_______________________________________________________________ Maxim Integrated Products 1
For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642,
or visit Maxim’s website at www.maxim-ic.com.
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
General Description
The MAX17435/MAX17535 integrated multichemistry
battery-charger ICs simplify construction of accurate
and efficient chargers. The MAX17435/MAX17535
provide SMBusK-programmable charge current, charge
voltage, input current limit, relearn voltage, and digital
readback of the IINP voltage. The MAX17435/MAX17535
utilize a charge pump to control the adapter selection
n-channel MOSFETs when the adapter is present. When
the adapter is absent, the charge pump is shut down and
a p-channel MOSFET selects the battery.
The MAX17435/MAX17535 provide up to 7A of charge
current to 2, 3, or 4 lithium-ion (Li+) cells in series. The
charge current, and input current-limit sense amplifiers have
low offset errors and can use 10mI sense resistors. The
MAX17435/MAX17535 fixed-inductor ripple architecture
significantly reduces component size and circuit cost.
The MAX17435/MAX17535 provide a digital output that
indicates the presence of the adapter, an analog output
that indicates the adapter or battery current, depending
upon the presence or absence of the adapter, and a
digital output that indicates when the adapter current
exceeds a user-defined threshold.
The MAX17435 switches at an 850kHz frequency and the
MAX17535 switches at 500kHz.
The MAX17435/MAX17535 are available in a small, 4mm
x 4mm x 0.75mm, 24-pin, lead-free TQFN package. An
evaluation kit is available.
Applications
Notebook Computers
PDAs and Mobile Communicators
2- to 4- Li+ Cell Battery-Powered Devices
Features
S Low-Cost SMBus Charger
S High Switching Frequency (0.85MHz/0.5MHz)
S Internal Boost Switches
S SMBus-Programmable Charge Voltage, Input
Current Limit, Charge Current, Relearn Voltage,
and Digital IINP Readback
S Single-Point Compensation
S Automatic Selection of System Power Source
Adapter n-Channel MOSFETs Driven by an
Internal Dedicated Charge Pump
Adapter Soft-Start
S ±0.4% Accurate Charge Voltage
S ±2.5% Accurate Input Current Limiting
S ±3% Accurate Charge Current
S Monitor Outputs for
AC Adapter Current (±2% Accuracy)
Battery Discharge Current (±2% Accuracy)
AC Adapter Presence
S AC Adapter Overvoltage Protection
S 11-Bit Battery Voltage Setting
S 6-Bit, Charge-Current Setting/Input Current Setting
S Improved IINP Accuracy at Low Input Current
Ordering Information
Pin Configuration
19-4817; Rev 1; 9/10
+Denotes a lead(Pb)-free/RoHS-compliant package.
*EP = Exposed pad.
SMBus is a trademark of Intel Corp.
EVALUATION KIT
AVAILABLE
MAX17435
MAX17535
19
20
21
22
12 3 4 5 6
18 17 16 15 14 13
23
24
12
11
10
9
8
7
ACIN
VAA
ITHR
VCC
EN
SCL
SDA
DCIN
LDO
DLO
ADAPTLIM
IINP
CC
CSSN
PDSL
BATT
GND
CSIP
ACOK
CSIN
DHI
BST
LX
CSSP
TOP VIEW
PART TEMP RANGE PIN-PACKAGE
MAX17435ETG+ -40NC to +85NC 24 TQFN-EP*
MAX17535ETG+ -40NC to +85NC 24 TQFN-EP*
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
2 ______________________________________________________________________________________
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.
DCIN, CSSP, BATT, CSIP to GND ......................... -0.3V to +28V
CSIP to CSIN, CSSP to CSSN .............................. -0.3V to +0.3V
VCC, SCL, SDA, VAA, EN, ACIN, ITHR,
ADAPTLIM, ACOK to GND ..................................-0.3V to +6V
PDSL to GND ......................................................... -0.3V to +37V
GND to PGND ...................................................... -0.3V to +0.3V
DHI to LX. .................................................-0.3V to (VBST + 0.3V)
BST to LX ................................................................. -0.3V to +6V
BST to GND ...........................................................-0.3V to +34V
DLO to PGND ..........................................-0.3V to (VLDO + 0.3V)
LX to GND ................................................................ -6V to +28V
CC, IINP to GND ......................................-0.3V to (VLDO + 0.3V)
LDO Short Circuit to GND ......................................... Momentary
Continuous Power Dissipation (TA = +70NC)
24-Pin TQFN (derate 20.8mW/NC above +70NC) .......1666mW
Operating Temperature Range .......................... -40NC to +85NC
Junction Temperature .....................................................+150NC
Storage Temperature Range ............................ -65NC to +150NC
Lead Temperature (soldering, 10s) .................................+300NC
Soldering Temperature ....................................................+260NC
ABSOLUTE MAXIMUM RATINGS
ELECTRICAL CHARACTERISTICS
(Circuit of Figure 1, no load on LDO, VDCIN = VCSSP = VCSSN = 19V, VLX = 0V, VBST - VLX = 5V, VBATT = VCSIP = VCSIN = 16.8V,
TA = 0°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
INPUT SUPPLIES
Adapter Present Quiescent
Current (Note 1)
IDCIN + ICSSP +
ICSSN
Charging enabled,
VADAPTER = 19V,
VBATTERY = 16.8V
3 6 mA
Charging disabled 1.5 2.2 mA
BATT + CSIP + CSIN +
LX Input Current
VBATT = 16.8V Adapter absent or charger
shut down (Note 1) 2.0 FA
VBATT = 2V to 19V, adapter present (Note 1) 200 650
DCIN Input Current IDCIN Charger disabled 0.7 1.0 mA
VCC Supply Current ICC Charger added 1.5 2.5 mA
DCIN Input Voltage Range
for Charger 8 26 V
DCIN Undervoltage-Lockout
Trip Point for Charger
VDCIN falling 7 7.2 V
VDCIN rising 7.7 7.9
DCIN Input Voltage Range 8 26 V
CHARGE-VOLTAGE REGULATION
Battery Full-Charge Voltage
and Accuracy
ChargingVoltage() = 0x41A0 16.733 16.8 16.867 V
-0.4 +0.4 %
ChargingVoltage() = 0x3130 12.516 12.592 12.668 V
-0.6 +0.6 %
ChargingVoltage() = 0x20D0 8.333 8.4 8.467 V
-0.8 +0.8 %
ChargingVoltage() = 0x1060 4.15 4.192 4.234 V
-1.0 +1.0 %
Battery Undervoltage-Lockout
Trip Point for Trickle Charge 3 3.5 4 V
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
_______________________________________________________________________________________ 3
ELECTRICAL CHARACTERISTICS (continued)
(Circuit of Figure 1, no load on LDO, VDCIN = VCSSP = VCSSN = 19V, VLX = 0V, VBST - VLX = 5V, VBATT = VCSIP = VCSIN = 16.8V,
TA = 0°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
CHARGE-CURRENT REGULATION
CSIP-to-CSIN Full-Scale
Current-Sense Voltage 78.22 80.64 83.06 mV
Charge Current and Accuracy
RS2 = 10mI, Figure 1,
ChargingCurrent() = 0x1f80
7.822 8.064 8.306 A
-3 +3 %
RS2 = 10mI, Figure 1,
ChargingCurrent() = 0x0f80
3.829 3.968 4.107 A
-3.5 +3.5 %
RS2 = 10mI, Figure 1,
ChargingCurrent() = 0x0080
64 128 192 mA
-50 +50 %
Charge-Current Gain Error Based on ChargeCurrent() = 128mA and
8.064A -2 +2 %
INPUT CURRENT REGULATION
Input Current-Limit Threshold
RS1 = 10mI, Figure 1,
InputCurrent() = full scale
107.25 110 112.75
mV
-2.5 +2.5
RS1 = 10mI, Figure 1,
