NCP1530_05_技术文档

NCP1530

600 mA PWM/PFM

Step−Down Converter with

External Synchronization Pin

The NCP1530 is a PWM/PFM non−synchronous step−down

(Buck) DC−DC converter for usage in systems supplied from 1−cell

Li−ion, or 2 or more cells Alkaline/NiCd/NiMH batteries. It can

operate in Constant−Frequency PWM mode or PWM/PFM mode in

which the controller will automatically switch to PFM mode

operation at low output loads to maintain high efficiency. The

switching frequency can also be synchronized to external clock

between 600 kHz and 1.2 MHz. The maximum output current is up

to 600 mA. Applying an external synchronizing signal to SYN pin

can supersede the PFM operation.

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MARKING

DIAGRAM

Micro8]

DM SUFFIX

CASE 846A

xxxx

ALYW

8

1

The NCP1530 consumes only 47 mA (typ) of supply current

(V

= 3.0 V, no switching) and can be forced to shutdown mode by

OUT

bringing the enable input (EN) low. In shutdown mode, the regulator

is disabled and the shutdown supply current is reduced to

0.5 mA (typ). Other features include built−in undervoltage lockout,

internal thermal shutdown, an externally programmable soft−start

time and output current limit protection. The NCP1530 operates

from a maximum input voltage of 5.0 V and is available in a space

saving, low profile Micro8 package.

xxxx = Specific Device Code

A

L

= Assembly Location

= Wafer Lot

Y

W

= Year

= Work Week

PIN CONNECTIONS

Features

• Pb−Free Package is Available

V

1

2

8

7

6

5

LX

V

IN

• High Conversion Efficiency, up to 92% at V = 4.3 V,

SYN

IN

REF

V

OUT

= 3.3 V, I

= 300 mA

OUT

SS

V

OUT

3

4

• Current−Mode PWM Control

GND

EN

• Automatic PWM/PFM Mode for Current Saving at Low Output Loads

• Internal Switching Transistor Support 600 mA Output Current

(Top View)

(V = 5.0 V, V

= 3.3 V)

OUT

IN

• High Switching Frequency (600 kHz), Support Small Size Inductor

and Capacitor, Ceramic Capacitors Can be Used

• Synchronize to External Clock Signal up to 1.2 MHz

• 100% Duty Cycle for Maximum Utilization of the Supply Source

• Programmable Soft−Start Time through External Chip Capacitor

• Externally Accessible Voltage Reference

ORDERING INFORMATION

See detailed ordering and shipping information in the package

dimensions section on page 14 of this data sheet.

• Built−In Input Undervoltage Lockout

• Built−In Output Overvoltage Protection

• Power Saving Shutdown Mode

• Space Saving, Low Profile Micro8 Package

Typical Applications

• PDAs

• Digital Still Camera

• Cellular Phone and Radios

• Portable Test Equipment

• Portable Scanners

• Portable Audio Systems

Semiconductor Components Industries, LLC, 2005

1

Publication Order Number:

January, 2005 − Rev. 4

NCP1530/D

NCP1530

L1 5.6 mH

V

IN

= 2.8 V to 5.0 V

V

OUT

= 3.0 V

V

IN

LX

D1

MBRM120ET3

NCP1530

SYN

SS

V

OUT

V

REF

*C

SS

GND

EN

C

IN

*C

VREF

C

OUT

22 mF

1.0 mF

22 mF

*Optional Component

Figure 1. Typical Step−Down Converter Application

V

IN

1

MASTER ENABLE

ISEN

ENABLE

DETECT

THERMAL

SHUTDOWN

UVLO

EN 5

MODE

SELECTION

SYNC

DETECT

AND

ISEN

MODE

ISEN

ILIMIT

SYN 2

TIMING

BLOCK

ISEN

DRV

−

OV

+

0.04

+

8 LX

V

REF

CONTROL

LOGIC

−

+

−

FB

6 V

OUT

OTA

+

50 nA

−

+

VOLTAGE

REFERENCE

AND

V

REF

SS 3

FB

SOFT−START

10 pF

V

REF

7

4 GND

Figure 2. Simplified Functional Block Diagram

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2

NCP1530

PIN FUNCTION DESCRIPTIONS

1

Symbol

Description

V

IN

UnregulatedSupply Input.

2

SYN

Oscillator Synchronization and Mode Selection Input.

SYNC = GND (Automatic PWM/PFM mode) The converter operates at 600 kHz fixed−frequency PWM mode

primarily, and automatically switches to variable−frequency PFM mode at small output loads for power saving.

SYNC = V (Constant−Frequency PWM mode) The converter operates at 600 kHz fixed−frequency PWM mode

IN

always.

SYNC = External clock signal between 600 to 1200 kHz. The converter will be synchronized with the external

clock signal.

The SYNC pin is internally pulled to GND.

