IPP111N15N3 G [INFINEON]

与次优竞品相比，150V OptiMOS™ R DS(on) 降低 40%，品质因数 (FOM) 降低 45%。这一显著改进创造了全新的可能性，如从引脚封装转变为 SMD 封装或使用一个 OptiMOS™ 部件有效替换两个原有部件。;


型号：	IPP111N15N3 G
厂家：	Infineon
描述：	与次优竞品相比，150V OptiMOS™ R DS(on) 降低 40%，品质因数 (FOM) 降低 45%。这一显著改进创造了全新的可能性，如从引脚封装转变为 SMD 封装或使用一个 OptiMOS™ 部件有效替换两个原有部件。
文件：	总11页 (文件大小：757K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

IPB108N15N3 G IPP111N15N3 G

IPI111N15N3 G

OptiMOS^TM3 Power-Transistor

Product Summary

Features

V_DS

150

10.8

• N-channel, normal level

R_{DS(on),max (TO263)}

I_D

• Excellent gate charge x R _DS(on)product (FOM)

• Very low on-resistance R _DS(on)

• 175 °C operating temperature

• Pb-free lead plating; RoHS compliant; Halogen free

• Qualified according to JEDEC¹⁾for target application

• Ideal for high-frequency switching and synchronous rectification

•Halogen-free according to IEC61249-2-21

Type

IPB108N15N3 G

IPP111N15N3 G

IPI111N15N3 G

Package

Marking

PG-TO263

108N15N

PG-TO220-3

111N15N

PG-TO262-3

111N15N

Maximum ratings, at T _j=25 °C, unless otherwise specified

Value

Parameter

Symbol Conditions

Unit

I _D

T _C=25 °C

T _C=100 °C

T _C=25 °C

Continuous drain current

Pulsed drain current²⁾

I _D,pulse

E _AS

332

I _D=83 A, R _GS=25 W

Avalanche energy, single pulse

Gate source voltage

330

V _GS

±20

P _tot

T _C=25 °C

Power dissipation

214

°C

T _j, T _stg

Operating and storage temperature

IEC climatic category; DIN IEC 68-1

-55 ... 175

55/175/56

¹⁾J-STD20 and JESD22

²⁾See figure 3

Rev. 2.2

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2017-02-23

IPB108N15N3 G IPP111N15N3 G

IPI111N15N3 G

Values

typ.

Parameter

Symbol Conditions

Unit

min.

max.

Thermal characteristics

R _thJC

Thermal resistance, junction - case

0.7

K/W

R _thJA

minimal footprint

Thermal resistance, junction -

ambient

6 cm2 cooling area³⁾

Electrical characteristics, at T _j=25 °C, unless otherwise specified

Static characteristics

V _(BR)DSSV _GS=0 V, I _D=1 mA

V _GS(th)V _DS=V _GS, I _D=160 µA

Drain-source breakdown voltage

Gate threshold voltage

150

V _DS=120 V, V _GS=0 V,

T _j=25 °C

I _DSS

Zero gate voltage drain current

0.1

µA

V _DS=120 V, V _GS=0 V,

T _j=125 °C

100

I _GSS

V _GS=20 V, V _DS=0 V

Gate-source leakage current

100 nA

V _GS=10 V, I _D=83 A,

(TO220; TO262)

R _DS(on)

Drain-source on-state resistance

9.4

11.1

10.8

11.3

V _GS=10 V, I _D=83 A,

(TO263)

9.1

9.5

V _GS=8 V, I _D=41 A,

(TO220; TO262)

V _GS=8 V, I _D=41 A,

(TO263)

9.2

2.4

R _G

g _fs

Gate resistance

|V _DS|>2|I _D|R _DS(on)max

I _D=83 A

Transconductance

³⁾Device on 40 mm x 40 mm x 1.5 mm epoxy PCB FR4 with 6 cm²(one layer, 70 µm thick) copper area for drain

connection. PCB is vertical in still air.

Rev. 2.2

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2017-02-23

IPB108N15N3 G IPP111N15N3 G

IPI111N15N3 G

Values

typ.

Parameter

Symbol Conditions

Unit

min.

max.

Dynamic characteristics

Input capacitance

Output capacitance

Reverse transfer capacitance

Turn-on delay time

Rise time

C _iss

3230

378

V _GS=0 V, V _DS=75 V,

f =1 MHz

C _oss

C _rss

t _d(on)

t _r

V _DD=75 V, V _GS=10 V,

I _D=83 A, R _G=1.6 W

t _d(off)

t _f

Turn-off delay time

Fall time

Gate Charge Characteristics⁴⁾

Gate to source charge

Gate to drain charge

Switching charge

Q _gs

Q _gd

V _DD=75 V, I _D=83 A,

V _GS=0 to 10 V

Q _sw

Q _g

5.7

106

Gate charge total

V _plateau

Q _oss

Gate plateau voltage

Output charge

V _DD=75 V, V _GS=0 V

141 nC

Reverse Diode

I _S

Diode continous forward current

Diode pulse current

T _C=25 °C

I _S,pulse

332

V _GS=0 V, I _F=83 A,

T _j=25 °C

V _SD

Diode forward voltage

1.2

t _rr

Reverse recovery time

132

415

V _R=75 V, I _F=I _S,

di _F/dt =100 A/µs

Q _rr

Reverse recovery charge

⁴⁾See figure 16 for gate charge parameter definition

⁵⁾Plotted values correspond to IPP11N15N3 G and IPI111N15N3 G. Corresponding values for

