ISL6236AIRZ-T Intersil, ISL6236AIRZ-T Datasheet - Page 28

ISL6236AIRZ-T

Manufacturer Part Number

ISL6236AIRZ-T

Description

IC MAIN PWR CTRLR QUAD 32-QFN

Manufacturer

Intersil

Datasheet

1.ISL6236AIRZ.pdf (37 pages)

Specifications of ISL6236AIRZ-T

Applications

Controller, Notebook Computers

Voltage - Input

4.5 ~ 25 V

Number Of Outputs

Operating Temperature

-40°C ~ 100°C

Mounting Type

Surface Mount

Package / Case

32-VQFN Exposed Pad, 32-HVQFN, 32-SQFN, 32-DHVQFN

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Voltage - Output

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Reference and Linear Regulators (VREF3,

REF, LDO and 14V Charge Pump)

The 3.3V reference (VREF3) is accurate to ±1.5%

over-temperature, making VREF3 useful as a precision

system reference. VREF3 can supply up to 5mA for external

loads. Bypass VREF3 to GND with a 0.01µF capacitor.

Leave it open if there is no load.

The 2V reference (REF) is accurate to ±1% over- temperature,

also making REF useful as a precision system reference.

Bypass REF to GND with a 0.1µF (min) capacitor. REF can

supply up to 50µA for external loads.

An internal regulator produces a fixed 5V

(LDOREFIN < 0.2V) or 3.3V (LDOREFIN > VCC - 1V). In an

adjustable mode, the LDO output can be set from 0.7V to

4.5V. The LDO output voltage is equal to two times the

LDOREFIN voltage. The LDO regulator can supply up to

100mA for external loads. Bypass LDO with a minimum

4.7µF ceramic capacitor. When the LDOREFIN < 0.2V and

BYP voltage is 5V, the LDO bootstrap-switchover to an

internal 0.7Ω P-Channel MOSFET switch connects BYP to

LDO pin while simultaneously shutting down the internal

linear regulator. These actions bootstrap the device,

powering the loads from the BYP input voltages, rather than

through internal linear regulators from the battery. Similarly,

when the BYP = 3.3V and LDOREFIN = VCC, the LDO

bootstrap-switchover to an internal 1.5Ω P-Channel

MOSFET switch connects BYP to LDO pin while

simultaneously shutting down the internal linear regulator.

No switchover action in adjustable mode.

In Figure 68, the external 14V charge pump is driven by

LGATE1. When LGATE1 is low, D1a charged C

from OUT1. C

drop. When LGATE1 transitions to high, the charges from C

will transfer to C

plus VC8. As LGATE1 transitions low on the next cycle, C

will charge C

FB<Reg.Point

FIGURE 73. ULTRASONIC CURRENT WAVEFORMS

FB<REG.POINT

voltage is equal to OUT1 minus a diode

to its voltage minus a diode drop through

through D1b and charge it to VLGATE1

40µs (MAX)

ON-TIME (t

)

ON )

)

Zero-Crossing

ZERO-CROSSING

Detection

DETECTION

INDUCTOR

CURRENT

sourced

ISL6236A

D2a. Finally, C

switched to high. CP output voltage is shown in Equation 4:

where:

• V

SECFB is used to monitor the charge pump through the

resistive divider. In an event when SECFB dropped below

2V, the detection circuit force the highside MOSFET

(SMPS1) off and the lowside MOSFET (SMPS1) on for

300ns to allow CP to recharge and SECFB rise above 2V. In

the event of an overload on CP where SECFB cannot reach

more than 2V, the monitor will be deactivated. Special care

should be taken to ensure enough normal voltage ripple on

each cycle as to prevent CP shut-down. The SECFB pin has

~17mV of hysteresis, so the ripple should be enough to bring

the SECFB voltage above the threshold by ~3x the

hysteresis, or (2V + 3*17mV) = 2.051V. Reducing the CP

decoupling capacitor and placing a small ceramic capacitor

(10pF to 47pF) in parallel with the upper leg of the SECFB

resistor feedback network (R

increase the robustness of the charge pump.

Current-Limit Circuit (ILIM ) with r

Temperature Compensation

The current-limit circuit employs a "valley" current-sensing

algorithm. The ISL6236A uses the ON-resistance of the

synchronous rectifier as a current-sensing element. If the

magnitude of the current-sense signal at PHASE is above

the current-limit threshold, the PWM is not allowed to initiate

a new cycle. The actual peak current is greater than the

current-limit threshold by an amount equal to the inductor

ripple current. Therefore, the exact current-limit

characteristic and maximum load capability are a function of

the current-limit threshold, inductor value and input and

output voltage.

FIGURE 74. “VALLEY” CURRENT LIMIT THRESHOLD POINT

LGATE1

is the forward diode dropped across the Schottkys

OUT1

is the peak voltage of the LGATE1 driver

2 V

⋅

charges C

LGATE1

LIM

(

VAL

–

)

TIME

4 V

I LOAD(MAX)

⋅

LOAD

of Figure 68), will also

thru D2b when LGATE1

I PEAK

I LOAD

I LIMIT

DS(ON)

March 18, 2008

FN6453.3

(EQ. 4)

ISL6236AIRZ-T Intersil, ISL6236AIRZ-T Datasheet - Page 28

ISL6236AIRZ-T

Specifications of ISL6236AIRZ-T

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