3

SS

Soft−Start Timing control pin. An external soft−start capacitor can be connected to this pin if extended soft−start is

required. A 50 nA current will be sourced from this pin to charge up the capacitor during startup and gently ramps

the device into service to prevent output voltage overshoot. If this pin is floated, built−in 500 ms (typ.) soft−start

will be activated.

4

5

GND

EN

Ground Terminal.

Active−High Enable Input. Active to enable the device. Bring this pin to GND and the quiescent current is reduced

to less than 0.5 mA. This pin is internally pulled to V

.

IN

6

7

V

Feedback Terminal. The output voltage is sensed by this pin.

OUT

V

Connected to voltage reference decoupling capacitor. For noise non−sensitive applications, the internal voltage

reference can operate without decoupling capacitor.

REF

8

LX

Inductor Terminal. This pin is connected to the drains of the internal P−channel switching transistors. The inductor

must be connected between this pin and the output terminal.

MAXIMUM RATINGS

Rating

Symbol

Value

−0.3 to 6

240

Unit

V

Power Supply (Pin 1)

V

IN

IO

Input/Output Pins (Pins 2−4 & Pins 7−8)

V

Thermal Characteristics

Micro8 Plastic Package

Thermal Resistance, Junction−to−Air

R

q

JA

°C/W

Operating Junction Temperature Range

Operating Ambient Temperature Range

Storage Temperature Range

T

0 to +150

0 to +85

°C

J

T

A

T

stg

−55 to +150

Maximumratings are those values beyond which device damage can occur. Maximum ratings applied to the device are individual stress limit values

(not normal operating conditions) and are not valid simultaneously. If these limits are exceeded, device functional operation is not implied, damage

may occur and reliability may be affected.

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

Human Body Model (HBM) "2.0 kV per JEDEC standard: JESD22−A114.

Machine Model (MM) "200 V per JEDEC standard: JESD22−A115.

2. Latchup Current Maximum Rating: "150 mA per JEDEC standard: JESD78.

3. Moisture Sensitivity Level (MSL): 1 per IPC/JEDEC standard: J−STD−020A.

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3

NCP1530

ELECTRICAL CHARACTERISTICS (V = V + 1.0 V, test circuit, refer to Figure 1, C = NC and C

= 1.0 mF, T = 25°C for

A

IN

R

SS

VREF

typical value, 0°C ≤ T ≤ 85°C for min/max values unless otherwise noted.) *V is the factory−programmed output voltage setting.

A

R

Characteristic

Symbol

Min

Typ

Max

Unit

V

Input Voltage

V

IN

1.1 V

−

5.0

R

Output Voltage (I

= 150 mA, V + 1.0 V < V < 5.0 V) (Note 4)

V

OUT

V

load

R

IN

NCP1530DM25R2

NCP1530DM27R2

NCP1530DM30R2

NCP1530DM33R2

2.425

2.619

2.910

3.201

2.5

2.7

3.0

3.3

2.575

2.781

3.090

3.399

Maximum Output Current (V = 5.0 V, V

= 3.0 V) (Note 5)

I

OUT(max)

600

−

mA

W

IN

OUT

Supply Current (V = V + 1.0 V, No Load, EN and SYN Pins NC)

I

IN

45

0.5

−

95

IN

R

Shutdown Supply Current (V = 5.0 V, No Load, V = 0 V)

I

SHDN

−

1.0

0.5

IN

EN

LX Pin Leakage Current (No Load, V = 0 V)

I

LX

−

EN

Internal P−FET ON Resistance at LX Pin

R

DS(ON)

−

0.3

(V = V + 1.0 V, I = 150 mA)

Load

IN

R

Oscillator Frequency

(V = V = V + 1.0 V, I = 100 mA, SYN Pin NC)

Load

f

480

−

600

−

720

100

kHz

OSC

IN

EN

R

Maximum PWM Duty Cycle (Note 5)

D

%

MAX−PWM

PFM to PWM Switch−Over Current Threshold

I

mA

PFM−PWM

(V = 4.5 V, SYN Pin NC, L = 5.6 mH, C

= 22 mF) (Note 5)

IN

OUT

NCP1530DM25R2

NCP1530DM27R2

NCP1530DM30R2

NCP1530DM33R2

−

83

90

100

102

−

PWM to PFM Switch−Over Current Threshold

I

mA

PWM−PFM

(V = 4.5 V, SYN Pin NC, L = 5.6 mH, C

= 22 mF) (Note 5)

IN

OUT

NCP1530DM25R2

NCP1530DM27R2

NCP1530DM30R2

NCP1530DM33R2

−

27

38

39

48

−

Input Undervoltage Lockout Threshold

V

−

1.184

−

2.0

2.45

1.216

−

V

UVLO

Reference Voltage (V = V + 1.0 V, C

= 1.0 mF)

V

REF

1.20

0.03

IN

R

VREF

Reference Voltage Temperature Coefficient

(V = V + 1.0 V, C = 1.0 mF) (Note 5)

TC

mV/°C

VREF

IN

R

VREF

Reference Voltage Load Current

(V = V + 1.0 V, C = 1.0 mF) (Note 6)

