal to losses at V DCIN(MAX), with lower losses in
between. If the losses at VDCIN(MIN) are significantly
higher than the losses at VDCIN(MAX), consider increasing the size of P1. Conversely, if the losses at
VDCIN(MAX) are significantly higher than the losses at
VDCIN(MIN), consider reducing the size of P1. If DCIN
does not vary over a wide range, the minimum power
dissipation occurs where the resistive losses equal the
switching losses.
Choose a low-side MOSFET that has the lowest possible on-resistance (RDS(ON)), comes in a moderatesized package, and is reasonably priced. Make sure
that the DLO gate driver can supply sufficient current to
support the gate charge and the current injected into
the parasitic gate-to-drain capacitor caused by the
high-side MOSFET turning on; otherwise, cross-conduction problems can occur.
The MAX1909 has an adaptive dead-time circuit that
prevents the high-side and low-side MOSFETs from
conducting at the same time (see MOSFET Drivers).
Even with this protection, it is still possible for delays
internal to the MOSFET to prevent one MOSFET from
turning off when the other is turned on.
Select devices that have low turn-off times. To be conservative, make sure that P1(t DOFF (MAX)) N1(tDON(MIN)) < 40ns. Failure to do so may result in
efficiency-killing shoot-through currents. If delay mismatch causes shoot-through currents, consider adding
extra capacitance from gate to source on N1 to slow
down its turn-on time.
MOSFET Power Dissipation
Worst-case conduction losses occur at the duty factor
extremes. For the high-side MOSFET, the worst-case
power dissipation (PD) due to resistance occurs at the
minimum supply voltage:
V
 I
2
PD(P1) =  BATT   LOAD  × RDS(ON)
 VDCIN   2 
Generally, a small high-side MOSFET is desired to
reduce switching losses at high input voltages.
However, the RDS(ON) required to stay within package
power-dissipation limits often limits how small the
MOSFET can be. The optimum occurs when the switching (AC) losses equal the conduction (I 2 R DS(ON) )
losses. High-side switching losses do not usually
become an issue until the input is greater than approxi-
______________________________________________________________________________________
25
MAX1909
Table 2. Recommended Components
(continued)
mately 15V. Switching losses in the high-side MOSFET
can become an insidious heat problem when maximum
AC adapter voltages are applied, due to the squared
term in the CV2 f switching-loss equation. If the highside MOSFET that was chosen for adequate RDS(ON)
at low supply voltages becomes extraordinarily hot
when subjected to VDCIN(MAX), then choose a MOSFET
with lower losses. Calculating the power dissipation in
P1 due to switching losses is difficult since it must allow
for difficult quantifying factors that influence the turn-on
and turn-off times. These factors include the internal
gate resistance, gate charge, threshold voltage, source
inductance, and PC board layout characteristics. The
following switching-loss calculation provides only a
very rough estimate and is no substitute for breadboard
evaluation, preferably including a verification using a
thermocouple mounted on P1:
PD(P1_ Switching) =
VDCIN(MAX)2 × CRSS × fSW × ILOAD
2 IGATE
1.5
3 CELLS
4 CELLS
RIPPLE CURRENT (A)
MAX1909
Multichemistry Battery Charger with Automatic
System Power Selector
1.0
0.5
VDCIN = 19V
VCTL = ICTL = LDO
0
8
9
10 11 12 13 14 15 16 17 18
VBATT (V)
Figure 11. Ripple Current vs. Battery Voltage
 V
 I
2
PD(N1) = 1−  BATT    LOAD  × RDS(ON)
  VDCIN    2 
tOFF = 0.3us for VBATT > 0.88 VDCIN
Figure 11 illustrates the variation of the ripple current
vs. battery voltage when the circuit is charging at 3A
with a fixed input voltage of 19V.
Higher inductor values decrease the ripple current.
Smaller inductor values require high-saturation current
capabilities and degrade efficiency. Designs that set
LIR = ∆IL/ICHG = 0.3 usually result in a good balance
between inductor size and efficiency.
Choose a Schottky diode (D1, Figure 2) having a forward voltage low enough to prevent the N1 MOSFET
body diode from turning on during the dead time. As a
general rule, a diode with a DC current rating equal to
1/3rd the load current is sufficient. This diode is optional and can be removed if efficiency is not critical.
The input capacitor must meet the ripple current
requirement (IRMS) imposed by the switching currents.
Nontantalum chemistries (ceramic, aluminum, or OSCON) are preferred due to their resilience to power-up
surge currents.
where CRSS is the reverse transfer capacitance of P1,
and IGATE is the peak gate-drive source/sink current.
For the low-side MOSFET (N1), the worst-case power
dissipation always occurs at maximum input voltage:
Inductor Selection
The charge current, ripple, and operating frequency
(off-time) determine the inductor characteristics.
