MC33262PG - ON Semiconductor - searchdatasheet.com

September, 2011 − Rev. 13

1Publication Order Number:

MC34262/D

MC34262, MC33262

Power Factor Controllers

The MC34262/MC33262 are active power factor controllers

specifically designed for use as a preconverter in electronic ballast

and in off−line power converter applications. These integrated

circuits feature an internal startup timer for stand−alone applications,

a one quadrant multiplier for near unity power factor, zero current

detector to ensure critical conduction operation, transconductance

error amplifier, quickstart circuit for enhanced startup, trimmed

internal bandgap reference, current sensing comparator, and a totem

pole output ideally suited for driving a power MOSFET.

Also included are protective features consisting of an overvoltage

comparator to eliminate runaway output voltage due to load removal,

input undervoltage lockout with hysteresis, cycle−by−cycle current

limiting, multiplier output clamp that limits maximum peak switch

current, an RS latch for single pulse metering, and a drive output high

state clamp for MOSFET gate protection. These devices are

available in dual−in−line and surface mount plastic packages.

Features

•Overvoltage Comparator Eliminates Runaway Output Voltage

•Internal Startup Timer

•One Quadrant Multiplier

•Zero Current Detector

•Trimmed 2% Internal Bandgap Reference

•Totem Pole Output with High State Clamp

•Undervoltage Lockout with 6.0 V of Hysteresis

•Low Startup and Operating Current

•Supersedes Functionality of SG3561 and TDA4817

•These are Pb−Free and Halide−Free Devices

Figure 1. Simplified Block Diagram

Voltage

Feedback

Input

Multiplier,

Latch,

PWM,

Timer,

Logic

Error Amp

Multiplier

Undervoltage

Lockout

2.5V

Reference

Zero Current Detector

Drive Output

GND

Zero Current

Detect Input

Multiplier

Input

Compensation

VCC

Current Sense

Input

Overvoltage

Comparator

+1.08 Vref

+Vref

Quickstart

POWER FACTOR

CONTROLLERS

PIN CONNECTIONS

SOIC−8

D SUFFIX

CASE 751

PDIP−8

P SUFFIX

CASE 626

Voltage Feedback

Input 1

(Top View)

Compensation

Multiplier Input

Current Sense

Input

VCC

Drive Output

GND

Zero Current

Detect Input

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See detailed ordering and shipping information in the package

dimensions section on page 17 of this data sheet.

ORDERING INFORMATION

x = 3 or 4

A = Assembly Location

WL, L = Wafer Lot

YY, Y = Year

WW, W = Work Week

G = Pb−Free Package

G= Pb−Free Package

MARKING

DIAGRAMS

MC3x262P

AWL

YYWWG

3x262

ALYW

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MAXIMUM RATINGS

Rating Symbol Value Unit

Total Power Supply and Zener Current (ICC + IZ) 30 mA

Output Current, Source or Sink (Note 1) IO500 mA

Current Sense, Multiplier, and Voltage Feedback Inputs Vin −1.0 to +10 V

Zero Current Detect Input

High State Forward Current

Low State Reverse Current

Iin

−10

Power Dissipation and Thermal Characteristics

P Suffix, Plastic Package, Case 626

Maximum Power Dissipation @ TA = 70°C

Thermal Resistance, Junction−to−Air

D Suffix, Plastic Package, Case 751

Maximum Power Dissipation @ TA = 70°C

Thermal Resistance, Junction−to−Air

RqJA

800

100

450

178

°C/W

Operating Junction Temperature TJ+150 °C

Operating Ambient Temperature (Note 4)

MC34262

MC33262

0 to + 85

−40 to +105

°C

Storage Temperature Tstg −65 to +150 °C

ESD Protection (Note 2)

Human Body Model ESD

Machine Model ESD

Charged Device Model ESD

HBM

CDM

2000

200

2000

Stresses exceeding Maximum Ratings may damage the device. Maximum Ratings are stress ratings only. Functional operation above the

Recommended Operating Conditions is not implied. Extended exposure to stresses above the Recommended Operating Conditions may affect

device reliability.

1. Maximum package power dissipation limits must be observed.

2. ESD protection per JEDEC JESD22−A114−F for HBM, per JEDEC JESD22−A115−A for MM, and per JEDEC JESD22−C101D for CDM.

This device contains latchup protection and exceeds 100 mA per JEDEC Standard JESD78.

ELECTRICAL CHARACTERISTICS (VCC = 12 V (Note 3), for typical values TA = 25°C, for min/max values TA is the operating

ambient temperature range that applies (Note 4), unless otherwise noted.)

Characteristic Symbol Min Typ Max Unit

ERROR AMPLIFIER

Voltage Feedback Input Threshold

TA = 25°C

TA = Tlow to Thigh (VCC = 12 V to 28 V)

VFB

2.465

2.44

2.5

−

2.535

2.54

Line Regulation (VCC = 12 V to 28 V, TA = 25°C) Regline −1.0 10 mV

Input Bias Current (VFB = 0 V) IIB − − 0.1 −0.5 mA

Transconductance (TA = 25°C) gm80 100 130 mmho

Output Current

Source (VFB = 2.3 V)

Sink (VFB = 2.7 V)

−

Output Voltage Swing

High State (VFB = 2.3 V)

Low State (VFB = 2.7 V)

VOH(ea)

VOL(ea)

5.8

−

6.4

1.7

−

2.4

OVERVOLTAGE COMPARATOR

Voltage Feedback Input Threshold VFB(OV) 1.065 VFB 1.08 VFB 1.095 VFB V

MULTIPLIER

Input Bias Current, Pin 3 (VFB = 0 V) IIB − − 0.1 −0.5 mA

Input Threshold, Pin 2 Vth(M) 1.05 VOL(EA) 1.2 VOL(EA) −V

3. Adjust VCC above the startup threshold before setting to 12 V.

4. Tlow =0°C for MC34262 Thigh = +85°C for MC34262

=−40°C for MC33262 = +105°C for MC33262.

