HCPL-2201#560 Datasheet HCPL-2202-000E, HCPL-2212-060E, HCPL-2211-060E | P13-P15

13

V

OL

– LOW LEVEL OUTPUT VOLTAGE – V

-60

0

T

A

– TEMPERATURE – °C

100

1.0

-20

0.4

20 60-40 0 40 80

0.6

0.8

0.2

V

CC

= 4.5 V

V

F

= 0 V

I

O

= 6.4 mA

0.1

0.3

0.5

0.7

0.9

I

OH

– HIGH LEVEL OUTPUT CURRENT – mA

-60

-8

T

A

– TEMPERATURE – °C

100

0

-20

-5

20 60-40 0 40 80

-3

-1

-6

V

CC

= 4.5 V

I

F

= 5 mA

-7

-4

-2

V

O

= 2.7 V

V

O

= 2.4 V

V

O

– OUTPUT VOLTAGE – V

0

I

F

– INPUT CURRENT – mA

1.5

5

2

1.00.5

3

1

V

CC

= 4.5 V

T

A

= 25 °C

4

I

O

= 6.4 mA

I

O

= -2.6 mA

I

F

– FORWARD CURRENT – mA

1.1

0.001

V

F

– FORWARD VOLTAGE – V

1.0

1000

1.3

0.01

1.51.2 1.4

0.1

T

A

= 25 °C

10

100

HCPL-22XX

HCPL-02XX

I

F

+

–

V

F

I

F

– FORWARD CURRENT – mA

1.1

0.001

V

F

– FORWARD VOLTAGE – V

1.0

1000

1.3

0.01

1.51.2 1.4

0.1

10

100

HCNW22XX

I

F

+

–

V

F

1.6

T

A

= 25 °C

7

1

4

5

6

8

HCPL-2201/11

HCPL-02XX

HCNW22XX

GND

V

CC

5 V

619 Ω

INPUT

MONITORING

NODE

PULSE GEN.

t

r

= t

f

=

5 ns

f = 100 kHz

10 % DUTY

CYCLE

V

O

= 5 V

Z

O

= 50

C

2

=

15 pF

THE PROBE AND JIG CAPACITANCES

ARE INCLUDED IN C

1

AND

C

2

.

OUTPUT V

O

MONITORING

NODE

V

CC

R

1

D

1

D

2

5 kΩ

D

3

D

4

2

3

C

1

=

120 pF

R

1

I

F

(ON)

2.15 kΩ

1.6 mA

1.10 kΩ

3 mA

681 Ω

5 mA

ALL DIODES ARE 1N916 OR 1N3064.

*

7

4

5

6

8

HCPL-223X

GND

V

CC

5 V

619 Ω

INPUT

MONITORING

NODE

PULSE GEN.

t

r

= t

f

=

5 ns

f = 100 kHz

10 % DUTY

CYCLE

V

O

= 5 V

Z

O

= 50

C

2

=

15 pF

THE PROBE AND JIG CAPACITANCES

ARE INCLUDED IN C

1

AND

C

2

.

OUTPUT V

O

MONITORING

NODE

V

CC

R

1

D

1

D

2

5 kΩ

D

3

D

4

2

3

C

1

=

120 pF

R

1

I

F

(ON)

1.96 kΩ

1.8 mA

1.10 kΩ

3 mA

681 Ω

5 mA

ALL DIODES ARE 1N916 OR 1N3064.

1

*

I

F

(ON)

50 % I

F

(ON)

0 mA

t

PLH

t

PHL

V

OH

1.3 V

V

OL

INPUT I

F

OUTPUT V

O

* 0.1 μF BYPASS — SEE NOTE 9.

Figure 1. Typical logic low output voltage vs.

temperature.

Figure 2. Typical logic high output current vs.

temperature.

Figure 3. Typical output voltage vs. forward

input current.

Figure 4. Typical input diode forward characteristic.

Figure 5. Circuit for t

PLH

, t

PHL

, t

r

, t

f

.

14

t

P

– PROPAGATION DELAY – ns

-60

50

T

A

– TEMPERATURE – °C

100

200

250

-20

100

20 60-40 0 40 80

150

I

F

(mA)

HCPL-22XX

HCPL-02XX

5

3

1.6*

- 5

t

PLH

t

PHL

V

CC

= 5.0 V, 20 V

C1 (120 pF) PEAKING

CAPACITOR IS USED.

SEE FIGURE 5.