InputCurrent() = 0C80
62.08 64 65.92
-3 +3
RS1 = 10mI, Figure 1,
InputCurrent() = 0780
36.86 38.4 39.94 %
-4 +4
CSSP/CSSN Input Voltage Range 8 26 V
IINP Voltage Gain 19.7 20 20.3 V/V
IINP Output Voltage Range 0 4.2 V
IINP Accuracy
VCSSP - VCSSN = 110mV -5 +5
%VCSSP - VCSSN = 55mV -4 +4
VCSSP - VCSSN = 5mV -10 +10
IINP Gain Error Based on VCSSP - VCSSN = 110mV and
VCSSP - VCSSN = 55mV -1.5 +1.5 %
IINP Offset Error Based on VCSSP - VCSSN = 110mV and
VCSSP - VCSSN = 55mV -350 +350 FV
REFERENCE
REF Output Voltage REF IREF = 50FA4.082 4.096 4.115 V
REF Undervoltage-Lockout
Threshold REF falling 3.1 3.9 V
LINEAR REGULATOR
LDO Output Voltage LDO IREF = 50FA5.2 5.4 5.6 V
LDO Load Regulation 0 < ILDO < 40mA 127 250 mV
LDO Undervoltage-Lockout
Threshold LDO falling, 500mV (typ) hysteresis 3.2 4.1 5.0 V
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
4 ______________________________________________________________________________________
ELECTRICAL CHARACTERISTICS (continued)
(Circuit of Figure 1, no load on LDO, VDCIN = VCSSP = VCSSN = 19V, VLX = 0V, VBST - VLX = 5V, VBATT = VCSIP = VCSIN = 16.8V,
TA = 0°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
ACOK
ACOK Sink Current VACOK = 0.4V, VACIN = 2.5V 1 mA
ACOK Leakage Current VACOK = 5.5V, VACIN = 0.5V, TA = +25NC1FA
ACIN
ACIN Threshold Rising, 20mV (typ) hysteresis 1.465 1.485 1.53 V
ACIN Input Bias Current TA = +25NC-1 +1 FA
ITHR/ADAPTLIM
ITHR Leakage Current VITHR = 0V to LDO, TA = +25NC-1 +1 FA
ADAPTLIM Sink Current VITHR > VIINP 1 mA
ADAPTLIM Leakage Current VITHR < VIINP, TA = +25NC1FA
ITHR Threshold Calculated = VITHR - VIINP -12 +12 mV
LOGIC LEVELS
SDA/SCL Input Low Voltage 0.8 V
SDA/SCL Input High Voltage 2.1 V
SDA/SCL Input Bias Current TA = +25NC-1 +1 FA
SWITCHING REGULATOR
DHI Off-Time K Factor VDCIN = 19V, VBATT = 10V, MAX17435 55 61 67 ns/V
VDCIN = 19V, VBATT = 10V, MAX17535 93 100 107
Sense Voltage for Minimum
Discontinuous Mode
Ripple Current
VCSIP - VCSIN 5 mV
Zero-Crossing Comparator
Threshold VCSIP - VCSIN 5 mV
Cycle-by-Cycle Current-Limit
Sense Voltage VCSIP - VCSIN 120 125 130 mV
DHI Resistance High IDHI = 10mA 1.5 3 I
DHI Resistance Low IDHI = -10mA 0.8 1.6 I
DLO Resistance High IDLO = 10mA 3 6 I
DLO Resistance Low IDLO = -10mA 3 6 I
ADAPTER DETECTION
Adapter Absence Detect
Threshold VDCIN - VBATT, VDCIN falling 50 120 200 mV
Adapter Detect Threshold VDCIN - VBATT, VDCIN rising 340 430 600 mV
CHARGE-PUMP MOSFET DRIVER
PDSL Gate-Driver Source Current VPDSL - VDCIN = 3V, VDCIN = 19V 40 64 FA
PDSL Gate-Driver Output Voltage
HIGH VDCIN = 19V, open load VDCIN
+ 5.3
VDCIN
+ 8 V
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
_______________________________________________________________________________________ 5
ELECTRICAL CHARACTERISTICS (continued)
(Circuit of Figure 1, no load on LDO, VDCIN = VCSSP = VCSSN = 19V, VLX = 0V, VBST - VLX = 5V, VBATT = VCSIP = VCSIN = 16.8V,
TA = 0°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.)
ELECTRICAL CHARACTERISTICS
(Circuit of Figure 1, no load on LDO, VDCIN = VCSSP = VCSSN = 19V, VLX = 0V, VBST - VLX = 5V, VBATT = VCSIP = VCSIN = 16.8V,
TA = -40°C to +85°C, unless otherwise noted.) (Note 2)
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
ADAPTER OVERVOLTAGE PROTECTION
ACOVP Threshold Rising 2.04 2 2.1 V
ACOVP Threshold Hysteresis 30 mV
ADAPTER OVERCURRENT PROTECTION
ACOCP Threshold With respect to VCSSP - VCSSN 144 mV
ACOCP Blanking Time 16 ms
ACOCP Waiting Time When ACOCP comparator is high and at the
time the blanking time expires 0.6 s
PDSL SWITCH CONTROL
PDSL Turn-Off Resistance 2.5 4 kI
SMBus TIMING SPECIFICATIONS
SMBus Frequency fSMB 10 100 kHz
Bus Free Time tBUF 4.7 Fs
START Condition Hold Time
from SCL tHD:STA 4Fs
START Condition Setup Time
from SCL tSU:STA 4.7 Fs
STOP Condition Setup Time
from SCL tSU:STO 4Fs
Holdup Time from SCL tHD:DAT 300 ns
Setup Time from SCL tSU:DAT 250 ns
SCL Low Period tLOW 4.7 Fs
SCL High Period tHIGH 4Fs
Maximum Charging Period
Without a Charge_Voltage() or
ChargeCurrent() Command
140 175 210 s
PARAMETER SYMBOL CONDITIONS MIN MAX UNITS
INPUT SUPPLIES
Adapter Present Quiescent
Current
IDCIN + ICSSP +
ICSSN (Note 1)
Charging enabled,
VADAPTER = 19V,
VBATTERY = 16.8V
6 mA
Charging disabled 2.2 mA
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
6 ______________________________________________________________________________________
ELECTRICAL CHARACTERISTICS (continued)
(Circuit of Figure 1, no load on LDO, VDCIN = VCSSP = VCSSN = 19V, VLX = 0V, VBST - VLX = 5V, VBATT = VCSIP = VCSIN = 16.8V,
TA = -40°C to +85°C, unless otherwise noted.) (Note 2)
PARAMETER SYMBOL CONDITIONS MIN MAX UNITS
BATT + CSIP + CSIN + LX Input
Current
VBATT = 16.8V Adapter absent or charger
shut down (Note 1) 1.5 FA
VBATT = 2V to 19V, adapter present (Note 1) 650
DCIN Input Current IDCIN Charger disabled 1 mA
VCC Supply Current ICC Charger enabled 2.5 mA
DCIN Input Voltage Range
for Charger 8 26 V
DCIN Undervoltage-Lockout
Trip Point for Charger
VDCIN falling 7 V
VDCIN rising 7.9
DCIN Input Voltage Range 8 26 V
CHARGE-VOLTAGE REGULATION
Battery Full-Charge Voltage
and Accuracy
ChargingVoltage() = 0x41A0 16.73 16.87 V
-0.416 +0.416 %
ChargingVoltage() = 0x3130 12.516 12.668 V
-0.6 +0.6 %
ChargingVoltage() = 0x20D0 8.333 8.467 V
-0.8 +0.8 %
ChargingVoltage() = 0x1060 4.15 4.234 V
-1.0 +1.0 %
Battery Undervoltage-Lockout
Trip Point for Trickle Charge 3 4 V
CHARGE-CURRENT REGULATION
CSIP-to-CSIN Full-Scale
Current-Sense Voltage 78.22 83.06 mV
Charge Current and Accuracy
RS2 = 10mI, Figure 1,
ChargingCurrent() = 0x1f80
7.822 8.306 A
-3 +3 %
RS2 = 10mI, Figure 1,
ChargingCurrent() = 0x0f80
3.829 4.107 A
-3.5 +3.5 %
RS2 = 10mI, Figure 1,
ChargingCurrent() = 0x0080
64 192 mA
-50 +50 %
Charge-Current Gain Error Based on ChargeCurrent() = 128mA and
8.064A -2 +2 %
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
_______________________________________________________________________________________ 7
ELECTRICAL CHARACTERISTICS (continued)
(Circuit of Figure 1, no load on LDO, VDCIN = VCSSP = VCSSN = 19V, VLX = 0V, VBST - VLX = 5V, VBATT = VCSIP = VCSIN = 16.8V,
TA = -40°C to +85°C, unless otherwise noted.) (Note 2)
PARAMETER SYMBOL CONDITIONS MIN MAX UNITS
INPUT CURRENT REGULATION
Input Current-Limit Threshold
RS1 = 10mI, Figure 1,
InputCurrent() = full scale
106.7 113.3 mV
-2.5 +2.5 %
RS1 = 10mI, Figure 1,
InputCurrent() = 0C80
62.08 65.92 mV
-3 +3 %
RS1 = 10mI, Figure 1,
InputCurrent() = 0780
36.86 39.94 mV
-4 +4 %
CSSP/CSSN Input Voltage Range 8 26 V
IINP Voltage Gain 19.7 20.3 %
IINP Output Voltage Range 0 4 V
IINP Accuracy
VCSSP - VCSSN = 110mV -5 +5
%VCSSP - VCSSN = 55mV -4 +4
VCSSP - VCSSN = 5mV -11 +11
IINP Gain Error Based on VCSSP - VCSSN = 100mV and
VCSSP - VCSSN = 20mV -1.5 +1.5 %
IINP Offset Error Based on VCSSP - VCSSN = 100mV and
VCSSP - VCSSN = 5mV -520 +520 FV
REFERENCE
