UCC28019D_技术文档

UCC28019

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SLUS755–APRIL 2007

8-Pin Continuous Conduction Mode (CCM) PFC Controller

FEATURES

DESCRIPTION

•

8-pin Solution Without Sensing Line Voltage

Reduces External Components

The UCC28019 8-pin active Power Factor Correction

(PFC) controller uses the boost topology operating in

Continuous Conduction Mode (CCM). The controller

is suitable for systems in the 100 W to >2 kW range

over a wide-range universal AC line input. Startup

current during under-voltage lockout is less than 200

µA. The user can control low power standby mode

by pulling the VSENSE pin below 0.77 V.

•

Wide-Range Universal AC Input Voltage

Fixed 65-kHz Operating Frequency

Maximum Duty Cycle of 97%

Output Over/Under-Voltage Protection

Input Brown-Out Protection

Low-distortion wave-shaping of the input current

using average current mode control is achieved

without input line sensing, reducing the Bill of

Materials component count. Simple external

networks allow for flexible compensation of the

current and voltage control loops. The switching

frequency is internally fixed and trimmed to better

than ±5% accuracy at 25°C. Fast 1.5-A gate peak

current drives the external switch.

Cycle-by-Cycle Peak Current Limiting

Open Loop Detection

Low-Power User Controlled Standby Mode

APPLICATIONS

•

CCM Boost Power Factor Correction Power

Converters in the 100 W to >2 kW Range

Server and Desktop Power Supplies

Telecom Rectifiers

Industrial Electronics

Home Electronics

•

Numerous system-level protection features include

peak current limit, soft over-current, open-loop

detection,

input

brown-out,

output

over/under-voltage, a no-power discharge path on

VCOMP, and overload protection on ICOMP.

Soft-Start limits boost current during start-up. A

trimmed internal reference provides accurate

protection thresholds and regulation set-point. An

internal clamp limits the gate drive voltage to 12.5 V.

CONTENTS

•

Electrical Characteristics 3

Device Information 10

Application Information 12

Design Example 23

Additional References 43

TYPICAL APPLICATION DIAGRAM

V_OUT

EMI Filter

LINE

INPUT

Bridge

Rectifier

–

+

GND

GATE

VCC

1

2

3

4

8

7

6

5

Auxilary

Supply

ICOMP

ISENSE VSENSE

VINS

VCOMP

R_load

UCC28019

Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas

Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.

PRODUCTION DATA information is current as of publication date.

Products conform to specifications per the terms of the Texas

Instruments standard warranty. Production processing does not

necessarily include testing of all parameters.

UCC28019

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SLUS755–APRIL 2007

ORDERING INFORMATION

OPERATING TEMPERATURE

RANGE, T_A

PART NUMBER

UCC28019D

UCC28019P

PACKAGE⁽¹⁾

SOIC 8-Pin (D) ead (Pb)-Free/Green

–40°C to 125°C

Plastic DIP 8 Pin (P) Lead

(Pb)-Free/Green

(1) SOIC (D) package is available taped and reeled by adding "R" suffix the the above part number, reeled quantities are 2500 devices per

reel.

ABSOLUTE MAXIMUM RATINGS⁽¹⁾

over operating free-air temperature range (unless otherwise noted)

VALUE

–0.3 to 22

–0.3 to 16

–0.3 to 7

–24 to 7

–1 to 1

UNIT

VCC

GATE

Input voltage range

V

VINS, VSENSE, VCOMP, ICOMP

ISENSE

Input current range

VSENSE, ISENSE

Operating

mA

–55 to 150

–65 to 150

300°

Junction temperature, T_J

Lead temperature, T_SOL

Storage

°C

Soldering, 10s

(1) Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings

only and functional operation of the device at these or any other condition beyond those included under “Recommended Operating

Conditions” is not implied. Exposure to absolute-maximum-rated conditions for extended periods of time may affect device reliability.

DISSIPATION RATINGS⁽¹⁾

PACKAGE

THERMAL IMPEDANCE

JUNCTION TO AMBIENT

(°C/W)

T_A= 25°C POWER RATING (W) T_A= 85°C POWER RATING (W)

SOIC-8 (D)

PDIP-8 (P)

160

110

0.65

1

0.25

0.36

(1) Tested per JEDEC EIA/JESD 51-1. Thermal resistance is a strong function of board construction and layout. Air flow reduces thermal

resistance. This number is only a general guide. See TI document SPRA953 Thermal Metrics.

RECOMMENDED OPERATING CONDITIONS

over operating free-air temperature range (unless otherwise noted)

PARAMETER

VCC input voltage from a low-impedance source

Operating junction temperature

MIN

MAX

UNIT

V

VCC_OFF(max)+ 1 V

–40

21

T_J

125

°C

ELECTROSTATIC DISCHARGE (ESD) PROTECTION

over operating free-air temperature range (unless otherwise noted)

PARAMETER

Human Body Model (HBM)

RATING

UNIT

2

kV

V

Charged Device Model (CDM)

500

2

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ELECTRICAL CHARACTERISTICS

Unless otherwise noted, VCC = 15 V_DC, 0.1 µF from VCC to GND, -40°C ≤ T_J= T_A≤ 125°C. All voltages are with respect to

GND. Currents are positive into and negative out of the specified terminal.

PARAMETER

TEST CONDITIONS

MIN

TYP

MAX

UNIT

VCC Bias Supply

I_VCC(start)

Pre-start current

Standby current

Operating current

VCC = VCC_ON– 0.1 V

25

100

200

µA

I_VCC(stby)

VSENSE = 0.5 V

1.0

4

2.1

7

2.9

10

mA

I_{VCC(on_load)}

VSENSE = 4.5 V, C_GATE= 4.7 nF

Under Voltage Lockout (UVLO)

VCC_ON

VCC_OFF

UVLO

Turn on threshold

10.0

9

10.5

9.5

11.0

10

Turn off threshold

Hysteresis

V

0.8

1.0

1.2

Oscillator

T_A= 25°C

61.7

59

65.0

65

68.3

71

f_SW

Switching frequency,

kHz

– 40°C ≤ T_A≤ 125°C

PWM

VCOMP = 0 V, VSENSE = 5 V,

ICOMP = 6.4 V

D_MIN

Minimum duty cycle

0%

D_MAX

Maximum duty cycle

Minimum off time

VSENSE = 4.95 V

94%

100

97%

250

99.3%

600

t_OFF(min)

VSENSE = 3 V, ICOMP = 1 V

ns

System Protection

ISENSE threshold, soft over current

(SOC) ,

V_SOC

V_PCL

V_OLP

-0.66

-1.00

0.77

-0.73

-1.08

0.82

100

-0.79

-1.15

0.86

250

ISENSE threshold, peak current Limit

(PCL) ,

V

VSENSE threshold, open loop

protection (OLP),

ICOMP = 1 V, ISENSE = 0 V,

VCOMP = 1 V

Open loop protection (OLP) internal

pull-down current

VSENSE = 0.5 V

nA

VSENSE threshold, output

under-voltage detection (UVD),

V_UVD

4.63

5.12

0.76

1.4

4.75

5.25

0.82

4.87

5.38

0.88

VSENSE threshold, output

over-voltage protection (OVP),

V_OVP

ISENSE = -0.2 V

V

Input brown-out detection (IBOP)

high-to-low threshold

VINS_{BROWNOUT_th}

Input brown-out Detection (IBOP)

low-to-high threshold

VINS_{ENABLE_th}

I_{VINS_0 V}

1.5

0

1.6

VINS bias current

VINS = 0 V

±0.1

µA

V

ICOMP threshold, external overload

protection

0.6

3

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ELECTRICAL CHARACTERISTICS (continued)

Unless otherwise noted, VCC = 15 V_DC, 0.1 µF from VCC to GND, -40°C ≤ T_J= T_A≤ 125°C. All voltages are with respect to

GND. Currents are positive into and negative out of the specified terminal.

