AD7528JNZ Analog Devices Inc, AD7528JNZ Datasheet - Page 6
AD7528JNZ
Manufacturer Part Number
AD7528JNZ
Description
IC DAC 8BIT DUAL MULTIPLY 20-DIP
Manufacturer
Analog Devices Inc
Datasheet
1.AD7528KNZ.pdf
(8 pages)
Specifications of AD7528JNZ
Settling Time
400ns
Number Of Bits
8
Number Of Converters
2
Voltage Supply Source
Single Supply
Power Dissipation (max)
450mW
Operating Temperature
-40°C ~ 85°C
Mounting Type
Through Hole
Package / Case
20-DIP (0.300", 7.62mm)
Resolution (bits)
8bit
Sampling Rate
5.6MSPS
Input Channel Type
Parallel
Supply Current
2mA
Digital Ic Case Style
DIP
No. Of Pins
20
Data Interface
CMOS, Parallel, TTL
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Available stocks
Company
Part Number
Manufacturer
Quantity
Price
Part Number:
AD7528JNZ
Manufacturer:
ADI/亚德诺
Quantity:
20 000
AD7528
APPLICATIONS INFORMATION
Application Hints
To ensure system performance consistent with AD7528 specifi-
cations, careful attention must be given to the following points:
1. GENERAL GROUND MANAGEMENT: AC or transient
2. OUTPUT AMPLIFIER OFFSET: CMOS DACs exhibit a
3. HIGH FREQUENCY CONSIDERATIONS: The output
DYNAMIC PERFORMANCE
The dynamic performance of the two DACs in the AD7528 will
depend upon the gain and phase characteristics of the output
amplifiers together with the optimum choice of the PC board
layout and decoupling components. Figure 6 shows the relation
Figure 7. Suggested PC Board Layout for AD7528 with
AD644 Dual Op Amp
C1 LOCATION
voltages between the AD7528 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 AD7528. In more
complex systems where the AGND–DGND intertie is on the
backplane, it is recommended that diodes be connected in
inverse parallel between the AD7528 AGND and DGND
pins (1N914 or equivalent).
code-dependent output resistance which in turn causes a
code-dependent amplifier noise gain. The effect is a code-
dependent differential nonlinearity term at the amplifier
output which depends on V
voltage). This differential nonlinearity term adds to the R/2R
differential nonlinearity. To maintain monotonic operation, it
is recommended that amplifier V
1 LSB over the temperature range of interest.
capacitance of a CMOS DAC works in conjunction with the
amplifier feedback resistance to add a pole to the open loop
response. This can cause ringing or oscillation. Stability can
be restored by adding a phase compensation capacitor in
parallel with the feedback resistor.
–100
–90
–80
–70
–60
–50
V
Figure 6. Channel-to-Channel Isolation
REF
LSB
V
WR
CS
DD
B*
AD644
20k
AD7528
AGND
INPUT FREQUENCY – Hz
50k
V+
V–
PIN 8 OF TO-5 CAN (AD644)
OS
V
DGND
DAC A/DAC B
MSB
100k
REF
(V
AD7528 PIN 1
C2 LOCATION
A*
OS
OS
T
V
V
A
DD
IN
= +25 C
be no greater than 10% of
is amplifier input offset
= 20V PEAK TO PEAK
200k
= +15V
*NOTE
INPUT SCREENS
FEEDTHROUGH.
LAYOUT SHOWS
COPPER SIDE
(i.e., BOTTOM VIEW).
TO REDUCE
500k
1M
–6–
ship between input frequency and channel to channel isolation.
Figure 7 shows a printed circuit layout for the AD7528 and the
AD644 dual op amp which minimizes feedthrough and crosstalk.
SINGLE SUPPLY APPLICATIONS
The AD7528 DAC R-2R ladder termination resistors are con-
nected to AGND within the device. This arrangement is par-
ticularly convenient for single supply operation because AGND
may be biased at any voltage between DGND and V
8 shows a circuit which provides two +5 V to +8 V analog out-
puts by biasing AGND +5 V up from DGND. The two DAC
reference inputs are tied together and a reference input voltage
is obtained without a buffer amplifier by making use of the
constant and matched impedances of the DAC A and DAC B
reference inputs. Current flows through the two DAC R-2R
ladders into R1 and R1 is adjusted until the V
inputs are at +2 V. The two analog output voltages range from
+5 V to +8 V for DAC codes 00000000 to 11111111.
Figure 9 shows DAC A of the AD7528 connected in a positive
reference, voltage switching mode. This configuration is useful
in that V
operation. However, to retain specified linearity, V
the range 0 V to +2.5 V and the output buffered or loaded with
a high impedance, see Figure 10. Note that the input voltage is
connected to the DAC OUT A and the output voltage is taken
from the DAC V
Figure 10. Typical AD7528 Performance in Single Supply
Voltage Switching Mode (K/B/T, L/C/U Grades)
Figure 9. AD7528 in Single Supply, Voltage Switching Mode
DAC A/DAC B
2 VOLTS
INPUTS
DATA
Figure 8. AD7528 Single Supply Operation
10k
OUT
V
3
2
1
2.5
WR
IN
CS
R1
(0V TO +2.5V)
is the same polarity as V
T
V
R2
1k
A
3
DD
= +25 C
REF
= +15V
+15V
3.5
DB0
DB7
V
DD
A pin.
AD7528
DAC A
DAC B
4
4.5
V
V
AD7528
DD
NONLINEARITY
IN
DAC A
A – Volts
= +15V
V
REF
5
AD584J
A
5.5
SUGGESTED
OP AMP:
AD644
IN
DIFFERENTIAL
NONLINEARITY
allowing single supply
GND
OUT A
6
REF
6.5
V
V
V
DD
OUT
OUT
A and V
IN
B = +5V TO +8V
A = +5V TO +8V
7
V
DD
OUT
must be in
. Figure
7.5
REV. B
REF
B
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