ISL6253HAZ-T Intersil, ISL6253HAZ-T Datasheet - Page 14

ISL6253HAZ-T

Manufacturer Part Number

ISL6253HAZ-T

Description

IC BATTERY CHRGR NOTEBOOK 28QSOP

Manufacturer

Intersil

Datasheet

1.ISL6253HAZ.pdf (22 pages)

Specifications of ISL6253HAZ-T

Function

Charge Management

Battery Type

Lithium-Ion (Li-Ion), Lithium-Polymer (Li-Pol)

Voltage - Supply

7 V ~ 25 V

Operating Temperature

-10°C ~ 100°C

Mounting Type

Surface Mount

Package / Case

28-SSOP (0.150", 3.95mm Width)

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

ISL6253HAZ-T

Manufacturer:

Intersil

Quantity:

1 600

Current page: 14 of 22
Download datasheet (550Kb)

Connect CELLS as shown in Table 1 to charge 2, 3, or 4 Li+

cells. When charging other cell chemistries, use CELLS to

select an output voltage range for the charger. The internal

error amplifier gm1 maintains voltage regulation. The voltage

error amplifier is compensated at VCOMP. The component

values shown in Figure 18 provide suitable performance for

most applications. Individual compensation of the voltage

regulation and current-regulation loops allows for optimal

compensation.

Setting the Battery Charge Current Limit

The CHLIM input sets the maximum charging current. The

current set by the current sense-resistor connects between

CSOP and CSON. There are three default battery charge

current-sense threshold voltages: 127mV for CHLIM = 3.3V,

100mV for CHLIM = VREF, 65mV for Float, and 30mV for

ground. The full-scale differential voltage between CSOP

and CSON is 100mV for CHLIM = VREF, so the maximum

charging current is 4.0A for a 25mΩ sensing resistor. Other

battery charge current-sense threshold values can be set by

connecting a resistor divider from VREF or VDD to ground,

or by connecting a low impedance voltage source like a D/A

converter in the microcontroller. The charge current limit

threshold is given by:

If the battery voltage is less than 3.0V/cell and the battery

charging voltage is a percentage of the charging current in

constant current charge mode, the trickle charge current limit

threshold is given by:

When choosing the current sensing resistor, note that the

voltage drop across the sensing resistor causes further

power dissipation, reducing efficiency. However, adjusting

CHLIM voltage to reduce the voltage across the current

sense resistor R1 will degrade accuracy due to the smaller

signal to the input of the current sense amplifier. There is a

trade-off between accuracy and power dissipation. A low

pass filter is recommended to eliminate switching noise.

Connect the resistor to the CSOP pin instead of the CSON

pin, as the CSOP pin has lower bias current and less

influence on current-sense accuracy.

Setting the Input Current Limit

The total input current from an AC adapter, or other DC

source, is a function of the system supply current and the

battery-charging current. The input current regulator limits

CHG

TR CHG

------ -

TABLE 1. CELL NUMBER PROGRAMMING





------ - 0.00157

---------------- -

VREF

CELLS

0.07

VCC

GND

Float

(

CHLIM

0.03





0.0037

CELL NUMBER





(EQ. 2)

(EQ. 3)

ISL6253

the input current by reducing the charging current, when the

input current exceeds the input current

System current normally fluctuates as portions of the system

are powered up or down. Without input current regulation,

the source must be able to supply the maximum system

current and the maximum charger input current

simultaneously. By using the input current limiter, the current

capability of the AC adapter can be lowered, reducing

system cost.

The ISL6253 limits the battery charge current when the input

current-limit threshold is exceeded, ensuring the battery

charger does not load down the AC adapter voltage. An

internal amplifier gm3 compares the voltage between CSIP

and CSIN to the input current limit threshold voltage set by

ACLIM. Connect ACLIM to REF, Float and GND for the full-

scale input current limit threshold voltage of 103mV, 78mV,

and 53mV, respectively, or use a resistor divider from VREF to

ground to set the input current limit as the following equation:

When choosing the current sense resistor, note that the

voltage drop across this resistor causes further power

dissipation, reducing efficiency. The AC adapter current

sense accuracy is very important. Use a 1% tolerance

current-sense resistor. The highest accuracy of ± 3% is

achieved with 103mV current-sense threshold voltage for

ACLIM = VREF, but it has the highest power dissipation. For

example, it has 400mW power dissipation for rated 4A AC

adapter, and a 1W sensing resistor may have to be used. ±

4% and ± 6% accuracy can be achieved with 78mV and

53mV current-sense threshold voltage for ACLIM = Floating

and ACLIM = GND, respectively.

A low pass filter is recommended to eliminate the switching

noise. Connect the resistor to the CSIN pin instead of the

CSIP pin because the CSIN pin has lower bias current and

less influence on the current-sense accuracy.

AC Adapter Detection

Connect the AC adapter voltage through a resistor divider to

ACSET to detect when AC power is available, as shown in

Figure 17. ACPRN is an open-drain output and is high

impedance when ACSET is less than V

impedance when ACSET is above V

Where I

hysteresis is I

and 4.8µA (max.)

INPUT

ACSET

th,fall

th rise

th fall

are given by:

hys

= 1.235V (min), 1.26V (typ.) and 1.285V (max.). The

------ -













is the ACSET input bias current hysteresis and





------ -

---------------- - V

VREF

hys

0.05













•

, where I

ACLIM

ACSET

0.053

hys

–

hys

= 2µA (min.), 3.4µA (typ.)





th,fall

−

th,rise

limit set point.

. V

th,rise

and active low

and

(EQ. 5)

(EQ. 4)

ISL6253HAZ-T Intersil, ISL6253HAZ-T Datasheet - Page 14

ISL6253HAZ-T

Specifications of ISL6253HAZ-T

Available stocks

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