dac0830-mwc National Semiconductor Corporation, dac0830-mwc Datasheet - Page 11

dac0830-mwc

Manufacturer Part Number

dac0830-mwc

Description

8-bit ?p Compatible, Double-buffered D To A Converters

Manufacturer

National Semiconductor Corporation

Datasheet

1.DAC0830-MWC.pdf (28 pages)

Current page: 11 of 28
Download datasheet (554Kb)

DAC0830 Series Application Hints

Pulling WR

“1” on either of these lines will prevent the changing of the

analog output.

ILE=LOGIC “1”; WR2 and XFER GROUNDED

1.2 Single-Buffered Operation

In a microprocessor controlled system where maximum data

throughput to the DAC is of primary concern, or when only

one DAC of several needs to be updated at a time, a

single-buffered configuration can be used. One of the two

internal registers allows the data to flow through and the

other register will serve as the data latch.

Digital signal feedthrough (see Section 1.5) is minimized if

the input register is used as the data latch. Timing for this

mode is shown in Figure 4 .

Single-buffering in a “stand-alone” system is achieved by

strobing WR

XFER grounded and ILE tied high.

1.3 Flow-Through Operation

Though primarily designed to provide microprocessor inter-

face compatibility, the MICRO-DAC’s can easily be config-

ured to allow the analog output to continuously reflect the

state of an applied digital input. This is most useful in appli-

cations where the DAC is used in a continuous feedback

control loop and is driven by a binary up-down counter, or in

function generation circuits where a ROM is continuously

providing DAC data.

Simply grounding CS, WR

high allows both internal registers to follow the applied digital

inputs (flow-through) and directly affect the DAC analog

output.

1.4 Control Signal Timing

When interfacing these MICRO-DAC to any microprocessor,

there are two important time relationships that must be con-

sidered to insure proper operation. The first is the minimum

WR strobe pulse width which is specified as 900 ns for all

valid operating conditions of supply voltage and ambient

temperature, but typically a pulse width of only 180ns is

adequate if V

guaranteed minimum data hold time of 50ns should be met

(Continued)

low will then update the analog output. A logic

low to update the DAC with CS, WR

=15V

. A second consideration is that the

, WR

, and XFER and tying ILE

and

FIGURE 4.

or erroneous data can be latched. This hold time is defined

as the length of time data must be held valid on the digital

inputs after a qualified (via CS) WR strobe makes a low to

high transition to latch the applied data.

If the controlling device or system does not inherently meet

these timing specs the DAC can be treated as a slow

memory or peripheral and utilize a technique to extend the

write strobe. A simple extension of the write time, by adding

a wait state, can simultaneously hold the write strobe active

and data valid on the bus to satisfy the minimum WR pulse-

width. If this does not provide a sufficient data hold time at

the end of the write cycle, a negative edge triggered

one-shot can be included between the system write strobe

and the WR pin of the DAC. This is illustrated in Figure 5 for

an exemplary system which provides a 250ns WR strobe

time with a data hold time of less than 10ns.

The proper data set-up time prior to the latching edge (LO to

HI transition) of the WR strobe, is insured if the WR pulse-

width is within spec and the data is valid on the bus for the

duration of the DAC WR strobe.

1.5 Digital Signal Feedthrough

When data is latched in the internal registers, but the digital

inputs are changing state, a narrow spike of current may flow

out of the current output terminals. This spike is caused by

the rapid switching of internal logic gates that are responding

to the input changes.

There are several recommendations to minimize this effect.

When latching data in the DAC, always use the input register

as the latch. Second, reducing the V

from +15V to +5V offers a factor of 5 improvement in the

magnitude of the feedthrough, but at the expense of internal

logic switching speed. Finally, increasing C

value consistent with the actual circuit bandwidth require-

ments can provide a substantial damping effect on any

output spikes.

00560807

supply for the DAC

( Figure 8 ) to a

www.national.com

dac0830-mwc National Semiconductor Corporation, dac0830-mwc Datasheet - Page 11

dac0830-mwc

Related parts for dac0830-mwc