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ELECTRICAL CHARACTERISTICS (continued) (VCC = 12 V (Note 6), for typical values TA = 25°C, for min/max values TA is the

operating ambient temperature range that applies (Note 7), unless otherwise noted.)

Characteristic Symbol Min Typ Max Unit

MULTIPLIER

Dynamic Input Voltage Range

Multiplier Input (Pin 3)

Compensation (Pin 2)

VPin 3

VPin 2

0 to 2.5

Vth(M) to

(Vth(M) + 1.0)

0 to 3.5

Vth(M) to

(Vth(M) + 1.5)

−

Multiplier Gain (VPin 3 = 0.5 V, VPin 2 = Vth(M) + 1.0 V) (Note 8) K 0.43 0.65 0.87 1/V

ZERO CURRENT DETECTOR

Input Threshold Voltage (Vin Increasing) Vth 1.33 1.6 1.87 V

Hysteresis (Vin Decreasing) VH100 200 300 mV

Input Clamp Voltage

High State (IDET = + 3.0 mA)

Low State (IDET = −3.0 mA)

VIH

VIL

6.1

0.3

6.7

0.7

−

1.0

CURRENT SENSE COMPARATOR

Input Bias Current (VPin 4 = 0 V) IIB − − 0.15 −1.0 mA

Input Offset Voltage (VPin 2 = 1.1 V, VPin 3 = 0 V) VIO −9.0 25 mV

Maximum Current Sense Input Threshold (Note 9) Vth(max) 1.3 1.5 1.8 V

Delay to Output tPHL(in/out) −200 400 ns

DRIVE OUTPUT

Output Voltage (VCC = 12 V)

Low State (ISink = 20 mA)

Low State (ISink = 200 mA)

High State (ISource = 20 mA)

High State (ISource = 200 mA)

VOL

VOH

−

9.8

7.8

0.3

2.4

10.3

8.4

0.8

3.3

−

Output Voltage (VCC = 30 V)

High State (ISource = 20 mA, CL = 15 pF)

VO(max)

14 16 18

Output Voltage Rise Time (CL = 1.0 nF) tr−50 120 ns

Output Voltage Fall Time (CL = 1.0 nF) tf−50 120 ns

Output Voltage with UVLO Activated

(VCC = 7.0 V, ISink = 1.0 mA)

VO(UVLO) −0.1 0.5 V

RESTART TIMER

Restart Time Delay tDLY 200 620 −ms

UNDERVOLTAGE LOCKOUT

Startup Threshold (VCC Increasing) Vth(on) 11.5 13 14.5 V

Minimum Operating Voltage After Turn−On (VCC Decreasing) VShutdown 7.0 8.0 9.0 V

Hysteresis VH3.8 5.0 6.2 V

TOTAL DEVICE

Power Supply Current

Startup (VCC = 7.0 V)

Operating

Dynamic Operating (50 kHz, CL = 1.0 nF)

ICC

−

0.25

6.5

9.0

0.4

Power Supply Zener Voltage (ICC = 25 mA) VZ30 36 −V

5. Maximum package power dissipation limits must be observed.

6. Adjust VCC above the startup threshold before setting to 12 V.

7. Tlow =0°C for MC34262 Thigh = +85°C for MC34262

=−40°C for MC33262 = +105°C for MC33262.

8. K +Pin 4 Threshold

VPin 3 (VPin2 *Vth(M))

9. This parameter is measured with VFB = 0 V, and VPin 3 = 3.0 V.

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1.4-0.2 3.80.6 2.2 3.0

VPin 2 = 2.0 V

VCC = 12 V

TA = 25°C

VM, MULTIPLIER PIN 3 INPUT VOLTAGE (V)

Figure 2. Current Sense Input Threshold

versus Multiplier Input

-0.12

VM, MULTIPLIER PIN 3 INPUT VOLTAGE (V)

-0.06 0.06 0.12 0.18 0.240

VCC = 12 V

TA = 25°C

Figure 3. Current Sense Input Threshold

versus Multiplier Input, Expanded View

0.2

1.6 0.08

1.4

1.2

1.0

0.8

0.6

0.4

0.07

0.06

0.05

0.04

0.03

0.02

0.01

VPin 2 = 3.75 V

VPin 2 = 2.25 V

VPin 2 = 2.5 V

VPin 2 = 2.75 V

VPin 2 = 3.0 V VPin 2 = 2.25 V

VPin 2 = 2.5 V

VPin 2 = 3.75 V

VPin 2 = 2.75 V

VPin 2 = 2.0 V

VPin 2 = 3.25 V

VPin 2 = 3.0 V

VPin 2 = 3.25 V

VPin 2 = 3.5 V

Figure 4. Voltage Feedback Input Threshold

Change versus Temperature

Figure 5. Overvoltage Comparator Input

Threshold versus Temperature

VCC = 12 V

-55

TA, AMBIENT TEMPERATURE (°C)

-25 0 25 50 75 100

Figure 6. Error Amp Transconductance and

Phase versus Frequency

-55

TA, AMBIENT TEMPERATURE (°C)

-25 0 25 50 75 100 125

VCC = 12 V

Pins 1 to 2

Figure 7. Error Amp Transient Response

125

3.0 k 10 k 30 k 100 k 300 k 1.0 M 3.0 M

120

150

180

f, FREQUENCY (Hz)

