NCP1054P136_技术文档

NCP1050, NCP1051,

NCP1052, NCP1053,

NCP1054, NCP1055

Monolithic High Voltage

Gated Oscillator Power

Switching Regulator

The NCP1050 through NCP1055 are monolithic high voltage

regulators that enable end product equipment to be compliant with low

standby power requirements. This device series combines the required

converter functions allowing a simple and economical power system

solution for office automation, consumer, and industrial products.

These devices are designed to operate directly from a rectified AC line

source. In flyback converter applications they are capable of providing

an output power that ranges from 6.0 W to 40 W with a fixed AC input

of 100 V, 115 V, or 230 V, and 3.0 W to 20 W with a variable AC input

that ranges from 85 V to 265 V.

This device series features an active startup regulator circuit that

eliminates the need for an auxiliary bias winding on the converter

transformer, fault detector and a programmable timer for converter

overload protection, unique gated oscillator configuration for extremely

fast loop response with double pulse suppression, power switch current

limiting, input undervoltage lockout with hysteresis, thermal shutdown,

and auto restart fault detection. These devices are available in

economical 8−pin dual−in−line and 4−pin SOT−223 packages.

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MARKING

DIAGRAMS

8

NCP105XZ

AWL

YYWW

DIP−8

CASE 626A

P SUFFIX

8

1

Pin: 1.

2.

V

CC

Control Input

3, 7−8. Ground

4.

No Connection

5.

Power Switch Drain

4

Features

SOT−223

CASE 318E

ST SUFFIX

4

N5XZ

ALYW

• Startup Circuit Eliminates the Need for Transformer Auxiliary Bias

Winding

1

• Optional Auxiliary Bias Winding Override for Lowest Standby

Power Applications

• Converter Output Overload and Open Loop Protection

• Auto Restart Fault Protection

• IC Thermal Fault Protection

Pin: 1. V

CC

2. Control Input

3. Power Switch Drain

4. Ground

• Unique, Dual Edge, Gated Oscillator Configuration for Extremely

X

Z

A

= Current Limit (0, 1, 2, 3, 4, 5)

= Oscillator Frequency (A, B, C)

= Assembly Location

Fast Loop Response

• Oscillator Frequency Dithering with Controlled Slew Rate Driver for

Reduced EMI

• Low Power Consumption Allowing European Blue Angel Compliance

WL, L = Wafer Lot

YY, Y = Year

WW, W = Work Week

• On−Chip 700 V Power Switch Circuit and Active Startup Circuit

• Rectified AC Line Source Operation from 85 V to 265 V

• Input Undervoltage Lockout with Hysteresis

ORDERING INFORMATION

See detailed ordering and shipping information on page 22 of

• Oscillator Frequency Options of 44 kHz, 100 kHz, 136 kHz

this data sheet.

Typical Applications

• AC−DC Converters

• Wall Adapters

• Portable Electronic Chargers

• Low Power Standby and Keep−Alive Supplies

Semiconductor Components Industries, LLC, 2003

1

Publication Order Number:

July, 2003 − Rev. 7

NCP1050/D

NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

+

AC Line

Input

+

Snubber

+

Converter

DC Output

−

5

Power Switch Circuit Output

V

CC

Startup & V

CC

Regulator Circuit

+

1

Power

Switch

Circuit

Fault Detector

2

Control Input

Oscillator &

Gating Logic

Ground 3, 7−8

Figure 1. Typical Application

Pin Function Description

(SOT−223)

(DIP−8)

Function

Description

This is the positive supply voltage input. During startup, power is supplied to this input

1

V

CC

from Pin 5. When V reaches V (on), the Startup Circuit turns off and the output is

CC

allowed to begin switching with 1.0 V hysteresis on the V pin. The capacitance

CC

connected to this pin programs fault timing and frequency modulation rate.

2

4

2

Control Input

The Power Switch Circuit is turned off when a current greater than approximately

50 m A is drawn out of or applied to this pin. A 10 V clamp is built onto the chip to

protect the device from ESD damage or overvoltage conditions.

3, 7, 8

Ground

This pin is the control circuit and Power Switch Circuit ground. It is part of the

integrated circuit lead frame.

−

3

4

5

No Connection

Power Switch

Drain

This pin is designed to directly drive the converter transformer primary, and internally

connects to Power Switch and Startup Circuit.

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2

NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

+

AC Line

Input

Snubber

+

Converter

DC Output

−

Power Switch Circuit Output

V

CC

Startup

Circuit

Startup/V Reg

+

CC

10 V

+

−

Fault

Detector

Internal

Bias

+

V

Bypass/

7.5/8.5 V

CC

Fault Timing/

Sweep

Control

Fault

Latch

S

V

CO

Power

Switch

Circuit

Thermal

Shutdown

Undervoltage

Lockout

Q

−

+

R

Driver

+

4.5 V

V

CC

Oscillator

I

H

= 10 m A

Turn On

Latch

48 m A

Turn Off

Latch

R

Q

Ck

+

2.6 V

S

Q

Control

Input

R

10 V

Leading Edge

Blanking

+

−

+

3.3 V

+

Current Limit

Comparator

R

SENSE

I

H

= 10 m A

48 m A

Ground

Figure 2. Representative Block Diagram

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3

NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

f

OSC (high)

8.5 V

7.5 V

f

OSC (low)

