AD7538(RevA) Просмотр технического описания (PDF) - Analog Devices
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AD7538 Datasheet PDF : 8 Pages
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AD7538
The transfer function of Figure 7 is:
Gain = VOUT = – REQ
V IN
RFB
(1)
REQ is the equivalent transfer impedance of the DAC from the
VREF pin to the IOUT pin and can be expressed as
REQ
=
2n RIN
N
(2)
Where: n is the resolution of the DAC
Where: N is the DAC input code in decimal
Where: RIN is the constant input impedance
Where: of the DAC (RIN = RLAD)
Substituting this expression into Equation 1 and assuming zero
gain error for the DAC (RIN = RFB) the transfer function simpli-
fies to
VOUT = – 2n
VIN
N
(3)
The ratio N/2n is commonly represented by the term D and, as
such, is the fractional representation of the digital input word.
VOUT = – –2n = –1
VIN
ND
(4)
Equation 4 indicates that the gain of the circuit can be varied
from 16,384 down to unity (actually 16,384/16,383) in 16,383
steps. The all 0s code is never applied. This avoids an open-
loop condition thereby saturating the amplifier. With the all 0s
code excluded there remains 2n – 1 possible input codes allow-
ing a choice of 2n – 1 output levels. In dB terms the dynamic
range is
20
log10
VOUT
V IN
= 20 log10 (2n –1) = 84 dB.
MICROPROCESSOR INTERFACING
The AD7538 is designed for easy interfacing to 16-bit micro-
processors and can be treated as a memory mapped peripheral.
This reduces the amount of external logic needed for interfacing
to a minimal.
AD7538-8086 INTERFACE
Figure 8 shows the 8086 processor interface to a single device.
In this setup the double buffering feature (using LDAC) of the
DAC is not used. The 14-bit word is written to the DAC in one
MOV instruction and the analog output responds immediately.
Figure 8. AD7538-8086 Interface Circuit
In a multiple DAC system the double buffering of the AD7538
allows the user to simultaneously update all DACs. In Figure 9,
a 14-bit word is loaded to the Input Registers of each of the
DACs in sequence. Then, with one instruction to the appropri-
ate address, CS4 (i.e., LDAC) is brought low, updating all the
DACs simultaneously.
APPLICATION HINTS
Output Offset: CMOS D/A converters in circuits such as Fig-
ures 4 and 5 exhibit a code dependent output resistance which
in turn can cause a code dependent error voltage at the output
of the amplifier. The maximum amplitude of this error, which
adds to the D/A converter nonlinearity, depends on VOS, where
VOS is the amplifier input offset voltage. To maintain specified
accuracy with VREF at 10 V, it is recommended that VOS be no
greater than 0.25 mV, or (25 × 10–6) (VREF), over the tempera-
ture range of operation. The AD711 is a suitable op amp. The
op amp has a wide bandwidth and high slew rate and is recom-
mended for ac and other applications requiring fast settling.
General Ground Management: Since the AD7538 is speci-
fied for high accuracy, it is important to use a proper grounding
technique. AC or transient voltages between AGND and
DGND can cause noise injection into the analog output. The
simplest method of ensuring that voltages at AGND and
DGND are equal is to tie AGND and DGND together at the
AD7538. In more complex systems where the AGND and
DGND intertie is on the backplane, it is recommended that two
diodes be connected in inverse parallel between the AD7538
AGND and DGND pins (1N914 or equivalent).
Figure 9. AD7538-8086 Interface: Multiple DAC System
REV. A
–7–
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