PARAMETER

TEST CONDITIONS

MIN

TYP

MAX

UNIT

Current Loop

gmi

Transconductance gain

Output linear range

T_A= 25°C

0.75

0.95

1.15

mS

µA

V

±50

4.0

ICOMP voltage during OLP

VSENSE = 0.5 V

3.7

4.3

Voltage Loop

V_REF

Reference voltage

-40°C ≤ T_A≤ 125°C

4.90

31.5

5.00

42

5.10

52.5

V

gmv

Transconductance gain

µS

Maximum sink current under normal

operation

VSENSE = 6 V, VCOMP = 4 V

21

30

38

Source current under soft start

VSENSE = 4 V, VCOMP = 0 V

VSENSE = 4 V, VCOMP = 4 V

–21

–100

–60

-30

–170

–100

-38

–250

–140

µA

Maximum source current under EDR

operation

Enhanced dynamic response, V_SENSE

low threshold, falling

4.63

4.75

4.87

V

V_SENSEinput bias current

V_COMPvoltage during OLP

1 V ≤ VSENSE ≤ 5 V

100

0.2

250

0.4

nA

V

VSENSE = 0.5 V, I_VCOMP= 0.5 mA

0

GATE Driver

GATE current, peak, sinking⁽¹⁾

GATE current, peak, sourcing⁽¹⁾

GATE rise time

C_GATE= 4.7 nF

2.0

–1.5

40

A

C_GATE= 4.7 nF

C_GATE= 4.7 nF, GATE = 2 V to 8 V

C_GATE= 4.7 nF, GATE = 8 V to 2 V

GATE = 0 A

60

40

ns

GATE fall time

25

GATE low voltage, no load

GATE low voltage, sinking

GATE low voltage, sourcing

GATE low voltage, sinking

GATE high voltage

0

0.05

0.8

GATE = 20 mA

0.3

GATE = -20 mA

–0.3

0.75

0.9

–0.8

1.2

VCC = 5 V, GATE = 5 mA

VCC = 5 V, GATE = 20 mA

VCC = 20 V, C_GATE= 4.7 nF

VCC = 11 V, C_GATE= 4.7 nF

0.2

11

V

1.5

12.5

10.5

14

GATE high voltage

9.5

11.0

VCC = VCC_OFF+ 0.2 V,

C_GATE= 4.7 nF

GATE high voltage

8.0

9.0

10.2

(1) Not tested. Characterized by design.

4

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TYPICAL CHARACTERISTICS

Unless otherwise noted, VCC = 15 V_DC, 0.1 µF from VCC to GND, T_J= T_A= 25°C. All voltages are with respect

to GND. Currents are positive into and negative out of the specified terminal.

SUPPLY CURRENT

vs

BIAS SUPPLY VOLTAGE

UVLO THRESHOLDS

vs

TEMPERATURE

4.0

3.5

3.0

2.5

2.0

1.5

1.0

0.5

12.0

11.0

10.0

9.0

VSENSE = VINS = 3V

No Gate Load

VCC Turn ON (VCC_ON

)

I_VCCTurn OFF

I_VCCTurn ON

VCC Turn OFF (VCC_OFF

)

0

8.0

0

5

10

15

20

-60

-35

-10

15

40

65

90

115 140

VCC - Bias Supply Voltage - V

T_J- Temperature - °C

Figure 1.

Figure 2.

SUPPLY CURRENT

vs

TEMPERATURE

SUPPLY CURRENT

vs

TEMPERATURE

10

9

8

7

6

5

4

3

2

1

0

0.5

VCC = VCC_ON- 0.1 V

0.4

0.3

Operating, GATE Load = 4.7 nF

I_{VCC(on_load)}

0.2

0.1

0

Standby

I_VCC(stby)

Pre-Start

(I_VCC(start)

)

-60

-35

-10

15

40

65

90

115 140

-60

-35

-10

15

40

65

90

115 140

T_J- Temperature - °C

Figure 3.

Figure 4.

5

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TYPICAL CHARACTERISTICS (continued)

OSCILLATOR FREQUENCY

vs

TEMPERATURE

OSCILLATOR FREQUENCY

vs

BIAS SUPPLY VOLTAGE

75

73

71

69

75

73

71

69

67

65

67

65

63

61

59

57

55

Switching Frequency

63

61

59

57

55

-60

-35

-10

15

40

65

90

115 140

10

12

14

16

18

20

T_J- Temperature - °C

VCC - Bias Supply Voltage - V

Figure 5.

Figure 6.

CURRENT AVERAGING

AMPLIFIER TRANSCONDUCTANCE

VOLTAGE ERROR AMPLIFIER

TRANSCONDUCTANCE

vs

TEMPERATURE

2.0

1.8

50

48

46

1.6

1.4

1.2

1.0

Gain

44

42

40

Gain

0.8

0.6

0.4

0.2

0

38

36

34

32

30

-60

-35

-10

15

40

65

90

115 140

-60

-35

-10

15

40

65

90

115 140

T_J- Temperature - °C

Figure 7.

Figure 8.

6

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TYPICAL CHARACTERISTICS (continued)

VSENSE THRESHOLD

vs

TEMPERATURE

VSENSE THRESHOLD

vs

TEMPERATURE

5.50

5.25

5.00

4.75

4.50

2.0

1.8

1.6

1.4

1.2

1.0

Over-Voltage Protection (V_OVP

)

Open Loop Protection (V_OLP

)

0.8

0.6

0.4

0.2

Under-Voltage Protection (V_UVD

)

0

-60

-35

-10

15

40

65

90

115 140

-60

-35

-10

15

40

65

T_J- Temperature - °C

90

115 140

T_J- Temperature - °C

Figure 9.

Figure 10.

VINS THRESHOLD

vs

TEMPERATURE

ISENSE THRESHOLD

vs

TEMPERATURE

0

2.0

1.8

-0.1

-0.2

-0.3

-0.4

1.6

1.4

1.2

1.0

VINS Enable (VINS_{ENABLE_TH}

)

-0.5

-0.6

Soft Over-Current Protection (SOC)

0.8

0.6

0.4

0.2

-0.7

-0.8

Input Brown-Out Protection (VINS_{BROWNOUT_TH}

)

-0.9

-1.0

0

-60

-35

-10

15

40

65

90

115 140

-60

-35

-10

15

40

65

T_J- Temperature - °C

90

115 140

T_J- Temperature - °C

Figure 11.

Figure 12.

7

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TYPICAL CHARACTERISTICS (continued)

MINIMUM OFF TIME

vs

TEMPERATURE

GATE DRIVE SWITCHING

vs

TEMPERATURE

600

550

50

45

VSENSE = 3 V

ICOMP = 1 V

C_GATE= 4.7 nF

V_GATE= 2 V - 8 V

500

450

400

350

40

35

30

25

Fall Time

300

250

200

105

100

20

15

10

5

t_OFF(min)

Rise Time

0

-60

-35

-10

15

40

65

90

115 140

-60

-35

-10

15

40

65

90

115 140

T_J- Temperature - °C

Figure 13.

Figure 14.

GATE DRIVE SWITCHING

vs

BIAS SUPPLY VOLTAGE

GATE LOW VOLTAGE

WITH DEVICE OFF

vs

TEMPERATURE

50

45

2.0

1.8

C_GATE= 4.7 nF

V_GATE= 2 V - 8 V

VCC = 5 V

I_VCC= 20 mA

40

35

30

25

1.6

1.4

1.2

1.0

V_GATE

Rise Time

20

15

10

5

0.8

0.6

0.4

0.2

0

Fall Time

0

10

12

14

16

18

20

-60

-35

-10

15

40

65

90

115 140

VCC - Bias Supply Voltage - V

T_J- Temperature - °C

Figure 15.

Figure 16.

8

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TYPICAL CHARACTERISTICS (continued)

REFERENCE VOLTAGE

vs

TEMPERATURE

5.50

VCC = 15V

5.25

Reference Voltage

5.00

4.75

4.50

-60

-35

-10

15

40

65

90

115 140

T_J- Temperature - °C

Figure 17.

9

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DEVICE INFORMATION

Connection Diagram

UCC28019 Top View (SOIC-8, PDIP-8)

GND

GATE

VCC

1

2

3

4

8

7

6

5

ICOMP

ISENSE

VINS

VSENSE

VCOMP

Pin Descriptions

Terminal Functions

TERMINAL

I/O

FUNCTION

NAME

GATE

GND

#

8

1

Gate drive: Integrated push-pull gate driver for one or more external power MOSFETs. 2.0-A sink and 1.5-A

source capability. Output voltage is clamped at 12.5 V.

