Datasheet
Table Of Contents
- Features
- Applications
- Functional Block Diagram
- General Description
- Table of Contents
- Electrical Characteristics—20 kΩ, 50 kΩ, 200 kΩ Versions
- Timing Characteristics—20 kΩ, 50 kΩ, 200 kΩ Versions
- Absolute Maximum Ratings
- Pin Configuration and Pin Function Descriptions
- Typical Performance Characteristics
- Test Circuits
- SPI-Compatible Digital Interface (DIS = 0)
- I2C-Compatible Digital Interface (DIS = 1)
- Operation
- Programming the Variable Resistor
- Programming the Potentiometer Divider Voltage Output Operation
- Pin-Selectable Digital Interface
- SPI-Compatible 3-Wire Serial Bus (DIS = 0)
- I2C-Compatible 2-Wire Serial Bus (DIS = 1)
- Additional Programmable Logic Output
- Self-Contained Shutdown Function
- Multiple Devices on One Bus
- Level Shift for Negative Voltage Operation
- ESD Protection
- Terminal Voltage Operating Range
- Power-Up Sequence
- VLOGIC Power Supply
- Layout and Power Supply Bypassing
- RDAC Circuit Simulation Model
- Applications Information
- Bipolar DC or AC Operation from Dual Supplies
- Gain Control Compensation
- Programmable Voltage Reference
- 8-Bit Bipolar DAC
- Bipolar Programmable Gain Amplifier
- Programmable Voltage Source with Boosted Output
- Programmable 4 to 20 mA Current Source
- Programmable Bidirectional Current Source
- Programmable Low-Pass Filter
- Programmable Oscillator
- Resistance Scaling
- Resistance Tolerance, Drift, and Temperature Coefficient Mismatch Considerations
- Outline Dimensions
AD5263 Data Sheet
Rev. F | Page 24 of 28
8-BIT BIPOLAR DAC
Figure 60 shows a low cost, 8-bit, bipolar DAC. It offers the
same number of adjustable steps, but not the precision as compared
to conventional DACs. The linearity and temperature coefficient,
especially at low values codes, are skewed by the effects of the
digital potentiometer wiper resistance. The output of this circuit is
REF
O
V
D
V ×
−= 1
256
2
(4)
03142-059
AB
A1
W
U1
VIN
GND
V
O
1
VOUT
ADR425
+15V
TRIM
+5VREF
–5VREF
A2
V
I
AD5263
OP2177
V–
V+
+15V
–15V
OP2177
V–
V+
Figure 60. 8-Bit Bipolar DAC
BIPOLAR PROGRAMMABLE GAIN AMPLIFIER
For applications requiring bipolar gain, Figure 61 shows one
implementation similar to the previous circuit. The digital
potentiometer U1 sets the adjustment range. The wiper voltage
at W2 can therefore be programmed between V
I
and –KV
I
at a
given U2 setting. Configuring A2 in the noninverting mode
allows linear gain and attenuation. The transfer function is
( )
−+××
+= KK
D2
R1
R2
V
V
I
O
1
256
1
(5)
where K is the ratio of R
WB1
/R
WA 1
set by U1.
03142-060
A1
AD5263
W1
V
O
A2
A2
B2
V
SS
V
DD
U2
–KV
I
B1
A1
C1
V
I
R2
R1
AD5263
U1
W2
V
DD
V
SS
OP2177
V–
V+
OP2177
V–
V+
Figure 61. Bipolar Programmable Gain Amplifier
Similar to the previous example, in the simpler (and much more
usual) case where K = 1, a single channel is used and U1 is
replaced by a matched pair of resistors to apply V
I
and –V
I
at
the ends of the digital potentiometer. The relationship becomes
I
O
V
D2
R1
R2
V ×
−
×
×
+= 1
256
2
1
(6)
If R2 is large, a compensation capacitor of a few pF may be
needed to avoid any gain peaking.
Table 10 shows the result of adjusting D, with A2 configured with
unity gain, gain of 2, and gain of 10. The result is a bipolar amplifier
with linearly programmable gain and 256-step resolution.
Table 10. Result of Bipolar Gain Amplifier
D
R1 =
∞
, R2 = 0
R1 = R2 R2 = 9 × R1
0 –1 –2 –10
64 –0.5 –1 –5
128 0 0 0
192
0.5
1
5
255 0.968 1.937 9.680
PROGRAMMABLE VOLTAGE SOURCE WITH
BOOSTED OUTPUT
For applications that require high current adjustment, such as a
laser diode driver or tunable laser, a boosted voltage source can
be considered. See Figure 62.
03142-061
+V
W
SIGNAL
C
C
R
BIAS
LD
V
IN
A
B
V
OUT
U1
AD5263
U3 2N7002
U2
–V
I
L
AD8601
Figure 62. Programmable Booster Voltage Source
In this circuit, the inverting input of the op amp forces the V
OUT
to
be equal to the wiper voltage set by the digital potentiometer. The
load current is then delivered by the supply via the N-channel
FET, N1. N1 power handling must be adequate to dissipate power
equal to (V
IN
− V
OUT
) × I
L
. This circuit can source a maximum of
100 mA with a 5 V supply. For precision applications, a voltage
reference such as ADR421 or ADR03 can be applied at the A
terminal of the digital potentiometer.