REF Output Voltage REF IREF = 50FA4.075 4.115 V
REF Undervoltage-Lockout
Threshold REF falling 3.9 V
LINEAR REGULATOR
LDO Output Voltage LDO IREF = 50FA5.2 5.6 V
LDO Load Regulation 0 < ILDO < 40mA 300 mV
LDO Undervoltage-Lockout
Threshold LDO falling, 500mV (typ) hysteresis 3.2 5.0 V
ACOK
ACOK Sink Current VACOK = 0.4V, VACIN = 1.5V 1 mA
ACIN
ACIN Threshold Rising, 20mV (typ) hysteresis 1.465 1.530 V
ACIN Input Bias Current -1 +1 FA
ITHR/ADAPTLIM
ITHR Leakage Current VITHR = 0 to 5.4V 1 FA
ADAPTLIM Sink Current VITHR > VIINP 1 mA
ADAPTLIM Leakage Current VITHR < VIINP 1FA
ITHR Threshold Calculated = VITHR - VIINP -12 +12 mV
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
8 ______________________________________________________________________________________
ELECTRICAL CHARACTERISTICS (continued)
(Circuit of Figure 1, no load on LDO, VDCIN = VCSSP = VCSSN = 19V, VLX = 0V, VBST - VLX = 5V, VBATT = VCSIP = VCSIN = 16.8V,
TA = -40°C to +85°C, unless otherwise noted.) (Note 2)
PARAMETER SYMBOL CONDITIONS MIN MAX UNITS
LOGIC LEVELS
SDA/SCL Input Low Voltage 0.8 V
SDA/SCL Input High Voltage 2.1 V
SDA/SCL Input Bias Current -1 FA
SWITCHING REGULATOR
DHI Off-Time K Factor VDCIN = 19V, VBATT = 10V, MAX17435 55 67 ns/V
VDCIN = 19V, VBATT = 10V, MAX17435 93 107
Cycle-by-Cycle Current-Limit
Sense Voltage VCSIP - VCSIN 120 130 mV
DHI Resistance High IDHI = 10mA 3 I
DHI Resistance Low IDHI = -10mA 1.6 I
DLO Resistance High IDLO = 10mA 6 I
DLO Resistance Low IDLO = -10mA 6 I
ADAPTER DETECTION
Adapter Absence Detect
Threshold VDCIN - VBATT, VDCIN falling 50 200 mV
Adapter Detect Threshold VDCIN - VBATT, VDCIN rising 270 600 mV
CHARGE-PUMP MOSFET DRIVER
PDSL Gate-Driver Source Current VPDSL - VDCIN = 3V, VDCIN = 19V 40 FA
PDSL Gate-Driver
Output Voltage High VDCIN = 19V VDCIN
+ 5.3 V
ADAPTER OVERVOLTAGE PROTECTION
ACOVP Threshold Rising 2.04 2.1 V
PDSL SWITCH CONTROL
PDSL Turn-Off Resistance 4 kI
SMBus TIMING SPECIFICATIONS
SMBus Frequency fSMB 10 100 kHz
Bus Free Time tBUF 4.7 Fs
START Condition Hold Time
from SCL tHD:STA 4Fs
START Condition Setup Time
from SCL tSU:STA 4.7 Fs
STOP Condition Setup Time
from SCL tSU:STO 4Fs
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
_______________________________________________________________________________________ 9
ELECTRICAL CHARACTERISTICS (continued)
(Circuit of Figure 1, no load on LDO, VDCIN = VCSSP = VCSSN = 19V, VLX = 0V, VBST - VLX = 5V, VBATT = VCSIP = VCSIN = 16.8V,
TA = -40°C to +85°C, unless otherwise noted.) (Note 2)
Note 1: Adapter present conditions are tested at VDCIN = 19V and VBATT = 16.8V. Adapter absent conditions are tested at
VDCIN = 16V, VBATT = 16.8V.
Note 2: Specifications to TA = -40°C are guaranteed by design and not production tested.
Typical Operating Characteristics
(Circuit of Figure 1, VIN = 19V, VCC = VDD = 5V, EN = VCC, TA = +25NC, unless otherwise specified.)
INPUT CURRENT-LIMIT ERROR
vs. INPUT CURRENT-LIMIT SETTING
MAX17435 toc01
INPUT CURRENT-LIMIT SETTING (A)
INPUT CURRENT-LIMIT ERROR (%)
642
-2
0
2
4
6
8
10
12
14
16
-4
0 8
INPUT CURRENT-LIMIT ERROR
vs. SYSTEM CURRENT
MAX17435 toc02
SYSTEM CURRENT (A)
INPUT CURRENT-LIMIT ERROR (%)
321
-3.5
-3.0
-2.5
-2.0
-1.5
-1.0
-0.5
0
-4.0
0 4
VBATT = 16.8V
INPUT CURRENT LIMIT = 3.584A
VBATT = 12.6V
VBATT = 8.4V
IINP ERROR vs. SYSTEM CURRENT
(DC SWEEP)
MAX17435 toc03
VCSSP - VCSSN (mV)
IINP ERROR (%)
4020
0
5
10
15
20
25
30
-5
0 60
VADAPTER = 0V, VBATT = 15V
VADAPTER = 20V
PARAMETER SYMBOL CONDITIONS MIN MAX UNITS
Hold Time from SCL tHD:DAT 300 ns
Setup Time from SCL tSU:DAT 250 ns
SCL Low Period tLOW 4.7 Fs
SCL High Period tHIGH 4Fs
Maximum Charging Period
Without a Charge_Voltage() or
ChargeCurrent() Command
(Note 4) 140 210 s
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
10 _____________________________________________________________________________________
Typical Operating Characteristics (continued)
(Circuit of Figure 1, VIN = 19V, VCC = VDD = 5V, EN = VCC, TA = +25NC, unless otherwise specified.)
IINP ERROR vs. SYSTEM CURRENT
MAX17435 toc04
SYSTEM CURRENT (A)
IINP ERROR (%)
321
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
-0.5
0 4
INPUT CURRENT LIMIT = 3.584A
VBATT = 16.8V
VBATT = 12.6V VBATT = 8.4V
CHARGER-CURRENT ERROR
vs. BATTERY VOLTAGE
MAX17435 toc05
BATTERY VOLTAGE (V)
CHARGER-CURRENT ERROR (%)
138
0
0.5
1.0
1.5
2.0
2.5
3.0
-0.5
3 18
ICHARGER = 5A
ICHARGER = 4A
ICHARGER = 3A
CHARGER-CURRENT ERROR
vs. SMBus SETTING
MAX17435 toc06
INPUT CURRENT-LIMIT SETTING (A)
CHARGER-CURRENT ERROR (%)
42
1
2
3
4
5
6
7
8
9
0
6
CHARGE VOLTAGE
ACCURACY AT 3.854A
MAX17435 toc07
CHARGE VOLTAGE (V)
ERROR (%)
15105
-0.10
-0.05
0
0.05
0.10
0.15
0.20
-0.15
0 20
CHARGER VOLTAGE ERROR
vs. CHARGER CURRENT
MAX17435 toc08
CHARGER CURRENT (A)
CHARGER VOLTAGE ERROR (%)
42
-0.6
-0.5
-0.4
-0.3
-0.2
-0.1
0
0.1
0.2
0.3
-0.7
0 6
VBATT = 16.8V
VBATT = 8.4V VBATT = 12.6V
BATTERY REMOVAL
(VBATT = 3V)
MAX17435 toc09
IL
1A/div
VPDSL
5V/div
VBATT
5V/div
VDCIN
5V/div
100Fs/div
SYSTEM LOAD TRANSIENT
(0A 3A 0A)
MAX17435 toc10
ISYSLD
1A/div
IL
1A/div
VBATT
200mV/div
VCC
1V/div
1ms/div
CHARGE-OUTPUT SHORT CIRCUIT
MAX17435 toc11
20Fs/div
IL
2A/div
0A
VBATT
5V/div
EFFICIENCY vs. CHARGE CURRENT
(2, 3, AND 4 CELLS)
MAX17435 toc12
CHARGE CURRENT (A)
EFFICIENCY (%)
54321
55
60
65
70
75
80
85
90
95
100
50
0 6
4 CELL
3 CELL
2 CELL
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
______________________________________________________________________________________ 11
Typical Operating Characteristics (continued)
(Circuit of Figure 1, VIN = 19V, VCC = VDD = 5V, EN = VCC, TA = +25NC, unless otherwise specified.)
LDO VOLTAGE
vs. LDO CURRENT
MAX17435 toc13
LDO CURRENT (mA)
LDO VOLTAGE (V)
40302010
5.36
5.38
5.40
5.42
5.44
5.46
5.48
5.34
0 50
VAA DEVIATION, SWITCHING
AND NOT SWITCHING
MAX17435 toc14
DCIN (V)
DEVIATION (mV)
25205 10 15
-1.5
-1.0
-0.5
0
0.5
1.0
1.5
2.0
-2.0
0 30
NOT SWITCHING
SWITCHING
VAA vs. TEMPERATURE
MAX17435 toc15
TEMPERATURE (NC)
VAA VOLTAGE (V)
806040200-20
4.085
4.090
4.095
4.100
4.105
4.110
4.080
-40 100
FREQUENCY
vs. VBATT AT 4A ICHG
MAX17435 toc16
VBATT (V)
FREQUENCY (kHz)
15105
100
200
300
400
500
600
700
800
900
1000
0
0 20
POWER-SOURCE SELECTOR SCHEME
WITH BATTERY PRESENT
(ADAPTER REMOVAL)
MAX17435 toc17
10ms/div
VPDSL
5V/div
VADAPTER
5V/div
VSYSLD
5V/div
VBATT
5V/div
POWER-SOURCE SELECTOR SCHEME
WITH BATTERY PRESENT
(ADAPTER INSERTION)
MAX17435 toc18
40ms/div
VPDSL
5V/div
VSYSLD
5V/div
VADAPTER
5V/div
VBATT
5V/div
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
12 _____________________________________________________________________________________
Pin Description
PIN NAME FUNCTION
1 SCL SMBus Clock Input. Connect to an external pullup resistor according to SMBus specifications.
2 SDA SMBus Data I/O. Open-drain output. Connect to an external pullup resistor according to SMBus
specifications.
