AD ADT70GR

a
FEATURES
PRTD Temperature Measurement Range
Typical IC Measurement Error ⴞ1ⴗC
Includes Two Matched Current Sources
Rail-to-Rail Output Instrumentation Amp
Uncommitted, Rail-to-Rail Output Op Amp
On-Board ⴙ2.5 V Reference
Temperature Coefficient ⴞ25 ppm/ⴗC
ⴙ5 V or ⴞ5 V Operation
Supply Current 4 mA Max
10 ␮A Max in Shutdown
APPLICATIONS
Temperature Controllers
Portable Instrumentation
Temperature Acquisition Cards
GENERAL DESCRIPTION
The ADT70 provides excitation and signal conditioning for
resistance-temperature devices (RTDs). It is ideally suited for
1 kΩ Platinum RTDs (PRTDs), allowing a very wide range of
temperature measurement. It can also easily interface to 100 Ω
PRTDs. Using a remote, low cost thin-film PRTD, the ADT70
can measure temperature in the range of –50°C to +500°C.
With high performance platinum elements, the temperature
change can be extended to 1000°C. Accuracy of the ADT70
and PRTD system over a –200°C to +1000°C temperature
range heavily depends on the quality of the PRTD. Typically
the ADT70 will introduce an error of only ± 1°C over the
transducer's temperature range, and the error may be trimmed
to zero at a single calibration point.
The ADT70 consists of two matched 1 mA (nominal) current
sources for transducer and reference resistor excitation, a precision rail-to-rail output instrumentation amplifier, a 2.5 V reference and an uncommitted rail-to-rail output op amp. The
ADT70 includes a shutdown function for battery powered
equipment, which reduces the quiescent current from 4 mA to
less than 10␣ µA. The ADT70 operates from either single +5 V
or ±5 V supplies. Gain or full-scale range for the PRTD and
ADT70 system is set by a precision external resistor connected
to the instrumentation amplifier. The uncommitted op amp may
be used for scaling the internal voltage reference, providing a
“PRTD open” signal or “over-temperature” warning, a heater
switching signal, or other external conditioning determined by
the user.
The ADT70 is specified for operation from ⴚ40°C to ⴙ125°C
and is available in 20-lead DIP and SO packages.
PRTD Conditioning Circuit
and Temperature Controller
ADT70*
FUNCTIONAL BLOCK DIAGRAM
NULLA
NULLB
BIAS 2.5VREFOUT
ADT70
OUTOA
IOUTA
MATCHED
CURRENT
SOURCES
+INOA
IOUTB
2.5V
REF
+INIA
ⴚINOA
INST
AMP
SHUTDOWN
SHUTDOWN
ⴚINIA
OUTIA AGND ⴚVS
RGA RGB GND
SENSE
DGND
PIN CONFIGURATIONS
20-Lead P-DIP
(N Suffix)
–VS 1
20 +VS
AGND 2
19 VOUT OA
VREFOUT 3
18 –INOA
BIAS 4
17 +INOA
ADT70
NULLA 5
16 SHUTDOWN
TOP VIEW
NULLB 6 (Not to Scale) 15 DGND
IOUTA 7
14 VOUT IA
IOUTB 8
13 GND SENSE
–INIA 9
12 RGB
11 RGA
+INIA 10
a
20-Lead SOIC
(R Suffix)
–VS 1
20 +VS
AGND 2
19 VOUT OA
VREFOUT 3
18 –INOA
BIAS 4
NULLA 5
17 +INOA
ADT70
16 SHUTDOWN
TOP VIEW
NULLB 6 (Not to Scale) 15 DGND
IOUTA 7
14 VOUT IA
IOUTB 8
13 GND SENSE
2 INIA 9
*Patent pending.
