ADC0820CCWMX/NOPB - Texas Instruments High-Performance Analog

ADC0820

8-Bit High Speed µP Compatible A/D Converter with

Track/Hold Function

General Description

By using a half-flash conversion technique, the 8-bit

ADC0820 CMOS A/D offers a 1.5 µs conversion time and

dissipates only 75 mW of power. The half-flash technique

consists of 32 comparators, a most significant 4-bitADC and

a least significant 4-bit ADC.

The input to the ADC0820 is tracked and held by the input

sampling circuitry eliminating the need for an external

sample-and-hold for signals moving at less than 100 mV/µs.

For ease of interface to microprocessors, the ADC0820 has

been designed to appear as a memory location or I/O port

without the need for external interfacing logic.

Key Specifications

jResolution 8 Bits

jConversion Time 2.5 µs Max (RD Mode)

1.5 µs Max (WR-RD Mode)

jLow Power 75 mW Max

jTotal Unadjusted

Error ±

⁄

LSB and ±1 LSB

Features

nBuilt-in track-and-hold function

nNo missing codes

nNo external clocking

nSingle supply—5 V

nEasy interface to all microprocessors, or operates

stand-alone

nLatched STRI-STATE output

nLogic inputs and outputs meet both MOS and T

voltage level specifications

nOperates ratiometrically or with any reference value

equal to or less than V

n0V to 5V analog input voltage range with single 5V

supply

nNo zero or full-scale adjust required

nOverflow output available for cascading

n0.3" standard width 20-pin DIP

n20-pin molded chip carrier package

n20-pin small outline package

n20-pin shrink small outline package (SSOP)

Connection and Functional Diagrams

Dual-In-Line, Small Outline

and SSOP Packages

DS005501-1

Top View

Molded Chip Carrier

Package

DS005501-33

June 1999

ADC0820 8-Bit High Speed µP Compatible A/D Converter with Track/Hold Function

Connection and Functional Diagrams (Continued)

Ordering Information

Part Number Total Package Temperature

Unadjusted Error Range

ADC0820BCV V20A—Molded Chip Carrier 0˚C to +70˚C

ADC0820BCWM ±

⁄

LSB M20B—Wide Body Small Outline 0˚C to +70˚C

ADC0820BCN N20A—Molded DIP 0˚C to +70˚C

ADC0820CCJ

±1 LSB

J20A—Cerdip −40˚C to +85˚C

ADC0820CCWM M20B—Wide Body Small Outline 0˚C to +70˚C

ADC0820CIWM M20B—Wide Body Small Outline −40˚C to +85˚C

ADC0820CCN N20A—Molded DIP 0˚C to +70˚C

DS005501-2

FIGURE 1.

ADC0820

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Absolute Maximum Ratings (Notes 1, 2)

If Military/Aerospace specified devices are required,

please contact the National Semiconductor Sales Office/

Distributors for availability and specifications.

Supply Voltage (V

) 10V

Logic Control Inputs −0.2V to V

+0.2V

Voltage at Other Inputs and Output −0.2V to V

+0.2V

Storage Temperature Range −65˚C to +150˚C

Package Dissipation at T

= 25˚C 875 mW

Input Current at Any Pin (Note 5) 1 mA

Package Input Current (Note 5) 4 mA

ESD Susceptability (Note 9) 1200V

Lead Temp. (Soldering, 10 sec.)

Dual-In-Line Package (plastic) 260˚C

Dual-In-Line Package (ceramic) 300˚C

Surface Mount Package

Vapor Phase (60 sec.) 215˚C

Infrared (15 sec.) 220˚C

Operating Ratings (Notes 1, 2)

Temperature Range T

MIN

≤T

MAX

ADC0820CCJ −40˚C≤T

≤+85˚C

ADC0820CIWM −40˚C≤T

≤+85˚C

ADC0820BCN, ADC0820CCN 0˚C≤T

≤70˚C

ADC0820BCV 0˚C≤T

≤70˚C

ADC0820BCWM, ADC0820CCWM 0˚C≤T

≤70˚C

Range 4.5V to 8V

Converter Characteristics

The following specifications apply for RD mode (pin 7=0), V

=5V, V

REF

(+)=5V,and V

REF

(−)=GND unless otherwise specified.

Boldface limits apply from T

MIN

to T

MAX

; all other limits T

=25˚C.