3 DCIN
Charger Supply Input. Connect to adapter supply. For minimum input bias current connect to the
center of the input/soft-start FETs. Bypass with a 1FF ceramic capacitor to PGND placed close to
the pin. Add a 10ω resistor to reduce input surge at adapter insertion.
4 LDO
Linear Regulator Output. This is a 30mA LDO that powers the DLO driver, the BST circuit, and the
internal SMBus circuitry. Bypass with a 1FF ceramic capacitor to PGND placed close to the pin.
LDO is active when the Adapter Present = 1, independent of the state of EN. LDO is also active
when DCIN is supply by the battery while Adapter Present = 0 and EN is high. The SMBus registers
are reset by the rising LDO UVLO.
5 DLO Low-Side Power-MOSFET Driver Output. Connect to low-side n-channel MOSFET gate.
6 ADAPTLIM
Adaptive System Current-Limit Comparator Output. This open-drain output is high impedance when
the voltage at the IINP pin is lower than the ITHR threshold. For a typical application, use a 10kI
pullup resistor to LDO (pin 4).
7 BST High-Side Driver Supply. Connect a 0.1FF capacitor from BST to LX.
8 LX High-Side Driver Source Connection
9 DHI High-Side Power MOSFET Driver Output. Connect to high-side n-channel MOSFET gate.
10 ACOK
AC Detect Output. This open-drain output is high impedance when ACIN is lower than 1.485V.
The ACOK output remains high when the MAX17435/MAX17535 are powered down. For a typical
application, use a 10kI pullup resistor to LDO (pin 4).
11 CSIN Output Current-Sense Negative Input. Connect this pin to the negative terminal of the sense resistor.
See the Setting Charge Current section for resistor value and scaling.
12 CSIP
Output Current-Sense Positive Input. Connect a current-sense resistor from CSIP to CSIN; the
voltage across these two pins is interpreted by the MAX17435/MAX17535 as proportional to the
charge current delivered to the battery with approximately 110mV full-scale voltage. See the Setting
Charge Current section for resistor value and scaling.
13 BATT Battery Voltage Feedback Input. Connect as close as possible to the battery terminal.
14 PDSL
Power-Source n-Channel MOSFET Switch Driver Output. When the adapter is not present or an
overvoltage event is detected at the input, the PDSL output is pulled to GND with a 2.5kI (typ)
resistor. Otherwise, it is typically 8V above the adapter voltage when the part is not using the
battery. This is powered by an internal charge pump.
15 CSSN Input Current-Sense Negative Input. See the description of the CSSP pin for resistor value and
scaling.
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
______________________________________________________________________________________ 13
Pin Description (continued)
PIN NAME FUNCTION
16 CSSP
Current Sense for Positive Input. Connect a current-sense resistor from CSSP to CSSN. The voltage
across CSSP to CSSN determines the current at which the charger reduces charging current to
keep from drawing more current from the adapter than is allowed. As the system current flowing in
the resistor from CSSN to CSSP increases, the charger reduces charge current to keep the system
current at the limit value. When the system current reaches 130% of InputCurrent() setting for more
than 16ms, the PDSL pin turns off the adapter selector FET to prevent excess current from being
drawn from the adapter. The adaptor selector FET is re-enabled after 0.6s. If the fault continues, the
cycle is repeated three times after which the MAX17435/MAX17535 is latched off. To reset the latch,
remove and reinsert the adapter.
17 CC Voltage Regulation Loop-Compensation Point. Connect a 10nF capacitor from CC to GND.
18 IINP
Input Current-Monitor Output. The voltage at the IINP pin is 20 times the voltage from CSSP to
CSSN. This voltage is present when charging is enabled to monitor the system current, and when
the battery is discharging to monitor the battery discharge current.
19 ACIN
AC Adapter-Detect Input. ACIN is the input to a comparator with a 1.485V (typ) reference voltage.
The output of the comparator is ACOK. ACOK goes low when the threshold voltage is exceeded,
indicating that the AC adapter is present, and it enables the charger. When the ACIN input is above
2.0V, the MAX17435/MAX17535 interpret that as an adapter overvoltage event. The charger is then
disabled and the adapter MOSFETs are turned off. If the part is charging and the ACIN voltage
drops below the programmed threshold, the charger is disabled, and a ChargeCurrent() and
ChargeVoltage() command have to be written over the SMBus to re-enable the charger.
20 ITHR
Adaptive System Current-Limit Comparator Threshold. This pin connects to the inverting input of a
comparator. The noninverting input of the comparator is the IINP input, while the output is driving
the ADAPTLIM open drain. When the input to ITHR is greater than IINP, the ADAPTLIM output is
high.
21 VAA 4.096V Internal Reference Voltage; No External Load Allowed. Bypass to analog ground using a 1FF
or greater ceramic capacitor. VAA is active only after LDO and the internal reference are active.
22 VCC Circuitry Supply-Voltage Input. Connect to LDO through 10I and bypass with a 0.1FF capacitor to
GND as close as possible to the package pin.
23 GND Analog Ground
24 EN
Enable/Disable Charger Operation. This disables the charger and associated circuitry when EN
goes low and is in addition to the ACOK charger enable. If the adapter is absent and EN is pulled
up to a voltage higher than 2.4V, LDO, VAA, the input charge current, and the battery discharge
current monitor on IINP are enabled.
EP Exposed Pad. Connect backside EP to power ground.
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
14 _____________________________________________________________________________________
Figure 1. Standard Application Circuit
Detailed Description
The MAX17435/MAX17535 charger includes all the
functions necessary to charge Li+, NiMH, and NiCd smart
batteries. A high-efficiency synchronous rectified step-
down DC-DC converter is used to implement a constant-
current constant-voltage charger. The DC-DC converter
drives a high-side n-channel MOSFET and provides
synchronous rectification with a low-side n-channel
MOSFET. The charge current and input current-sense
amplifiers have low-input offset errors (200FV typ),
allowing the use of small-valued sense resistors. The
MAX17435/MAX17535 use an SMBus interface similar
to the MAX8731A to set charge current, charge voltage,
and input current limit. In addition, the MAX17435/
MAX17535 SMBus interface supports ChargeVoltage
(), ChargeCurrent(), InputCurrent(), RELEARN(), and
IINPVoltage() readback.
BATTERY
ADAPTER
BST
CSSP CSSN
DHI
LX
DLO
PGND PAD
CSIN
CSIP
BATT
CC
SCL
LDO
GND
IINP
V
AA
V
CC
C
IN
N1
N2
N3
N4
L1
SYSTEM LOAD
C
IN
= 2 x 4.7FF
C
OUT
= 4.7FF
L1 = 2FH
R11
2MI
R4
150kI
C6
10nF
RS1
10mI
C10
1FF
C4
0.1FF
C5
0.01FF
RS2
10mI
R7
10kI
R8
49.9kI
R6
7.06kI
R9
103kI
R10
10kI
R5
10kI
R16
10I
Q1A
Q1B
ACIN
ACOK
SDA
EN
DCIN PDSL
GND
ITHR
ADAPTLIM
LDO
LDO
LDO
R12
10kI
IINP VOLTAGE
ADAPTER
CURRENT-LIMIT
FLAG
SMBus
CONTROL
ACOK
LDO
MAX17435
MAX17535
R17
10I
R18
1kI
R14
10kI
R13
10kI
C
OUT
C1
1FF
C3
1FF
C11
1FF
C2
0.1FF
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
______________________________________________________________________________________ 15
Figure 2. Block Diagram
The MAX17435/MAX17535 control input current (CCS
control loop), charge current (CCI control loop), or
charge voltage (CCV control loop), depending on the
operating condition. The three control loops, CCV, CCI,
and CCS, are brought together internally at the lowest
voltage clamp (LVC) amplifier. The output of the LVC
amplifier is the feedback control signal for the DC-DC
controller. The minimum voltage at the CCV, CCI, or
CCS appears at the output of the LVC amplifier and
clamps the other 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). The
CCI loop is internally compensated and the CCV and
CCS loops share a common compensation network at
CC. The dominant control loop (CCV, CCS) drives the
compensation network.
CSSN
CSSP
IINP LDO DLO PGND (PAD)
BST DHI LX
CURRENT-
SENSE
AMPLIFIER
CURRENT-
SENSE
AMPLIFIER
CSIN
CSIP
CSI
BATT
CHARGE
VOLTAGE()
400mV
5.4V
REGULATOR
gMV
SCL
SMBus LOGIC
BATTERY
OVP
IMAX
8.064A
CCMP IMIN
ZCMP
750mA
500mA
DC-DC
CONVERTER
BATTERY
CC
LVC AND CAP
SWITCH LOGIC
SDA
IN_SET
ADAPTER
PRESENT
HIGH-SIDE
DRIVER
DCIN
CSIN
BDIV
DCIN
1.485V
ACIN ACOK ITHR PDSL
4.096V
REFERENCE
VAA
GND
PDSL LOGIC
AC_EN
AC_EN
A = 20V/V
EN
ADAPTLIM
gMI
GMS
CHG_EN
MAX17435
MAX17535
LOW-SIDE
DRIVER
IINP
LDO
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
16 _____________________________________________________________________________________
Table 1. EN Pin Function
EN Pin
The EN pin is a logic input. The state of the EN pin and
the presence or absence of the adapter determines the
state of PDSL, the IINP path, and the charger function as
shown in Table 1.
