ISL97650ARTZ-T Intersil, ISL97650ARTZ-T Datasheet - Page 14

ISL97650ARTZ-T

Manufacturer Part Number

ISL97650ARTZ-T

Description

IC LCD SUPPLY HP 4CHN 36-TQFN

Manufacturer

Intersil

Datasheet

1.ISL97650ARTZ-TK.pdf (20 pages)

Specifications of ISL97650ARTZ-T

Applications

LCD TV/Monitor

Current - Supply

250µA

Voltage - Supply

4 V ~ 14 V

Operating Temperature

-40°C ~ 105°C

Mounting Type

Surface Mount

Package / Case

36-TQFN

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Meier Automation Equipment Co., Limited

Part Number:

ISL97650ARTZ-T

Manufacturer:

INTERSIL

Quantity:

20 000

Current page: 14 of 20
Download datasheet (348Kb)

Rectifier Diode (Buck Converter)

A Schottky diode is recommended due to fast recovery and

low forward voltage. The reverse voltage rating should be

higher than the maximum input voltage. The peak current

rating is 2A, and the average current should be as shown in

Equation 15:

Where I

shows some recommended diodes.

Output Capacitor (Buck Converter)

Four 10µF or two 22µF ceramic capacitors are recommended

for this part. The overshoot and undershoot will be reduced

with more capacitance, but the recovery time will be longer.

PI Loop Compensation (Buck Converter)

The buck converter of ISL97650 can be compensated by a

RC network connected from CM2 pin to ground. C9 = 4.7nF

and R2 = 2k RC network is used in the demo board. The

larger value resistor can lower the transient overshoot,

however, at the expense of stability of the loop.

The stability can be optimized in a similar manner to that

described in the section “PI Loop Compensation (Boost

Converter)” on page 12.

Bootstrap Capacitor (C16)

This capacitor is used to provide the supply to the high driver

circuitry for the buck MOSFET. The bootstrap supply is

formed by an internal diode and capacitor combination. A

1µF is recommended for ISL97650. A low value capacitor

can lead to overcharging and in turn damage the part.

If the load is too light, the on-time of the low side diode may

be insufficient to replenish the bootstrap capacitor voltage. In

this case, if V

device may be unable to turn-on until V

there is a minimum load requirement in this case. The

avg

CAPACITOR

TABLE 9. BUCK OUTPUT CAPACITOR RECOMMENDATION

PMEG2020EJ

100µF/6.3V

10µF/6.3V

22µF/6.3V

TABLE 8. BUCK RECTIFIER DIODE RECOMMENDATION

DIODE

SS22

(

1 D

–

is the output current of buck converter. Table 8

)*I

-V

BUCK

RATING

SIZE

0805

1210

1206

20V/2A

AVG

< 1.5V, the internal MOSFET pull-up

TDK

Murata

TDK

Murata

VENDOR

PACKAGE

SOD323F

SMB

LOGIC

C2012X5R0J106M

GRM21BR60J106K

C3216X5R0J226M

GRM31CR60J107M

Philips

Semiconductors

Fairchild

Semiconductor

PART NUMBER

VENDOR

falls. Hence,

(EQ. 15)

ISL97650

minimum load can be adjusted by the feedback resistors

to FBL.

The bootstrap capacitor can only be charged when the

higher side MOSFET is off. If the load is too light which can

not make the on time of the low side diode be sufficient to

replenish the boot strap capacitor, the MOSFET can’t turn

on. Hence there is minimum load requirement to charge the

bootstrap capacitor properly.

Charge Pump Controllers (V

The ISL97650 includes 2 independent charge pumps (see

charge pump block and connection diagram, Figure 17). The

negative charge pump inverts the V

provides a regulated negative output voltage. The positive

charge pump doubles or triples the V

provides a regulated positive output voltage. The regulation

of both the negative and positive charge pumps is generated

by internal comparator that senses the output voltage and

compares it with the internal reference.

The pumps use pulse width modulation to adjust the pump

period, depending on the load present. The pumps can

provide 30mA for V

Positive Charge Pump Design Consideration

The positive charge pump integrates all the diodes (D1, D2

and D3 shown in the “Block Diagram” on page 9) required

for x2 (V

operation. During the chip start-up sequence, the mode of

operation is automatically detected when the charge pump is

enabled. With both C7 and C8 present, the x3 mode of

operation is detected. With C7 present, C8 open and with

C1+ shorted to C2+, the x2 mode of operation will be

detected.

Due to the internal switches to V

pump is enabled. This is important for TFT applications

where the negative charge pump output voltage (V

The maximum P

from the following equations assuming a 50% switching

duty:

Note: V

function of I

2 V

---------------------------------------------------------------------------------------------------------------------- 0.95A

3 V

---------------------------------------------------------------------------------------------------------------------- 0.95V

MAX

VDD

OUT

•

SUP

(

supplies need to be established before P

is independent of the voltage on V

DIODE

)

(

SUP

–

∼

(

•

min of 50mA or

MAX

•

(

•

3 r

doubler) and x3 (V

(

2 r

•

(2 • I

DIODE

•

OUT

ONH

and V

ONH

OFF

MAX

charge pump current can be estimated

(

2 I

DIODE

2 r •

) is the on-chip diode voltage as a

•

and 20mA for V

•

ONL

MAX

ONL

)

(40mA) < 0.7V.

) V V

)

) V V

)

–

)

SUP

(

SUP

Tripler) modes of

SUP

(M1, M2 and M3),

and V

)

SUP

voltage and

•

voltage and

OFF

until the charge

OUT

)

OFF

April 17, 2009

(EQ. 16)

FN9198.4

) and

ISL97650ARTZ-T Intersil, ISL97650ARTZ-T Datasheet - Page 14

ISL97650ARTZ-T

Specifications of ISL97650ARTZ-T

Available stocks

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