AD AD594

a
Monolithic Thermocouple Amplifiers
with Cold Junction Compensation
AD594/AD595
FEATURES
Pretrimmed for Type J (AD594) or
Type K (AD595) Thermocouples
Can Be Used with Type T Thermocouple Inputs
Low Impedance Voltage Output: 10 mV/ⴗC
Built-In Ice Point Compensation
Wide Power Supply Range: +5 V to ⴞ15 V
Low Power: <1 mW typical
Thermocouple Failure Alarm
Laser Wafer Trimmed to 1ⴗC Calibration Accuracy
Setpoint Mode Operation
Self-Contained Celsius Thermometer Operation
High Impedance Differential Input
Side-Brazed DIP or Low Cost Cerdip
PRODUCT DESCRIPTION
The AD594/AD595 is a complete instrumentation amplifier and
thermocouple cold junction compensator on a monolithic chip.
It combines an ice point reference with a precalibrated amplifier
to produce a high level (10 mV/°C) output directly from a thermocouple signal. Pin-strapping options allow it to be used as a
linear amplifier-compensator or as a switched output setpoint
controller using either fixed or remote setpoint control. It can
be used to amplify its compensation voltage directly, thereby
converting it to a stand-alone Celsius transducer with a low
impedance voltage output.
FUNCTIONAL BLOCK DIAGRAM
–IN
14
–ALM
13
+ALM
12
V+
11
COMP
10
VO
9
FB
8
OVERLOAD
DETECT
AD594/AD595
+A
ICE
POINT
COMP. –TC
G
G
+TC
1
2
3
4
5
6
7
+IN
+C
+T
COM
–T
–C
V–
are available at the package pins so that the circuit can be
recalibrated for the thermocouple types by the addition of two
or three resistors. These terminals also allow more precise calibration for both thermocouple and thermometer applications.
The AD594/AD595 is available in two performance grades. The
C and the A versions have calibration accuracies of ± 1°C and
± 3°C, respectively. Both are designed to be used from 0°C to
+50°C, and are available in 14-pin, hermetically sealed, sidebrazed ceramic DIPs as well as low cost cerdip packages.
PRODUCT HIGHLIGHTS
The AD594/AD595 includes a thermocouple failure alarm that
indicates if one or both thermocouple leads become open. The
alarm output has a flexible format which includes TTL drive
capability.
1. The AD594/AD595 provides cold junction compensation,
amplification, and an output buffer in a single IC package.
The AD594/AD595 can be powered from a single ended supply
(including +5 V) and by including a negative supply, temperatures below 0°C can be measured. To minimize self-heating, an
unloaded AD594/AD595 will typically operate with a total supply current 160 µA, but is also capable of delivering in excess of
± 5 mA to a load.
3. Flexible pinout provides for operation as a setpoint controller or a stand-alone temperature transducer calibrated in
degrees Celsius.
The AD594 is precalibrated by laser wafer trimming to match
the characteristic of type J (iron-constantan) thermocouples and
the AD595 is laser trimmed for type K (chromel-alumel) inputs.
The temperature transducer voltages and gain control resistors
2. Compensation, zero, and scale factor are all precalibrated by
laser wafer trimming (LWT) of each IC chip.
4. Operation at remote application sites is facilitated by low
quiescent current and a wide supply voltage range +5 V to
dual supplies spanning 30 V.
5. Differential input rejects common-mode noise voltage on the
thermocouple leads.
REV. C
Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices for its
use, nor for any infringements of patents or other rights of third parties
which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Analog Devices.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781/329-4700
World Wide Web Site: http://www.analog.com
Fax: 781/326-8703
© Analog Devices, Inc., 1999
(@ +25ⴗC and VS = 5 V, Type J (AD594), Type K (AD595) Thermocouple,
AD594/AD595–SPECIFICATIONS unless otherwise noted)
Model
AD594A
Typ
Max
Min
ABSOLUTE MAXIMUM RATING
+VS to –V S
Common-Mode Input Voltage
Differential Input Voltage
Alarm Voltages
+ALM
–ALM
Operating Temperature Range
Output Short Circuit to Common
36
+VS
+VS
–VS – 0.15
–VS
–VS
–VS
–55