VCC = 12 V

VO = 2.5 V to 3.5 V

RL = 100 k to 3.0 V

CL = 2.0 pF

TA = 25°C

5.0 ms/DIV

Transconductance

Phase

0 V/DIV

VCC = 12 V

RL = 100 k

CL = 2.0 pF

TA = 25°C

110

109

108

106

107

4.0

-4.0

-12

-16

-8.0

120

100

4.00 V

3.25 V

2.50 V

DVFB, VOLTAGE FEEDBACK THRESHOLD CHANGE (mV) VCS, CURRENT SENSE PIN 4 THRESHOLD (V)

VCS, CURRENT SENSE PIN 4 THRESHOLD (V)

DVFB(OV), OVERVOLTAGE INPUT THRESHOLD (%VFB)

gm, TRANSCONDUCTANCE (mmho)

q, EXCESS PHASE (DEGREES)

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-55

TA, AMBIENT TEMPERATURE (°C)

-25 0 25 50 75 100 125

VCC = 12 V

Figure 8. Quickstart Charge Current

versus Temperature

Figure 9. Restart Timer Delay

versus Temperature

TA, AMBIENT TEMPERATURE (°C)

-55 -25 0 25 50 75 100 125

Current

Voltage

900

800

700

600

500

VCC = 12 V

800

700

600

500

400

1.80

1.76

1.72

1.68

1.64

Figure 10. Zero Current Detector Input

Threshold Voltage versus Temperature

Figure 11. Output Saturation Voltage

versus Load Current

0 80 160 240 32

IO, OUTPUT LOAD CURRENT (mA)

-55

TA, AMBIENT TEMPERATURE (°C)

-25 0 25 50 75 100 125

VCC = 12 V VCC

GND

-2.0

-4.0

-6.0

2.0

4.0

1.7

1.5

1.3

1.6

1.4

Upper Threshold

(Vin, Increasing)

Lower Threshold

(Vin, Decreasing)

Source Saturation

(Load to Ground)

Sink Saturation

(Load to VCC)

VCC = 12 V

80 ms Pulsed Load

120 Hz Rate

VCC = 12 V

CL = 1.0 nF

TA = 25°C

VCC = 12 V

CL = 15 pF

TA = 25°C

5.0 V/DIV100 mA/DIV

100 ns/DIV 100 ns/DIV

ICC, SUPPLY CURRENT VO, OUTPUT VOLTAGE

Figure 12. Drive Output Waveform Figure 13. Drive Output Cross Conduction

90%

10%

Vchg, QUICKSTART CHARGE VOLTAGE (V)

Ichg, QUICKSTART CHARGE CURRENT (mA)

tDLY, RESTART TIME DELAY (ms)

Vsat, OUTPUT SATURATION VOLTAGE (V)

Vth, THRESHOLD VOLTAGE (V)

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ICC, SUPPLY CURRENT (mA)

0 10203040

VCC, SUPPLY VOLTAGE (V)

VFB = 0 V

Current Sense = 0 V

Multiplier = 0 V

CL = 1.0 nF

f = 50 kHz

TA = 25°C

-55 -25 0 25 50 75 100 125

TA, AMBIENT TEMPERATURE (°C)

VCC, SUPPLY VOLTAGE (V)

Figure 14. Supply Current

versus Supply Voltage

Figure 15. Undervoltage Lockout Thresholds

versus Temperature

Startup Threshold

(VCC Increasing)

8.0

4.0

9.0

7.0

8.0

Minimum Operating Threshold

(VCC Decreasing)

FUNCTIONAL DESCRIPTION

Introduction

With the goal of exceeding the requirements of

legislation on line−current harmonic content, there is an

ever increasing demand for an economical method of

obtaining a unity power factor. This data sheet describes a

monolithic control IC that was specifically designed for

power factor control with minimal external components. It

offers the designer a simple, cost−effective solution to

obtain the benefits of active power factor correction.

Most electronic ballasts and switching power supplies

use a bridge rectifier and a bulk storage capacitor to derive

raw dc voltage from the utility ac line, Figure 16.

Figure 16. Uncorrected Power Factor Circuit

Line

Rectifiers Converter

Bulk

Storage

Capacitor

+Load

This simple rectifying circuit draws power from the line

when the instantaneous ac voltage exceeds the capacitor

voltage. This occurs near the line voltage peak and results

in a high charge current spike, Figure 17. Since power is

only taken near the line voltage peaks, the resulting spikes

of current are extremely nonsinusoidal with a high content

of harmonics. This results in a poor power factor condition

where the apparent input power is much higher than the real

power. Power factor ratios of 0.5 to 0.7 are common.

Power factor correction can be achieved with the use of

either a passive or an active input circuit. Passive circuits

usually contain a combination of large capacitors,

inductors, and rectifiers that operate at the ac line

frequency. Active circuits incorporate some form of a high

frequency switching converter for the power processing,

with the boost converter being the most popular topology,

Figure 18. Since active input circuits operate at a frequency

much higher than that of the ac line, they are smaller,

lighter in weight, and more efficient than a passive circuit

that yields similar results. With proper control of the

preconverter, almost any complex load can be made to

appear resistive to the ac line, thus significantly reducing

the harmonic current content.

Figure 17. Uncorrected Power Factor

Input Waveforms

Vpk

Rectified

AC Line

Voltage

AC Line

Current

Line Sag

The MC34262, MC33262 are high performance, critical

conduction, current−mode power factor controllers

specifically designed for use in off−line active

preconverters. These devices provide the necessary

features required to significantly enhance poor power

factor loads by keeping the ac line current sinusoidal and

in phase with the line voltage.

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Operating Description

The MC34262, MC33262 contain many of the building

blocks and protection features that are employed in modern

high performance current mode power supply controllers.

