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| LT1025ACJ8 Datasheet, PDF (6/12 Pages) Linear Technology – Micropower Thermocouple Cold Junction Compensator | |||
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LT1025
APPLICATIO S I FOR ATIO
In many situations, thermocouples are used in high noise
environments, and some sort of input filter is required.
(See discussion of input filters). To reject 60Hz pick-up
with reasonable capacitor values, input resistors in the
10k-100k range are needed. Under these conditions, bias
current for the amplifier needs to be less than 1nA to avoid
offset and drift effects.
To avoid gain error, high open loop gain is necessary for
single-stage thermocouple amplifiers with 10mV/°C or higher
outputs. A type K amplifier, for instance, with 100mV/°C
output, needs a closed loop gain of â2,500. An ordinary op
amp with a minimum open loop of 50,000 would have an
initial gain error of (2,500)/(50,000) = 5%! Although closed
loop gain is commonly trimmed, temperature drift of open
loop gain will have a very deleterious effect on output
accuracy. Minimum suggested open loop gain for type E, J,
K, and T thermocouples is 250,000. This gain is adequate for
type R and S if output scaling is 10mV/°C or less.
Suggested Amplifier Types
THERMOCOUPLE
E, J, K, T
±15V
LTKA0x
LT1012
LT1001
SUPPLY VOLTAGE
±5V
SINGLE SUPPLY
LTKA0x
LT1012
LT1001
LTC1050
LTC1052
LT1006
LTC1050
LTC1052
LT1006
R, S
LTKA0x
LTC1050
LTC1050
LT1012
LTC1052
LTC1052
LTKA0x
LT1006
Thermocouple Nonlinearities
Thermocouples are linear over relatively limited temperature
spans if accuracies of better than 2°C are needed. The graph
in Figure 4 shows thermocouple nonlinearity for the
temperature range of 0°C to 400°C. Nonlinearities can be
dealt with in hardware by using offsets, breakpoints, or power
series generators. Software solutions include look-up tables,
power series expansions, and piece-wise approximations.
For tables and power series coefficients, the reader is referred
to the ASTM Publication 470A.
Hardware correction for nonlinearity can be as simple as an
offset term. This is shown in Figure 5. The thermocouple
shown in the figure has an increasing slope (α) with
6
0
KâSCALE
0
2.5
1
5
2
7.5
JâSCALE
3
10
4
12.5
SCALEâE
5
15
6
17.5
7
20
SCALEâT
8
0 50 100 150 200 250 300 350 400
TEMPERATURE (°C)
LT1025 ⢠G04
Figure 4. Thermocouple Nonlinearity, 0°C to 400°C
ERROR BEFORE OFFSETTING
VH
ERROR AFTER OFFSETTING
OFFSET AMPLIFIER
SIMPLE AMPLIFIER
THERMOCOUPLE
VL
0
TL T1/6 TM
T5/6 TH
TEMPERATURE (°C)
LT1025 ⢠G05
Figure 5. Offset Curve Fitting
temperature. The temperature range of interest is between TL
and TH, with a calibration point at TM. If a simple amplifier is
used and calibrated at TM, the output will be very high at TL
and very low at TH. Adding the proper offset term and
calibrating at T1/6 or T5/6 can significantly reduce errors. The
technique is as follows:
1. Calculate amplifier gain:
G = (SF) (TH â TL)/(VH â VL)
SF = Output scale factor, e.g., 10mV/°C
VH = Thermocouple output at TH
VL = Thermocouple output at TL
2. Use precision resistors to set gain or calibrate gain by
introducing a precision âdeltaâ input voltage and trimming
for proper âdeltaâ output.
1025fb
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