Panasonic 2SK0620 Technical data

Silicon MOS FETs (Small Signal)

G

D

S

2SK0620 (2SK620)

Silicon N-Channel MOS FET

For switching

+0.2

2.8

–0.3
+0.25

1.5

0.65±0.15 0.65±0.15

–0.05

unit: mm

■ Features

● High-speed switching

● Mini-type package, allowing downsizing of the sets and automatic

insertion through the tape/magazine packing.

■ Absolute Maximum Ratings (Ta = 25°C)

Parameter

Drain to Source breakdown voltage
Gate to Source voltage
Drain current
Max drain current
Allowable power dissipation
Channel temperature
Storage temperature

Symbol

V

DSS

V

GSO

I

D

I

DP

P

D

T

ch

T

stg

Ratings

50

8
100
200
150
150

−55 to +150

Unit

V

V
mA
mA

mW

°C
°C

■ Electrical Characteristics (Ta = 25°C)

Parameter

Drain to Source cut-off current
Gate to Source leakage current
Drain to Source breakdown voltage
Gate threshold voltage
Drain to Source ON-resistance
Forward transfer admittance
Input capacitance (Common Source)
Output capacitance (Common Source)
Reverse transfer capacitance (Common Source)
Turn-on time
Turn-off time

*

ton, t

measurement circuit

off

= 5V

V

GS

50Ω

V

out

200Ω

100µF

V

DD

Symbol

I

DSS

I

GSS

V
V
R
| Yfs |
C
C
C
t

on

t

off

= 5V

DSS

th

DS(on)

iss

oss

rss

*

*

Conditions

VDS = 10V, VGS = 0
VGS = 8V, VDS = 0
ID = 100µA, VGS = 0
ID = 100µA, VDS = V

GS

ID = 20mA, VGS = 5V
ID = 20mA, VDS = 5V, f = 1kHz

VDS = 5V, VGS = 0, f = 1MHz

VDD = 5V, VGS = 0 to 5V, RL = 200Ω
VDD = 5V, VGS = 5 to 0V, RL = 200Ω

90%

V

in

V

out

10%

10%
90%

1

0.950.95

+0.2

–0.05

2.9

1.9±0.2

2

+0.2

–0.1

0.8

1.1

0.1 to 0.3

0.4±0.2

1: Gate JEDEC: TO-236
2: Source EIAJ: SC-59
3: Drain Mini Type Package (3-pin)

1.45

3

+0.1

+0.1

0 to 0.1

Marking Symbol: 3N
Internal Connection

min

50

1.5

20

typ

30

10
20

max

10
50

3.5
50

15

5
1

Unit

–0.05

0.4

–0.06

0.16

µA
nA

V
V

Ω

mS

pF
pF
pF

ns
ns

t

ontoff

Note) The part number in the parenthesis shows conventional part number.

281

Silicon MOS FETs (Small Signal)

2SK0620

PD  Ta ID  V

240

)
mW

(

200

D

160

120

80

40

Allowable power dissipation P

0

0 16040 12080 14020 10060

Ambient temperature Ta (˚C

C

, C

, C

iss

oss

rss

12

)

,

)

pF

(

10

rss

,C

Common source

(

oss

,C

8

iss

C

)

6

, Output capacitance

)

Common source

(

4

Common source

(

2

 V

C

iss

C

oss

DS

VGS=0
f=1MHz
Ta=25˚C

DS

120

100

)
mA

(

80

D

60

40

Drain current I

20

0

012108264

)

Drain to source voltage VDS (V

ID  V

120

100

GS

Ta=25˚C

VGS=6.0V

5.5V

5.0V

4.5V

4.0V

3.5V

3.0V

2.5V

V

=5V

DS

Ta=25˚C

)

)
mA

(

80

D

60

40

Ta=–25˚C

25˚C

75˚C

60

)
mS

(

50

|

fs

40

30

20

10

Forward transfer admittance |Y

0

120

)

Ω

(

100

DS(on)

80

60

40

Drain current I

20

20

| Yfs |  V

012108264

GS

VDS=5V
Ta=25˚C

Gate to source voltage VGS (V

R

 V

DS(on)

GS

ID=20mA

Ta=75˚C

25˚C

–25˚C

)

Input capacitance

Reverse transfer capacitance

0

1 3 10 30 100

Drain to source voltage VDS (V

VIN  I

100

30

)

10

V

(

IN

3

1

0.3

Input voltage V

0.1

0.03

0.01

0.1 1 10 1000.3 3 30

Output current IO (mA

C

O

rss

VO=5V
Ta=25˚C

)

0

012108264

)

Gate to source voltage VGS (V

Drain to source ON-resistance R

0

012108264

)

Gate to source voltage VGS (V

)

282