Parameter Conditions ADC0820BCN, ADC0820CCN Limit

Units

ADC0820CCJ ADC0820BCV, ADC0820BCWM

ADC0820CCWM, ADC0820CIWM

Typ Tested Design Typ Tested Design

(Note 6) Limit Limit (Note 6) Limit Limit

(Note 7) (Note 8) (Note 7) (Note 8)

Resolution 888Bits

Total Unadjusted ADC0820BCN, BCWM ±

⁄

LSB

Error ADC0820CCJ ±1LSB

(Note 3) ADC0820CCN, CCWM, CIWM, ±1±1LSB

ADC0820CCMSA ±1±1LSB

Minimum Reference 2.3 1.00 2.3 1.2 kΩ

Resistance

Maximum Reference 2.3 62.3 5.3 6kΩ

Resistance

Maximum VREF(+) VCC VCC VCC V

Input Voltage

Minimum VREF(−) GND GND GND V

Input Voltage

Minimum VREF(+) VREF(−) VREF(−) VREF(−) V

Input Voltage

Maximum VREF(−) VREF(+) VREF(+) VREF(+) V

Input Voltage

Maximum VIN Input VCC+0.1 VCC+0.1 VCC+0.1 V

Voltage

Minimum VIN Input GND−0.1 GND−0.1 GND−0.1 V

Voltage

Maximum Analog CS =VCC

Input Leakage VIN=VCC 30.3 3µA

Current VIN=GND −3 −0.3 −3 µA

Power Supply VCC=5V±5% ±1/16 ±

⁄

±1/16 ±

⁄

LSB

Sensitivity

ADC0820

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DC Electrical Characteristics

The following specifications apply for V

=5V, unless otherwise specified. Boldface limits apply from T

MIN

to T

MAX

; all other

limits T

=25˚C.

Parameter Conditions ADC0820BCN, ADC0820CCN Limit

Units

ADC0820CCJ ADC0820BCV, ADC0820BCWM

ADC0820CCWM, ADC0820CIWM

Typ Tested Design Typ Tested Design

(Note 6) Limit Limit (Note 6) Limit Limit

(Note 7) (Note 8) (Note 7) (Note 8)

VIN(1), Logical “1” VCC=5.25V CS , WR , RD 2.0 2.0 2.0 V

Input Voltage Mode 3.5 3.5 3.5 V

VIN(0), Logical “0” VCC=4.75V CS , WR , RD 0.8 0.8 0.8 V

Input Voltage Mode 1.5 1.5 1.5 V

IIN(1), Logical “1” VIN(1)=5V; CS , RD 0.005 10.005 1µA

Input Current VIN(1)=5V; WR 0.1 30.1 0.3 3µA

VIN(1)=5V; Mode 50 200 50 170 200 µA

IIN(0), Logical “0” VIN(0)=0V;CS,RD,WR, −0.005 −1 −0.005 −1 µA

Input Current Mode

VOUT(1), Logical “1” VCC=4.75V, IOUT=−360 µA; 2.4 2.8 2.4 V

Output Voltage DB0–DB7, OFL , INT

VCC=4.75V, IOUT=−10 µA; 4.5 4.6 4.5 V

DB0–DB7, OFL , INT

VOUT(0), Logical “0” VCC=4.75V, IOUT=1.6 mA; 0.4 0.34 0.4 V

Output Voltage DB0–DB7, OFL , INT , RDY

IOUT, TRI-STATE VOUT=5V; DB0–DB7, RDY 0.1 30.1 0.3 3µA

Output Current VOUT=0V; DB0–DB7, RDY −0.1 −3 −0.1 −0.3 −3 µA

ISOURCE, Output VOUT=0V; DB0–DB7, OFL −12 −6 −12 −7.2 −6 mA

Source Current INT −9 −4.0 −9 −5.3 −4.0 mA

ISINK, Output Sink VOUT=5V; DB0–DB7, OFL , 14 714 8.4 7mA

Current INT , RDY

ICC, Supply Current CS =WR =RD =0 7.5 15 7.5 13 15 mA

AC Electrical Characteristics

The following specifications apply for V

=5V, t

=20 ns, V

REF

(+)=5V, V

REF

(−)=0V and T

=25˚C unless otherwise specified.

Typ Tested Design

Parameter Conditions (Note 6) Limit Limit Units

(Note 7) (Note 8)

CRD

, Conversion Time for RD

Mode Pin 7 = 0,

Figure 2

1.6 2.5 µs

ACC0

, Access Time (Delay from Pin 7 = 0,

Figure 2

CRD

+20 t

CRD

+50 ns

Falling Edge of RD to Output

Valid)

CWR-RD

, Conversion Time for Pin 7 = V

= 600 ns, 1.52 µs

WR-RD Mode t

=600 ns;

Figures 3, 4

, Write Time Min Pin 7 = V

;

Figures 3, 4

600 ns

Max (Note 4) See Graph 50 µs

, Read Time Min Pin 7 = V

;

Figures 3, 4

600 ns

(Note 4) See Graph

ACC1

, Access Time (Delay from Pin 7 = V

;

Figure 3

Falling Edge of RD to Output

Valid) C

=15 pF 190 280 ns

=100 pF 210 320 ns

ADC0820

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AC Electrical Characteristics (Continued)

The following specifications apply for V

=5V, t

=20 ns, V

REF

(+)=5V, V

REF

(−)=0V and T

=25˚C unless otherwise specified.

