MAX2003ACPE - Maxim Integrated Products, Inc.

_______________General Description

The MAX2003/MAX2003A are fast-charge battery charg-

ers (with conditioning) for NiCd (nickel cadmium) or

NiMH (nickel-metal hydride) rechargeable batteries. The

MAX2003A has the same features as the MAX2003 with

an additional pulsed trickle-charge mode to prevent den-

drite formation in NiMH batteries. Each can be config-

ured as a switch-mode current regulator or as a gating

controller for an external current source. Switch-mode

current regulation provides efficient energy transfer,

reducing power dissipation and the associated heating.

Gating control of an external current source requires

minimal components, saving space and cost.

On-chip algorithms determine charge termination, so the

MAX2003/MAX2003A can be used as stand-alone

chargers. Fast-charge termination is accomplished by

five methods: temperature slope, negative voltage

change, maximum temperature, maximum time, and

maximum voltage. As a safety feature, the start of fast-

charge is inhibited until battery voltage and temperature

are within safe limits. By selecting the appropriate

charge-termination method, a single circuit can be built

with the MAX2003/MAX2003A to fast-charge both NiMH

and NiCd batteries.

The MAX2003/MAX2003A provide a switch-activated

discharge-before-charge option that allows for battery

conditioning and more accurate capacity measure-

ment. Other features include optional top-off charging

and direct drivers for LED status lights.

The MAX2003, in DIP and wide SO packages, is a direct

plug-in replacement for the bq2003. The MAX2003/

MAX2003A also come in a space-saving narrow SO

package. The MAX2003A evaluation kit (MAX2003A

EVKIT-SO) is available to assist in designs.

________________________Applications

Battery-Powered Equipment:

Laptop, Notebook, and Palmtop Computers

Handy-Terminals

Portable Consumer Products:

Portable Stereos

Cordless Phones

Backup-Battery Applications:

Memory Hold-Up

Emergency Switchovers

____________________________Features

♦Stand-Alone NiCd or NiMH Fast Chargers

♦New Pulsed Trickle-Charge Mode (MAX2003A only)

♦Provide Switch-Mode, Gated, or Linear Control

Regulation

♦Small, Narrow SO Package Available

♦On-Chip Fast-Charge Termination Methods:

• Temperature Slope • Maximum Voltage

• Negative Delta Voltage • Maximum Time

• Maximum Temperature

♦Automatically Switch from Fast-Charge to

Trickle-Charge or Top-Off Charge

♦Optional Discharge-Before-Charge

♦Directly Drive Status LEDs

♦Optional Top-Off Charge

MAX2003/MAX2003A

NiCd/NiMH Battery Fast-Charge Controllers

________________________________________________________________

Maxim Integrated Products

For free samples & the latest literature: http://www.maxim-ic.com, or phone 1-800-998-8800

19-0371; Rev 2; 7/96

PART

MAX2003CPE

MAX2003CSE 0°C to +70°C

0°C to +70°C

TEMP. RANGE PIN-PACKAGE

16 Plastic DIP

16 Narrow SO

__________________Pin Configuration

VCC

DIS

MOD

CHG

TM1

DVEN

DCMD

CCMD

TOP VIEW

MAX2003

MAX2003A

TEMP

MCV

TCO

SNS

VSS

BAT

TM2

DIP/SO

MAX2003CWE

MAX2003C/D 0°C to +70°C

0°C to +70°C 16 Wide SO

Dice*

* Contact factory for dice specifications.

EVALUATION KIT MANUAL

FOLLOWS DATA SHEET

MAX2003ACPE

MAX2003ACSE

MAX2003ACWE

MAX2003AC/D

0°C to +70°C

0°C to +70°C 16 Plastic DIP

16 Narrow SO

0°C to +70°C

0°C to +70°C 16 Wide SO

Dice*

______________Ordering Information

MAX2003/MAX2003A

NiCd/NiMH Battery Fast-Charge Controllers

2 _______________________________________________________________________________________

ABSOLUTE MAXIMUM RATINGS

ELECTRICAL CHARACTERISTICS

(VCC = 4.5V to 5.5V, Figure 1, all measurements are with respect to VSS, TA= TMIN to TMAX, unless otherwise noted.)

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.

All Pins to VSS...........................................................-0.3V, +6.0V

Continuous Power Dissipation (TA= +70°C)

Plastic DIP (derate 10.53mW/°C above +70°C) ...........842mW

Narrow SO (derate 8.70mW/°C above +70°C) .............696mW

Wide SO (derate 9.52mW/°C above +70°C).................762mW

Operating Temperature Range...............................0°C to +70°C

Storage Temperature Range.............................-65°C to +150°C

Lead Temperature (soldering, 10sec).............................+300°C

VBAT - VSNS

No load

VCC = 5V

VCC = 5V, VTCO = 1.4V

VCC = 5V

VTS - VSNS

VCC = 5V

CONDITIONS

mV16VTHERM

Thermistor Input Resolution

(Note 2)

mV12-∆V

Negative Delta Voltage

(Note 2)

mV30

VSNSHI -

VSNSLO

Delta Sense Voltage

(Note 1)

0.044VCC - 25mV 0.044VCC + 25mV

0.044VCC

VSNSLO

Sense Trip Threshold Low

0.05VCC - 25mV 0.05VCC + 25mV

0.05VCC

VSNSHI

Sense Trip Threshold High

V0.0 VCC

VCELL

Cell Potential mA0.75 2.2ICC

V4.5 5.0 5.5VCC

Supply Voltage

Supply Current

(VLTF/8) (VLTF/8) (VLTF/8)

+ (7VTCO/8) + 7VTCO/8 + (7VTCO/8)

- 30mV + 30mV

VHTF

High-Temperature

Trip Threshold

VVLTF - 0.2VCC VLTF

VTCO

Temperature Cutoff Voltage

0.4VCC - 30mV 0.4VCC + 30mV

0.4VCC

VLTF

Low-Temperature

Trip Threshold

VVEDV VEDV + 0.2VCC

VMCV

Maximum Cell Voltage

V0.0 VCC

VBAT

Battery Voltage Input V0.0 VCC

VTEMP

Temperature Potential

V0.0 VCC

VTS

Temperature Sense

Input Voltage

UNITSMIN TYP MAXSYMBOLPARAMETER

VCC = 5V V

0.2VCC - 30mV 0.2VCC + 30mV

0.2VCC

VEDV

End-of-Discharge Voltage

MAX2003/MAX2003A

NiCd/NiMH Battery Fast-Charge Controllers

_______________________________________________________________________________________ 3

ELECTRICAL CHARACTERISTICS (continued)

(VCC = 4.5V to 5.5V, Figure 1, all measurements are with respect to VSS, TA= TMIN to TMAX, unless otherwise noted.)

TIMING CHARACTERISTICS

(VCC = 4.5V to 5.5V, Figure 1, all measurements are with respect to VSS, TA= TMIN to TMAX, unless otherwise noted. Typical values

are at VCC = 5.0V, TA= +25°C.)

Note 3: Ratio of actual versus expected timeout (see Table 4). Tested with TM1 = TM2 = floating.

Note 4: To recognize a battery insert signal, VBAT must be greater than VMCV for at least tBTO.

