FAN5093MTCX Fairchild Semiconductor, FAN5093MTCX Datasheet - Page 13

FAN5093MTCX

Manufacturer Part Number

FAN5093MTCX

Description

IC CTRLR DC-DC SYNC 2PH 24TSSOP

Manufacturer

Fairchild Semiconductor

Datasheet

1.FAN5093MTC.pdf (17 pages)

Specifications of FAN5093MTCX

Applications

Controller, Intel Pentium® IV

Voltage - Input

12V

Number Of Outputs

Voltage - Output

1.1 ~ 1.85 V

Operating Temperature

0°C ~ 70°C

Mounting Type

Surface Mount

Package / Case

24-TSSOP

Output Voltage

1.85 V

Output Current

50 A

Input Voltage

10.8 V to 13.2 V

Mounting Style

SMD/SMT

Maximum Operating Temperature

+ 70 C

Minimum Operating Temperature

0 C

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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PRODUCT SPECIFICATION

the VFB pin exceeds 2.2V, an over-voltage condition is

assumed and the FAN5093 latches on the external low-side

MOSFET and latches off the high-side MOSFET. The

DC-DC converter returns to normal operation only after V

has been recycled.

Over Temperature Protection

If the FAN5093 die temperature exceeds approximately

150 C, the IC shuts itself off. It remains off until the temper-

ature has dropped approximately 25 C, at which time it

resumes normal operation.

Component Selection

MOSFET Selection

This application requires N-channel Enhancement Mode Field

Effect Transistors. Desired characteristics are as follows:

• Low Drain-Source On-Resistance,

• R

• Power package with low Thermal Resistance;

• Drain-Source voltage rating > 15V;

• Low gate charge, especially for higher frequency

For the low-side MOSFET, the on-resistance (R

primary parameter for selection. Because of the small duty

cycle of the high-side, the on-resistance determines the

power dissipation in the low-side MOSFET and therefore

signiﬁcantly affects the efﬁciency of the DC-DC converter.

For high current applications, it may be necessary to use two

MOSFETs in parallel for the low-side for each phase.

For the high-side MOSFET, the gate charge is as important

as the on-resistance, especially with a 12V input and with

higher switching frequencies. This is because the speed of

the transition greatly affects the power dissipation. It may be

a good trade-off to select a MOSFET with a somewhat

higher R

available. For high current applications, it may be necessary

to use two MOSFETs in parallel for the high-side for each

phase.

At the FAN5093’s highest operating frequencies, it may be

necessary to limit the total gate charge of both the high-side

and low-side MOSFETs together, to avert excess power dis-

sipation in the IC.

For details and a spreadsheet on MOSFET selection, refer to

Applications Bulletin AB-8.

Gate Resistors

Use of a gate resistor on every MOSFET is mandatory. The

gate resistor prevents high-frequency oscillations caused by

the trace inductance ringing with the MOSFET gate

capacitance. The gate resistors should be located physically

as close to the MOSFET gate as possible.

REV. 1.1.0 3/27/03

operation.

DS,ON

DS,on

< 10m (lower is better);

, if by so doing a much smaller gate charge is

DS,ON

) is the

The gate resistor also limits the power dissipation inside the

IC, which could otherwise be a limiting factor on the switch-

ing frequency. It may thus carry signiﬁcant power, especially

at higher frequencies. As an example: The FDB7045L has a

maximum gate charge of 70nC at 5V, and an input capaci-

tance of 5.4nF. The total energy used in powering the gate

during one cycle is the energy needed to get it up to 5V, plus

the energy to get it up to 12V:

This power is dissipated every cycle, and is divided between

the internal resistance of the FAN5093 gate driver and the

gate resistor. Thus,

and each gate resistor thus requires a 1/4W resistor to ensure

worst case power dissipation.

Inductor Selection

Choosing the value of the inductor is a tradeoff between

allowable ripple voltage and required transient response.

A smaller inductor produces greater ripple while producing

better transient response. In any case, the minimum induc-

tance is determined by the allowable ripple. The ﬁrst order

equation (close approximation) for minimum inductance for

a two-phase converter is:

where:

Vin = Input Power Supply

Vout = Output Voltage

f = DC/DC converter switching frequency

ESR = Equivalent series resistance of all output capacitors in

parallel

Vripple = Maximum peak to peak output ripple voltage

budget.

Schottky Diode Selection

The application circuit of Figure 2 shows a Schottky diode,

D1 (D2 respectively), one in each phase. They are used as

free-wheeling diodes to ensure that the body-diodes in the

low-side MOSFETs do not conduct when the upper

MOSFET is turning off and the lower MOSFETs are turning

on. It is undesirable for this diode to conduct because its high

forward voltage drop and long reverse recovery time

degrades efﬁciency, and so the Schottky provides a shunt

path for the current. Since this time duration is extremely

short, being minimized by the adaptive gate delay, the

selection criterion for the diode is that the forward voltage of

Rgate

min

482nJ

-- - C

-------------------------------- -

4.7

------------------------------------------------ -

---------------------------------- -

gate

E f R

4.7

–

V 2

2 V

0.5

internal

out

70nC 5V

gate

131mW

---------- -

out

+ 5.4nF

482nJ 300KHz

-----------------

-- -

ESR

ripple

12V 5V

FAN5093

–

FAN5093MTCX Fairchild Semiconductor, FAN5093MTCX Datasheet - Page 13

FAN5093MTCX

Specifications of FAN5093MTCX

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