There are, however, two areas where there is a major

difference when compared to popular devices such as the

UC3842 series. Referring to the block diagrams in

Figures 20, 21, and 22 note that a multiplier has been added

to the current sense loop and that this device does not

contain an oscillator. The reasons for these differences will

become apparent in the following discussion. A description

of each of the functional blocks is given below.

Figure 18. Active Power Factor Correction Preconverter

Rectifiers PFC Preconverter

High

Frequency

Bypass

Capacitor

Converter

Bulk

Storage

Capacitor

+Load

MC34362

Line

Error Amplifier

An Error Amplifier with access to the inverting input and

output is provided. The amplifier is a transconductance

type, meaning that it has high output impedance with

controlled voltage−to−current gain. The amplifier features

a typical gm of 100 mmhos (Figure 6). The noninverting

input is internally biased at 2.5 V ±2.0% and is not pinned

out. The output voltage of the power factor converter is

typically divided down and monitored by the inverting

input. The maximum input bias current is −0.5 mA, which

can cause an output voltage error that is equal to the product

of the input bias current and the value of the upper divider

resistor R2. The Error Amp output is internally connected

to the Multiplier and is pinned out (Pin 2) for external loop

compensation. Typically, the bandwidth is set below 20 Hz,

so that the amplifier’s output voltage is relatively constant

over a given ac line cycle. In effect, the error amp monitors

the average output voltage of the converter over several

line cycles. The Error Amp output stage was designed to

have a relatively constant transconductance over

temperature. This allows the designer to define the

compensated bandwidth over the intended operating

temperature range. The output stage can sink and source

10 mA of current and is capable of swinging from 1.7 V to

6.4 V, assuring that the Multiplier can be driven over its

entire dynamic range.

A key feature to using a transconductance type amplifier,

is that the input is allowed to move independently with

respect to the output, since the compensation capacitor is

connected to ground. This allows dual usage of of the

Voltage Feedback Input pin by the Error Amplifier and by

the Overvoltage Comparator.

Overvoltage Comparator

An Overvoltage Comparator is incorporated to eliminate

the possibility of runaway output voltage. This condition

can occur during initial startup, sudden load removal, or

during output arcing and is the result of the low bandwidth

that must be used in the Error Amplifier control loop. The

Overvoltage Comparator monitors the peak output voltage

of the converter, and when exceeded, immediately

terminates MOSFET switching. The comparator threshold

is internally set to 1.08 Vref. In order to prevent false

tripping during normal operation, the value of the output

filter capacitor C3 must be large enough to keep the

peak−to−peak ripple less than 16% of the average dc

output. The Overvoltage Comparator input to Drive Output

turn−off propagation delay is typically 400 ns. A

comparison of startup overshoot without and with the

Overvoltage Comparator circuit is shown in Figure 24.

Multiplier

A single quadrant, two input multiplier is the critical

element that enables this device to control power factor.

The ac full wave rectified haversines are monitored at Pin 3

with respect to ground while the Error Amp output at Pin 2

is monitored with respect to the Voltage Feedback Input

threshold. The Multiplier is designed to have an extremely

linear transfer curve over a wide dynamic range, 0 V to

3.2 V for Pin 3, and 2.0 V to 3.75 V for Pin 2, Figures 2 and

3. The Multiplier output controls the Current Sense

Comparator threshold as the ac voltage traverses

sinusoidally from zero to peak line, Figure 18. This has the

effect of forcing the MOSFET on−time to track the input

line voltage, resulting in a fixed Drive Output on−time, thus

making the preconverter load appear to be resistive to the

ac line. An approximation of the Current Sense

Comparator threshold can be calculated from the following

equation. This equation is accurate only under the given

test condition stated in the electrical table.

VCS, Pin 4 Threshold ≈ 0.65 (VPin 2 − Vth(M)) VPin 3

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A significant reduction in line current distortion can be

attained by forcing the preconverter to switch as the ac line

voltage crosses through zero. The forced switching is

achieved by adding a controlled amount of offset to the

Multiplier and Current Sense Comparator circuits. The

equation shown below accounts for the built−in offsets and

is accurate to within ten percent. Let Vth(M) = 1.991 V

VCS, Pin 4 Threshold = 0.544 (VPin 2 − Vth(M)) VPin 3

+ 0.0417 (VPin 2 − Vth(M))

Zero Current Detector

The MC34262 operates as a critical conduction current

mode controller, whereby output switch conduction is

initiated by the Zero Current Detector and terminated when

the peak inductor current reaches the threshold level

established by the Multiplier output. The Zero Current

Detector initiates the next on−time by setting the RS Latch

at the instant the inductor current reaches zero. This critical

conduction mode of operation has two significant benefits.

First, since the MOSFET cannot turn−on until the inductor

current reaches zero, the output rectifier reverse recovery

time becomes less critical, allowing the use of an

inexpensive rectifier. Second, since there are no deadtime

gaps between cycles, the ac line current is continuous, thus

limiting the peak switch to twice the average input current.

The Zero Current Detector indirectly senses the inductor

current by monitoring when the auxiliary winding voltage

falls below 1.4 V. To prevent false tripping, 200 mV of

hysteresis is provided. Figure 10 shows that the thresholds

are well−defined over temperature. The Zero Current

Detector input is internally protected by two clamps. The

upper 6.7 V clamp prevents input overvoltage breakdown

while the lower 0.7 V clamp prevents substrate injection.

Current limit protection of the lower clamp transistor is

provided in the event that the input pin is accidentally

shorted to ground. The Zero Current Detector input to

Drive Output turn−on propagation delay is typically 320 ns.

Figure 19. Inductor Current and MOSFET

Gate Voltage Waveforms

Inductor Current Average

MOSFET

Off

Peak

Current Sense Comparator and RS Latch

The Current Sense Comparator RS Latch configuration

used ensures that only a single pulse appears at the Drive

Output during a given cycle. The inductor current is

converted to a voltage by inserting a ground−referenced

sense resistor R7 in series with the source of output switch

Q1. This voltage is monitored by the Current Sense Input

and compared to a level derived from the Multiplier output.