30mA LDO
The 5.4V LDO is powered from DCIN and is compensated
for loads from 0 to 30mA with a single 1FF ceramic
capacitor. The load regulation over the 30mA load is
34mV (typ), 100mV max. The LDO supplies the drive for
the DLO driver and also the BST circuitry. It is shut down
when the adapter is absent.
Analog Input Current Monitor Output
IINP monitors the system-input current sensed across the
sense resistor (RS1) that connects between CSSP and
CSSN. The voltage at IINP is proportional to the input
current according to the following equation:
IINP
INPUT
V
IRS1 A
=×
where IINPUT is the DC current supplied by the AC
adapter and A is the gain (20V/V typ). VIINP has a 0V to
2.2V output voltage range.
Table 1 shows the charge and IINP status when the
adapter is present or absent and as a function of the
EN pin. When connected as shown in the standard
application circuit, IINP monitors the input system
current when the adapter is present or the battery
discharge current when the adapter is absent. Leave
IINP unconnected if not used.
Table 2 is the fault protection and shutdown operation
table.
SMBus Implementation
The MAX17435/MAX17535 receive control inputs from
the SMBus interface. The MAX17435/MAX17535 use
a subset of the commands documented in the System
Management Bus Specifications V1.1, which can be
downloaded from www.smbus.org. The MAX17435/
MAX17535 use the SMBus read-word and write-word
protocols to communicate with the system controller. The
MAX17435/MAX17535 operate only as slave devices
with address 0b0001001_ (0x12) and do not initiate
communication on the bus. In addition, the MAX17435/
MAX17535 have two identification registers: (0xFF), a
16-bit device ID register and a 16-bit manufacturer ID
register (0xFE). The SMBus implementation is similar to
the MAX8731A with the addition of the RELEARN() and
IINPVoltage() commands. The SMBus is not powered
from an external supply, so during states that disable the
charger, the SMBus register data is lost, so the register
data must be rewritten when reenabled. See Figure 3.
Table 2. Fault Protection and Shutdown
Operation Table
MODE CONTROLLER
STATE
DRIVER
STATE
Thermal fault (latched,
reset by adapter
reinsertion)
Charger disabled,
PDSL low, LDO,
and VAA off
DHI and
DLO low
ACOV fault or less
than 3 ACOCP faults
(not latched)
Charger disabled,
PDSL low, LDO,
and VAA active
DHI and
DLO low
More than 3 ACOCP
faults (latched, reset
by adapter reinsertion)
Charger disabled,
PDSL low, LDO,
and VAA off
DHI and
DLO low
Battery OV fault
(not latched)
Charger disabled,
PDSL high, LDO,
and VAA active
DHI and
DLO low
ADAPTER
PRESENT EN PDSL STATUS CHARGER STATUS SYSTEM CURRENT MONITOR
STATUS (IINP PATH)
Yes High PDSL is pumped 8V above the DCIN
voltage (charge pump on). Enabled Enabled
Yes Low PDSL is pumped 8V above the DCIN
voltage (charge pump on). Disabled Enabled
No High Charge pump is off and PDSL is
forced to 0V (typ, 27C). Disabled Enabled
No Low Charge pump is off and PDSL is
forced to 0V (typ, 27C). Disabled Disabled
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
______________________________________________________________________________________ 17
Figure 3. SMBus Write-Word and Read-Word Protocols
Figure 4. SMBus Write Timing
The data (SDA) and clock (SCL) pins have Schmitt-
trigger inputs that can accommodate slow edges.
Choose pullup resistors for SDA and SCL to achieve rise
times according to the SMBus specifications.
Communication starts when the master signals a START
condition, which is a high-to-low transition on SDA, while
SCL is high. When the master has finished communicating,
the master issues a STOP condition, which is a low-to-
high transition on SDA, while SCL is high. The bus is
then free for another transmission. Figures 4 and 5 show
the timing diagrams for signals on the SMBus interface.
The address byte, command byte, and data bytes are
transmitted between the START and STOP conditions.
The SDA state is allowed to change only while SCL is
low, except for the START and STOP conditions. Data
is transmitted in 8-bit bytes and is sampled on the rising
edge of SCL. Nine clock cycles are required to transfer
each byte in or out of the MAX17435/MAX17535 because
either the master or the slave acknowledges the receipt
of the correct byte during the ninth clock. The MAX17435/
MAX17535 support the charger commands as described
in Table 4.
S
a) Write-Word Format
W ACK ACK ACK P
COMMAND
BYTE
LOW DATA
BYTE
HIGH DATA
BYTE
SLAVE
ADDRESS ACK
7 bits 8 bits1b
MSB LSB MSB LSB
8 bits
MSB LSB
8 bits
MSB LSB0
1b
0
1b
0
1b
0
1b
0
PRESET TO
0b0001001
Relearn() = 0x3D
ChargingCurrent() = 0x14
ChargerVoltage() = 0x15
INP_Voltage() = 0x3E
D7 D0 D15 D8
S
b) Read-Word Format
W ACK ACK NACK P
COMMAND
BYTE
LOW DATA
BYTE
HIGH DATA
BYTE
SLAVE
ADDRESS SACK
7 bits 8 bits1b
MSB LSB
SLAVE
ADDRESS
7 bits
MSB LSBMSB LSB
8 bits
MSB LSB
8 bits
MSB LSB0
1b
0
R ACK
1b
1
1b
0
1b
0
1b
0
1b
1
PRESET TO
0b0001001
PRESET TO
0b0001001
D7 D0 D15 D8
LEGEND:
S = START CONDITION OR REPEATED START CONDITION
ACK = ACKNOWLEDGE (LOGIC-LOW)
W = WRITE BIT (LOGIC-LOW)
P = STOP CONDITION
NACK = NOT ACKNOWLEDGE (LOGIC-HIGH)
R = READ BIT (LOGIC-HIGH)
MASTER TO SLAVE
SLAVE TO MASTER
SMBCLK
A B C D EF G H IJK
SMBDATA
tSU:STA tHD:STA
tLOW tHIGH
tSU:DAT tHD:DAT
tHD:DAT tSU:STO tBUF
A = START CONDITION
B = MSB OF ADDRESS CLOCKED INTO SLAVE
C = LSB OF ADDRESS CLOCKED INTO SLAVE
D = R/W BIT CLOCKED INTO SLAVE
E = SLAVE PULLS SMBDATA LINE LOW
LM
F = ACKNOWLEDGE BIT CLOCKED INTO MASTER
G = MSB OF DATA CLOCKED INTO SLAVE
H = LSB OF DATA CLOCKED INTO SLAVE
I = SLAVE PULLS SMBDATA LINE LOW
J = ACKNOWLEDGE CLOCKED INTO MASTER
K = ACKNOWLEDGE CLOCK PULSE
L = STOP CONDITION, DATA EXECUTED BY SLAVE
M = NEW START CONDITION
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
18 _____________________________________________________________________________________
Battery Charger Commands
The MAX17435/MAX17535 support four battery-charger
commands that use either write-word or read-word
protocols as summarized in Table 3. ManufacturerID()
and DeviceID() can be used to identify the
MAX17435/MAX17535. On the MAX17435/MAX17535,
ManufacturerID() always returns 0x004D and DeviceID()
always returns 0x0008.
Setting Charge Voltage
To set the output voltage, use the SMBus to write a
16-bit ChargeVoltage() command using the data format
listed in Table 4. The ChargeVoltage() command uses
the write-word and read-word protocols (see Figure
3). The command code for ChargeVoltage() is 0x15
(0b00010101). The MAX17435/MAX17535 provide
a charge-voltage range of 4.095V to 19.200V, with
16mV resolution. Set ChargeVoltage() below 4.095V to
terminate charging. Upon reset, the ChargeVoltage()
and ChargeCurrent() values are cleared and the charger
remains off until both the ChargeVoltage() and the
ChargeCurrent() command are sent. Both DHI and DLO
remain low until the charger is restarted.
Setting Charge Current
To set the charge current, use the SMBus to write a 16-bit
ChargeCurrent() command using the data format listed in
Table 5. The ChargeCurrent() command uses the write-word
and read-word protocols (see Figure 3). The command
code for ChargeCurrent() is 0x14 (0b00010100). When
RS2 = 10mI, the MAX17435/MAX17535 provide a charge-
current range of 128mA to 8.064A, with 128mA resolution.
If a sense resistor other than 10mI is used, the current
limit must be scaled by RS/10mI, where RS is the sense
resistor value used on the circuit. Set ChargeCurrent() to
0 to terminate charging. Upon reset, the ChargeVoltage()
and ChargeCurrent() values are cleared and the charger
remains off until both the ChargeVoltage() and the
ChargeCurrent() command are sent. Both DHI and DLO
remain low until the charger is restarted.
The MAX17435/MAX17535 include a fault limiter for
low-battery conditions. If the battery voltage is less than
3V, the charge current is temporarily set to 128mA. The
ChargeCurrent() register is preserved and becomes
active again when the battery voltage is higher than 3V.