MOD pin in fast-charge mode, VCC = 5V

(Note 3)

CCMD, DCMD CONDITIONS

kHz100fMAX

MOD Switching Frequency 0.84 1.00 1.16 µs1.0tMPW

Minimum Pulse Width

Variation of Fast-Charge Timeout

UNITSMIN TYP MAXSYMBOLPARAMETER

CCMD, DCMD,

DVEN at VCC and VSS

CCMD, DCMD, DVEN

TM1, TM2 = VCC

TM1, TM2 = VSS

For DIS, TEMP and CHG,

0mA ≤ILOAD ≤5mA; For MOD,

0mA ≤ILOAD ≤10mA

µA-1.0 1.0ILKG

Input Logic Leakage

1.0

VCC - 1.0

VIH

Input Logic Voltage High

µA-70.0IIH

Input Logic Current High µA70.0IIL

Input Logic Current Low

VVCC - 0.5VOH

Logic-High Threshold

TM1, TM2 = tri-state

BAT, MCV, TCO, SNS, TS µA-2.0 2.0IIZ

Input Logic Current High-Z MΩ50Input Impedance

TM1, TM2 V

VCC - 0.3

TM1, TM2 V

0.3

VIL

Input Logic Voltage Low

ms200 250 300tBTO

Battery Replacement Timeout

(Note 4)

Note 1: The sense trip levels are determined by an internal resistor divider network that provides a typical difference of 30mV from

SNSHI to SNSLO. Slight variation in this delta is seen if there is a resistor mismatch in the network.

Note 2: Typical variations of Negative Delta Voltage and Thermistor Input Resolution parameters are less than ±4mV.

For DIS, TEMP and CHG,

0mA ≤ILOAD ≤5mA; For MOD,

0mA ≤ILOAD ≤10mA V0.5VOL

Logic-Low Threshold

CONDITIONS UNITSMIN TYP MAXSYMBOLPARAMETER

MAX2003/MAX2003A

NiCd/NiMH Battery Fast-Charge Controllers

4 _______________________________________________________________________________________

______________________________________________________________Pin Description

NAME FUNCTION

1CCMD Charge-Enabled Mode Input—initiates fast-charge on a digital signal (see

Detailed Description

for operating

conditions).

2 DCMD Discharge-Enable Mode Input—initiates discharge-before-charge on a digital signal (see

Detailed

Description

for operating conditions).

3 DVEN Negative Delta Voltage (-∆V) Enable Input—enables -∆V charge-termination mode. If DVEN is high, the con-

troller uses negative-voltage change detection to terminate charge. If DVEN is low, this mode is disabled.

4, 5 TM1,

TM2 These inputs are used to program the fast-charge and hold-off times, and to enable the top-off charge

mode. The inputs can be high, low, or floating. See Table 4 for details.

9 SNS Current-Sense Input—connected to the negative battery terminal. TS and BAT are referenced to this pin.

The voltage at SNS is directly proportional to the current through the battery and is used to determine how

and when MOD switches.

8 VSS Ground

7 BAT Input Voltage of Single Battery Cell. If more than one cell is present, a resistor divider is needed to divide the

voltage down to a single cell voltage.

6 TS Temperature Sense-Voltage Input from external thermistor. The thermistor temperature coefficient is nega-

tive, so the higher the temperature, the lower the voltage at this pin (See

Detailed Description

for conditions

of operation).

14 MOD Modulation Output. This push/pull output switches to enable or disable charging current. If MOD is high,

current is enabled. If it is low, current is disabled. For a 5V supply, if the voltage at the SNS pin is less than

220mV, MOD is high. If the voltage is above 250mV, MOD is low.

13 CHG Charge Status Output. This push/pull LED driver indicates charge status (see

Detailed Description

12 TEMP Temperature Status Output. This push/pull LED driver indicates that the temperature is outside the accept-

able limits, and fast-charge and top-off are inhibited (see

Maximum Temperature Termination

section in

Detailed Description

11 MCV Maximum Cell Voltage Input. If the voltage from BAT to SNS exceeds the voltage at MCV, fast or top-off

charging is terminated.

10 TCO Temperature Cutoff-Voltage Input. If the voltage from TS to SNS is less than the voltage at TCO, a hot ther-

mistor (negative coefficient) is detected and fast or top-off charging is terminated.

16 VCC Power-Supply Voltage Input (+5V nominal). Bypass with a 0.1µF capacitor placed close to the device.

15 DIS Discharge-Switch Control Output. This push/pull output turns on the FET that discharges the battery.

MAX2003/MAX2003A

NiCd/NiMH Battery Fast-Charge Controllers

_______________________________________________________________________________________ 5

MAX2003

MAX2003A

MOD

R1

60.4k

100k

R2

3.48k

R3

33.2k

13V/2A

DC SOURCE

RTR

10k

(*150Ω (2W))

*TRICKLE-CHARGE

RATE

C/40

1N5822

0.1µF

1, 3, 5 2, 4, 6

10V ZENER

Q1

P

MMDF3P03HD 100µH

1N5819

RB1

100k

RB2 

20k

RSNS 

0.14Ω

1%

(1W)

1700mAh

6 NiMH

RDIS 

4Ω (20W)

NTC

100k

DISCHARGE

RATE

CHARGE

RATE

CT

0.1µF

1µF

10k

CB

0.1µF

TO VCC

RT1

RT2 



DURACELL DR17

Q2

N

MMSF5NO3HD

* COMPONENT USED FOR MAX2003.

8, 10, 12

9, 11, 13

DIS

SNS

BAT

VSS

VCC

TM2

PUSH TO

DISCHARGE

TM1

DCMD

TEMP

CHG

MCV

TC0

LED

CCMD

DVEN

74HC04

LM317

243Ω

22µF

22µF732Ω

ADJ

5V OUT

0.1µF

Figure 1. Switched-Mode Operation for NiMH Batteries with

∆

t Termination

MAX2003/MAX2003A

NiCd/NiMH Battery Fast-Charge Controllers

6 _______________________________________________________________________________________

_______________Detailed Description

The MAX2003/MAX2003A is a fast-charge battery charg-

er that uses several methods of charge termination. The

device constantly monitors your choice of the following

conditions to determine termination of fast-charge:

•Negative Delta Voltage (-∆V)

•Rate-of-Change of Temperature (∆T/∆t)

•Maximum Voltage

•Maximum Time

•Maximum Temperature

Figure 2 shows the block diagram for the MAX2003/

MAX2003A.

The first step in creating a fast-charge battery-charger

circuit is to determine what type of battery will be used

and what conditions the battery manufacturer recom-

mends for termination of fast-charge. The type of bat-

tery (NiCd or NiMH) and charge rate determine which

method(s) of termination should be used.

The charging characteristics of NiMH batteries are simi-

lar to those of NiCd batteries, but there are some key dif-

ferences that affect the choice of charge-termination

method. Since the type of charge termination can be dif-

ferent for NiCd and NiMH batteries, it may not always be

possible to use the same circuit for both battery types.

A comparison of the voltage profiles for NiCd and NiMH

batteries (shown in Figure 3) reveals that NiCd batteries

display a larger negative drop in voltage at the end of

charge than do NiMH batteries. Therefore, the negative

delta voltage detection (-∆V) method of terminating

fast-charge should only be used for NiCd batteries.

This termination method can cause errors in NiMH bat-

teries, since the drop in voltage at full capacity is not as

great, and may lead to an overcharged battery.

