NCV6323DMTAAWTBG_技术文档

Buck Converter -

Synchronous

3 MHz, 2 A

High Efficiency, Low Ripple, Adjustable

Output Voltage

NCP6323, NCV6323

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The NCP/NCV6323 is a synchronous buck converter which is

optimized to supply different sub systems of portable applications

powered by one cell Li−ion or three cell Alkaline/NiCd/NiMH

batteries. The devices are able to deliver up to 2 A on an external

adjustable voltage. Operation with 3 MHz switching frequency allows

employing small size inductor and capacitors. Input supply voltage

feedforward control is employed to deal with wide input voltage

range. Synchronous rectification offer improved system efficiency.

The NCP/NCV6323 is in a space saving, low profile 2.0 x 2.0 x

0.75 mm WDFN8 package or a WDFNW8 wettable flank package.

MARKING

DIAGRAMS

1

XX MG

WDFN8

(NCV6323)

CASE 511BT

G

1

Features

XX MG

WDFN8

(NCP6323)

CASE 511BE

G

• 2.5 V to 5.5 V Input Voltage Range

• External Adjustable Voltage

• Up to 2 A Output Current

• 3 MHz Switching Frequency

• Synchronous Rectification

• Enable Input

1

XX MG

WDFNW8

(NCV6323)

CASE 511CL

G

• Power Good Output Option

• Soft−Start

XX = Specific Device Code

M

G

= Date Code

= Pb−Free Package

• Over Current Protection

• Active Discharge When Disabled

• Thermal Shutdown Protection

(Note: Microdot may be in either location)

• WDFN8, 2 x 2 mm, 0.5 mm Pitch Package &

PINOUT DIAGRAM

WDFNW8, 2 x 2 mm, 0.5 mm Pitch Package with Wettable Flanks

• Maximum 0.8 mm Height for Super Thin Applications

PGND

1

2

3

4

8

7

6

5

PVIN

AVIN

• NCV Prefix for Automotive and Other Applications Requiring

Unique Site and Control Change Requirements; AEC−Q100

Qualified and PPAP Capable

SW

AGND

FB

• These Devices are Pb−Free, Halogen Free/BFR Free and are RoHS

Compliant

9

PG

EN

Typical Applications

• Cellular Phones, Smart Phones, and PDAs

• Portable Media Players

• Digital Still Cameras

(Top View)

• Wireless and DSL Modems

• USB Powered Devices

• Point of Load

ORDERING INFORMATION

See detailed ordering, marking and shipping information on

page 2 of this data sheet.

• Game and Entertainment System

1

Publication Order Number:

July, 2020 − Rev. 10

NCV6323/D

NCP6323, NCV6323

ORDERING INFORMATION

Device

†

Marking

Package

Shipping

NCV6323BMTAATBG

NCP6323DMTAATBG

NCV6323DMTAATBG

NCV6323BMTAAWTBG

23

NN

VA

DQ

WDFN8

(Pb−Free)

3000 / Tape & Reel

WDFNW8

with wettable flanks

(Pb−Free)

NCV6323DMTAAWTBG

TM

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

Specifications Brochure, BRD8011/D.

NCP/NCV6323

PGND PVIN

1uH

Vo = 0.6V to Vin

Vin = 2.5 V to 5.5 V

Rpg

Cin

10uF

Cout

10uF

SW

AVIN

PG

1M

Power Good

Cfb

AGND

FB

R1

R2

Enable

EN

(a) Power Good Output Option (NCP/NCV6323)

Figure 1. Typical Application Circuit

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2

NCP6323, NCV6323

PIN DESCRIPTION

Name

Type

Description

1

PGND

Power

Ground

Power Ground for power, analog blocks. Must be connected to the system ground.

2

3

4

5

6

SW

AGND

FB

Power

Output

Switch Power pin connects power transistors to one end of the inductor.

Analog

Ground

Analog Ground analog and digital blocks. Must be connected to the system ground.

Analog

Input

Feedback Voltage from the buck converter output. This is the input to the error amplifier. This pin

is connected to the resistor divider network between the output and AGND.

EN

Digital

Input

Enable of the IC. High level at this pin enables the device. Low level at this pin disables the de-

vice.

PG

Digital

Output

It is open drain output. Low level at this pin indicates the device is not in power good, while high

impedance at this pin indicates the device is in power good. When not used, this pin can be left

unconnected.

7

8

9

AVIN

PVIN

PAD

Analog

Input

Analog Supply. This pin is the analog and the digital supply of the device. An optional 1 mF or lar-

ger ceramic capacitor bypasses this input to the ground. This capacitor should be placed as close

as possible to this input.

Power

Input

Power Supply Input. This pin is the power supply of the device. A 10 mF or larger ceramic capacit-

or must bypass this input to the ground. This capacitor should be placed as close a possible to

this input.

Exposed

Pad

Exposed Pad. Must be soldered to system ground to achieve power dissipation performances.