O

I

Ground: Device ground reference.

Current loop compensation: Transconductance current amplifier output. A capacitor connected to GND

provides compensation and averaging of the current sense signal in the current control loop. The controller is

disabled if the voltage on ICOMP is less than 0.6 V.

ICOMP

2

Inductor current sense: An input for the voltage across the external current sense resistor, which

represents the instantaneous current through the PFC boost inductor. This voltage is averaged to eliminate

the effects of noise and ripple. Soft Over Current (SOC) limits the average inductor current. Cycle-by-cycle

peak current limit (PCL) immediately shuts off the GATE drive if the peak-limit voltage is exceeded. Use a

220-Ω resistor between this pin and the current sense resistor to limit inrush-surge currents into this pin.

ISENSE

3

Device supply: External bias supply input. Under Voltage Lock Out (UVLO) disables the controller until VCC

exceeds a turn-on threshold of 10.5 V. Operation continues until VCC falls below the turn-off (UVLO)

threshold of 9.5 V. A ceramic by-pass capacitor of 0.1 µF minimum value should be connected from VCC to

GND as close to the device as possible for high frequency filtering of the VCC voltage.

VCC

7

5

Voltage loop compensation: Transconductance voltage error amplifier output. A resistor-capacitor network

connected from this pin to GND provides compensation. VCOMP is held at GND until VCC, VINS, and

VSENSE all exceed their threshold voltages. Once these conditions are satisfied, VCOMP is charged until

the VSENSE voltage reaches 95% of its nominal regulation level. When the Enhanced Dynamic Response

(EDR) is engaged, additional current is applied to VCOMP to reduce the charge time. EDR additional current

is inhibited during soft-start. Soft-start is programmed by the capacitance on this pin.

VCOMP

O

Input ac voltage sense: Input Brown Out Protection (IBOP) detects when the system ac-input voltage is

above a user-defined normal operating level, or below a user-defined “brown-out” level. A filtered

resistor-divider network connects from this pin to the rectified-mains node. At startup the controller is disabled

until the VINS voltage exceeds a threshold of 1.5 V, initiating a soft-start. The controller is also disabled if

VINS drops below the brown-out threshold of 0.8 V. Operation will not resume until both VINS and VSENSE

voltages exceed their enable thresholds, initiating another soft-start.

VINS

4

6

I

Output voltage sense: An external resistor-divider network connected from this pin to the PFC output

voltage provides feedback sensing for output voltage regulation. A small capacitor from this pin to GND filters

high-frequency noise. Standby disables the controller and discharges VCOMP when the voltage at VSENSE

drops below the enable threshold of 0.8V. An internal 100nA current source pulls VSENSE to GND for

Open-Loop Protection (OLP), including pin disconnection. Output over-voltage protection (OVP) disables the

GATE output when VSENSE exceeds 105% of the reference voltage. Enhanced Dynamic Response (EDR)

rapidly returns the output voltage to its normal regulation level when a system line or load step causes

VSENSE to fall below 95% of the reference voltage.

VSENSE

I

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EMI Filter

L_BST

D_BST

V_OUT

LINE

INPUT

Bridge

Rectifier

–

+

R_VINS1

R_FB1

Q_BST

R_GATE

C_IN

C_OUT

R_LOAD

R_VINS2

R_FB2

10k

R_SENSE

ICOMP

2

Current

Amplifier

VCC

PWM

Comparator

_PC(s)

Gate Driver

K

C_ICOMP

+

FAULT

ICOMP

gmi

S

R

Q

+

Fault

IBOP

PWM

RAMP

M₂

Fault

Logic

Q

UVLO

OLP

GAIN

M₁

GATE

8

Min Off Time

65kHz

Oscillator

PCL

OVP

S

R

Q

Pre-Drive and

Clamp Circuit

Clock

M₂

M₁

VCOMP

EDR

Auxilary

Supply

UVLO

VCC

SOC

R_ISENSE

+

7

VCC_ON

10.5V

Q

S

ISENSE

40k

C_VCC

Peak Current Limit (PCL)

3

GND

1

R

300ns

Leading Edge

Blanking

V_PCL

1.08V

VCC_OFF

9.5V

-1x

PCL

UVLO

+

C_ISENSE

+

OVERVOLTAGE

5.25V

OVP

Soft Over Current (SOC)

OLP/STANDBY

0.82V

+

V_SOC0.73V

SOC

OLP/STANDBY

EDR

+

UNDERVOLTAGE

4.75V

Input Brown-Out Protection

(IBOP)

VINS

20k

SS

EDR

4

+

S

R

Q

VSENSE

6

VIN_{ENABLE_th}1.5V

C_VINS

5V

+

IBOP

gmv

5V

VIN_{BROWNOUT_th}0.82V

C_VSENSE

Voltage Error

Amplifier

FAULT

100µA

VCOMP

5

R_VCOMP

C_VCOMP-P

C_VCOMP

Figure 18. Block Diagram

11

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APPLICATION INFORMATION

UCC28019 Operation

The UCC28019 is a switch-mode controller used in boost converters for power factor correction operating at a

fixed frequency in continuous conduction mode. The UCC28019 requires few external components to operate as

an active PFC pre-regulator. Its trimmed oscillator provides a nominal fixed switching frequency of 65 kHz,

ensuring that both the fundamental and second harmonic components of the conducted-EMI noise spectrum are

below the EN55022 conducted-band 150-kHz measurement limit.

Its tightly-trimmed internal 5-V reference voltage provides for accurate output voltage regulation over the typical

world-wide 85 V_ACto 265 V_ACmains input range from zero to full output load. The usable system load ranges

from 100 W to 2 kW and may be extended in special situations.

Regulation is accomplished in two loops. The inner current loop shapes the average input current to match the

sinusoidal input voltage under continuous inductor current conditions. Under extremely light load conditions,

depending on the boost inductor value, the inductor current may go discontinuous but still meet Class-D

requirements of IEC 1000-3-2 despite the higher harmonics. The outer voltage loop regulates the output voltage

on VCOMP (dependent upon the line and load conditions) which determines the internal gain parameters for

maintaining a low-distortion steady-state input current waveshape.

12

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APPLICATION INFORMATION (continued)

Power Supply

The UCC28019 operates from an external bias supply. It is recommended that the device be powered from a

regulated auxiliary supply. This device is not intended to be used from a bootstrap bias supply. A bootstrap bias

supply is fed from the input high voltage through a resistor with sufficient capacitance on VCC to hold up the

voltage on VCC until current can be supplied from a bias winding on the boost inductor. The minimal hysteresis

on VCC would require an unreasonable value of hold-up capacitance.

During normal operation, when the output is regulated, current drawn by the device includes the nominal run

current plus the current supplied to the gate of the external boost switch. Decoupling of the bias supply must

take switching current into account in order to keep ripple voltage on VCC to a minimum. A ceramic capacitor

with a minimum value of 0.1 µF is recommended from VCC to GND with short, wide traces.

VCC

VCC_ON10.5V

VCC_OFF9.5V

I_VCC

I_VCC(ON)

I_VCC(stby)<2.9mA

I_VCC(start)<200µA

Controller

State

Soft-

Start

UVLO

OFF

Soft-Start

Ramp

Run

Fault/Standby

OFF

Run

UVLO

OFF

PWM

State

Regulated

Ramp Regulated

Figure 19. Device Supply States

The device bias operates in several states. During startup, VCC Under-Voltage LockOut (UVLO) sets the

minimum operational dc input voltage of the PFC controller. There are two UVLO thresholds. When the UVLO

turn-on threshold is exceeded, the controller turns ON. If VCC falls below the UVLO lower turn-off threshold, the

controller turns OFF. During UVLO, current drawn by the device is minimal. After the device turns on, Soft Start

(SS) is initiated and the output is ramped up in a controlled manner to reduce the stress on the external

components and prevents output voltage overshoot. During soft start and after the output is in regulation, the

device draws its normal run current. If any of several fault conditions is encountered or if the device is put in

Standby with an external signal, the device draws a reduced standby current.