V

CC

Oscillator Duty

Cycle

Oscillator Clock

47.5 m A

37.5 m A

I

CONTROL, SINK

0

m A

Leading Edge On

Feedback Off

Leading Edge On

Duty Cycle Off

Leading Edge On

Duty Cycle Off

Leading Edge On

Current Limit Off

Delay On

Duty Cycle Off

No Second

Pulse

Power Switch

Circuit Gate Drive

Current Limit

Threshold

Primary Current

Current Limit

Propagation

Delay

Figure 3. Timing Diagram for Gated Oscillator with Dual Edge PWM

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4

NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

I

, Current Measurement

CC1

I

, Current Measurement

CC2

V

CC(on)

Hysteretic Regulation

V

CC(off)

V

CC

V

CC(reset)

I

, Current Measurement

CC3

0 V

6.3 mA

I

(start)

0 mA

I

CC1

I

CC2

CC

CC3

0 mA

I

(start)

47.5 m A

37.5 m A

I

CONTROL, SINK

0

m

A

V

(pin 5)

Fault Removed

Fault Applied

Figure 4. Non−Latching Fault Condition Timing Diagram

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5

NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

MAXIMUM RATINGS (Note 1)

Rating

Symbol

Value

Unit

Power Switch and Startup Circuit

Drain Voltage Range

Drain Current Peak During Transformer Saturation

V

*0.3 to 700

V

A

DS

I

2.0 I Max

DS(pk)

lim

Power Supply/V Bypass and Control Input

CC

Voltage Range

Current

V

*0.3 to 10

V

mA

IR

I

100

max

Thermal Characteristics

°C/W

P Suffix, Plastic Package Case 626A−01

Junction−to−Lead

Junction−to−Air, 2.0 Oz. Printed Circuit Copper Clad

0.36 Sq. Inch

R

9.0

q

JL

q

JA

77

60

1.0 Sq. Inch

ST Suffix, Plastic Package Case 318E−04

Junction−to−Lead

R

14

q

JL

Junction−to−Air, 2.0 Oz. Printed Circuit Copper Clad

0.36 Sq. Inch

1.0 Sq. Inch

R

q

JA

74

55

Operating Junction Temperature

Storage Temperature

T

*40 to +150

*65 to +150

°C

J

T

stg

1. Maximum Ratings are those values beyond which damage to the device may occur. Exposure to these conditions or conditions beyond those

indicated may adversely affect device reliability. Functional operation under absolute maximum−rated conditions is not implied. Functional

operation should be restricted to the Recommended Operating Conditions.

A. This device series contains ESD protection and exceeds the following tests:

Pins 1−3: Human Body Model 2000 V per MIL−STD−883, Method 3015.

Machine Model Method 400 V.

Pin 5: Human Body Model 1000 V per MIL−STD−883, Method 3015.

Machine Model Method 400 V.

Pin 5 is connected to the power switch and start−up circuits, and is rated only to the max voltage of the part, or 700 V.

B. This device contains Latch−up protection and exceeds $100 mA per JEDEC Standard JESD78.

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6

NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

ELECTRICAL CHARACTERISTICS (V = 8.0 V, for typical values T = 25°C, for min/max values, T is the operating junction

CC

J

temperature range that applies (Note 2), unless otherwise noted.)

Characteristics

OSCILLATOR

Symbol

Min

Typ

Max

Unit

Frequency (V = 7.5 V)

f

kHz

CC

OSC(low)

T = 25°C:

J

A Suffix Device

B Suffix Device

C Suffix Device

38

87

119

42.5

97

132

47

107

145

T = T

to T

high

J

low

A Suffix Device

B Suffix Device

C Suffix Device

37

84

113

−

47

107

145

Frequency (V = 8.5 V)

f

kHz

CC

OSC(high)

T = 25°C:

J

A Suffix Device

B Suffix Device

C Suffix Device

41

93

126

45.5

103

140

50

113

154

T = T

to T

high

J

low

A Suffix Device

B Suffix Device

C Suffix Device

39

90

120

−

50

113

154

Frequency Sweep (V = 7.5 V to 8.5 V, T = 25°C)

%f

−

5.0

77

−

%

CC

J

OSC

Maximum Duty Cycle

D

74

80

(max)

CONTROL INPUT

Lower Window Input Current Threshold

m

A

Switching Enabled, Sink Current Increasing

Switching Disabled, Sink Current Decreasing

Upper Window Input Current Threshold

I

−58

−50

−47.5

−37.5

−37

−25

off(low)

on(low)

Switching Enabled, Source Current Increasing

Switching Disabled, Source Current Decreasing

I

37

25

47.5

37.5

58

50

off(high)

on(high)

Control Window Input Voltage

V

Lower (I

Upper (I

= 25 m A)

V

high

1.1

4.2

1.35

4.6

1.6

5.0

sink

source

low

2. Tested junction temperature range for the NCP105X series:

= −40°C = +125°C

T

low

T

high

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NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

ELECTRICAL CHARACTERISTICS (V = 8.0 V, for typical values T = 25°C, for min/max values, T is the operating junction

CC

J

temperature range that applies (Note 3), unless otherwise noted.)