Indefinite
–VS + 36
+VS
+125
TEMPERATURE MEASUREMENT
(Specified Temperature Range
0°C to +50°C)
Calibration Error at +25°C1
Stability vs. Temperature 2
Gain Error
Nominal Transfer Function
AMPLIFIER CHARACTERISTICS
Closed Loop Gain 3
Input Offset Voltage
Input Bias Current
Differential Input Range
Common-Mode Range
Common-Mode Sensitivity – RTO
Power Supply Sensitivity – RTO
Output Voltage Range
Dual Supply
Single Supply
Usable Output Current4
3 dB Bandwidth
ALARM CHARACTERISTICS
VCE(SAT) at 2 mA
Leakage Current
Operating Voltage at – ALM
Short Circuit Current
POWER REQUIREMENTS
Specified Performance
Operating5
Quiescent Current (No Load)
+VS
–VS
PACKAGE OPTION
TO-116 (D-14)
Cerdip (Q-14)
AD594C
Typ
Max
Min
36
+VS
+VS
–VS – 0.15
–VS
–VS
–VS
–55
Indefinite
–VS + 36
+VS
+125
ⴞ3
ⴞ0.05
ⴞ1.5
10
193.4
(Temperature in °C) ×
51.70 µV/°C
0.1
–10
+50
–VS – 0.15
–VS – 4
10
10
–VS + 2.5
0
±5
15
+VS – 2
+VS – 2
193.4
(Temperature in °C) ×
51.70 µV/°C
0.1
–VS
–VS
–55
Indefinite
–VS + 36
+VS
+125
–VS – 0.15
–VS – 4
10
10
–VS + 2.5
0
+VS – 2
–VS – 2
–VS + 2.5
0
±5
15
0.3
±5
15
20
AD594AD
AD594AQ
160
100
AD594CD
AD594CQ
300
AD595C
Typ
Max
Units
36
+VS
+VS
Volts
Volts
Volts
–VS + 36
+VS
+125
Volts
Volts
°C
ⴞ1
ⴞ0.025
ⴞ0.75
10
°C
°C/°C
%
mV/°C
–VS – 0.15
–VS
–VS
–VS
–55
Indefinite
247.3
(Temperature in °C) ×
40.44 µV/°C
0.1
–10
+50
–VS – 0.15
–VS – 4
10
10
–VS + 2.5
0
±5
15
AD595AD
AD595AQ
ⴞ1
+VS – 4
20
+VS = 5, –VS = 0
+VS to –VS ≤ 30
160
100
+VS – 2
+VS – 2
0.3
ⴞ1
+VS – 4
20
+VS = 5, –VS = 0
+VS to –VS ≤ 30
300
+VS – 2
+VS + 2
0.3
ⴞ1
+VS – 4
20
Min
ⴞ3
ⴞ0.05
ⴞ1.5
10
247.3
(Temperature in °C) ×
40.44 µV/°C
0.1
–10
+50
–VS – 0.15
–VS – 4
10
10
ⴞ1
+VS – 4
160
100
36
+VS
+VS
–VS – 0.15
–VS
ⴞ1
ⴞ0.025
ⴞ0.75
10
0.3
+VS = 5, –VS = 0
+VS to –VS ≤ 30
AD595A
Typ
Max
Min
+VS = 5, –VS = 0
+VS to –VS ≤ 30
300
160
100
µV
µA
mV
Volts
mV/V
mV/V
Volts
Volts
mA
kHz
Volts
µA max
Volts
mA
Volts
Volts
300
µA
µA
AD595CD
AD595CQ
NOTES
1
Calibrated for minimum error at +25°C using a thermocouple sensitivity of 51.7 µV/°C. Since a J type thermocouple deviates from this straight line approximation, the AD594 will normally
read 3.1 mV when the measuring junction is at 0°C. The AD595 will similarly read 2.7 mV at 0°C.
2
Defined as the slope of the line connecting the AD594/AD595 errors measured at 0°C and 50°C ambient temperature.
3
Pin 8 shorted to Pin 9.
4
Current Sink Capability in single supply configuration is limited to current drawn to ground through a 50 kΩ resistor at output voltages below 2.5 V.
5
–VS must not exceed –16.5 V.
Specifications shown in boldface are tested on all production units at final electrical test. Results from those tests are used to calculate outgoing quality levels. All min and max specifications
are guaranteed, although only those shown in boldface are tested on all production units.
Specifications subject to change without notice.
compensated signal, the following transfer functions should be
used to determine the actual output voltages:
AD594 output = (Type J Voltage + 16 µV) × 193.4
AD595 output = (Type K Voltage + 11 µV) × 247.3 or conversely:
Type J voltage = (AD594 output/193.4) – 16 µV
Type K voltage = (AD595 output/247.3) – 11 µV
INTERPRETING AD594/AD595 OUTPUT VOLTAGES
To achieve a temperature proportional output of 10 mV/°C and
accurately compensate for the reference junction over the rated
operating range of the circuit, the AD594/AD595 is gain trimmed
to match the transfer characteristic of J and K type thermocouples
at 25°C. For a type J output in this temperature range the TC is
51.70 µV/°C, while for a type K it is 40.44 µV/°C. The resulting
gain for the AD594 is 193.4 (10 mV/°C divided by 51.7 µV/°C)
and for the AD595 is 247.3 (10 mV/°C divided by 40.44 µV/°C).
In addition, an absolute accuracy trim induces an input offset to
the output amplifier characteristic of 16 µV for the AD594 and
11 µV for the AD595. This offset arises because the AD594/
AD595 is trimmed for a 250 mV output while applying a 25°C
thermocouple input.