Typ Tested Design

Parameter Conditions (Note 6) Limit Limit Units

(Note 7) (Note 8)

ACC2

, Access Time (Delay from

Falling Edge of RD to Output

Valid)

Pin 7 = V

;

Figure 4

=15 pF 70 120 ns

=100 pF 90 150 ns

ACC3

, Access Time (Delay from

Rising Edge of RDY to Output

Valid)

PULLUP

= 1k and C

=15pF 30 ns

, Internal Comparison Time Pin 7=V

;

Figures 4, 5

800 1300 ns

=50 pF

, TRI-STATE Control R

=1k, C

=10 pF 100 200 ns

(Delay from Rising Edge of RD to

Hi-Z State)

INTL

, Delay from Rising Edge of Pin 7 = V

=50pF

WR to Falling Edge of INT t

;

Figure 4

;

Figure 3

+200 t

+290 ns

INTH

, Delay from Rising Edge of

Figures 2, 3, 4

125 225 ns

RD to Rising Edge of INT C

=50 pFc

INTHWR

, Delay from Rising Edge of

Figure 5

=50 pF 175 270 ns

WR to Rising Edge of INT

RDY

, Delay from CS to RDY

Figure 2

=50 pF, Pin 7 =0 50 100 ns

, Delay from INT to Output Valid

Figure 5

20 50 ns

, Delay from RD to INT Pin 7=V

200 290 ns

Figure 3

, Delay from End of Conversion

Figures 2, 3, 4, 5

500 ns

to Next Conversion (Note 4) See Graph

Slew Rate, Tracking 0.1 V/µs

VIN

, Analog Input Capacitance 45 pF

OUT

, Logic Output Capacitance 5 pF

, Logic Input Capacitance 5 pF

Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. DC and AC electrical specifications do not apply when operating

the device beyond its specified operating conditions.

Note 2: All voltages are measured with respect to the GND pin, unless otherwise specified.

Note 3: Total unadjusted error includes offset, full-scale, and linearity errors.

Note 4: Accuracy may degrade if tWR or tRD is shorter than the minimum value specified. See Accuracy vs tWR and Accuracy vs tRD graphs.

Note 5: When the input voltage (VIN) at any pin exceeds the power supply rails (VIN <V−or VIN >V+) the absolute value of current at that pin should be limited

to 1 mA or less. The 4 mA package input current limits the number of pins that can exceed the power supply boundaries witha1mAcurrent limit to four.

Note 6: Typicals are at 25˚C and represent most likely parametric norm.

Note 7: Tested limits are guaranteed to National’s AOQL (Average Outgoing Quality Level).

Note 8: Design limits are guaranteed but not 100% tested. These limits are not used to calculate outgoing quality levels.

Note 9: Human body model, 100 pF discharaged through a 1.5 kΩresistor.

ADC0820

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TRI-STATE Test Circuits and Waveforms

Timing Diagrams

DS005501-3 DS005501-4

tr=20 ns

DS005501-5

DS005501-6

tr=20 ns

DS005501-7

Note: On power-up the state of INT can be high or low.

FIGURE 2. RD Mode (Pin 7 is Low)

ADC0820

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Timing Diagrams (Continued)

DS005501-8

FIGURE 3. WR-RD Mode (Pin 7 is High and t

)

DS005501-9

FIGURE 4. WR-RD Mode (Pin 7 is High and t

)

DS005501-10

FIGURE 5. WR-RD Mode (Pin 7 is High)

Stand-Alone Operation

ADC0820

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Typical Performance Characteristics

Logic Input Threshold

Voltage vs Supply Voltage

DS005501-34

Conversion Time (RD Mode)

vs Temperature

DS005501-35

Power Supply Current vs

Temperature (not including

reference ladder)

DS005501-36

Accuracy vs t

DS005501-37

Accuracy vs t

DS005501-38

Accuracy vs t

DS005501-39

Accuracy vs V

REF

(+)-V

REF

(-)]

DS005501-40

, Internal Time Delay vs

Temperature

DS005501-41

Output Current vs

Temperature

DS005501-42

ADC0820

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Description of Pin Functions

Pin Name Function

Analog input; range =GND≤V

≤V

2 DB0 TRI-STATE data output—bit 0 (LSB)

3 DB1 TRI-STATE data output—bit 1

4 DB2 TRI-STATE data output—bit 2

5 DB3 TRI-STATE data output—bit 3

6WR

/RDY WR-RD Mode

WR: With CS low, the conversion is

started on the falling edge of WR.