This pin is internally unconnected

L

Vo

Vin

PVIN

8

SW

2

1uH

Cin

Cout

10uF

PWM

Control

AVIN

7

UVLO

PGND

1

Cfb

R1

FB

4

Enable

EN

5

Error

Amp

Logic Control

&

Current Limit

&

Thermal

Shutdown

R2

Rpg

1M

Power Good

PG

6

AGND

3

PG

Reference

Voltage

Figure 2. Functional Block Diagram

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3

NCP6323, NCV6323

MAXIMUM RATINGS

Value

Min

−0.3

Max

6.0

Rating

Symbol

Unit

V

Analog Pins DC non switching:

Power Pins DC non switching:

AVIN, PG, FB, EN

PVIN, SW

V

A−DC

V

P−DC

6.0

V

Between PVIN, PGND pins, transient 3 ns − 3 MHz

Human Body Model (HBM) ESD Rating are (Note 1)

Machine Model (MM) ESD Rating (Note 1)

Latchup Current (Note 2)

V

P−TR

7.5

V

ESD HBM

ESD MM

2000

200

100

TSD

150

V

I

LU

−100

−40

mA

°C

Junction Temperature Range (Note 3)

Storage Temperature Range

T

JMAX

T

STG

−55

°C

Thermal Resistance Junction−to−Top Case (Note 4)

Thermal Resistance Junction−to−Board (Note 4)

Thermal Resistance Junction−to−Ambient (Note 4)

Power Dissipation (Note 5)

R

12

30

62

1.6

1

°C/W

W

q

JC

JB

JA

D

R

P

Moisture Sensitivity Level (Note 6)

MSL

−

Stresses exceeding those listed in the Maximum Ratings table may damage the device. If any of these limits are exceeded, device functionality

should not be assumed, damage may occur and reliability may be affected.

1. This device series contains ESD protection and passes 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 per JEDEC standard: JESD78 Class II.

3. The thermal shutdown set to 170°C (typical) avoids potential irreversible damage on the device due to power dissipation.

4. The thermal resistance values are dependent of the PCB heat dissipation. The board used to drive this data was an 80x50 mm NCP6324EVB

board. It is a multilayer board with 1 ounce internal power and ground planes and 2−1 ounce copper traces on top and bottom of the board.

If the copper traces of top and bottom are 1 ounce too, R

= 11°C/W, R

= 30°C/W, and R

= 72°C/W.

q

JC

JB

JA

5. The maximum power dissipation (PD) is dependent on input voltage, maximum output current and external components selected.

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

RECOMMENDED OPERATING CONDITIONS

Rating

Symbol

Min

2.5

Typ

−

Max

5.5

+125

−

Unit

V

Analog Input Supply

Power Input Supply

AV

PV

INR

2.5

−

V

Operating Junction Temperature Range (Note 7)

Inductor for DC to DC Converter (Note 8)

Output Capacitor (Note 8, 9)

T

J

−40

0.67

7.0

−

°C

mH

mF

L

OUT

1.0

10

C

−

OUT

Input Capacitor for Power Supply (Note 8)

C

7.0

−

PVIN

Functional operation above the stresses listed in the Recommended Operating Ranges is not implied. Extended exposure to stresses beyond

the Recommended Operating Ranges limits may affect device reliability.

7. The thermal shutdown set to 170°C (typical) avoids potential irreversible damage due to power dissipation.

8. Including de−ratings (Refer to the Application Information section of this document for further details).

9. The output capacitor value contributes to the regulator loop stability. Special care should be taken for C

contact your sales office.

selection. In case of doubt, please

OUT

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4

NCP6323, NCV6323

ELECTRICAL CHARACTERISTICS (V = 3.6 V, V

= 1.8 V, L = 1 mH, C = 10 mF, typical values are referenced to T = 25°C, Min

and Max values are referenced to T up to 125°C, unless other noted.)

IN

OUT

J

Symbol

Characteristics

Test Conditions

Min

Typ

Max

Unit

SUPPLY VOLTAGE

V

IN

Input Voltage V Range

(Note 10)

2.5

−

5.5

V

IN

SUPPLY CURRENT

I

V

IN

V

IN

Quiescent Supply Current

Shutdown Current

EN high, no load, Forced PWM Mode

EN low (Note 12 for NCP6323)

−

5.7

−

mA

Q

I

−

1

mA

SD

OUTPUT VOLTAGE

V

Output Voltage Range

FB Voltage

(Note 11)

0.6

594

−

V

OUT

IN

V

PWM Mode

600

−0.5

606

mV

%/A

FB

FB Voltage in Load Regulation

V

IN

= 3.6 V, I

from 200 mA to I ,

OUTMAX

−

OUT

PWM mode (Note 11)

= 200 mA, V from MAX (V +

NOM

FB Voltage in Line Regulation

Maximum Duty Cycle

I

−

0

−

%/V

%

OUT

IN

0.5 V, 2.3 V) to 5.5 V, PWM mode (Note 11)

D

(Note 11)