+VS
12 RGB
11 RGA
1 INIA 10
a
REV. 0
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., 1998
ADT70–SPECIFICATIONS (V = ⴙ5 V, ⴚ40ⴗC ≤ T ≤ ⴙ125ⴗC unless otherwise noted)
A
S
Parameter
Symbol
SYSTEM CONFIGURATION
Gain
Line Regulation
CURRENT SOURCES
Output Current
Output Current Mismatch
Voltage Compliance
INSTRUMENTATION AMP
Input Offset Voltage
I Q1, IQ2
I Q1 – IQ2
Conditions
Min
Typ
Max
Units
RL = 1 kΩ
1.234
–2.25
1.295
⫾0.35
1.364
2.25
mV/Ω
%/V
–2
0.9
⫾0.5
–V S to +VS – 1.5
2
mA
µA
V
⫾150
⫾100
⫾5
⫾3
⫾40
⫾30
⫾1
85
700
500
12
7
75
60
3
RL = 1 kΩ
RL = 1 kΩ
VIOS
TA = +25°C
Output Offset Voltage
VOOS
Input Bias Current
IB
Input Offset Current
Common-Mode Rejection
Output Voltage Swing
Power Supply Rejection Ratio
I OS
CMR
VOUT
PSRR
TA = +25°C
TA = +25°C
VCM = 0.5 V to 3 V
RL = ∞ , VS = ⫾5 V
+ 4.5 V ≤ VS ≤ ⫾5.5 V
VOLTAGE REFERENCE
Output Voltage
TA = +25°C
I L = 0 mA to 1 mA
Load Regulation
Temperature Coefficient
Line Regulation
OPERATIONAL AMPLIFIER
Input Offset Voltage
VIOA
TCVIOA
IB
TA = +25°C
Input Offset Current
Open-Loop Voltage Gain
Output Voltage Swing
Common-Mode Rejection Ratio
I OS
AVOL
VOUTA
CMRR
Power Supply Rejection Ratio
Slew Rate
PSRR
SR
SHUTDOWN INPUT
Input Low Voltage
Input High Voltage
POWER SUPPLY
Supply Current
Shutdown Supply Current
Supply Voltage
Dual Supply Voltage
RL = ∞
RL = ∞
VCM = 1 V to 4 V
TA = +25°C
⫾3 V ≤ VS ≤ ⫾6 V
TA = +25°C, AV = 1,
VIN = 0 V to 4 V
VIL
VIH
I SY
I SD
VS
⫾0.5
+V S – 25
2.5
µV
µV
mV
mV
nA
nA
nA
dB
mV
mV/V
2.485
2.49
2.5
2.5
250
⫾10
⫾75
2.515
2.51
V
V
ppm/mA
ppm/°C
ppm/V
–1,000
–800
⫾400
⫾200
1
⫾40
⫾30
⫾1
2
1,000
800
µV
µV
µV/°C
nA
nA
nA
V/µV
mV
dB
dB
dB
V/µs
+ 4.5 V ≤ VS ≤ +5.5 V
TA = +25°C
Input Offset Voltage Drift
Input Bias Current
–700
–500
–12
–7
–75
–60
–3
65
–V S + 25
–2.5
–75
–60
–3
–V S + 10
85
88
100
75
60
3
+V S – 10
105
110
150
0.17
0.8
V
V
5
30
+5.5
⫾5.5
mA
µA
V
V
2.4
RL = 1 kΩ
3.5
10
+4.5
⫾4.5
Specifications subject to change without notice.
–2–
REV. 0
ADT70
ABSOLUTE MAXIMUM RATINGS*
ORDERING GUIDE
Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ⴙ16 V
Output Short-Circuit Duration . . . . . . . . . . . . . . . . . Indefinite
Storage Temperature Range
N, R Package . . . . . . . . . . . . . . . . . . . . . . ⴚ65°C to ⴙ150°C
Operating Temperature Range . . . . . . . . . . ⴚ40°C to ⴙ125°C
Junction Temperature Range
N, R Package . . . . . . . . . . . . . . . . . . . . . . ⴚ65°C to ⴙ125°C
Lead Temperature (Soldering, 60 sec) . . . . . . . . . . . . ⴙ300°C
Model
Temperature
Range
Package
ADT70GR
ADT70GN
ⴚ40°C to ⴙ125°C
ⴚ40°C to ⴙ125°C
20-Lead SOIC
20-Lead PDIP
TRANSISTOR COUNT: 158
NOTE
*Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only; functional operation of the
device at these or any other conditions above those listed in the operational sections
of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.