Approximately 800 ns (the preset internal

time out, t

) after the WR rising edge, the

result of the conversion will be strobed

into the output latch, provided that RD

does not occur prior to this time out (see

Figures 3, 4

RD Mode

RDY: This is an open drain output (no

internal pull-up device). RDY will go low

after the falling edge of CS; RDY will go

TRI-STATE when the result of the

conversion is strobed into the output

latch. It is used to simplify the interface

to a microprocessor system (see

Figure

7 Mode Mode: Mode selection input—it is

internally tied to GND through a 50 µA

current source.

RD Mode: When mode is low

WR-RD Mode: When mode is high

8RD WR-RD Mode

With CS low, the TRI-STATE data

outputs (DB0-DB7) will be activated

when RD goes low (see

Figure 5

). RD

can also be used to increase the speed

of the converter by reading data prior to

the preset internal time out (t

,∼800 ns).

If this is done, the data result transferred

to output latch is latched after the falling

edge of the RD (see

Figures 3, 4

RD Mode

With CS low, the conversion will start

with RD going low, also RD will enable

the TRI-STATE data outputs at the

completion of the conversion. RDY going

TRI-STATE and INT going low indicates

the completion of the conversion (see

Figure 2

Pin Name Function

9 INT WR-RD Mode

INT going low indicates that the

conversion is completed and the data

result is in the output latch. INT will go

low, ∼800 ns (the preset internal time

out, t

) after the rising edge of WR (see

Figure 4

); or INT will go low after the

falling edge of RD , if RD goes low prior

to the 800 ns time out (see

Figure 3

INT is reset by the rising edge of RD or

CS (see

Figures 3, 4

RD Mode

INT going low indicates that the

conversion is completed and the data

result is in the output latch. INT is reset

by the rising edge of RD or CS (see

Figure 2

10 GND Ground

11 V

REF

(−) The bottom of resistor ladder, voltage

range: GND≤V

REF

(−)≤V

REF

(+) (Note 5)

12 V

REF

(+) The top of resistor ladder, voltage range:

REF

(−)≤V

REF

(+)≤V

(Note 5)

13 CS CS must be low in order for the RD or

WR to be recognized by the converter.

14 DB4 TRI-STATE data output—bit 4

15 DB5 TRI-STATE data output—bit 5

16 DB6 TRI-STATE data output—bit 6

17 DB7 TRI-STATE data output—bit 7 (MSB)

18 OFL Overflow output—If the analog input is

higher than the V

REF

(+), OFL will be low

at the end of conversion. It can be used

to cascade 2 or more devices to have

more resolution (9, 10-bit). This output is

always active and does not go into

TRI-STATE as DB0–DB7 do.

19 NC No connection

20 V

Power supply voltage

1.0 Functional Description

1.1 GENERAL OPERATION

The ADC0820 uses two 4-bit flash A/D converters to make

an 8-bit measurement (

Figure 1

). Each flash ADC is made

up of 15 comparators which compare the unknown input to a

reference ladder to get a 4-bit result. To take a full 8-bit

reading, one flash conversion is done to provide the 4 most

significant data bits (via the MS flash ADC). Driven by the 4

MSBs, an internal DAC recreates an analog approximation

of the input voltage. This analog signal is then subtracted

from the input, and the difference voltage is converted by a

second 4-bit flash ADC (the LS ADC), providing the 4 least

significant bits of the output data word.

The internal DAC is actually a subsection of the MS flash

converter. This is accomplished by using the same resistor

ADC0820

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1.0 Functional Description (Continued)

ladder for the A/D as well as for generating the DAC signal.

The DAC output is actually the tap on the resistor ladder

which most closely approximates the analog input. In addi-

tion, the “sampled-data” comparators used in the ADC0820

provide the ability to compare the magnitudes of several

analog signals simultaneously, without using input summing

amplifiers. This is especially useful in the LS flash ADC,

where the signal to be converted is an analog difference.

1.2 THE SAMPLED-DATA COMPARATOR

Each comparator in the ADC0820 consists of a CMOS in-

verter with a capacitively coupled input (

Figures 6, 7

). Ana-

log switches connect the two comparator inputs to the input

capacitor (C) and also connect the inverter’s input and out-

put. This device in effect now has one differential input pair.

A comparison requires two cycles, one for zeroing the com-

parator, and another for making the comparison.

