April 2001 TOKO, Inc.

Page 1

TK83854D

GND

PKLMT

CAOUT

ISENSE

MULTOUT

IAC

VAOUT

VRMS

GTDRV

VCC

RSET

VSENSE

ENA

Vref

ENA

OSC

7-5 V

REF

IC POWER

15 V

RUN

VSENSE

IAC

VRMS

ISENSE

RSET

GND

GTDRV

VCC

Vref

PKLMT

CAOUT

MULTOUT

VAOUT

VCC

16/10 V

7.5 V

2.5/2.25 V

14 礎

IM =

FEATURES

Control Boost PWM to 0.99 Power Factor

Limit Line Current Distortion to < 5%

Worldwide Operation without Switches

Feed-Forward Line Regulation

Low Noise Sensitivity

Pin Compatible with UC3854

(Licensed Source)

FEATURES (CONT.)

Low Start-Up Supply Current

Fixed-Frequency PWM Drive

Low-Offset Analog Multiplier/Divider

1 Amp Totem-Pole Gate Driver

Precision Voltage Reference

BLOCK DIAGRAM

TK83854

DESCRIPTION

The TK83854 provides active power factor correction for
power systems that otherwise would draw non-sinusoidal
current from sinusoidal power lines. This part implements all
the control functions necessary to build a power supply
preregulator capable of optimally using available power-line
current while minimizing line-current distortion. To do this,
the TK83854 contains a voltage amplifier, a precision
analog multiplier/divider, a current amplifier, and a fixed-
frequency PWM. In addition, the TK83854 contains a power
MOSFET gate driver, 7.5 V reference, line anticipator, load-
enable comparator, low supply detector, and overcurrent
comparator.

The TK83854 uses average current-mode control to
accomplish fixed-frequency current control with stability
and low distortion. Unlike peak current-mode control,
average current control accurately maintains sinusoidal
line current without slope compensation.

The TK83854's high reference voltage and high oscillator
amplitude minimize noise sensitivity while fast PWM
elements permit chopping frequencies above 200 kHz.
The TK83854 can be used in systems with line voltages
that vary from 75 to 275 V and with line frequencies across
the 50 Hz to 400 Hz range. To reduce the burden on the
circuitry that supplies power to this device, the TK83854

features low start-up supply current.

This device is available in the 16-pin plastic dual in-line
(DIP) package.

83854

DIP-16

HIGH POWER FACTOR PREREGULATOR

ORDERING INFORMATION

TAPE/REEL CODE

TL: Tape Left
MG: Magazine

Tape/Reel Code

TK83854

Package Code

PACKAGE CODE

D: DIP-16

Page 2

April 2001 TOKO, Inc.

TK83854D

ABSOLUTE MAXIMUM RATINGS

TK83854 ELECTRICAL CHARACTERISTICS

Test conditions: V

= 18 V, R

SET

= 15 k to GND, C

= 1.5 nF, PKLMT

= 1 V, ENA = 7.5 V, V

RMS

= 1.5 V, IAC

= 100 礎,

SENSE

= 0 V, V

OUT(CA)

= 3.5 V, V

OUT(VA)

= 5 V, V

SENSE

= 7.5 V, No load on SS, CA

OUT

, VA

OUT

, V

ref

, GTDRV, T

= Operating

Temperature Range, unless otherwise specified.

Supply Voltage ......................................................... 35 V
Power Dissipation TK83854D (Note 1) ...................... 1 W
GTDRV Current (Continuous) ................................... 0.5 A
GTDRV Current (50% Duty Cycle) ........................... 1.5 A
Input Voltage (V

SENSE,

RMS

) ...................................... 11 V

Input Voltage (ENA, I

SENSE

, MULTOUT) .................... 11 V

Input Voltage (PKLMT) ................................................ 5 V

Input Voltage (IAC, R

SET

, PKLMT) ......................... 10 mA

Storage Temperature Range ...................... -55 to +150 癈
Operating Temperature Range ........................ 0 to +70 癈
Junction Temperature ........................................... 150 癈
Lead Soldering Temperature (10 s) ........................ 235 癈

Note 1: Power dissipation is 1 W when mounted as recommended. Derate at 8 mW/癈 for operation above 25癈.
Gen. Note: All voltages with respect to GND (Pin 1).
Gen. Note: All currents are positive into the specified terminal.