100

MAX

OUTPUT CURRENT

I

Output Current Capability

(Note 11)

2.0

2.3

−

A

OUTMAX

I

Output Peak Current Limit P−Channel

Output Peak Current Limit N−Channel

2.8

0.9

3.3

LIMP

I

LIMN

VOLTAGE MONITOR

V

UVLO Falling Threshold

UVLO Hysteresis

−

2.4

200

92

V

mV

%

INUV−

IN

V

INHYS

60

87

140

90

V

Power Good Low Threshold

V

OUT

falls down to cross the threshold

(percentage of FB voltage)

PGL

V

Power Good Hysteresis

V

rises up to cross the threshold

0

5

7

%

PGHYS

OUT

(percentage of Power Good Low Threshold

(V ) voltage)

PGL

Td

Power Good High Delay in Start Up

Power Good Low Delay in Shut Down

From EN rising edge to PG going high.

−

1.15

8

−

ms

PGH1

Td

From EN falling edge to PG going low.

(Note 11)

ms

PGL1

Td

Power Good High Delay in Regulation From V going higher than 95% nominal

−

5

8

−

ms

PGH

FB

level to PG going high.

Not for the first time in start up. (Note 11)

Td

Power Good Low Delay in Regulation

From V going lower than 90% nominal

PGL

FB

level to PG going low. (Note 11)

Voltage at PG pin with 5 mA sink current

3.6 V at PG pin when power good valid

VPG_L

PG_LK

Power Good Pin Low Voltage

−

0.3

V

Power Good Pin Leakage Current

100

nA

INTEGRATED MOSFETs

R

High−Side MOSFET ON Resistance

V

= 3.6 V (Note 12 for NCP6323)

IN

−

160

130

200

mW

ON_H

IN

V

= 5 V (Note 12 for NCP6323)

−

R

Low−Side MOSFET ON Resistance

V

IN

= 3.6 V (Note 12 for NCP6323)

= 5 V (Note 12 for NCP6323)

110

100

140

−

ON_L

V

IN

SWITCHING FREQUENCY

Normal Operation Frequency

F

SW

2.7

3.0

3.3

MHz

10.Operation above 5.5 V input voltage for extended periods may affect device reliability. At the first power−up, input voltage must be > 2.6 V.

11. Guaranteed by design, not tested in production.

12.Maximum value applies for T = 85°C.

J

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NCP6323, NCV6323

ELECTRICAL CHARACTERISTICS (V = 3.6 V, V

= 1.8 V, L = 1 mH, C = 10 mF, typical values are referenced to T = 25°C, Min

and Max values are referenced to T up to 125°C, unless other noted.)

IN

OUT

J

Symbol

Characteristics

Test Conditions

Min

Typ

Max

Unit

SOFT START

T

Time from EN to 90% of

output voltage target

ms

Start Time

NCP/NCV6323B

0

0.18

0.32

0.1

1

START

Start Time

NCP/NCV6323D

NCP/NCV6323B

NCP/NCV6323D

T

SS

Time from 10% to 90% of

output voltage target

Soft−Start Time

−

0.16

0.24

0.3

CONTROL LOGIC

EN Input High Voltage

V

EN_H

1.1

−

0.4

−

V

EN Input Low Voltage

EN Input Hysteresis

EN Input Bias Current

EN_L

V

−

270

0.1

mV

mA

EN_HYS

EN_BIAS

I

1

OUTPUT ACTIVE DISCHARGE

R_DIS

Internal Output Discharge Resistance

from SW to PGND

75

500

700

W

THERMAL SHUTDOWN

T

Thermal Shutdown Threshold

Thermal Shutdown Hysteresis

−

170

25

−

°C

SD

SD_HYS

T

Product parametric performance is indicated in the Electrical Characteristics for the listed test conditions, unless otherwise noted. Product

performance may not be indicated by the Electrical Characteristics if operated under different conditions.

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NCP6323, NCV6323

TYPICAL OPERATING CHARACTERISTICS

2

1.5

1

2

V

IN

V

IN

V

IN

= 5.5 V

= 3.6 V

= 2.5 V

1.5

1

0.5

0

0.5

0

2.5

3

3.5

4

4.5

5

5.5

−40

−15

10

35

60

85

V

IN

(V)

Temperature (°C)

Figure 3. Shutdown Current vs. Input Voltage

Figure 4. Shutdown Current vs. Temperature

(EN = Low, V_IN= 3.6 V)

(EN = Low, T_A= 255C)

8

7.5

7

8

7.5

7

V

IN

V

IN

V

IN

= 5.5 V

= 3.6 V

= 2.5 V

6.5

6

6.5

6

5.5

5

5.5

5

4.5

4

4.5

4

2.5

3

3.5

4

4.5

5

5.5

−40

−15

10

35

60

85

V

IN

(V)

V

IN

(V)

Figure 5. PWM Quiescent Current vs. Input

Voltage (EN = High, Open Loop, V_OUT= 1.8 V,

T_A= 255C)

Figure 6. PWM Quiescent Current vs.

