UPD22148CA-A_技术文档

DATA SHEET

MOS INTEGRATED CIRCUIT

µPD22100, 22148

CROSSPOINT SWITCH WITH CONTROL MEMORY

CMOS IC

The µPD22100 consists of 16 crosspoint switches organized in 4 rows and 4 columns, and the µPD22148 consists

of 32 crosspoint switches organized in 4 row and 8 columns. Any of the 16 or 32 switches can be selected by applying

appropriate address. The selected crosspoint turns on if during strobe and data In are high and turns off if during

strobe and data In are low.

FEATURES

µPD22100

µPD22148

4 × 4 CROSSPOINT SWITCHES

4 × 8 CROSSPOINT SWITCHES

•

INTERNAL POWER ON RESET FUNCTION

Low ON-RESISTANCE

Including the Level Shifter Circuit

Low ON-RESISTANCE

60 Ω Typ. (V^DD= 15 V)

60 Ω Typ. (VDD = 15 V)

Wide operating temperature Range

−40 °C to +85 °C

Wide operating temperature Range

−40 °C to +85 °C

•

ORDERING INFORMATION

Part Number

µPD22100C

µPD22100GS

µPD22148CA

Package

16 pin plastic DIP (300 mil)

16 pin plastic SOP (300 mil)

22 pin plastic shrink DIP (300 mil)

TRUTH TABLE

µPD22100

INPUT

SELECTED CHANNELS

Y

0

Y

0

Y

0

Y

0

Y

1

Y

1

Y

1

Y

1

Y

2

Y

2

Y

2

Y

2

Y

3

Y

3

Y

3

Y

3

S

D

C

B

A

DATA

X

0

X

1

X

2

X

3

X

0

X

1

X

2

X

3

X

0

X

1

X

2

X

3

X

0

X

1

X

2

X

3

L

X

L

X

L

X

L

X

L

X

L

NC

H

OFF NC

ON NC

L

H

L

H

L

NC OFF NC

NC ON NC

L

H

L

H

NC

OFF NC

ON NC

L

H

L

H

OFF NC

ON NC

H

L

NC

OFF

ON

H

Document No. IC-2128 (1st edition)

Date Published March 1997 P

Printed in Japan

1987

©

µPD22100, 22148

µPD22148

INPUTS

SELECTED CHANNELS

Y

X

0

Y

X

0

1

Y

X

0

2

Y

X

0

3

Y

X

1

0

Y

X

1

Y

X

1

2

Y

X

1

3

Y

X

2

0

Y

X

2

1

Y

X

2

Y

X

2

3

Y

X

3

0

Y

X

3

1

Y

X

3

2

Y

X

3

Y

X

4

0

Y

X

4

1

Y

X

4

2

Y

X

4

3

Y

X

5

0

Y

X

5

1

Y

X

5

2

Y

X

5

3

Y

X

6

0

Y

X

6

1

Y

X

6

2

Y

X

6

3

Y

X

7

0

Y

X

7

1

Y

X

7

2

Y

X

7

3

S E D C B A DATA

L

X X X X X

X

L

NC

H

L

OFF NC

ON NC

H

L

H

L

NC OFF NC

NC ON NC

L

H

L

OFF

L

H

NC

OFF

ON

L

H

L

H H

NC

L

H

L

H

L

OFF NC

ON NC

H

L

H

L

OFF NC

ON NC

H

L

H H

OFF NC

ON NC

L

H

H H H H H H

L

NC

OFF

ON

H

TIMING DIAGRAM

STROBE

DATA IN

ADDRESS

SWITCH 1

SWITCH 2

DON'T CARE

ADDRESS 1

DON'T CARE

ADDRESS 2

DON'T CARE

ON

OFF

ON

OFF

2

µPD22100, 22148

BLOCK DIAGRAM

µPD22100

STROBE DATA IN

Y

0

1

2

0

4

1

5

2

6

3

7

A

B

A

D

R

E

S

8

9

10

14

11

15

C

D

Y3

12

13

NOTE)

n

: Analog switch

X

0

X

1

X

2

X

3

µPD22148

STROBE DATA IN

Y

0

1

2

3

4

5

6

7

0

1

2

3

A

4

5

6

7

8

9

10

14

18

22

26

30

11

15

19

23

27

31

B

C

D

E

A

D

R

E

S

12

16

20

24

28

13

17

21

25

29

NOTE)

n

: Analog switch

X

0

X1

X

2

X3

3

µPD22100, 22148

CONNECTION DIAGRAM (TOP VIEW)

