74LV4066PW_技术文档

INTEGRATED CIRCUITS

74LV4066

Quad bilateral switches

Product specification

1998 Jun 23

Supersedes data of 1996 Jan 01

IC24 Data Handbook

Philips

Semiconductors

Philips Semiconductors

Product specification

Quad bilateral switches

74LV4066

The 74LV4066 has four independent analog switches. Each switch

has two input/output terminals (nY, nZ) and an active HIGH enable

input (nE). When nE is LOW the corresponding analog switch is

turned off.

FEATURES

• Optimized for Low Voltage applications: 1.0V to 6.0V

• Accepts TTL input levels between V = 2.7 V and V = 3.6 V

CC

The 74LV4066 has an on resistance which is dramatically reduced

in comparison with 74HCT4066.

• Typical V

(output ground bounce) < 0.8 V at V = 3.3 V,

OLP

= 25 °C.

CC

T

amb

• Very low typ “ON” resistance:

25W at V – VEE = 4.5 V

FUNCTION TABLE

CC

INPUTS

SWITCH

nE

35W at V – VEE = 3.0 V

CC

60W at V – VEE = 2.0 V

CC

• Output capability: non-standard

L

off

on

• I category: SSI

CC

H

NOTES:

H

L

=

HIGH voltage level

LOW voltage level

DESCRIPTION

The 74LV4066 is a low-voltage Si-gate CMOS device that is pin and

function compatible with 74HC/HCT4066.

QUICK REFERENCE DATA

GND = 0 V; T

= 25°C; t =t v 2.5 ns

amb

r f

SYMBOL

PARAMETER

Turn “ON” time: nE to V

CONDITIONS

C = 15pF

TYPICAL

UNIT

t

/t

10

ns

L

PZH PZL

OS

R = 1K

W

L

/t

Turn “OFF” time: nE to V

Input capacitance

13

ns

V

= 3.3V

PHZ PLZ

OS

CC

C

3.5

11

8

pF

I

Power dissipation capacitance per switch

Maximum switch capacitances

Notes 1, 2

PD

S

NOTES:

1. C is used to determine the dynamic power dissipation (P in µW)

PD

D

2

P

= C × V

× f )ȍ (C × V

× f ) where:

D

PD

CC

i

L

CC o

f = input frequency in MHz; C = output load capacity in pF;

i

L

f = output frequency in MHz; C = maximum switch capacitance in pF;

o

s

2

ȍ {(C + C ) × V

× F } = sum of the outputs.

L

S

CC

o

V

CC

= supply voltage in V.

2. The condition is V = GND to V

I

CC.

ORDERING AND PACKAGE INFORMATION

PACKAGES

TYPE NUMBER

PINS

PACKAGE

DIL

MATERIAL

Plastic

CODE

74LV4066N

74LV4066D

74LV4066DB

74LV4066PW

16

SOT27-1

SOT108-1

SOT337-1

SOT402-1

SO

Plastic

SSOP

TSSOP

Plastic

PIN CONFIGURATION

PIN DESCRIPTION

1Y

1Z

1

2

3

4

5

6

7

14

V

CC

SYMBOL

NUMBER

FUNCTION

13 1E

12 4E

11 4Y

2Z

1, 4, 8, 11

2, 3, 9, 10

13, 5, 6, 12

7

1Y – 4Y Independent inputs/outputs

1Z – 4Z Independent inputs/outputs

1E to 4E Enable input (active HIGH)

2Y

10

9

2E

4Z

3Z

3E

GND

Ground (0V)

8

3Y

GND

14

V

CC

Positive supply voltage

SV01669

2

1998 Jun 23

853-2077 19619

Philips Semiconductors

Product specification

Quad bilateral switches

74LV4066

FUNCTIONAL DIAGRAM

IEC LOGIC SYMBOL

1

2

3

9

1

1Y

1E

2Y

2E

3Y

3E

4Y

4E

1Z

2Z

3Z

4Z

1

13

4

2

13#

2

3

1

X1

13#

4

1

3

4

5#

X1

5

5#

8

1

9

8

9

6#

X1

6#

6

10

11

10

1

11

12

10

1

12#

X1

(a)

(b)