Temperature (EN = High, Open Loop,

V

_OUT= 1.8 V, V_IN= 3.6 V)

90

85

80

75

70

65

60

55

50

95

90

85

80

75

70

65

60

55

50

V

IN

V

IN

V

IN

= 5.5 V

= 3.6 V

= 2.5 V

V

IN

V

IN

V

IN

= 5.5 V

= 3.6 V

= 2.5 V

0

400

800

1200

(mA)

1600

2000

0

400

800

1200

(mA)

1600

2000

I

OUT

Figure 7. Efficiency vs. Output Current and

Figure 8. Efficiency vs. Output Current and

Input Voltage (V_OUT= 1.05 V, T_A= 255C)

Input Voltage (V_OUT= 1.8 V, T_A= 255C)

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NCP6323, NCV6323

TYPICAL OPERATING CHARACTERISTICS

100

95

100

95

90

85

80

75

70

65

60

55

50

90

85

80

75

70

65

60

V

IN

V

IN

= 4.5 V

= 5.5 V

V

IN

V

IN

= 3.6 V

= 5.5 V

55

50

0

400

800

1200

(mA)

1600

2000

0

400

800

1200

(mA)

1600

2000

I

OUT

Figure 9. Efficiency vs. Output Current and

Figure 10. Efficiency vs. Output Current and

Input Voltage (V_OUT= 3.3 V, T_A= 255C)

Input Voltage (V_OUT= 4 V , T_A= 255C)

Figure 11. Output Ripple Voltage in PWM Mode

(V_IN= 3.6 V, V_OUT= 1.8 V, I_OUT= 1 A, L=1 mH,

Figure 12. Load Transient Response (V_IN= 3.6 V,

= 1.8 V, I_OUT= 500 mA to 1500 mA, L = 1 mH,

V

OUT

C

_OUT= 10 mF)

C

_OUT= 10 mF)

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NCP6323, NCV6323

TYPICAL OPERATING CHARACTERISTICS

Figure 13. Power Up Sequence and Inrush Current in

Figure 14. Power Up Sequence and Power Good

Input (V_IN= 3.6 V, V_OUT= 1.8 V, I_OUT= 0 A,

(V_IN= 3.6 V, V_OUT= 1.8 V, I_OUT= 0 A, L = 1 mH,

L = 1 mH, C_OUT= 10 mF)

C_OUT= 10 mF)

Figure 15. Power Down Sequence and Active Output

Discharge (V_IN= 3.6 V, V_OUT= 1.8 V, I_OUT= 0 A,

L = 1 mH, C_OUT= 10 mF)

Figure 16. Soft−start Time for NCP6323D

(V_IN= 4.2 V, V_OUT= 1.1 V, I_OUT= 0 A,

L = 1 mH,C_OUT= 10 mF)

Figure 17. Soft−start Time for NCV6323B

(V_IN= 4.2 V, V_OUT= 1.8 V, I_OUT= 0 A,

L = 1 mH,C_OUT= 10 mF)

Figure 18. Soft−start Time for NCP6323D

(V_IN= 4.2 V, V_OUT= 1.8 V, I_OUT= 0 A,

L = 1 mH,C_OUT= 10 mF)

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NCP6323, NCV6323

DETAILED DESCRIPTION

General

N−MOSFET operates as synchronous rectifier and its

turn−on signal is complimentary to that of the P−MOSFET.

The NCP/NCV6323 is a synchronous buck converter

which is optimized to supply different sub−systems of

portable applications powered by one cell Li−ion or three

cell Alkaline/NiCd/NiMH batteries. The devices are able to

deliver up to 2 A on an external adjustable voltage.

Operation with 3 MHz switching frequency allows

employing small size inductor and capacitors. Input supply

voltage feedforward control is employed to deal with wide

input voltage range. Synchronous rectification offer

improved system efficiency.

Undervoltage Lockout

The input voltage VIN must reach or exceed 2.5 V

(typical) before the NCP/NCV6323 enables the converter

output to begin the start up sequence. The UVLO threshold

hysteresis is typically 100 mV.

Enable

The NCP/NCV6323 has an enable logic input pin EN. A

high level (above 1.1 V) on this pin enables the device to

active mode. A low level (below 0.4 V) on this pin disables

the device and makes the device in shutdown mode. There

is an internal filter with 5 ms time constant. The EN pin is

pulled down by an internal 10 nA sink current source. In

most of applications, the EN signal can be programmed

independently to VIN power sequence.

PWM Mode Operation

In medium and heavy load range, the inductor current is

continuous and the device operates in PWM mode with fixed

switching frequency, which has a typical value of 3 MHz. In

this mode, the output voltage is regulated by on−time pulse

width modulation of an internal P−MOSFET. An internal

Figure 19. Power Good and Active Discharge Timing Diagram

Power Good Output

Soft−Start

The device monitors the output voltage and provides a

power good output signal at the PG pin. This pin is an

open−drain output pin. To indicate the output of the

converter is established, a power good signal is available.

