Panasonic MAS3132D User Manual

Switching Diodes

This product complies with the RoHS Directive (EU 2002/95/EC).

MAS3132D

Silicon epitaxial planar type

For switching circuits

■ Features

•

Two elements are contained in one package, allowing high­density mounting

•

Short reverse recovery time t

•

Small terminal capacitance C

■ Absolute Maximum Ratings Ta = 25°C

Parameter Symbol Rating Unit

Reverse voltage V

Maximum peak reverse voltage V

Forward current Single I

Double 150

Peak forward current Single I

Double 340

Non-repetitive peak

forward surge current *Double 750

Junction temperature T

Storage temperature T

Note)*: t = 1 s

Single I

rr

t

R

RM

F

FM

FSM

j

stg

80 V

80 V

100 mA

225 mA

500 mA

150 °C

−55 to +150 °C

+0.05

0.33

–0.02

3

12

+0.05

0.23

–0.02

5˚

(0.40)(0.40)

0.80

±0.05

1.20±0.05

Marking Symbol: MO

Internal Connection

12

Unit: mm

+0.05

0.10

–0.02

±0.050.15 min.

1.20±0.05

0.80
5˚

0.52±0.03

0 to 0.01

1: Cathode 1
2: Cathode 2
3: Anode 1, 2

SSSMini3-F1 Package

3

0.15 min.

0.15 max.

■ Electrical Characteristics Ta = 25°C ± 3°C

Parameter Symbol Conditions Min Typ Max Unit

Forward voltage V

Reverse voltage V

Reverse current I

F

R

R

Terminal capacitance C

Reverse recovery time

*

t

rr

Note) 1. Measuring methods are based on JAPANESE INDUSTRIAL STANDARD JIS C 7031 measuring method for diodes.

2. Absolute frequency of input and output is 100 MHz.

3.*: t

measurement circuit

rr

Bias Application Unit N-50BU

A

Pulse Generator
(PG-10N)

= 50 Ω

R

s

Publication date: November 2003 SKF00064BED

Wave Form Analyzer
(SAS-8130)
R

= 50 Ω

i

IF = 100 mA 1.2 V

IR = 100 µA80V

VR = 75 V 100 nA

VR = 0 V, f = 1 MHz 15 pF

t

IF = 10 mA, VR = 6 V 10 ns

Irr = 0.1 IR , RL = 100 Ω

Input Pulse Output Pulse

t

t

p

r

10%

90%

V

R

= 2 µs

t

p

= 0.35 ns

t

r

δ = 0.05

t

I

F

I

= 10 mA

F

= 6 V

V

R

= 100 Ω

R

L

t

rr

I

= 0.1 I

rr

t

R

1

MAS3132D

This product complies with the RoHS Directive (EU 2002/95/EC).

IF  V

3

10

2

10

)

mA
(

F

10

1

Forward current I

−1

10

−2

10

0 0.2 0.4 0.6 0.8 1.0 1.2

F

Forward voltage VF (V

IR  T

a

)
nA

(

4

10

3

10

R

2

10

10

T

a

V

= 150°C

100°C

25°C

−20°C

)

= 75 V

R

35 V

6 V

IR  V

R

)
nA

(

4

10

3

10

R

2

10

10

Reverse current I

1

−1

10

0 20 40 60 80 100 120

Reverse voltage VR (V

Ct  V

8

)
pF

6

(

t

4

R

= 150°C

T

a

100°C

25°C

f = 1 MHz

= 25°C

T

a

VF  T

1.6

)

1.2

V
(

F

0.8

Forward voltage V

0.4

0

)

−40 0 40 80 120 160 200

Ambient temperature Ta (°C

I

F(surge)

)
A

(

F(surge)

3

10

2

10

10

a

 t

Non repetitive

= 100 mA

I

F

W

= 25°C

T

a

t

W

I

F(surge)

10 mA

3 mA

)

Reverse current I

1

−1

10

−40 0 40 80 120 160 200

Ambient temperature Ta (°C

2

Terminal capacitance C

1

Forward surge current I

0

)

0 20 40 60 80 100 120

Reverse voltage VR (V

)

−1

10

−1

Pulse width tW (ms

10110

)

2

SKF00064BED