SV01671

SV01670

SCHEMATIC DIAGRAM (ONE SWITCH)

nY

nE

V

CC

GND

nZ

SV01672

RECOMMENDED OPERATING CONDITIONS

SYMBOL

PARAMETER

CONDITIONS

MIN

1.0

0

TYP

3.3

–

MAX

UNIT

V

CC

DC supply voltage

See Note 1

6

V

I

Input voltage

V

CC

V

CC

V

O

Output voltage

0

–

See DC and AC

characteristics

–40

+85

+125

T

Operating ambient temperature range in free air

Input rise and fall times

°C

amb

V

= 1.0V to 2.0V

= 2.0V to 2.7V

= 2.7V to 3.6V

= 3.6V to 5.5V

–

500

200

100

50

CC

t , t

r

ns/V

f

NOTE:

1. The LV is guaranteed to function down to V = 1.0V (input levels GND or V ); DC characteristics are guaranteed from V = 1.2V to V = 5.5V.

CC

1, 2

ABSOLUTE MAXIMUM RATINGS

In accordance with the Absolute Maximum Rating System (IEC 134).

Voltages are referenced to GND (ground = 0 V).

SYMBOL

PARAMETER

DC supply voltage

CONDITIONS

RATING

–0.5 to +7.0

20

UNIT

V

CC

V

"I

DC input diode current

DC output diode current

DC switch current

V < –0.5 or V > V + 0.5V

mA

°C

IK

I

CC

"I

V

O

< –0.5 or V > V + 0.5V

50

OK

O

CC

"I

–0.5V < V < V + 0.5V

25

O

CC

T

stg

Storage temperature range

–65 to +150

Power dissipation per package

– plastic DIL

– plastic mini-pack (SO)

for temperature range: –40 to +125°C

above +70°C derate linearly with 12 mW/K

above +70°C derate linearly with 8 mW/K

above +60°C derate linearly with 5.5 mW/K

750

500

400

P

TOT

mW

– plastic shrink mini-pack (SSOP and TSSOP)

NOTES:

1. Stresses beyond those listed may cause permanent damage to the device. These are stress ratings only and functional operation of the

device at these or any other conditions beyond those indicated under “recommended operating conditions” is not implied. Exposure to

absolute-maximum-rated conditions for extended periods may affect device reliability.

2. The input and output voltage ratings may be exceeded if the input and output current ratings are observed.

3

1998 Jun 23

Philips Semiconductors

Product specification

Quad bilateral switches

74LV4066

DC ELECTRICAL CHARACTERISTICS

Over recommended operating conditions. Voltages are referenced to GND (ground = 0 V).

LIMITS

MAX

-40°C to +85°C

-40°C to +125°C

SYMBOL

PARAMETER

TEST CONDITIONS

= 1.2 V

UNIT

1

MIN

0.90

1.40

2.00

3.15

4.20

TYP

MIN

0.90

1.4

MAX

V

CC

V

CC

V

CC

V

CC

V

CC

V

CC

V

CC

V

CC

V

CC

V

CC

= 2.0 V

HIGH level Input

voltage

= 2.7 to 3.6 V

= 4.5 V

2.0

V

IH

V

3.15

4.20

= 6.0 V

= 1.2 V

0.30

0.60

0.80

1.35

1.80

0.30

0.60

0.80

1.35

1.80

= 2.0 V

LOW level Input

voltage

= 2.7 to 3.6 V

= 4.5 V

V

IL

V

= 6.0 V

Input leakage

current

V

= 3.6 V; V = V or GND

1.0

2.0

1.0

2.0

CC

I

CC

±I

µA

I

= 6.0 V; V = V or GND

I

CC

Analog switch

OFF-state current

per channel

V

CC

V

CC

= 3.6 V; V = V or V

1.0

2.0

1.0

2.0

I

IH

IL

±I

S

= 6.0 V; V = V or V

I

IH

Analog switch

ON-state current

per channel

V

CC

V

CC

= 3.6 V; V = V or V

1.0

2.0

1.0

2.0

I

IH

IL

µA

S

= 6.0 V; V = V or V

I

IH

Quiescent supply

current

V

CC

V

CC

= 3.6V; V = V or GND; I = 0

20

40

80

I

CC

O

I

CC

= 6.0V; V = V or GND; I = 0

I

CC

Additional

quiescent supply

current per input

∆I

CC

V

CC

= 2.7 V to 3.6 V; V = V – 0.6 V

500

850

I

CC

V

= 1.2 V; V = V or V

300

60

41

37

25

23

–

130

60

72

52

47

–

150

90

83

60

54

CC

I

IH

IL

= 2.0 V; V = V or V

I

IH

ON-resistance

(peak)

