ADG5204BRUZ-RL7 Datasheet ADG5204BCPZ-RL7, ADG5204BRUZ, ADG5204BRUZ-RL7 | P10-P12

ADG5204

Rev. 0 | Page 9 of 20

PIN CONFIGURATIONS AND FUNCTION DESCRIPTIONS

ADG5204

NC = NO CONNECT

1

2

3

4

5

6

7

EN

V

SS

S1

NC

D

S2

A0

14

13

12

11

10

9

8

GND

V

DD

S3

NC

S4

A1

TOP VIEW

(Not to Scale)

09768-002

Figure 2. TSSOP Pin Configuration

NOTES

1. NC = NO CONNECT.

2

. EXPOSED PAD TIED TO SUBSTRATE,

V

SS

.

1V

SS

2NC

3S1

4S2

11 V

DD

12 GND

10 S3

9S4

5

NC

6

D

7

NC

8

NC

15

A0

16

EN

14

A1

13

NC

TOP VIEW

(Not to Scale)

ADG5204

09768-003

Figure 3. LFCSP Pin Configuration

Table 7. Pin Function Descriptions

Pin No.

TSSOP LFCSP Mnemonic Description

1 15 A0 Logic Control Input.

2 16 EN

Active High Digital Input. When this pin is low, the device is disabled and all switches are off.

When this pin is high, the Ax logic inputs determine the on switches.

3 1 V

SS

Most Negative Power Supply Potential.

4 3 S1 Source Terminal. Can be an input or an output.

5 4 S2 Source Terminal. Can be an input or an output.

6 6 D Drain Terminal. Can be an input or an output.

7 to 9 2, 5, 7, 8, 13 NC No Connect. These pins are open.

10 9 S4 Source Terminal. Can be an input or an output.

11 10 S3 Source Terminal. Can be an input or an output.

12 11 V

DD

Most Positive Power Supply Potential.

13 12 GND Ground (0 V) Reference.

14 14 A1 Logic Control Input.

N/A

1

EP Exposed Pad

Exposed Pad. The exposed pad is connected internally. For increased reliability of the solder

joints and maximum thermal capability, it is recommended that the pad be soldered to the

substrate, V

SS

.

1

N/A means not applicable.

TRUTH TABLE

Table 8.

EN A1 A0 S1 S2 S3 S4

0 X

1

X

1

Off Off Off Off

1 0 0 On Off Off Off

1 0 1 Off On Off Off

1 1 0 Off Off On Off

1 1 1 Off Off Off On

1

X is don’t care.

ADG5204

Rev. 0 | Page 10 of 20

TYPICAL PERFORMANCE CHARACTERISTICS

160

0

20

40

60

80

100

120

140

–25 –20 –15 –10 –5 0 5 10 15 20 25

ON RESISTANCE (Ω)

V

S

, V

D

(V)

T

A

= 25°C

V

DD

= +18V

V

SS

= –18V

V

DD

= +20V

V

SS

= –20V

V

DD

= +22V

V

SS

= –22V

09768-104

Figure 4. R

ON

as a Function of V

D

or V

S

, Dual Supply

250

200

150

100

50

0

–20 –15 –10 –5 0 5 10 15 20

ON RESISTANCE (Ω)

V

S

, V

D

(V)

T

A

= 25°C

V

DD

= +9V

V

SS

= –9V

V

DD

= +13.2V

V

SS

= –13.2V

V

DD

= +15V

V

SS

= –15V

V

DD

= +16.5V

V

SS

= –16.5V

09768-105

Figure 5. R

ON

as a Function of V

D

or V

S

, Dual Supply

500

450

400

350

300

250

200

150

100

50

0

01412108642

ON RESISTANCE (Ω)

V

S

, V

D

(V)

T

A

= 25°C

V

DD

= 9V

V

SS

= 0V

V

DD

= 10.8V

V

SS

= 0V

V

DD

= 12V

V

SS

= 0V

V

DD

= 13.2V

V

SS

= 0V

09768-106

Figure 6. R

ON

as a Function of V

D

or V

S

, Single Supply

160

140

120

100

80

60

40

20

0

043530252015105

ON RESISTANCE (Ω)

V

S

, V

D

(V)