The power good signal is low when EN is high but the output

voltage has not been established. Once the output voltage of

the converter drops out below 90% of its regulation during

operation, the power good signal is pulled low and indicates

a power failure. A 5% hysteresis is required on power good

comparator before signal going high again. When not used,

it is allowed to leave this pin unconnected.

A soft start limits inrush current when the converter is

enabled. After a minimum 80 ms delay time following the

enable signal, the output voltage starts to ramp up. Ramping

from 10% to 90% of the target voltage takes 100 ms typical

(NCP/NCV6323B) or 240 ms typical (NCP/NCV6323D).

Active Output Discharge

An output discharge operation is active in when EN is low.

A discharge resistor (500 W typical) is enabled in this

condition to discharge the output capacitor through SW pin.

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NCP6323, NCV6323

Cycle−by−Cycle Current Limitation

Negative Current Protection

The NCP/NCV6323 protects the device from over current

with a fixed−value cycle−by−cycle current limitation. The

typical peak current limit ILMT is 2.8 A. If inductor current

exceeds the current limit threshold, the P−MOSFET will be

turned off cycle−by−cycle. The maximum output current

can be calculated by

The NCP/NCV6323 includes a 1 A negative current

protection. It helps to protect the internal NMOS in case of

applications which require high output capacitor value.

Thermal Shutdown

The NCP/NCV6323 has a thermal shutdown protection to

protect the device from overheating when the die

temperature exceeds 170°C. After the thermal protection is

triggered, the fault state can be ended by re−applying VIN

and/or EN when the temperature drops down below 125°C.

ǒ

Ǔ

V

_OUT@ V_IN* V_OUT

(eq. 1)

I

_MAX+ I_LMT*

2 @ V_IN@ f_SW@ L

where VIN is input supply voltage, VOUT is output voltage,

L is inductance of the filter inductor, and f

normal switching frequency.

is 3 MHz

SW

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NCP6323, NCV6323

APPLICATION INFORMATION

Output Filter Design Considerations

The output filter introduces a double pole in the system at

a frequency of

to 50% of the maximum output current IOUT_MAX for a

trade−off between transient response and output ripple. The

inductance corresponding to the given current ripple is

1

ǒ_V

Ǔ

_IN* V_OUT@ V_OUT

_IN@ f_SW@ I_{L_PP}

f_LC

+

(eq. 2)

(eq. 3)

Ǹ

L +

2 @ p @ L @ C

V

The internal compensation network design of the

NCP/NCV6323 is optimized for the typical output filter

comprised of a 1.0 mH inductor and a 10 mF ceramic output

capacitor, which has a double pole frequency at about

50 kHz. Other possible output filter combinations may have

a double pole around 50 kHz to have optimum operation

with the typical feedback network. Normal selection range

of the inductor is from 0.47 mH to 4.7 mH, and normal

selection range of the output capacitor is from 4.7 mF to

22 mF.

The selected inductor must have high enough saturation

current rating to be higher than the maximum peak current

that is

I_{L_PP}

(eq. 4)

I

_{L_MAX}+ I_{OUT_MAX})

2

The inductor also needs to have high enough current

rating based on temperature rise concern. Low DCR is good

for efficiency improvement and temperature rise reduction.

Table 1 shows some recommended inductors for high power

applications and Table 2 shows some recommended

inductors for low power applications.

Inductor Selection

The inductance of the inductor is determined by given

peak−to−peak ripple current IL_PP of approximately 20%

Table 1. LIST OF RECOMMENDED INDUCTORS FOR HIGH POWER APPLICATIONS

Case Size

(mm)

Rated Current (mA)

(Inductance Drop)

Manufacturer

MURATA

Part Number

L (mH)

2.2

Structure

Wire Wound

LQH44PN2R2MP0

LQH44PN1R0NP0

LQH32PNR47NNP0

4.0 x 4.0 x 1.8

3.0 x 2.5 x 1.7

2500 (−30%)

MURATA

1.0

2950 (−30%)

MURATA

0.47

3400 (−30%)

Table 2. LIST OF RECOMMENDED INDUCTORS FOR LOW POWER APPLICATIONS

Case Size

(mm)

Rated Current (mA)

(Inductance Drop)

1320 (−30%)

2000 (−30%)

1150 (−30%)

Manufacturer

MURATA

TDK

Part Number

L (mH)

2.2

Structure

Wire Wound

LQH44PN2R2MJ0

LQH44PN1R0NJ0

VLS201612ET−2R2

VLS201612ET−1R0

4.0 x 4.0 x 1.1

2.0 x 1.6 x 1.2

1.0

2.2

TDK

1.0

1650 (−30%)

Output Capacitor Selection

operation mode, the three ripple components can be

obtained by

The output capacitor selection is determined by output

voltage ripple and load transient response requirement. For

a given peak−to−peak ripple current IL_PP in the inductor

of the output filter, the output voltage ripple across the

output capacitor is the sum of three ripple components as

below.