µPD22100

µPD22148

Y

3

1

22

21

20

19

18

17

16

15

14

13

12

V

Y

X

Y

X

DD

0

X

1

2

3

4

5

6

7

8

16

15

14

13

12

11

10

9

V

Y

X

Y

X

DD

X

2

DATA IN

0

V

CC

3

1

C

1

DATA IN

4

2

D

3

C

5

3

B

A

2

D

6

2

3

E

7

5

B

A

8

7

STROBE

2

9

6

VSS

0

STROBE

10

11

4

V

SS

0

4

µPD22100, 22148

µPD22100

ABSOLUTE MAXIMUM RATINGS (Ta = 25 °C, VSS = 0 V)

DC Supply Voltage

Input Voltage

VDD

V^I

−0.5 to +20

−0.5 to VDD + 0.5

10

V

Input Current

I^I

mA

mW

°C

Power Dissipation

Operating Temperature

Storage Temperature

P^D

T^opt

T^stg

200

−40 to +85

−65 to +125

°C

RECOMMENDED OPERATING CONDITIONS (Ta = −40 to +85 °C)

CHARACTERISTIC

Operating Voltage

SYMBOL

VDD

MIN.

TYP.

MAX.

18

UNIT

CONDITIONS

3

0.7 VDD

0

V

Input Voltage (Control)

Analog Input Voltage

VIH

VDD

VIL

0.3 VDD

VDD

VIA

VSS

Vxn − Vyn ≤ 0.5 V

ELECTRICAL CHARACTERISTICS

Ta = −40 °C

Ta = 25 °C

Ta = +85 °C

CHARACTERISTIC SYMBOL

UNIT

CONDITIONS

MIN.

MAX.

530

100

75

MIN.

TYP.

160

80

MAX.

650

120

90

MIN.

MAX.

820

150

120

110

VDD (V)

5

On-State

Resistance

10

VDD − VSS

R^ON

Ω

V^IS=

2

70

12

70

60

85

15

On-State

35

5

Resistance Dif-

ference Between

Any Two Switches

Input Leakage

Current

20

10

VDD − VSS

∆R^ON

Ω

V^IS=

2

18

12

15

IL

±300

±1

±300

±10000

nA

V

18

All Switches OFF

Input Voltage

3.5

7

3.5

7

3.5

7

5

Switch ON

VIH

10

15

5

RON < RON MAX.

11

Input Voltage

1.5

3

1.5

3

1.5

3

Switch OFF

VIL

II

V

10

15

18

5

IL < 0.2 µA

4

Input Current

Quiescent

Current

±0.3

5

±10⁻⁵

0.04

0.08

±0.3

5

±1

µA

VI = VSS, VDD

150

300

600

3000

10

20

100

10

20

100

10

15

20

IDD

µA

5

µPD22100, 22148

SWITCHING TIME CHARACTERISTICS (Ta = 25 °C)

CHARACTERISTIC

SYMBOL MIN. TYP. MAX.