Package Type
␪JA*
␪JC
Units
20-Lead SOIC (R)
20-Lead PDIP (N)
74
102
24
31
°C/W
°C/W
NOTE
*
θJA is specified for device in socket/soldered on circuit board (worst case conditions).
CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily
accumulate on the human body and test equipment and can discharge without detection.
Although the ADT70 features proprietary ESD protection circuitry, permanent damage may
occur on devices subjected to high energy electrostatic discharges. Therefore, proper ESD
precautions are recommended to avoid performance degradation or loss of functionality.
REV. 0
–3–
WARNING!
ESD SENSITIVE DEVICE
ADT70
5
100
VS = +5V, NO LOAD
INSTRUMENTATION AMPLIFIER INPUT
OFFSET VOLTAGE – mV
4.5
SUPPLY CURRENT – mA
4
3.5
3
2.5
2
1.5
1
0.5
0
225
25
75
TEMPERATURE – 8C
20
0
220
240
260
280
225
25
75
TEMPERATURE – 8C
125
10
INSTRUMENTATION AMPLIFIER OUTPUT
OFFSET VOLTAGE – mV
VS = +5V, NO LOAD
1.35
SYSTEM GAIN – mV/V
40
Figure 4. Instrumentation Amplifier Input Offset Voltage
vs. Temperature
1.4
1.3
1.25
1.2
225
25
75
TEMPERATURE – 8C
4
2
0
22
24
26
28
225
25
75
TEMPERATURE – 8C
125
0
INSTRUMENTATION AMPLIFIER INPUT
BIAS CURRENT – nA
VS = +5V, NO LOAD
0.06
0.04
0.02
0
20.02
20.04
20.06
20.08
20.1
VS = +5V, NO LOAD
6
Figure 5. Instrumentation Amplifier Output Offset Voltage
vs. Temperature
0.1
0.08
8
210
125
Figure 2. System Gain vs. Temperature
SYSTEM GAIN PSRR – %/V
VS = +5V, NO LOAD
60
2100
125
Figure 1. Supply Current vs. Temperature
80
225
25
75
TEMPERATURE – 8C
VS = +5V, NO LOAD
220
230
240
250
260
270
125
Figure 3. Total System Gain PSRR vs. Temperature
210
225
25
75
TEMPERATURE – 8C
125
Figure 6. Instrumentation Amplifier Input Bias Current vs.
Temperature
–4–
REV. 0
ADT70
0
400
VS = +5V, NO LOAD
210
OP AMP INPUT BIAS CURRENT – nA
INSTRUMENTATION AMPLIFIER INPUT
OFFSET CURRENT – pA
500
300
200
100
0
2100
2200
2300
220
230
240
250
260
2400
2500
225
25
75
TEMPERATURE – 8C
270
125
Figure 7. Instrumentation Amplifier Input Offset Current
vs. Temperature
OP AMP INPUT OFFSET CURRENT – pA
INSTRUMENTATION AMPLIFIER GAIN – V/V
VS = +5V, NO LOAD
1.55
1.5
1.45
225
125
VS = +5V, NO LOAD
400
300
200
100
0
25
75
TEMPERATURE – 8C
125
225
25
75
TEMPERATURE – 8C
125
Figure 11. Op Amp Input Offset Current vs. Temperature
100
2.51
80
VS = +5V, NO LOAD
VS = +5V, NO LOAD
60
REFERENCE VOLTAGE – V
OP AMP INPUT OFFSET VOLTAGE – mV
25
75
TEMPERATURE – 8C
500
Figure 8. Instrumentation Amplifier Gain vs. Temperature
40
20
0
220
240
260
2.505
2.5
2.495
280
2100
225
25
75
TEMPERATURE – 8C
2.49
125
Figure 9. Op Amp Input Offset Voltage vs. Temperature
REV. 0
225
Figure 10. Op Amp Input Bias Current vs. Temperature
1.6
1.4
VS = +5V, NO LOAD
225
25
75
TEMPERATURE – 8C
125
Figure 12. Reference Voltage vs. Temperature
–5–
ADT70
950
VCC = 5V
VEE = 0
TA = +258C
DVCC,
SOURCING
CURRENT
100
DVEE,
SINKING
CURRENT
10
VCC = 5V
VEE = 0V
VREF = 2.5V
OUTPUT OF CURRENT SOURCE – mA
D RAIL OUTPUT VOLTAGE – mV
1000
940
+1258C
930
+258C
920
910
4.5
1
1
10
100
1k
2558C
10k
4.75
LOAD CURRENT – mA
5.0
5.25
SUPPLY VOLTAGE – Volts
5.5
Figure 16. Output of Current Source vs. Supply Voltage
Figure 13. Op Amp Output Voltage from Rails vs.
