ISL6540A Datasheet, PDF(12/22 Page) Intersil Corporation – Single-Phase Buck PWM Controller with Integrated High Speed MOSFET Driver and Pre-Biased Load Capability

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ISL6540A Datasheet, PDF (12/22 Pages) Intersil Corporation – Single-Phase Buck PWM Controller with Integrated High Speed MOSFET Driver and Pre-Biased Load Capability

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ISL6540A

Power-Good

The power-good comparator references the voltage on the

soft-start pin to prevent accidental tripping during margining.

The trip points are shown in Figure 3. Additionally,

power-good will not be asserted until after the completion of

the soft-start cycle. A 0.1ÂµF capacitor at the PG_DLY pin will

add an additional ~7ms delay to the assertion of power-good.

PG_DLY does not delay the de-assertion of power-good.

Under and Overvoltage Protection

The Undervoltage (UV) and Overvoltage (OV) protection

circuitry compares the voltage on the VMON pin with the

reference that tracks with the margining circuitry to prevent

accidental tripping. UV and OV functionality is not enabled

until the end of soft-start.

An OV event is detected asynchronously and causes the

high side MOSFET to turn off, the low side MOSFET to turn

on (effectively a 0% duty cycle), and PGOOD to pull low. The

regulator stays in this state and overrides sourcing and

sinking OCP protections until the OV event is cleared.

An UV event is detected asynchronously and results in the

PGOOD pulling low.

Overcurrent Protection

The ISL6540A monitors both the high side MOSFET and low

side MOSFET for overcurrent events. Dual sensing allows the

ISL6540A to detect overcurrent faults at the very low and very

high duty cycles that can result from the ISL6540Aâs wide input

range. The OCP function is enabled with the drivers at startup

and detects the peak current during each sensing period. A

resistor and a capacitor between the LSOC pin and GND set

the low side source and sinking current limits. A 100ÂµA current

source develops a voltage across the resistor which is then

compared with the voltage developed across the low side

MOSFET at conduction mode. The measurement comparator

uses offset correcting circuitry to provide precise current

measurements with roughly Â±2mV of offset error. An ~120ns

blanking period, implemented on the upper and lower MOSFET

current sensing circuitries, is used to reduce the current

sampling error due to the leading-edge switching noise. An

additional 120ns low pass filter is used to further reduce

measurement error due to noise. In sourcing current

applications, the LSOC voltage is inverted and compared with

the voltage across the MOSFET while on. When this voltage

exceeds the LSOC set voltage, a sourcing OCP fault is

triggered. A 1000pF or greater filter capacitor should be used in

parallel with RLSOC to prevent on-chip parasitics from

impacting the accuracy of the OCP measurement.

The ISL6540Aâs sinking current limit is set to the same

voltage as its sourcing limit. In sinking applications, when the

voltage across the MOSFET is greater than the voltage

developed across the resistor (RLSOC) a sinking OCP event

is triggered. To avoid non-synchronous operation at light

load, the peak-to-peak output inductor ripple current should

not be greater than twice of the sinking current limit.

The high side sourcing current limit is set by connecting the

HSOC pin with a resistor (RHSOC) and a capacitor to the drain

of the high side MOSEFT. A 100ÂµA current source develops a

voltage across the resistor which is then compared with the

voltage developed across the high side MOSFET while on.

When the voltage drop across the MOSFET exceeds the

voltage drop across the resistor, a sourcing OCP event

occurs. A 1000pF or greater filter capacitor should be used in

parallel with RHSOC to prevent on-chip parasitics from

impacting the accuracy of the OCP measurement and to

smooth the voltage across RHSOC in the presence of

switching noise on the input bus.

Simple Low Side OCP Equation

RLSOC = I--O-----C----_---S----O----U---R----C----E--1---â¢0----0r--D--Î¼---S-A---(--O----N----)---L---o---w----S----i--d---e-

(EQ. 2)

Detailed Low Side OCP Equations

RLSOC

-ââ--I--O-----C----_---S---O----U----R----C----E-----+-----Î--2-----I--â â----â¢-----r--D----S----(--O-----N----)--,-L--

ILSOC â¢ NL

ÎI

V-----I--N-----------V----O----U-----T-

FS L

â¢

V-----O----U----T--

VIN

I O C _SINK

I--L----S----O----C-----â¢-----N----L-----â¢----R-----L---S----O----C--

r D S ( O N ) ,L

Î----I

NL = Number of low side MOSFETs

(EQ. 3)

Sourcing OCP faults cause the regulator to disable (Ugate and

Lgate drives pulled low, PGOOD pulled low, soft-start capacitor

discharged) itself for a fixed period of time after which a normal

soft-start sequence is initiated. The period of time the regulator

waits before attempting a soft-start sequence is set by three

charge and discharge cycles of the soft-start capacitor.

Simple High Side OCP Equation

RHSOC = -I-O-----C----_---S---O-----U---R----C----E---1--â¢-0---r-0-D--Î¼---S-A---(--O----N----)---H----i-g----h---S----i-d----e-

(EQ. 4)

Detailed High Side OCP Equation

RHSOC

-ââ--I--O-----C----_---S---O----U----R----C----E-----+-----Î---2----I--â â----â¢-----r--D----S----(--O-----N----)--,-U---

IHSOC â¢ NU

(EQ. 5)

NU = Number of high side MOSFETs

Sinking OCP faults cause the low side MOSFET drive to be

disabled, effectively operating the ISL6540A in a

non-synchronous manner. The fault is maintained for three

clock cycles at which point it is cleared and normal operation

is restored. OVP fault implementation overrides sourcing

and sinking OCP events, immediately turning on the low side

MOSFET and turning off the high side MOSFET. The OC trip

FN6288.5

October 7, 2008

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