ML2259CCP datasheet, PDF - EEWORLD Datasheet

May 1997

ML2252*, ML2259**

µP Compatible 8-Bit A/D Converters

with 2- or 8-Channel Multiplexer

GENERAL DESCRIPTION

The ML2252 and ML2259 combine an 8-bit A/D

converter, 2- or 8-channel analog multiplexer, and a

microprocessor compatible 8-bit parallel interface and

control logic in a single monolithic CMOS device.

Easy interface to microprocessors is provided by the

latched and decoded multiplexer address inputs and a

double buffered three-state data bus. These analog-to-

digital converters allow the microprocessor to operate

completely asynchronous to the converter clock.

The built in sample and hold function provides the ability

to digitize a 5V, 50kHz sinewave to 8-bit accuracy. The

differential comparator design provides low power supply

sensitivity to DC and AC variations. The voltage reference

can be externally set to any value between ground and

V

CC

, thus allowing a full conversion over a relatively

small span. All parameters are guaranteed over

temperature with a power supply voltage of 5V ±10%.

The device is suitable for a wide range of applications

from process and machine control to consumer,

automotive, and telecommunication applications.

FEATURES

s

Conversion time (f

CLK

= 1.46MHz); 6.6µs

Total unadjusted error; ±1/2LSB or ±1LSB

No missing codes

Sample and hold; 390ns acquisition

Capable of digitizing a 5V, 50kHz sinewave

2- or 8-channel input multiplexer

0V to 5V analog input range with single 5V

power supply

Operates ratiometrically or with up to 5V

voltage reference

No zero or full scale adjust required

Analog input protection; 25mA per input min

Continuous conversion mode

Low power dissipation; 15mW max

TTL and CMOS compatible digital inputs and outputs

ML2252 BLOCK DIAGRAM

* This Part Is Obsolete

** This Part Is End of Life As Of August 1, 2000

V

CC

CH0

2-CHANNEL

MULTIPLEXER

CLOCK

CONTROL

& TIMING

START

EOC

CH1

+

Σ

–

8pF

+

COMP

–

DB0

SUCCESSIVE

APPROXIMATION

REGISTER

THREE

STATE

OUTPUT

BUFFER

D/A

CONVERTER

DB1

DB2

DB3

DB4

DB5

DB6

DB7

ADDRESS

LATCH

AND

DECODER

ALE

A0

8pF

A/D WITH

SAMPLE-AND-HOLD FUNCTION

GND

+V

REF

–V

REF

OE

1

ML2252, ML2259

ML2259 BLOCK DIAGRAM

V

CC

CH0

CH1

CH2

CH3

CH4

CH5

CH6

CH7

8pF

8-CHANNEL

MULTIPLEXER

+

CONTROL

& TIMING

CLK

START

EOC

Σ

–

DB0

+

COMP

–

SUCCESSIVE

APPROXIMATION

REGISTER

THREE

STATE

OUTPUT

BUFFER

D/A

CONVERTER

DB1

DB2

DB3

DB4

DB5

DB6

DB7

ADDRESS

LATCH

AND

DECODER

ALE

A0

A1

A2

8pF

A/D WITH

SAMPLE-AND-HOLD FUNCTION

GND

+V

REF

–V

REF

OE

PIN CONFIGURATION

ML2252

20-Pin DIP (P20)

CH1

START

EOC

DB3

OE

CLK

V

CC

+V

REF

GND

DB1

1

2

3

4

5

6

7

8

9

10

20

19

18

17

16

15

14

13

12

11

ML2252

20-Pin PLCC (Q20)

ADDR0

19

18

17

16

15

14

9

GND

10 11

DB1

DB2

12

–V

REF

13

DB0

ALE

DB7

DB6

DB5

DB4

CH1

START

CH1

1

CH3

CH0

ADDR0

ALE

DB7

DB6

DB5

DB4

DB0

–V

REF

DB2

3

DB3

OE

CLK

V

CC

+V

REF

4

5

6

7

8

2

20

TOP VIEW

ML2259

28-Pin DIP(P28W)

CH3

CH4

CH5

CH6

CH7

START

EOC

DB3

OE

CLK

V

CC

+V

REF

GND

DB1

1

2

3

4

5

6

7

8

9

10

11

12

13

14

28

27

26

25

24

23

22

21

20

19

18

17

16

15

ML2259

28-Pin PLCC (Q28)

CH6

CH5

CH4

CH2

CH1

CH0

ADDR0

ADDR1

ADDR2

ALE

DB7

DB6

DB5

DB4

DB0

–V

REF

DB2

CH0

4

CH7

START

EOC

DB3

OE

CLK

V

CC

5

6

7

8

9

10

11

12

+V

REF

3

2

1

28

CH0

EOL

27

26

25

24

23

22

21

20

19

18

DB4

ADDR0

ADDR1

ADDR2

ALE

DB7

DB6

DB5

13 14

GND

DB1

15

DB2

16

–V

REF

17

DB0

TOP VIEW

2

ML2252, ML2259

PIN DESCRIPTION

Pin Number

ML2252 ML2259

1

2

3

4

5

6

7

Name

CH3

CH4

CH5

CH6

CH7

START

EOC

Function

Analog input 3.