Characteristics

Symbol

Min

Typ

Max

Unit

POWER SWITCH CIRCUIT

Power Switch Circuit On−State Resistance

R

W

DS(on)

NCP1050, NCP1051, NCP1052 (I = 50 mA)

D

T = 25°C

T = 125°C

J

−

22

42

30

55

J

NCP1053, NCP1054, NCP1055 (I = 100 mA)

D

T = 25°C

T = 125°C

J

−

10

23

15

28

J

Power Switch Circuit & Startup Breakdown Voltage

V

700

−

V

(BR)DS

(I

D(off)

= 100 m A, T = 25°C)

A

Power Switch Circuit & Startup Circuit Off−State Leakage Current

(V = 650 V) T = 25°C

I

m

A

DS(off)

−

25

15

40

80

DS

J

(V = 650 V) T = 125°C

DS

J

Switching Characteristics (R = 50 W, V set for I = 0.7 I

)

ns

L

DS

D

Iim

Turn−on Time (90% to 10%)

Turn−off Time (10% to 90%)

t

on

t

off

−

20

10

−

CURRENT LIMIT AND THERMAL PROTECTION

Current Limit Threshold (T = 25°C) (Note 6)

I

lim

mA

J

NCP1050

NCP1051

NCP1052

NCP1053

NCP1054

NCP1055

93

100

200

300

400

530

680

107

214

321

428

567

728

186

279

372

493

632

2

Conversion Power Deviation (T = 25°C) (Note 7)

I f

−

0

10

%A Hz

J

OSC

Propagation Delay, Current Limit Threshold to Power Switch Circuit Output

NCP1050, NCP1051, NCP1052

NCP1053, NCP1054, NCP1055

t

ns

PLH

−

135

160

−

Thermal Protection (V = 8.6 V) (Note 3, 4, 5)

°C

CC

Shutdown (Junction Temperature Increasing)

Hysteresis (Junction Temperature Decreasing)

T

140

−

160

75

−

sd

H

STARTUP CONTROL

Startup/V Regulation

V

CC

Startup Threshold/V Regulation Peak (V Increasing)

V

8.0

7.0

−

8.5

7.5

1.0

9.0

8.0

−

CC

CC(on)

Minimum Operating/V Valley Voltage After Turn−On

CC

CC(off)

V

H

Hysteresis

Undervoltage Lockout Threshold Voltage, V Decreasing

V

4.0

4.5

5.0

V

CC

CC(reset)

Startup Circuit Output Current (Power Switch Circuit Output = 40 V)

I

mA

start

V

CC

= 0 V

T = 25°C

T = −40 to 125°C

J

5.4

4.5

6.3

−

7.2

8.0

J

V

CC

= V

− 0.2 V

CC(on)

T = 25°C

T = −40 to 125°C

J

4.6

3.5

5.6

−

6.6

7.0

J

Minimum Start−up Drain Voltage (I

= 0.5 mA, V = V

− 0.2 V)

V

start(min)

−

13.4

20

V

start

CC

CC(on)

Output Fault Condition Auto Restart

(V Capacitor = 10 m F, Power Switch Circuit Output = 40 V)

CC

Average Switching Duty Cycle

Frequency

D

f

−

6.0

3.5

−

%

Hz

rst

3. Tested junction temperature range for the NCP105X series:

T

low

= −40°C

T

high

= +125°C

4. Maximum package power dissipation limits must be observed.

5. Guaranteed by design only.

6. Adjust di/dt to reach I in 4.0 m sec.

lim

7. Consult factory for additional options including test and trim for output power accuracy.

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8

NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

ELECTRICAL CHARACTERISTICS (V = 8.0 V, for typical values T = 25°C, for min/max values, T is the operating junction

CC

J

temperature range that applies (Note 8), unless otherwise noted.)

Characteristics

TOTAL DEVICE

Symbol

Min

Typ

Max

Unit

Power Supply Current After UVLO Turn−On (Note 9)

Power Switch Circuit Enabled

NCP1050, NCP1051, NCP1052

A Suffix Device

mA

I

CC1

0.35

0.40

0.45

0.50

0.525

0.55

0.60

0.65

B Suffix Device

C Suffix Device

NCP1053, NCP1054, NCP1055

A Suffix Device

0.40

0.45

0.50

0.575

0.65

0.60

0.70

0.80

B Suffix Device

C Suffix Device

Power Switch Circuit Disabled

Non−Fault Condition

Fault Condition

I

0.35

0.10

0.45

0.175

0.55

0.25

CC2

CC3

8. Tested junction temperature range for the NCP105X series:

T

low

= −40°C

T

high

= +125°C

9. See Non−Latching Fault Condition Timing Diagram in Figure 4.

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9

NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

46

45

44

43

42

104

V

CC

= V

CC(on)

V

= V

CC(on)

CC

102

100

98

V

CC

= V

CC(off)

V

CC

= V

CC(off)

96

41

40

94

92

−50 −25

0

25

50

75

100

125 150

−50 −25

0

25

50

75

100

125 150

TEMPERATURE (°C)

Figure 5. Oscillator Frequency (A Suffix)

versus Temperature

Figure 6. Oscillator Frequency (B Suffix)

versus Temperature

142

140

9

8

7

6

5

4

3

2

V

= V

CC(on)

CC

136 kHz

100 kHz

138

136

134

132

130

128

V

= V

CC(off)

CC

44 kHz

1

0

126

124

−50 −25

0

25

50

75

100

125 150

−50 −25

0

25

50

75

100

125 150

TEMPERATURE (°C)

Figure 7. Oscillator Frequency (C Suffix)

versus Temperature

Figure 8. Frequency Sweep versus

Temperature

55

50

45

40

77.6

77.4

77.2

77.0

76.8

76.6

CURRENT RISING

CURRENT FALLING

35

30

76.4

76.2

−50 −25

0

25

50

75

100

125 150

−50 −25

0

25

50

75

100

125 150

TEMPERATURE (°C)

Figure 9. Maximum Duty Cycle versus

Temperature

Figure 10. Lower Window Control Input

Current Thresholds versus Temperature

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10

NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

50

46

42

38

1.39

1.38

CURRENT RISING

1.37

1.36

1.35

1.34

I

= 25 m A

1.33

1.32

1.31

1.30

SINK

CURRENT FALLING

34

30

1.29

1.28

−50 −25

0

25

50

75

100

125 150

−50 −25

0

25

50

75

100

125 150

TEMPERATURE (°C)