I_{L_PP}

(eq. 6)

V_{OUT_PP(C)}

+

8 @ C @ f_SW

V

_{OUT_PP(ESR)}+ I_{L_PP}@ ESR

(eq. 7)

(eq. 8)

ESL

V

_{OUT_PP}[ V_{OUT_PP(C)}) V_{OUT_PP(ESR)}) V_{OUT_PP(ESL)}

V_{OUT_PP(ESL)}

+

@ V_IN

ESL ) L

(eq. 5)

and the peak−to−peak ripple current is

where VOUT_PP(C) is a ripple component by an equivalent

total capacitance of the output capacitors, VOUT_PP(ESR)

is a ripple component by an equivalent ESR of the output

capacitors, and VOUT_PP(ESL) is a ripple component by

an equivalent ESL of the output capacitors. In PWM

ǒ_V

Ǔ

_IN* V_OUT@ V_OUT

_IN@ f_SW@ L

(eq. 9)

I_{L_PP}

+

V

www.onsemi.com

12

NCP6323, NCV6323

2

In applications with all ceramic output capacitors, the

ǒ Ǔ

_{OUT_MAX}@ D * D

I

(eq. 11)

(eq. 12)

main ripple component of the output ripple is

VOUT_PP(C). So that the minimum output capacitance can

be calculated regarding to a given output ripple requirement

VOUT_PP in PWM operation mode.

C_{IN_MIN}+

V

_{IN_PP}@ f_SW

where

V_OUT

V_IN

I_{L_PP}

D +

(eq. 10)

C_MIN

+

8 @ V_{OUT_PP}@ f_SW

In addition, the input capacitor needs to be able to absorb

the input current, which has a RMS value of

Input Capacitor Selection

Ǹ

_{IN_RMS}+ I_{OUT_MAX}@

D * D²

(eq. 13)

One of the input capacitor selection guides is the input

voltage ripple requirement. To minimize the input voltage

ripple and get better decoupling in the input power supply

rail, ceramic capacitor is recommended due to low ESR and

ESL. The minimum input capacitance regarding to the input

ripple voltage VIN_PP is

I

The input capacitor also needs to be sufficient to protect

the device from over voltage spike, and normally at least a

4.7 mF capacitor is required. The input capacitor should be

located as close as possible to the IC on PCB.

Table 3. LIST OF RECOMMENDED INPUT CAPACITORS AND OUTPUT CAPACITORS

Rated

Voltage

(V)

Case

Size

Height

Max (mm)

Manufacturer

MURATA

TDK

Part Number

C (mF)

22

Structure

MLCC

GRM21BR60J226ME39, X5R

C2012X5R0J226M, X5R

0805

0603

0805

1.4

1.25

1.35

1.25

0.9

6.3

10

22

MURATA

TDK

GRM21BR61A106KE19, X5R

C2012X5R1A106M, X5R

10

MURATA

TDK

GRM188R60J106ME47, X5R

C1608X5R0J106M, X5R

10

6.3

0.8

10

MURATA

Murata

TDK

GRM188R60J475KE19, X5R

GRM21BR70J106KE76, X7R

C2012X7R0J106K125AB, X7R

GRM21BR71A106KE51, X7R

C2012X7R1A106K125AC, X7R

0.87

1.4

4.7

10

1.45

1.4

10

Murata

TDK

10

1.45

10

Design of Feedback Network

the resistance from FB to AGND, which is used to program

the output voltage according to equation (14) once the value

of R1 has been selected. A capacitor Cfb needs to be

The output voltage is programmed by an external resistor

divider connected from V to FB and then to AGND, as

OUT

shown in the typical application schematic Figure 1(a). The

programmed output voltage is

employed between the V

and FB in order to provide

OUT

feedforward function to achieve optimum transient

response. Normal value range of Cfb is from 0 to 100 pF, and

a typical value is 15 pF for applications with the typical

output filter and R1 = 220 kW.

R₁

_@ǒ_{1 )}Ǔ

(eq. 14)

V

_OUT+ V_FB

R₂

Table 4 provides reference values of R1 and Cfb in case

of different output filter combinations. The final design may

need to be fine tuned regarding to application specifications.

where V is equal to the internal reference voltage 0.6 V,

FB

R1 is the resistance from V

to FB, which has a normal

OUT

value range from 50 kW to 1 MW and a typical value of

220 kW for applications with the typical output filter. R2 is

www.onsemi.com

13

NCP6323, NCV6323

Table 4. REFERENCE VALUES OF FEEDBACK NETWORKS (R1 AND CFB) FOR OUTPUT FILTER COMBINATIONS (L

and C)

R1 (kW)

L (mH)

Cfb (pF)

0.47

220

3

0.68

220

5

1

2.2

220

15

3.3

330

15

4.7

330

22

220

8

4.7

10

22

220

8

220

10

220

15

220

27

330

27

330

39

C (mF)

220

15

220

22

220

27

220

39

330

47

330

56

www.onsemi.com

14

NCP6323, NCV6323

LAYOUT CONSIDERATIONS

Electrical Layout Considerations

• Arrange a “quiet” path for output voltage sense and

feedback network, and make it surrounded by a ground

plane.