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APPLICATION INFORMATION (continued)

Soft Start

VCOMP, the output of the voltage loop transconductance amplifier, is pulled low during UVLO, IBOP, and

OLP(Open-Loop Protection)/STANDBY. After the fault condition is released, soft start controls the rate of rise of

VCOMP in order to obtain a linear control of the increasing duty cycle as a function of time. During soft start a

constant 30 µA of current is sourced into the compensation components causing the voltage on this pin to ramp

linearly until the output voltage reaches 85% of its final value. At this point, the sourcing current begins to

decrease until the output voltage reaches 95% of its final rated voltage. The soft-start time is controlled by the

voltage error amplifier compensation components selected, and is user-programmable based on desired loop

crossover frequency. Once V_OUTexceeds 95% of rate voltage, EDR is no longer inhibited.

5V

+

gmv

VCOMP

FAULT

VSENSE

VCOMP

I_SS= -30uA

for VSENSE < 4.75V

during Soft-Start

Figure 20. Soft Start

System Protection

System level protection features keep the system in safe operating limits:

OVP 105% V_REF

100% V_REF

EDR 95% V_REF

Feedback

Voltage

OLP/SS 16% V_REF

Protection

State

Soft-Start

(No EDR)

OVP

(No Gate Output)

UVD

(EDR on)

OLP

Run

OLP

Figure 21. Output Protection States

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APPLICATION INFORMATION (continued)

VCC Under-Voltage Lockout (UVLO)

During startup, UVLO keeps the device in the off state until VCC rises above the 10.5-V enable threshold,

VCC_ON. With a typical 1 V of hysteresis on UVLO to eliminate noise, the device turns off when VCC drops to the

9.5-V disable threshold, VCC_OFF

.

VCC

Auxilary Supply

+

S

R

Q

VCC_ON10.5V

VCC_OFF9.5V

C_DECOUPLE

GND

UVLO

Figure 22. UVLO

Input Brown-Out Protection (IBOP)

The VINS, (sensed input line voltage), input provides a means for the designer to set the desired mains RMS

voltage level at which the PFC pre-regulator should start-up, V_AC(turnon), as well as the desired mains RMS level

at which it should shut down, V_AC(turnoff). This prevents unwanted sustained system operation at or below a

“brown-out” voltage, where excessive line current could overheat components. In addition, because VCC bias is

not derived directly from the line voltage, IBOP protects the circuit from low line conditions that may not trigger

the VCC UVLO turn-off.

Input Brown-Out Protection (IBOP)

R_VINS1

20k

5V

VINS

C_VINS

Rectified AC Line

+

S

R

Q

VIN_{ENABLE_th}

1.5 V

R_VINS2

C_IN

IBOP

VIN_{BROWNOUT_th}

0.82 V

+

Figure 23. Input Brown-Out Protection (IBOP)

Input line voltage is sensed directly from the rectified ac mains voltage through a resistor divider filter network

providing a scaled and filtered value at the VINS input. IBOP puts the device in standby mode when VINS falls

(high-to-low) below 0.8 V, VINS_{BROWNOUT_th}. The device comes out of standby when VINS rises (low-to-high)

above 1.5 V, VINS_{ENABLE_th}. I_{VINS_0 V}, bias current sourced from VINS, is less than 0.1 µA. With a bias current

this low, there is little concern for any set-point error caused by this current flowing through the sensing network.

The highest reasonable value resistance for this network should be chosen to minimize power dissipation,

especially in applications requiring low standby power. Be aware that higher resistance values are more

susceptible to noise pickup, but low noise PCB layout techniques can help mitigate this. Also, depending on the

resistor type used and its voltage rating, R_VINS1should be implemented with multiple resistors in series to reduce

voltage stresses.

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APPLICATION INFORMATION (continued)

First, select R_VINS1based on the the highest reasonable resistance value available for typical applications.

Then select R_VINS2based on this value:

VINS_{ENABLE _th(max)}

R_{VINS 2}= R_VINS1

2V_{AC( on )}-VINS_{ENABLE _th(max)}-V_{F _ BRIDGE}

Where V_{F_Bridge}is the forward voltage drop across the ac rectifier bridge.

Power dissipated in the resistor network is:

2

V_{IN _ RMS}

P

=

VINS

R

_VINS1+ R_{VINS 2}

The filter capacitor, C_VINS, has two functions. First, to attenuate the voltage ripple to levels between the enable

and brown-out thresholds which will prevent the ripple on VINS from falsely triggering IBOP when the converter

is operating at low line. Second, C_VINSdelays the brown-out protection operation for a desired number of line

half-cycle periods while still having a good response to an actual brown-out event.

The capacitor is chosen so that it will discharge to the VINS_{BROWNOUT_th}level after N number of half line cycles

of delay to accommodate line dropouts.

-t_{CVIN _dschg}

C_VINS

=

é

ê

ù

ú

VINS_{BROWNOUT _th(min)}

R_{VINS 2}

_VINS1+ R_{VINS 2}

R_{VINS 2}ln

0.9V_{IN _ RMS(min)}

(

)

ê

ë

ú

û

R

Where:

N_{half _cycles}

=

t_{CVINS _dschrg}

2 f_LINE(min)

and V_{IN_RMS(min)}is the lowest normal operating RMS input voltage.

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APPLICATION INFORMATION (continued)

Output Over-Voltage Protection (OVP)

V_OUT(OVP)is the output voltage exceeding 5% of the rated value, causing VSENSE to exceed a 5.25-V threshold

(5-V reference voltage + 5%), V_OVP. The normal voltage control loop is bypassed and the GATE output is

disabled until VSENSE falls below 5.25 V. For example, V_OUT(OVP)is 420 V in a system with a 400-V rated

output.

Open Loop Protection/Standby (OLP/Standby)

If the output voltage feedback components were to fail and disconnect (open loop) the signal from the VSENSE

input, then it is likely that the voltage error amp would increase the GATE output to maximum duty cycle. To

prevent this, an internal pull-down forces VSENSE low. If the output voltage falls below 16% of its rated voltage,

causing VSENSE to fall below 0.8 V, the device is put in Standby, a state where the PWM switching is halted

and the device is still on but draws standby current below 3 mA. This shutdown feature also gives the designer

the option of pulling VSENSE low with an external switch.

Output Under-Voltage Detection (UVD) / Enhanced Dynamic Response (EDR)

During large changes in load, Enhanced Dynamic Response (EDR) acts to speed up the slow response of the

low-bandwidth voltage loop.

Output Voltage

OVP

+

R_FB1

Standby

OVERVOLTAGE

5.25V

VSENSE

UVD

UNDERVOLTAGE 4.75V

+

R_FB2

OPEN LOOP

PROTECTION/

STANDBY

Optional

OLP/STANDBY

0.82V

Figure 24. Over Voltage Protection, Open Loop Protection/Standby

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APPLICATION INFORMATION (continued)

Overcurrent Protection

Inductor current is sensed by R_SENSE, a low value resistor in the return path of input rectifier. The other side of

the resistor is tied to the system ground. The voltage is sensed on the rectifier side of the sense resistor and is

always negative. There are two over-current protection features; Peak Current Limit (PCL) protects against

inductor saturation and Soft Over Current (SOC) protects against an overload on the output.

Soft Over Current (SOC)

LINE

INPUT

V_SOC0.73V

SOC

–

+

V_OUT

+

R_SENSE

ISENSE

C_ISENSE

300ns

Leading Edge

Blanking

R_ISENSE

V_PCL

1.08V

PCL

(Optional)

+

-1x

Peak Current Limit (PCL)

Figure 25. Soft Over Current (SOC) / Peak Current Limit (PCL)

Soft Over-Current (SOC)

SOC limits the input current. SOC is activated when the current sense voltage on ISENSE reaches -0.73 V,

affecting the internal VCOMP level, and the control loop is adjusted to reduce the PWM duty cycle.

Peak Current Limit (PCL)

Peak current limit operates on a cycle-by-cycle basis. When the current sense voltage on ISENSE reaches -1.08

V, PCL is activated terminating the active switch cycle. The voltage at ISENSE is amplified by a fixed gain of

-1.0 and then leading-edge blanked to improve noise immunity against false triggering.