Analog input 4.

Analog input 5.

Analog input 6.

Analog input 7.

Start of conversion. Active high digital input pulse initiates conversion.

End of conversion. This output goes low after a START pulse occurs, stays

low for the entire A/D conversion, and goes high after conversion is

completed. Data on DB0–DB7 is valid on rising edge of EOC and stays valid

until next EOC rising edge.

Data output 3.

Output enable input. When OE = 0, DB0–DB7 are in high impedance state;

OE = 1, DB0–DB7 are active outputs.

Clock. Clock input provides timing for A/D converter, S/H, and digital

interface.

Positive supply. 5V ±10%.

Positive reference voltage.

Ground. 0V, all analog and digital inputs or outputs are referenced to this

point.

Data output 1.

Data output 2.

Negative reference voltage.

Data output 0.

Data output 4.

Data output 5.

Data output 6.

Data output 7.

Address latch enable. Input to latch in the digital address (ADDR2-0) on the

rising edge of the multiplexer.

Address input 2 to multiplexer. Digital input for selecting analog input.

Address input 1 to multiplexer. Digital input for selecting analog input.

Address input 0 to multiplexer. Digital input for selecting analog input.

Analog input 0.

Analog input 1.

Analog input 2.

2

3

4

5

6

7

8

9

10

11

12

13

14

15

16

17

18

8

9

10

11

12

13

14

15

16

17

18

19

20

21

22

23

24

25

26

27

28

DB3

OE

CLK

V

CC

+V

REF

GND

DB1

DB2

–V

REF

DB0

DB4

DB5

DB6

DB7

ALE

ADDR2

ADDR1

ADDR0

CH0

CH1

CH2

19

20

1

3

ML2252, ML2259

ABSOLUTE MAXIMUM RATINGS

Absolute maximum ratings are those values beyond which

the device could be permanently damaged. Absolute

maximum ratings are stress ratings only and functional

device operation is not implied.

Supply Voltage, V

CC ..............................................................

6.5V

Logic Inputs ....................................... –0.3V to V

CC

0.3V

Analog Inputs ..................................... –0.3V to V

CC

0.3V

Input Current per Pin ............................................ ±25mA

Storage Temperature ................................ –65°C to 150°C

Lead Temperature (Soldering 10 sec.) .................... 260°C

Thermal Resistance (q

JA

)

20-Pin PDIP ..................................................... 67°C/W

20-Pin PLCC .................................................... 78°C/W

28 Pin PDIP ..................................................... 48°C/W

28-Pin PLCC .................................................... 68°C/W

OPERATING CONDITIONS

Supply Voltage, V

CC ..............................................

4.5V to 6.3V

Temperature Range ........................................ 0°C to 70°C

ELECTRICAL CHARACTERISTICS

Unless otherwise specified, V

CC

= +V

REF

= 5V ±10%, –V

REF

= GND, f

CLK

= 1.46MHz,

T

A

= Operating temperature range (Note 1)

ML2252B, ML2259B

PARAMETER

CONDITIONS

MIN

TYP

MAX

MIN

ML2252C, ML2259C

TYP

MAX

UNITS

Converter and Multiplexer Characteristics

Total Unadjusted Error

+V

REF

Voltage Range

–V

REF

Voltage Range

Reference Input Resistance

Analog Input Range

Power Supply Sensitivity

(Note 3)

DC, V

CC

= 5V ±10%

100mVp-p, 100kHz

Sine on V

CC

, V

IN

= 0

I

OFF

, Off Channel Leakage

Current (Note 9)

On Channel = V

CC,

(Note 4)

Off Channel = 0V

On Channel = 0V, (Note 4)

Off Channel = V

CC

I

ON

, On Channel Leakage

Current (Note 9)

On Channel = 0V, (Note 4)

Off Channel = V

CC

On Channel = V

CC,

(Note 4)

Off Channel = 0V

–1

1

–1

1

–1

1

V

REF

= V

CC,

(Note 2)

–V

REF

GND – 0.1

14

GND – 0.1

±1/32

±1/16

–1

1

20

±1/2

V

CC

+ 0.1

+V

REF

35

–V

REF

GND – 0.1

14

20

±1

V

CC

+ 0.1

+V

REF

28

V

CC

+ 0.1

±1/32

±1/16

±1/4

LSB

V

k½

V

LSB

µA

V

CC

+ 0.1 GND – 0.1

±1/4

SYMBOL

Digital and DC

V

IN(1)