I

5.0

−

mA

VREF

IN

R

VREF

Enable Logic High Threshold Voltage (V = V + 1.0 V, I

= 0 mA)

V

−

0.5

−

1.5

1.2

100

6.0

1.5

500

145

15

1.85

−

V

IN

R

Load

EN−H

Enable Logic Low Threshold Voltage (V = V + 1.0 V, I

V

IN

R

Load

EN−L

PWM−ON

PWM Minimum On−Time (Note 5)

PWM OV Protection Level

t

−

ns

%

A

%V

−

12

−

OV

PWM Cycle−by−Cycle Current Limit (Note 5)

Built−in Soft−Start Time (V = 3.0 V, SS Pin NC) (Note 5)

I

−

LIM

t

SS

−

ms

°C

OUT

Thermal Shutdown Threshold (V = 3.5 V, I

= 0 mA) (Note 5)

TH

−

IN

Load

SHD

Thermal Shutdown Hysteresis (V = 3.5 V, I

= 0 mA) (Note 5)

TH

−

IN

Load

HSYS

4. Tested at V = V + 1.0 V in production only. Full V range guaranteed by design.

IN

R

IN

5. Parameter guaranteed by design only, not tested in production.

6. Loading capability decreases with V decreases.

OUT

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4

NCP1530

TYPICAL OPERATING CHARACTERISTICS (V = V + 1.0 V, test circuit, refer to Figure 1, C = NC and C

= 1.0 mF, T =

A

IN

R

SS

VREF

25°C for typical value, 0°C ≤ T ≤ 85°C for min/max values unless otherwise noted.) *V is the factory−programmed output voltage setting.

A

R

2.60

2.55

2.50

2.45

2.40

2.80

2.75

2.70

2.65

2.60

I

= 150 mA

I

= 150 mA

Load

V

= 3.7 V

= 5.0 V

34

V

= 3.5 V

= 5.0 V

34

IN

0

17

51

68

85

0

17

51

68

85

T , AMBIENT TEMPERATURE (°C)

A

Figure 3. Output Voltage vs. Ambient Temperature

(V_OUT= 2.5 V)

Figure 4. Output Voltage vs. Ambient Temperature

(V_OUT= 2.7 V)

3.10

3.05

3.40

3.35

3.30

3.25

3.20

I

= 150 mA

I

= 150 mA

Load

V

= 4.0 V

= 5.0 V

IN

V

IN

= 4.3 V

= 5.0 V

3.00

2.95

V

IN

2.90

0

17

34

51

68

85

0

17

34

51

68

T , AMBIENT TEMPERATURE (°C)

A

Figure 5. Output Voltage vs. Ambient Temperature

(V_OUT= 3.0 V)

Figure 6. Output Voltage vs. Ambient Temperature

(V_OUT= 3.3 V)

90

75

60

45

30

500

V

= 5.0 V

IN

V

= V + 1.0 V

R

IN

I

= 0 mA

Load

I

= 0 mA

Load

400

300

200

100

0

3.3 V

3.0 V

2.5 V

68

2.5 V

2.7 V

0

17

34

51

68

85

0

17

34

51

T , AMBIENT TEMPERATURE (°C)

A

T , AMBIENT TEMPERATURE (°C)

A

Figure 7. Supply Current vs. Ambient Temperature

Figure 8. Shutdown Current vs. Ambient Temperature

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5

NCP1530

750

675

600

525

450

0.50

V

= V

= 0 mA

=V + 1.0 V

V

= V

= 0 mA

=V + 1.0 V

IN

REN

R

IN

REN R

I

Load

SYN Pin = NC

0.40

0.30

0.20

2.7 V

3.0 V

3.3 V

2.5 V

3.3 V

2.7 V

2.5 V

0.10

85

0

17

34

51

68

0

17

34

51

68

85

T , AMBIENT TEMPERATURE (°C)

A

T , AMBIENT TEMPERATURE (°C)

A

Figure 9. Oscillator Frequency

vs. Ambient Temperature

Figure 10. P−FET ON Resistance

vs. Ambient Temperature

140

120

100

80

140

120

100

80

L = 5.6 mH, C

SYN Pin = NC

= 22 mF

L = 5.6 mH, C

SYN Pin = NC

= 22 mF

OUT

PWM

60

40

PFM

20

0

3.5

4.0

4.5

5.0

3.5

4.0

4.5

5.0

V , INPUT VOLTAGE (V)

IN

V , INPUT VOLTAGE (V)

IN

Figure 11. PWM/PFM Switchover Current

Thresholds vs. Input Voltage (V_OUT= 2.5 V)

Figure 12. PWM/PFM Switchover Current

Thresholds vs. Input Voltage (V_OUT= 2.7 V)

140

120

100

80

140

120

100

80

L = 5.6 mH, C

SYN Pin = NC

= 22 mF

L = 5.6 mH, C

SYN Pin = NC

= 22 mF

OUT

PWM

PFM

PWM

PFM

60

40

20

0

4.0

4.25

4.5

4.75

5.0

4.25

4.5

V , INPUT VOLTAGE (V)