In the first cycle, one input switch and the inverter’s feedback

switch (

Figure 6

) are closed. In this interval, C is charged to

the connected input (V1) less the inverter’s bias voltage (V

approximately 1.2V). In the second cycle (

Figure 7

), these

two switches are opened and the other (V2) input’s switch is

closed. The input capacitor now subtracts its stored voltage

from the second input and the difference is amplified by the

inverter’s open loop gain. The inverter’s input (V

') becomes

and the output will go high or low depending on the sign of

'−V

The actual circuitry used in the ADC0820 is a simple but

important expansion of the basic comparator described

above. By adding a second capacitor and another set of

switches to the input (

Figure 8

), the scheme can be ex-

panded to make dual differential comparisons. In this circuit,

the feedback switch and one input switch on each capacitor

(Z switches) are closed in the zeroing cycle. A comparison is

then made by connecting the second input on each capacitor

and opening all of the other switches (S switches). The

change in voltage at the inverter’s input, as a result of the

change in charge on each input capacitor, will now depend

on both input signal differences.

1.3 ARCHITECTURE

In theADC0820, one bank of 15 comparators is used in each

4-bit flash A/D converter (

Figure 12

). The MS (most signifi-

cant) flashADC also has one additional comparator to detect

input overrange. These two sets of comparators operate

alternately, with one group in its zeroing cycle while the other

is comparing.

When a typical conversion is started, the WR line is brought

low. At this instant the MS comparators go from zeroing to

comparison mode (

Figure 11

). When WR is returned high

after at least 600 ns, the output from the first set of compara-

tors (the first flash) is decoded and latched. At this point the

two 4-bit converters change modes and the LS (least signifi-

cant) flash ADC enters its compare cycle. No less than 600

ns later, the RD line may be pulled low to latch the lower 4

data bits and finish the 8-bit conversion. When RD goes low,

the flashA/Ds change state once again in preparation for the

next conversion.

Figure 11

also outlines how the converter’s interface timing

relates to its analog input (V

). In WR-RD mode, V

DS005501-12

•VO=V

•V on C = V1−VB

•CS= stray input node capacitor

•VB= inverter input bias voltage

Zeroing Phase

FIGURE 6. Sampled-Data Comparator

DS005501-13

Compare Phase

FIGURE 7. Sampled-Data Comparator

DS005501-14

DS005501-45

FIGURE 8. ADC0820 Comparator (from MS Flash ADC)

ADC0820

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1.0 Functional Description (Continued)

measured while WR is low. In RD mode, sampling occurs

during the first 800 ns of RD. Because of the input connec-

tions to the ADC0820’s LS and MS comparators, the con-

verter has the ability to sample V

at one instant (Section

2.4), despite the fact that two separate 4-bit conversions are

being done. More specifically, when WR is low the MS flash

is in compare mode (connected to V

), and the LS flash is in

zero mode (also connected to V

). Therefore both flash

ADCs sample V

at the same time.

1.4 DIGITAL INTERFACE

The ADC0820 has two basic interface modes which are

selected by strapping the MODE pin high or low.

RD Mode

With the MODE pin grounded, the converter is set to Read

mode. In this configuration, a complete conversion is done

by pulling RD low until output data appears. An INT line is

provided which goes low at the end of the conversion as well

as a RDY output which can be used to signal a processor

that the converter is busy or can also serve as a system

Transfer Acknowledge signal.

When in RD mode, the comparator phases are internally

triggered. At the falling edge of RD, the MS flash converter

goes from zero to compare mode and the LS ADC’s com-

parators enter their zero cycle. After 800 ns, data from the

MS flash is latched and the LS flash ADC enters compare

mode. Following another 800 ns, the lower 4 bits are recov-

ered.

WR then RD Mode

With the MODE pin tied high, the A/D will be set up for the

WR-RD mode. Here, a conversion is started with the WR

input; however, there are two options for reading the output

data which relate to interface timing. If an interrupt driven

scheme is desired, the user can wait for INT to go low before

reading the conversion result (

Figure 10

). INT will typically

go low 800 ns after WR’s rising edge. However, if a shorter

conversion time is desired, the processor need not wait for

INT and can exercise a read after only 600 ns (

Figure 9

). If

this is done, INT will immediately go low and data will appear

at the outputs.

Stand-Alone

For stand-alone operation in WR-RD mode, CS and RD can

be tied low and a conversion can be started with WR. Data

will be valid approximately 800 ns following WR’s rising

edge.