The peak inductor current under normal operating

conditions is controlled by the threshold voltage of Pin 4

where:

Pin 4 Threshold

IL(pk ) =

Abnormal operating conditions occur during

preconverter startup at extremely high line or if output

voltage sensing is lost. Under these conditions, the

Multiplier output and Current Sense threshold will be

internally clamped to 1.5 V. Therefore, the maximum peak

switch current is limited to:

1.5 V

Ipk(max) =

An internal RC filter has been included to attenuate any

high frequency noise that may be present on the current

waveform. This filter helps reduce the ac line current

distortion especially near the zero crossings. With the

component values shown in Figure 21, the Current Sense

Comparator threshold, at the peak of the haversine varies

from 1.1 V at 90 Vac to 100 mV at 268 Vac. The Current

Sense Input to Drive Output turn−off propagation delay is

typically less than 200 ns.

Timer

A watchdog timer function was added to the IC to

eliminate the need for an external oscillator when used in

stand−alone applications. The Timer provides a means to

automatically start or restart the preconverter if the Drive

Output has been off for more than 620 ms after the inductor

current reaches zero. The restart time delay versus

temperature is shown in Figure 9.

Undervoltage Lockout and Quickstart

An Undervoltage Lockout comparator has been

incorporated to guarantee that the IC is fully functional

before enabling the output stage. The positive power

supply terminal (VCC) is monitored by the UVLO

comparator with the upper threshold set at 13 V and the

lower threshold at 8.0 V. In the stand−by mode, with VCC

at 7.0 V, the required supply current is less than 0.4 mA.

This large hysteresis and low startup current allow the

implementation of efficient bootstrap startup techniques,

making these devices ideally suited for wide input range

off−line preconverter applications. An internal 36 V

clamp has been added from VCC to ground to protect the IC

and capacitor C4 from an overvoltage condition. This

feature is desirable if external circuitry is used to delay the

startup of the preconverter. The supply current, startup, and

operating voltage characteristics are shown in Figures 14

and 15.

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A Quickstart circuit has been incorporated to optimize

converter startup. During initial startup, compensation

capacitor C1 will be discharged, holding the error amp

output below the Multiplier threshold. This will prevent

Drive Output switching and delay bootstrapping of

capacitor C4 by diode D6. If Pin 2 does not reach the

multiplier threshold before C4 discharges below the lower

UVLO threshold, the converter will “hiccup” and

experience a significant startup delay. The Quickstart

circuit is designed to precharge C1 to 1.7 V, Figure 8. This

level is slightly below the Pin 2 Multiplier threshold,

allowing immediate Drive Output switching and bootstrap

operation when C4 crosses the upper UVLO threshold.

Drive Output

The MC34262/MC33262 contain a single totem−pole

output stage specifically designed for direct drive of power

MOSFETs. The Drive Output is capable of up to ±500 mA

peak current with a typical rise and fall time of 50 ns with

a 1.0 nF load. Additional internal circuitry has been added

to keep the Drive Output in a sinking mode whenever the

Undervoltage Lockout is active. This characteristic

eliminates the need for an external gate pulldown resistor.

The totem−pole output has been optimized to minimize

cross−conduction current during high speed operation. The

addition of two 10 W resistors, one in series with the source

output transistor and one in series with the sink output

transistor, helps to reduce the cross−conduction current and

radiated noise by limiting the output rise and fall time. A

16 V clamp has been incorporated into the output stage to

limit the high state VOH. This prevents rupture of the

MOSFET gate when VCC exceeds 20 V.

APPLICATIONS INFORMATION

The application circuits shown in Figures 20, 21 and 22

reveal that few external components are required for a

complete power factor preconverter. Each circuit is a peak

detecting current−mode boost converter that operates in

critical conduction mode with a fixed on−time and variable

off−time. A major benefit of critical conduction operation

is that the current loop is inherently stable, thus eliminating

the need for ramp compensation. The application in

Figure 20 operates over an input voltage range of 90 Vac to

138 Vac and provides an output power of 80 W (230 V at

350 mA) with an associated power factor of approximately

0.998 at nominal line. Figures 21 and 22 are universal input

preconverter examples that operate over a continuous input

voltage range of 90 Vac to 268 Vac. Figure 21 provides an

output power of 175 W (400 V at 440 mA) while Figure 22

provides 450 W (400 V at 1.125 A). Both circuits have an

observed worst−case power factor of approximately 0.989.

The input current and voltage waveforms of Figure 21 are

shown in Figure 23 with operation at 115 Vac and 230 Vac.

The data for each of the applications was generated with the

test set−up shown in Figure 25.

MC34262, MC33262

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Table 1. Design Equations

Notes Calculation Formula

Calculate the maximum required output power. Required Converter Output Power PO = VO IO

Calculated at the minimum required ac line voltage

for output regulation. Let the efficiency h = 0.92 for

low line operation.

Peak Inductor Current IL(pk) = 22 P

hVac(LL)

Let the switching cycle t = 40 ms for universal input

(85 to 265 Vac) operation and 20 ms for fixed input

(92 to 138 Vac, or 184 to 276 Vac) operation. Inductance LP =

2 VO PO

VO− Vac(LL) h Vac(LL)2

ǒǓ

In theory the on−time ton is constant. In practice ton

tends to increase at the ac line zero crossings due

to the charge on capacitor C5. Let Vac = Vac(LL) for initial

ton and toff calculations.