IN

4.75

5.0

V

IN

, INPUT VOLTAGE (V)

Figure 13. PWM/PFM Switchover Current

Thresholds vs. Input Voltage (V_OUT= 3.0 V)

Figure 14. PWM/PFM Switchover Current

Thresholds vs. Input Voltage (V_OUT= 3.3 V)

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NCP1530

100

90

80

70

60

50

100

PWM/PFM

90

80

70

60

50

PWM/PFM

SYN 600 kHz

PWM

SYN 600 kHz

SYN 1.2 MHz

PWM

L = 5.6 mH, C

= 22 mF

L = 5.6 mH, C

= 22 mF

OUT

1

10

100

1000

1

10

100

1000

I , OUTPUT LOAD CURRENT (mA)

LOAD

I , OUTPUT LOAD CURRENT (mA)

LOAD

Figure 15. Efficiency vs. Output Load Current

(V_IN= 3.5 V, V_OUT= 2.5 V)

Figure 16. Efficiency vs. Output Load Current

(V_IN= 5.0 V, V_OUT= 2.5 V)

100

90

80

70

60

50

100

90

80

70

60

50

PWM/PFM

SYN 1.2 MHz

SYN 600 kHz

PWM

SYN 1.2 MHz

PWM

SYN 600 kHz

L = 5.6 mH, C

= 22 mF

L = 5.6 mH, C

= 22 mF

OUT

1

10

100

1000

1

10

100

1000

I , OUTPUT LOAD CURRENT (mA)

LOAD

I , OUTPUT LOAD CURRENT (mA)

LOAD

Figure 17. Efficiency vs. Output Load Current

(V_IN= 3.7 V, V_OUT= 2.7 V)

Figure 18. Efficiency vs. Output Load Current

(V_IN= 5.0 V, V_OUT= 2.7 V)

100

90

80

70

60

50

100

90

80

70

60

50

PWM/PFM

SYN 1.2 MHz

SYN 600 kHz

SYN 1.2 MHz

PWM

L = 5.6 mH, C

= 22 mF

L = 5.6 mH, C

= 22 mF

OUT

1

10

100

1000

1

10

100

1000

I , OUTPUT LOAD CURRENT (mA)

LOAD

I , OUTPUT LOAD CURRENT (mA)

LOAD

Figure 19. Efficiency vs. Output Load Current

(V_IN= 4.0 V, V_OUT= 3.0 V)

Figure 20. Efficiency vs. Output Load Current

(V_IN= 5.0 V, V_OUT= 3.0 V)

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NCP1530

100

90

80

70

60

50

100

PWM/PFM

90

80

70

60

50

SYN 600 kHz

SYN 1.2 MHz

SYN 600 kHz

SYN 1.2 MHz

PWM

L = 5.6 mH, C

= 22 mF

L = 5.6 mH, C

= 22 mF

OUT

1

10

100

1000

1

10

100

1000

I , OUTPUT LOAD CURRENT (mA)

LOAD

I , OUTPUT LOAD CURRENT (mA)

LOAD

Figure 21. Efficiency vs. Output Load Current

(V_IN= 4.3 V, V_OUT= 3.3 V)

Figure 22. Efficiency vs. Output Load Current

(V_IN= 5.0 V, V_OUT= 3.3 V)

5.0

3.0

V

IN

= 5.0 V

V

IN

= 5.0 V

3.0

0

V

IN

= 3.5 V

V

IN

= 3.7 V

−3.0

L = 5.6 mH, C

= 22 mF

L = 5.6 mH, C

= 22 mF

OUT

SYNC PIN = NC

−5.0

1

10

100

1000

1

10

100

1000

I , OUTPUT LOAD CURRENT (mA)

LOAD

I , OUTPUT LOAD CURRENT (mA)

LOAD

Figure 23. Output Voltage Regulation vs.

Output Load Current (V_OUT= 2.5 V)

Figure 24. Output Voltage Regulation vs.

Output Load Current (V_OUT= 2.7 V)

5.0

3.0

5.0

3.0

V

IN

= 5.0 V

V

IN

=4.0 V

0

V

IN

= 4.3 V

V

IN

= 5.0 V

−3.0

L = 5.6 mH, C

= 22 mF

OUT

SYNC PIN = NC

−5.0

1

10

100

1000

1

10

100

1000

I , OUTPUT LOAD CURRENT (mA)

LOAD

I , OUTPUT LOAD CURRENT (mA)

LOAD

Figure 25. Output Voltage Regulation vs.

Output Load Current (V_OUT= 3.0 V)

Figure 26. Output Voltage Regulation vs.

Output Load Current (V_OUT= 3.3 V)

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8

NCP1530

(V = 3.5 V, V

= 2.5 V, I

= 10 mA)

(V = 3.5 V, V

= 2.5 V, I

= 80 mA)

IN

OUT

LOAD

IN

OUT

LOAD

Upper Trace: Output Voltage Ripple, 50 mVac/Div.

