ISL6269A_14 Datasheet, PDF(9/15 Page) Intersil Corporation – High-Performance Notebook PWM Controller

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ISL6269A_14 Datasheet, PDF (9/15 Pages) Intersil Corporation – High-Performance Notebook PWM Controller

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ISL6269A

impedance if VVCC has not reached the rising POR threshold

VVCC_THR, or if VVCC is below the falling POR threshold VVCC_THF.

The ISL6269A features a unique fault-identification capability

that can drastically reduce troubleshooting time and effort. The

pull-down resistance of the PGOOD pin corresponds to the fault

status of the controller. During soft-start or if an undervoltage

fault occurs, the PGOOD pull-down resistance is 95Î©, or 30Î© for

an overcurrent fault, or 60Î© for an overvoltage fault.

TABLE 1. PGOOD PULL-DOWN RESISTANCE

CONDITION

PGOOD RESISTANCE

VCC Below POR

Undefined

Soft Start or Undervoltage

95Î©

Overvoltage

60Î©

Overcurrent

30Î©

MOSFET Gate-Drive Outputs LG and UG

The ISL6269A has internal gate drivers for the high-side and low-

side N-Channel MOSFETs. The LG gate driver is optimized for low

duty-cycle applications where the low-side MOSFET conduction

losses are dominant, requiring a low rDS(ON) MOSFET. The LG

pull-down resistance is small in order to clamp the gate of the

MOSFET below the VGS(th) at turnoff. The current transient

through the gate at turnoff can be considerable because the

switching charge of a low rDS(ON) MOSFET can be large. Adaptive

shoot-through protection prevents a gate-driver output from

turning on until the opposite gate-driver output has fallen below

approximately 1V. The dead-time shown in Figure 5 is extended

by the additional period that the falling gate voltage stays above

the 1V threshold. The high-side gate-driver output voltage is

measured across the UG and PHASE pins while the low-side

gate-driver output voltage is measured across the LG and PGND

pins. The power for the LG gate driver is sourced directly from the

PVCC pin. The power for the UG gate driver is sourced from a

âbootâ capacitor connected across the BOOT and PHASE pins.

The boot capacitor is charged from a 5V bias supply through a

âboot diodeâ each time the low-side MOSFET turns on, pulling the

PHASE pin low. The ISL6269A has an integrated boot diode

connected from the PVCC pin to the BOOT pin.

tLGFUGR

tUGFLGR

50%

FIGURE 5. LG AND UG DEAD-TIME

Diode Emulation

The ISL6269A normally operates in Continuous Conduction

Mode (CCM), minimizing conduction losses by forcing the

low-side MOSFET to operate as a synchronous rectifier. An

improvement in light-load efficiency is achieved by allowing the

converter to operate in Diode Emulation Mode (DEM), where the

low-side MOSFET behaves as a smart-diode, forcing the device to

block negative inductor current flow. The ISL6269A can be

configured to operate in DEM by setting the FCCM pin low.

Setting the FCCM pin high will disable DEM.

Positive-going inductor current flows from either the source of

the high-side MOSFET, or the drain of the low-side MOSFET.

Negative-going inductor current usually flows into the drain of the

low-side MOSFET. When the low-side MOSFET conducts positive

inductor current, the phase voltage will be negative with respect

to the GND and PGND pins. Conversely, when the low-side

MOSFET conducts negative inductor current, the phase voltage

will be positive with respect to the GND and PGND pins. Negative

inductor current occurs when the output load current is less than

Â½ the inductor ripple current. Sinking negative inductor current

through the low-side MOSFET lowers efficiency through

unnecessary conduction losses. Efficiency can be further

improved with a reduction of unnecessary switching losses by

reducing the PWM frequency. It is characteristic of the R3â¢

architecture for the PWM frequency to decrease while in diode

emulation. The extent of the frequency reduction is proportional

to the reduction of load current. Upon entering DEM, the PWM

frequency makes an initial step-reduction because of a 33%

step-increase of the window voltage VW.

With FCCM pulled low, the converter will automatically enter DEM

after the PHASE pin has detected positive voltage, while the LG

gate-driver pin is high for eight consecutive PWM pulses. The

converter will return to CCM on the following cycle after the

PHASE pin detects negative voltage, indicating that the body

diode of the low-side MOSFET is conducting positive inductor

current.

Overcurrent and Short-Circuit Protection

The Overcurrent Protection (OCP) and short-circuit protection

(SCP) setpoint is programmed with resistor RSEN that is

connected across the ISEN and PHASE pins. The PHASE pin is

connected to the drain terminal of the low-side MOSFET.

The SCP setpoint is internally set to twice the OCP setpoint. When

an OCP or SCP fault is detected, the PGOOD pin will pull down to

until the EN pin has been pulled below the falling EN threshold

voltage VENTHF or if VVCC has decayed below the falling POR

threshold voltage VVCC_THF.

The OCP circuit does not directly detect the DC load current

leaving the converter. The OCP circuit detects the peak of

positive-flowing output inductor current. The low-side MOSFET

drain current ID is assumed to be equal to the positive output

inductor current when the high-side MOSFET is off. The inductor

current develops a negative voltage across the rDS(ON) of the

low-side MOSFET that is measured shortly after the LG

gate-driver output goes high. The ISEN pin sources the OCP sense

current ISEN, through the OCP programming resistor RSEN,

forcing the ISEN pin to zero volts with respect to the GND pin. The

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FN9253.3

November 18, 2014

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