Switch On−Time h Vac2

ton =

2 PO LP

The off−time toff is greatest at the peak of the ac line

voltage and approaches zero at the ac line zero

crossings. Theta (q) represents the angle of the ac

line voltage.

Switch Off−Time VO− 1

toff =

2 Vac ⎪Sin q⎜

ton

The minimum switching frequency occurs at the peak

of the ac line voltage. As the ac line voltage traverses

from peak to zero, toff approaches zero producing an

increase in switching frequency.

Switching Frequency f = ton + toff

Set the current sense threshold VCS to 1.0 V for

universal input (85 Vac to 265 Vac) operation and

to 0.5 V for fixed input (92 Vac to 138 Vac, or

184 Vac to 276 Vac) operation. Note that VCS must

be <1.4 V.

Peak Switch Current R7 = IL(pk)

VCS

Set the multiplier input voltage VM to 3.0 V at high

line. Empirically adjust VM for the lowest distortion

over the ac line voltage range while guaranteeing

startup at minimum line.

Multiplier Input Voltage

+ 1

Vac

Ǔǒ

VM =

The IIB R1 error term can be minimized with a divider

current in excess of 50 mA. Converter Output Voltage − IIB R2

Ǔǒ

VO = Vref

R2+ 1

The calculated peak−to−peak ripple must be less than

16% of the average dc output voltage to prevent false

tripping of the Overvoltage Comparator. Refer to the

Overvoltage Comparator text. ESR is the equivalent

series resistance of C3.

Converter Output

Peak to Peak

Ripple Voltage

2pfac C3

+ ESR2

Ǔǒ

DVO(pp) = IO

The bandwidth is typically set to 20 Hz. When operating

at high ac line, the value of C1 may need to be

increased. (See Figure 26)

Error Amplifier Bandwidth BW = gm

2 p C1

The following converter characteristics must be chosen:

VO − Desired output voltage

IO − Desired output current

DVO − Converter output peak−to−peak ripple voltage

Vac − AC RMS line voltage

Vac (LL) − AC RMS low line voltage

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0.01

Multiplier

7.5k

R311k

220

100

13V/

8.0V

MTP

8N50E

2.2M

Figure 20. 80 W Power Factor Controller

RFI

Filter

6.7V

Zero Current

Detector

UVLO

Current Sense

Comparator

Latch

1.2V

1.6V/

1.4V

36V

2.5V

Reference

16V

Drive

Output 10

Timer

Delay

92 to

138 Vac

22k

100k

R61N4934

1.0M

0.1

MUR130

230V/

0.35A

0.68

1.5V

Error Amp

Overvoltage

Comparator

+1.08 Vref

+Vref

Quickstart

10mA

10pF

20k

Power Factor Controller Test Data

AC Line Input DC Output

Current Harmonic Distortion (% Ifund)

Vrms Pin PF Ifund THD 2357V

O(pp) VOIOPOh(%)

90 85.9 0.999 0.93 2.6 0.08 1.6 0.84 0.95 4.0 230.7 0.350 80.8 94.0

100 85.3 0.999 0.85 2.3 0.13 1.0 1.2 0.73 4.0 230.7 0.350 80.8 94.7

110 85.1 0.998 0.77 2.2 0.10 0.58 1.5 0.59 4.0 230.7 0.350 80.8 94.9

120 84.7 0.998 0.71 3.0 0.09 0.73 1.9 0.58 4.1 230.7 0.350 80.8 95.3

130 84.4 0.997 0.65 3.9 0.12 1.7 2.2 0.61 4.1 230.7 0.350 80.8 95.7

138 84.1 0.996 0.62 4.6 0.16 2.4 2.3 0.60 4.1 230.7 0.350 80.8 96.0

= Coilcraft N2881−A

Primary: 62 turns of # 22 AWG

Secondary: 5 turns of # 22 AWG

Core: Coilcraft PT2510, EE 25

Gap: 0.072″ total for a primary inductance (LP) of 320 mH

= AAVID Engineering Inc. 590302B03600, or 593002B03400

Heatsink

This data was taken with the test set−up shown in Figure 25.

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0.68

1.5V

Error Amp

Overvoltage

Comparator

+1.08 Vref

Quickstart

10mA

10pF

20k

+1.6V/

1.4V

Timer R 330

100

13V/

8.0V

MTP

14N50E

1.3M

Figure 21. 175 W Universal Input Power Factor Controller

RFI

Filter

0.01

6.7V

Zero Current

Detector

UVLO

Current Sense

Comparator

Latch

1.2V

36V

2.5V

Reference

16V

Drive

Output 10

Multiplier

Delay

90 to

268 Vac

12k

22k

100k

R61N4934

10k

1.6M

0.1

MUR460

D5400V/

0.44A

Vref

Power Factor Controller Test Data

AC Line Input DC Output

Current Harmonic Distortion (% Ifund)

Vrms Pin PF Ifund THD 2357V

O(pp) VOIOPOh(%)

90 193.3 0.991 2.15 2.8 0.18 2.6 0.55 1.0 3.3 402.1 0.44 176.9 91.5

120 190.1 0.998 1.59 1.6 0.10 1.4 0.23 0.72 3.3 402.1 0.44 176.9 93.1

138 188.2 0.999 1.36 1.2 0.12 1.3 0.65 0.80 3.3 402.1 0.44 176.9 94.0

180 184.9 0.998 1.03 2.0 0.10 0.49 1.2 0.82 3.4 402.1 0.44 176.9 95.7

240 182.0 0.993 0.76 4.4 0.09 1.6 2.3 0.51 3.4 402.1 0.44 176.9 97.2

268 180.9 0.989 0.69 5.9 0.10 2.3 2.9 0.46 3.4 402.1 0.44 176.9 97.8

= Coilcraft N2880−A

Primary: 78 turns of # 16 AWG

Secondary: 6 turns of # 18 AWG

Core: Coilcraft PT4215, EE 42−15

Gap: 0.104″ total for a primary inductance (LP) of 870 mH

= AAVID Engineering Inc. 590302B03600

Heatsink

This data was taken with the test set−up shown in Figure 25.