This function effectively provides a foldback current limit
that protects the charger during short circuit and overload.
Figure 5. SMBus Read Timing
Table 3. Battery Charger Command Summary
Note: ‘x’ means the data is sent to the analog block.
SMBCLK
A = START CONDITION
B = MSB OF ADDRESS CLOCKED INTO SLAVE
C = LSB OF ADDRESS CLOCKED INTO SLAVE
D = R/W BIT CLOCKED INTO SLAVE
A B C D EF G H IJ
SMBDATA
tSU:STA tHD:STA
tLOW tHIGH
tSU:DAT tHD:DAT tSU:DAT tSU:STO tBUF
K
E = SLAVE PULLS SMBDATA LINE LOW
F = ACKNOWLEDGE BIT CLOCKED INTO MASTER
G = MSB OF DATA CLOCKED INTO MASTER
H = LSB OF DATA CLOCKED INTO MASTER
I = ACKNOWLEDGE CLOCK PULSE
J = STOP CONDITION
K = NEW START CONDITION
COMMAND COMMAND NAME READ/WRITE DESCRIPTION POR STATE
0x14 ChargeCurrent() Read and write 6-bit charge-current setting, readback
(3’b0, 6’bx, 7’b0) 0x0000
0x15 ChargeVoltage() Read and write 11-bit charge-voltage setting, readback
(1’b0, 11’bx, 4’b0) 0x0000
0x3D Relearn Voltage Read and write 11-bit relearn voltage set and 1-bit enable/status 0x4B00
0x3E IINPVoltage() Read only Digital readback of IINP voltage NA
0x3F InputCurrent() Read and write 6-bit input-current setting readback
(3’b0, 6’bx, 7’b0) 0x1000
0xFE ManufacturerID() Read only Manufacturer ID 0x004D
0xFF DeviceID() Read only Device ID 0x0008
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
______________________________________________________________________________________ 19
Table 4. ChargeVoltage() (0x15)
Table 5. ChargeCurrent() (0x14) (10mI Sense Resistor, RS2)
BIT BIT NAME DESCRIPTION
0 Not used. Normally a 1mV weight.
1 Not used. Normally a 2mV weight.
2 Not used. Normally a 4mV weight.
3 Not used. Normally an 8mV weight.
4 Charge Voltage, DACV 0 0 = Adds 0mV of charger voltage compliance, 4095mV min.
1 = Adds 16mV of charger voltage compliance.
5 Charge Voltage, DACV 1 0 = Adds 0mV of charger voltage compliance, 4095mV min.
1 = Adds 32mV of charger voltage compliance.
6 Charge Voltage, DACV 2 0 = Adds 0mV of charger voltage compliance, 4095mV min.
1 = Adds 64mV of charger voltage compliance.
7 Charge Voltage, DACV 3 0 = Adds 0mV of charger voltage compliance, 4095mV min.
1 = Adds 128mV of charger voltage compliance.
8 Charge Voltage, DACV 4 0 = Adds 0mV of charger voltage compliance, 4095mV min.
1 = Adds 256mV of charger voltage compliance.
9 Charge Voltage, DACV 5 0 = Adds 0mV of charger voltage compliance, 4095mV min.
1 = Adds 512mV of charger voltage compliance.
10 Charge Voltage, DACV 6 0 = Adds 0mA of charger voltage compliance, 4095mV min.
1 = Adds 1024mV of charger voltage compliance.
11 Charge Voltage, DACV 7 0 = Adds 0mV of charger voltage compliance, 4095mV min.
1 = Adds 2048mV of charger voltage compliance.
12 Charge Voltage, DACV 8 0 = Adds 0mV of charger voltage compliance.
1 = Adds 4096mV of charger voltage compliance.
13 Charge Voltage, DACV 9 0 = Adds 0mV of charger voltage compliance.
1 = Adds 8192mV of charger voltage compliance.
14 Charge Voltage, DACV 10 0 = Adds 0mV of charger voltage compliance.
1 = Adds 16384mV of charger voltage compliance, 19200mV max.
15 Not used. Normally a 32768mV weight.
BIT BIT NAME DESCRIPTION
0 Not used. Normally a 1mA weight.
1 Not used. Normally a 2mA weight.
2 Not used. Normally a 4mA weight.
3 Not used. Normally an 8mA weight.
4 Not used. Normally a 16mA weight.
5 Not used. Normally a 32mA weight.
6 Not used. Normally a 64mA weight.
7 Charge Current, DACI 0 0 = Adds 0mA of charger current compliance.
1 = Adds 128mA of charger current compliance.
8 Charge Current, DACI 1 0 = Adds 0mA of charger current compliance.
1 = Adds 256mA of charger current compliance.
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
20 _____________________________________________________________________________________
Setting Input-Current Limit
System current normally fluctuates as portions of the
system are powered up or put to sleep. By using the input-
current-limit circuit, the output-current requirement of the
AC wall adapter can be lowered, reducing system cost.
The total input current is the sum of the system supply
current, the charge current flowing into the battery, and
the current required by the charger. When the input
current exceeds the input current limit set with the
InputCurrent() command, the MAX17435/MAX17535
reduce the charge current to provide priority to system
load current. As the system supply current increases,
the charge current is reduced as needed to maintain
the total input current at the input current limit. The
MAX17435/MAX17535 decrease the charge current to
zero, if necessary, to reduce the input current to the input
current limit. Thereafter, if the system current continues
to increase, there is nothing the MAX17435/MAX17535
can do to maintain the input current at the input current
limit. If the system current continues to increase so that
the input current exceeds the ACOCP threshold (130%
of InputCurrent() setting) for more than 16ms (typ), the
MAX17435/MAX17535 drive PDSL low, which turns off the
adapter selector FETs and disconnects the adapter from
the system. After waiting 0.6s, the MAX17435/MAX17535
re-enable PDSL. If the ACOCP fault occurs again, the
MAX17435/MAX17535 drive PDSL low again after the
16ms (typ) delay. This cycle is repeated a maximum
of three times, after which the MAX17435/MAX17535
are latched off, and need to be reset by removing and
reinserting the adapter.
The total input current can be estimated as follows:
INPUT SYSTEM CHARGER
CHARGE BATTERY IN
I I I
[(I V ) (V )]
= + +
× × η
where E is the efficiency of the DC-DC converter (typically
85% to 95%).
To set the input current limit, use the SMBus to write a
16-bit InputCurrent() using the data format listed in Table
6. The InputCurrent() command uses the write-word
and read-word protocols (see Figure 3). The command
code for InputCurrent() is 0x3F (0b00111111). When RS1
= 10mI, the MAX17435/MAX17535 provide an input
current-limit range of 256mA to 11.004A with 256mA
resolution. If a resistor RS other than 10mI is used, the
input current limit is scaled by a factor of 10mI/RS1.
InputCurrent() settings from 1mA to 256mA result in a
current limit of 256mA. Upon reset, the input current limit
is 256mA.
Setting Relearn Voltage
To set the relearn voltage, use the SMBus to write a 16-bit
RelearnVoltage() command using the data format listed in
Table 7. The RelearnVoltage() command uses the
write-word and read-word protocols (see Figure 3).
The command code for RelearnVoltage() is 0x3D
(0b00111101). The MAX17435/MAX17535 provide a
charge-voltage range of 4.095V to 19.200V with 16mV
resolution. When the relearn function is enabled by setting
bit 0 to 1, the MAX17435/MAX17535 drive PDSL low,
turning off the adapter selector FETs and turning on the
battery selector FET. This allows the battery to discharge
by powering the system while the adapter is still present.
The battery voltage is monitored until the battery voltage
reaches the relearn voltage corresponding to a known low
state of charge. The relearn bit 0 is set to zero, and PDSL
is re-enabled.
Table 5. ChargeCurrent() (0x14) (10mI Sense Resistor, RS2) (continued)
BIT BIT NAME DESCRIPTION
9 Charge Current, DACI 2 0 = Adds 0mA of charger current compliance.
1 = Adds 512mA of charger current compliance.
10 Charge Current, DACI 3 0 = Adds 0mA of charger current compliance.
1 = Adds 1024mA of charger current compliance.
11 Charge Current, DACI 4 0 = Adds 0mA of charger current compliance.
1 = Adds 2048mA of charger current compliance.
12 Charge Current, DACI 5 0 = Adds 0mA of charger current compliance.
1 = Adds 4096mA of charger current compliance, 8064mA max
13 Not used. Normally a 8192mA weight.
14 Not used. Normally a 16386mA weight.
15 Not used. Normally a 32772mA weight.
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
______________________________________________________________________________________ 21
Table 6. InputCurrent() (0x3F) (10mI Sense Resistor, RS1)
Table 7. Relearn() (0x3D)
BIT BIT NAME DESCRIPTION
0 Not used. Normally a 2mA weight.
1 Not used. Normally a 4mA weight.
2 Not used. Normally an 8mA weight.
3 Not used. Normally a 16mA weight.
4 Not used. Normally a 32mA weight.
5 Not used. Normally a 64mA weight.
6 Not used. Normally a 128mA weight.
7 Input Current, DACS 0 0 = Adds 0mA of input current compliance.
1 = Adds 256mA of input current compliance.
8 Input Current, DACS 1 0 = Adds 0mA of input current compliance.
1 = Adds 512mA of input current compliance.