Inductor L1 must have a saturation current rating of at
least the maximum charge current plus 1/2 of the ripple
current (∆IL):
ISAT = ICHG + (1/2) ∆IL
The ripple current is determined by:
∆IL = VBATT tOFF / L
where:
tOFF = 2.5us (VDCIN - VBATT) / VDCIN for
VBATT < 0.88 VDCIN
or:
26
Input Capacitor Selection
 V

BATT (VDCIN − VBATT )
IRMS = ICHG 


VDCIN


The input capacitors should be sized so that the
temperature rise due to ripple current in continuous
conduction does not exceed about 10°C. The
maximum ripple current occurs at 50% duty factor or
VDCIN = 2 ✕ VBATT, which equates to 0.5 ✕ ICHG. If the
application of interest does not achieve the maximum
value, size the input capacitors according to the
worst-case conditions.
Output Capacitor Selection
The output capacitor absorbs the inductor ripple current and must tolerate the surge current delivered from
the battery when it is initially plugged into the charger.
______________________________________________________________________________________
Multichemistry Battery Charger with Automatic
System Power Selector
BATTERY
MAX1909
It is desirable to charge deeply discharged batteries at
a low rate to improve cycle life. The MAX1909 automatically reduces the charge current when the voltage per
cell is below 3.1V. The charge current-sense voltage is
set to 4.5mV (ICHG = 300mA with RS2 = 15mΩ) until
the battery voltage rises above the threshold. There is
approximately 300mV for 3 cell, 400mV for 4 cell of hysteresis to prevent the charge current magnitude from
chattering between the two values.
Thermal Charge Qualification
Based on the cell characteristics, the MAX1909 should
not charge batteries operating above a specified
temperature. Often a PTC thermistor is included inside
the battery pack to measure its temperature. When
connected to the charger, the thermistor forms a voltagedivider with a resistive pullup to the LDO. The threshold
voltage of PKPRES is 90% of VLDO (typ), with hysteresis
of 1% of VLDO to prevent erratic transitions. The thermistor can be selected to have a resistance vs. temperature
characteristic that abruptly increases above a critical
temperature. This arrangement automatically shuts down
the MAX1909 when the battery pack is above a critical
temperature. For the example shown in Figure 12, a
Thermometrics YSC060 device is selected with the thermal threshold of approximately +60°C.
Layout and Bypassing
Bypass DCIN with a 1µF capacitor to ground (Figure 1).
D4 protects the MAX1909 when the DC power source
input is reversed. A signal diode for D4 is adequate
because DCIN only powers the LDO and the internal
reference. Bypass LDO, DHIV, DLOV, and other pins
as shown in Figure 1.
Good PC board layout is required to achieve specified
noise, efficiency, and stable performance. The PC
board layout artist must be given explicit instructions—
preferably, a sketch showing the placement of the
power-switching components and high-current routing.
LDO
LDO
CLDO
1µF
Applications Information
Startup Conditioning Charge for
Overdischarged Cells
MAX1909
As such, both capacitance and ESR are important
parameters in specifying the output capacitor as a filter
and to ensure the stability of the DC-to-DC converter.
(See the Compensation section.) Beyond the stability
requirements, it is often sufficient to make sure that the
output capacitor’s ESR is much lower than the battery’s
ESR. Either tantalum or ceramic capacitors can be
used on the output. Ceramic devices are preferable
because of their good voltage ratings and resilience to
surge currents.
TEMP
R1
10kΩ
R2
70kΩ
PKPRES
THERMISTER
Figure 12. Use of a PTC Thermistor for Thermal Change
Qualification
Refer to the PC board layout in the MAX1909 evaluation
kit for examples. A ground plane is essential for optimum performance. In most applications, the circuit is
located on a multilayer board, and full use of the four or
more copper layers is recommended. Use the top layer
for high-current connections, the bottom layer for quiet
connections, and the inner layers for an uninterrupted
ground plane.
Use the following step-by-step guide:
1) Place the high-power connections first, with their
grounds adjacent:
a) Minimize the current-sense resistor trace
lengths, and ensure accurate current sensing
with Kelvin connections.
b) Minimize ground trace lengths in the high-current
paths.
c) Minimize other trace lengths in the high-current
paths.
d) Use > 5mm wide traces.
e) Connect C1 and C2 to the high-side MOSFET
(10mm max length). Return these capacitors to
the power ground plane.
f)
Minimize the LX node (MOSFETs, rectifier cathode, inductor (15mm max length)).
Ideally, surface-mount power components are
flush against one another with their ground
terminals almost touching. These high-current
grounds are then connected to each other with
______________________________________________________________________________________
27
MAX1909
Multichemistry Battery Charger with Automatic
System Power Selector
a wide, filled zone of top-layer copper, so they
do not go through vias.