Because a thermocouple output voltage is nonlinear with respect
to temperature, and the AD594/AD595 linearly amplifies the
Table I lists the ideal AD594/AD595 output voltages as a function of Celsius temperature for type J and K ANSI standard
thermocouples, with the package and reference junction at
25°C. As is normally the case, these outputs are subject to calibration, gain and temperature sensitivity errors. Output values
for intermediate temperatures can be interpolated, or calculated
using the output equations and ANSI thermocouple voltage
tables referred to zero degrees Celsius. Due to a slight variation
in alloy content between ANSI type J and DIN FE-CUNI
–2–
REV. C
AD594/AD595
Table I. Output Voltage vs. Thermocouple Temperature (Ambient +25°C, VS = –5 V, +15 V)
Thermocouple
Temperature
°C
Type J
Voltage
mV
AD594
Output
mV
Type K
Voltage
mV
AD595
Output
mV
–200
–180
–160
–140
–120
–7.890
–7.402
–6.821
–6.159
–5.426
–1523
–1428
–1316
–1188
–1046
–5.891
–5.550
–5.141
–4.669
–4.138
–1454
–1370
–1269
–1152
–1021
–100
–80
–60
–40
–20
–4.632
–3.785
–2.892
–1.960
–.995
–893
–729
–556
–376
–189
–3.553
–2.920
–2.243
–1.527
–.777
–10
0
10
20
25
–.501
0
.507
1.019
1.277
–94
3.1
101
200
250
30
40
50
60
80
1.536
2.058
2.585
3.115
4.186
100
120
140
160
180
Type J
Voltage
mV
AD594
Output
mV
Type K
Voltage
mV
AD595
Output
mV
500
520
540
560
580
27.388
28.511
29.642
30.782
31.933
5300
5517
5736
5956
6179
20.640
21.493
22.346
23.198
24.050
5107
5318
5529
5740
5950
–876
–719
–552
–375
–189
600
620
640
660
680
33.096
34.273
35.464
36.671
37.893
6404
6632
6862
7095
7332
24.902
25.751
26.599
27.445
28.288
6161
6371
6581
6790
6998
–.392
0
.397
.798
1.000
–94
2.7
101
200
250
700
720
740
750
760
39.130
40.382
41.647
42.283
–
7571
7813
8058
8181
–
29.128
29.965
30.799
31.214
31.629
7206
7413
7619
7722
7825
300
401
503
606
813
1.203
1.611
2.022
2.436
3.266
300
401
503
605
810
780
800
820
840
860
–
–
–
–
–
–
–
–
–
–
32.455
33.277
34.095
34.909
35.718
8029
8232
8434
8636
8836
5.268
6.359
7.457
8.560
9.667
1022
1233
1445
1659
1873
4.095
4.919
5.733
6.539
7.338
1015
1219
1420
1620
1817
880
900
920
940
960
–
–
–
–
–
–
–
–
–
–
36.524
37.325
38.122
38.915
39.703
9035
9233
9430
9626
9821
200
220
240
260
280
10.777
11.887
12.998
14.108
15.217
2087
2302
2517
2732
2946
8.137
8.938
9.745
10.560
11.381
2015
2213
2413
2614
2817
980
1000
1020
1040
1060
–
–
–
–
–
–
–
–
–
–
40.488
41.269
42.045
42.817
43.585
10015
10209
10400
10591
10781
300
320
340
360
380
16.325
17.432
18.537
19.640
20.743
3160
3374
3588
3801
4015
12.207
13.039
13.874
14.712
15.552
3022
3227
3434
3641
3849
1080
1100
1120
1140
1160
–
–
–
–
–
–
–
–
–
–
44.439
45.108
45.863
46.612
47.356
10970
11158
11345
11530
11714
400
420
440
460
480
21.846
22.949
24.054
25.161
26.272
4228
4441
4655
4869
5084
16.395
17.241
18.088
18.938
19.788
4057
4266
4476
4686
4896
1180
1200
1220
1240
1250
–
–
–
–
–
–
–
–
–
–
48.095
48.828
49.555
50.276
50.633
11897
12078
12258
12436
12524
thermocouples Table I should not be used in conjunction with
European standard thermocouples. Instead the transfer function
given previously and a DIN thermocouple table should be used.
ANSI type K and DIN NICR-NI thermocouples are composed
CONSTANTAN
(ALUMEL)
+5V
10mV/8C
Thermocouple
Temperature
°C
SINGLE AND DUAL SUPPLY CONNECTIONS
The AD594/AD595 is a completely self-contained thermocouple
conditioner. Using a single +5 V supply the interconnections
shown in Figure 1 will provide a direct output from a type J
thermocouple (AD594) or type K thermocouple (AD595) measuring from 0°C to +300°C.