UNIT

ns

VDD(V)

5

CONDITIONS

30

15

60

Signal INPUT → Signal OUTPUT

tPLH

tPHL

30

10

15

5

RL = 10 kΩ, CL = 50 pF. tr = tf = 20 ns

10

20

300

125

80

600

250

160

420

220

150

700

270

180

330

170

140

420

220

150

870

420

320

190

50

Strobe INPUT

RL = 1 kΩ

tPZH

tPZL

tPHZ

tPZL

tPHZ

tset up

thold

ns

10

15

5

→ OUTPUT

CL = 50 pF

tr, tf = 20 ns

210

110

100

350

135

90

Data INPUT

10

15

5

→ OUTPUT

Address INPUT

Propagation Delay

Time

ns

10

15

5

→ OUTPUT

165

85

Strobe INPUT

ns

10

15

5

→ OUTPUT

70

210

110

100

435

210

160

95

Data INPUT

ns

10

15

5

→ OUTPUT

Address INPUT

ns

10

15

5

→ OUTPUT

Set Up Time

Hold Time

Frequency

Data INPUT

25

ns

10

15

5

Strobe

→

15

30

Address

180

110

60

360

220

120

Data INPUT

ns

10

15

5

Strobe INPUT

→

Address INPUT

0.6

1.6

2.5

1.2

3.2

5

RL = 1 kΩ, CL = 50 pF

fφmax.

MHz

ns

10

15

5

tr, tf = 20 ns

Strobe Pulse

Width

300

120

90

600

240

190

PW

10

15

(

STROBE)

Crosstalk Voltage

mV

(peak)

pF

RL = 10 kΩ

75

10

tr = tf = 20 ns Rectronglar

INPUT Capacitance

5

7.5

Data, Strobe, Address INPUT

CIN

30

pF

Signal

INPUT

Xn

Yn

Feedthrough

Capacitance

Frequency

C^IN/OUT

0.4

pF

RL = 1 kΩ, VIS = 5 V(p-p)

Response

−

40

MHz

10

VOS

VIS

20 log

= −3 dB

(Switch ON)

Feedthrough

Attenuation

RL = 1 kΩ, f = 1.6 kHz, VIS = 5 V(p-p)

−

−80

0.5

1.5

dB

%

10

Sine Wave Input

(Switch Off)

Sine Wave

RL = 1 kΩ, VIS = 5 V(p-p)

Distortion

f = 1 kHz

Crosstalk Between

Any Two Switches

RL = 1 kΩ

VO (B)

VI (A)

MHz

SW(A) = ON

SW(B) = OFF

20 log

= −40 dB

6

µPD22100, 22148

µPD22148

ABSOLUTE MAXIMUM RATINGS (Ta = 25 °C, VSS = 0 V)

DC Supply Voltage 1

DC Supply Voltage 2

Input Voltage

VDD

V^CC

V^I

VCC to +20

−0.5 to +6

−0.5 to VCC + 0.5

−0.5 to VDD + 0.5

±10

V

Input Voltage (Analog)

Input Current

V^IA

I^I

V

mA

mW

°C

Power Dissipation

Operating Temperature

Storage Temperature

P^D

T^opt

T^stg

200

−40 to +85

−65 to +125

RECOMMENDED OPERATING CONDITIONS (Ta = −40 to +85 °C)

CHARACTERISTIC

Operating Voltage 1

Operating Voltage 2

Input Voltage (Control)

Analog Input Voltage

SYMBOL

VDD

MIN.

VCC

TYP.

5

MAX.

18

UNIT

CONDITIONS

V

VCC

4.5

5.5

VIH

0.7 VCC

0

VCC

VIL

0.3 VCC

VDD

V^IA

VSS

Vxn − Vyn ≤ 0.5 V

ELECTRICAL CHARACTERISTICS

T^a= −40 °C

Ta = 25 °C

Ta = +85 °C

CHARACTERISTIC SYMBOL

UNIT

CONDITIONS

MIN.

MAX.

530

100

75

MIN.

TYP.

160

80

MAX.

650

120

90

MIN.

MAX.