V

IN(0)

I

IN(1)

I

IN(0)

V

OUT(1)

V

OUT(0)

I

OUT

I

CC

PARAMETER

CONDITIONS

MIN

TYP

MAX

UNITS

Logical “1” Input Voltage

Logical “0” Input Voltage

Logical “1” Input Current

Logical “0” Input Current

Logical “1” Output Voltage

Logical “0” Output Voltage

Three-State Output Current

V

IN

= V

CC

V

IN

= 0V

I

OUT

= –2mA

I

OUT

= 2mA

V

OUT

= 0V

V

OUT

= V

CC

Supply Current

2.0

0.8

1

–1

4.0

0.4

–1

1

1.5

3

V

µA

V

µA

mA

4

ML2252, ML2259

ELECTRICAL CHARACTERISTICS

SYMBOL

PARAMETER

(Continued)

CONDITIONS

MIN

TYP

MAX

UNITS

AC and Dynamic Performance Characteristics (Note 5)

t

ACQ

f

CLK

t

C

SNR

Sample and Hold Acquisition

Clock Frequency

Conversion Time

Signal to Noise Ratio

V

IN

= 51kHz, 5V sine.

f

CLK

= 1.46MHz

(f

SAMPLING

> 150kHz). Noise is sum

of all nonfundamental components

up to 1/2 of f

SAMPLING

V

IN

= 51kHz, 5V sine.

f

CLK

= 1.46MHz

(f

SAMPLING

> 150kHz).

THD is sum 2, 3, 4, 5 harmonics

relative to fundamental

V

IN

= f

A

+ f

B

. f

A

= 49kHz, 2.5V sine.

f

B

= 47.8kHz, 2.5V sine,

f

CLK

= 1.46MHz

(f

SAMPLING

> 150kHz). IMD is (f

A

+ f

B

),

(f

A

– f

B

), (2f

A

+ f

B

), (2f

A

– f

B

), (f

A

+ 2f

B

),

(f

A

– 2f

B

) relative to fundamental

V

IN

= 0 to 50kHz. 5V sine relative

to 1kHz

(Note 6)

40

1/2

50

Synchronous only, (Note 7)

40

50

0

50

Figure 1, C

L

= 50pF

Figure 1, C

L

= 10pF

t

1H, 0H

C

IN

C

OUT

Output Disable for DB0–DB7

Figure 1, C

L

= 50pF

Figure 1, C

L

= 10pF

Capacitance of Logic Input

Capacitance of Logic Outputs

5

10

100

50

100

50

10

8.5

47

1/2

1460

8.5 + 250ns

1/f

CLK

kHz

1/f

CLK

dB

THD

Total Harmonic Distortion

–60

dB

IMD

Intermodulation Distortion

–60

dB

FR

t

DC

t

EOC

t

WS

t

SS

t

WALE

t

S

t

H

t

H1, H0

Frequency Response

Clock Duty Cycle

End of Conversion Delay

Start Pulse Width

Start Pulse Setup Time

Address Latch Enable

Pulse Width

Address Setup

Address Hold

Output Enable for DB0–DB7

0.1

60

1/2 + 250ns

dB

%

1/f

CLK

ns

pF

Note 1: Limits are guaranteed by 100% testing, sampling, or correlation with worst-case test conditions.

Note 2: Total unadjusted error includes offset, full scale, linearity, multiplexer and sample and hold errors.

Note 3: For –V

REF

• V

IN

(+) the digital output code will be 0000 0000. Two on-chip diodes are tied to each analog input which will forward conduct for analog input voltages

one diode drop below ground or one diode drop greater than the V

CC

supply. Be careful, during testing at low V

CC

levels (4.5V), as high level analog inputs (5V) can

cause this input diode to conduct — especially at elevated temperatures, and cause errors for analog inputs near full scale. The spec allow 100mV forward bias of either

diode. This means that as long as the analog V

IN

or V

REF

does not exceed the supply voltage by more than 100mV, the output code will be correct. To achieve an

absolute 0V

DC

to 5V

DC

input voltage range will therefore require a minimum supply voltage of 4.900V

DC

over temperature variations, initial tolerance and loading.

Note 4: Leakage current is measured with the clock not switching.

Note 5: C

L

= 50pF, timing measured at 50% point.

Note 6: A 40% to 60% clock duty cycle range insures proper operation at all clock frequencies. In the case that an available clock has a duty cycle outside of these limits,

the minimum time the clock is high or the minimum time the clock is low must be at least 40ns. The maximum time the clock can be high or low is 60µs.

Note 7: The conversion start setup time requirement only needs to be satisfied if a conversion must be synchronized to a given clock rising edge. If the setup time is not met,

start conversion will have an uncertainty of one clock pulse.

5

ML2259CCP

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