Figure 11. Upper Window Control Input

Current Thresholds versus Temperature

Figure 12. Control Input Lower Window Clamp

Voltage versus Temperature

4.66

4.64

4.62

4.60

4.58

4.56

45

40

NCP1050,1,2

(I = 50 mA)

D

35

30

25

20

15

10

I

= 25 m A

SOURCE

NCP1053,4,5

(I = 100 mA)

D

4.54

4.52

5

0

−50 −25

0

25

50

75

100

125 150

−50 −25

0

25

50

75

100 125 150

TEMPERATURE (°C)

Figure 13. Control Input Upper Window Clamp

Voltage versus Temperature

Figure 14. On Resistance versus Temperature

120

100

80

100

10

1

T = 25°C

J

NCP1053,4,5

NCP1050,1,2

60

T = −40°C

J

40

T = 25°C

J

20

0

T = 125°C

J

0

100 200 300 400 500 600 700 800 900

APPLIED VOLTAGE (V)

0

100

200

300

400

500

600

700

APPLIED VOLTAGE (V)

Figure 15. Power Switch and Startup Circuit

Leakage Current versus Voltage

Figure 16. Power Switch and Startup Circuit

Output Capacitance versus Applied Voltage

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NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

1.02

1.00

0.98

0.96

0.94

0.92

8.6

STARTUP

THRESHOLD

8.4

8.2

8.0

7.8

7.6

V

CC(on)

MINIMUM

OPERATING

THRESHOLD

V

CC(off)

0.90

0.88

7.4

7.2

−50 −25

0

25

50

75

100

125 150

−50 −25

0

25

50

75

100

125 150

TEMPERATURE (°C)

Figure 17. Normalized Peak Current Limit

versus Temperature

Figure 18. Supply Voltage Thresholds versus

Temperature

8

7

6

5

4

3

2

4.56

4.54

4.52

4.50

4.48

4.46

4.44

4.42

4.40

4.38

V

= 0 V

CC

V

CC

= 8.3 V

V

= 20 V

PIN 5

1

0

4.36

4.34

−50 −25

0

25

50

75

100

125 150

−50 −25

0

25

50

75

100

125 150

TEMPERATURE (°C)

Figure 20. Start Current versus Temperature

Figure 19. Undervoltage Lockout Threshold

versus Temperature

8

6

4

2

7

6

5

4

3

2

1

V

CC

= 0 V

V

= 8 V

CC

T = 25°C

J

V

PIN 5

= 20 V

0

T = 25°C

J

0

−2

1

10

100

1000

1

2

3

4

5

6

7

8

9

SUPPLY VOLTAGE (V)

PIN 5 VOLTAGE (V)

Figure 21. Startup Current versus Supply

Voltage

Figure 22. Startup Current versus Pin 5

Voltage

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NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

0.55

0.50

0.45

0.70

136 kHz

0.65

0.60

100 kHz

0.55

0.50

0.45

44 kHz

0.40

0.35

0.40

0.35

−50 −25

0

25

50

75

100

125 150

−50 −25

0

25

50

75

100

125 150

TEMPERATURE (°C)

Figure 23. Supply Current versus Temperature

(NCP1050/1/2)

Figure 24. Supply Current versus Temperature

(NCP1053/4/5)

0.48

0.47

0.46

0.45

0.44

0.43

0.21

0.20

0.19

0.18

0.17

0.16

0.15

0.14

0.42

0.41

0.13

0.12

−50 −25

0

25

50

75

100

125 150

−50 −25

0

25

50

75

100

125 150

TEMPERATURE (°C)

Figure 25. Supply Current When Switching

Disable versus Temperature

Figure 26. Supply Current in Fault Condition

versus Temperature

14.0

13.9

CONDITION:

V

CC

pin = 1 m F to ground

13.8

13.7

13.6

13.5

13.4

13.3

13.2

Control pin = open

Drain pin = 1 kW to Power Supply,

Increase Voltage Until Switching

13.1

13.0

−50 −25

0

25

50

75

100

125 150

TEMPERATURE (°C)

Figure 27. Supply Voltage versus Temperature

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13

NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

OPERATING DESCRIPTION

Introduction

followers at approximately 47.5 m A with 10 m A hysteresis.

When a source or sink current in excess of this value is

applied to this input, a logic signal generated internally

changes state to block power switch conduction. Since the

output of the Control Input sense is sampled continuously

The NCP105X series represents a new higher level of

integration by providing on a single monolithic chip all of

the active power, control, logic, and protection circuitry

required to implement a high voltage flyback converter and

compliance with very low standby power requirements for

modern consumer electronic power supplies. This device

series is designed for direct operation from a rectified 240

VAC line source and requires minimal external components

for a complete cost sensitive converter solution. Potential

markets include cellular phone chargers, standby power

supplies for personal computers, secondary bias supplies for

microprocessor keep−alive supplies and IR detectors. A

description of each of the functional blocks is given below,

and the representative block diagram is shown in Figure 2.

This device series features an active startup regulator

circuit that eliminates the need for an auxiliary bias winding

on the converter transformer, fault logic with a programmable

timer for converter overload protection, unique gated

oscillator configuration for extremely fast loop response with

double pulse suppression, oscillator frequency dithering with

during t (77% duty cycle), it is possible to turn the Power

on

Switch Circuit on or off at any time within t . Because it

on

does not have to wait for the next cycle (rising edge of the

clock signal) to switch on, and because it does not have to

wait for current limit to turn off, the circuit has a very fast

transient response as shown in Figure 3.

