1.5SMC62A-H 参数 Datasheet PDF下载

1.5SMC Transient Voltage Suppressor Diode Series

3312 - 2 mm SMD Trimming Potentiometer

Rating

100

Characteristic Curves

&

100

Peak Pulse Derating in Percent of

Peak Pulse Derating in Percent of

Peak Pulse Derating in Percent of

Peak Power or Current

Peak Power or Current

Peak Power or Current

Peak Pulse Derating in Percent of

Peak Pulse Derating in Percent of

Peak Pulse Derating in Percent of

Peak Power or Current

Peak Power or Current

Peak Power or Current

100

100

Pulse Derating Curve

75

100

75

75

100

75

200

IFSM - Peak Forward Surge Current (A)

FSM - Peak Forward Surge Current (A)

IFSM I- Peak Forward Surge Current (A)

180

200

200

IFSM - Peak Forward Surge Current (A)

IFSM - Peak Forward Surge Current (A)

IFSM - Peak Forward Surge Current (A)

160

180

200

140

160

180

50

50

120

140

160

75

75

50

100

50

120

140

25

25

80

100

5010 x 1000 Waveform as Defined

50

120

10 x 1000 Waveform as Defined

25

6080

25

by R.E.A.

100

by R.E.A.

10 x 1000 Waveform as Defined

0

10 x 1000 Waveform as Defined

0 25

4060

25

by R.E.A.

80

200

by R.E.A. 50

0

25 0 50 25

75

100 75

125 100

150 125

175 150

200 175

0 10 x 1000 Waveform as Defined

2040

0 10 x 1000 Waveform as Defined

Ambient Temperature (°C)

Ambient Temperature (°C)

200 60

0

25 0 by R.E.A. by R.E.A. 125 100

50 25

75 50

100 75

150 125

175 150

200 175

020

0

0

Ambient Temperature (°C)

40

Ambient Temperature (°C)

1

200

25 0 50 25

75 50

100 75

125 100

150 125

175 150

200 175

0

0

20

Ambient Temperature (°C)

Ambient Temperature (°C)

1

0

1

Maximum Non-Repetitive Surge Current

160

180

200

140

160

180

120

140

160

100

120

140

80

100

120

6080

100

4060

80

2040

60

020

40

1

10

10

0

Number of Cycles at 60 Hz

20 1Number of Cycles at 60 Hz

10

10

0

Number of Cycles at 60 Hz

Number of Cycles at 60 Hz

1

10

10

180

200

100

100

100

100

100

100

Number of Cycles at 60 Hz

Number of Cycles at 60 Hz

Pulse Waveform

100

IP, Peak Pulse Current (%)

IP, Peak Pulse Current (%)

IP, Peak Pulse Current (%)

100000

Peak value (IRSM)

100000

Bidirectional V = 0 V

Peak value (IRSM)

100

Bidirectional V = 0 V

TR=10 µs

TR=10 µs

10000

IRSM

10000

IRSM

Half value=

Peak value (IRSM)

Bidirectional V = 0 V

100000

100000

Peak value (IRSM)

2

100 Half value= 2

Bidirectional V = 0Unidirectional Unidirectional V = 0 V

V

100

V=0V

TR=10 µs TR=10 µs

10000

IRSM

10000

IRSM

Half value=

Half value=

Peak value (IRSM)2 Pulse width (TP)

Peak value (IRSM)

Bidirectional V = 0 V V = 0 V

Bidirectional V = 0 VUnidirectional Unidirectional V = 0 V

2 Pulse width (TP)

1000

100

100

is defined as that point

1000

Unidirectional Unidirectional @ VR

@ VR

is defined as that point

10000

10000

IRSM

IRSM

where the peak current

Half value= Half value=

Pulse width (TP)

Pulse width (TP)

1000

2 is defined as that point

2where the peak current

decays to 50 % of IPSM.

UnidirectionalUnidirectional V = 0 V

V=0V

50

1000

decays to 50 % of IPSM.

50

Unidirectional Unidirectional @ VR

@ VR

is defined as that point

where the peak current

100

where the peak current

10 x 1000 waveform

100

Pulse width (TP)

Pulse width (TP)

decays to 50 % of IPSM.

10 x 1000 waveform

50

1000

1000

decays to 50 % of IPSM.

as defined by R.E.A.

50 TA=25 °C TA=25 °C

is defined as that point

UnidirectionalUnidirectional @ VR

@ VR

is defined as that point

as defined by R.E.A.

100

TP

where the peak current

where the peak current

10 x 1000 waveform

100

TP

10 x 1000 waveform

decays to 50 % of IPSM.

decays to 50 % of IPSM.

as defined by R.E.A.

50

50 TA=25 °C TA=25 °C

as defined by R.E.A.

10 T = 25 10 TJ = 25 °C

TP

°C

100

100 J

TP

10 x 1000 waveform

10 x 1000 waveform

f = 1.0 MHz f = 1.0 MHz

0

TA=25 °C TA=25 °C

10 V T = 25 °C

as defined by R.E.A.

as defined by R.E.A.