Load Current
140
2.52
2.515
120
2.51
100
CMRR – dB
2.505
2.5
80
AV = 14
60
2.495
AV = 1.4
40
2.49
20
2.485
0
1
2
3
4
5
6
LOAD CURRENT – mA
7
8
0
10
9
100
1k
10k
FREQUENCY – Hz
100k
Figure 17. In Amp CMRR vs. Frequency
Figure 14. Reference Voltage vs. Load Current
4
TA = +258C
VCM INAMP = 1V
VEE = GND
GAIN – dB
3.8
3.6
3.4
3.2
120
270
100
225
80
180
60
135
40
90
20
45
0
0
220
245
240
290
260
3
4.5
4.75
5.0
5.25
SUPPLY VOLTAGE – Volts
1M
280
100
5.5
PHASE MARGIN – Degrees
2.48
ISY, SUPPLY CURRENT – mA
REFERENCE VOLTAGE – V
VS = +5V, DUT SOURCING
2135
1k
10k
100k
FREQUENCY – Hz
1M
2180
10M
Figure 18. Op Amp Open Loop Gain and Phase vs.
Frequency
Figure 15. Supply Current vs. Supply Voltage
–6–
REV. 0
ADT70
120
140
120
100
100
80
60
CMRR – dB
PSRR – dB
80
+ PSRR
40
60
40
20
2 PSRR
20
0
220
10
100
1k
10k
FREQUENCY – Hz
100k
0
1M
Figure 19. In Amp PSRR vs. Frequency – AV = 1.4
10
100
1k
10k
FREQUENCY – Hz
100k
1M
Figure 22. Op Amp CMRR vs. Frequency
140
120
120
100
100
80
PSRR – dB
PSRR – dB
80
+ PSRR
60
40
+ PSRR
40
2 PSRR
2 PSRR
20
20
0
0
220
60
10
100
1k
10k
FREQUENCY – Hz
100k
220
1M
100
100
50
80
40
40
20
AV = 14
0
220
1M
30
20
AVCL = 10
10
0
AVCL = 0
AV = 1.4
210
240
1k
10k
100k
FREQUENCY – Hz
1M
220
100
10M
Figure 21. In Amp Closed Loop Gain vs. Frequency
REV. 0
100k
TA = +258C
VCC = 4V
VEE = 21V
AVCL = 100
60
260
100
1k
10k
FREQUENCY – Hz
Figure 23. Op Amp PSRR vs. Frequency
CLOSED LOOP GAIN – dB
CLOSED LOOP GAIN – dB
Figure 20. In Amp PSRR vs. Frequency – AV = 14
10
1k
10k
100k
FREQUENCY – Hz
1M
10M
Figure 24. Op Amp Closed Loop Gain vs. Frequency
–7–
ADT70
A basic physical property of any metal is that its electrical resistivity changes with temperature. Some metals are known to have
a very predictable and repeatable change of resistance for a
given change in temperature. An RTD is fabricated from one of
these metals to a nominal ohmic value at a specified temperature. By measuring its resistance at some unknown temperature
and comparing this value to the resistor’s nominal value, the
change in resistance is determined. Because the temperature vs.
resistance characteristics are also known, the change in temperature from the point initially specified can be calculated. This
makes the RTD a practical temperature sensor, which in its bare
form is a resistive element.
50
SYSTEM RESPONSE TIME – ms
VOUT OF IN AMP = 300mV
VCC = 5V SINGLE SUPPLY
40
TURNING ON
30
= LOW TO HIGH
VSHUTDOWN
20
TURNING OFF
10
= HIGH TO LOW
VSHUTDOWN
0
250
225
0
25
50
75
100
125
TEMPERATURE – 8C
Figure 25. System Response Time from Shutdown vs.
