ADC-0803 Harris, ADC-0803 Datasheet - Page 13

ADC-0803

Manufacturer Part Number

ADC-0803

Description

(ADC0802 - ADC0804) 8-Bit/ Microprocessor- Compatible/ A/D Converters

Manufacturer

Harris

Datasheet

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Figures 19 and 20 show more sophisticated test circuits.

Typical Applications

Interfacing 8080/85 or Z-80 Microprocessors

This converter has been designed to directly interface with

8080/85 or Z-80 Microprocessors. The three-state output

capability of the A/D eliminates the need for a peripheral

interface device, although address decoding is still required

to generate the appropriate CS for the converter. The A/D

can be mapped into memory space (using standard mem-

ory-address decoding for CS and the MEMR and MEMW

strobes) or it can be controlled as an I/O device by using the

I/OR and I/OW strobes and decoding the address bits A0

A7 (or address bits A8

same 8-bit address information) to obtain the CS input.

Using the I/O space provides 256 additional addresses and

may allow a simpler 8-bit address decoder, but the data can

only be input to the accumulator. To make use of the addi-

tional memory reference instructions, the A/D should be

mapped into memory space. See AN020 for more discus-

sion of memory-mapped vs I/O-mapped interfaces. An

example of an A/D in I/O space is shown in Figure 21.

The standard control-bus signals of the 8080 (CS, RD and

WR) can be directly wired to the digital control inputs of the

A/D, since the bus timing requirements, to allow both starting

the converter, and outputting the data onto the data bus, are

met. A bus driver should be used for larger microprocessor

systems where the data bus leaves the PC board and/or

must drive capacitive loads larger than 100pF.

It is useful to note that in systems where the A/D converter is

1 of 8 or fewer I/O-mapped devices, no address-decoding

circuitry is necessary. Each of the 8 address bits (A0 to A7)

can be directly used as CS inputs, one for each I/O device.

FIGURE 19. A/D TESTER WITH ANALOG ERROR OUTPUT. THIS

ANALOG

INPUTS

DIGITAL

INPUTS

FIGURE 20. BASIC “DIGITAL” A/D TESTER

CIRCUIT CAN BE USED TO GENERATE “ERROR

PLOTS” OF FIGURE 11.

“A”

10-BIT

DAC

A/D UNDER

8-BIT

TEST

“B”

ANALOG

A15, since they will contain the

100R

A/D UNDER

10-BIT

TEST

DAC

ADC0802, ADC0803, ADC0804

100X ANALOG

ERROR VOLTAGE

ANALOG OUTPUT

OUTPUTS

DIGITAL

“C”

6-17

Interfacing the Z-80 and 8085

The Z-80 and 8085 control buses are slightly different from

that of the 8080. General RD and WR strobes are provided

and separate memory request, MREQ, and I/O request,

IORQ, signals have to be combined with the generalized

strobes to provide the appropriate signals. An advantage of

operating the A/D in I/O space with the Z-80 is that the CPU

will automatically insert one wait state (the RD and WR

strobes are extended one clock period) to allow more time

for the I/O devices to respond. Logic to map the A/D in I/O

space is shown in Figure 22. By using MREQ in place of

IORQ, a memory-mapped conﬁguration results.

Additional I/O advantages exist as software DMA routines are

available and use can be made of the output data transfer

which exists on the upper 8 address lines (A8 to A15) during

I/O input instructions. For example, MUX channel selection for

the A/D can be accomplished with this operating mode.

The 8085 also provides a generalized RD and WR strobe, with

an IO/M line to distinguish I/O and memory requests. The circuit

of Figure 22 can again be used, with IO/M in place of IORQ for

a memory-mapped interface, and an extra inverter (or the logic

equivalent) to provide IO/M for an I/O-mapped connection.

Interfacing 6800 Microprocessor Derivatives (6502, etc.)

The control bus for the 6800 microprocessor derivatives does

not use the RD and WR strobe signals. Instead it employs a

single R/W line and additional timing, if needed, can be derived

from the 2 clock. All I/O devices are memory-mapped in the

6800 system, and a special signal, VMA, indicates that the cur-

rent address is valid. Figure 23 shows an interface schematic

where the A/D is memory-mapped in the 6800 system. For sim-

plicity, the CS decoding is shown using

in many 6800 systems, an already decoded 4/5 line is brought

out to the common bus at pin 21. This can be tied directly to the

CS pin of the A/D, provided that no other devices are

addressed at HEX ADDR: 4XXX or 5XXX.

In Figure 24 the ADC0802 series is interfaced to the MC6800

microprocessor through (the arbitrarily chosen) Port B of the

MC6820 or MC6821 Peripheral Interface Adapter (PlA). Here

the CS pin of the A/D is grounded since the PlA is already

memory-mapped in the MC6800 system and no CS decoding

is necessary. Also notice that the A/D output data lines are con-

nected to the microprocessor bus under program control

through the PlA and therefore the A/D RD pin can be grounded.

Application Notes

NOTE #

AN016

AN018

AN020

AN030

“Selecting A/D Converters”

“Do’s and Don’ts of Applying A/D

Converters”

“A Cookbook Approach to High Speed

Data Acquisition and Microprocessor

Interfacing”

“The ICL7104 - A Binary Output A/D

Converter for Microprocessors”

DESCRIPTION

DM8092. Note that

AnswerFAX

DOC. #

9016

9018

9020

9030

ADC-0803 Harris, ADC-0803 Datasheet - Page 13

ADC-0803

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