AN-9066 Datasheet, PDF(1/8 Page) Fairchild Semiconductor – Optimized Switch for Discontinuous Current Mode Power Factor Correction

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AN-9066 Datasheet, PDF (1/8 Pages) Fairchild Semiconductor – Optimized Switch for Discontinuous Current Mode Power Factor Correction

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AN-9066

UniFETâ¢ â Optimized Switch for Discontinuous Current

Mode Power Factor Correction

Abstract

This application note discusses merits of planar technology

power MOSFET in discontinuous current mode power

factor correction application. In most test conditions it is

cost competitive and gives performance benefits compared

to a super-junction technology device. The benefits are

verified through the mathematical simulation and system-

level experiments. A new planar technology power

MOSFET from Fairchild shows faster switching

characteristics that contribute to higher efficiency and lower

device temperature.

Introduction

Switch-mode power supplies are increasingly being

designed with an active power factor correction at the input

stage to meet international regulations for harmonics. The

boost topology in discontinuous current mode (DCM) is

most suitable power factor correction (PFC) method for

converters with less than 300W power rating[1]. In this

topology, the switching-on power loss of boost switch is

negligible, and the major power losses are the switching-off

losses and conduction losses. After the super-junction

devices have been introduced, they are often considered as

optimized switches for active power factor correction

because of extremely low on-resistance and highly non-

linear capacitance curves. In the discontinuous current mode

power factor correction, however, the conventional planar

devices can compete against the powerful super-junction

family. This article shows that Fairchildâs UniFETâ¢ power

MOSFET can provide performance superior to the super-

junction devices in the discontinuous current mode power

factor correction applications.

Power MOSFET Technologies

The super-junction technology utilizes deep P-type pillar

structure in the body of the power MOSFET. The effect of

the pillars is to confine the electric field in the lightly doped

epitaxial region of the power MOSFET. Thanks to this P-

pillar, the resistivity of N-epi can be reduced compared to

the conventional planar technology, while maintaining the

same breakdown voltage. Therefore, typical on-resistance of

the super-junction MOSFETs is only one third of the

conventional planar power MOSFETs at the same chip size.

Most commercially available super-junction devices adopt

multiple epi-layers to build the deep P-pillar structure. The

multi-epi process, however, has some disadvantages, such

Rev. 1.0.1 â¢ 4/3/09

as increased process steps and higher manufacturing cost. In

contrast, the UniFETâ¢ power MOSFET utilizes a planar

double-diffused metal-oxide semiconductor (DMOS)

process that is very mature and highly cost competitive.

Moreover, it has improved ring terminations and optimized

active cell structures compared to the conventional planar

power MOSFETs. The resulting specific on-resistance of

the UniFET is even close to some super-junction devices at

500V of breakdown voltage range.

The planar power MOSFETs also have higher reliability

than the super-junction MOSFETs under unclamped

inductive switching (UIS) condition, which can occur

during power supply power-up or AC line transient. The

devices can enter breakdown, and even be destroyed, in the

worst situations. Typically, the planar MOSFETs are much

better than the super-junction devices in UIS mode. The

newest super-junction technology enabled equivalent UIS

rating to the planar MOSFETs at unit area; however, its

practical rating as a single device is still inferior to planar

MOSFETs because of smaller die size. The UIS ruggedness

of UniFET is also far better than previous generations of

planar technology. For an example, a 265mÎ©, 500V

UniFET shows more than 80A of avalanche current under

low coil UIS test. Moreover, it does not fail at all in the test.

On the contrary, a conventional planar MOSFET with same

on-resistance failed at around 40A. The improved

ruggedness ensures enhanced reliability. In terms of

switching performance, a gate charge is one of the

benchmarks to compare different devices. The UniFET has

a smaller gate charge, faster switching characteristics, and

reduced switching power losses than the conventional

planar MOSFETs. Some typical electric characteristics

benchmarks are shown in Table 1.

Table 1. Gate Charge and Parasitic Capacitance

Benchmark Data

FDB12N50

22nC

COSS

140pF

CISS

985Pf

CRSS

12pF

FQB12N50

39nC 220pF 1550pF 25pF

FDA16N50

32nC 235pF 1495pF 20pF

FQA16N50

60nC 325pF 2300pF 35pF

Note:

1. FDB12N50 and FDA16N50 are UniFETâ¢. FQB12N50

and FQA16N50 are QFETÂ®, is a previous generation of

planar power MOSFET.

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