Figure 1. Basic Connection, Single Supply Operation
Any convenient supply voltage from +5 V to +30 V may be
used, with self-heating errors being minimized at lower supply
levels. In the single supply configuration the +5 V supply connects to Pin 11 with the V– connection at Pin 7 strapped to
power and signal common at Pin 4. The thermocouple wire inputs connect to Pins 1 and 14 either directly from the measuring
point or through intervening connections of similar thermocouple wire type. When the alarm output at Pin 13 is not used it
should be connected to common or –V. The precalibrated feedback network at Pin 8 is tied to the output at Pin 9 to provide a
10 mV/°C nominal temperature transfer characteristic.
of identical alloys and exhibit similar behavior. The upper temperature limits in Table I are those recommended for type J and
type K thermocouples by the majority of vendors.
By using a wider ranging dual supply, as shown in Figure 2, the
AD594/AD595 can be interfaced to thermocouples measuring
both negative and extended positive temperatures.
13
14
12
11
10
9
8
OVERLOAD
DETECT
AD594/
AD595
+A
G
G
+TC
IRON
(CHROMEL)
1
2
3
4
5
ICE
POINT
COMP. –TC
6
7
COMMON
REV. C
–3–
AD594/AD595
The printed circuit board layout shown also provides for placement of optional alarm load resistors, recalibration resistors and
a compensation capacitor to limit bandwidth.
+5V TO +30V
CONSTANTAN
(ALUMEL)
14
13
12
11
9
10
8
OVERLOAD
DETECT
AD594/
AD595
G
G
+TC
IRON
(CHROMEL)
1
2
To ensure secure bonding the thermocouple wire should be
cleaned to remove oxidation prior to soldering. Noncorrosive
rosin flux is effective with iron, constantan, chromel and alumel
and the following solders: 95% tin-5% antimony, 95% tin-5%
silver or 90% tin-10% lead.
+A
3
4
5
ICE
POINT –TC
COMP.
6
SPAN OF
5V TO 30V
7
FUNCTIONAL DESCRIPTION
The AD594 behaves like two differential amplifiers. The outputs are summed and used to control a high gain amplifier, as
shown in Figure 4.
COMMON
0V TO –25V
Figure 2. Dual Supply Operation
–IN
14
With a negative supply the output can indicate negative temperatures and drive grounded loads or loads returned to positive
voltages. Increasing the positive supply from 5 V to 15 V extends the output voltage range well beyond the 750°C
temperature limit recommended for type J thermocouples
(AD594) and the 1250°C for type K thermocouples (AD595).
G
+C
–IN
+ALM
–ALM
COMMON
–T
–C
V–
8
VOUT
+A
ICE
POINT
COMP. –TC
G
1
2
3
4
5
6
7
+IN
+C
+T
COM
–T
–C
V–
In addition to the feedback signal, a cold junction compensation
voltage is applied to the right-hand differential amplifier. The
compensation is a differential voltage proportional to the Celsius
temperature of the AD594/AD595. This signal disturbs the differential input so that the amplifier output must adjust to restore
the input to equal the applied thermocouple voltage.
COMP
7
FB
8
In normal operation the main amplifier output, at Pin 9, is connected to the feedback network, at Pin 8. Thermocouple signals
applied to the floating input stage, at Pins 1 and 14, are amplified by gain G of the differential amplifier and are then further
amplified by gain A in the main amplifier. The output of the
main amplifier is fed back to a second differential stage in an inverting connection. The feedback signal is amplified by this
stage and is also applied to the main amplifier input through a
summing circuit. Because of the inversion, the amplifier causes
the feedback to be driven to reduce this difference signal to a
small value. The two differential amplifiers are made to match
and have identical gains, G. As a result, the feedback signal that
must be applied to the right-hand differential amplifier will precisely match the thermocouple input signal when the difference
signal has been reduced to zero. The feedback network is trimmed so that the effective gain to the output, at Pins 8 and 9, results in a voltage of 10 mV/°C of thermocouple excitation.
CONSTANTAN
(ALUMEL)
14
VO
9
Figure 4. AD594/AD595 Block Diagram
A method that provides for thermal equilibrium is the printed
circuit board connection layout illustrated in Figure 3.
1
COMP
10
+TC
The isothermal terminating connections of a pair of thermocouple wires forms an effective reference junction. This junction
must be kept at the same temperature as the AD594/AD595 for
the internal cold junction compensation to be effective.
+IN
V+
11
AD594/AD595
THERMOCOUPLE CONNECTIONS
+T
+ALM
12
OVERLOAD
DETECT
Common-mode voltages on the thermocouple inputs must remain
within the common-mode range of the AD594/AD595, with a
return path provided for the bias currents. If the thermocouple
is not remotely grounded, then the dotted line connections in
Figures 1 and 2 are recommended. A resistor may be needed in
this connection to assure that common-mode voltages induced
in the thermocouple loop are not converted to normal mode.