The resulting top-layer ground plane is connected
to the normal inner-layer ground plane at the output ground terminals, which ensures that the IC’s
analog ground is sensing at the supply’s output
terminals without interference from IR drops and
ground noise. Other high-current paths should also
be minimized, but focusing primarily on short
ground and current-sense connections eliminates
about 90% of all PC board layout problems.
2) Place the IC and signal components. Keep the main
switching node (LX node) away from sensitive analog components (current-sense traces and REF
capacitor). Important: The IC should be less than
10mm from the current-sense resistors.
VIA CONNECTING
POWER GROUND TO
QUIET ANALOG GROUND
HIGH-CURRENT
PGND PLANE
QUIET GROUND
ISLAND
Quiet connections to REF, VCTL, ICTL, CCV, CCI,
CCS, IINP, ACIN, and DCIN should be returned to a
separate ground (GND) island. The appropriate
traces are marked on the schematic with the
ground symbol ( ). There is very little current flowing in these traces, so the ground island need not
be very large. When placed on an inner layer, a sizable ground island can help simplify the layout
because the low-current connections can be made
through vias. The ground pad on the backside of
the package should also be connected to this quiet
ground island.
3) Keep the gate drive traces (DHI and DLO) as short
as possible (L < 20mm), and route them away from
the current-sense lines and REF. These traces
should also be relatively wide (W > 1.25mm).
KELVIN-SENSE VIAS
UNDER THE SENSE
RESISTOR
(REFER TO EVALUATION KIT)
INDUCTOR
COUT
COUT
CIN
INPUT
4) Place ceramic bypass capacitors close to the IC.
The bulk capacitors can be placed further away.
5) Use a single-point star ground placed directly
below the part at the PGND pin. Connect the power
ground (ground plane) and the quiet ground island
at this location. See Figure 13.
OUTPUT
GND
Figure 13. PC Board Layout Examples
Chip Information
TRANSISTOR COUNT: 2720
PROCESS: BiCMOS
28
______________________________________________________________________________________
Multichemistry Battery Charger with Automatic
System Power Selector
b
CL
0.10 M C A B
D2/2
D/2
PIN # 1
I.D.
QFN THIN.EPS
D2
0.15 C A
D
k
0.15 C B
PIN # 1 I.D.
0.35x45
E/2
E2/2
CL
(NE-1) X e
E
E2
k
L
DETAIL A
e
(ND-1) X e
CL
CL
L
L
e
e
0.10 C
A
C
0.08 C
A1 A3
PROPRIETARY INFORMATION
TITLE:
PACKAGE OUTLINE
16, 20, 28, 32L, QFN THIN, 5x5x0.8 mm
APPROVAL
COMMON DIMENSIONS
DOCUMENT CONTROL NO.
REV.
21-0140
C
1
2
EXPOSED PAD VARIATIONS
NOTES:
1. DIMENSIONING & TOLERANCING CONFORM TO ASME Y14.5M-1994.
2. ALL DIMENSIONS ARE IN MILLIMETERS. ANGLES ARE IN DEGREES.
3. N IS THE TOTAL NUMBER OF TERMINALS.
4. THE TERMINAL #1 IDENTIFIER AND TERMINAL NUMBERING CONVENTION SHALL CONFORM TO JESD 95-1
SPP-012. DETAILS OF TERMINAL #1 IDENTIFIER ARE OPTIONAL, BUT MUST BE LOCATED WITHIN THE
ZONE INDICATED. THE TERMINAL #1 IDENTIFIER MAY BE EITHER A MOLD OR MARKED FEATURE.
5. DIMENSION b APPLIES TO METALLIZED TERMINAL AND IS MEASURED BETWEEN 0.25 mm AND 0.30 mm
FROM TERMINAL TIP.
6. ND AND NE REFER TO THE NUMBER OF TERMINALS ON EACH D AND E SIDE RESPECTIVELY.
7. DEPOPULATION IS POSSIBLE IN A SYMMETRICAL FASHION.
8. COPLANARITY APPLIES TO THE EXPOSED HEAT SINK SLUG AS WELL AS THE TERMINALS.
9. DRAWING CONFORMS TO JEDEC MO220.
10. WARPAGE SHALL NOT EXCEED 0.10 mm.
PROPRIETARY INFORMATION
TITLE:
PACKAGE OUTLINE
16, 20, 28, 32L, QFN THIN, 5x5x0.8 mm
APPROVAL
DOCUMENT CONTROL NO.
REV.
21-0140
C
2
2
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are
implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 ____________________ 29
© 2003 Maxim Integrated Products
Printed USA
is a registered trademark of Maxim Integrated Products.
MAX1909
Package Information
(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,
go to www.maxim-ic.com/packages.)