In a typical converter application the control input current

is drawn by an optocoupler. The collector of the optocoupler

is connected to the Control Input pin and the emitter is

connected to ground. The optocoupler LED is mounted in

series with a shunt regulator (typically a TL431) at the DC

output of the converter. When the power supply output is

greater than the reference voltage (shunt regulator voltage

plus optocoupler diode voltage drop), the optocoupler turns

on, pulling down on the Control Input. The control input

logic is configured for line input sensing as well.

a

controlled slew rate driver for reduced EMI,

Turn On Latch

cycle−by−cycle current limiting, input undervoltage lockout

with hysteresis, thermal shutdown, and auto restart or latched

off fault detect device options. These devices are available in

economical 8−pin PDIP and 4−pin SOT−223 packages.

The Oscillator output is typically a 77% positive duty

cycle square waveform. This waveform is inverted and

applied to the reset input of the turn−on latch to prevent any

power switch conduction during the guaranteed off time.

This square wave is also gated by the output of the control

section and applied to the set input of the same latch.

Because of this gating action, the power switch can be

activated when the control input is not asserted and the

oscillator output is high.

The use of this unique gated Turn On Latch over an

ordinary Gated Oscillator allows a faster load transient

response. The power switch is allowed to turn on

immediately, within the maximum duty cycle time period,

when the control input signals a necessary change in state.

Oscillator

The Oscillator is a unique fixed−frequency, duty−cycle−

controlled oscillator. It charges and discharges an on chip

timing capacitor to generate a precise square wave signal

used to pulse width modulate the Power Switch Circuit.

During the discharge of the timing capacitor, the Oscillator

duty cycle output holds one input of the Driver low. This

action keeps the Power Switch Circuit off, thus limiting the

maximum duty cycle.

A frequency modulation feature is incorporated into the

IC in order to aide in EMI reduction. Figure 3 illustrates this

frequency modulation feature. The power supply voltage,

Turn Off Latch

A Turn Off Latch feature has been incorporated into this

device series to protect the power switch circuit from

excessive current, and to reduce the possibility of output

overshoot in reaction to a sudden load removal. If the Power

Switch current reaches the specified maximum current limit,

the Current Limit Comparator resets the Turn Off Latch and

turns the Power Switch Circuit off. The turn off latch is also

reset when the Oscillator output signal goes low or the

Control Input is asserted, thus terminating output MOSFET

conduction. Because of this response to control input

signals, it provides a very fast transient response and very

tight load regulation. The turn off latch has an edge triggered

set input which ensures that the switch can only be activated

once during any oscillator period. This is commonly

referred to as double pulse suppression.

V

, acts as the input to the built−in voltage controlled

CC

oscillator. As the V voltage is swept across its nominal

operating range of 7.5 to 8.5 V, the oscillator frequency is

swept across its corresponding range.

CC

The center oscillator frequency is internally programmed

for 44 kHz, 100 kHz, or 136 kHz operation with a controlled

charge to discharge current ratio that yields a maximum

Power Switch duty cycle of 77%. The Oscillator

temperature characteristics are shown in Figures 5

through 9. Contact an ON Semiconductor sales

representative for further information regarding frequency

options.

Control Input

The Control Input pin circuit has parallel source follower

input stages with voltage clamps set at 1.35 and 4.6 V.

Current sources clamp the input current through the

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14

NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

Current Limit Comparator and Power Switch Circuit

Undervoltage Lockout

The Power Switch Circuit is constructed with a

SENSEFET in order to monitor the drain current. A

portion of the current flowing through the circuit goes into

An Undervoltage Lockout (UVLO) comparator is

included to guarantee that the integrated circuit has

sufficient voltage to be fully functional. The UVLO

comparator monitors the supply capacitor input voltage at

Pin 1 and disables the Power Switch Circuit whenever the

capacitor voltage drops below the undervoltage lockout

threshold. When this level is crossed, the controller enters a

new startup phase by turning the current source on. The

supply voltage will then have to exceed the startup threshold

in order to turn off the startup current source. Startup and

normal operation of the converter are shown in Figure 3.

a sense element, R

. The current limit comparator detects

sense

if the voltage across R

exceeds the reference level that

sense

is present at its inverting input. If this level is exceeded, the

comparator quickly resets the Turn Off Latch, thus

protecting the Power Switch Circuit.

A Leading Edge Blanking circuit was placed in the current

sensing signal path to prevent a premature reset of the Turn

Off Latch. A potential premature reset signal is generated

each time the Power Switch Circuit is driven into conduction

and appears as a narrow voltage spike across current sense

Fault Detector

The NCP105X series has integrated Fault Detector

circuitry for detecting application fault conditions such as

open loop, overload or a short circuited output. A timer is

generated by driving the supply capacitor with a known

current and hysteretically regulating the supply voltage

between set thresholds. The timer period starts when the

supply voltage reaches the nominal upper threshold of 8.5 V

and stops when the drain current of the integrated circuit

draws the supply capacitor voltage down to the undervoltage

lockout threshold of 7.5 V.

If, during this timer period, no feedback has been applied

to the control input, the fault detect logic is set to indicate an

abnormal condition. This may occur, for example, when the

optocoupler fails or the output of the application is

overloaded or completely shorted. In this case, the part will

stop switching, go into a low power mode, and begin to draw

down the supply capacitor to the reset threshold voltage of

4.5 V. At that time, the startup circuit will turn on again to

drive the supply to the turn on threshold. Then the part will

begin the cycle again, effectively sampling the control input

to determine if the fault condition has been removed. This

mode is commonly referred to as burst mode operation and

is shown is Figure 4.

resistor R

. The spike is due to the Power Switch Circuit

sense

gate to source capacitance, transformer interwinding

capacitance, and output rectifier recovery time. The Leading

Edge Blanking circuit has a dynamic behavior that masks the

current signal until the Power Switch Circuit turn−on

transition is completed. The current limit propagation delay

time is typically 135 to 165 nanoseconds. This time is

measured from when an overcurrent appears at the Power

Switch Circuit drain, to the beginning of turn−off. Care must

be taken during transformer saturation so that the maximum

device current limit rating is not exceeded.