IRON
(CHROMEL)
–ALM
13
The compensation is applied through the gain scaling resistors
so that its effect on the main output is also 10 mV/°C. As a
result, the compensation voltage adds to the effect of the thermocouple voltage a signal directly proportional to the difference
between 0°C and the AD594/AD595 temperature. If the thermocouple reference junction is maintained at the AD594/AD595
temperature, the output of the AD594/AD595 will correspond
to the reading that would have been obtained from amplification
of a signal from a thermocouple referenced to an ice bath.
V+
Figure 3. PCB Connections
Here the AD594/AD595 package temperature and circuit board
are thermally contacted in the copper printed circuit board
tracks under Pins 1 and 14. The reference junction is now composed of a copper-constantan (or copper-alumel) connection
and copper-iron (or copper-chromel) connection, both of which
are at the same temperature as the AD594/AD595.
–4–
REV. C
AD594/AD595
The AD594/AD595 also includes an input open circuit detector
that switches on an alarm transistor. This transistor is actually a
current-limited output buffer, but can be used up to the limit as
a switch transistor for either pull-up or pull-down operation of
external alarms.
The ice point compensation network has voltages available with
positive and negative temperature coefficients. These voltages
may be used with external resistors to modify the ice point compensation and recalibrate the AD594/AD595 as described in the
next column.
The feedback resistor is separately pinned out so that its value
can be padded with a series resistor, or replaced with an external
resistor between Pins 5 and 9. External availability of the feedback
resistor allows gain to be adjusted, and also permits the AD594/
AD595 to operate in a switching mode for setpoint operation.
CAUTIONS:
The temperature compensation terminals (+C and –C) at Pins 2
and 6 are provided to supply small calibration currents only. The
AD594/AD595 may be permanently damaged if they are
grounded or connected to a low impedance.
The AD594/AD595 is internally frequency compensated for feedback ratios (corresponding to normal signal gain) of 75 or more.
If a lower gain is desired, additional frequency compensation
should be added in the form of a 300 pF capacitor from Pin 10
to the output at Pin 9. As shown in Figure 5 an additional 0.01 µF
capacitor between Pins 10 and 11 is recommended.
AD594/
AD595
VO 9
300pF
COMP 10
0.01mF
+V 11
Figure 5. Low Gain Frequency Compensation
RECALIBRATION PRINCIPLES AND LIMITATIONS
The ice point compensation network of the AD594/AD595
produces a differential signal which is zero at 0°C and corresponds to the output of an ice referenced thermocouple at the
temperature of the chip. The positive TC output of the circuit is
proportional to Kelvin temperature and appears as a voltage at
+T. It is possible to decrease this signal by loading it with a
resistor from +T to COM, or increase it with a pull-up resistor
from +T to the larger positive TC voltage at +C. Note that
adjustments to +T should be made by measuring the voltage which
tracks it at –T. To avoid destabilizing the feedback amplifier the
measuring instrument should be isolated by a few thousand
ohms in series with the lead connected to –T.
1
+IN
+T
3
this terminal can be produced with a resistor between –C and
–T to balance an increase in +T, or a resistor from –T to COM
to offset a decrease in +T.
If the compensation is adjusted substantially to accommodate a
different thermocouple type, its effect on the final output voltage will increase or decrease in proportion. To restore the
nominal output to 10 mV/°C the gain may be adjusted to match
the new compensation and thermocouple input characteristics.
When reducing the compensation the resistance between –T
and COM automatically increases the gain to within 0.5% of the
correct value. If a smaller gain is required, however, the nominal
47 kΩ internal feedback resistor can be paralleled or replaced
with an external resistor.
Fine calibration adjustments will require temperature response
measurements of individual devices to assure accuracy. Major
reconfigurations for other thermocouple types can be achieved
without seriously compromising initial calibration accuracy, so
long as the procedure is done at a fixed temperature using the
factory calibration as a reference. It should be noted that intermediate recalibration conditions may require the use of a
negative supply.
EXAMPLE: TYPE E RECALIBRATION—AD594/AD595
Both the AD594 and AD595 can be configured to condition the
output of a type E (chromel-constantan) thermocouple. Temperature characteristics of type E thermocouples differ less from
type J, than from type K, therefore the AD594 is preferred for
recalibration.
While maintaining the device at a constant temperature follow
the recalibration steps given here. First, measure the device
temperature by tying both inputs to common (or a selected
common-mode potential) and connecting FB to VO. The AD594
is now in the stand alone Celsius thermometer mode. For this
example assume the ambient is 24°C and the initial output VO
is 240 mV. Check the output at VO to verify that it corresponds
to the temperature of the device.
Next, measure the voltage –T at Pin 5 with a high impedance
DVM (capacitance should be isolated by a few thousand ohms
of resistance at the measured terminals). At 24°C the –T voltage
will be about 8.3 mV. To adjust the compensation of an AD594
to a type E thermocouple a resistor, R1, should be connected
between +T and +C, Pins 2 and 3, to raise the voltage at –T by
the ratio of thermocouple sensitivities. The ratio for converting a
type J device to a type E characteristic is:
r (AD594) =(60.9 µV/°C)/(51.7 µV/°C)= 1.18
Thus, multiply the initial voltage measured at –T by r and experimentally determine the R1 value required to raise –T to that
level. For the example the new –T voltage should be about 9.8 mV.