Temperature
FUNCTIONAL DESCRIPTION
The ADT70 provides excitation and signal conditioning for
resistance-temperature devices (RTDs). It is ideally suited for
1 kΩ Platinum RTDs (PRTDs), which allow a much wider
range of temperature measurement than silicon-based sensors.
Using a low cost PRTD, the ADT70 can measure temperatures
in the range of –50°C to +500°C.
The two main components in the ADT70 are the adjustable
current sources and the instrumentation amplifier. The current
sources provide matching excitation currents to the PRTD and
to the Reference Resistor. The instrumentation amplifier compares the voltage drop across both the PRTD and Reference
Resistor, and provides an amplified output signal voltage that is
proportional to temperature.
Besides the matching current sources and the instrumentation
amplifier, there is a general purpose op amp for any application
desired. The ADT70 comes with a +2.5 V reference on board.
NULLA
NULLB
BIAS 2.5VREFOUT
ADT70
+VS
OUTOA
IOUTA
MATCHED
CURRENT
SOURCES
+INOA
IOUTB
2.5V
REF
+INIA
INST
AMP
ⴚINOA
SHUTDOWN
SHUTDOWN
ⴚINIA
Several types of metal can be chosen for fabricating RTDs.
These include: Copper, balco (an iron-nickel alloy), nickel,
tungsten, iridium and platinum. Platinum is by far the most
popular material used, due to its nearly linear response to temperature, wide temperature operating range and superior longterm stability. The price of Platinum Resistance Temperature
Detectors (PRTDs) are becoming more competitive through the
wide use of thin-film-type resistive elements.
Temperature Coefficient of Resistance
The temperature coefficient (TC, also referred to as α) of an
RTD, describes the average resistance change per unit temperature from the ice point to the boiling point of water.
(
)
TCR Ω Ω °C =
R100 − R0
100°C × R0
R0 = Resistance of the sensor at 0°C
R100 = Resistance of the sensor at +100°C
TCR = Thermal Coefficient of Resistance.
For example, a platinum thermometer measuring 100 Ω at 0°C
and 138.5 Ω at 100°C, has TCR 0.00385 Ω/Ω/°C .
TCR =
138.5 Ω − 100 Ω
= 0.00385
100 Ω × 100°C
The larger the TCR, the greater the change in resistance for a
given change in temperature. The most common use of TCR is
to distinguish between curves for platinum, which is available
with TCRs ranging from 0.00375 to 0.003927. The highest
TCR indicates the highest purity platinum and is mandated by
ITS-90 for standard platinum thermometers.
Basically, TCRs must be properly matched when replacing RTDs
or connecting them to instruments. There are no technical advantages of one TCR over another in practical industrial applications. 0.00385 platinum is the most popular worldwide standard
and is available in both wire-wound and thin-film elements.
Understanding Error Source
RGA RGB GND
SENSE
OUTIA AGND ⴚVS
DGND
Figure 26. Block Diagram
What is an RTD?
The measurable temperature range of the ADT70 heavily depends on the characteristics of the resistance-temperature detector (RTD). Thus, it is important to choose the right RTD to
suit the actual application.
The ADT70 uses an instrumentation amplifier that amplifies the
difference in voltage drop across the RTD and the reference resistor, to output a voltage proportional to the measured temperature.
Thus, it is important to use a reference resistor that has stable resistance over temperature. The accuracy of the reference resistor
should be determined by the end application.
The lead resistance of wires connecting to the RTD and the reference resistor can add inaccuracy to the ADT70. If the reference
resistor is located close to the part, while the RTD is located at a
remote location connected by wires, the lead-wires’ resistance
–8–
REV. 0
ADT70
would contribute to the difference in voltage drop between the
RTD and the reference resistor. Thus, an error in reading the actual temperature could occur.
As shown above, this is a significant inaccuracy, especially for applications where the PRTD would be hundreds of feet away from
the ADT70. To reduce lead-wire error it is recommended to use
a larger sensitivity RTD; 1 kΩ instead of 100 Ω. Furthermore, in
the application circuit section, Figure 28 illustrates how to eliminate such error by using the part’s general purpose op amp.
Table I. Copper Wire Gauge Size to Resistance Table.