820

150

120

110

VDD (V)

5

On-State

Resistance

10

VDD − VSS

RON

Ω

VIS =

2

70

12

70

60

85

15

On-State

35

5

Resistance Dif-

ference Between

Any Two Switches

Input Leakage

Current

20

10

VDD − VSS

∆RON

Ω

VIS =

2

18

12

15

IL

±300

±1

±300

±10000

nA

18

All Switches OFF

Input Voltage

VCC = 5 V

VIH

VIL

II

3.5

V

−

VDD > 10 V

Input Voltage

Input Current

VCC = 5 V

1.5

VDD > 10 V

VCC = 6 V

±0.3

±10⁻⁵

±0.3

±1

µA

VI = VSS, VCC

Quiescent

Current

10

20

40

0.08

0.16

10

20

40

300

600

5

IDD

µA

10

15

VI = VSS, VDD

1200

7

µPD22100, 22148

SWITCHING TIME CHARACTERISTICS (Ta = 25 °C)

CHARACTERISTIC

SYMBOL MIN. TYP. MAX.

UNIT

ns

VDD(V)

5

CONDITIONS

30

15

60

30

Signal INPUT → Signal OUTPUT

tPLH

tPHL

10

15

5

RL = 10 kΩ, CL = 50 pF. tr = tf = 20 ns

10

20

400

225

180

310

220

200

450

235

190

265

185

170

310

210

200

535

310

260

140

70

800

450

360

620

440

400

900

470

380

530

370

340

620

420

400

1070

720

520

280

140

120

540

360

220

Strobe INPUT

RL = 1 kΩ

CL = 50 pF

tr, tf = 20 ns

tPZH

tPHZ

tP

ns

10

15

5

→ OUTPUT

Data INPUT

10

15

5

→ OUTPUT

Address INPUT

Propagation Delay

Time

ns

10

15

5

→ OUTPUT

Strobe INPUT

ns

10

15

5

→ OUTPUT

Data INPUT

ns

10

15

5

→ OUTPUT

Address INPUT

tPHZ

tset up

thold

ns

10

15

5

→ OUTPUT

Set Up Time

Hold Time

Frequency

Data INPUT

ns

10

15

5

Strobe

→

60

Address

270

180

110

1.2

3.2

5

Data INPUT

ns

10

15

5

Strobe INPUT

→

Address INPUT

0.6

1.6

2.5

RL = 1 kΩ, CL = 50 pF

fφmax.

MHz

ns

10

15

5

tr, tf = 20 ns

Strobe Pulse

Width

300

120

90

600

240

190

PW

10

15

(

STROBE)

Crosstalk Voltage

mV

(peak)

pF

RL = 10 kΩ

75

10

tr = tf = 20 ns Rectronglar

INPUT Capacitance

5

7.5

Data, Strobe, Address INPUT

CIN

105

75

pF

Signal

INPUT

Xn

Yn

Feedthrough

Capacitance

Frequency

C^IN/OUT

1.1

pF

RL = 1 kΩ, VIS = 5 V(p-p)

Response

−

15

MHz

10

VOS

VIS

20 log

= −3 dB

(Switch ON)

Feedthrough

Attenuation

RL = 1 kΩ, f = 1.6 kHz, VIS = 5 V(p-p)

−

−60

0.5

1.5

dB

%

10

Sine Wave Input

(Switch Off)

Sine Wave

RL = 1 kΩ, VIS = 5 V(p-p)

Distortion

f = 1 kHz

Crosstalk Between

Any Two Switches

RL = 1 kΩ

VO (B)

V^I(A)

20 log

= −40 dB

MHz

SW(A) = ON

SW(B) = OFF VCC = 5 V

8

µPD22100, 22148

TEST CIRCUITS

PROPAGATION DELAY TIMES

(1) SIGNAL INPUT → SIGNAL OUTPUT

ON

V

DD

50 %

V

IS

SW

V

OS

V

IS

V

SS

t

PLH

R

L

CL

t

PHL

OH

50 %

VOS

V

OL

(2) STROBE INPUT → OUTPUT

VDD

VSS

VDD

VSS

VOH

VOL

STROBE

DATA IN

STROBE

50 %

t

setup

t

hold

VDD

50 %

VIS

SW

V

OS

t

PHZ

t

PZH

R

L

C

L

V

OS

90 %

10 %

(3) DATA INPUT → OUTPUT (STROBE = V^DD)