The resistance value should be approximately 1.8 kΩ.
Figure 6. Decreased Sensitivity Adjustment
The zero differential point must now be shifted back to 0°C.
This is accomplished by multiplying the original output voltage
VO by r and adjusting the measured output voltage to this value
by experimentally adding a resistor, R2, between –C and –T,
Pins 5 and 6. The target output value in this case should be
about 283 mV. The resistance value of R2 should be approximately 240 kΩ.
Changing the positive TC half of the differential output of the
compensation scheme shifts the zero point away from 0°C. The
zero can be restored by adjusting the current flow into the negative input of the feedback amplifier, the –T pin. A current into
Finally, the gain must be recalibrated such that the output VO
indicates the device’s temperature once again. Do this by adding
a third resistor, R3, between FB and –T, Pins 8 and 5. VO should
now be back to the initial 240 mV reading. The resistance value
14 –IN
AD594/
AD595
COM 4
8 FB
9
REV. C
VO
–T
5
–5–
AD594/AD595
of R3 should be approximately 280 kΩ. The final connection
diagram is shown in Figure 7. An approximate verification of
the effectiveness of recalibration is to measure the differential
gain to the output. For type E it should be 164.2.
1 +IN
THERMAL ENVIRONMENT EFFECTS
The inherent low power dissipation of the AD594/AD595 and
the low thermal resistance of the package make self-heating
errors almost negligible. For example, in still air the chip to ambient thermal resistance is about 80°C/watt (for the D package).
At the nominal dissipation of 800 µW the self-heating in free air
is less than 0.065°C. Submerged in fluorinert liquid (unstirred)
the thermal resistance is about 40°C/watt, resulting in a selfheating error of about 0.032°C.
COM 4
14 –IN
+T 3
AD594/
AD595
R1
+C 2
SETPOINT CONTROLLER
The AD594/AD595 can readily be connected as a setpoint
controller as shown in Figure 9.
–C 6
9 VO
R2
–T
8 FB
5
HEATER
DRIVER
R3
CONSTANTAN
HEATER (ALUMEL)
Figure 7. Type E Recalibration
When implementing a similar recalibration procedure for the
AD595 the values for R1, R2, R3 and r will be approximately
650 Ω, 84 kΩ, 93 kΩ and 1.51, respectively. Power consumption will increase by about 50% when using the AD595 with
type E inputs.
SETPOINT
VOLTAGE
INPUT
+5V
14
13
12
11
10
9
8
20MV
(OPTIONAL)
FOR
HYSTERESIS
OVERLOAD
DETECT
AD594/
AD595
+A
G
G
+TC
Note that during this procedure it is crucial to maintain the
AD594/AD595 at a stable temperature because it is used as the
temperature reference. Contact with fingers or any tools not at
ambient temperature will quickly produce errors. Radiational
heating from a change in lighting or approach of a soldering iron
must also be guarded against.
IRON
(CHROMEL)
TEMPERATURE
CONTROLLED
REGION
1
2
3
4
5
ICE
POINT –TC
COMP.
6
7
COMMON
Figure 9. Setpoint Controller
The thermocouple is used to sense the unknown temperature
and provide a thermal EMF to the input of the AD594/AD595.
The signal is cold junction compensated, amplified to 10 mV/°C
and compared to an external setpoint voltage applied by the
user to the feedback at Pin 8. Table I lists the correspondence
between setpoint voltage and temperature, accounting for the
nonlinearity of the measurement thermocouple. If the setpoint
temperature range is within the operating range (–55°C to
+125°C) of the AD594/AD595, the chip can be used as the
transducer for the circuit by shorting the inputs together and
utilizing the nominal calibration of 10 mV/°C. This is the centigrade thermometer configuration as shown in Figure 13.
USING TYPE T THERMOCOUPLES WITH THE AD595
Because of the similarity of thermal EMFs in the 0°C to +50°C
range between type K and type T thermocouples, the AD595
can be directly used with both types of inputs. Within this ambient temperature range the AD595 should exhibit no more than
an additional 0.2°C output calibration error when used with
type T inputs. The error arises because the ice point compensator is trimmed to type K characteristics at 25°C. To calculate
the AD595 output values over the recommended –200°C to
+350°C range for type T thermocouples, simply use the ANSI
thermocouple voltages referred to 0°C and the output equation
given on page 2 for the AD595. Because of the relatively large
nonlinearities associated with type T thermocouples the output
will deviate widely from the nominal 10 mV/°C. However, cold
junction compensation over the rated 0°C to +50°C ambient
will remain accurate.