9 Input Current, DACS 2 0 = Adds 0mA of input current compliance.
1 = Adds 1024mA of input current compliance.
10 Input Current, DACS 3 0 = Adds 0mA of input current compliance.
1 = Adds 2048mA of input current compliance.
11 Input Current, DACS 4 0 = Adds 0mA of input current compliance.
1 = Adds 4096mA of input current compliance.
12 Input Current, DACS 5 0 = Adds 0mA of input current compliance.
1 = Adds 8192mA of input current compliance, 11004mA max.
13 Not used. Normally a 16384mA weight.
14 Not used. Normally a 32768mA weight.
15 Not used. Normally a 65536mA weight.
BIT BIT NAME DESCRIPTION
0 Relearn, RL 0
0 = Disables the relearn function.
1 = Enables the relearn function.
When the relearn threshold is crossed as the battery discharges, bit 0
is reset to zero by the MAX17435/MAX17535.
1 Not used.
2 Not used.
3 Not used.
4 Relearn, RL 1 0 = Adds 0mV of relearn threshold compliance, 1024mV min.
1 = Adds 16mV of relearn threshold compliance.
5 Relearn, RL 2 0 = Adds 0mV of relearn threshold compliance, 1024mV min.
1 = Adds 32mV of relearn threshold compliance.
6 Relearn, RL 3 0 = Adds 0mV of relearn threshold compliance, 1024mV min.
1 = Adds 64mV of relearn threshold compliance.
7 Relearn, RL 4 0 = Adds 0mV of relearn threshold compliance, 1024mV min.
1 = Adds 128mV of relearn threshold compliance.
8 Relearn, RL 5 0 = Adds 0mV of relearn threshold compliance, 1024mV min.
1 = Adds 256mV of relearn threshold compliance.
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
22 _____________________________________________________________________________________
Reading IINP Voltage
To read the digital version of the IINP voltage, issue the
SMBus command IINPVoltage() command using the
16-bit data format listed in Table 8. The command code
for IINPVoltage() is 0x3E (0b00111110). The IINPVoltage()
command uses the read-word protocol (see Figure 3).
Charger Timeout
The MAX17435/MAX17535 include a timer to
terminate charging if the charger has not received a
ChargeVoltage() or ChargeCurrent() command within
140s (min). If a timeout occurs, both ChargeVoltage()
and ChargeCurrent() commands must be sent again to
reenable charging.
Table 7. Relearn() (0x3D) (continued)
Table 8. IINPVoltage() (0x3E)
BIT BIT NAME DESCRIPTION
9 Relearn, RL 6 0 = Adds 0mV of relearn threshold compliance, 1024mV min.
1 = Adds 512mV of relearn threshold compliance.
10 Relearn, RL 7 0 = Adds 0mA of relearn threshold compliance.
1 = Adds 1024mV of relearn threshold compliance.
11 Relearn, RL 8 0 = Adds 0mV of relearn threshold compliance.
1 = Adds 2048mV of relearn threshold compliance.
12 Relearn, RL 9 0 = Adds 0mV of relearn threshold compliance.
1 = Adds 4096mV of relearn threshold compliance.
13 Relearn, RL 10 0 = Adds 0mV of relearn threshold compliance.
1 = Adds 8192mV of relearn threshold compliance.
14 Relearn, RL 11 0 = Adds 0mV of relearn threshold compliance.
1 = Adds 16384mV of relearn threshold compliance, 19200mV max.
15 Not used.
BIT BIT NAME DESCRIPTION
0 Not used. Normally a 1mV weight.
1 Not used. Normally a 2mV weight.
2 Not used. Normally a 4mV weight.
3 Not used. Normally a 8mV weight.
4 IINP Voltage, DACV 0 0 = Adds 0mV of IINP voltage.
1 = Adds 12.8mV of IINP voltage.
5 IINP Voltage, DACV 1 0 = Adds 0mV of IINP voltage.
1 = Adds 25.6mV of IINP voltage.
6 IINP Voltage, DACV 2 0 = Adds 0mV of IINP voltage.
1 = Adds 51.2mV of IINP voltage.
7 IINP Voltage, DACV 3 0 = Adds 0mV of IINP voltage.
1 = Adds 103.6mV of IINP voltage.
8 IINP Voltage, DACV 4 0 = Adds 0mV of IINP voltage.
1 = Adds 207.2mV of IINP voltage.
9 IINP Voltage, DACV 5 0 = Adds 0mV of IINP voltage.
1 = Adds 414.4mV of IINP voltage.
High-Frequency,
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MAX17435/MAX17535
______________________________________________________________________________________ 23
DC-DC Converter
The MAX17435/MAX17535 employ a synchronous step-
down DC-DC converter with an n-channel, high-side
MOSFET switch and an n-channel low-side synchronous
rectifier. The MAX17435/MAX17535 feature a pseudo-
fixed-frequency, current-mode control scheme with cycle-
by-cycle current limit. The controller’s constant off-time
(tOFF) is calculated based on VDCIN, VCSIN, and a time
constant with a minimum value of 300ns. The MAX17435/
MAX17535 can also operate in discontinuous conduction
mode for improved light-load efficiency. The operation of
the DC-DC controller is determined by the following five
comparators as shown in the block diagram in Figure 2:
U The IMIN comparator sets the peak inductor current
in discontinuous mode. IMIN compares the control
signal (LVC) against 100mV (typ). When LVC voltage
is less than 100mV, DHI and DLO are both low.
U The CCMP comparator is used for current-mode
regulation in continuous conduction mode. CCMP
compares LVC against the charging current feedback
signal (CSI). The comparator output is high and the
high-side MOSFET on-time is terminated when the
CSI voltage is higher than LVC.
U The IMAX comparator provides a cycle-by-cycle
current limit. IMAX compares CSI to 2V (corresponding
to 10A when RS2 = 10mI). The comparator output is
high and the high-side MOSFET on-time is terminated
when the current-sense signal exceeds 10A. A new
cycle cannot start until the IMAX comparator output
goes low.
U The ZCMP comparator provides zero-crossing
detection during discontinuous conduction. ZCMP
compares the current-sense feedback signal to
500mA (RS2 = 10mI). When the inductor current
is lower than the 500mA threshold, the comparator
output is high and DLO is turned off.
U The OVP comparator checks for the battery voltage
400mV above the set point and, if that condition is
detected, it disables charging.
CCV, CCI, CCS, and LVC Control Blocks
The MAX17435/MAX17535 control input current (CCS
control loop), charge current (CCI control loop), or
charge voltage (CCV control loop), depending on the
operating condition. The three control loops, CCV, CCI,
and CCS are brought together internally at the lowest
voltage clamp (LVC) amplifier. The output of the LVC
amplifier is the feedback control signal for the DC-DC
controller. The minimum voltage at the CCV, CCI, or CCS
appears at the output of the LVC amplifier and clamps
the other 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 charge current, the MAX17435/
MAX17535s’ inductor current never crosses zero,
which is defined as continuous conduction mode.
The MAX17435 switches at 850kHz (nominal) and the
MAX17535 switches at 500kHz (nominal) if the charger
is not in dropout (VCSIN < 0.88 x VDCIN). The controller
starts a new cycle by turning on the high-side MOSFET
and turning off the low-side MOSFET. When the charge
current feedback signal (CSI) is greater than the control
point (LVC), the CCMP comparator output goes high and
the controller initiates the off-time by turning off the high-
side MOSFET and turning on the low-side MOSFET. The
operating frequency is governed by the off-time and is
dependent upon VCSIN and VDCIN.
At the end of the fixed off-time, the controller initiates a
new cycle if the control point (LVC) is greater than 150mV,
and the peak charge current is less than the cycle-by-
cycle current limit. Restated another way, IMIN must be
high, IMAX must be low, and OVP must be low for the
Table 8. IINPVoltage() (0x3E) (continued)
BIT BIT NAME DESCRIPTION
10 IINP Voltage, DACV 6 0 = Adds 0mA of IINP voltage.
1 = Adds 828.8mV of IINP voltage.
11 IINP Voltage, DACV 7 0 = Adds 0mV of IINP voltage.
1 = Adds 1.6576V of IINP voltage to a maximum of 2.20V.
12 Not used. Normally a 4096mV weight.
13 Not used. Normally a 8192mV weight.
14 Not used. Normally a 16384mV weight.
15 Not used. Normally a 32768mV weight.
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
24 _____________________________________________________________________________________
controller to initiate a new cycle. If the peak inductor
current exceeds IMAX comparator threshold or the output
voltage exceeds the OVP threshold, then the on-time is
terminated. The cycle-by-cycle current limit effectively
protects against overcurrent and short-circuit faults.
If, during the off-time, the inductor current goes to zero, the
ZCMP comparator output pulls high, turning off the low-side
MOSFET. Both the high- and low-side MOSFETs are turned
off until another cycle is ready to begin. The MAX17435/
MAX17535 enter into the discontinuous conduction mode
(see the Discontinuous Conduction section).
