ISL6567 Datasheet, PDF(17/26 Page) Intersil Corporation – Multipurpose Two-Phase Buck PWM Controller with Integrated MOSFET Drivers

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ISL6567 Datasheet, PDF (17/26 Pages) Intersil Corporation – Multipurpose Two-Phase Buck PWM Controller with Integrated MOSFET Drivers

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ISL6567

Specificationsâ table starting on page 5 ). Once these

conditions are met, the controller immediately initiates a

soft-start sequence.

General Application Design Guide

This design guide is intended to provide a high-level

explanation of the steps necessary to create a multi-phase

power converter. It is assumed that the reader is familiar with

many of the basic skills and techniques referenced in the

following. In addition to this guide, Intersil provides complete

reference designs that include schematics, bills of materials,

and example board layouts for typical applications.

ISL6567

EXTERNAL CIRCUIT

PVCC

POR

CIRCUIT

VCC

VIN

RBIAS

E/A -

VREF

SHUNT REG

VREG

FIGURE 17. INTERNAL SHUNT REGULATOR USE WITH

EXTERNAL RESISTOR (PASSIVE

CONFIGURATION)

BIAS SUPPLY CONSIDERATIONS

The ISL6567 features an on-board shunt regulator capable of

sinking up to 100mA (minimally). This integrated regulator can

be used to produce the necessary bias voltage for the

controller and the MOSFETs. The integrated regulator can be

utilized directly, via a properly sized resistor, as shown in

Figure 17, or via an external NPN transistor and additional

resistors when either the current needed or the power being

dissipated becomes too large to be handled inside the

ISL6567 in the given operating environment.

A first step in determining the feasibility and selecting the

proper bias regulator configuration consists in determining

the maximum bias current required by the circuit. While the

bias current required by the ISL6567 is listed in the

âElectrical Specificationsâ table starting on page 5, the bias

current required by the controlled MOSFETs needs be

calculated. Equation 10 helps determine this bias current

function of the sum of the gate charge of all the controlled

MOSFETs at 5V VGS, QGTOTAL, and the switching

frequency, FSW:

IB â QGTOTAL â FSW

(EQ. 10)

IBIAS = IVCC + IB

Total required bias current, IBIAS, sums up the ISL6567âs

bias current, IVCC, to that required by the MOSFETs, IB.

ÎVIN = 1V

80 ÎVIN = 2V

ÎVIN = 3V

ÎVIN = 4V

ÎVIN = 5V

ÎVIN = 6V

ÎVIN = 7V

ÎVIN = 8V

VINmin (V)

FIGURE 18. NORMALIZED MAXIMUM BIAS CURRENT

OBTAINABLE IN PASSIVE CONFIGURATION vs

INPUT VOLTAGE RANGE CHARACTERISTIC;

VVCC = 5V

The maximum bias current, IBIAS, that can be obtained via

the internal shunt regulator and a simple external resistor is

characterized in Figure 18 and can also be determined using

Equation 11.

IBIASMAX

-V-----I--N----M----I--N------â----V----V----C-----C--

VINMAX â VVCC

(EQ. 11)

To exemplify the use, for an input voltage ranging from 10V

to 14V, find the intersection of the ÎVIN = 4V curve with the

VINmin = 10V mark and project the result on the Y axis to

find the maximum bias current obtainable (approximately

56% of the maximum current obtainable via the integrated

shunt regulator, IVREG_MAX).

Once the maximum obtainable bias current, IBIAS_MAX, is

determined, and providing it is greater than the bias current,

IBIAS, required by the circuit, RSHUNT can be determined

based on the lowest input voltage, VINMIN:

RBIAS

V-----I--N----M-----I-N------â----V----V----C-----C--

IBIAS

(EQ. 12)

Figure 19 helps with a quick resistor selection based on the

previous guidelines presented. Divide the value thus

obtained by the maximum desired bias current, IBIAS, to

obtain the actual resistor value to be used.

FN9243.3

May 28, 2009

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