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April 2001 TOKO, Inc.

Page 3

TK83854D

Note 3: Guaranteed by design; not 100% tested.
Gen Note: ENA input is internally clamped to approximately 14 V.

TK83854 ELECTRICAL CHARACTERISTICS (CONT.)

Test conditions: V

= 18 V, R

SET

= 15 k to GND, C

= 1.5 nF, PKLMT

= 1 V, ENA = 7.5 V, V

RMS

= 1.5 V, IAC

= 100 礎,

SENSE

= 0 V, V

OUT(CA)

= 3.5 V, V

OUT(VA)

= 5 V, V

SENSE

= 7.5 V, No load on SS, CA

OUT

, VA

OUT

, V

ref

, GTDRV, T

= Operating

Temperature Range, unless otherwise specified.

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Page 4

April 2001 TOKO, Inc.

TK83854D

Note 4: Multiplier gain constant (K) is defined by IOM = [K x I

IAC

x (V

OUT(VA)

- 1)] / V

RMS

TK83854 ELECTRICAL CHARACTERISTICS (CONT.)

Test conditions: V

= 18 V, R

SET

= 15 k to GND, C

= 1.5 nF, PKLMT

= 1 V, ENA = 7.5 V, V

RMS

= 1.5 V, IAC

= 100 礎,

SENSE

= 0 V, V

OUT(CA)

= 3.5 V, V

OUT(VA)

= 5 V, V

SENSE

= 7.5 V, No load on SS, CA

OUT

, VA

OUT

, V

ref

, GTDRV, T

= Operating

Temperature Range, unless otherwise specified.

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April 2001 TOKO, Inc.

Page 5

TK83854D

10 k

100

10 k

10 nF

0.1 nF

0.39 nF

1.0 nF

0.01 nF

8.2 k

10 k

15 k

100

10 礔

0.1 礔

GND

PKLMT

CAOUT

ISENSE

MULT

IAC

VAOUT

V RMS

GTDRV

VCC

RSET

VSENSE

ENA

Vref

PKLMT

CAOUT

IAC

MULTOUT

VAOUT

VRMS

ENA

VCC

7.5 V

IM = (AB) / C

TYPICAL PERFORMANCE CHARACTERISTICS

= T

= 25 癈

TEST CIRCUIT

MULTOUT

(礎)

400

MULTIPLIER OUTPUT vs.

VOLTAGE ON MULTIPLIER

IAC (礎)

0 200 400 600 800

200

600

VAOUT = 5 V
V(rms) = 2 V

MULTOUT = 3 V

MULTOUT = 0 V

MULTOUT = 1 V

MULTOUT = 2 V

0.1 1 10 100 1000 10000

FREQUENCY (kHz)

OL(CA)

(dB)AND PHASE MARGIN ( )

120

100

PHASE MARGIN

OPEN LOOP GAIN

CURRENT AMPLIFIER GAIN AND

PHASE vs. FREQUENCY

-20

0.1 1 10 100 1000 10000

FREQUENCY (kHz)

OL(VA)

(dB)AND PHASE MARGIN ( )

120

100

PHASE MARGIN

OPEN LOOP GAIN

VOLTAGE AMPLIFIER GAIN AND

PHASE vs. FREQUENCY

-20

0 10 100

RSET (k

)

DUTY CYCLE (%)

100

GATE DRIVE MAXIMUM DUTY

CYCLE vs. RSET

FREQUENCY (kHz)

RSET (k

)

1 10 100

1000

100

100 pF

OSCILLATOR FREQUENCY

VS.