The on-time is calculated according to the following
equation:
RIPPLE
ON CSSN BATT
L I
tV - V
×
=
where:
BATT OFF
RIPPLE
V t
IL
×
=
There is a 0.3Fs minimum off-time when the (VDCIN -
VBATT) differential becomes too small. If VBATT R 0.88
x VDCIN, then the threshold for minimum off-time is
reached and the off-time is fixed at 0.27Fs. The switching
frequency in this mode varies according to the equation:
RIPPLE OFF
CSSN BATT
1
fL I t
V - V
=×+
Discontinuous Conduction
The MAX17435/MAX17535 can also operate in
discontinuous conduction mode to ensure that the
inductor current is always positive. The MAX17435/
MAX17535 enter discontinuous conduction mode when
the output of the LVC control point falls below 110mV. For
RS2 = 10mI, this corresponds to 367mA:
1
DIS 2
110mV
I 367mA
15 RS2
= × =
×
where IDIS is the current level for discontinuous
conduction.
In discontinuous mode, a new cycle is not started until
the LVC voltage rises above 150mV. 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.
Under extremely light loads, the BST capacitor may
become discharged if there is no DLO pulse. After 192µs
(typ), the MAX17435/MAX17535 turn on DLO for 300ns
and 550ns, respectively, to recharge the BST capacitor.
This DLO pulse need not be followed by a DHI pulse.
Compensation
The CCI loop is internally compensated. The CCV and
the CCS share the external compensation capacitor.
The control loop, which is dominant, uses the external
compensation cap and the one that is not used uses an
internal compensation capacitor.
CCV Loop Compensation
The simplified schematic in Figure 6 is sufficient to
describe the operation of the MAX17435/MAX17535
when the voltage loop (CCV) is in control. The required
compensation network is a pole-zero pair formed with
CCC and RCC, which is an internal 1.7kI. The pole is
necessary to roll off the voltage loop’s response at low
frequency; CCC = 330pF is sufficient for most applications.
MOSFET Drivers
The DHI and DLO outputs are optimized for driving
moderate-sized power MOSFETs. The MOSFET drive
capability is the same for both the low-side and high-
sides 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.
There must be a low-resistance, low-inductance path
from the DLO driver to the MOSFET gate to prevent shoot-
through. Otherwise, the sense circuitry in the MAX17435/
MAX17535 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 50ns (typ)
delay time to prevent the low-side MOSFET from turning
on until DHI is fully off. The same considerations should be
used for routing the DHI signal to the high-side MOSFET.
Figure 6. CC Loop Diagram
CCC
COUT
RCC
RLRESR
ROGMV
CC
BATT
gMV
REF
GM(OUT)
High-Frequency,
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MAX17435/MAX17535
______________________________________________________________________________________ 25
The high-side driver (DHI) swings from LX to 5V above LX
(BST) and has a typical impedance of 1.5I sourcing and
0.8I sinking. The low-side driver (DLO) swings from DLOV
to ground and has a typical impedance of 3I sinking and
3I sourcing. 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 MOSFETs that can be
used. Using a low-side MOSFET with smaller gate-to-drain
capacitance can prevent these problems.
Design Procedure
MOSFET Selection
Choose the n-channel MOSFETs according to the maxi-
mum required charge current. Low-current applications
usually require less attention. The high-side MOSFET
(N1) must be able to dissipate the resistive losses plus
the switching losses at both VDCI(MIN) and VDCIN(MAX).
Calculate both these sums.
Ideally, the losses at VDCIN(MIN) should be roughly equal
to losses at VDCIN(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 N1.
Conversely, if the losses at VDCIN(MAX) are significantly
higher than the losses at VIN(MIN), consider reducing the
size of N1. 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 moderate-sized package (i.e., one
or two 8-pin SO, DPAK, or D2 PAK), 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. Select devices
that have short turn-off times, and make sure that:
N2(tDOFF(MAX)) - N1(tDON(MIN)) < 40ns, and
N1(tDOFF(MAX)) - N2(tDON(MIN)) < 40ns
Failure to do so could result in efficiency-reducing shoot-
through currents.
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:
LOAD
BATT DS(ON)
DCIN
2
I
V
PD(High - side) R
V 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 (RDS(ON)) losses. 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 high-side MOSFET that was chosen
for adequate RDS(ON) at low supply voltages becomes
extraordinarily hot when subjected to VIN(MAX), then
choose a MOSFET with lower losses. Calculating the
power dissipation in N1 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 PCB 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 N1:
2
DCIN(MAX) RSS SW LOAD
GATE
V C f I
PD(HS_Switching) 2 I
× × ×
=×
where CRSS is the reverse transfer capacitance of N1
and IGATE is the peak gate-drive source/sink current
(3.3A sourcing and 5A sinking).
For the low-side MOSFET (N2), the worst-case power
dissipation always occurs at maximum input voltage:
LOAD
BATT DS(ON)
DCIN
2
I
V
PD(Low - side) 1- R
V 2
= ×
Inductor Selection
The charge current, ripple, and operating frequency
(off-time) determine the inductor characteristics. For
optimum efficiency, choose the inductance according to
the following equation:
L = VBATT O tOFF/(0.3 x ICHG)
This sets the ripple current to 1/3 the charge current and
results in a good balance between inductor size and
efficiency. Higher inductor values decrease the ripple
current. Smaller inductor values require high saturation
current capabilities and degrade efficiency.
Due to the minimum tOFF blanking effect upon zero-
crossing detection, higher inductor values are desired for
proper operation for a design with low input voltage and
high output voltage, especially for MAX17535.
High-Frequency,
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MAX17435/MAX17535
26 _____________________________________________________________________________________
Inductor L1 must have a saturation current rating of at
least the maximum charge current plus 1/2 the ripple
current (DIL):
ISAT = ICHG + (1/2) DIL
The ripple current is determined by:
DIL = VBATT O tOFF/L
where:
tOFF = 2.5Fs (VDCIN - VBATT)/
VDCIN for VBATT < 0.88 VDCIN
or:
tOFF = 0.3Fs for VBATT > 0.88 VDCIN
Input Capacitor Selection
The input capacitor must meet the ripple current
requirement (IRMS) imposed by the switching currents.
Nontantalum chemistries (ceramic, aluminum, or
OS-CON) are preferred due to their resilience to power-
up surge currents:
( )
BATT DCIN BATT
RMS CHG DCIN
V V - V
I I V
=
The input capacitors should be sized so that the
temperature rise due to ripple current in continuous
conduction does not exceed approximately 10NC. The
maximum ripple current occurs at 50% duty factor or
VDCIN = 2 x VBATT, which equates to 0.5 x 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.
As such, both capacitance and ESR are important
parameters in specifying the output capacitor as a filter
and to the ensure stability of the DC-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. For most
applications the output capacitance can be as low as
4.7FF. If the output voltage is low and the input voltage is
high, the output capacitance may need to be increased.
Applications Information
Layout and Bypassing
Bypass DCIN with a 0.1FF ceramic to ground (Figure 1).
N3 and Q1A protect the MAX17435/MAX17535 when the
DC power source input is reversed. Bypass VCC, DCIN,
LDO, and VAA, as shown in Figure 1.
Good PCB layout is required to achieve specified noise
immunity, efficiency, and stable performance. The
PCB layout artist must be given explicit instructions—
preferably, a sketch showing the placement of the power
switching components and high current routing. Refer
to the PCB layout in the MAX17435 and MAX17535
Evaluation Kits 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:
U Minimize the current-sense resistor trace lengths,
and ensure accurate current sensing with Kelvin
connections.
U Minimize ground trace lengths in the high-current
paths.
U Minimize other trace lengths in the high-current
paths.
U Use > 5mm wide traces in the high-current paths.
U Connect C1 and C2 to high-side MOSFET (10mm
max length).
U Minimize the LX node (MOSFETs, rectifier cathode,
inductor (15mm max length). Keep LX on one side
of the PCB to reduce EMI radiation.
High-Frequency,
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MAX17435/MAX17535
______________________________________________________________________________________ 27
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 a wide, filled zone of
top-layer copper, so they do not go through vias. The
resulting top-layer subground plane is connected to
the normal inner-layer ground plane at the paddle.
Other high-current paths should also be minimized,
but focusing primarily on short ground and current-
sense connections eliminates about 90% of all PCB
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 VAA
capacitor). Important: The IC must be no further
than 10mm from the current-sense resistors. Quiet
connections to VAA, CC, 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).
4) Place ceramic bypass capacitors close to the IC. The
bulk capacitors can be placed further away. Place the
current-sense input filter capacitors under the part,
connected directly to the GND pin.
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.
Refer to the MAX17435 and MAX17535 Evaluation Kit
layouts for a layout example.
Chip Information
PROCESS: BiCMOS
Package Information
For the latest package outline information and land patterns,
go to www.maxim-ic.com/packages. Note that a “+”, “#”, or
“-” in the package code indicates RoHS status only. Package
drawings may show a different suffix character, but the drawing
pertains to the package regardless of RoHS status.
PACKAGE
TYPE
PACKAGE
CODE
OUTLINE
NO.
LAND
PATTERN NO.
24 TQFN-EP T2444+3 21-0139 90-0021
High-Frequency,
Low-Cost SMBus Chargers
MAX17435/MAX17535
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.
28 Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600
© 2010 Maxim Integrated Products Maxim is a registered trademark of Maxim Integrated Products, Inc.
Revision History
REVISION
NUMBER
REVISION
DATE DESCRIPTION PAGES
CHANGED
0 7/09 Initial release
1 9/10 Removed the MAX17035 from the data sheet.1–28