AD569BD Analog Devices Inc, AD569BD Datasheet - Page 6
AD569BD
Manufacturer Part Number
AD569BD
Description
IC,D/A CONVERTER,SINGLE,16-BIT,BICMOS,DIP,28PIN
Manufacturer
Analog Devices Inc
Datasheet
1.AD569JNZ.pdf
(12 pages)
Specifications of AD569BD
Rohs Status
RoHS non-compliant
Settling Time
4µs
Number Of Bits
16
Data Interface
Parallel
Number Of Converters
1
Voltage Supply Source
Dual ±
Operating Temperature
-25°C ~ 85°C
Mounting Type
Through Hole
Package / Case
28-CDIP (0.600", 15.24mm)
Power Dissipation (max)
-
Lead Free Status / RoHS Status
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AD569
MULTIPLYING FEEDTHROUGH ERROR: This is the error
due to capacitive feedthrough from the reference to the output
with the input registers loaded with all zeroes.
FULL-SCALE ERROR: The AD569’s voltage dividing archi-
tecture gives rise to a fixed full-scale error which is independent
of the reference voltage. This error is trimmed by adjusting the
voltage applied to the +V
DIGITAL-TO-ANALOG GLITCH IMPULSE: The charge in-
jected into the analog output when a new input is latched into
the DAC register gives rise to the Digital-to-Analog Glitch
Impulse.
Figure 5. Typical DNL at Segment Boundary Transitions
Figure 6. Typical DNL Within Segments
b. Segment 256
a. Segment 1
REF
terminals.
–6–
Zener diode can be used to reduce one of the supplies to 9 volts
with the remaining one left at 15 volts. Figure 7a illustrates this
scheme. A 1N753A or equivalent diode is an appropriate choice
for the task. Asymmetrical power supplies can be used since the
AD569’s output is referenced to –V
plies are available. Figure 7c shows this approach. A combina-
tion of +V
ence inputs of the AD569. It is doing double-duty by simulta-
neously regulating the supply voltages for the AD569 through
the use of the level shifting Zeners and transistors. This scheme
utilizes the capability of the outputs of the AD588 to source as
well as sink current. Two other benefits are realized by using
this approach. The first is that the AD569 is no longer directly
connected to the system power supplies. Output sensitivity to
variations in those supplies is, therefore, eliminated. The second
Glitches can be due to either time skews between the input bits
or charge injection from the internal switches. Glitch Impulse
for the AD569 is mainly due to charge injection, and is mea-
sured with the reference connections tied to ground. It is speci-
fied as the area of the glitch in nV-secs.
TOTAL ERROR: The worst-case Total Error is the sum of the
fixed full-scale and offset errors and the linearity error.
POWER SUPPLY AND REFERENCE VOLTAGE RANGES
The AD569 is specified for operation with 12 volt power
supplies. With 10% power supply tolerances, the maximum
reference voltage range is 5 volts. Reference voltages up to
approach their lower limits of 10.8 volts (12 volts - 10%).
If 12 volt power supplies are unavailable in the system, several
alternative schemes may be used to obtain the needed supply
voltages. For example, in a system with 15 V supplies, a single
relative to logic ground (GND, Pin 18). Assuming a worst-case
maximum reference voltage ranges would be +6 and –2 volts for
+V
and –V
Alternately, two 3 V Zener diodes or voltage regulators can be
used to drop each 15 volt supply to 12 volts, respectively. In
Figure 7b, 1N746A diodes are a good choice for this task.
A third method may be used if both 15 volt and 5 volt sup-
range of 0 to 6 volts, while supplies of +V
–15 V can support a reference range of 0 to –8 volts. Again,
10% power supply tolerances are assumed.
NOTE: Operation with +V
erating conditions causing minimum write pulse widths to ex-
tend to 1 s or more. Control signals CS, HBE, LBE, and
LDAC should, therefore, be tied low to render the latches trans-
parent.
No timing problems exist with operation at +V
–V
ate a worst-case condition at –V
(assuming +V
conditions, write pulse widths can stretch to 200 ns with similar
degradation of data setup and hold times. However, 0.75 V
tolerances ( 5%) yield minimal effects on digital timing with
write pulse widths remaining below 100 ns.
Finally, Figure 7d illustrates the use of the combination of an
AD588 and AD569 in a system with 15 volt supplies. As
shown, the AD588 is connected to provide 5 V to the refer-
6 volts can be used but linearity will degrade if the supplies
1.5 volt tolerance on both supplies (10% of 15 volts), the
S
S
= –15 V. However, 10% tolerances on these supplies gener-
= +15 V and V
S
= –15 V .
S
= +15 V and –V
S
is derived from a +15 V supply). Under these
S
= –9 V, and +2 to –8 volts for +V
S
S
= +5 V alters the input latches’ op-
= –5 V can support a reference
S
= –16.5 V and +V
REF
only and thus floats
S
= +5 V and –V
S
= 9 V and
S
= +7.5 V
S
REV. A
= 9 V
S
=
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