In operation if the setpoint voltage is above the voltage corresponding to the temperature being measured the output swings
low to approximately zero volts. Conversely, when the temperature rises above the setpoint voltage the output switches to
the positive limit of about 4 volts with a +5 V supply. Figure
9 shows the setpoint comparator configuration complete with a
heater element driver circuit being controlled by the AD594/
AD595 toggled output. Hysteresis can be introduced by injecting a current into the positive input of the feedback amplifier
when the output is toggled high. With an AD594 about 200 nA
into the +T terminal provides 1°C of hysteresis. When using a
single 5 V supply with an AD594, a 20 MΩ resistor from VO to
+T will supply the 200 nA of current when the output is forced
high (about 4 V). To widen the hysteresis band decrease the
resistance connected from VO to +T.
STABILITY OVER TEMPERATURE
Each AD594/AD595 is tested for error over temperature with
the measuring thermocouple at 0°C. The combined effects of
cold junction compensation error, amplifier offset drift and gain
error determine the stability of the AD594/AD595 output over
the rated ambient temperature range. Figure 8 shows an AD594/
AD595 drift error envelope. The slope of this figure has units
of °C/°C.
+0.68C
DRIFT ERROR
LOW = > T < SETPOINT
HIGH = > T > SETPOINT
TEMPERATURE
COMPARATOR OUT
0
258C
–0.68C
508C
TEMPERATURE OF AD594C/AD595C
Figure 8. Drift Error vs. Temperature
–6–
REV. C
AD594/AD595
ALARM CIRCUIT
In all applications of the AD594/AD595 the –ALM connection,
Pin 13, should be constrained so that it is not more positive
than (V+) – 4 V. This can be most easily achieved by connecting Pin 13 to either common at Pin 4 or V– at Pin 7. For most
applications that use the alarm signal, Pin 13 will be grounded
and the signal will be taken from +ALM on Pin 12. A typical
application is shown in Figure 10.
The alarm can be used with both single and dual supplies. It
can be operated above or below ground. The collector and emitter of the output transistor can be used in any normal switch
configuration. As an example a negative referenced load can be
driven from –ALM as shown in Figure 12.
+10V
CONSTANTAN
(ALUMEL)
14
In this configuration the alarm transistor will be off in normal
operation and the 20 k pull up will cause the +ALM output on
Pin 12 to go high. If one or both of the thermocouple leads are
interrupted, the +ALM pin will be driven low. As shown in Figure 10 this signal is compatible with the input of a TTL gate
which can be used as a buffer and/or inverter.
13
12
11
10
9
8
AD594/
AD595
+A
G
G
+TC
IRON
(CHROMEL)
1
2
3
4
5
ICE
POINT –TC
COMP.
6
7
+5V
20kV
13
14
12
11
9
10
GND
ALARM
TTL GATE
ALARM OUT
CONSTANTAN
(ALUMEL)
10mV/8C
OVERLOAD
DETECT
ALARM
RELAY
10mV/8C
8
–12V
OVERLOAD
DETECT
AD594/
AD595
Figure 12. –ALM Driving A Negative Referenced Load
+A
G
G
+TC
IRON
(CHROMEL)
1
2
3
4
5
ICE
POINT –TC
COMP.
6
7
GND
Figure 10. Using the Alarm to Drive a TTL Gate
(“Grounded’’ Emitter Configuration)
Since the alarm is a high level output it may be used to directly
drive an LED or other indicator as shown in Figure 11.
V+
LED
CONSTANTAN
(ALUMEL)
13
Additionally, the AD594/AD595 can be configured to produce
an extreme upscale or downscale output in applications where
an extra signal line for an alarm is inappropriate. By tying either
of the thermocouple inputs to common most runaway control
conditions can be automatically avoided. A +IN to common
connection creates a downscale output if the thermocouple opens,
while connecting –IN to common provides an upscale output.
CELSIUS THERMOMETER
270V
14
The collector (+ALM) should not be allowed to become more
positive than (V–) +36 V, however, it may be permitted to be
more positive than V+. The emitter voltage (–ALM) should be
constrained so that it does not become more positive than 4
volts below the V+ applied to the circuit.
10mV/8C
12
11
10
9
8
The AD594/AD595 may be configured as a stand-alone Celsius
thermometer as shown in Figure 13.
OVERLOAD
DETECT
AD594/
AD595
14
G
G
+TC
IRON
(CHROMEL)
1
2
+5V TO +15V
+A
3
4
5
12
11
9
8
AD594/
AD595
+A
7
G
G
COMMON
+TC
Figure 11. Alarm Directly Drives LED
A 270 Ω series resistor will limit current in the LED to 10 mA,
but may be omitted since the alarm output transistor is current
limited at about 20 mA. The transistor, however, will operate in
a high dissipation mode and the temperature of the circuit will
rise well above ambient. Note that the cold junction compensation will be affected whenever the alarm circuit is activated. The
time required for the chip to return to ambient temperature will
depend on the power dissipation of the alarm circuit, the nature
of the thermal path to the environment and the alarm duration.