RD Mode (Pin 7 is Low)

DS005501-16

DS005501-17

FIGURE 9. WR-RD Mode (Pin 7 is High and t

)

DS005501-18

FIGURE 10. WR-RD Mode (Pin 7 is High and t

)

WR-RD Mode (Pin 7 is High) Stand-Alone Operation

DS005501-19

ADC0820

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1.0 Functional Description (Continued)

OTHER INTERFACE CONSIDERATIONS

In order to maintain conversion accuracy, WR has a maxi-

mum width spec of 50 µs. When the MS flash ADC’s

sampled-data comparators (Section 1.2) are in comparison

mode (WR is low), the input capacitors (C,

Figure 8

) must

hold their charge. Switch leakage and inverter bias current

can cause errors if the comparator is left in this phase for too

long.

Since the MS flash ADC enters its zeroing phase at the end

of a conversion (Section 1.3), a new conversion cannot be

started until this phase is complete. The minimum spec for

this time (t

Figures 2, 3, 4, 5

) is 500 ns.

DS005501-20

Note: MS means most significant

LS means least significant

FIGURE 11. Operating Sequence (WR-RD Mode)

ADC0820

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Detailed Block Diagram

DS005501-15

FIGURE 12.

ADC0820

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2.0 Analog Considerations

2.1 REFERENCE AND INPUT

The two V

REF

inputs of theADC0820 are fully differential and

define the zero to full-scale input range of the A to D con-

verter. This allows the designer to easily vary the span of the

analog input since this range will be equivalent to the voltage

difference between V

(+) and V

(−). By reducing

REF

(+)−V

REF

(−)) to less than 5V, the sensitivity

of the converter can be increased (i.e., if V

REF

=2V then 1

LSB=7.8 mV). The input/reference arrangement also facili-

tates ratiometric operation and in many cases the chip power

supply can be used for transducer power as well as the V

REF

source.

This reference flexibility lets the input span not only be varied

but also offset from zero. The voltage at V

REF

(−) sets the

input level which produces a digital output of all zeroes.

Though V

is not itself differential, the reference design

affords nearly differential-input capability for most measure-

ment applications.

Figure 13

shows some of the configura-

tions that are possible.

2.2 INPUT CURRENT

Due to the unique conversion techniques employed by the

ADC0820, the analog input behaves somewhat differently

than in conventional devices. The A/D’s sampled-data com-

parators take varying amounts of input current depending on

which cycle the conversion is in.

The equivalent input circuit of the ADC0820 is shown in

Figure 14

. When a conversion starts (WR low, WR-RD

mode), all input switches close, connecting V

to thirty-one

1 pF capacitors. Although the two 4-bit flash circuits are not

both in their compare cycle at the same time, V

still sees all

input capacitors at once. This is because the MS flash

converter is connected to the input during its compare inter-

val and the LS flash is connected to the input during its

zeroing phase (Section 1.3). In other words, the LS ADC

uses V

as its zero-phase input.

The input capacitors must charge to the input voltage

through the on resistance of the analog switches (about 5 kΩ

to 10 kΩ). In addition, about 12 pF of input stray capacitance

must also be charged. For large source resistances, the

analog input can be modeled as an RC network as shown in

Figure 15

.AsR

increases, it will take longer for the input

capacitance to charge.

In RD mode, the input switches are closed for approximately

800 ns at the start of the conversion. In WR-RD mode, the

time that the switches are closed to allow this charging is the

time that WR is low. Since other factors force this time to be

at least 600 ns, input time constants of 100 ns can be

accommodated without special consideration. Typical total

input capacitance values of 45 pF allow R

to be 1.5 kΩ

without lengthening WR to give V

more time to settle.

External Reference 2.5V Full-Scale

DS005501-21

Power Supply as Reference

DS005501-22

Input Not Referred to GND

DS005501-23

FIGURE 13. Analog Input Options

ADC0820

www.national.com 14

2.0 Analog Considerations (Continued)

2.3 INPUT FILTERING

It should be made clear that transients in the analog input

signal, caused by charging current flowing into V

, will not

degrade the A/D’s performance in most cases. In effect the

ADC0820 does not “look” at the input when these transients

occur. The comparators’ outputs are not latched while WR is

low, so at least 600 ns will be provided to charge the ADC’s

input capacitance. It is therefore not necessary to filter out

these transients by putting an external cap on the V

termi-

nal.

2.4 INHERENT SAMPLE-HOLD

Another benefit of the ADC0820’s input mechanism is its

ability to measure a variety of high speed signals without the

help of an external sample-and-hold. In a conventional SAR

type converter, regardless of its speed, the input must re-

main at least

⁄

LSB stable throughout the conversion pro-

cess if full accuracy is to be maintained. Consequently, for

many high speed signals, this signal must be externally

sampled, and held stationary during the conversion.