Figure 4 shows the temperature profiles of the two

types of batteries. During the first 80% of the charge

cycle, the NiCd battery temperature slowly rises. The

NiMH battery temperature rises more rapidly during this

period. As the cells approach 90% of capacity, the

temperature of the NiCd cells rises more rapidly. When

the cells approach full capacity, the rates-of-rise of

temperature are comparable for both battery types. The

rate of temperature change (∆T/∆t) can therefore be

used to terminate fast-charge for both NiCd and NiMH

batteries; fast-charge is terminated when the rate of

temperature rise exceeds a preset rate.

Table 1 provides some guidelines to help in the selection of

the proper fast-charge termination method, but the manu-

facturer’s recommendations take priority in case of conflict.

Figure 1 shows a standard application circuit for a

switched-mode battery charger that charges NiMH bat-

teries at a rate of C. Though this circuit is shown for

NiMH batteries, it can be used for NiCd batteries (see

Table 1b). The description below will use this standard

application to explain, in detail, the functionality of the

MAX2003/MAX2003A.

Battery Sense Voltage

The BAT pin measures the per-cell voltage of the bat-

tery pack; this voltage is used to determine fast-charge

initiation and termination. The voltage is determined by

the resistor-divider combination RB1 and RB2, shown in

Figure 1, where:

Total Number of Cells = (RB1 / RB2) + 1

Since BAT has extremely high input impedance (50MΩ

minimum), reasonable values can be selected for resis-

tors RB1 and RB2. These values, however, must not be

low enough to drain the battery or high enough to

unduly lengthen the time constant of the signal going to

the BAT pin. The total resistance value from the positive

to negative terminal of the battery (RB1 + RB2) should

be between 100kΩand 500kΩto prevent these prob-

lems.

A simple RC lowpass filter (RB, CB) may be needed to

give a more accurate reading by removing any noise

that may be present. Remember that the RC time delay

from the cell to BAT must not exceed 200ms or the bat-

tery detection logic might not function properly (RBx

CB< 200ms).

Table 1a. Fast-Charge Termination

Methods for NiMH Batteries

Table 1b. Fast-Charge Termination

Methods for NiCd Batteries

Yes

Max

Temp.

Yes

Max

Time

Yes

Max

Voltage

Charge

Rate

NoYes>C/2

Negative

∆V

∆T/∆t

Yes

Max

Temp.

Yes

Max

Time

Yes

Max

Voltage

Charge

Rate

YesYes>2C

Negative

∆V

∆T/∆t

2C to

C/2 * * Yes Yes Yes

* Use one or both of these termination methods.

MAX2003/MAX2003A

NiCd/NiMH Battery Fast-Charge Controllers

_______________________________________________________________________________________ 7

MAX2003

MAX2003A

CHARGE

CONTROL

STATE

MACHINE

A/D

DISCHARGE 

CONTROL

DISPLAY 

CONTROL

TEMP

CHG

CCMD

DCMD

DVEN

TIMING

CONTROL LTF

CHECK TCO

CHECK

OSC

TM1 TM2 VCC

DIS MOD VSS

MOD

CONTROL EDV 

CHECK MCV

CHECK

(VTS - VSNS)

TCO

SNS

BAT

MCV

(VBAT - VSNS)

–

Figure 2. Block Diagram

0.8 0 120

1.0

1.6

1.8

2.0

MAX2003-03

CHARGE CAPACITY (% OF MAXIMUM)

VOLTAGE/CELL (V)

40 6020 80 100

1.4

1.2

NiCd

NiMH

Figure 3. Voltage-Charge Characteristics of NiCd and NiMH

Batteries

15 0 120

MAX2003-04

CHARGE CAPACITY (% OF MAXIMUM)

TEMPERATURE (°C)

40 6020 80 100

30 NiCd

NiMH

Figure 4. Temperature-Charge Characteristics of NiCd and

NiMH Batteries

MAX2003/MAX2003A

Temperature Measurement

The MAX2003/MAX2003A employs a negative tempera-

ture-coefficient (NTC) thermistor to measure the bat-

tery’s temperature. This temperature value can be used

to determine start and termination of fast-charge. The

two temperature conditions that can be used for fast-

charge termination are:

•Maximum Temperature

•Rate-of-Change of Temperature (∆T/∆t)

Figure 5 shows the various temperature cutoff points and

the typical voltages that the device will see at the TS pin.

VLTF (low-temperature fault voltage) refers to the volt-

age at TS when the battery temperature is too low, and

VHTF (high-temperature fault voltage) refers to the high-

temperature cutoff. If the voltage is outside these limits,

the MAX2003/MAX2003A will not enter fast-charge

mode. After fast-charge is initiated, the termination

point for high-temperature termination is VTCO (temper-

ature cutoff voltage), rather than VHTF. See Figure 5 for

TEMP LED status.

VLTF is set internally at 0.4VCC, so (with a 5V supply)

VLTF is 2V. VTCO is set up using external resistors to

determine the high-temperature cutoff after fast-charge

begins. VHTF is internally set to be (VLTF - VTCO) / 8

above VTCO.

Thermistors are inherently nonlinear with respect to

temperature. This nonlinearity is especially noticed

when ∆T/∆t measurements are made to determine

charge termination. The simplest way around this is to

place a resistor-divider network in parallel with the ther-

mistor (Figure 6) to reduce the effects of nonlinearity.

The lowpass filter (RT, CT) placed on the TS pin attenu-

ates high-frequency noise on the signal seen by TS.

Charge Pending

Before fast-charge is initiated, the cell voltage and tem-

perature of the battery pack must be within the

assigned limits. If the voltage or temperature is outside

these limits, the device is said to be in a “charge-pend-

ing” state. During this mode, the CHG pin will cycle low

(LED on) for 0.125sec and high (LED off) for 1.375sec.

Fast-charge is normally initiated if the cell voltage is

greater than VEDV (end-of-discharge voltage). If the cell

voltage is too low (below VEDV), the device waits until

the trickle current brings the voltage up before fast-

charge is initiated. VEDV is set internally at 0.2VCC, so

(for a 5V supply) VEDV is 1V.

If the temperature of the cell is not between VLTF and

VHTF the device is also in a charge-pending state (see

Temperature Measurement

section).

Initiate Fast-Charge

If the MAX2003/MAX2003A are out of the charge-pend-

ing state, fast-charge can be initiated upon one of the

following conditions:

•Battery Replacement

•Applying Power to the MAX2003/MAX2003A

(battery already present)

•Digital Control Signal

During fast-charge, the CHG pin will be continuously

low (LED on). For the initial period of fast-charge (the

hold-off time), the voltage charge-termination methods

are disabled. The hold-off time is a function of the

charge rate selected by TM1 and TM2 (see Table 4).

NiCd/NiMH Battery Fast-Charge Controllers

8 _______________________________________________________________________________________

VCC = 5V

VLTF - VTCO

VLTF = 0.4VCC

1/8 (VLTF - VTCO)

7/8 (VLTF - VTCO)

VHTF

VTCO

VSS = 0V

OFF

TEMP LED

STATUS

Figure 5. Temperature Measurement Scale

RC FILTER

100k

VCC

CT

0.1µF

NTC

SNS

RT2

RT1

MAX2003

MAX2003A

Figure 6. Thermistor Configuration for Temperature Measurement

Battery Replacement

Before a battery is inserted, the BAT pin is pulled high-

er than the maximum cell voltage (MCV) by the resistor

(RTR) and the divider network (RB1/RB2) (Figure 1).