RSET AND CT

200 pF

500 pF

10 nF

5 nF

1 nF

2 nF

3 nF

t R(G)

/ t

F(G)

(ns)

100

500

GATE DRIVE RISE AND FALL TIMES

vs. LOAD CAPACITANCE

CLOAD (礔)

0 .01 .02 .03 .04 .05

300

700

FALL TIME

RISE TIME

April 2001 TOKO, Inc.

Page 7

TK83854D

PIN DESCRIPTION

GROUND PIN (GND)

All voltages are measured with respect to GND. V

and

ref

should be bypassed directly to GND with a 0.1 礔 or

larger ceramic capacitor. The timing capacitor discharge
current also returns to this pin, so the lead from the
oscillator timing capacitor to GND should also be as short
and as direct as possible.

PEAK LIMIT (PKLMT)

The threshold for PKLMT is GND. Connect this input to the
negative voltage on the current sense resistor as shown in
Figure 1. Use a resistor to V

ref

to offset the negative current

sense signal up to GND.

CURRENT AMPLIFIER OUTPUT (CA

OUT

)

This is the output of a wide-bandwidth op-amp that senses
line current and commands the Pulse Width Modulator
(PWM) to force the correct current. This output can swing
close to GND, allowing the PWM to force zero duty cycle
when necessary. The current amplifier will remain active
even if the IC is disabled.

CURRENT SENSE MINUS (I

SENSE

)

This is the inverting input to the current amplifier. This input
and the non-inverting input MULT

OUT

remain functional

down to and below GND. Care should be taken to avoid
taking these inputs below �0.5 V, because they are
protected with diodes to GND.

MULTIPLIER OUTPUT AND CURRENT SENSE PLUS
(MULT

OUT

)

The output of the analog multiplier and the non-inverting
input of the current amplifier are connected together at
MULT

OUT

. The cautions about taking I

SENSE

below �0.5 V

also apply to MULT

OUT

. As the multiplier output is a

current, this is a high impedance input similar to I

SENSE

, so

the current amplifier can be configured as a differential
amplifier to reject GND noise. Figure 1 shows an example
of using the current amplifier differentially.

INPUT AC CURRENT (IAC)

This input to the analog multiplier is a current. The multiplier
is tailored for very low distortion from this current input (IAC
to MULT

OUT

), so this is the only multiplier input that should

be used for sensing instantaneous line voltage. The nominal
voltage on IAC is 6 V, so in addition to a resistor from IAC
to rectified line, connect a resistor from IAC to V

ref

. If the

resistor to V

ref

is one-fourth of the value of the resistor to

the rectifier, then the 6 V offset will be cancelled, and the
line current will have minimal crossover distortion.

VOLTAGE AMPLIFIER OUTPUT (VA

OUT

)

This is the output of the op-amp that regulates output
voltage. Like the current amplifier, the voltage amplifier will
also stay active even if the IC is disabled with either ENA
or V

. This means that large feedback capacitors across

the amplifier will stay charged through momentary disable
cycles. Voltage amplifier output levels below ~1 V will
inhibit multiplier output.

RMS LINE VOLTAGE (V(rms))

The output of a boost PWM is proportional to the input
voltage, so when the line voltage into a low-bandwidth
boost PWM voltage regulator changes, the output will
change immediately and slowly recover to the regulated
level. For these devices, the V(rms) input compensates for
line voltage changes if it is connected to a voltage
proportional to the RMS input line voltage. For best control,
the V

RMS

voltage should stay between 1.5 V and 3.5 V.

VOLTAGE REFERENCE OUTPUT (V

ref

)

ref

is the output of an accurate 7.5 V voltage reference.

This output is capable of delivering 10 mA to peripheral
circuitry and is internally short circuit current limited. V

ref

disabled and will remain at 0 V when V

is low or when

ENA is low. Bypass V

ref

to GND with a 0.1 礔 or larger

ceramic capacitor for best stability.

ENABLE (ENA)

ENA is a logic input that will enable the PWM output,
voltage reference, and oscillator. ENA also will release the
soft start clamp, allowing SS to rise. When unused, connect
ENA to a +5 V supply or pull ENA high with a 22 k resistor.
The ENA pin is not intended to be used as a high-speed
shutdown to the GTDRV output.

