ISL6252AHRZ Intersil, ISL6252AHRZ Datasheet - Page 16

ISL6252AHRZ

Manufacturer Part Number

ISL6252AHRZ

Description

IC BATTERY CHARGER CTRLR 28-QFN

Manufacturer

Intersil

Datasheet

1.ISL6252HAZ.pdf (25 pages)

Specifications of ISL6252AHRZ

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-VFQFN Exposed Pad

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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Inductor Selection

The inductor selection has trade-offs between cost, size,

crossover frequency and efficiency. For example, the lower

the inductance, the smaller the size, but ripple current is

higher. This also results in higher AC losses in the magnetic

core and the windings, which decrease the system

efficiency. On the other hand, the higher inductance results

in lower ripple current and smaller output filter capacitors,

but it has higher DCR (DC resistance of the inductor) loss,

lower saturation current and has slower transient response.

So, the practical inductor design is based on the inductor

ripple current being ±15% to ±20% of the maximum

operating DC current at maximum input voltage. Maximum

ripple is at 50% duty cycle or V

required inductance can be calculated from Equation 16:

Where V

and switching frequency, respectively.

The inductor ripple current ΔI is found from Equation 17:

where the maximum peak-to-peak ripple current is 30% of

the maximum charge current is used.

For V

the closest standard value gives L = 10µH. Ferrite cores are

often the best choice since they are optimized at 300kHz to

600kHz operation with low core loss. The core must be large

enough not to saturate at the peak inductor current IPeak in

Equation 18:

Inductor saturation can lead to cascade failures due to very

high currents. Conservative design limits the peak and RMS

current in the inductor to less than 90% of the rated

saturation current.

Crossover frequency is heavily dependent on the inductor

value. f

frequency and a conservative design has f

of the switching frequency. The highest f

control mode with the battery removed and may be

calculated (approximately) from Equation 19:

Output Capacitor Selection

The output capacitor in parallel with the battery is used to

absorb the high frequency switching ripple current and

RIPPLE

PEAK

= 300kHz, the calculated inductance is 8.3µH. Choosing

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

4 f

IN,MAX

⋅

5 11 R

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

⋅

IN,MAX

IN MAX

L MAX

should be less than 20% of the switching

0.3 I ⋅

⋅

2π L

⋅

RIPPLE

= 19V, V

⋅

SENSE

L MAX

and f

-- -

⋅

RIPPLE

BAT

are the maximum input voltage,

= 16.8V, I

BAT

= V

BAT,MAX

IN,MAX

is in voltage

= 2.6A, and

/2. The

less than 10%

ISL6252, ISL6252A

(EQ. 16)

(EQ. 17)

(EQ. 19)

(EQ. 18)

smooth the output voltage. The RMS value of the output

ripple current I

where the duty cycle D is the ratio of the output voltage

(battery voltage) over the input voltage for continuous

conduction mode which is typical operation for the battery

charger. During the battery charge period, the output voltage

varies from its initial battery voltage to the rated battery

voltage. So, the duty cycle change can be in the range of

between 0.53 and 0.88 for the minimum battery voltage of

10V (2.5V/Cell) and the maximum battery voltage of 16.8V.

The maximum RMS value of the output ripple current occurs

at the duty cycle of 0.5 and is expressed as Equation 21:

For V

10F ceramic capacitor is a good choice to absorb this

current and also has very small size. Organic polymer

capacitors have high capacitance with small size and have a

significant equivalent series resistance (ESR). Although

ESR adds to ripple voltage, it also creates a high frequency

zero that helps the closed loop operation of the buck

regulator.

EMI considerations usually make it desirable to minimize

ripple current in the battery leads. Beads may be added in

series with the battery pack to increase the battery

impedance at 300kHz switching frequency. Switching ripple

current splits between the battery and the output capacitor

depending on the ESR of the output capacitor and battery

impedance. If the ESR of the output capacitor is 10mΩ and

battery impedance is raised to 2Ω with a bead, then only

0.5% of the ripple current will flow in the battery.

MOSFET Selection

The Notebook battery charger synchronous buck converter

has the input voltage from the AC adapter output. The

maximum AC adapter output voltage does not exceed 25V.

Therefore, 30V logic MOSFET should be used.

The high side MOSFET must be able to dissipate the

conduction losses plus the switching losses. For the battery

charger application, the input voltage of the synchronous

buck converter is equal to the AC adapter output voltage,

which is relatively constant. The maximum efficiency is

achieved by selecting a high side MOSFET that has the

conduction losses equal to the switching losses. Switching

losses in the low-side FET are very small. The choice of

low-side FET is a trade-off between conduction losses

the low-side FET is 2x the r

RMS

DS(ON)

= 300kHz, the maximum RMS current is 0.19A. A typical

IN,MAX

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

----------------------------------- D

) and cost. A good rule of thumb for the r

12 L F

⋅

IN MAX

12 L f

⋅

IN MAX

= 19V, VBAT = 16.8V, L = 10µH, and

RMS

⋅

is given by Equation 20:

⋅

(

1 D

–

DS(ON)

)

of the high-side FET.

August 25, 2010

DS(ON)

(EQ. 21)

(EQ. 20)

FN6498.3

ISL6252AHRZ Intersil, ISL6252AHRZ Datasheet - Page 16

ISL6252AHRZ

Specifications of ISL6252AHRZ

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