Good electrical layout is a key to make sure proper

operation, high efficiency, and noise reduction. Electrical

layout guidelines are:

Thermal Layout Considerations

• Use wide and short traces for power paths (such as

PVIN, VOUT, SW, and PGND) to reduce parasitic

inductance and high−frequency loop area. It is also

good for efficiency improvement.

• The device should be well decoupled by input capacitor

and input loop area should be as small as possible to

reduce parasitic inductance, input voltage spike, and

noise emission.

Good thermal layout helps high power dissipation from a

small package with reduced temperature rise. Thermal

layout guidelines are:

• The exposed pad must be well soldered on the board.

• A four or more layers PCB board with solid ground

planes is preferred for better heat dissipation.

• More free vias are welcome to be around IC and/or

underneath the exposed pad to connect the inner ground

layers to reduce thermal impedance.

• SW node should be a large copper pour, but compact

because it is also a noise source.

• Use large area copper especially in top layer to help

thermal conduction and radiation.

• Do not put the inductor to be too close to the IC, thus

the heat sources are distributed.

• It would be good to have separated ground planes for

PGND and AGND and connect the two planes at one

point. Directly connect AGND pin to the exposed pad

and then connect to AGND ground plane through vias.

Try best to avoid overlap of input ground loop and

output ground loop to prevent noise impact on output

regulation.

GND

VIN

P

PGND

SW

PVIN

1

2

3

4

8

7

6

5

A

AVIN

A

AGND

FB

MODE/PG

EN

F

P

L

P

Cfb

R1

O

P

F

R2

A

VOUT

GND

Figure 20. Recommended PCB Layout for Application Boards

www.onsemi.com

15

MECHANICAL CASE OUTLINE

PACKAGE DIMENSIONS

WDFN8 2x2, 0.5P

CASE 511BE−01

ISSUE A

1

DATE 27 MAY 2011

SCALE 2:1

L

A

B

E

NOTES:

D

1. DIMENSIONING AND TOLERANCING PER

ASME Y14.5M, 1994.

2. CONTROLLING DIMENSION: MILLIMETERS.

3. DIMENSION b APPLIES TO PLATED

TERMINAL AND IS MEASURED BETWEEN

0.15 AND 0.30 MM FROM TERMINAL TIP.

4. COPLANARITY APPLIES TO THE EXPOSED

PAD AS WELL AS THE TERMINALS.

L1

PIN ONE

REFERENCE

DETAIL A

ALTERNATE

CONSTRUCTIONS

2X

0.10 C

MILLIMETERS

DIM MIN

MAX

0.80

0.05

2X

0.10

C

A3

A

A1

A3

b

0.70

0.00

0.20 REF

0.20

2.00 BSC

TOP VIEW

EXPOSED Cu

MOLD CMPD

0.30

DETAIL B

A

D

0.10

C

D2

E

E2

e

1.50

2.00 BSC

0.80

0.50 BSC

0.25 REF

1.70

A3

C

A1

1.00

DETAIL B

ALTERNATE

0.08

C

CONSTRUCTIONS

K

A1

SIDE VIEW

NOTE 4

L

L1

0.20

−−−

0.40

0.15

SEATING

PLANE

GENERIC

MARKING DIAGRAM*

D2

DETAIL A

^8XL

1

8

4

1

XX MG

G

E2

b

XX = Specific Device Code

M

G

= Date Code

= Pb−Free Package

5

K

8X

e

0.10

C

A

B

(Note: Microdot may be in either location)

0.05

NOTE 3

BOTTOM VIEW

*This information is generic. Please refer to

device data sheet for actual part marking.

Pb−Free indicator, “G” or microdot “ G”,

may or may not be present.

RECOMMENDED

SOLDERING FOOTPRINT*

8X

0.50

1.70

PACKAGE

OUTLINE

1.00

2.30

1

8X

0.50

PITCH

0.30

DIMENSIONS: MILLIMETERS

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

details, please download the ON Semiconductor Soldering and

Mounting Techniques Reference Manual, SOLDERRM/D.

Electronic versions are uncontrolled except when accessed directly from the Document Repository.

Printed versions are uncontrolled except when stamped “CONTROLLED COPY” in red.

DOCUMENT NUMBER:

DESCRIPTION:

98AON48936E

WDFN8, 2X2, 0.5P

PAGE 1 OF 1

ON Semiconductor and

are trademarks of Semiconductor Components Industries, LLC dba ON Semiconductor or its subsidiaries in the United States and/or other countries.