Page 8

April 2001 TOKO, Inc.

TK83854D

VOLTAGE AMPLIFIER INVERTING OUTPUT (V

SENSE

)

This is normally connected to a feedback network and to
the boost converter output through a divider network.

OSCILLATOR CHARGING CURRENT AND MULTIPLIER
LIMIT SET (R

SET

)

A resistor from R

SET

to ground will program oscillator

charging current and maximum multiplier output. Multiplier
output current will not exceed 3.75 V divided by the resistor
from R

SET

to ground.

SOFT-START (SS)

SS will remain at GND as long as the IC is disabled or V

is too low. SS will pull up to over 8 V by an internal 14 礎
current source when both V

becomes valid and the IC is

enabled. SS will act as the reference input to the voltage
amplifier if SS is below V

ref

. With a large capacitor from SS

to GND, the reference to the voltage regulating amplifier
will rise slowly, and increase the PWM duty cycle slowly.
In the event of a disable command or a supply dropout, SS
will quickly discharge to ground and disable the PWM.

OSCILLATOR TIMING CAPACITOR (C

)

A capacitor from C

to GND will set the PWM oscillator

frequency according to this relationship:

OSC

= 1.25 / (R

SET

x C

)

POSITIVE SUPPLY VOLTAGE (V

)

Connect V

to a stable source of at least 20 mA above 17

V for normal operation. Also bypass V

directly to GND to

absorb supply current spikes required to charge external
MOSFET gate capacitances. To prevent inadequate
GTDRV signals, these devices will be inhibited unless V

exceeds the upper undervoltage lockout threshold and
remains above the lower threshold.

GATE DRIVER (GTDRV)

The output of the PWM is a totem pole MOSFET gate
driver on GTDRV. This output is internally clamped to
15 V so the IC can be operated with V

as high as 35 V.

Use a series gate resistor of at least 5 ohms to prevent

PIN DESCRIPTION (CONT.)

interaction between the gate impedance and the GTDRV
output driver that might cause the GTDRV output to
overshoot excessively. Some overshoot of the GTDRV
output is always expected when driving a capacitive load.

April 2001 TOKO, Inc.

Page 9

TK83854D

APPLICATION INFORMATION

A 250 W PREREGULATOR

Figure 1 shows a typical application of the TK83854 as a
preregulator with high power factor and efficiency. The
assembly consists of two distinct parts, the control circuit
centering on the TK83854 and the power section.

The power section is a "boost" converter, with the inductor
operating in the continuous mode. In this mode, the duty
cycle is dependent on the ratio between input and output
voltages. Also, the input current has low switching frequency
ripple, which means that the line noise is low. Furthermore,
the output voltage must be higher than the peak value of
the highest expected AC line voltage, and all components
must be rated accordingly.

In the control section, the TK83854 provides PWM pulses
to the power MOSFET gate (GTDRV, Pin 16). The duty
cycle of this output is simultaneously controlled by four
separate inputs to the chip:

INPUT

PIN #

FUNCTION

SENSE

11 Output DC Voltage

IAC

Line Voltage Waveform

SENSE

/MULT

OUT

4/5 Line Current

RMS

8 RMS Line Voltage

Additional controls of an auxiliary nature are provided.
They are intended to protect the switching power MOSFET
from certain transient conditions, as follows:

INPUT

PIN #

FUNCTION

ENA 10 Start-up Delay

SS 13 Soft Start

PKLMT

Maximum Current Limit

PROTECTION INPUTS

Enable (ENA)

The ENA input must reach 2.5 V before the V

ref

and

GTDRV outputs are enabled. This provides a means to
shut down the gate in case of trouble, or to add a time delay
at power up. A hysteresis gap of 200 mV is provided at this
terminal to prevent erratic operation. Undervoltage
protection is provided directly at Pin 15, where the on/off
thresholds are 16 V and 10 V, respectively.

