Panasonic MA2S7280G User Manual

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

Schottky Barrier Diodes (SBD)

MA2S7280G

Silicon epitaxial planar type

For switching

For wave detection

■ Features

•

High-density mounting is possible

•

Low forward voltage V

•

Small temperature coefficient of forward characteristic

•

Small reverse current I

and good wave detection efficiency η

F

R

■ Package

•

Code
SSMini2-F4

•

Pin Name

1: Anode
2: Cathode

■ Absolute Maximum Ratings Ta = 25°C

■ Marking Symbol: B

Parameter Symbol Rating Unit

Reverse voltage V

Maximum peak reverse voltage V

Forward current I

Peak forward current I

Junction temperature T

Storage temperature T

R

RM

F

FM

j

stg

30 V

30 V

30 mA

150 mA

125 °C

−55 to +125 °C

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

Parameter Symbol Conditions Min Typ Max Unit

Forward voltage V

Reverse current I

F1

V

F2

R

Terminal capacitance C

Reverse recovery time

*

t

rr

Detection efficiency η VIN = 3 V

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

2. This product is sensitive to electric shock (static electricity, etc.). Due attention must be paid on the charge of a human body

and the leakage of current from the operating equipment.

3. Absolute frequency of input and output is 2 GHz.

4.*:trr measurement circuit

Bias Application Unit (N-50BU)

A

Pulse Generator
(PG-10N)

= 50 Ω

R

s

Wave Form Analyzer
(SAS-8130)

= 50 Ω

R

i

IF = 1 mA 0.4 V

IF = 30 mA 1.0

VR = 30 V 300 nA

VR = 1 V, f = 1 MHz 1.5 pF

t

IF = IR = 10 mA 1.0 ns

Irr = 1 mA, RL = 100 Ω

, f = 30 MHz 65 %

(peak)

RL = 3.9 kΩ, CL = 10 pF

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

= 10 mA

I

F

= 10 mA

I

R

= 100 Ω

R

L

t

rr

I

= 1 mA

rr

t

Publication date: October 2007 SKH00174AED

1

MA2S7280G

I

Ta = 125°C

)

mA

(

3

10

2

10

F

10

1

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

 V

F

F

75°C 25°C

−20°C

3

10

2

10

)
µA

(

R

10

1

IR  V

R

Ta = 125°C

75°C

VF  T

1.6

)

1.2

V
(

F

0.8

a

IF = 30 mA

Forward current I

–1

10

–2

10

0 0.4 0.8 1.2

Forward voltage VF (V

IR  T

2

10

)

10

A

(µ

R

1

−1

Reverse current I

10

−2

10

−40 0 40 80 120 160 200

a

VR = 30 V
10 V
1 V

Ambient temperature Ta (°C

I

 T

)
A

(m

F(AV)

T

= 125

j

F(AV)

°C

50

40

30

a

I

F

t

p

Reverse current I

−1

10

−2

10

)

0 5 10 15 20 25 30

Reverse voltage VR (V

Ct  V

3.0

)
pF

(

t

2.0

1.0

25°C

)

R

Terminal capacitance C

0

)

T

0102030

Reverse voltage VR (V

)

Forward voltage V

0.4

0

−40 0 40 80 120 160 200

3 mA

1 mA

Ambient temperature Ta (°C

I

 t

)
A

(

F(surge)

3

10

2

10

10

1

F(surge)

W

Ta = 25°C

t

W

Forward surge current I

−1

10

−1

10

110

Pulse width tW (ms

)

I

F(surge)

)

20

10

Forward current (Average) I

0

0DC40 16012080

Ambient temperature Ta (°C

2

)

SKH00174AED