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0.68

1.5V

Error Amp

Overvoltage

Comparator

+1.08 Vref

Quickstart

10mA

10pF

20k

+1.6V/

1.4V

Timer R 330

100

13V/

8.0V

MTW

20N50E

1.3M

Figure 22. 450 W Universal Input Power Factor Controller

RFI

Filter

0.01

6.7V

Zero Current

Detector

UVLO

Current Sense

Comparator

Latch

1.2V

36V

2.5V

Reference

16V

Drive

Output 10

Multiplier

Delay

90 to

268 Vac

12k

22k

100k

R61N4934

10k

1.6M

0.05

MUR460

D5400V/

1.125A

0.001

330

Vref

Power Factor Controller Test Data

AC Line Input DC Output

Current Harmonic Distortion (% Ifund)

Vrms Pin PF Ifund THD 2357V

O(pp) VOIOPOh(%)

90 489.5 0.990 5.53 2.2 0.10 1.5 0.25 0.83 8.8 395.5 1.14 450.9 92.1

120 475.1 0.998 3.94 2.5 0.12 0.29 0.62 0.52 8.8 395.5 1.14 450.9 94.9

138 470.6 0.998 3.38 2.1 0.06 0.70 1.1 0.41 8.8 395.5 1.14 450.9 95.8

180 463.4 0.998 2.57 4.1 0.21 2.0 1.6 0.71 8.9 395.5 1.14 450.9 97.3

240 460.1 0.996 1.91 4.8 0.14 4.3 2.2 0.63 8.9 395.5 1.14 450.9 98.0

268 459.1 0.995 1.72 5.8 0.10 5.0 2.5 0.61 8.9 395.5 1.14 450.9 98.2

= Coilcraft P3657−A

Primary: 38 turns Litz wire, 1300 strands of #48 AWG, Kerrigan−Lewis, Chicago, IL

Secondary: 3 turns of # 20 AWG

Core: Coilcraft PT4220, EE 42−20

Gap: 0.180″ total for a primary inductance (LP) of 190 mH

= AAVID Engineering Inc. 604953B04000 Extrusion

Heatsink

This data was taken with the test set−up shown in Figure 25.

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Figure 23. Power Factor Corrected Input Waveforms

(Figure 21 Circuit)

Figure 24. Output Voltage Startup Overshoot

(Figure 21 Circuit)

Input = 115 VAC, Output = 175 W Input = 230 VAC, Output = 175 W

2.0 ms/DIV 2.0 ms/DIV

Voltage = 100 V/DIV

Current = 1.0 A/DIV

Voltage = 100 V/DIV

Current = 1.0 A/DIV

Without Overvoltage Comparator

200 ms/DIV200 ms/DIV

500 V

400 V

0 V

432 V

400 V

0 V

80 V/DIV

26% 8%

With Overvoltage Comparator

Figure 25. Power Factor Test Set−Up

0.005

1.0

0.005

HARMFREQ

0.1

0 to 270 Vac

Output to Power

Factor

Controller Circuit

Earth

Line

Neutral

115 Vac

Input

RFI Test Filter

Autoformer

2X Step-Up

Isolation

Transformer

HIHI

AinstAcfVcf

ArmsVrmsPFVAW

1397

53210

Voltech

AC POWER ANALYZER

PM 1000

An RFI filter is required for best performance when connecting the preconverter directly to the ac line. The filter attenuates

the level of high frequency switching that appears on the ac line current waveform. Figures 20 and 21 work well with

commercially available two stage filters such as the Delta Electronics 03DPCG5. Shown above is a single stage test filter

that can easily be constructed with four ac line rated capacitors and a common−mode transformer. Coilcraft CMT3−28−2

was used to test Figures 20 and 21. It has a minimum inductance of 28 mH and a maximum current rating of 2.0 A. Coilcraft

CMT4−17−9 was used to test Figure 22. It has a minimum inductance of 17 mH and a maximum current rating of 9.0 A. Circuit

conversion efficiency h (%) was calculated without the power loss of the RFI filter.

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Figure 26. Error Amp Compensation

Error Amp

10mA

The Error Amp output is a high impedance node and is susceptible to noise pickup. To minimize pickup, compensation

capacitor C1 must be connected as close to Pin 2 as possible with a short, heavy ground returning directly to Pin 6. When

operating at high ac line, the voltage at Pin 2 may approach the lower threshold of the Multiplier, ≈2.0 V. If there is

excessive ripple on Pin 2, the Multiplier will be driven into cut−off causing circuit instability, high distortion and poor power

factor. This problem can be eliminated by increasing the value of C1.

Figure 27. Current Waveform Spike Suppression

10pF

22k

Current

Sense

Comparator

A narrow turn−on spike is usually present on the leading edge of

the current waveform and can cause circuit instability. The

MC34262 provides an internal RC filter with a time constant of

220 ns. An additional external RC filter may be required in

universal input applications that are above 200 W. It is

suggested that the external filter be placed directly at the Current

Sense Input and have a time constant that approximates the

spike duration.

Figure 28. Negative Current Waveform

Spike Suppression

10pF

22k

Current

Sense

Comparator

A negative turn−off spike can be observed on the trailing edge of

the current waveform. This spike is due to the parasitic

inductance of resistor R7, and if it is excessive, it can cause

circuit instability. The addition of Schottky diode D1 can

effectively clamp the negative spike. The addition of the external

RC filter shown in Figure 27 may provide sufficient spike

attenuation.