The high voltage Power Switch Circuit is monolithically

integrated with the control logic circuitry and is designed to

directly drive the converter transformer. Because the

characteristics of the power switch circuit are well known,

the gate drive has been tailored to control switching

transitions to help limit electromagnetic interference (EMI).

The Power Switch Circuit is capable of switching 700 V

with an associated drain current that ranges nominally from

0.10 to 0.68 Amps.

Startup Circuit

Rectified AC line voltage is applied to the Startup Circuit

on Pin 5, through the primary winding. The circuit is

self−biasing and acts as a constant current source, gated by

control logic. Upon application of the AC line voltage, this

circuit routes current into the supply capacitor typically

connected to Pin 1. During normal operation, this capacitor

is hysteretically regulated from 7.5 to 8.5 V by monitoring

the supply voltage with a comparator and controlling the

startup current source accordingly. This Dynamic

Self−Supply (DSS) functionality offers a great deal of

applications flexibility as well. The startup circuit is rated at

a maximum 700 V (maximum power dissipation limits must

be observed).

Proper selection of the supply capacitor allows successful

startup with monotonically increasing output voltage,

without falsely sensing a fault condition. Figure 4 shows

successful startup and the evolution of the signals involved

in the presence of a fault.

Thermal Shutdown

The internal Thermal Shutdown block protects the device

in the event that the maximum junction temperature is

exceeded. When activated, typically at 160°C, one input of

the Driver is held low to disable the Power Switch Circuit.

The Power Switch is allowed to resume operation when the

junction temperature falls below 85°C. The thermal

shutdown feature is provided to prevent catastrophic device

failures from accidental overheating. It is not intended to be

used as a substitute for proper heatsinking.

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15

NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

APPLICATIONS

Two application examples have been provided in this

to provide a tightly regulated DC output. IC3 is a shunt

regulator that samples the output voltage by virtue of R5 and

R6 to provide drive to the optocoupler, IC2, Light Emitting

Diode (LED). C10 is used to compensate the shunt regulator.

When the application is configured as a Charger, Q1 delivers

additional drive to the optocoupler LED when in constant

current operation by sampling the output current through R7

and R8.

document, and they are described in detail in this section.

Figure 28 shows a Universal Input, 6 Watt Converter

Application as well as a 5.5 Watt Charger Application using

the NCP1053B. The Charger consists of the additional

components Q1, C13, and R7 through R10, as shown. These

were constructed and tested using the printed circuit board

layout shown in Figure 40. The board consists of a fiberglass

epoxy material (FR4) with a single side of two ounce per

square foot (70 m m thick) copper foil. Test data from the two

applications is given in Figures 29 through 39.

Both applications generate a well−regulated output

voltage over a wide range of line input voltage and load

current values. The charger application transitions to a

constant current output if the load current is increased

beyond a preset range. This can be very effective for battery

charger application for portable products such as cellular

telephones, personal digital assistants, and pagers. Using the

NCP105X series in applications such as these offers a wide

range of flexibility for the system designer.

Component Selection Guidelines

Choose snubber components R1, C3, and D5 such that the

voltage on pin 5 is limited to the range from 0 to 700 volts.

These components protect the IC from substrate injection if

the voltage was to go below zero volts, and from avalanche

if the voltage was to go above 700 volts, at the cost of slightly

reduced efficiency. For lower power design, a simple RC

snubber as shown, or connected to ground, can be sufficient.

Ensure that these component values are chosen based upon

the worst−case transformer leakage inductance and

worst−case applied voltage. Choose R2 and C4 for best

performance radiated switching noise.

The NCP105X application offers a low cost alternative to

other applications. It uses a Dynamic Self−Supply (DSS)

function to generate its own operating supply voltage such

that an auxiliary transformer winding is not needed. (It also

offers the flexibility to override this function with an

auxiliary winding if ultra−low standby power is the

designer’s main concern.) This product also provides for

automatic output overload, short circuit, and open loop

protection by entering a programmable duty cycle burst

mode of operation. This eliminates the need for expensive

devices overrated for power dissipation or maximum

current, or for redundant feedback loops.

The application shown in Figure 28 can be broken down

into sections for the purpose of operating description.

Components C1, L1 and C6 provide EMI filtering for the

design, although this is very dependent upon board layout,

component type, etc. D1 through D4 along with C2 provide

the AC to bulk DC rectification. The NCP1053 drives the

primary side of the transformer, and the capacitor, C5, is an

integral part of the Dynamic Self−Supply. R1, C3, and D5

comprise an RCD snubber and R2 and C4 comprise a ringing

damper both acting together to protect the IC from voltage

transients greater than 700 volts and reduce radiated noise

from the converter. Diode D6 along with C7−9, L2, C11, and

C12 rectify the transformer secondary and filter the output

Capacitor C5 serves multiple purposes. It is used along

with the internal startup circuitry to provide power to the IC

in lieu of a separate auxiliary winding. It also serves to

provide timing for the oscillator frequency sweep for

limiting the conducted EMI emissions. The value of C5 will

also determine the response during an output fault (overload

or short circuit) or open loop condition as shown in Figure 4,

along with the total output capacitance.

Resistors R5 and R6 will determine the regulated output

voltage along with the reference voltage chosen with IC3.