When the battery is inserted, the voltage per cell at BAT

falls from the default voltage to the battery voltage.

Fast-charge is initiated on a falling edge when the BAT

voltage crosses the voltage on MCV.

Applying Power to the MAX2003/MAX2003A

(battery already present)

There may be some cases where a battery is connect-

ed before power is applied to the MAX2003/

MAX2003A. When power is applied, the device goes

into reset mode for approximately 1.5sec and then

samples the CCMD and DCMD pins. Its charge status

is determined by the voltage at both the CCMD and

DCMD pins. Table 2 summarizes the various conditions

the MAX2003/MAX2003A might see on power-up.

Table 2 shows that the MAX2003/MAX2003A can be

set-up for fast-charge on power-up by making sure

CCMD and DCMD are at the same potential. If fast-

charge on power-up is not desired, make sure CCMD

and DCMD are at different logic levels during power-

up, and use a digital signal to control fast-charge (see

Digital Control

section).

Digital Control

The CCMD pin can be used to initiate fast-charge. This is

useful when neither the power supply nor the battery can

be removed from the charger. The CCMD signal needed

to initiate fast-charge depends on the potential at DCMD.

If DCMD is low, a rising edge on CCMD initiates fast-

charge. If DCMD is high, a falling edge on CCMD pro-

vides the fast-charge signal. Table 3 summarizes the

conditions used to start fast-charge.

Discharge-Before-Charge (optional)

The discharge-before-charge function is optional and

can be used to condition old batteries. It is especially

useful in NiCd batteries, since it alleviates the voltage

depression problems associated with partially dis-

charged NiCd cells. The discharge-before-charge

function is initiated by a rising edge into DCMD.

When the digital signal is applied, the DIS pin will be

pulled high, turning on the attached circuit and dis-

charging its battery. The discharge process continues

until the single cell voltage drops below 0.2VCC. During

the discharge phase, the CHG pin will be low (LED on)

for 1.375sec and high (LED off) for 0.125sec.

The MAX2003/MAX2003A does not control the current

during discharge-before-charge. If the discharge rate

is too great, the battery could overheat and be dam-

aged. The battery manufacturer will be able to specify

a safe discharge rate, but a rate of C or slower is typi-

cally acceptable. It is also important to choose compo-

nents (Q2, RDIS) that are rated for that particular

discharge rate. Since the gate-source drive for Q2 can

be as low as 4.5V, use a logic-level MOSFET.

Fast-Charge Current

The fast-charge current can be generated using two

categories of circuits:

•Circuits with a sense resistor (RSNS)

•Circuits without sense resistor (SNS tied to VSS)

Circuits with SNS Resistor

The standard application circuit of Figure 1 uses an

inductor and a switched mode of operation to supply

the current. The charge current is determined by the

sense resistor placed between the negative terminal of

the battery (SNS) and ground (VSS).

The SNS pin is the input to a comparator with hystere-

sis. If the voltage at SNS drops below 0.044VCC, the

MOD pin is turned on. If the SNS voltage is above

0.050VCC, MOD is turned off. In the switched mode of

operation, the SNS voltage ramps between 0.044VCC

and 0.050VCC, which is 220mV and 250mV when VCC

MAX2003/MAX2003A

NiCd/NiMH Battery Fast-Charge Controllers

_______________________________________________________________________________________ 9

Table 2. Device Status on Power-Up if

Battery is Already Present Table 3. Digital Control of Fast-Charge

(VCC and battery present)

•The device does not enter fast-charge

immediately.

• Fast-charge is initiated by the rising

edge of a pulse on CCMD.

LowHigh

•Fast-charge is initiated on power-up.

HighHigh

•The device does not enter fast-charge

immediately.

•Fast-charge is initiated by the falling

edge of a pulse on CCMD.

HighLow

CCMD

•Fast-charge is initiated on power-up.

LowLow

MAX2003/MAX2003A Status when

Power is Applied

DCMD

•Fast-charge is initiated by a falling

edge on CCMD.

High

CCMD

•Fast-charge is initiated by a rising

edge on CCMD.

Low

CCMD Status to Initiate Fast-ChargeDCMD

MAX2003/MAX2003A

is 5V (Figure 7). The average voltage at SNS, therefore,

is 235mV, and can be used to calculate the charge cur-

rent as follows:ICHARGE = 0.235V / RSNS

where RSNS is the sense resistor and ICHARGE is the

charge current required.

Circuits without SNS Resistor

In some applications (shown later), SNS is tied directly

to ground. In these cases, the MOD pin remains on

until any one charge-termination condition is exceeded

(Figure 8). A reasonable external current limit (such as

a current-limited DC source) must be provided for

these applications, to prevent battery damage due to

excessive charge currents.

Charge Termination

The MAX2003 has several charge-termination methods.

The termination method selected depends on the type

of battery and charge rate used. Table 1 summarizes

the conditions used to terminate fast-charge with differ-

ent battery types and charge rates.

Temperature Rate Termination

The Temperature Rate Termination (∆T/∆t) method ter-

minates fast-charge when a particular rate-of-change in

temperature is exceeded. As the battery begins fast-

charge, its temperature increases at a slow rate. When

the battery nears full capacity, this rate of temperature

change increases. When the rate of temperature

change exceeds a preset number, fast-charge is termi-

nated. This method of fast-charge termination can be

used for both NiCd and NiMH batteries.

The MAX2003 samples the voltage at the TS pin every 34

seconds and compares it with a value taken 68 seconds

earlier. Since an NTC thermistor is used for temperature

measurements, a gradual rise in temperature will result in

successively lower voltage readings. If the new reading is

more than 0.0032VCC (16mV for VCC = 5V) below the old

reading, fast-charge is terminated.

The MAX2003A varies the sampling interval as a function

of charge rate (Table 4). As the charge rate increases,

the sampling interval decreases, thereby allowing more

accurate termination of fast charge.

Note: This method of charge termination is valid only

when the battery’s temperature is between VLTF and

VTCO (Figure 5).

NiCd/NiMH Battery Fast-Charge Controllers

10 ______________________________________________________________________________________

TIME

MOD

SNS

ILOAD

0.044

VCC

0.050

VCC

IBAT

FAST CHARGE FAST-CHARGE

TERMINATE

Figure 7. Current Regulation with an SNS Resistor

TIME

SNS = 0V

TIME

MOD

SNS

ILOAD

0.044

VCC

0.050

VCC

IBAT

FAST CHARGE FAST-CHARGE

TERMINATE

Figure 8. Current Regulation without an SNS Resistor

Negative Delta Voltage Termination

The Negative Delta Voltage Termination (-∆V) method

measures a negative delta voltage to determine termi-

nation of fast-charge. After maximum charge is

reached, the terminal voltage of NiCd batteries

declines significantly, whereas the terminal voltage of

NiMH batteries does not. Hence, the -∆V method of

fast-charge termination is suitable for NiCd batteries,

but not for NiMH batteries.

The MAX2003/MAX2003A sample the BAT pin every 34

seconds and compare it with all previous values. If the

new value is less than any of the previous values by

more than 12mV, a negative delta voltage has been

detected and fast-charge is terminated.

Note: This method of charge termination is valid only

when the voltage at BAT is between VMCV and VMCV -

0.2VCC.

