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OP295 Datasheet, PDF (9/12 Pages) Analog Devices – DUAL/QUAD RAIL-TO-RAIL OPERATIONAL AMPLIFIERS
OP295/OP495
common-mode rejection performance and minimize drift. This
instrumentation amplifier can operate from a supply voltage as
low as 3 volts.
A Single Supply RTD Thermometer Amplifier
This RTD amplifier takes advantage of the rail-to-rail swing of
the OP295/OP495 to achieve a high bridge voltage in spite of a
low 5 V supply. The OP295/OP495 amplifier servos a constant
200 µA current to the bridge. The return current drops across
the parallel resistors 6.19 kΩ and the 2.55 MΩ, developing a
voltage that is servoed to 1.235 V, which is established by the
AD589 bandgap reference. The 3-wire RTD provides an equal
line resistance drop in both 100 Ω legs of the bridge, thus im-
proving the accuracy.
The AMP04 amplifies the differential bridge signal and converts
it to a single-ended output. The gain is set by the series resis-
tance of the 332 Ω resistor plus the 50 Ω potentiometer. The
gain scales the output to produce a 4.5 V full scale. The
0.22 µF capacitor to the output provides a 7 Hz low-pass filter
to keep noise at a minimum.
200Ω ZERO ADJ
10-TURNS
26.7k
0.5%
26.7k
0.5%
+5V
7
31
50Ω
332Ω
8 0.22µF
100Ω
RTD
100Ω
0.5%
1
2
1/2
AMP04
5
4
6
VO
4.5V = 450°C
0V = 0°C
OP295/
OP495
2.55M
1%
23
1.235
+5V
6.19k
1%
37.4k
AD589
Figure 6. Low Power RTD Amplifier
A Cold Junction Compensated, Battery Powered
Thermocouple Amplifier
The OP295/OP495’s 150 µA quiescent current per amplifier
consumption makes it useful for battery powered temperature
measuring instruments. The K-type thermocouple terminates
into an isothermal block where the terminated junctions’ ambi-
ent temperatures can be continuously monitored and corrected
by summing an equal but opposite thermal EMF to the ampli-
fier, thereby canceling the error introduced by the cold junctions.
1.235V
AD589
ISOTHERMAL
BLOCK
1N914
7.15k
1%
ALUMEL
1.5M 24.9k
1%
1%
AL
COLD
JUNCTIONS
CR
CHROMEL
K-TYPE
THERMOCOUPLE
40.7µV/°C
475Ω 2.1k
1% 1%
24.9k
9V
24.3k
1%
SCALE
ADJUST
1.33MΩ 20k
4.99k
1%
2
8
500Ω
10-TURN
OP295/
OP495
1
3
4
ZERO
ADJUST
VO
0V = 0°C
5V = 500°C
Figure 7. Battery Powered, Cold-Junction Compensated
Thermocouple Amplifier
To calibrate, immerse the thermocouple measuring junction in a
0°C ice bath, adjust the 500 Ω Zero Adjust pot to zero volts out.
Then immerse the thermocouple in a 250°C temperature bath
or oven and adjust the Scale Adjust pot for an output voltage of
2.50 V, which is equivalent to 250°C. Within this temperature
range, the K-type thermocouple is quite accurate and produces
a fairly linear transfer characteristic. Accuracy of ± 3°C is achiev-
able without linearization.
Even if the battery voltage is allowed to decay to as low as 7 volts,
the rail-to-rail swing allows temperature measurements to
700°C. However, linearization may be necessary for tempera-
tures above 250°C where the thermocouple becomes rather
nonlinear. The circuit draws just under 500 µA supply current
from a 9 V battery.
A 5 V Only, 12-Bit DAC That Swings 0 V to 4.095 V
Figure 8 shows a complete voltage output DAC with wide out-
put voltage swing operating off a single +5 V supply. The serial
input 12-bit D/A converter is configured as a voltage output
device with the 1.235 V reference feeding the current output pin
(IOUT) of the DAC. The VREF which is normally the input now
becomes the output.
The output voltage from the DAC is the binary weighted volt-
age of the reference, which is gained up by the output amplifier
such that the DAC has a 1 mV per bit transfer function.
+5V
+5V
R1
17.8kΩ
+1.23V
3
IOUT
8
VDD
DAC8043
2
RFB
VREF 1
AD589
GND CLK SRI LD
4 765
DIGITAL
CONTROL
TOTAL POWER DISSIPATION = 1.6mW
+5V
38
OP295/
OP495
2
4
D
VO = 4096 (4.096V)
1
R4
R2
41.2k
R3
5kΩ
100kΩ
Figure 8. A 5 Volt 12-Bit DAC with 0 V to +4.095 Output
Swing
4–20 mA Current Loop Transmitter
Figure 9 shows a self powered 4–20 mA current loop transmit-
ter. The entire circuit floats up from the single supply (12 V to
36 V) return. The supply current carries the signal within the 4
to 20 mA range. Thus the 4 mA establishes the baseline
NULL ADJ
SPAN ADJ
100kΩ
10-TURN
10kΩ 182k 1.21M
10-TURN 1% 1%
VIN
3
0 + 3V
2
6 REF02 2
GND
5V
4
100Ω
8
1
4
1/2
OP295/
OP495
220Ω
2N1711
220pF
HP
100k
5082-2800 1%
100Ω
1%
+12V
TO
+36V
4–20m A
RL
100Ω
Figure 9. 4–20 mA Current Loop Transmitter
REV. B
–9–