Lower Trace: LX Pin Switching Waveform, 2.0 V/Div.

Upper Trace: Output Voltage Ripple, 50 mVac/Div.

Lower Trace: LX Pin Switching Waveform, 2.0 V/Div.

Figure 27. PFM Switching Waveform and

Output Ripple for V_OUT= 2.5 V

Figure 28. DCM PWM Switching Waveform

and Output Ripple for V_OUT= 2.5 V

(V = 3.5 V, V

= 2.5 V, I

= 600 mA)

(V = 4.3 V, V

= 3.3 V, I

= 10 mA)

IN

OUT

LOAD

IN

OUT

LOAD

Upper Trace: Output Voltage Ripple, 50 mVac/Div.

Lower Trace: LX Pin Switching Waveform, 2.0 V/Div.

Upper Trace: Output Voltage Ripple, 50 mVac/Div.

Lower Trace: LX Pin Switching Waveform, 2.0 V/Div.

Figure 29. CCM PWM Switching Waveform

and Output Ripple for V_OUT= 2.5 V

Figure 30. PFM Switching Waveform and

Output Ripple for V_OUT= 3.3 V

(V = 4.3 V, V

= 3.3 V, I

= 50 mA)

(V = 4.3 V, V

= 3.3 V, I

= 600 mA)

IN

OUT

LOAD

IN

OUT

LOAD

Upper Trace: Output Voltage Ripple, 50 mVac/Div.

Lower Trace: LX Pin Switching Waveform, 2.0 V/Div.

Upper Trace: Output Voltage Ripple, 50 mVac/Div.

Lower Trace: LX Pin Switching Waveform, 2.0 V/Div.

Figure 31. DCM PWM Switching Waveform

and Output Ripple for V_OUT= 3.3 V

Figure 32. CCM PWM Switching Waveform

and Output Ripple for V_OUT= 3.3 V

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9

NCP1530

(V = 3.5 V, V

= 2.5 V, C = 100 pF, No load)

(V = 4.3 V, V

= 3.3 V, C = 100 pF, No load)

OUT SS

IN

OUT

SS

IN

Upper Trace: Output Voltage, 2.0 V/Div.

Lower Trace: EN Pin Waveform, 2.0 V/Div.

Time Scale: 5.0 ms/Div.

Upper Trace: Output Voltage, 2.0 V/Div.

Lower Trace: EN Pin Waveform, 2.0 V/Div.

Time Scale: 5.0 ms/Div.

Figure 33. Soft−Start Output Voltage

Waveform for V_OUT= 2.5 V

Figure 34. Soft−Start Output Voltage

Waveform for V_OUT= 3.3 V

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NCP1530

DETAILED OPERATING DESCRIPTION

Introduction

controlling the ramp up of the internal voltage reference.

The soft−start time can be user adjusted by an external

The NCP1530 series are step−down converters with a

smart control scheme that operates with 600 kHz fixed

Pulse Width Modulation (PWM) at moderate to heavy load

currents, so that high efficiency, noise free output voltage

can be generated. In order to improve the system efficiency

at light loads, this device can be configured to work in

auto−mode. In auto−mode operation, the control unit will

detect the loading condition and switch to power saving

Pulse Frequency Modulation (PFM) control scheme at

light load. With these enhanced features, the converter can

achieve high operating efficiency for all loading

conditions. Additionally, the switching frequency can also

be synchronized to external clock signal in between

600 kHz to 1.2 MHz range. The converter uses peak

current mode PWM control as a core, with the high

switching frequency incorporated. Good line and load

regulation can be achieved easily with small value ceramic

input and output capacitors. Internal integrated

compensation voltage ramp ensures stable operation at all

operating modes. NCP1530 series are designed to support

up to 600 mA output current with cycle−by−cycle current

limit protection.

capacitor, C , connecting to the SS pin (pin 3). During

SS

converter powerup, a 50 nA current flowing out from the

SS pin will charge−up the timing capacitor. The voltage

across the SS pin controls the ramp up of the internal

reference voltage by slowly releasing it until the nominal

value is reached. For an external timing capacitor of value

C

= 100 pF, the soft−start time is about 5.0 ms including

SS

the small logic delay time, Figure 33 and 34. In the case

where the SS pin is left floating, a small built−in capacitor

together with other parasitic capacitance will provide a

minimum intrinsic soft−start time of 500 ms. As the

soft−start function is implemented by simple circuitry, the

final timing depends on non−linear functions, where

accurate deterination of the soft−start timing is impossible.