The base to emitter voltage drop of Q1 along with the

value of R7 will set the fixed current limit value of the

Charger application. R9 is used to limit the base current of

Q1. Component R8 can be selected to keep the current limit

fixed with very low values of output voltage or to provide

current limit foldback with results as shown in

Figures 29 and 33. A relatively large value of R8 allows for

enough output voltage to effectively drive the optocoupler

LED for fixed current limit. A low value of R8, along with

resistor R10, provides for a low average output power using

the fault protection feature when the output voltage is very

low. C13 provides for output voltage stability when the

Charger application is in current limit.

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16

NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

Test

Line Regulation

Conditions

= 85 − 265 V ; I = 120 mA

Converter Results

Charger Results

V

in

V

in

V

in

2 mV

1 mV

2 mV

AC out

= 85 − 265 V ; I = 600 mA

AC out

= 85 − 265 V ; I = 1.2 A

AC out

V

in

V

in

V

in

= 85 − 265 V ; I = 100 mA

11 mV

24 mV

41 mV

AC out

= 85 − 265 V ; I = 500 mA

AC out

= 85 − 265 V ; I = 1.00 A

AC out

Load Regulation

V

in

V

in

V

in

V

in

= 85 V ; I = 120 mA − 1.2 A

12 mV

13 mV

12 mV

13 mV

AC out

= 110 V ; I = 120 mA − 1.2 A

AC out

= 230 V ; I = 120 mA − 1.2 A

AC out

= 265 V ; I = 120 mA − 1.2 A

AC out

V

in

V

in

V

in

V

in

= 85 V ; I = 100 mA − 1.00 A

58 mV

65 mV

71 mV

67 mV

AC out

= 110 V ; I = 100 mA − 1.00 A

AC out

= 230 V ; I = 100 mA − 1.00 A

AC out

= 265 V ; I = 100 mA − 1.00 A

AC out

Output Ripple

Efficiency

V

= 110 V ; I = 1.2 A

86 mV

p−p

in

AC out

= 230 V ; I = 1.2 A

127 mV

AC out

p−p

V

in

V

in

= 110 V ; I = 1.00 A

80 mV

p−p

AC out

= 230 V ; I = 1.00 A

155 mV

AC out

p−p

V

in

V

in

= 110 V ; I = 1.2 A

72.4%

69.6%

AC out

= 230 V ; I = 1.2 A

AC out

V

in

V

in

= 110 V ; R = 1.2

,

WI = 1.00 A

out

54.6%

53.6%

AC

8

out

= 230 V ; R = 1.2

,WI = 1.00 A

AC

8

V

in

V

in

= 110 V ; R = 0

,

WI = 1.00 A

out

66.1%

63.3%

AC

8

out

= 230 V ; R = 0

,WI = 1.00 A

AC

8

No Load Input Power

V

in

V

in

= 110 V ; I = 0 A

100 mW

200 mW

100 mW

200 mW

AC out

= 230 V ; I = 0 A

AC out

Standby Output Power

Short Circuit Load Input Power

V

= 110 V ; P = 1 W

680 mW

630 mW

640 mW

540 mW

in

AC

in

= 230 V ; P = 1 W

AC

in

V

in

V

in

= 110 V ; V = 0 V (Shorted)

400 mW

550 mW

AC out

= 230 V ; V = 0 V (Shorted)

AC out

V

in

V

in

= 110 V ; R = 1.2

,

WV = 0 V (Shorted)

out

750 mW

900 mW

AC

8

out

= 230 V ; R = 1.2

,WV = 0 V (Shorted)

AC

8

V

in

V

in

= 110 V ; R = 0

,

WV = 0 V (Shorted)

out

700 mW

850 mW

AC

8

out

= 230 V ; R = 0

,WV = 0 V (Shorted)

AC

8

Figure 29. Converter and Charger Test Data Summary

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18

NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

5.224

5.222

5.220

5.218

5.216

5.214

5.212

5.23

5.22

I

= 120 mA

= 600 mA

out

I

= 100 mA

out

5.21

5.20

5.19

5.18

5.17

5.16

out

I

= 500 mA

out

I

= 1.2 A

out

5.210

5.208

5.15

5.14

I

= 1 A

out

80

130

180

230

280

80

130

180

230

280

LINE INPUT VOLTAGE (V

)

LINE INPUT VOLTAGE (V

)

AC

Figure 30. Converter Line Regulation

Figure 31. Charger Line Regulation

6

5

4

3

2

1

6

5

4

3

2

V

in

= 230 V

AC

V

= 85 V

AC

in

V

in

= 110 V

AC

V

= 265 V

AC

in

V

in

= 85 V

AC

V

in

= 265 V

AC

V

= 110 V

AC

in

1

0

V

= 230 V

AC

in

0

0.5

1

1.5

2

0

0.5

1.0

1.5

LOAD CURRENT (A)

Figure 32. Converter Load Regulation

Figure 33. Charger Load Regulation

Ch1: V

out

Ch1: V

out

Ch2: I = 0.2 A/div

out

Ch2: I = 0.2 A/div

out

(V = 230 V

in

)

AC

(V = 230 V

in

)

AC

Figure 34. Converter Load Transient Response

Figure 35. Charger Load Transient Response

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19

NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

70

75

70

65

60

V

= 110 V

AC

in

V

in

= 85 V

AC

V

= 85 V

AC

in

65

60

55

V

= 230 V

AC

V

in

= 110 V

AC

in

= 265 V

in

AC

V

in

= 230 V

AC

V

in

= 265 V

AC

50

45

55

50

0

0.5

1.0

1.5

0

0.5

1.0

1.5

LOAD CURRENT (A)