Sampled-data comparators, by nature of their input switch-

ing, already accomplish this function to a large degree (Sec-

tion 1.2). Although the conversion time for the ADC0820 is

1.5 µs, the time through which V

must be

⁄

LSB stable is

much smaller. Since the MS flash ADC uses V

as its

“compare” input and the LSADC uses V

as its “zero” input,

the ADC0820 only “samples” V

when WR is low (Sections

1.3 and 2.2). Even though the two flashes are not done

simultaneously, the analog signal is measured at one instant.

The value of V

approximately 100 ns after the rising edge

of WR (100 ns due to internal logic prop delay) will be the

measured value.

Input signals with slew rates typically below 100 mV/µs can

be converted without error. However, because of the input

time constants, and charge injection through the opened

comparator input switches, faster signals may cause errors.

Still, the ADC0820’s loss in accuracy for a given increase in

signal slope is far less than what would be witnessed in a

conventional successive approximation device.An SAR type

converter with a conversion time as fast as 1 µs would still

not be able to measure a 5V 1 kHz sine wave without the aid

of an external sample-and-hold. TheADC0820, with no such

help, can typically measure 5V, 7 kHz waveforms.

DS005501-24

FIGURE 14.

DS005501-25

FIGURE 15.

ADC0820

www.national.com15

3.0 Typical Applications

8-Bit Resolution Configuration

DS005501-26

9-Bit Resolution Configuration

DS005501-27

ADC0820

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3.0 Typical Applications (Continued)

Telecom A/D Converter

DS005501-28

•V

=3 kHz max ±4V

•No track-and-hold needed

•Low power consumption

Multiple Input Channels

DS005501-29

8-Bit 2-Quadrant Analog Multiplier

DS005501-30

ADC0820

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3.0 Typical Applications (Continued)

Fast Infinite Sample-and-Hold

DS005501-31

ADC0820

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3.0 Typical Applications (Continued)

Digital Waveform Recorder

DS005501-32

ADC0820

www.national.com19

Physical Dimensions inches (millimeters) unless otherwise noted

Hermetic Dual-In-Line Package (J)

Order Number ADC0820CCJ

NS Package Number J20A

ADC0820

www.national.com 20

Physical Dimensions inches (millimeters) unless otherwise noted (Continued)

SO Package (M)

Order Number ADC0820BCWM, ADC0820CCWM or ADC0820CIWM

NS Package Number M20B

Molded Dual-In-Line Package (N)

Order Number ADC0820BCN or ADC0820CCN

NS Package Number N20A

ADC0820

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Physical Dimensions inches (millimeters) unless otherwise noted (Continued)

LIFE SUPPORT POLICY

NATIONAL’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT

DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT AND GENERAL

COUNSEL OF NATIONAL SEMICONDUCTOR CORPORATION. As used herein:

1. Life support devices or systems are devices or

systems which, (a) are intended for surgical implant

into the body, or (b) support or sustain life, and

whose failure to perform when properly used in

accordance with instructions for use provided in the

labeling, can be reasonably expected to result in a

significant injury to the user.

2. A critical component is any component of a life

support device or system whose failure to perform

can be reasonably expected to cause the failure of

the life support device or system, or to affect its

safety or effectiveness.

National Semiconductor

Corporation

Americas

Email: support@nsc.com

National Semiconductor

Europe Fax: +49 (0) 180-530 85 86

Email: europe.support@nsc.com

Deutsch Tel: +49 (0) 69 9508 6208

English Tel: +44 (0) 870 24 0 2171

Français Tel: +33 (0) 1 41 91 8790

National Semiconductor

Asia Pacific Customer

Response Group

Tel: 65-2544466

Fax: 65-2504466

Email: ap.support@nsc.com

National Semiconductor

Japan Ltd.

Tel: 81-3-5639-7560

Fax: 81-3-5639-7507

www.national.com

Molded Chip Carrier Package (V)

Order Number ADC0820BCV

NS Package Number V20A

ADC0820 8-Bit High Speed µP Compatible A/D Converter with Track/Hold Function

National does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and National reserves the right at any time without notice to change said circuitry and specifications.

National P/N ADC0820 - 8-Bit High Speed µP Compatible A/D Converter with Track/Hold Function

See Microcontroller

Products

Products > Analog - Data Acquisition > A-to-D Converters - General Purpose > ADC0820

ADC0820 Product Folder

8-Bit High Speed µP Compatible A/D Converter with Track/Hold Function

Generic P/N 0820

General

Description Features Datasheet Package

& Models Samples

& Pricing Application

Notes

Parametric Table Parametric Table

On-Board Reference No

Resolution 8 bits

Conversion Time (us) 1.50

Differential Input No

Input Sample/Hold Yes

Input Multiplexer 1

Digital Interface Parallel

Software Powerdown No

Onboard Controller No

Conversion Accuracy (LSB) .5

Power Supply Voltage (Volts) 5.0

Datasheet

Title Size in

Kbytes Date View Online Download Receive via

ADC0820 8-Bit High Speed µP Compatible A D Converter

with Track Hold Function 468

Kbytes

10-

Dec-

01 View Online Download Receive via

ADC0820 8-Bit High Speed µP Compatible A D Converter

with Track Hold Function (JAPANESE)693

Kbytes

View Online

Download

Receive via

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Package Availability, Models, Samples & Pricing