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APPLICATION INFORMATION (continued)

Current Sense Resistor, R_SENSE

The current sense resistor, R_SENSE, is sized using the minimum threshold value of Soft Over Current (SOC),

V_SOC(min)= 0.66 V. To avoid triggering this threshold during normal operation, taking into account the gain of the

internal non-linear power limit, resulting in a decreased duty cycle, the resistor is typically sized for an overload

current of 25% more than the peak inductor peak current.

V_SOC(min)

R_SENSE

£

1.25I_{L_ PEAK(max)}

Since R_SENSEsees the average input current, worst-case power dissipation occurs at input low line when input

line current is at its maximum. Power dissipated by the sense resistor is:

P_RSENSE= ( I_{IN _ RMS (max)})²R_SENSE

Peak Current Limit (PCL) protection turns off the output driver when the voltage across the sense resistor

reaches the PCL threshold, V_PCL. The absolute maximum peak current, I_PCL, is given as:

V_PCL

=

I_PCL

R_SENSE

Gate Driver

The GATE output is designed with a current-optimized structure to directly drive large values of total MOSFET

gate capacitance at high turn-on and turn-off speeds. An internal clamp limits voltage on the MOSFET gate to

12.5 V. An external gate drive resistor, R_GATE, limits the rise time and dampens ringing caused by parasitic

inductances and capacitances of the gate drive circuit thus reducing EMI. The final value of the resistor depends

upon the parasitic elements associated with the layout and other considerations. A 10-kΩ resistor close to the

gate of the MOSFET, between the gate and ground, discharges stray gate capacitance and protects against

inadvertent dv/dt-triggered turn-on.

VCC

Rectified

AC

L _BST

UVLO

D_BST

V_OUT

VCC

From

PWM

Latch

Fault

Logic

OLP

Q_BST

IBOP

GATE

C_OUT

R_GATE

PCL

OVP

10k

S

R

Q

GND

Pre-Drive and

Clamp Circuit

Clock

Figure 26. Gate Driver

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APPLICATION INFORMATION (continued)

Current Loop

The overall system current loop consists of the current averaging amplifier stage, the pulse width modulator

(PWM) stage, the external boost inductor stage, and the external current sensing resistor.

ISENSE and ICOMP Functions

The negative polarity signal from the current sense resistor is buffered and inverted at the ISENSE input. The

internal positive signal is then averaged by the current amplifier (gmi), whose output is the ICOMP pin. The

voltage on ICOMP is proportional to the average inductor current. An external capacitor to GND is applied to the

ICOMP pin for current loop compensation and current ripple filtering. The gain of the averaging amplifier is

determined by the internal VCOMP voltage. This gain is non-linear to accommodate the world-wide ac-line

voltage range. ICOMP is connected to 4 V internally whenever the device is in a Fault or Standby condition.

Pulse Width Modulator

The PWM stage compares the ICOMP signal with a periodic ramp to generate a leading-edge-modulated output

signal which is high whenever the ramp voltage exceeds the ICOMP voltage. The slope of the ramp is defined

by a non-linear function of the internal VCOMP voltage.

The PWM output signal always starts low at the beginning of the cycle, triggered by the internal clock. The

output stays low for a minimum off-time, t_OFF(min), after which the ramp rises linearly to intersect the ICOMP

voltage. The ramp-I_COMPintersection determines t_OFF, and hence D_OFF. Since D_OFF= V_IN/V_OUTby the

boost-topology equation, and since V_INis sinusoidal in wave-shape, and since ICOMP is proportional to the

inductor current, it follows that the control loop forces the inductor current to follow the input voltage wave-shape

to maintain boost regulation. Therefore, the average input current is also sinusoidal in wave-shape.

Control Logic

The output of the PWM comparator stage is conveyed to the GATE drive stage, subject to control by various

protection functions incorporated into the IC. The GATE output duty-cycle may be as high as 99%, but will

always have a minimum off-time t_OFF(min). Normal duty-cycle operation can be interrupted directly by OVP and

PCL on a cycle-by-cycle basis. UVLO, IBOP and OLP/Standby also terminate the GATE output pulse, and

further inhibit output until the SS operation can begin.

Voltage Loop

The outer control loop of the PFC controller is the voltage loop. This loop consists of the PFC output sensing

stage, the voltage error amplifier stage, and the non-linear gain generation.

Output Sensing

A resistor-divider network from the PFC output voltage to GND forms the sensing block for the voltage control

loop. The resistor ratio is determined by the desired output voltage and the internal 5-V regulation reference

voltage.

Like the VINS input, the very low bias current at the VSENSE input allows the choice of the highest practicable

resistor values for lowest power dissipation and standby current. A small capacitor from VSENSE to GND serves

to filter the signal in a high-noise environment. This filter time constant should generally be less than 100 µs.

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APPLICATION INFORMATION (continued)

Voltage Error Amplifier

The transconductance error amplifier (gmv) generates an output current proportional to the difference between

the voltage feedback signal at VSENSE and the internal 5-V reference. This output current charges or

discharges the compensation network capacitors on the VCOMP pin to establish the proper VCOMP voltage for

the system operating conditions. Proper selection of the compensation network components leads to a stable

PFC pre-regulator over the entire ac-line range and 0-100% load range. The total capacitance also determines

the rate-of-rise of the VCOMP voltage at soft start, as discussed earlier.

The amplifier output VCOMP is pulled to GND during any Fault or Standby condition to discharge the

compensation capacitors to an initial zero state. Usually, the large capacitor has a series resistor which delays

complete discharge by their respective time constant (which may be several hundred milliseconds). If VCC bias

voltage is quickly removed after UVLO, the normal discharge transistor on VCOMP loses drive and the large

capacitor could be left with substantial voltage on it, negating the benefit of a subsequent Soft-Start. The

UCC28019 incorporates a parallel discharge path which operates without VCC bias, to further discharge the

compensation network after VCC is removed.

When output voltage perturbations greater than ±5% appear at the VSENSE input, the amplifier moves out of

linear operation. On an over-voltage, the OVP function acts directly to shut off the GATE output until VSENSE

returns within ±5% of regulation. On an under-voltage, the UVD function invokes EDR which immediately

increases the internal VCOMP voltage by 2 V and increases the external VCOMP charging current typically to

100 µA to 170 µA. This higher current facilitates faster charging of the compensation capacitors to the new

operating level, improving transient response time.

Non-linear Gain Generation

The voltage at VCOMP is used to set the current amplifier gain and the PWM ramp slope. This voltage is

buffered internally and is then subject to modification by the EDR function and the SOC function, as discussed

earlier.

Together the current gain and the PWM slope adjust to the different system operating conditions (set by the

ac-line voltage and output load level) as VCOMP changes, to provide a low-distortion, high-power-factor input

current wave-shape following that of the input voltage.

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APPLICATION INFORMATION (continued)

Layout Guidelines

As with all PWM controllers, the effectiveness of the filter capacitors on the signal pins depends upon the

integrity of the ground return. The pinout of the UCC28019 is ideally suited for separating the high di/dt induced

noise on the power ground from the low current quiet signal ground required for adequate noise immunity. A star

point ground connection at the GND pin of the device can be achieved with a simple cut out in the ground plane

of the printed circuit board. As shown in Figure 27, the capacitors on ISENSE, VINS, VCOMP, and VSENSE

(C11, C12, C15, C17, and C16, respectively) must all be returned directly to the quiet portion of the ground

plane, indicated by Signal GND, and not the high current return path of the converter, shown as the Power GND.

Because the example circuit in Figure 27 uses surface mount components, the ICOMP capacitor, C10, has its

own dedicated return to the GND pin.

Power

GND

Cut out in

ground plane

GATE

VCC

GND

ICOMP

ISENSE

VSENSE

VCOMP

VINS

Signal

GND

Figure 27. Recommended Layout for the UCC28019

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DESIGN EXAMPLE

350-W, Universal Input, 390-V_DCOutput, PFC Converter

Design Goals

This example illustrates the design process and component selection for a continuous conduction mode power

factor correction boost converter utilizing the UCC28019. The target design is a universal input, 350W PFC

designed for an ATX supply application. This design process is directly tied to the UCC28019 Design Calculator

spreadsheet that can be found in the Tools section of the UCC28019 product folder on the Texas Instruments

website.