0

T

A

= 25°C

V

DD

= 32.4V

V

SS

= 0V

V

DD

= 36V

V

SS

= 0V

V

DD

= 39.6V

V

SS

= 0V

09768-107

Figure 7. R

ON

as a Function of V

D

or V

S

, Single Supply

250

200

150

100

50

0

–15 –10 –5 0 5 10 15

ON RESISTANCE (Ω)

V

S,

V

D

(V)

V

DD

= +15V

V

SS

= –15V

T

A

= +125°C

T

A

= +85°C

T

A

= +25°C

T

A

= –40°C

09768-108

Figure 8. R

ON

as a Function of V

D

or V

S

, for Different Temperatures,

±15 V Dual Supply

200

160

120

80

40

180

140

100

60

20

0

–20 –15 –10 –5 0 5 10 2015

ON RESISTANCE (Ω)

V

S,

V

D

(V)

V

DD

= +20V

V

SS

= –20V

T

A

= +125°C

T

A

= +85°C

T

A

= +25°C

T

A

= –40°C

09768-109

Figure 9. R

ON

as a Function of V

D

or V

S

, for Different Temperatures,

±20 V Dual Supply

ADG5204

Rev. 0 | Page 11 of 20

500

400

300

200

100

450

340

250

150

50

0

024681012

ON RESISTANCE (Ω)

V

S,

V

D

(V)

V

DD

= 12V

V

SS

= 0V

T

A

= +125°C

T

A

= +85°C

T

A

= +25°C

T

A

= –40°C

09768-110

Figure 10. R

ON

as a Function of V

D

or V

S

for Different Temperatures,

12 V Single Supply

250

200

100

150

50

0

03530252015105

ON RESISTANCE (Ω)

V

S,

V

D

(V)

V

DD

= 36V

V

SS

= 0V

T

A

= +125°C

T

A

= +85°C

T

A

= +25°C

T

A

= –40°C

09768-111

Figure 11. R

ON

as a Function of V

D

or V

S

for Different Temperatures,

36 V Single Supply

10

–70

–60

–50

–40

–30

–20

–10

0

0 20 40 60 80 100 120

LEAKAGE CURRENT (pA)

TEMPERATURE (°C)

V

DD

= +15V

V

SS

= –15V

V

BIAS

= +10V/–10V

I

D

(OFF) – +

I

S

(OFF) – +

I

S

(OFF) + –

I

D

(OFF) + –

I

D,

I

S

(ON) + +

I

D,

I

S

(ON) – –

09768-112

Figure 12. Leakage Current vs. Temperature, ±15 V Dual Supply

0 20 40 60 80 100 120

TEMPERATURE (°C)

100

–200

–150

–100

–50

0

50

LEAKAGE CURRENT (pA)

V

DD

= +20V

V

SS

= –20V

V

BIAS

= +15V/–15V

I

D

(OFF) – +

I

S

(OFF) – +

I

S

(OFF) + –

I

D

(OFF) + –

I

D,

I

S

(ON) + +

I

D,

I

S

(ON) – –

09768-113

Figure 13. Leakage Current vs. Temperature, ±20 V Dual Supply

0 20406080100120

TEMPERATURE (°C)

40

20

–120

–100

–80

–60

–40

–20

0

LEAKAGE CURRENT (pA)

V

DD

= 12V

V

SS

= 0V

V

BIAS

= 1V/10V

I

D

(OFF) – +

I

S

(OFF) – +

I

S

(OFF) + –

I

D

(OFF) + –

I

D,

I

S

(ON) + +

I

D,

I

S

(ON) – –

09768-114

Figure 14. Leakage Current vs. Temperature, 12 V Single Supply

0 20406080100120

TEMPERATURE (°C)

50

–250

–200

–150

–100

–50

0

LEAKAGE CURRENT (pA)

V

DD

= 36V

V

SS

= 0V

V

BIAS

= 1V/30V

I

D

(OFF) – +

I

S

(OFF) – +

I

S

(OFF) + –

I

D

(OFF) + –

I

D

,I

S

(ON) + +

I

D

,I

S

(ON) – –

09768-115

Figure 15. Leakage Current vs. Temperature, 36 V Single Supply

ADG5204BRUZ-RL7

ADG5204BRUZ-RL7

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