ON Semiconductor reserves the right to make changes without further notice to any products herein. ON Semiconductor makes no warranty, representation or guarantee regarding

the suitability of its products for any particular purpose, nor does ON Semiconductor 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. ON Semiconductor does not convey any license under its patent rights nor the

rights of others.

www.onsemi.com

MECHANICAL CASE OUTLINE

PACKAGE DIMENSIONS

WDFN8 2x2, 0.5P (Customer Special Only)

CASE 511BT−01

ISSUE O

1

DATE 26 MAY 2011

SCALE 2:1

B

E

A

NOTES:

D

1. DIMENSIONING AND TOLERANCING PER

ASME Y14.5M, 1994.

L

2. CONTROLLING DIMENSION: MILLIMETERS.

3. DIMENSION b APPLIES TO PLATED

TERMINAL AND IS MEASURED BETWEEN

0.15 AND 0.30 MM FROM TERMINAL TIP.

4. COPLANARITY APPLIES TO THE EXPOSED

PAD AS WELL AS THE TERMINALS.

PIN ONE

REFERENCE

L1

DETAIL A

2X

0.10 C

MILLIMETERS

DIM MIN

MAX

0.80

0.05

2X

0.10

C

A

A1

A3

b

0.70

0.00

0.20 REF

0.20

2.00 BSC

TOP VIEW

MOLD CMPD

EXPOSED Cu

0.30

DETAIL B

A

D

0.10

0.08

C

D2

E

E2

e

1.50

2.00 BSC

0.80

0.50 BSC

0.25 REF

1.70

A3

C

1.00

A3

A1

C

K

DETAIL B

A1

SIDE VIEW

NOTE 4

L

L1

0.20

−−−

0.40

0.15

SEATING

PLANE

GENERIC

MARKING DIAGRAM*

D2

DETAIL A

8X L

1

8

4

1

XX MG

G

E2

b

XX = Specific Device Code

M

G

= Date Code

= Pb−Free Package

5

K

8X

e

0.10

C

A B

(Note: Microdot may be in either location)

0.05

NOTE 3

*This information is generic. Please refer to

device data sheet for actual part marking.

Pb−Free indicator, “G” or microdot “ G”,

may or may not be present.

BOTTOM VIEW

RECOMMENDED

SOLDERING FOOTPRINT*

8X

0.50

1.70

PACKAGE

OUTLINE

1.00

2.30

1

8X

0.50

PITCH

0.30

DIMENSIONS: MILLIMETERS

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

details, please download the ON Semiconductor Soldering and

MountingTechniques Reference Manual, SOLDERRM/D.

98AON57461E

ON SEMICONDUCTOR STANDARD

DOCUMENT NUMBER:

STATUS:

Electronic versions are uncontrolled except when

accessed directly from the Document Repository. Printed

versions are uncontrolled except when stamped

“CONTROLLED COPY” in red.

NEW STANDARD:

©

Semiconductor Components Industries, LLC, 2002

Case Outline Number:

http://onsemi.com

October, 2D0E0S2 C− RReIPv.T0ION: WDFN8, 2X2 (CUSTOMER SPECIAL ONLY)

PAGE 1 OF 2

XXX

1

DOCUMENT NUMBER:

98AON57461E

PAGE 2 OF 2

ISSUE

REVISION

DATE

26 MAY 2011

O

RELEASED FOR PRODUCTION. REQ. BY C. GOYON.

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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.

©

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Case Outline Number:

May, 2011 − Rev. 01O

511BT

MECHANICAL CASE OUTLINE

PACKAGE DIMENSIONS

WDFNW8 2x2, 0.5P

CASE 511CL

ISSUE B

1

SCALE 2:1

DATE 03 DEC 2019

GENERIC

MARKING DIAGRAM*

1

XX MG

G

XX = Specific Device Code

M

= Date Code

G

= Pb−Free Package

(Note: Microdot may be in either location)

*This information is generic. Please refer to

device data sheet for actual part marking.

Pb−Free indicator, “G” or microdot “ G”, may

or may not be present. Some products may

not follow the Generic Marking.

Electronic versions are uncontrolled except when accessed directly from the Document Repository.

Printed versions are uncontrolled except when stamped “CONTROLLED COPY” in red.

DOCUMENT NUMBER:

DESCRIPTION:

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WDFNW8 2x2, 0.5P

PAGE 1 OF 1

ON Semiconductor and

are trademarks of Semiconductor Components Industries, LLC dba ON Semiconductor or its subsidiaries in the United States and/or other countries.

ON Semiconductor reserves the right to make changes without further notice to any products herein. ON Semiconductor makes no warranty, representation or guarantee regarding

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


型号：	NCV6323DMTAAWTBG
厂家：	ONSEMI
描述：	同步降压转换器，3 MHz，2 A 转换器
文件：	总20页 (文件大小：983K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

NCV6323DMTAAWTBG [ONSEMI]

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