Table 1. Design Goal Parameters

PARAMETER

Input characteristics

Input voltage

TEST CONDITION

MIN

TYP

MAX

UNIT

V_IN

85

47

115

265

VAC

Hz

Input frequency

f_LINE

63

V_AC(on)

I_OUT= 0.9 A

75

65

Brown out voltage

VAC

V_AC(off)

I_OUT= 0.9 A

Output characteristics

V_OUT

85 VAC ≤ V_IN≤ 265 VAC

47 Hz ≤ f_LINE≤ 63 Hz

0 A ≤ I_OUT≤ 0.9 A

Output voltage

370

390

410

VDC

85 VAC ≤ V_IN≤ 65VAC

I_OUT= 0.440 A

Line regulation

Load regulation

5%

V_IN= 115 VAC, f_LINE= 60 Hz

0 A ≤ I_OUT≤ 0.9 A

V_IN= 230 VAC, f_LINE= 50 Hz

0 A ≤ I_OUT≤ 0.9 A

V_RIPPLE(SW)

V_IN= 115 VAC, f_LINE= 60 Hz

I_OUT= 0.9 A

3.9

High frequency output voltage

ripple

V_RIPPLE(SW)

V_IN= 230 VAC , f_LINE= 50 Hz

I_OUT= 0.9 A

Vpp

V_{RIPPLE(f_LINE)}

V_IN= 115 VAC, f_LINE= 60 Hz,

I_OUT= 0.9 A

19.5

Line frequency output voltage

ripple

V_{RIPPLE(f_LINE)}

V_IN= 230 VAC, f_LINE= 50 Hz

I_OUT= 0.9 A

I_OUT

Output load current

85 VAC ≤ V_IN≤ 265 VAC

47 Hz ≤ f_LINE≤ 63 Hz

0.9

A

Output power

P_OUT

350

W

V

Output over voltage protection

Output under voltage protection

V_OUT(OVP)

V_OUT(UVP)

410

370

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DESIGN EXAMPLE (continued)

Table 1. Design Goal Parameters (continued)

PARAMETER

TEST CONDITION

MIN

TYP

MAX

UNIT

Control loop characteristics

Switching frequency

f_SW, T_J= 25°C

61.7

65

10

70

68.3

kHz

Hz

f_(CO)

Control loop bandwidth

Phase margin

V_IN= 162 VDC, I_OUT= 0.45 A

degrees

PF

Power factor

0.99

V_IN= 115 VAC, I_OUT= 0.9 A

THD

V_IN= 115 VAC, f_LINE= 60 Hz

I_OUT= 0.9 A

4.13%

10%

Total harmonic distortion

THD

V_IN= 230 VAC, f_LINE= 50 Hz

I_OUT= 0.9 A

6.67%

η

Full load efficiency

V_IN= 115 VAC, f_LINE= 60 Hz,

I_OUT= 0.9 A

0.92

Ambient temperature

T_AMB

50

°C

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The following procedure refers to the schematic shown in Figure 28.

Figure 28. Design Example Schematic

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Current Calculations

First, determine the maximum average output current, I_OUT(max)

:

P

OUT(max)

I_OUT(max)

=

V_OUT

350W

390V

I_OUT(max)

=

@ 0.9 A

The maximum input RMS line current, I_{IN_RMS(max)}, is calculated using the parameters from Table 1 and the

efficiency and power factor initial assumptions:

P

OUT(max)

I

=

IN _ RMS(max)

hV_IN(min)PF

350W

I

=

= 4.52A

IN _ RMS(max)

0.92´85V ´0.99

Based upon the calculated RMS value, the maximum peak input current, I_{IN_PEAK(max)}, and the maximum average

input current, I_{IN_AVG(max)}, assuming the waveform is sinusoidal, can be determined.

I_{IN _ PEAK(max)}= 2I_{IN _ RMS(max)}

I_{IN _ PEAK(max)}= 2 ´4.52A = 6.39A

2I_{IN _ PEAK(max)}

I_{IN _ AVG(max)}

=

p

2´6.39A

I_{IN _ AVG(max)}

=

= 4.07A

p

Bridge Rectifier

Assuming a forward voltage drop, V_{F_BRIDGE}, of 0.95 V across the rectifier diodes, BR1, the power loss in the

input bridge, P_BRIDGE, can be calculated:

P

= 2V_{F _ BRIDGE}I_{IN _ AVG(max)}

BRIDGE

P

= 2´0.95V ´4.07A = 7.73W

BRIDGE

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Input Capacitor

Note that the UCC28019 is a continuous conduction mode controller and as such the inductor ripple current

should be sized accordingly. Allowing an inductor ripple current, I_RIPPLE, of 20% and a high frequency voltage

ripple factor, V_{RIPPLE_IN}, of 6%, the maximum input capacitor value, C_IN, is calculated by first determining the

input ripple current, I_RIPPLE, and the input voltage ripple, V_{IN_RIPPLE(max)}

:

I

_RIPPLE= DI_RIPPLEI_{IN _ PEAK(max)}

DI_RIPPLE= 0.2

_RIPPLE= 0.2´6.39A =1.28A

V_{IN _ RIPPLE(max)}= DV_{RIPPLE _ IN}V_{IN _ RECTIFIED(max)}

DV_{RIPPLE _ IN}= 0.06

I

V_{IN _ RECTIFIED}= 2V_IN

V_{IN _ RECTIFIED(max)}= 2 ´265V = 375V

V_{IN _ RIPPLE(max)}= 0.06´375V = 7.21V

The value for the input x-capacitor can now be calculated:

I

RIPPLE

C_IN=

8 f_SWV_{IN _ RIPPLE(max)}

1.28A

8´65kHz´7.21V

C_IN=

= 0.341mF

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Boost Inductor

The boost inductor, L_BST, is selected after determining the maximum inductor peak current, I_{L_PEAK(max)}

:

I_RIPPLE

+

I_{L_ PEAK(max)}= I_{IN _ PEAK(max)}

2

1.28A

I_{L_ PEAK(max)}= 6.39A+

= 7.03A

2

The minimum value of the boost inductor is calculated based upon a worst case duty cycle of 0.5:

V_OUTD(1- D )

L_BST(min)

³

f_{SW ( typ )}I_RIPPLE

390V ´0.5(1- 0.5)

65kHz´1.28A

L_BST(min)

³

³1.17mH

The actual value of the boost inductor that will be used is 1.25 mH.

The maximum duty cycle, DUTY_(max), can be calculated and will occur at the minimum input voltage:

V_OUT-V_{IN _ RECTIFIED(min)}

=

DUTY

(max)

V_OUT

V_{IN _ RECTIFIED(min)}= 2 ´85V =120V

390V -120V

DUTY

=

= 0.692

(max)

390V

Boost Diode

The diode losses are estimated based upon the forward voltage drop, V_F, at 125°C and the reverse recovery

charge, Q_RR, of the diode. Using a silicone carbide diode, although more expensive, will essentially eliminate the

reverse recovery losses:

P

=V_{F _125C}I_OUT(max)+ 0.5 f_{SW ( typ )}V_OUTQ_RR

DIODE

V_{F _125C}=1.5V

Q_RR= 0nC

P

=1.5V ´0.897A+ 0.5´65kHz´390V ´0nC =1.35W

DIODE

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Switching Element

The conduction losses of the switch are estimated using the R_DS(on)of the FET at 125°C , found in the FET data

sheet, and the calculated drain to source RMS current, I_{DS_RMS}

:

P

= I_D²_{S _ RMS}R_{DSon(125C )}

COND

R_{DSon(125C )}= 0.35W

P

16V_{IN _ RECTIFIED(min)}

OUT(max)

I_{DS _ RMS}

=

2 -

V_{IN _ RECTIFIED(min)}

3pV_OUT

350W

120V

16´120V

3p ´390V

I_{DS _ RMS}

=

2 -

= 3.54A

P

= 3.54A²´0.35W = 4.38W

COND

The switching losses are estimated using the rise time of the gate, t_r, and the output capacitance losses.