VDD

DATA IN

V

DD

VDD

R

L

V

DD

DATA IN

50 %

DATA IN

50 %

t

VIS

SW

V

OS

SW

V

OS

VSS

V

SS

PZL

t

PZH

RL

CL

V

OH

VOH

90 %

VOS

V

OS

10 %

VOL

V

OL

9

µPD22100, 22148

(4) ADDRESS INPUT → OUTPUT (STROBE = VDD)

V

DD

ADDRESS = L

ADDRESS = H

ADDRESS

50 %

VDD

V

SS

t

setup

t

hold

SW

VOS1

SW

V

OS2

V

DD

DATA IN

50 %

RL

CL

RL

CL

VSS

t

PZH

V

OH

90 %

V

OS1

V

OL

t

PHZ

V

OH

OS2

10 %

VOL

CROSSTALK VOLTAGE

CONTROL INPUT (DATA IN, ADDRESS, STROBE)

VDD

CONTROL

VSS

VIS

SW

VOS

1 kΩ

RL

0 V

CROSSTALK VOLTAGE

CROSSTALK FREQUENCY

ON

OFF

V^OS

SW

(A)

SW

(B)

20 log

= −40 dB

V^IS

V^OS

VIS

1 kΩ

1 kΩ 1 kΩ

1 kΩ

10

µPD22100, 22148

TYPICAL CHARACTERISTICS (Ta = 25 °C)

(A) RON − VIS Characteristics

200

100

V

DD = −VSS = 2.5 V

V

DD = −VSS = 5 V

V

DD = −VSS = 6 V

V

DD = −VSS = 7.5 V

−7.5

−5

−2.5

0

2.5

5

7.5

INPUT VOLTAGE VIS (V)

(B) Crosstalk Frequency Characteristics

−40

−50

−60

−70

−80

−90

−100

1 k

10 k

100 k

1 M

Crosstalk Frequency (Hz)

11

µPD22100, 22148

APPLICATION CIRCUITS

µPD22100

A

B

C

D

A

B

C

D

µ

PD22100C

Y

n

Y

n

STROBE

DATA IN

STROBE

DATA IN

V

DD

1/4µ PD4081BC

R

C

τ = RC > 50 ms

(For Power ON Reset Time)

Xn

µPD22100/22148 BIAS CIRCUIT

V

DD

V

DD

V

CC* = 5 V

V

DD

R

R = 10 kΩ to 100 kΩ

X

n

X

n

Y

n

Y

n

V

SS

V

SS

*

µ

PD22148 only

V

SS

12

µPD22100, 22148

16PIN PLASTIC DIP (300 mil)

16

9

1

8

A

K

L

P

I

J

H

G

C

F

R

M

B

N

D

NOTES

ITEM MILLIMETERS

INCHES

1) Each lead centerline is located within 0.25 mm (0.01 inch) of

its true position (T.P.) at maximum material condition.

A

B

C

20.32 MAX.

1.27 MAX.

2.54 (T.P.)

0.800 MAX.

0.050 MAX.

0.100 (T.P.)

2) Item "K" to center of leads when formed parallel.

+0.004

0.020

D

0.50±0.10

–0.005

F

G

H

I

1.2 MIN.

3.5±0.3

0.047 MIN.

0.138±0.012

0.020 MIN.

0.170 MAX.

0.200 MAX.

0.300 (T.P.)

0.252

0.51 MIN.

4.31 MAX.

5.08 MAX.

7.62 (T.P.)

6.4

J

K

L

+0.10

0.25

+0.004

0.010

M

–0.05

–0.003

N

P

R

0.25

0.01

1.0 MIN.

0~15°

0.039 MIN.

0~15°

P16C-100-300A,C-1

13

µPD22100, 22148

16 PIN PLASTIC SOP (300 mil)

16

9

detail of lead end

1

8

A

H

I

J

L

B

C

N

M

D

NOTE

ITEM MILLIMETERS

INCHES

Each lead centerline is located within 0.12 mm (0.005 inch) of

its true position (T.P.) at maximum material condition.