Lead-wire AWG
Ohms/foot at +25ºC
12
14
16
18
20
22
24
26
28
30
0.0016
0.0026
0.0041
0.0065
0.0103
0.0162
0.0257
0.0413
0.0651
0.1027
Self-Heating Effect
Another contributor to measurement error is the self-heating effect on the RTD. As with any resistive element, power is dissipated in an amount equal to the square of the excitation current
times the resistance of the element. The error contribution of the
heat generated by this power dissipation can easily be calculated.
For example, if the package thermal resistance is 50°C/W, the
RTD nominal resistance is 1 kΩ and the element is excited with a
1 mA current source, then the artificial increase in temperature
(ƼC) as a result of self-heating is:
∆°C = I 2 R0 × θ PACKAGE
From Table I the amount of lead-wire resistance effect in the
circuit can be estimated. For example, connect 100 feet of
AWG 22 wire to a 100 Ω Platinum RTD (PF element). The
lead-wire resistance will be: R = 100 ft 3 0.0162 Ω/ft = 1.62 Ω.
Thus the total resistance you have with the PRTD will be:
( )
2
∆°C = 1 mA × 1000 Ω × 50°C /W
∆°C = 0.05°C
where:
␪PACKAGE = thermal resistance of package
R0 = value of RTD resistance
RTOTAL = 100 Ω + 1.62 Ω = 101.62 Ω
Since the 100 Ω reference resistor is assumed to be relatively close
to the ADT70, the lead-wire resistance is negligible. This shows
1.62 Ω of inaccuracy.
APPLICATION INFORMATION
As shown in Figure 27, using a 1 kΩ PRTD, 1 kΩ reference
resistor, 49.9 kΩ resistor between RGA (Pin 11) and RGB (Pin
12), and shorting BIAS (Pin 4) with VREFOUT (Pin 3) together,
the output of OUTIA (Pin 14) will have a transfer function of
From the PRTD’s data sheet, the PRTD’s sensitivity rating
(Ω/°C) can be used with the lead-wire resistance to approximate
the accuracy error in temperature degree (°C). Following the example above, the sensitivity of the 100 Ω PRTD is 0.385 Ω/°C
(taken from PRTD data sheet). Hence the approximate error is:
VOUT = 1.299 mV / Ω × ∆R ( PRTD RESISTANCE − REFERENCE RESISTANCE )
Error = 1.62 Ω / 0.385 Ω / °C = 4.21°C
assuming the reference resistor is constant at 100 Ω throughout
the temperature range.
+5V
50k⍀
POTENTIOMETER
IS USED TO
NULLA
ACHIEVE HIGHER
PRECISION OF
MATCHING
CURRENT.
NULLB
BIAS
2.5VREFOUT
ADT70
+VS
OUTOA
IOUTA
MATCHED
CURRENT
SOURCES
IOUTB
+INOA
ⴚINOA
2.5V
REF
ⴚINIA
INST
AMP
+INIA
1k⍀
REF
RESISTOR
1k⍀
PRTD
RGA
SHUTDOWN
RGB GND OUTIA AGND
SENSE
49.9k⍀
ⴚVS
DGND
ⴚ1V < ⴚVS < ⴚ5V
VOUT @ 5mV/ⴗC
Figure 27. Basic Operational Diagram
REV. 0
–9–
SHUTDOWN
INDEPENDENT
OP AMP
ADT70
NULLA
NULLB
BIAS
2.5VREFOUT
5V
ADT70
1k⍀
REF
RESISTOR NODE C
NODE D
+VS
OUTOA
IOUTA
MATCHED
CURRENT
SOURCES
IOUTB
+INOA
ⴚINOA
2.5V
REF
ⴚINIA
NODE A
1k⍀
PRTD
INST
AMP
+INIA
RGA
NODE B
RGB GND
SENSE
SHUTDOWN
OUTIA
AGND ⴚVS
SHUTDOWN
DGND
50k⍀
ⴚ5V
Figure 28. 4-Wire Lead-Wire Resistance Cancellation Circuit
If PRTD has a tempco resistance of 0.00385 Ω/Ω/°C or sensitivity of 3.85 Ω/°C, the system output voltage scaling factor will
be 5 mV/°C.