For the selected device:

t_r= 4.5ns

C_OSS= 780pF

P

= f_{SW ( typ )}(t_rV_OUT

I

_{IN _ PEAK(max)}+ 0.5C_OSSV_O²_UT

)

SW

P

= 65kHz( 4.5ns´390V ´6.39A+ 0.5´780pF ´390V ²) = 4.59W

SW

Total FET losses:

P

_COND+ P = 4.38W + 4.59W = 8.97W

SW

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Sense Resistor

To accommodate the gain of the internal non-linear power limit, R_SENSE, is sized such that it will trigger the soft

over-current at 25% higher than the maximum peak inductor current using the minimum SOC threshold, V_SOC, of

ISENSE.

V_SOC

R_SENSE

=

I

_{L_ PEAK(max)}´1.25

0.66V

7.03A´1.25

R_SENSE

=

= 0.075W

Using a parallel combination of available standard value resistors, the sense resistor is chosen.

R_SENSE= 0.067W

The power dissipated across the sense resistor, P_Rsense, must be calculated:

P_Rsense= I_I²_{N _ RMS(max)}R_SENSE

P

= 4.52A²´0.067W =1.36W

Rsense

The peak current limit, PCL, protection feature will be triggered when current through the sense resistor results

in the voltage across R_SENSEto be equal to the V_PCLthreshold. For a worst case analysis, the maximum V_PCL

threshold is used:

V_PCL

I_PCL

=

R_SENSE

1.15V

I_PCL

=

=17.25A

0.067W

To protect the device from inrush current, a standard 220-mΩ resistor, R_ISENSE, is placed in series with the

ISENSE pin. A 1000-pF capacitor is placed close to the device to improve noise immunity on the ISENSE pin.

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Output Capacitor

The output capacitor, C_OUT, is sized to meet holdup requirements of the converter. Assuming the downstream

converters require the output of the PFC stage to never fall below 300 V, V_{OUT_HOLDUP(min)}, during one line cycle,

t_HOLDUP= 1/f_LINE(min), the minimum calculated value for the capacitor is:

2P_OUTt_HOLDUP

V_O²_UT-V_O²_{UT _ HOLDUP(min)}

C_OUT(min)

³

2´350W ´21.28ms

390V ²-300V ²

C_OUT(min)

³

³ 240mF

It is advisable to de-rate this capacitor value by 20%; the actual capacitor used is 270 µF.

Setting the maximum peak-to-peak output ripple voltage to be less than 5% of the output voltage will ensure that

the ripple voltage will not trigger the output over-voltage or output under-voltage protection features of the

controller. The maximum peak-to-peak ripple voltage, occurring at twice the line frequency, and the ripple

current of the output capacitor are calculated:

V_{OUT _ RIPPLE( pp )}< 0.05V_OUT

V_{OUT _ RIPPLE( pp )}< 0.05´390V <19.5V_PP

I_OUT

V_{OUT _ RIPPLE( pp )}

=

p( 2 f_LINE(min))C_OUT

0.9A

V_{OUT _ RIPPLE( pp )}

=

=11.26V

p( 2´47Hz )´270mF

The required ripple current rating at twice the line frequency is equal to:

I_OUT(max)

I_{Cout _2 fline}

=

2

0.9A

I_{Cout _2 fline}

=

= 0.635A

2

There will also be a high frequency ripple current through the output capacitor:

16V_OUT

I_{Cout _ HF}= I_OUT(max)

-1.5

3pV_{IN _ RECTIFIED(min)}

16´390V

I_{Cout _ HF}= 0.9A

-1.5 =1.8A

3p ´120V

The total ripple current in the output capacitor is the combination of both and the output capacitor must be

selected accordingly:

I

_{Cout _ RMS( total )}= I_C²_{out _ 2 fline}+ I_C²_{out _ HF}

I

_{Cout _ RMS( total )}= 0.635A²+1.8A²=1.9A

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Output Voltage Set Point

For low power dissipation and minimal contribution to the voltage set point error, it is recommended to use 1 MΩ

for the top voltage feedback divider resistor, R_FB1. Multiple resistors in series are used due to the maximum

allowable voltage across each. Using the internal 5-V reference, V_REF, select the bottom divider resistor, R_FB2, to

meet the output voltage design goals.

V_REFR_FB1

R_FB2

=

V_OUT-V_REF

5V ´1MW

390V -5V

R_FB2

=

=13.04kW

Using 13 kΩ for R_FB2results in a nominal output voltage set point of 391 V.

The over-voltage protection, OVD, will be triggered when the output voltage exceeds 5% of its nominal set-point:

æ

ç

è

ö

÷

ø

R

_FB1+ R_FB2

V_{OUT( OVP )}=VSENSE_OVP

R_FB2

1MW +13kW

13kW

æ

ç

è

ö

÷

ø

V_{OUT( OVP )}= 5.25V ´

= 410.7V

The under-voltage detection, UVD, will be triggered when the output voltage falls below 5% of its nominal

set-point:

æ

ç

è

ö

÷

ø

R

_FB1+ R_FB2

V_{OUT(UVD )}=VSENSE_UVD

R_FB2

1M W +13kW

13kW

æ

ç

è

ö

÷

ø

V_{OUT ( UVD )}= 4.75V ´

= 371.6V

A small capacitor on VSENSE must be added to filter out noise that would trigger the enhanced dynamic

response in a no-load high-line configuration. Limit the value of the filter capacitor such that the RC time

constant is less than 0.1ms so as not to significantly reduce the control response time to output voltage

deviations.

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Loop Compensation

The selection of compensation components, for both the current loop and the voltage loop, is made easier by

using the UCC28019 Design Calculator spreadsheet that can be found in the Tools section of the UCC28019

product folder on the Texas Instruments website. The current loop is compensated first by determining the

product of the internal loop variables, M₁M₂, using the internal controller constants K₁and K_FQ

:

I_OUT(max)V_O²_UTR_SENSE

K

1

M M =

1

2

h²V_IN²_{_ RMS}K_FQ

1

K_FQ

=

f_{SW ( typ )}

1

K_FQ

=

=15.385ms

65kHz

K = 7

1

0.9A´390V ²´0.067W´7

0.92²´115V ²´15.385ms

V

M M =

= 0.372

1

2

ms

The VCOMP operating point is found on Figure 29. The Design Calculator spreadsheet enables the user to

iteratively select the appropriate VCOMP value.

M₁M₂

vs

VCOMP

2.0

1.8

1.6

1.4

1.2

1.0

0.8

0.6

0.4

0.2

0

1

2

3

4

5

6

7

VCOMP - V

Figure 29. M₁M₂vs. VCOMP

For the given M₁M₂of 0.372 V/µs, the VCOMP, approximately equal to 4, as shown in Figure 29.

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The individual loop factors, M₁which is the current loop gain factor, and M₂which is the voltage loop PWM ramp

slope, are calculated using the following conditions:

The M₁current loop gain factor:

if : 0 <VCOMP < 2

then : M = 0.064

1

if : 2 £ VCOMP < 3

then : M = 0.139´VCOMP - 0.214

1

if : 3 £VCOMP < 5.5

then : M = 0.279´VCOMP - 0.632

1

if : 5.5 £ VCOMP < 7

then : M = 0.903

1

VCOMP = 4

M = 0.279´4 - 0.632 = 0.484

1

The M₂PWM ramp slope:

if : 0 <VCOMP <1.5

V

then : M = 0

2

ms

if : 1.5 £VCOMP < 5.6

V

then : M = 0.1223´(VCOMP -1.5)²

2

ms

if : 5.6 £VCOMP < 7

V

then : M = 2.056

2

ms

VCOMP = 4

V

M = 0.1223´( 4 -1.5)²

= 0.764

2

ms

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Verify that the product of the individual gain factors is approximately equal to the M₁M₂factor determined above,

if not, reselect VCOMP and recalculate M₁M₂.