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(Top View)

Figure 29. Printed Circuit Board and Component Layout

(Circuits of Figures 20 and 21)

4.5″

3.0″

(Bottom View)

NOTE: Use 2 oz. copper laminate for optimum circuit performance.

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DEVICE ORDERING INFORMATION

Device Operating Temperature Range Package Shipping†

MC34262DG

TA = 0°C to +85°C

SOIC−8

(Pb−Free)

98 Units / Rail

MC34262DR2G SOIC−8

(Pb−Free)

2500 / Tape & Reel

MC34262PG PDIP−8

(Pb−Free)

50 Units / Rail

MC33262DG

TA = −40°C to +105°C

SOIC−8

(Pb−Free)

98 Units / Rail

MC33262DR2G SOIC−8

(Pb−Free)

2500 / Tape & Reel

MC33262PG PDIP−8

(Pb−Free)

50 Units / Rail

MC33262CDR2G SOIC−8

(Pb−Free)

2500 / Tape & Reel

†For information on tape and reel specifications, including part orientation and tape sizes, please refer to our Tape and Reel Packaging

Specifications Brochure, BRD8011/D.

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PACKAGE DIMENSIONS

PDIP−8

P SUFFIX

CASE 626−05

ISSUE M

NOTE 5

TOP VIEW

CSEATING

PLANE

0.010 CA

SIDE VIEW

END VIEW

NOTE 3

DIM MIN NOM MAX

INCHES

A−−−− −−−− 0.210

A1 0.015 −−−− −−−−

b0.014 0.018 0.022

C0.008 0.010 0.014

D0.355 0.365 0.400

D1 0.005 −−−− −−−−

e0.100 BSC

E0.300 0.310 0.325

L0.115 0.130 0.150

−−−− −−−− 5.33

0.38 −−−− −−−−

0.35 0.46 0.56

0.20 0.25 0.36

9.02 9.27 10.02

0.13 −−−− −−−−

2.54 BSC

7.62 7.87 8.26

2.92 3.30 3.81

MIN NOM MAX

MILLIMETERS

NOTES:

1. DIMENSIONING AND TOLERANCING PER ASME

Y14.5M, 1994.

2. CONTROLLING DIMENSION: INCHES.

3. DIMENSION E IS MEASURED WITH THE LEADS RE-

STRAINED PARALLEL AT WIDTH E2.

4. DIMENSION E1 DOES NOT INCLUDE MOLD FLASH.

5. ROUNDED CORNERS OPTIONAL.

E1 0.240 0.250 0.280 6.10 6.35 7.11

E3 −−−− −−−− 0.430 −−−− −−−− 10.92

0.300 BSC 7.62 BSC

e/2

MC34262, MC33262

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PACKAGE DIMENSIONS

SOIC−8

D SUFFIX

CASE 751−07

ISSUE AJ

SEATING

PLANE

X 45_

NOTES:

1. DIMENSIONING AND TOLERANCING PER

ANSI Y14.5M, 1982.

2. CONTROLLING DIMENSION: MILLIMETER.

3. DIMENSION A AND B DO NOT INCLUDE

MOLD PROTRUSION.

4. MAXIMUM MOLD PROTRUSION 0.15 (0.006)

PER SIDE.

5. DIMENSION D DOES NOT INCLUDE DAMBAR

PROTRUSION. ALLOWABLE DAMBAR

PROTRUSION SHALL BE 0.127 (0.005) TOTAL

IN EXCESS OF THE D DIMENSION AT

MAXIMUM MATERIAL CONDITION.

6. 751−01 THRU 751−06 ARE OBSOLETE. NEW

STANDARD IS 751−07.

0.10 (0.004)

DIM

MIN MAX MIN MAX

INCHES

4.80 5.00 0.189 0.197

MILLIMETERS

B3.80 4.00 0.150 0.157

C1.35 1.75 0.053 0.069

D0.33 0.51 0.013 0.020

G1.27 BSC 0.050 BSC

H0.10 0.25 0.004 0.010

J0.19 0.25 0.007 0.010

K0.40 1.27 0.016 0.050

M0 8 0 8

N0.25 0.50 0.010 0.020

S5.80 6.20 0.228 0.244

−X−

−Y−

0.25 (0.010)

−Z−

0.25 (0.010) ZSXS

____

1.52

0.060

7.0

0.275

0.6

0.024

1.270

0.050

4.0

0.155

ǒmm

inchesǓ

SCALE 6:1

*For additional information on our Pb−Free strategy and soldering

details, please download the ON Semiconductor Soldering and

Mounting Techniques Reference Manual, SOLDERRM/D.

SOLDERING FOOTPRINT*

ON Semiconductor and are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC reserves the right to make changes without further notice

to any products herein. SCILLC makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does SCILLC assume any

liability arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation special, consequential or incidental

damages. “Typical” parameters which may be provided in SCILLC data sheets and/or specifications can and do vary in different applications and actual performance may vary over

time. All operating parameters, including “Typicals” must be validated for each customer application by customer’s technical experts. SCILLC does not convey any license under

its patent rights nor the rights of others. SCILLC products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body,

or other applications intended to support or sustain life, or for any other application in which the failure of the SCILLC product could create a situation where personal injury or death

may occur. Should Buyer purchase or use SCILLC products for any such unintended or unauthorized application, Buyer shall indemnify and hold SCILLC and its officers, employees,

subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of

personal injury or death associated with such unintended or unauthorized use, even if such claim alleges that SCILLC was negligent regarding the design or manufacture of the part.

SCILLC is an Equal Opportunity/Affirmative Action Employer. This literature is subject to all applicable copyright laws and is not for resale in any manner.

MC34262/D

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Phone: 421 33 790 2910

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Phone: 81−3−5773−3850

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