However, for simplicity, the empirical formula below can

be used to estimate the soft−start time with respect to the

value of the external capacitor.

t

in ms [ 50 C in pF ) 500 ms

SS

Current Mode Pulse−Width Modulation (PWM)

Control Scheme

With the SYN pin (pin 2) connected to V , the converter

IN

The Internal Oscillator

will set to operate at constant switching frequency PWM

mode. NCP1530 uses peak current mode control scheme to

achieve good line and load regulation. The high switching

frequency, 600 kHz, and a carefully compensated internal

control loop, allows the use of low profile small value

ceramic type input and output capacitor for stable

operation. In current mode operation, the required ramp

function is generated by sensing the inductor current

(ISEN) and comparing with the voltage loop error

amplifier (OTA) output. The OTA output is derived from

The oscillator that governs the switching of the PWM

control cycle is self contained and no external timing

component is required to setup the switching frequency.

For PWM mode and auto−mode operation, all timing

signals required for proper operation are derived from the

internal oscillator. The internal fix frequency oscillator is

trimmed to run at 600 kHz " 20% over full temperature

range. In case the device is forced to operate at

Synchronization mode by applying an external clock signal

to SYN pin (pin 2), the external clock signal will supersede

the internal oscillator and take charge of the switching

operation.

feedback from the output voltage pin (V

− Pin 6) and

OUT

the internal reference voltage (V

− Pin 7). See Figure 2.

REF

On a cycle−by−cycle basis, the duty cycle is controlled to

keep the output voltage within regulation. The current

mode approach has outstanding line regulation

performance and good overall system stability.

Additionally, by monitoring the inductor current, a

cycle−by−cycle current limit protection is implemented.

Constant Frequency PWM scheme reduces output ripple

and noise, which is one of the important characteristics for

noise sensitive communication applications. The high

switching frequency allows the use of small size surface

mount components that saves significant PC board area and

improves layout compactness and EMI performance.

Voltage Reference and Soft−Start

An internal high accuracy voltage reference is included

in NCP1530. This reference voltage governs all internal

reference levels in various functional blocks required for

proper operation. This reference voltage is precisely

trimmed to 1.2 V " 1.5% over full temperature range. The

reference voltage can be accessed externally at V

REF

(pin 7), with an external capacitor, C

of 1.0 mF, privding

REF

up to 5.0 mA of loading. Additionally, NCP1530 has a

Soft−Start circuit built around the voltage reference block

that provide limits to the inrush current during start−up by

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11

NCP1530

Power Saving Pulse−Frequency−Modulation (PFM)

Control Scheme

Output Overvoltage Protection (OVP)

In order to prevent the output voltage from going to high

(when the load current is close to zero in a pure PWM mode

and other abnormal conditions), an Output Overvoltage

protection circuit is included in the NCP1530. In case the

output voltage is higher than its nominal level by more than

12% maximum, the protection circuitry will stop the

switching immediately.

With the SYN pin (pin 2) connected to ground or left

open, the converter will operate in PWM/PFM auto mode.

Under this operating mode, NCP1530 will stay in constant

frequency PWM operation in moderate to heavy load

conditions. When the load decreases down to a threshold

point, the operation will switch to the power saving PFM

operation automatically. The switchover mechanism

depends on the input voltage, output voltage and the

inductor current level. The mode change circuit will

determine whether the converter should be operated in

PWM or PFM mode. In order to maintain stable and smooth

switching mode transition, a small hysteresis on the load

current level for mode transition was implemented. The

detailed mode transition characteristics for each voltage

option are illustrated in Figures 11 and 14. PFM mode

operation provides high conversion efficiency even at very

light loading conditions. In PFM mode, most of the circuits

inside the device will be turned off and the converter

operates just as a simple voltage hysteretic converter.

When the load current increases, the converter returns to

PWM mode automatically.

Internal Thermal Shutdown

Internal thermal shutdown circuitry is provided to

protect the integrated circuit in the event that the maximum

junction temperature is exceeded. The protection will be

activated at about 145°C with a hysteresis of 15°C. This

feature is provided to prevent failures from unexpected

overheating.

Input Capacitor Selection

For a PWM converter operating in continuous current

mode, the input current of the converter is a square wave

with a duty ratio of approximately V

/V . The

OUT IN

pulsating nature of the input current transient can be a

source of EMI noise and system instability. Using an input

bypass capacitor can reduce the peak current transients

drawn from the input supply source, thereby reducing

switching noise significantly. The capacitance needed for

the input bypass capacitor depends on the source

impedance of the input supply. For NCP1530, a low ESR,

low profile ceramic capacitor of 22 mF can be used for most

of the cases. For effective bypass results, the input

External Synchronization Control

The NCP1530 has an internal fixed frequency oscillator

of 600 kHz or can be synchronized to an external clock

signal at SYN pin (pin 2). Connecting the SYN pin with an

external clock signal will force the converter to operate in

a pure PWM mode and the switching frequency will be

synchronized. The external clock signal should be in the

range of 600 kHz to 1.2 MHz and the pulse width should

not be less than 300 ns. The detection of the pulse train is

edge sensitive and independent of duty ratio. In the case

where the external clock frequency is too low, the detection

circuit may not be able to follow and will treat it as a

disturbance, thus affecting the converters normal

operation. The internal control circuit detects the rising

edge of the pulse train and the switching frequency

synchronized to the external clock signal. If the external

clock signal ceases for several clock cycles, the converter

will switch back to use the internal oscillator automatically.

capacitor should be placed just next to V pin (pin 1)

whenever it is possible.

