MAX1870AETJ+ Maxim Integrated Products, MAX1870AETJ+ Datasheet - Page 16

MAX1870AETJ+

Manufacturer Part Number

MAX1870AETJ+

Description

Battery Management Li+ Step Up/Step Down Battery Charger

Manufacturer

Maxim Integrated Products

Datasheet

1.MAX1870AETJ.pdf (32 pages)

Specifications of MAX1870AETJ+

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

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Step-Up/Step-Down

Li+ Battery Charger

The MAX1870A includes all of the functions necessary

to charge Li+, NiMH, and NiCd batteries. A high-effi-

ciency H-bridge topology DC-DC converter controls

charge voltage and current. A proprietary control

scheme offers improved efficiency and smaller inductor

size compared to conventional H-bridge controllers and

operates from input voltages above and below the bat-

tery voltage. The MAX1870A includes analog control

inputs to limit the AC adapter current, charge current,

and battery voltage. An analog output (IINP) delivers a

current proportional to the source current. The Typical

Application Circuit shown in Figure 1 uses a microcon-

troller (µC) to control the charge current or voltage,

while Figure 2 shows a typical application with the

charge voltage and current fixed to specific values for

the application. The voltage at ICTL and the value of

RS2 set the charge current. The voltage at VCTL and

the CELLS inputs set the battery regulation voltage for

the charger. The voltage at CLS and the value of R3 and

R4 set the source current limit.

The MAX1870A features a voltage-regulation loop

(CCV) and two current-regulation loops (CCI and CCS).

CCV is the compensation point for the battery voltage

regulation loop. CCI and CCS are the compensation

points for the battery charge current and supply current

loops, respectively. The MAX1870A regulates the

adapter current by reducing battery charge current

according to system load demands.

The MAX1870A provides high-accuracy regulation of

the charge voltage. Apply a voltage to VCTL to adjust

the battery-cell voltage limit. Set VCTL to a voltage

between 0 and V

tery cell voltage, or connect VCTL to LDO for a default

setting of 4.2V per cell. The limited adjustment range

reduces the sensitivity of the charge voltage to external

resistor tolerances. The overall accuracy of the charge

voltage is better than ±1% when using ±1% resistors to

divide down the reference to establish VCTL. The per-

cell battery-termination voltage is a function of the bat-

tery chemistry and construction. Consult the battery

manufacturer to determine this voltage. Calculate bat-

tery voltage using the following equation:

______________________________________________________________________________________

BATT

REFIN

CELLS

Setting the Charge Voltage

Detailed Description

for a 10% adjustment of the bat-

⎛

⎜

⎝

0 4 .

V x

REFIN

VCTL

⎞

⎟

⎠

Table 1. Cell-Count Programming Table

where N

VCTL is ratiometric with respect to REFIN to improve

accuracy when using resistive voltage-dividers.

Connect CELLS as shown in Table 1 to charge two,

three, or four cells. The cell count can either be hard-

wired or software controlled. The internal error amplifier

(GMV) maintains voltage regulation (see Figure 3 for

the Functional Diagram). Connect a 10kΩ resistor in

series with a 0.01µF capacitor from CCV to GND to

compensate the battery voltage loop. See the Voltage

Loop Compensation section for more information.

Set the maximum charge current using ICTL and the

current-sense resistor RS2 connected between CSIP

and CSIN. The current threshold is set by the ratio of

the battery charge current:

where V

threshold, 73mV (typ). The input range for ICTL is

force ICTL below V

The internal error amplifier (GMI) maintains charge-

current regulation (see Figure 3 for the Functional

Diagram). Connect a 0.01µF capacitor from CCI to GND

to compensate the charge-current loop. See the Charge-

Current Loop Compensation section for more information.

The total input current, from a wall adapter or other DC

source, is a function of the system supply current and

the battery charge current. The MAX1870A limits the wall

adapter current by reducing the charge current when the

input current exceeds the input current-limit set point. As

the system supply current rises, the available charge

current decreases linearly to zero in proportion to the

system current. After the charge current has fallen to

zero, the MAX1870A cannot further limit the wall adapter

current if the system current continues to increase.

ICTL

REFIN

/ V

/ 32 to V

CELLS

CSIT

REFIN

CELLS

REFIN

GND

Float

is the full-scale charge current-sense

. Use the following equation to program

CHG

Setting the Input Current Limit

is the cell count selected by CELLS.

REFIN

Setting the Charge Current

. To shut down the MAX1870A,

CSIT

/ 100.

REFIN

ICTL

CELL COUNT

MAX1870AETJ+ Maxim Integrated Products, MAX1870AETJ+ Datasheet - Page 16

MAX1870AETJ+

Specifications of MAX1870AETJ+

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