IPB108N15N3 G are 0.3mΩ lower

Rev. 2.2

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2017-02-23

IPB108N15N3 G IPP111N15N3 G

IPI111N15N3 G

1 Power dissipation

2 Drain current

P _tot=f(T _C)

I _D=f(T _C); V _GS≥10 V

240

200

160

120

100

150

200

100

150

200

T_C[°C]

3 Safe operating area

I _D=f(V _DS); T _C=25 °C; D =0

parameter: t _p

4 Max. transient thermal impedance

Z _thJC=f(t _p)

parameter: D =t _p/T

10³

10²

10¹

10⁰

10^-1

10⁰

1 µs

10 µs

0.5

0.2

100 µs

10^-1

1 ms

0.1

0.05

0.02

10 ms

0.01

single pulse

10^-2

10^-5

10^-4

10^-3

10^-2

10^-1

10⁰

10^-1

10⁰

10¹

10²

10³

t_p[s]

V_DS[V]

Rev. 2.2

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2017-02-23

IPB108N15N3 G IPP111N15N3 G

IPI111N15N3 G

6 Typ. drain-source on resistance ⁵⁾

5 Typ. output characteristics

I _D=f(V _DS); T _j=25 °C

R _DS(on)=f(I _D); T _j=25 °C

parameter: V _GS

200

8 V

5 V

7 V

10 V

5.5 V

6.5 V

6 V

150

100

6 V

8 V

10 V

5.5 V

5 V

4.5 V

I_D[A]

100

120

V_DS[V]

7 Typ. transfer characteristics

I _D=f(V _GS); |V _DS|>2|I _D|R _DS(on)max

parameter: T _j

8 Typ. forward transconductance

g _fs=f(I _D); T _j=25 °C

200

150

100

120

100

25 °C

175 °C

120

V_GS[V]

I_D[A]

Rev. 2.2

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2017-02-23

IPB108N15N3 G IPP111N15N3 G

IPI111N15N3 G

9 Drain-source on-state resistance

10 Typ. gate threshold voltage

R _DS(on)=f(T _j); I _D=83 A; V _GS=10 V

V _GS(th)=f(T _j); V _GS=V _DS

parameter: I _D

3.5

1600 µA

160 µA

2.5

98%

1.5

typ

0.5

-60

-20

100

140

180

-60

-20

T_j[°C]

100

140

180

T_j[°C]

11 Typ. capacitances

12 Forward characteristics of reverse diode

I _F=f(V _SD

C =f(V _DS); V _GS=0 V; f =1 MHz

)

parameter: T _j

10⁴

10³

Ciss

10³

Coss

10²

175 °C

25°C, 98%

10²

175°C, 98%

25 °C

10¹

Crss

10⁰

0.5

1.5

100

V_SD[V]

V_DS[V]

Rev. 2.2

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2017-02-23

IPB108N15N3 G IPP111N15N3 G

IPI111N15N3 G

13 Avalanche characteristics

14 Typ. gate charge

V _GS=f(Q _gate); I _D=83 A pulsed

parameter: V _DD

I _AS=f(t _AV); R _GS=25 W

parameter: T _j(start)

100

120 V

25 °C

100 °C

75 V

125 °C

30 V

100

1000

t_AV[µs]

Q_gate[nC]

15 Drain-source breakdown voltage

16 Gate charge waveforms

V _BR(DSS)=f(T _j); I _D=1 mA

170

165

160

155

150

145

140

135

V _GS

Q_g

V _gs(th)

Q_g(th)

Q_sw

Q_gd

Q_gate

Q_gs

-60

-20

100

140

180

T_j[°C]

Rev. 2.2

page 7

2017-02-23

IPB108N15N3 G IPP111N15N3 G

IPI111N15N3 G

PG-TO220-3: Outline

Rev. 2.2

page 8

2017-02-23

IPB108N15N3 G IPP111N15N3 G

IPI111N15N3 G

PG-TO263: Outline

Rev. 2.2

page 9

2017-02-23

IPB108N15N3 G IPP111N15N3 G

IPI111N15N3 G

PG-TO262-3: Outline

Rev. 2.2

page 10

2017-02-23

IPB108N15N3 G IPP111N15N3 G

IPI111N15N3 G

Published by

Infineon Technologies AG

81726 Munich, Germany

Legal Disclaimer

The information given in this document shall in no event be regarded as a guarantee of

conditions or characteristics. With respect to any examples or hints given herein, any typical

values stated herein and/or any information regarding the application of the device,

Infineon Technologies hereby disclaims any and all warranties and liabilities of any kind,

including without limitation, warranties of non-infringement of intellectual property rights

of any third party.

Information

For further information on technology, delivery terms and conditions and prices, please

contact the nearest Infineon Technologies Office (www.infineon.com).

on the types in question, please contact the nearest Infineon Technologies Office.

Infineon Technologies components may be used in life-support devices or systems only with

the express written approval of Infineon Technologies, if a failure of such components can

reasonably be expected to cause the failure of that life-support device or system or to affect

the safety or effectiveness of that device or system. Life support devices or systems are

intended to be implanted in the human body or to support and/or maintain and sustain

and/or protect human life. If they fail, it is reasonable to assume that the health of the user

or other persons may be endangered.

Rev. 2.2

page 11

2017-02-23

IPP111N15N3 G [INFINEON]

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