= 2.7 V; V = V or V

I IH

R

Ω

ON

= 3.0 to 3.6 V; V = V or V

I

IH

IL

= 4.5 V; V = V or V

I

IH

IL

= 6.0 V; V = V or V

I

IH

V

CC

V

CC

V

CC

V

CC

V

CC

V

CC

= 1.2 V; V = V or V

75

35

26

24

15

13

–

I

IH

IL

= 2.0 V; V = V or V

98

60

52

40

35

115

68

60

45

40

I

IH

ON-resistance

(rail)

= 2.7 V; V = V or V

I IH

ON

= 3.0 to 3.6 V; V = V or V

I

IH

= 4.5 V; V = V or V

I

IH

IL

= 6.0 V; V = V or V

I

IH

V

CC

V

CC

V

CC

V

CC

V

CC

V

CC

= 1.2 V; V = V or V

75

40

35

30

22

20

–

130

85

75

55

47

I

IH

IL

= 2.0 V; V = V or V

110

72

65

47

40

I

IH

ON-resistance

(rail)

= 2.7 V; V = V or V

I IH

= 3.0 to 3.6 V; V = V or V

I

IH

= 4.5 V; V = V or V

I

IH

IL

= 6.0 V; V = V or V

I

IH

V

CC

V

CC

V

CC

V

CC

V

CC

V

CC

= 1.2 V; V = V or V

–

5

4

3

2

I

IH

IL

Maximum variation

of ON-resistance

between any two

channels

= 2.0 V; V = V or V

I

IH

= 2.7 V; V = V or V

I

IH

∆R

ON

= 3.0 to 3.6 V; V = V or V

I

IH

= 4.5 V; V = V or V

I

IH

IL

= 6.0 V; V = V or V

I

IH

NOTE:

1. All typical values are measured at T

= 25°C.

amb

2. At supply voltage approaching 1.2V, the analog switch ON-resistance becomes extremely non-linear. Therefore it is recommended that

these devices be used to transmit digital signals only, when using these supply voltages.

4

1998 Jun 23

Philips Semiconductors

Product specification

Quad bilateral switches

74LV4066

LOW

(from enable inputs)

HIGH

(from enable inputs)

V

nY

nZ

A

nZ

nY

A

I

V

is

= 0 to V – GND

CC

is

V = V or GND

V

= GND or V

GND

I

CC

O

CC

GND

SV01673

SV01674

Figure 1. Test circuit for measuring ON-resistance (R

Figure 2. Test circuit for measuring OFF-state current.

on).

HIGH

V

= 2.0 V

CC

60

(from enable inputs)

R

(W)

ON

40

nY

nZ

V

= 3.0 V

= 4.5 V

CC

A

20

0

V

CC

V = V

I

or GND

V

O

(open circuit)

GND

CC

0

1.2

2.4

3.6

(V)

4.8

V

is

SV01675

SV01676

Figure 3. Test circuit for measuring ON-state current.

Figure 4. Typical ON-resistance (R ) as a function of input

ON

voltage (V ) for V = 0 to V – V .

EE

is

CC

AC CHARACTERISTICS

GND = 0 V; t = t ≤ 2.5ns; C = 50pF

r

f

L

LIMITS

–40 to +85 °C

CONDITION

OTHER

–40 to +125 °C

SYMBOL

PARAMETER

UNIT

1

MIN

TYP

8

MAX

MIN

MAX

V

(V)

CC

1.2

2.0

5

26

15

13

10

31

18

15

12

R = ∞;

L

Propagation delay

to V

2

C = 50 pF

t

/t

ns

3

2.7 to 3.6

4.5

L

PHL PLH

V

is

os

Figure 12

2

6.0

40

22

1.2

43

25

21

16

51

30

26

20

2.0

R = 1 kW;

L

Turn-on time

nE to V

2

C = 50 pF

t

/t

12

10

8

ns

2.7 to 3.6

4.5

L

PZH PZL

os

Figures 13 and 14

6.0

50

27

15

13

12

1.2

65

38

32

28

81

47

40

34

2.0

R = 1 kW;

L

Turn-off time

nE to V

2

C = 50 pF

/t

2.7 to 3.6

4.5

L

PHZ PLZ

os

Figures 13 and 14

6.0

NOTES:

1. All typical values are measured at T

= 25°C.