The -∆V method is inhibited during the hold-off time to

prevent false termination of fast-charge. The hold-off

time depends on the charge rate used, and is selected

by the inputs TM1 and TM2 (as shown in Table 4). After

the hold-off time has expired, the device begins to

monitor BAT for a voltage drop.

Maximum Temperature Termination

The Maximum Temperature Termination method is used

as a safety net to prevent problems, and should never

be needed under normal operation of the charger. The

maximum temperature that the battery can reach during

fast-charge has a corresponding voltage—the tempera-

ture cutoff voltage (VTCO), as seen in Figure 5. This volt-

age is set externally at the TCO pin using a resistor

divider from VCC. Although rarely experienced, an

excessively low temperature will also terminate fast-

charge. The minimum temperature is the low tempera-

ture fault (VLTF). This value is internally set at 0.4VCC.

When the thermistor exceeds these temperature limits,

fast-charge is terminated. The thermistor configuration

shown in Figure 5 is used to measure the battery’s tem-

perature and scale it to operate from VLTF to VTCO.

Resistors RT1 and RT2 are calculated to provide the

required cutoff at VTCO. See the

Design Guide

section

for a detailed design example.

Maximum Voltage Termination

The Maximum Voltage Termination method is another

safety feature designed to work if something is drastically

wrong. Under normal operation of the charger, this condi-

tion should only be reached when the battery is removed.

The maximum cell voltage expected is applied at the

MCV pin using a resistor-divider network. If the cell volt-

age measured at BAT exceeds that at MCV, fast-

charge is terminated. For most applications using both

NiCd and NiMH batteries, this voltage (VMCV) can be

set to 1.9V.

The MAX2003/MAX2003A do not terminate fast-charge

if the maximum voltage is reached before the hold-off

time has expired. If the cell voltage is greater than the

MCV during the hold-off time, the device will continue

fast-charge until the hold-off time has expired, and then

it will terminate fast-charge. The hold-off time is deter-

mined by the inputs TM1 and TM2, as shown in Table 4.

Maximum Timeout Termination

The final method is Maximum Timeout Termination,

which (like the maximum voltage and maximum tem-

perature methods) is another backup safety feature.

The timeout time depends on the charge rate selected

and is set by the control signals TM1 and TM2. Table 4

shows a list of different timeout periods available for dif-

ferent control-signal inputs. If the timeout is reached

before any other termination method is seen, fast-

charge is terminated to protect the charger and battery.

Top-Off Charge

Top-off charge is used to provide the last bit of charge

needed to reach full capacity after fast-charge is termi-

nated. Top-off charging puts slightly more energy into

the battery than simple trickle charging, and can be

used for both NiCd and NiMH batteries. Select it by

choosing the appropriate control signals on TM1 and

TM2 (Table 4).

MAX2003/MAX2003A

NiCd/NiMH Battery Fast-Charge Controllers

______________________________________________________________________________________ 11

*Enable100234CVCC

VCC

Disable10023

*Enable41090

*Enable200452CVCC

Open

CVCC

GND

*Enable820180C/2OpenVCC

4COpenOpen

Disable41090

Disable200452COpenGND

CGNDVCC

Disable820180C/2GNDOpen

Disable

Top-Off

Charge

140

Hold-Off

Time

∆V/MCV

(sec)

360

Fast-

Charge

Timeout

(min)

TM1

C/4GNDGND

Fast-

Charge

Rate

TM2

Table 4. Programmable Inputs for

Timeout/Hold-Off/Fast-Charge/Top-Off/

Pulse Trickle (VCC = 5V)

0.5

Disable

MAX2003A

Trickle

Charge (s)

On/Off

* MAX2003 is on for 4sec and off for 30sec.

MAX2003A is on for 0.5sec and off for 3.5sec.

128

544

MAX2003A

Sampling

Interval

(sec)

544

136

544

136

MAX2003/MAX2003A

The top-off charge is done at 1/8 the fast-charge rate.

For the MAX2003, the MOD pin is activated in every 34

second period to supply current to the battery for 4

seconds (MOD oscillates for 4 seconds and stays low

for 30 seconds) (Figure 7). If external regulation is used

(SNS tied to ground), MOD stays high for 4 seconds

and low for 30 seconds (Figure 8). This top-off process

continues until the fast-charge timeout (Table 4) is

exceeded, or if a maximum temperature or maximum

voltage condition is detected. The MAX2003A is slightly

modified to turn the MOD pin on for 0.5sec in every 4

second period. This shorter on-time reduces battery

heat and increases charge acceptance. During the top-

off charge, the CHG pin will cycle low (LED on) for

0.125sec and high (LED off) for 0.125sec.

Trickle-Charge

A trickle-charge is applied to the battery after fast-

charge and top-off charge have terminated to compen-

sate for self discharge. There are two methods of trickle

charge: constant and pulsed.

Pulsed Trickle-Charge (MAX2003A)

The MAX2003A provides a pulsed trickle-charge to the

battery by turning on the MOD pin briefly during a fixed

period of time. The duty cycle of the pulse is a function of

the programmable inputs TM1 and TM2 (Table 4 ). The

MAX2003A does not use the trickle resistor to provide the

trickle charge. However, the trickle resistor cannot be

entirely omitted because it is also used for the battery-

detect circuitry.

Constant Trickle-Charge (MAX2003)

The MAX2003 provides a steady trickle-charge to the

battery by connecting a resistor from the DC supply to

the positive battery terminal. This resistor has a dual

purpose, in that it provides a trickle-charge and pulls

the BAT pin above the MCV when the battery is absent.

The trickle-charge rate depends on the type of battery

used. For NiCd batteries, a nominal trickle-charge rate

would be C/16, and NiMH batteries could use a rate of

C/40. The resistor value used depends on the maxi-

mum DC voltage and the typical battery voltage. For

example, a six-cell 800mAh NiCd pack with a nominal

voltage of 1.2V per cell would have a total voltage of

1.2V x 6V = 7.2V. If the DC supply voltage used is 14V,

the voltage across the trickle resistor would be 14.0V -

7.2V = 6.8V. The trickle current needed would be C/16

= 800 / 16 = 50mA. The trickle resistor would therefore

be RTR = 6.8V / 50mA ≈150Ω. Similar calculations

should be made for NiMH batteries using C/40 as the

trickle-charge rate.

If a trickle-charge is not needed, a higher value of trick-

le resistor (like 100kΩ) can be selected to sense the

battery insertion.

Charge Status

The CHG pin is connected to a LED that indicates the

operating mode. Table 5 summarizes the different

charge conditions.

_______________________Design Guide

Using the circuit of Figure 1 as an example, the follow-

ing nine steps show how to design a 1.7A switch-mode

fast-charger that can charge a Duracell DR17 (NiMH

six-cell battery pack with a 1700mAh capacity).

1) Select DC Power Supply. The first step is to select

the DC power supply (such as a wall cube). The mini-

mum supply voltage should have a supply equal to

about 2V per cell, plus 1V headroom for external cir-

cuitry ((2V/cell) + 1V). The minimum supply voltage

must be greater than 6V. If, as in our example, there

are six cells, a minimum supply of about 13V is needed

((6 cells x 2V) + 1V).

2) Determine Charge Rate. The charge rate, or fast-

charge current (IFAST), is determined by two factors:

the capacity of the battery, and the time in which the

user wants the battery to be charged. The battery man-

ufacturer recommends a maximum fast-charge rate,

which must not be exceeded.