V

M ´ M = 0.484´0.764

= 0.37

1

2

ms

V

0.37

@ M M = 0.372

1

2

ms

The non-linear gain variable, M₃, can now be calculated:

if : 0 <VCOMP < 3

then : M = 0.0510´VCOMP²- 0.1543´VCOMP - 0.1167

3

if : 3 £ VCOMP < 7

then : M = 0.1026´VCOMP²- 0.3596´VCOMP + 0.3085

3

VCOMP = 4

M = 0.1026´4²- 0.3596´4 + 0.3085 = 0.512

3

The frequency of the current averaging pole, f_IAVG, is chosen to be at 9.5 kHz. The required capacitor on

ICOMP, C_ICOMP, for this is determined using the transconductance gain, gmi, of the internal current amplifier:

gmiM

1

C_ICOMP

=

K 2p f_IAVG

1

0.95mS ´0.484

C_ICOMP

=

=1100pF

7´2´p ´9.5kHz

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The transfer function of the current loop can be plotted:

K R_SENSEV_OUT

1

G_CL( f ) =

´

s( f )²K C_ICOMP

K_FQM M L_BST

1

2

s( f )+

gmiM

1

G_CLdB( f ) = 20log G ( f )

(

CL

)

CURRENT AVERAGING CIRCUIT

100

80

-80

60

40

20

0

-100

-120

Phase

Gain

-20

-40

-140

-160

-180

-60

-80

-100

10

100

1*10³

f - Hz

1*10⁴

1*10⁵

1*10⁶

Figure 30. Bode Plot of the Current Averaging Circuit.

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The open loop of the voltage transfer function, G_VL(f) contains the product of the voltage feedback gain, G_FB

,

and the gain from the pulse width modulator to the power stage, G_{PWM_PS}, which includes the pulse width

modulator to power stage pole, f_{PWM_PS}. The plotted result is shown in Figure 31.

R_FB2

G_FB

=

R

_FB1+ R_FB2

13kW

1MW +13kW

G_FB

=

= 0.013

1

f_{PWM _ PS}

=

K R_SENSEV_O³_UTC_OUT

1

2p

K_FQM M V_IN²_{( typ )}

1

2

1

f_{PWM _ PS}

=

=1.589Hz

7´0.067W´390V ³´270mF

V

15.385ms´0.484´0.764 ´115V ²

ms

M V_OUT

3

M M ´1ms

1

2

G_{PWM _ PS}( f ) =

s( f )

1+

2p f_{PWM _ PS}

G_VL( f ) = G_FBG_{PWM _ PS}( f )

G_VLdB( f ) = 20log G ( f )

(

VL

)

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OPEN LOOP VOLTAGE TRANSFER

FUNCTION

20

0

-20

-40

0

Gain

Phase

-20

-40

-60

-80

-100

0.01

0.1

1

10

100

1*10³

1*10⁴

f - Hz

Figure 31. Bode Plot of the Open Loop Voltage Transfer Function

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The voltage error amplifier is compensated with a zero, f_ZERO, at the f_{PWM_PS}pole and a pole, f_POLE, placed at 20

Hz to reject high frequency noise and roll off the gain amplitude. The overall voltage loop crossover, f_V, is

desired to be at 10 Hz. The compensation components of the voltage error amplifier are selected accordingly.

1

f_ZERO

=

2p R_VCOMPC_VCOMP

1

f_POLE

=

R_VCOMPC_VCOMPC_{VCOMP _ P}

2p

C_VCOMP+ C_{VCOMP _ P}

é

ê

ë

ù

ú

û

1+ s( f )R_VCOMPC_VCOMP

G ( f ) = gmv

EA

é

ù

ú

æ

ö

R_VCOMPC_VCOMPC_{VCOMP _ P}

C

(

_VCOMP+ C_{VCOMP _ P}s( f ) 1+ s( f )

ê

)

ç

÷

C_VCOMP+ C_{VCOMP _ P}

ê

ë

ú

û

è

ø

f_V=10Hz

From Figure 31, and the Design Calculator spreadsheet, the open loop gain of the voltage transfer function at 10

Hz is approximately 0.709 dB. Estimating that the parallel capacitor, C_{VCOMP_P}, is much smaller than the series

capacitor, C_VCOMP, the unity gain will be at f_V, and the zero will be at f_{PWM_PS}, the series compensation capacitor

is determined:

f_V

gmv

f_{PWM _ PS}

( f )

C_VCOMP

=

G

VLdB

20

10

´2p f_V

10Hz

42mS ´

1.589Hz

C_VCOMP

=

= 3.88mF

0.709 dB

20

10

´ 2´p ´10Hz

A 3.3-µF capacitor is used for C_VCOMP

.

1

R_VCOMP

=

2p f_ZEROC_VCOMP

1

R_VCOMP

=

= 30.36kW

2´p ´1.589Hz´3.3mF

A 33-kΩ resistor is used for R_VCOMP

.

C_VCOMP

C_{VCOMP _ P}

=

2p f_POLER_VCOMPC_VCOMP-1

3.3mF

C_{VCOMP _ P}

=

= 0.258mF

2´p ´20Hz´33kW´3.3mF -1

A 0.22-µF capacitor is used for C_{VCOMP_P}

.

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The total closed loop transfer function, G_{VL_total}, contains the combined stages and is plotted in Figure 32.

G_{VL_total}( f ) = G_FB( f )G_{PWM _ PS}( f )G_EA( f )

G_{VL_totaldB}( f ) = 20log G

(

( f )

)

VL_total

CLOSED LOOP VOLTAGE TRANSFER

FUNCTION

100

50

0

80

60

Gain

-50

40

20

0

Phase

-100

-150

0.01

0.1

1

10

100

1*10³

1*10⁴

f - Hz

Figure 32. Closed Loop Voltage Bode Plot

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Brown Out Protection

Select the top divider resistor into the VINS pin so as not to contribute excessive power loss. The extremely low

bias current into VINS means the value of R_VINS1could be hundreds of megaohms. For practical purposes, a

value less than 10 MΩ is usually chosen. Assuming approximately 150 times the input bias current through the

resistor dividers will result in an R_VINS1that is less than 10 MΩ , so as to not contribute excessive noise, and still

maintain minimal power loss. The brown out protection will turn off the gate drive when the input falls below the

user programmable minimum voltage, V_AC(off), and turn on when the input rises above V_AC(on)

.

I_VINS=150´ I_{VINS _0V}

I_VINS=150´0.1mA =150mA

V_{AC( on )}= 75V

V_{AC ( off}= 65V

)

2 ´V_{AC( on )}-V_{F _ BRIDGE}-VINS_{ENABLE _th(max)}

R_VINS1

=

I_VINS

2 ´75V - 0.95V -1.6V

150mA

R_VINS1

=

= 6.9MW

A 6.5-M resistance is chosen.

VINS _{ENABLE _th(max)}´R_VINS1

R_{VINS 2}

=

2 ´V_{AC( on )}-VINS_{ENABLE _th(max)}-V_{F _ BRIDGE}

1.6V ´6.5MW

=100kW

2 ´75V -1.6V - 0.95V

R_{VINS 2}

=

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The capacitor on VINS, C_VINS, is selected so that it's discharge time is greater than the output capacitor hold up

time. C_OUTwas chosen to meet one-cycle hold-up time so C_VINSwill be chosen to meet 2.5 half-line cycles.

N_{HALF _ CYCLES}

t_{CVINS _ dischrg}

=

2´ f_LINE(min)

2.5

t_{CVINS _ dischrg}

=

= 25.6ms

2´ 47Hz

-t_{CVINS _dischrg}

C_VINS

=

é

ê

ù

ú

VINS_{BROWNOUT _th(min)}

R_{VINS 2}´ln

ê

ë

æ

ç

è

ö

÷

ø

R_{VINS 2}

R_VINS1+ R_{VINS 2}

0.9´V

´

IN _ RMS(min)

ú

û

-25.6ms

C

=

= 0.63mF

VINS

é

ê

ù

ú

0.76V

100kW´ln

100kW

æ

ç

è

ö

÷

ø

ê

0.9´85V ´

ê

ë

ú

û

6.5MW +100kW

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REFERENCES

These references, additional design tools, and links to additional references, including design software and

models may be found on the web at http://www.power.ti.com under Technical Documents.

Evaluation Module, 350-W Universal Input, 390-V_DCOutput PFC Converter, Texas Instruments Literature No.

SLUA272

Design Spreadsheet, UCC28019 Design Calculator, Texas Instruments


型号：	UCC28019D
厂家：	TEXAS INSTRUMENTS
描述：	8-Pin Continuous Conduction Mode (CCM) PFC Controller 8针连续传导模式（CCM ） PFC控制器稳压器开关式稳压器或控制器电源电路开关式控制器功率因数校正光电二极管
文件：	总48页 (文件大小：823K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

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