amb

2. All typical values are measured at V = 3.3V.

CC

5

1998 Jun 23

Philips Semiconductors

Product specification

Quad bilateral switches

74LV4066

ADDITIONAL AC CHARACTERISTICS

GND = 0 V; t = t ≤ 2.5ns; C = 50pF

r

f

L

V

IS(P–P)

(V)

CC

SYMBOL

PARAMETER

TYP

UNIT

%

CONDITIONS

(V)

3.0

6.0

3.0

6.0

3.0

6.0

3.0

6.0

0.04

0.02

0.12

0.06

–50

–60

2.75

5.50

2.75

5.50

R = 10 kW; C = 50 pF

L

Sine-wave distortion f = 1 kHz

Sine-wave distortion f = 10 kHz

Switch “OFF” signal feed through

Crosstalk between any two switches

Figure 15

R = 10 kW; C = 50 pF

L

%

Figure 15

Note 1

R = 600 kW; C = 50 pF; f=1 MHz

L

dB

Figures 10 and 16

Note 1

R = 600 kW; C = 50 pF; f=1 MHz

L

Figure 12

R = 600 kW; C = 50 pF; f=1 MHz

110

220

3.0

6.0

L

Crosstalk voltage between enable or address

input to any switch (peak-to-peak value)

(nE, square wave between V and

V

(p–p)

mV

CC

GND, T = t = 6 ns) Figure 13

r

f

180

200

8

3.0

6.0

Note 2

R = 50 kW; C = 50 pF

Figures 11 and 14

L

f

Minimum frequency response (–3 dB)

Maximum switch capacitance

mHz

pF

max

C

S

GENERAL NOTES:

V

os

is the input voltage at nY or nZ terminal, whichever is assigned as an input.

is the output voltage at nY or nZ terminal, whichever is assigned as an output.

is

NOTES:

1. Adjust input voltage V is 0 dBm level (0 dBm = 1 mW into 600 W).

is

2. Adjust input voltage V is 0 dBm level at V for 1 MHz (0 dBm = 1 mW into 50 W).

is

os

5

0

(dB)

0

–50

–5

–100

2

3

4

5

6

10

SV01678

2

3

4

5

6

10

SV01677

10

f (kHz)

Figure 5. Typical switch “OFF” signal feed-through as a

function of frequency.

Figure 6. Typical frequency response.

NOTES TO FIGURES 5 AND 6:

Test conditions: V = 3.0 V; GND = 0 V; R = 50 W; R = 1kW.

CC

L

SOURCE

V

CC

2R

L

0.1 mF

R

L

nY/nZ

nZ/nY

nY/nZ

nZ/nY

V

is

V

os

2R

C

R

2R

C

L

dB

L

channel

ON

channel

OFF

GND

(a)

(b)

SV01679

Figure 7. Test circuit for measuring crosstalk between any two switches.

(a) channel ON condition; (b) channel OFF condition.

6

1998 Jun 23

Philips Semiconductors

Product specification

Quad bilateral switches

74LV4066

V

CC

V

nE

V

CC

V

CC

GND

2R

L

0.1 mF

2R

L

nY/nZ

nZ/nY

Vos

V

is

nY/nZ

nZ/nY

DUT

sine–wave

2R

C

dB

L

channel

ON

2R

C

L

oscilloscope

L

GND

SV01681

SV01682

Figure 8. Test circuit for measuring

crosstalk between control and any switch.

Figure 9. Test circuit for measuring

minimum frequency response.

NOTE TO FIGURE 8:

The crosstalk is defined as follows (oscilloscope output):

NOTE TO FIGURE 9:

Adjust input voltage to obtain 0 dBm at V when F = 1 MHz. After

OS

in

set-up frequency of f is increased to obtain a reading of –3 dB at V

in

OS.

V

(p–p)

SV01680

V

CC

V

CC

2R

L

2R

L

0.1 mF

10 mF

nY/nZ

nZ/nY

nY/nZ

nZ/nY

V

os

V

is

V

is

V

os

f

in

= 1 kHz

sine–wave

distortion

meter

2R

C

L

dB

2R

C

L

channel

ON

L

channel

OFF

GND

SV01684

SV01683

Figure 10. Test circuit for measuring sine-wave distortion.

Figure 11. Test circuit for measuring

switch “OFF” signal feed-through.