Capacity of Battery (mAh)

IFAST (mA) = ————————————

Charge Time (h)

For example, if a 1700mAh battery needs to be charged in

two hours (C/2), a fast-charge current of at least 850mA is

needed. A charge rate of C/2 will ideally charge a battery

in two hours but, because of inefficiencies in a battery’s

chemical processes, the time could be 30% to 40% more.

Our example circuit (Figure 1) charges the Duracell bat-

tery pack at a C rate of 1.7A, which should fully charge a

discharged battery in approximately 80 minutes.

NiCd/NiMH Battery Fast-Charge Controllers

12 ______________________________________________________________________________________

Table 5. Charge Status

LED on for 0.125sec, off for

0.125sec

Charge Complete and Top-

Off

LED onFast-Charge

LED on for 1.375sec, off for

0.125sec

Discharge-Before-Charge

LED on for 0.125sec, off for

1.375sec

Charge Pending

Charge State LED offBattery Absent CHG LED Status

3) Select Sense Resistor. The sense resistor deter-

mines the rate at which the battery is fast-charged. The

sense pin, SNS, has an average voltage of 235mV (see

Detailed Description

) and, since the charge current

(IFAST) is known from above, the resistor can be calcu-

lated by: RSNS = VSNS / IFAST = 0.235 / IFAST

In this example, a fast-charge current of 1.7A requires

a sense resistor of about 0.14Ω(1 watt).

4) Select TM1 and TM2. Once the charge rate is

determined, Table 4 can be used to select the TM1 and

TM2 inputs. TM1 and TM2 set the safety timeout, hold-

off time, and top-off enable (see

Fast-Charge

Termination

section in the

Detailed Description

In Figure 1, a fast-charge rate of C with top-off would

require TM1 to be GND and TM2 to be VCC.

5) Select RB1 and RB2. The MAX2003A requires the

user to select RB1 and RB2 to indicate the number of

cells in the battery. The total resistance value (RB1 +

RB2) should be between 100kΩand 500kΩto prevent

any problems with noise. In Figure 1 (with six cells) RB1

is selected to be 100kΩand, from the following equation:

RB2 = RB1 / (Number of Cells - 1) = 100kΩ/ (6 - 1)

RB2 can be calculated to be 20kΩ.

6) Select Temperature-Control Components. Most

sealed rechargeable battery packs have a built-in ther-

mistor to prevent air currents from corrupting the accurate

temperature measurements. The thermistor size and tem-

perature characteristics can be obtained from the bat-

tery-pack manufacturer, to help in designing the rest of

the circuit. Three-terminal battery packs that incorporate

a thermistor generally share a common connection for the

thermistor and the battery negative terminal. Large charg-

ing currents may produce voltage drops across the com-

mon negative connector, causing errors in thermistor

readings. Using separate contacts for the thermistor

ground sense and the battery ground sense at the nega-

tive battery terminal will reduce these errors. If an external

thermistor is to be used, take care to ensure that it is

placed in direct contact with the battery, and that the bat-

tery/thermistor set-up is placed in a sealed container.

Neither NiCd nor NiMH batteries should be fast-

charged outside the maximum and minimum tempera-

ture limits. However, some applications also require

termination using the ∆T/∆t criterion. The resistors RT1

and RT2 (Figure 1) will determine the temperature cutoff

(VTCO) and the rate-of-change of temperature (∆T/∆t).

Though NiCd batteries do not always require termina-

tion using the ∆T/∆t feature, it is not possible to isolate

and disable this mode. It is therefore recommended

that NiCd and NiMH batteries use the same ∆T/∆t termi-

nation parameters.

The Duracell DR17 battery pack used in our example

circuit recommended a low fault temperature (VLTF) of

+10°C and a maximum temperature cutoff (VTCO) of

+50°C. These maximum temperature values will never

be reached in most cases, but are used as a safety net

to prevent battery damage. According to Duracell, the

10kΩthermistor inside the pack varies from 17.96kΩat

+10°C to 4.16kΩat +50°C.

The circuit in Figure 1 will be designed so that a battery

temperature change of 1°C/min will result in fast-charge

termination. At 1°C/min, the battery will take 40 minutes

to change 40°C (10°C to 50°C). Since a charge rate of

C is used for this example, Table 4 shows that the

MAX2003A samples the TS pin every 68 seconds and

compares it with a value taken 136 seconds earlier. The

device will terminate fast-charge if the voltage at TS

changes by more than 0.0032VCC (16mV for VCC =

5V). At a charge rate of 16mV every 136 seconds, the

TS pin will charge 280mV in 40 minutes (40min x

60sec/min x 16mV/136sec).

The low fault temperature (VLTF) is set internally at

0.4VCC, which is 2.0V for a supply of 5V. The tempera-

ture cutoff voltage (VTCO) will be 280mV below VLTF, or:

VTCO = (2.00V - 0.28V) = 1.72V

Figure 5 shows that, at any given temperature:

VTS = VCC (RT2 || RNTC) / [(RT2 || RNTC) + RT1]

When the battery temperature is +10°C, the voltage is:

VTS10 = VCC (RT2 || RNTC10) / [(RT2 || RNTC10) + RT1]

And at +50°C:

VTS50 = VCC (RT2 || RNTC50) / [(RT2 || RNTC50) + RT1]

MAX2003/MAX2003A

NiCd/NiMH Battery Fast-Charge Controllers

______________________________________________________________________________________ 13

VCC

MCV

TCO

Figure 9. Resistor Configuration for MCV and TCO

MAX2003/MAX2003A

From solving these simultaneous equations:

RT2 = [(X) (RNTC10) - (RNTC50)] / (1 - X)

RT1 = [(RT2) (RNTC10) (VCC - VTS10)] / [VTS10 (RT2 +

RNTC10)].

[(RNTC50)(VTS10)(VCC - VTS50)]

where X = _____________________________

[(RNTC10) (VTS50) (VCC - VTS10)]

Using RNTC50 = 4.16kΩ, RNTC10 = 17.96kΩ, VTS50 =

1.72V, and VTS10 = 2.00V, it can be calculated that RT1

= 1.599kΩand RT2 = 2.303kΩ.

Select preferred resistor values for RT1 (2.21kΩ) and

RT2 (1.62kΩ). The actual voltages on MCV and TCO

can be verified as follows:

7) Select Maximum Cell Voltage (MCV) and

Temperature Cutoff (TCO). The MCV and TCO can be

selected with a resistor-divider combination (Figure 9).

In our example, TCO has been set to +10°C, which cor-

responds to a voltage of 1.72V at the TS pin. The MCV

for most fast-charge batteries can be set to about 1.9V.

To minimize the current load on VCC, choose R1 in the

range of 20kΩto 200kΩ. In this example, choose R1 =

60.4kΩ, then calculate R3 and R2 as follows:

R3 = (VTCO x R1) / (VCC - VMCV) = 33.5kΩ(1%)

and

R2 = (VMCV x R1) / (VCC - VMCV) - R3 = 3.51kΩ(1%)

Select preferred resistor values for R2 (3.48kΩ) and R3

(33.2kΩ). The actual voltages on MCV and TCO can be

verified as follows :

VTCO = VCC (R3) / (R1 + R2 + R3) = 1.71V

and

VMCV = VCC (R2 + R3) / (R1 + R2 + R3) = 1.89V.