*I

F

= 1.8 mA FOR HCPL-223X

DEVICES.

t

P

– PROPAGATION DELAY – ns

-60

50

T

A

– TEMPERATURE – °C

100

200

250

-20

100

20 60-40 0 40 80

150

HCNW22XX

V

CC

= 5.0 V, 20 V

C1 (120 pF) PEAKING CAPACITOR

IS USED. SEE FIGURE 5.

5

3

1.6

1.6,

5

I

F

(mA)

t

PHL

t

PLH

P

O

– MAXIMUM OUTPUT POWER

PER CHANNEL (mW)

0

V

CC

– SUPPLY VOLTAGE – V

20

60

80

5

20

10

T

A

= 75 °C

15

40

T

A

= 85 °C

T

A

=

80°C

V

OH

– HIGH LEVEL OUTPUT VOLTAGE – V

0

V

CC

– SUPPLY VOLTAGE – V

20

15

20

5

10 15

10

TYPICAL

V

OH

vs. V

CC

AT I

O

= -2.6 mA

T

A

= 25 °C

t

r

, t

f

– RISE, FALL TIME – ns

-60

0

T

A

– TEMPERATURE – °C

100

-20

40

20 60-40 0 40 80

60

80

20

t

r

V

CC

= 5 V

t

f

7

1

4

5

6

8

HCPL-2201/11

HCPL-02XX

HCNW22XX

0.1 μF

BYPASS

OUTPUT V

O

MONITORING

NODE

V

CC

R

IN

2

3

V

FF

A

B

–+

V

CM

PULSE GENERATOR

–

+

7

4

5

6

8

HCPL-2231/32

0.1 μF

BYPASS

OUTPUT V

O

MONITORING

NODE

V

CC

2

3

V

FF

A

B

–+

V

CM

PULSE GENERATOR

1

+

–

R

1

V

CM

(PEAK)

OUTPUT V

O

* SEE NOTE 7, 9.

** I

F

= 1.8 mA FOR HCPL-2231/32 DEVICES.

0 V

V

OH

|V

CM

|

V

OL

V

O

(MAX.)*

V

O

(MIN.)*

SWITCH AT A: I

F

= 1.6 mA**

SWITCH AT B: V

F

= 0 V

Figure 6. Typical propagation delays vs. temperature. Figure 7. Maximum output power per channel

vs. supply voltage.

Figure 8. Typical logic high output voltage vs.

supply voltage.

Figure 9. Typical rise, fall time vs. temperature.

Figure 10. Test circuit for common mode transient immunity and typical waveforms.

15

INPUT CURRENT THRESHOLD – mA

-60

0.5

T

A

– TEMPERATURE – °C

100

1.0

-20

0.7

20 60-40 0 40 80

0.8

0.9

0.6

V

CC

= 5.0 V

V

CC

= 20 V

HCPL-22XX

HCPL-02XX

I

F

(ON)

I

F

(OFF)

I

F

(ON)

I

F

(OFF)

INPUT CURRENT THRESHOLD – mA

-60

0.5

T

A

– TEMPERATURE – °C

100

1.0

-20

0.7

20 60-40 0 40 80

0.8

0.9

0.6

V

CC

= 5.0 V

V

CC

= 20 V

HCNW22XX

I

F

(ON)

I

F

(OFF)

I

F

(ON)

I

F

(OFF)

OUTPUT POWER – P

S

, INPUT CURRENT – I

S

0

T

S

– CASE TEMPERATURE – °C

20050

400

12525 75 100 150

600

800

200

100

300

500

700

P

S

(mW)

I

S

(mA)

HCPL-2211/2212 OPTION 060

175

OUTPUT POWER P

S

, INPUT CURRENT I

S

0

T

S

– CASE TEMPERATURE – °C

175

1000

50

400

12525 75 100 150

600

800

200

100

300

500

700

900

P

S

(mW)

I

S

(mA)

HCNW22XX

18

27

36

45

1

2

HCPL-2201/11

HCPL-02XX

HCNW22XX

DATA INPUT

TTL OR LSTTL

V

CC2

(+5 V)

UP TO 16 LSTTL LOADS

OR 4 TTL LOADS

*

* 0.1 μF BYPASS

1.1 kΩ

V

CC1

(+5 V)

DATA OUTPUT

Figure 11. Typical input threshold current vs. temperature.

Figure 12. Thermal derating curve, dependence of safety limiting value with case temperature per IEC/EN/DIN EN 60747-5-5.

Figure 13a. Recommended LSTTL to LSTTL circuit where 500 ns propagation delay is su cient.

HCPL-2201#560

HCPL-2201#560

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