A

B

C

10.46 MAX.

0.78 MAX.

1.27 (T.P.)

0.412 MAX.

0.031 MAX.

0.050 (T.P.)

+0.10

0.40

+0.004

0.016

D

–0.05

–0.003

E

F

G

H

I

0.1±0.1

1.8 MAX.

1.55

0.004±0.004

0.071 MAX.

0.061

7.7±0.3

5.6

0.303±0.012

0.220

J

1.1

0.043

+0.004

0.008

+0.10

0.20

K

L

–0.002

–0.05

+0.008

0.024

0.6±0.2

–0.009

M

N

0.12

0.10

0.005

0.004

+7°

3°

+7°

3°

P

–3°

P16GM-50-300B-4

14

µPD22100, 22148

22 PIN PLASTIC SHRINK DIP (300 mil)

22

12

1

11

K

L

A

F

M

R

C

B

M

N

D

NOTES

ITEM MILLIMETERS

INCHES

0.911 MAX.

0.106 MAX.

0.070 (T.P.)

1) Each lead centerline is located within 0.17 mm (0.007 inch) of

its true position (T.P.) at maximum material condition.

A

B

C

23.12 MAX.

2.67 MAX.

1.778 (T.P.)

2) Item "K" to center of leads when formed parallel.

+0.004

0.020

D

0.50±0.10

–0.005

F

G

H

I

0.85 MIN.

3.2±0.3

0.033 MIN.

0.126±0.012

0.020 MIN.

0.170 MAX.

0.200 MAX.

0.300 (T.P.)

0.256

0.51 MIN.

4.31 MAX.

5.08 MAX.

7.62 (T.P.)

6.5

J

K

L

+0.004

0.010

+0.10

0.25

M

–0.003

–0.05

N

R

0.17

0.007

0~15°

S22C-70-300B-1

15

µPD22100, 22148

No part of this document may be copied or reproduced in any form or by any means without the prior written

consent of NEC Corporation. NEC Corporation assumes no responsibility for any errors which may appear in

this document.

NEC Corporation does not assume any liability for infringement of patents, copyrights or other intellectual property

rights of third parties by or arising from use of a device described herein or any other liability arising from use

of such device. No license, either express, implied or otherwise, is granted under any patents, copyrights or other

intellectual property rights of NEC Corporation or others.

While NEC Corporation has been making continuous effort to enhance the reliability of its semiconductor devices,

the possibility of defects cannot be eliminated entirely. To minimize risks of damage or injury to persons or

property arising from a defect in an NEC semiconductor device, customers must incorporate sufficient safety

measures in its design, such as redundancy, fire-containment, and anti-failure features.

NEC devices are classified into the following three quality grades:

"Standard", "Special", and "Specific". The Specific quality grade applies only to devices developed based on a

customer designated "quality assurance program" for a specific application. The recommended applications of

a device depend on its quality grade, as indicated below. Customers must check the quality grade of each device

before using it in a particular application.

Standard: Computers, office equipment, communications equipment, test and measurement equipment,

audio and visual equipment, home electronic appliances, machine tools, personal electronic

equipment and industrial robots

Special: Transportation equipment (automobiles, trains, ships, etc.), traffic control systems, anti-disaster

systems, anti-crime systems, safety equipment and medical equipment (not specifically designed

for life support)

Specific: Aircrafts, aerospace equipment, submersible repeaters, nuclear reactor control systems, life

support systems or medical equipment for life support, etc.

The quality grade of NEC devices is "Standard" unless otherwise specified in NEC's Data Sheets or Data Books.

If customers intend to use NEC devices for applications other than those specified for Standard quality grade,

they should contact an NEC sales representative in advance.

Anti-radioactive design is not implemented in this product.

M4 96.5


型号：	UPD22148CA-A
厂家：	NEC
描述：	Crossbar Switch, 1-Bit, CMOS, PDIP22, 0.300 INCH, SHRINK, PLASTIC, DIP-22 存储开关
文件：	总16页 (文件大小：151K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

UPD22148CA-A [NEC]

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