8) Select Trickle Resistor (MAX2003 only). The trick-

le resistor (RTR) is selected to allow a trickle-charge

rate of C/16 to C/40. The resistor value is given by:

RTR = (VDC - VBAT) / ITR

where ITR is the required trickle current, VDC is the DC

supply voltage, and VBAT is the number of cells times

the cell voltage after fast-charge.

In our example, the 1700mAh NiMH battery needs a

trickle current of C/40; i.e., 42mA (1700mAh/40h).

Therefore, the minimum voltage (from the formula

above) is as follows:

RTR = [13.0V - (6 x 1.2V)] / 42mA ≈150Ω

The maximum power dissipated in the resistor can be

calculated by:

Power = (VDC - VBAT(MIN))2/ RTR

where VBAT(MIN) is the minimum cell voltage, VDC is the

DC supply voltage, and RTR is the trickle resistor value.

Since a shorted battery could have 0V, this must be the

minimum cell voltage possible. Therefore the power

dissipated in the trickle resistor would be:

Power = (13 - 0)2/ 150 = 1.2W

A 2W, 150Ωresistor should be sufficient for the trickle-

charge resistor. For the MAX2003A, refer to

Trickle-

Charge

section.

9) Select Inductor. The inductor value can be calcu-

lated using the formula:

VL= L δi /δt

where VLis the maximum voltage across the inductor, L

is the minimum inductor value, δi is the change in induc-

tor current, and t is the minimum on-time of the switch.

V V R II R

R II R R

5 1.62k II 17.96k

1.62k II 17.96k 2.21k

2.01V

V V R II R

R II R R

5 1.62k II 4.16k

1.62k II 4.16k 2.21k

1.72V.

TS10 CC T2 NTC10

T2 NTC10 T1

TS50 CC T2 NTC50

T2 NTC50 T1

()

[]

ΩΩ

()

ΩΩ

()

+Ω

[]

()

[]

ΩΩ

()

ΩΩ

()

+Ω

[]

NiCd/NiMH Battery Fast-Charge Controllers

14 ______________________________________________________________________________________

ILOAD

IMAX = 1.9A

INDUCTOR

CURRENT

IMIN = 1.5A

TIME

δi = IMAX - IMIN

TOFF TON

Figure 10. Inductor-Current Waveform in Continuous-

Conduction Mode

In order to provide high currents with minimum ripple,

the device must function in the continuous-conduction

mode. Figure 10 shows a current waveform of an

inductor in the continuous-conduction mode (where the

coil current never falls to zero).

The average load current (ILOAD) through the inductor

must be 1.7A, so a peak current (IMAX) of 1.9A should

give a fairly low ripple while keeping the inductor size

minimal. This means that the total current change (Figure

10) across the inductor is δi = 2 (1.9 - 1.7) = 0.4A.

The maximum voltage across the inductor is present

when the battery voltage is at its minimum. The mini-

mum cell voltage at the start of fast-charge will be 1V

per cell, giving a battery voltage of 6V for 6 cells. The

maximum voltage (VL) across the inductor is therefore:

VL= (input voltage - minimum battery voltage)

The input voltage for this application is 13V, so the

maximum voltage is:

VL= (13V - 6V) = 7V

The minimum on-time δt of the switch is given by:

δt = (VOUT / VIN ) x PERIOD

where VOUT is the minimum battery voltage, VIN is the

maximum input voltage, and PERIOD is the period of

the switching signal.

The maximum input voltage for this application will be

14V, and the maximum allowed switching frequency of

100kHz gives a period of 10µs. The minimum on-time

will therefore be:

δt = (VOUT / VIN ) x PERIOD = (6V / 13V) x 10µs = 4.62µs

The inductor value can be calculated from:

L = V δt / δi = (7V x 4.62µs) / 0.4A = 81µH.

If this inductor value is used, the actual switching fre-

quency will be lower than the 100kHz expected, due to

comparator delays and variations in the duty cycle. The

inductor value selected for our application will be

100µH—a preferred value just above the calculated

value. It is important to choose the saturation current

rating of the inductor to be a little higher than the peak

currents, to prevent the inductor from saturating during

operation. The inductor must be selected to ensure that

the switching frequency of the MOD pin will not exceed

the 100kHz maximum.

Additional Applications

_________________________Information

The MAX2003/MAX2003A can use several other cir-

cuits to charge batteries. Figure 9 shows a circuit that

uses a Darlington transistor to regulate the current a

six-cell NiCd battery pack receives. Figure 10 shows a

gated current-limited supply being used to charge a

Duracell NiMH battery pack. Table 6 lists the external

components used in these two application configura-

tions.

Linear Regulation of Charge Current

The circuit in Figure 11 uses an inexpensive transistor

to provide the charge current. Since the input for the

MAX667 can tolerate up to 16V, this circuit can charge

up to 7 cells. The MAX667 can be replaced with a dif-

ferent regulator if more cells need to be charged. The

DC source must supply a voltage equal to 2x the num-

ber of cells, plus 2V overhead to accommodate the

drop across external components.

When fast-charge is initiated, the voltage at the SNS pin

is sampled and compared to the trip levels (220mV low

and 250mV high). If the voltage at SNS is below

220mV, the MOD pin will switch high, and the 10k/1µF

RC lowpass filter will pull high, turning on the NPN tran-

sistor. This will pull the base of the Darlington TIP115

low, turning it on and allowing current to flow into the

battery. When the current through the battery and SNS

resistor are high enough, the voltage at SNS will

exceed 250mV and the MOD pin will turn off.

The amount of current the battery receives depends on

the resistor between SNS and VSS. In our example cir-

cuit, the average current through the SNS resistor will

be:

ISNS(AVG) = VSNS(AVG) / RSNS = 0.235 / 0.28 = 0.84A

The maximum current the resistor will receive is:

ISNS(MAX) = VSNS(MAX) / RSNS = 0.25 / 0.28 = 0.90A

The Darlington transistor must be biased to ensure that

a minimum of 0.90A will be supplied. This minimum

MAX2003/MAX2003A

NiCd/NiMH Battery Fast-Charge Controllers

______________________________________________________________________________________ 15

Table 6. External Component Sources

(602) 994-6430(602) 303-5454Motorola

Power

MOSFET &

Darlington

Transistor

(904) 462-4726

(203) 791-3273

(904) 462-3911

Energizer

Power

Systems

(800) 431-2658Duracell

Battery

(619) 549-4791

(510) 460-5498

Fax Number

(800) 235-5445

Alpha

Thermistor

Device

(510) 734-3060

Advanced

Power

Solutions

Power

Supply

Phone

Number

Manufacturer

MAX2003/MAX2003A

NiCd/NiMH Battery Fast-Charge Controllers

16 ______________________________________________________________________________________

MAX2003

MAX2003A

MAX667

MOD

R1

60.4k

100k

R2

3.48k

R3

33.2k

14V/2A

DC SOURCE

RTR

10k

(*150Ω (2W))

5V OUT IN

0.1µF47µF0.1µF47µF

*TRICKLE-CHARGE

RATE

C/16

1N5822

0.1µF

RB1

100k

RB2 

20k

RSNS 

0.294Ω

1%

(1W)

800mAh

6 NiCd

ALPHA

CURVE A

THERMISTOR

RDIS 

9Ω (10W)

NTCRT

100k

DISCHARGE

RATE

CHARGE

RATE

CT

0.1µF

1µF

CB

0.1µF

STO VCC

RT1

2.21k

10k



10k



TIP115

HEATSINK

6.8k



RT2

1.62k

Q2

N

MMSF5NO3HD

Q3

2N2222

DIS

SNS

BAT

VSS

VCC

DVEN

PUSH TO

DISCHARGE

TM2

TM1

DCMD

TEMP

CHG

MCV

TC0

LED

CCMD

*COMPONENT USED FOR MAX2003.