REV. C
10
OVERLOAD
DETECT
ICE
POINT –TC
COMP.
6
13
OUTPUT
10mV/8C
1
2
3
4
5
ICE
POINT –TC
COMP.
6
7
GND
0 TO –15V
Figure 13. AD594/AD595 as a Stand-Alone Celsius
Thermometer
Simply omit the thermocouple and connect the inputs (Pins 1
and 14) to common. The output now will reflect the compensation voltage and hence will indicate the AD594/AD595
temperature with a scale factor of 10 mV/°C. In this three terminal, voltage output, temperature sensing mode, the AD594/
AD595 will operate over the full military –55°C to +125°C temperature range.
–7–
AD594/AD595
and to arrange its output voltage so that it corresponds to a thermocouple referred to 0°C. This voltage is simply added to the
thermocouple voltage and the sum then corresponds to the standard voltage tabulated for an ice-point referenced thermocouple.
Thermocouples are economical and rugged; they have reasonably good long-term stability. Because of their small size, they
respond quickly and are good choices where fast response is important. They function over temperature ranges from cryogenics
to jet-engine exhaust and have reasonable linearity and accuracy.
V1'
Because the number of free electrons in a piece of metal depends on both temperature and composition of the metal, two
pieces of dissimilar metal in isothermal and contact will exhibit
a potential difference that is a repeatable function of temperature, as shown in Figure 14. The resulting voltage depends on
the temperatures, T1 and T2, in a repeatable way.
Cu
CONSTANTAN
V1' = V1
FOR PROPERLY
SCALED V3' = f(T3)
V1
C731g–0–11/99
THERMOCOUPLE BASICS
Cu
CuNi–
V2
T3
V3'
T1
V1
IRON
Cu
CONSTANTAN
Figure 15. Substitution of Measured Reference
Temperature for Ice Point Reference
Cu
CONSTANTAN
T2
T1
The temperature sensitivity of silicon integrated circuit transistors is quite predictable and repeatable. This sensitivity is
exploited in the AD594/AD595 to produce a temperature related voltage to compensate the reference of “cold” junction of a
thermocouple as shown in Figure 16.
IRON
ICE POINT
REFERENCE
UNKNOWN
TEMPERATURE
Figure 14. Thermocouple Voltage with 0°C Reference
Since the thermocouple is basically a differential rather than
absolute measuring device, a know reference temperature is
required for one of the junctions if the temperature of the other
is to be inferred from the output voltage. Thermocouples made
of specially selected materials have been exhaustively characterized in terms of voltage versus temperature compared to primary
temperature standards. Most notably the water-ice point of 0°C
is used for tables of standard thermocouple performance.
T3
CONSTANTAN
T1
An alternative measurement technique, illustrated in Figure 15,
is used in most practical applications where accuracy requirements
do not warrant maintenance of primary standards. The reference
junction temperature is allowed to change with the environment
of the measurement system, but it is carefully measured by some
type of absolute thermometer. A measurement of the thermocouple voltage combined with a knowledge of the reference
temperature can be used to calculate the measurement junction
temperature. Usual practice, however, is to use a convenient
thermoelectric method to measure the reference temperature
Cu
IRON
Cu
Figure 16. Connecting Isothermal Junctions
Since the compensation is at the reference junction temperature,
it is often convenient to form the reference “junction” by connecting directly to the circuit wiring. So long as these connections
and the compensation are at the same temperature no error will
result.
OUTLINE DIMENSIONS
Dimensions shown in inches and (mm).
Cerdip (Q) Package
0.77 ±0.015
(19.55 ±0.39)
0.430 (10.92)
0.040
(1.02) R
14
8
0.265 0.290 ±0.010
(6.73) (7.37 ±0.25)
1
14
8
0.260 ±0.020
(6.6 ±0.51)
0.310
(7.87)
7
1
PIN 1
0.31 ±0.01
(7.87 ±0.25)
0.700 ±0.010
(17.78 ±0.25)
0.035 ±0.010
(0.89 ±0.25)
(
7
PIN 1
0.095 (2.41)
0.085 (2.16)
0.125
(3.18)
MIN
0.047 ±0.007
+0.003 0.100
(1.19 ±0.18) 0.017 –0.002 (2.54)
BSC
0.43 +0.08
–0.05
PRINTED IN U.S.A.
TO-116 (D) Package
0.180 ±0.030
(4.57 ±0.76)
0.035 ±0.010
(0.889 ±0.254)
0.032
(0.812)
0.30 (7.62) REF
0.018
(0.457)
0.600 (15.24)
BSC
(
–8–
0.148 ±0.015
(3.76 ±0.38)
0.180 ±0.030
(4.57 ±0.76)
0.125
3.175)
MIN
0.01 ±0.002
(0.25 ±0.05)
0.300 (7.62)
REF
SEATING
PLANE
0.100
(2.54)
BSC
15°
0°
0.010 ±0.001
(0.254 ±0.025)
REV. C