IN

Inductor Value Selection

Selecting the proper inductance for the power inductor

is a trade−off between inductor’s physical sizes, transient

response, power delivering capability, output voltage

ripple and power conversion efficiency. Low value

inductor saves cost, PC board space and provides fast

transient response, however suffers high inductor ripple

current, core loss and lower overall conversion efficiency.

The relationship between the inductance and the inductor

ripple current is given by the equation in below.

Power Saving Shutdown Mode

(

)

T

V

* R

DS(ON)

I

OUT

* V

OUT

ON IN

L +

NCP1530 can be disabled whenever the EN pin (pin 5)

is tied to ground. In shutdown mode, the internal reference,

oscillator and most of the control circuitries are turned off.

With the device put in shutdown mode, the device current

consumption will be as low as 0.5 mA (typ).

I

L_RIPPLE(P * P)

Where L is the inductance required;

is the nominal ON time within a switching cycle;

T

R

V

ON

is the ON resistance of the internal MOSFET;

is the worst−case input voltage;

is the output voltage;

DS(ON)

IN

Input Undervoltage Lockout Protection (UVLO)

OUT

To prevent the P−Channel MOSFETs from operating

below safe input voltage levels, an Undervoltage Lockout

protection is incorporated in NCP1530. Whenever the

I

is the maximum allowed loading current;

OUT

is the acceptable inductor current ripple

L_RIPPLE(P−P)

level.

input voltage, V drops below approximately 2.0 V, the

IN

protection circuitry will be activated and the converter

operation will be stopped.

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12

NCP1530

Output Capacitor Selection

Selection of the output capacitor, C

governed by the required effective series resistance (ESR)

of the capacitor. Typically, once the ESR requirement is

met, the capacitance will be adequate for filtering. The

For ease of application, the previous equation was

plotted in Figure 35 to help end user to select the right

inductor for specific application. As a rule of thumb, the

user needs to be aware of the maximum peak inductor

current and should be designed not to exceed the saturation

limit of the inductor selected. Low inductance can supply

higher output current, but suffers higher output ripple and

reduced efficiency, but it limits the output current

capability. On the other hand, high inductance can improve

output ripple and efficiency, at the same time, it also limits

the output current capability. One other critical parameter

of the inductor is its DC resistance. This resistance can

introduce unwanted power loss and hence reduce overall

efficiency. The basic rule is selecting an inductor with

lowest DC resistance within the board space limitation.

is primarily

OUT

output voltage ripple, V

is approximated by,

RIPPLE

1

ǒ_{ESR )}

Ǔ

V

[ I

L_RIPPLE(P * P)

RIPPLE

4 F

C

OSC OUT

Where F

is the switching frequency and ESR is the

OSC

effective series resistance of the output capacitor.

From equation in above, it can be noted that the output

voltage ripple is contributed to by two parts. For most of the

cases, the major contributor is the capacitor’s ESR.

Ordinary aluminum−electrolytic capacitors have high ESR

and should be avoided. High quality Low ESR

aluminum−electrolytic capacitors are acceptable and

relatively inexpensive. Low ESR tantalum capacitors are

another alternative. For even better performance, surface

mounted ceramic capacitors can be used. Ceramic

capacitors have lowest ESR among all choices. The

NCP1530 is internally compensated for stable operation

with low ESR ceramic capacitors. However, ordinary

multi−layer ceramic capacitors have poor temperature and

frequency performance, for switching applications, so only

high quality, grade X5R and X7R ceramic capacitors can

be used.

12

R

DS(ON)

= 3.0 W

10

D1, MBRM120ET3

C

IN

= C

= 22 mF

OUT

I

= 600 mA

OUT

8.0

6.0

4.0

2.0

0

= 0.2 A

L_RIPPLE(P−P)

3.0 V

4.0

PCB Layout Recommendations

2.5 V 2.7 V

3.5

3.3 V

Good PCB layout plays an important role in switching

mode power conversion. Careful PCB layout can help to

minimize ground bounce, EMI noise and unwanted

feedbacks that can affect the performance of the converter.

Hints suggested below can be used as a guideline in most

situations.

3.0

4.5

5.0

V , INPUT VOLTAGE (V)

IN

Figure 35. Inductor Selection Chart

Flywheel Diode Selection

The flywheel diode is turned on and carries load current

during the off time. At high input voltages, the diode

Grounding

Star−ground connection should be used to connect the

output power return ground, the input power return ground

and the device power ground together at one point. All high

current running paths must be thick enough for current

flowing through and producing insignificant voltage drop

along the path.

conducts most of the time. In the case where V

IN

approaches V , the diode conducts only a small fraction

OUT

of the cycle. While the output terminals are shorted, the

diode will be subject to its highest stress. Under this

condition, the diode must be able to safely handle the peak

current circulating in the loop. So, it is important to select

a flywheel diode that can meet the diode peak current and

average power dissipation requirements. Under normal

conditions, the average current conducted by the flywheel

diode is given by,

Components Placement

Power components, i.e. input capacitor, inductor and

output capacitor, must be placed as close together as

possible. All connecting traces must be short, direct and

thick. High current flowing and switching paths must be

kept away from the feedback (V

avoid unwanted injection of noise into the feedback path.