Figure 11. Linear Mode to Charge NiCD Batteries with -

∆

V Termination

MAX2003/MAX2003A

NiCd/NiMH Battery Fast-Charge Controllers

______________________________________________________________________________________ 17

MAX2003

MAX2003A

MOD

R1

60.4k

100k

R2

3.48k

R3

33.2k

LM317

243Ω

RTR

10k

*180Ω (2W)

Q1

P

MMDF3P03HD

22µF

22µF732Ω

ADJ

5V OUT

OUT

19V

ILIMITED VSOURCE

2.6A

0.1µF

*TRICKLE-CHARGE

RATE

C/40

1N5822

0.1µF

RB1

80.6k

RB2

10k

2600mAh

9 NiMH

RDIS 

4Ω (20W)

NTC

100k

DISCHARGE

RATE

CT

0.1µF

CB

0.1µF

G DURACELL DR35

TO VCC

RT1

2.21k

12V ZENER

1k



10k



RT2

1.62k

Q2

N

MMSF3N03HD

Q3

2N2222

DIS

SNS

BAT

VSS

VCC

TM2

PUSH TO

DISCHARGE

TM1

DCMD

TEMP

CHG

MCV

TC0

LED

DVEN

CCMD

CHARGE

RATE

*COMPONENT USED FOR MAX2003.

Figure 12. Current-Limited Mode for NiMH Batteries with

∆

t Termination

MAX2003/MAX2003A

current value must be sufficiently guardbanded to

ensure the limiting factor is the SNS resistor, and not

the transistor. In our example, the maximum current

supplied by the Darlington will be guardbanded to

1.8A. Since the beta of the Darlington is typically 1000,

the base current needed will be:

IB= IC/ BETA = 1.8A / 1000 = 1.8mA

The emitter of the TIP115 will see 14V, so the base will

see about 12.6V. When the MOD pin is high, the

2N2222 transistor is on and the base resistor will be:

RB= VB/ IB= 12.6V / 1.8mA ≈6.8kΩ

This 1.8A current will never be reached because MOD

will be off when the SNS voltage reaches 0.25V (0.9A).

Current-Limited Supply

The circuit in Figure 12 is set up to charge a Duracell

DR35 battery pack (nine cells, 2.6Ah) using a 19V, 2.6A

current-limited power supply provided by Advanced

Power Solutions. Since many power supplies have

built-in current limiting, very few external components

are required for this charging method.

The SNS pin in this circuit is tied directly to VSS. This

signals the MOD pin to stay high until a termination

condition is met. When MOD is high, the NPN transistor

is turned on, hence pulling the gate of the MOSFET low.

This turns the MOSFET on and supplies current to the

battery at the current limit of the source (2.6A). The 12V

zener diode is placed between the source and gate of

the FET to ensure the FET’s maximum source-drain

voltage is not exceeded.

When a termination condition is reached, the MOD pin

goes low to turn off the FET and terminate the fast-

charge current.

NiCd/NiMH Battery Fast-Charge Controllers

18 ______________________________________________________________________________________

Table 7. Operation Summary

Discharge initiated with temperature

and voltage within set limits.

Discharge

Fast-charge initiated and tempera-

ture or voltage outside the set limits.

Charge Pending

a) Power applied and voltage at

CCMD = DCMD

b ) DCMD = Low, CCMD = Rising

Edge (power already present)

c ) DCMD = High, CCMD = Falling

Edge (power already present)

Initiate Fast-Charge

Rising edge on DCMDInitiate Discharge

Charge Status

(VBAT - VSNS) ≥VMCV

Battery Absent

Conditions

Low

MOD Status

High

Low

DIS

Status

1.375

0.125

—

CHG LED Status

0.125

1.375

Continuous

Pulse current provided by pulsing

MOD pin after fast-charge/top-off.

Pulsed Trickle-

Charge (MAX2003A)

Trickle current provided by external

resistor after fast-charge/top-off.

Constant Trickle-

Charge (MAX2003)

Charge complete and top-off

enabled without exceeding temper-

ature and voltage limits.

Top-Off Charge

Exceed one of the five termination

conditions.

Charge Complete

Fast-charge initiated with tempera-

ture and voltage within set limits.

Fast-Charge

Pulsed according to charge rate

(Table 4).

Low

MAX2003A: Activate for 0.5sec in

every 4sec period.

MAX2003: Active for 4sec in

every 34sec period.

Low

If VSNS > 0.050VCC, MOD = Low

If VSNS > 0.044VCC, MOD = High

Low

0.125

Continuous

0.125

—

LED On

(Low)

(sec)

LED Off

(High)

(sec)

MAX2003/MAX2003A

NiCd/NiMH Battery Fast-Charge Controllers

______________________________________________________________________________________ 19

___________________Chip Topography

MOD

DCMD

CCMD

0.089"

(2.261mm)

0.086"

(2.184mm)

BAT

DVEN

DIS

VCC

CHG

TEMP

MCV

TM1

TM2

VSS SNS

TCO

TRANSISTOR COUNT: 5514

SUBSTRATE CONNECTED TO VSS

________________________________________________________Package Information

DIM



A

A1

B

C

E

e

H

MIN

0.053

0.004

0.014

0.007

0.150



0.228

0.016

MAX

0.069

0.010

0.019

0.010

0.157



0.244

0.050

MIN

1.35

0.10

0.35

0.19

3.80



5.80

0.40

MAX

1.75

0.25

0.49

0.25

4.00



6.20

1.27

INCHES MILLIMETERS

21-0041A

Narrow SO

SMALL-OUTLINE

PACKAGE

(0.150 in.)

DIM



D

MIN

0.189

0.337

0.386

MAX

0.197

0.344

0.394

MIN

4.80

8.55

9.80

MAX

5.00

8.75

10.00

INCHES MILLIMETERS

PINS

8

14

1.270.050

0°-8°

A1 C

0.101mm

0.004in.

MAX2003/MAX2003A

NiCd/NiMH Battery Fast-Charge Controllers

20 ______________________________________________________________________________________

___________________________________________Package Information (continued)

DIM



A

A1

B

C

E

e

H

MIN

0.093

0.004

0.014

0.009

0.291



0.394

0.016

MAX

0.104

0.012

0.019

0.013

0.299



0.419

0.050

MIN

2.35

0.10

0.35

0.23

7.40



10.00

0.40

MAX

2.65

0.30

0.49

0.32

7.60



10.65

1.27

INCHES MILLIMETERS

21-0042A

Wide SO

SMALL-OUTLINE

PACKAGE

(0.300 in.)

DIM



D

MIN

0.398

0.447

0.496

0.598

0.697

MAX

0.413

0.463

0.512

0.614

0.713

MIN

10.10

11.35

12.60

15.20

17.70

MAX

10.50

11.75

13.00

15.60

18.10

INCHES MILLIMETERS

PINS

16

18

20

24

1.27

0.050

A1 C

0°- 8°

0.101mm

0.004in.