7

1998 Jun 23

Philips Semiconductors

Product specification

Quad bilateral switches

74LV4066

WAVEFORMS

V

= 1.5 V at V ≥ 2.7 V

M

CC

= 0.5 × V at V ≤ 2.7 V

M

CC

and V are the typical output voltage drop that occur with the

OL

OH

output load

V

X

V

X

V

Y

V

Y

= V + 0.3 V at V ≥ 2.7 V

OL CC

= V + 0.1 × V at V < 2.7 V

OL

CC

= V – 0.3 V at V ≥ 2.7 V

OH

CC

= V – 0.1 × V

V

< 2.7 V

OH

CC CC

V

I

V

I

V

nE INPUT

GND

V

M

V

M

is

GND

t

PZL

PLZ

t

PHL

V

PLH

CC

OUTPUT

LOW-to-OFF

OFF-to-LOW

V

OH

V

M

V

X

V

M

os

V

OL

t

PZH

t

PHZ

V

OL

SV01685

V

OH

V

Y

Figure 12. Input (V ) to output (V ) propagation delays.

OUTPUT

HIGH-to-OFF

OFF-to-HIGH

is

os

V

M

GND

outputs

enabled

outputs

disabled

outputs

enabled

SV01686

Figure 13. Turn-on and turn-off times

for the inputs (nS, E) to the output (V ).

os

TEST CIRCUIT

t

W

V

I

90%

NEGATIVE

S

90%

1

V

cc

V

S1

V

M

Open

GND

PULSE

10%

90%

0V

(t )

R

= 1k

L

V

O

t

(t )

t

TLH

l

THL

TLH

f

r

PULSE

GENERATOR

D.U.T.

(t )

r

t

(t )

THL f

V

= 1k

R

T

I

90%

M

C = 50pF

L

POSITIVE

PULSE

V

M

10%

t

W

0V

Test Circuit for Outputs

V

M

= 1.5V

Input Pulse Definition

DEFINITIONS

SWITCH POSITION

R = Load resistor

L

TEST

S

1

V

CC

V

I

V

S1

C = Load capacitance includes jig and probe capacitance

L

t

Open

< 2.7V

2.7–3.6V

≥ 4.5 V

V

2 < V

PLH/ PHL

CC

R = Termination resistance should be equal to Z

T

of

OUT

t

V

S1

2.7V

PLZ/ PZL

pulse generators.

t

/t

GND

V

CC

PHZ PZH

SY00044

Figure 14. Load circuitry for switching times.

8

1998 Jun 23

Philips Semiconductors

Product specification

Quad bilateral switches

74LV4066

DEFINITIONS

Data Sheet Identification

Product Status

Definition

This data sheet contains the design target or goal specifications for product development. Specifications

may change in any manner without notice.

Objective Specification

Formative or in Design

Preproduction Product

Full Production

This data sheet contains preliminary data, and supplementary data will be published at a later date. Philips

Semiconductors reserves the right to make changes at any time without notice in order to improve design

and supply the best possible product.

Preliminary Specification

Product Specification

This data sheet contains Final Specifications. Philips Semiconductors reserves the right to make changes

at any time without notice, in order to improve design and supply the best possible product.

Philips Semiconductors and Philips Electronics North America Corporation reserve the right to make changes, without notice, in the products,

including circuits, standard cells, and/or software, described or contained herein in order to improve design and/or performance. Philips

Semiconductors assumes no responsibility or liability for the use of any of these products, conveys no license or title under any patent, copyright,

or mask work right to these products, and makes no representations or warranties that these products are free from patent, copyright, or mask

work right infringement, unless otherwise specified. Applications that are described herein for any of these products are for illustrative purposes

only. PhilipsSemiconductorsmakesnorepresentationorwarrantythatsuchapplicationswillbesuitableforthespecifiedusewithoutfurthertesting

or modification.

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Philips Semiconductors and Philips Electronics North America Corporation Products are not designed for use in life support appliances, devices,

orsystemswheremalfunctionofaPhilipsSemiconductorsandPhilipsElectronicsNorthAmericaCorporationProductcanreasonablybeexpected

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P.O. Box 3409

Sunnyvale, California 94088–3409

Telephone 800-234-7381

Philips Semiconductors and Philips Electronics North America Corporation

register eligible circuits under the Semiconductor Chip Protection Act.

Copyright Philips Electronics North America Corporation 1998

print code

Date of release: 05-96

Document order number:

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