NLVHC4051ADTR2G Datasheet NLVHC4053ADWR2G, MC74HC4051ADR2G, MC74HC4053ADR2G | P10-P12

MC74HC4051A, MC74HC4052A, MC74HC4053A

www.onsemi.com

10

R

L

Figure 12. Crosstalk Between Any Two

Switches, Test Set−Up

Figure 13. Power Dissipation Capacitance,

Test Set−Up

Figure 14a. Total Harmonic Distortion, Test Set−Up Figure 14b. Plot, Harmonic Distortion

0

-10

-20

-30

-40

-50

- 100

1.0 2.0 3.125

FREQUENCY (kHz)

dB

-60

-70

-80

-90

FUNDAMENTAL FREQUENCY

DEVICE

SOURCE

ON

6

7

8

16

V

EE

C

L

*

*Includes all probe and jig capacitance

OFF

R

L

R

L

V

IS

R

L

C

L

*

V

OS

f

in

0.1mF

ON/OFF

6

7

8

16

V

CC

CHANNEL SELECT

NC

COMMON O/I

OFF/ON

ANALOG I/O

V

CC

A

11

V

CC

V

EE

ON

6

7

8

16

V

CC

V

EE

0.1mF

C

L

*

f

in

R

L

TO

DISTORTION

METER

*Includes all probe and jig capacitance

V

OS

V

IS

APPLICATIONS INFORMATION

The Channel Select and Enable control pins should be at

V

CC

or GND logic levels. V

CC

being recognized as a logic

high and GND being recognized as a logic low. In this

example:

V

CC

= +5V = logic high

GND = 0V = logic low

The maximum analog voltage swings are determined by

the supply voltages V

CC

and V

EE

. The positive peak analog

voltage should not exceed V

CC

. Similarly, the negative peak

analog voltage should not go below V

EE

. In this example,

the difference between V

CC

and V

EE

is ten volts. Therefore,

using the configuration of Figure 15, a maximum analog

signal of ten volts peak−to−peak can be controlled. Unused

analog inputs/outputs may be left floating (i.e., not

connected). However, tying unused analog inputs and

outputs to V

CC

or GND through a low value resistor helps

minimize crosstalk and feed−through noise that may be

picked up by an unused switch.

Although used here, balanced supplies are not a

requirement. The only constraints on the power supplies are

that:

V

CC

− GND = 2 to 6 volts

V

EE

− GND = 0 to −6 volts

V

CC

− V

EE

= 2 to 12 volts

and V

EE

≤ GND

When voltage transients above V

CC

and/or below V

EE

are

anticipated on the analog channels, external Germanium or

Schottky diodes (D

x

) are recommended as shown in Figure

16. These diodes should be able to absorb the maximum

anticipated current surges during clipping.

MC74HC4051A, MC74HC4052A, MC74HC4053A

www.onsemi.com

11

ANALOG

SIGNAL

Figure 15. Application Example Figure 16. External Germanium or

Schottky Clipping Diodes

a. Using Pull−Up Resistors b. Using HCT Interface

Figure 17. Interfacing LSTTL/NMOS to CMOS Inputs

ON

6

7

8

16

+5V

-5V

ANALOG

SIGNAL

+5V

-5V

+5V

-5V

11

10

9

TO EXTERNAL CMOS

CIRCUITRY 0 to 5V

DIGITAL SIGNALS

ON/OFF

7

8

16

V

CC

V

EE

V

EE

D

x

V

CC

D

x

V

EE

D

x

V

CC

D

x

ANALOG

SIGNAL

ON/OFF

6

7

8

16

+5V

V

EE

ANALOG

SIGNAL

+5V

V

EE

+5V

V

EE

11

10

9

R

*

R R

LSTTL/NMOS

CIRCUITRY

+5V

* 2K ≤ R ≤ 10K

ANALOG

SIGNAL

ON/OFF

6

7

8

16

+5V

V

EE

ANALOG

SIGNAL

+5V

V

EE

+5V

V

EE

11

10

9

LSTTL/NMOS

CIRCUITRY

+5V

HCT

BUFFER

Figure 18. Function Diagram, HC4051A

13

X0

14

X1

15

X2

12

X3

1

X4

5

X5

2

X6

4

X7

3

X

LEVEL

SHIFTER

LEVEL

SHIFTER

LEVEL

SHIFTER

LEVEL

SHIFTER

11

A

10

B

9

C

6

ENABLE

MC74HC4051A, MC74HC4052A, MC74HC4053A

www.onsemi.com

12

Figure 20. Function Diagram, HC4053A

Figure 19. Function Diagram, HC4052A

13

X1

12

X0

1

Y1

2

Y0

3

Z1

5

Z0

14

X

LEVEL

SHIFTER

LEVEL

SHIFTER

LEVEL

SHIFTER

LEVEL

SHIFTER

11

A

10

B

9

C

6

ENABLE

12

X0

14

X1

15

X2

11

X3

1

Y0

5

Y1

2

Y2

4

Y3

3

Y

LEVEL

SHIFTER

LEVEL

SHIFTER

LEVEL

SHIFTER

10

A

9

B

6

ENABLE

13

X

15

Y

4

Z

NLVHC4051ADTR2G

NLVHC4051ADTR2G

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