Figure 36. Converter Efficiency

Figure 37. Charger Efficiency

Ch1: V

out

Ch2: Rectified V

in

(V = 230 V

,

(V = 230 V

,

in

AC

in

AC

I

= 0.5 A)

I

= 0.5 A)

out

Figure 38. Converter On/Off Line Transient

Response

Figure 39. Charger On/Off Line Transient

Response

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20

NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

Board Graphics

AC Input

DC Output

+

−

IC3

F1

C5

C12

C11

C1

IC2

−

C10

R9

+

−

R8

L1

IC1

Q1

R7

L2

D4

C6

T1

R3

D2

D1

C9

+

−

D3

D6

R2

C4

C8

+

−

R1

C2

−

+

C3

C7

+

−

Top View

2.75″

NCP1050

Series

Bottom View

Figure 40. Printed Circuit Board and

Component Layout

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21

NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

DEVICE ORDERING INFORMATION (Note 10)

R

I

pk

DS(on)

(W)

(mA)

100

200

300

400

530

680

100

200

300

400

530

680

Device

NCP1050PZZZ

Package

Shipping

NCP1051PZZZ

30

15

30

15

NCP1052PZZZ

DIP−8

CASE 626A

50 Units/Rail

NCP1053PZZZ

NCP1054PZZZ

NCP1055PZZZ

NCP1050STZZZT3

NCP1051STZZZT3

NCP1052STZZZT3

NCP1053STZZZT3

NCP1054STZZZT3

NCP1055STZZZT3

SOT−223

CASE 318E

4000 Units/Tape & Reel

10.Consult factory for additional optocoupler fail−safe latching, frequency, current limit and line input options.

11. ZZZ = 44, 100, or 136 for different frequency options.

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22

NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

PACKAGE DIMENSIONS

DIP−8

P SUFFIX

CASE 626A−01

ISSUE O

NOTES:

1. DIMENSIONING AND TOLERANCING PER ANSI

Y14.5M, 1982.

2. CONTROLLING DIMENSION: MILLIMETER.

3. PACKAGE CONTOUR OPTIONAL (ROUND OR

SQUARE CORNERS).

8

5

4. DIMENSION L TO CENTER OF LEAD WHEN

FORMED PARALLEL.

5. DIMENSIONS A AND B ARE DATUMS.

B

L

M

1

4

MILLIMETERS

INCHES

MIN

J

DIM MIN

MAX

10.16

6.60

4.45

0.51

1.78

MAX

0.400

0.260

0.175

0.020

0.070

A

B

C

D

F

9.40

6.10

3.94

0.38

1.02

0.370

0.240

0.155

0.015

0.040

F

NOTE 3

A

G

H

J

2.54 BSC

0.100 BSC

0.76

0.20

2.92

1.27

0.30

3.43

0.030

0.008

0.115

0.050

0.012

0.135

K

L

C

7.62 BSC

0.300 BSC

M

N

−−−

0.76

10

_

1.01

−−−

0.030

10

_

0.040

−T−

SEATING

PLANE

N

D

K

G

H

M

0.13 (0.005)

T

A

B

SOT−223

ST SUFFIX

CASE 318E−04

ISSUE K

A

F

NOTES:

1. DIMENSIONING AND TOLERANCING PER ANSI

Y14.5M, 1982.

2. CONTROLLING DIMENSION: INCH.

4

2

INCHES

DIM MIN MAX

MILLIMETERS

S

B

MIN

6.30

3.30

1.50

0.60

2.90

2.20

MAX

6.70

3.70

1.75

0.89

3.20

2.40

0.100

0.35

2.00

1.05

10

1

3

A

B

C

D

F

0.249

0.130

0.060

0.024

0.115

0.087

0.263

0.145

0.068

0.035

0.126

0.094

D

G

H

J

L

0.0008 0.0040 0.020

G

0.009

0.060

0.033

0

0.014

0.078

0.041

10

0.24

1.50

0.85

0

J

K

L

C

M

S

_

0.08 (0003)

0.264

0.287

6.70

7.30

M

H

K

http://onsemi.com

23

NCP1050, NCP1051, NCP1052, NCP1053, NCP1054, NCP1055

The products described herein (NCP1050, 1051, 1052, 1053, 1054, 1055), may be covered by one or more of the following U.S. patents:

4,553,084; 5,418,410; 5,477,175; 6,137,696; 6,137,702; 6,271,735, 6,480,043, 6,362,067, 6,587,357. There may be other patents pending.

SENSEFET is a trademark of Semiconductor Components Industries, LLC (SCILLC)

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.

PUBLICATION ORDERING INFORMATION

Literature Fulfillment:

JAPAN: ON Semiconductor, Japan Customer Focus Center

2−9−1 Kamimeguro, Meguro−ku, Tokyo, Japan 153−0051

Phone: 81−3−5773−3850

Literature Distribution Center for ON Semiconductor

P.O. Box 5163, Denver, Colorado 80217 USA

Phone: 303−675−2175 or 800−344−3860 Toll Free USA/Canada

Fax: 303−675−2176 or 800−344−3867 Toll Free USA/Canada

Email: orderlit@onsemi.com

ON Semiconductor Website: http://onsemi.com

For additional information, please contact your local

Sales Representative.

N. American Technical Support: 800−282−9855 Toll Free USA/Canada

NCP1050/D

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24


型号：	NCP1054P136
厂家：	ONSEMI
描述：	Monolithic High Voltage Gated Oscillator Power Switching Regulator 单片高电压门控振荡器电源开关稳压器振荡器稳压器开关式稳压器或控制器电源电路开关式控制器电源开关光电二极管栅
文件：	总24页 (文件大小：249K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

NCP1054P136 [ONSEMI]

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