Bidirectional @ VR

0

10 V T = 50 mVp-p J= 50 mVp-p

Bidirectional @ VR

2.0

3.0

4.0

sigJ = 25 °C sig= 1.0 MHz

TP 1.0

TP0 1.0

f

0

2.0

3.0

4.0

1

f = 1.0 MHz

1

0

Bidirectional @ VR

0

10 VT = 25 10 Vsig== 50 mVp-p 10 Bidirectional @ VR 100

1mVp-p 25

1000

T, Time (ms) T, Time (ms)

J

0 1.0

1.0

2.0

3.0

4.0

sig = 50°C TJ 10 °C

1

100

1000

2.0

3.0

4.0

0

1

f = 1.0 MHz f = 1.0 MHzV

1

- Reverse Breakdown Voltage (V)

0

0

VV

Breakdown Voltage (V) Bidirectional VR

1 BR - ReverseBR

1000

T, Time (ms) T, Time (ms)

sig 50

1 Vsig = 50 mVp-p = 10 mVp-p 10Bidirectional @ VR 100 @ 1000

100

0 1.0

1.0

2.0

3.0

4.0

0

2.0

3.0

4.0

1

1

V BR - Reverse Breakdown Voltage (V)

V

- Reverse Breakdown Voltage (V)

T, Time (ms)T, Time (ms)

1 BR 10

10

100

1000

1

100

1000

C J - Junction Capacitance (pF)

C J - Junction Capacitance

C J - Junction Capacitance (pF) (pF)

C J - Junction Capacitance (pF)

C J - Junction Capacitance

C J - Junction Capacitance (pF) (pF)

IP, Peak Pulse Current (%)

IP, Peak Pulse Current (%)

IP, Peak Pulse Current (%)

V BR - ReverseBR - Reverse

Curve

Breakdown Voltage (V)

Steady State Power

V

Derating

Breakdown Voltage (V)

RM(AV) Steady State Power Dissipation (W)

RM(AV) Steady State Power Dissipation (W)

RM(AV) Steady State Power Dissipation (W)

TA = 25 °C TA = 25 °C

Non-repetitive Pulse Waveform

Non-repetitive Pulse Waveform

Shown in Pulse Waveform Graph

TA = 25 °C TA = 25 °C

Shown in Pulse Waveform Graph

Non-repetitive Pulse Waveform

Non-repetitive Pulse Waveform

Shown in Pulse Waveform Graph

TA = 25 °C TA = 25 °C

Shown in Pulse Waveform Graph

5.0

RM(AV) Steady State Power Dissipation (W)

RM(AV) Steady State Power Dissipation (W)

RM(AV) Steady State Power Dissipation (W)

5.0

4.0

5.0

4.0

3.0

4.0

3.0

2.0

3.0

2.0

1.0

2.0

1.0

5.0

5.0

4.0

5.0

4.0

3.0

4.0

3.0

2.0

3.0

2.0

1.0

2.0

1.0

TR=10 µs

TR=10 µs

100000

100000

Typical Junction Capacitance

Pulse Rating Curve

100

100

PP, Peak Power (KW)

PP, Peak Power (KW)

PP, Peak Power (KW)

PP, Peak Power (KW)

PP, Peak Power (KW)

PP, Peak Power (KW)

100

100

100

100

10

10

10

10

10

10

Non-repetitive Pulse Waveform

Non-repetitive Pulse Waveform

Shown in Pulse Waveform Graph

Shown in Pulse Waveform Graph

60 Hz Resistive or

60 Hz Resistive or

Inductive Load

Inductive Load

0.1 µs 10 µs

1.0 µs 100 µs

10 µs

100 µs 10 ms

1.0 ms

10 ms

60 Hz Resistive or

0.1 µs

1.0 µs

1.0 ms

0.0

1.0

60 Hz Resistive or

0.0

1.0

Inductive Load

200

0

TP, Pulse Width

1.0 50 25 75 50 100 75 125100 150125 175 150 200 175

1.0

Inductive Load

0

25

0.1 µs TP, Pulse Width

1.0 µs 100 µs

10 µs

100 µs 10 ms

1.0 ms

10 ms

0.1 µs

1.0 µs

10 µs

1.0 ms

0.0

60 Hz Resistive or

60 Hz Resistive or

0.0

TL, Lead Temperature (°C)

1.0

1.0

T , Lead Temperature (°C)

200

TP

0

25 0

50 L25 75 50 100 75 125100 150125 175 150 200 175

Inductive Load

Inductive Load

TP, Pulse Width , Pulse Width

0.1 µs 10 µs

1.0 µs

10 µs

100 µs 10 ms

1.0 ms

10 ms

0.1 µs

1.0 µs

1.0 ms

Specifications are subject to change without notice.

100 µs

0.0

0.0

TL, Lead Temperature (°C)

TL, Lead Temperature (°C)

The device characteristics and parameters in this data sheet can and do vary in different applications and actual device performance may vary over time.

125 175 150 200 175

200

0

25 0

50 25 75 50 100 75 125100 150

TP

TP, Pulse Width , Pulse Width

1.0

1.0

Users should verify actual device performance in their specific applications.

TL, Lead Temperature (°C)

TL, Lead Temperature (°C)