Part Number Package Status Models Samples &

Electronic

Orders

Budgetary

Pricing Std

Pack

Size

Package

Marking

Type Pins MSL SPICE IBIS Qty $US

each

ADC0820BCWM SOIC

WIDE 20 MSL Full production N/A N/A

24 Hour

Samples

Buy Now

1K+ $3.0300 rail

[logo]¢U¢Z¢2¢T

ADC0820

BCWM

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National P/N ADC0820 - 8-Bit High Speed µP Compatible A/D Converter with Track/Hold Function

ADC0820CCWM SOIC

WIDE 20 MSL Full production N/A N/A

24 Hour

Samples

Buy Now

1K+ $1.6000 rail

[logo]¢U¢Z¢2¢T

ADC0820

CCWM

ADC0820BCWMX SOIC

WIDE 20 MSL Full production N/A N/A

Buy Now

1K+ $3.0300 reel

1000

[logo]¢U¢Z¢2¢T

ADC0820

BCWM

ADC0820CCWMX SOIC

WIDE 20 MSL Full production N/A N/A 1K+ $1.6000 reel

1000

[logo]¢U¢Z¢2¢T

ADC0820

CCWM

ADC0820BCN MDIP 20 MSL Lifetime buy N/A N/A 1K+ $3.1800 rail

[logo]¢U¢Z¢3¢T¢P

ADC0820BCN

ADC0820CCN MDIP 20 MSL Full production N/A N/A

Buy Now

1K+ $1.6800 rail

[logo]¢U¢Z¢3¢T¢P

ADC0820CCN

ADC0820BCV PLCC 20 MSL Full production N/A N/A 1K+ $3.9400 rail

[logo]¢U¢Z¢2¢T¢P

ADC0820

BCV

ADC0820BCVX PLCC 20 MSL Full production N/A N/A 1K+ $3.9400 reel

1000

[logo]¢U¢Z¢2¢T¢P

ADC0820

BCV

ADC0820B MDC Die Full

production N/A N/A

Samples

tray

N/A -

ADC0820C MDC Die Full

production N/A N/A

Samples

tray

N/A -

ADC0820B MWC Wafer Full

production N/A N/A

wafer

jar

N/A

ADC0820C MWC Wafer Full

production N/A N/A

wafer

jar

N/A

General Description

By using a half-flash conversion technique, the 8-bit ADC0820 CMOS A/D offers a 1.5 µs conversion time and

dissipates only 75 mW of power. The half-flash technique consists of 32 comparators, a most significant 4-bit

ADC and a least significant 4-bit ADC.

The input to the ADC0820 is tracked and held by the input sampling circuitry eliminating the need for an

external sample-and-hold for signals moving at less than 100 mV/µs.

For ease of interface to microprocessors, the ADC0820 has been designed to appear as a memory location or

I/O port without the need for external interfacing logic.

Features

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National P/N ADC0820 - 8-Bit High Speed µP Compatible A/D Converter with Track/Hold Function
●     Built-in track-and-hold function
●     No missing codes
●     No external clocking
●     Single supply-5 VDC 
●     Easy interface to all microprocessors, or operates stand-alone
●     Latched STRI-STATE output
●     Logic inputs and outputs meet both MOS and T2L voltage level specifications
●     Operates ratiometrically or with any reference value equal to or less than VCC 
●     0V to 5V analog input voltage range with single 5V supply
●     No zero or full-scale adjust required
●     Overflow output available for cascading
●     0.3[Prime] standard width 20-pin DIP
●     20-pin molded chip carrier package
●     20-pin small outline package
●     20-pin shrink small outline package (SSOP)
Key Specification
Resolution 8 Bits
Conversion Time 2.5 µs Max (RD Mode)
  1.5 µs Max (WR-RD Mode)
Low Power 75 mW Max
Total Unadjusted Error ±½ LSB and ± 1 LSB
Application Notes
Title Size in Kbytes Date View Online Download Receive via Email
AN-769: Dynamic Specifications 
for Sampling A/D Converters 128 Kbytes 5-Aug-95 View Online Download Receive via Email
If you have trouble printing or viewing PDF file(s), see Printing Problems.
[Information as of 5-Aug-2002] 
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