Soft-Start (SS)

The voltage at Pin 13 (SS) can reduce the reference
voltage used by the error amplifier to regulate the output
DC voltage. With Pin 13 open, the reference voltage is
typically 7.5 V. An internal current source delivers
approximately 14 礎 from Pin 13. Thus, a capacitor
connected between that pin and GND will charge linearly
from zero to 7.5 V in 0.54 x C seconds, with C expressed
in microfarads.

Peak Current Limit (PKLMT)

Use Pin 2 to establish the highest value of current to be
controlled by the power MOSFET. With the resistor divider
values shown in Figure 1, the 0.0 V threshold at Pin 2 is
reached when the voltage drop across the 0.25

current

sense resistor is 7.5 V x 1.6 k / 10 k = 1.2 V, corresponding
to 4.8 A. A bypass capacitor from Pin 2 to ground is
recommended to filter out very high frequency noise.

CONTROL INPUTS

Output DC Voltage Sense (V

SENSE

)

The threshold voltage for the V

SENSE

input is 7.5 V and the

input bias current is typically -10 nA. The values shown in
Figure 1 are for an output voltage of 400 VDC. In this
circuit, the voltage amplifier operates with a constant low
frequency gain for minimum output excursions. The
0.047 礔 feedback capacitor places a 15 Hz pole in the
voltage loop that prevents 120 Hz ripple from propagating
to the output current.

Line Waveform (IAC)

In order to force the line current waveshape to follow the
line voltage, a sample of the power line voltage waveform
is introduced at Pin 6. This signal is multiplied by the output
of the voltage amplifier in the internal multiplier to generate
a reference signal for the current control loop.

This input is not a voltage, but a current (hence IAC). It is
set up by the 220 k and 910 k resistive divider (see Figure
1). The voltage at pin 6 is internally held at 6 V, and the two
resistors are chosen so that the current flowing into pin 6
varies from zero (at each zero crossing) to about 400 礎
at the peak of the waveshape. The following formulas were

Page 10

April 2001 TOKO, Inc.

TK83854D

used to calculate these resistors:

IAC

= V

PK(MAX)

/ 400 E - 6

= (260 VAC x 2 ) / 400 礎

= 910 k

REF

= R

IAC

/ 4 = 220 k

where V

is the peak line voltage.

Line Current (I

SENSE

/MULTOUT )

The voltage drop across the 0.25 W current-sense resistor
is applied to Pins 4 and 5 as shown. The current-sense
amplifier also operates with high low-frequency gain, but
unlike the voltage amplifier, it is set up to give the current-
control loop a very wide bandwidth. This enables the line
current to follow the line voltage as closely as possible. In
the present example, this amplifier has a zero at about 500
Hz, and a gain of about 18 dB thereafter.

RMS Line Voltage (V

RMS

)

An important feature of the TK83854 preregulator is that it
can operate with a three-to-one range of input line voltages,
covering everything from low line in Japan (85 VAC) to
high line in Europe (255 VAC). This is done using line feed-
forward, which keeps the input power constant with varying
input voltage (assuming constant load power). To do this,
the multiplier divides the line current by the square of the
rms value of the line voltage. The voltage applied to Pin 8,
proportional to the average of the rectified line voltage (and
proportional to the RMS value), is squared in the TK83854,
and then used as a divisor by the multiplier block. The
multiplier output, at Pin 5, is a current that increases with
the current at Pin 6 and the voltage at Pin 7, and decreases
with the square of the voltage at pin 8.

PWM Frequency

The PWM oscillator frequency in Figure 1 is 100 kHz. This
value is determined by C

at Pin 14 and R

SET

at Pin 12.

SET

should be chosen first because it affects the maximum

value of I

according to the equation:

OM(MAX)

= -3.75 V / R

SET

This effectively sets a maximum PWM-controlled current.

APPLICATION INFORMATION (CONT.)

With R

SET

= 15 k:

OM(MAX)

= -3.75 V / 15 k = -250 礎

It is also important to note that the multiplier output current
will never exceed twice IAC.