, pin 6) terminal to

V

* V

OUT

IN

V

I

D

+

I

OUT

) V

IN

F

Where I is the average diode current and V is the forward

D

F

Feedback Path

voltage drop of the diode.

Feedback of the output voltage must be a separate trace

separated from the power path. The output voltage sensing

A low forward voltage drop and fast switching diode

must also be used to optimize converter efficiency.

Schottky diodes are a good choice for low forward drop and

fast switching times.

trace to the feedback (V , pin 6) pin should be connected

OUT

to the output voltage directly at the anode of the output

capacitor.

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13

NCP1530

ORDERING INFORMATION

Device

†

Output Voltage

2.5 V

Device Marking

Package

Shipping

NCP1530DM25R2

NCP1530DM27R2

NCP1530DM30R2

NCP1530DM30R2G

DAAA

DAAB

DAAC

2.7 V

Micro8

3.0 V

4000 Units

Per 7 Inch Reel

3.0 V

Micro8

(Pb−Free)

NCP1530DM33R2

3.3 V

DAAD

Micro8

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

SpecificationsBrochure, BRD8011/D.

NOTE: The ordering information lists four standard output voltage device options. Additional device with output voltage ranging from 2.5 V to

3.5 V in 100 mV increments can be manufactured. Contact your ON Semiconductor representative for availability.

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14

NCP1530

PACKAGE DIMENSIONS

Micro8

DM SUFFIX

CASE 846A−02

ISSUE F

NOTES:

1. DIMENSIONING AND TOLERANCING PER ANSI

Y14.5M, 1982.

−A−

2. CONTROLLING DIMENSION: MILLIMETER.

3. DIMENSION A DOES NOT INCLUDE MOLD

FLASH, PROTRUSIONS OR GATE BURRS. MOLD

FLASH, PROTRUSIONS OR GATE BURRS SHALL

NOT EXCEED 0.15 (0.006) PER SIDE.

4. DIMENSION B DOES NOT INCLUDE INTERLEAD

FLASH OR PROTRUSION. INTERLEAD FLASH OR

PROTRUSION SHALL NOT EXCEED 0.25 (0.010)

PER SIDE.

−B−

K

5. 846A−01 OBSOLETE, NEW STANDARD 846A−02.

PIN 1 ID

G

MILLIMETERS

INCHES

D 8 PL

DIM MIN

MAX

3.10

1.10

MIN

MAX

0.122

0.043

0.016

M

S

0.08 (0.003)

T

B

A

B

C

D

G

H

J

2.90

−−−

0.114

−−−

0.25

0.40 0.010

0.65 BSC

0.026 BSC

SEATING

PLANE

0.05

0.13

4.75

0.40

0.15 0.002

0.23 0.005

5.05 0.187

0.70 0.016

0.006

0.009

0.199

0.028

−T−

C

0.038 (0.0015)

K

L

J

H

SOLDERING FOOTPRINT*

1.04

^8X0.041

0.38

8X

0.015

3.20

0.126

4.24

0.167 0.208

5.28

0.65

^6X0.0256

SCALE 8:1

mm

inches

ǒ

Ǔ

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

details, please download the ON Semiconductor Soldering and

MountingTechniques Reference Manual, SOLDERRM/D.

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15

NCP1530

Micro8 is a trademark of International Rectifier.

ON Semiconductor and

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

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

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

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

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

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

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

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

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

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

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

PUBLICATION ORDERING INFORMATION

LITERATURE FULFILLMENT:

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

USA/Canada

ON Semiconductor Website: http://onsemi.com

Order Literature: http://www.onsemi.com/litorder

Literature Distribution Center for ON Semiconductor

P.O. Box 61312, Phoenix, Arizona 85082−1312 USA

Phone: 480−829−7710 or 800−344−3860 Toll Free USA/Canada

Fax: 480−829−7709 or 800−344−3867 Toll Free USA/Canada

Email: orderlit@onsemi.com

Japan: ON Semiconductor, Japan Customer Focus Center

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

Phone: 81−3−5773−3850

For additional information, please contact your

local Sales Representative.

NCP1530/D

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16


型号：	NCP1530_05
厂家：	ONSEMI
描述：	600 mA PWM/PFM Step-Down Converter with External Synchronization Pin 600毫安PWM / PFM降压转换器与外部同步引脚转换器
文件：	总16页 (文件大小：136K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

NCP1530_05 [ONSEMI]

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