With the 3.9 k resistor from MULT

OUT

to the 0.25

current

sense resistor, the maximum current in the current sense
resistor will be:

RCS(MAX)

= (-I

OM(MAX)

x 3.9 k) / 0.25

= -3.9 A

Having selected R

SET

, the current sense resistor, and the

resistor from MULT

OUT

to the current sense resistor,

calculate C

for the desired PWM oscillator frequency from

the equation:

= 1.25 / (f

OSC

x R

SET

)

April 2001 TOKO, Inc.

Page 11

TK83854D

APPLICATION INFORMATION (CONT.)

ENA

OSC

7-5 V

REF

IC POWER

15 V

RUN

VSENSE

IAC

VRMS

ISENSE

RSET

GND

GTDRV

VCC

Vref

PKLMT

MULTOUT

VAOUT

C10

0.01 礔

220 礔

C16

1 礔

0.47 礔

R10

20 K

C12

0.1 礔

91 K

R25

910 K

R12

27 K

R13

75 K

R20

3 K

R27

8.2 M

R21

24 K

R23

470 K

R22

30 K

1N4746A

1N4148

ZVN4206A

0.47 礔

1KBU8J

TH1

KC015L

0.47 礔

1N5406

1 mH

C14

0.1 礔

C17

0.1 礔

D12

MUR110

D13 1N4148

D11 MUR110

240 K

C6 0.047 礔

0.25

3.9 K

1N5817

3.9 K

1.6 K

C3 270 pF

C13

68 pF

D10 1N4737

C15 680 pF

D8 1N5817

R29 10 K

24 K

C4 1 礔

R16

R18

10 K

R17

511 K

330 礔

MUR860

IRF840

1N5821

C11

1000 pF

R14
15 k

ILIMIT

14 礎

7.5 V

2.5 V

16 V

VCC

R28

220 K

IM =

VOUT

385 VDC

TIP50GE

6 A

FIGURE 1: 250 W PREREGULATOR

Page 12

April 2001 TOKO, Inc.

TK83854D

Marking Information

Marking
TK83854

83854

PACKAGE OUTLINE

Printed in the USA

TOKO AMERICA REGIONAL OFFICES

Toko America, Inc. Headquarters
1250 Feehanville Drive, Mount Prospect, Illinois 60056
Tel: (847) 297-0070 Fax: (847) 699-7864

IC-167-TK83854

0798O0.0K

Visit our Internet site at http://www.tokoam.com

The information furnished by TOKO, Inc. is believed to be accurate and reliable. However, TOKO reserves the right to make changes or improvements in the design, specification or manufacture of its
products without further notice. TOKO does not assume any liability arising from the application or use of any product or circuit described herein, nor for any infringements of patents or other rights of
third parties which may result from the use of its products. No license is granted by implication or otherwise under any patent or patent rights of TOKO, Inc.

DIP-16

2.54

0.5

4.2

3.2

0.25

19.05

0.5 min

7.62

0 ~15

3.3

6.35

Dimensions are shown in millimeters
Tolerance: x.x = 0.2 mm (unless otherwise specified)

0.3

0.25

+0.1
5
-0.05

Marking

Country of Origin

Lot Number

Western Regional Office
Toko America, Inc.
2480 North First Street , Suite 260
San Jose, CA 95131
Tel: (408) 432-8281
Fax: (408) 943-9790

Midwest Regional Office
Toko America, Inc.
1250 Feehanville Drive
Mount Prospect, IL 60056
Tel: (847) 297-0070
Fax: (847) 699-7864

Semiconductor Technical Support
Toko Design Center
4755 Forge Road
Colorado Springs, CO 80907
Tel: (719) 528-2200
Fax: (719) 528-2375

协谢械泻褌褉芯薪薪褘泄 泻芯屑锌芯薪械薪褌: tk83854d

协谢械泻褌褉芯薪薪褘泄泻芯屑锌芯薪械薪褌: tk83854d