The gain of the instrumentation amplifier is normally at 1.30,
with a 49.9 kΩ gain resistor. It can be changed by changing the
gain resistor using the following equation.

49.9 kΩ 
Instrumentation Amp Gain = 1.30 

 RGAIN RESISTOR 
In Figure 2 the ADT70 is powered by a dual power supply. In
order for the part to measure below 0°C, using a 1 kΩ PRTD,
–VS has to be at least –1 V. –VS can be grounded when the measured temperature is greater than 0°C using a 1 kΩ PRTD. GND
Sense (Pin 13), DGND (Pin 15), and AGND (Pin 2) are all connected to ground. If desired, GND Sense could be connected to
whatever potential desired for an output offset of the instrumentation amplifier. However, AGND and DGND must always be
connected to GND.
ADT70 will turn off if the SHUTDOWN pin(GND) is low,
and will turn on when SHUTDOWN pin becomes high (+VS).
If SHUTDOWN is not used in the design, it should be connected to +VS.
The undedicated op amp in the ADT70 can be used to transmit
measured signal to a remote location where noise might be introduced into the signal as it travels in a noisy environment. It can
also be used as a general purpose amplifier in any application desired. The op amp gain is set using standard feedback resistor
configurations.
Higher precision of matching the current sources can be
achieved by using a 50 kΩ potentiometer connected between
NULLA (Pin 5) and NULLB (Pin 6) with the center-tap of the
potentiometer connected to +VS (Pin 20). In Figure 27, the
ADT70’s Bias Pin (Pin 4) is generally connected to the
VREFOUT (Pin 3), but it can be connected to an external voltage
reference if different output current is preferred.
Eliminating Lead-Wire Resistance by Using 4-Wire
Configuration
In applications where the lead-wire resistance can significantly
contribute error to the measured temperature, implementing a
4-wire lead-resistance canceling circuit can dramatically minimize the lead-wire resistance effect.
In Figure 28, IOUTA and IOUTB provides matching excitation to
the reference resistor and the PRTD respectively. The lead-resistance from the current source to the PRTD or reference resistor is not of concern because the instrumentation amplifier is
measuring the difference in potential directly on the PRTD
(Node A) and reference resistor (Node C). Since there is almost
no current going from Node A and Node C into the amplifier’s
input, there is no lead-wire resistance error.
A potential source of temperature measurement errors is the
possibility of voltage differences between the ground side of the
reference resistor and the PRTD. Differences in lead-wire resistance from ground to these two points, coupled with the 1 mA
excitation current, will lead directly to differential voltage errors
at the input of the instrumentation amplifier of the ADT70. By
connecting the ground side of the PRTD (Node B of Figure 28)
to the noninverting input of the op amp and connecting the
ground side of the reference resistor (Node D) to both the inverting input and the output of the op amp, the two points can
be forced to the same potential. It is not important that this potential is exactly at ground since the instrumentation amplifier
rejects common-mode signals at the input. Note that all three
connections should be made as close as possible to the body of
the reference resistor and the PRTD to minimize error.
Single Supply Operation
When using the ADT70 in single supply applications a few
simple but important points need to be considered. The most
important issue is ensuring that the ADT70 is properly biased.
To bias the ADT70, first consider the 1 kΩ PRTD sensor. The
PRTD typically changes from 230 Ω at –200°C to 4080 Ω at
800°C ± 1 Ω error. This impedance range results in an ADT70
output of –1 V to +4 V respectively, which is impossible to
–10–
REV. 0
ADT70
achieve in a single supply application where the negative rail is
ground or 0 V. Therefore, to achieve full scale operation the
output of ADT70 should be shifted by 1 V to allow for operation in the 0 V to 5 V region.
However, a voltage applied to GND SENSE is not the only
method to shift the voltage range. Placing a 768 Ω resistor in the
PRTD sensor path also shifts the output voltage by 1 V. This
second method, as shown in Figure 30, is usually not recommended for the following reasons; the input voltage range of the
op amps is limited to around 1 V from the negative and positive
rails and this could cause problems at high temperature, limiting
the upper range to 600°C; the physical location of this resistor
(if placed at a distance from the ADT70) may have an impact
on the noise performance. The method frees up the on-board op
amp for another function and achieves the lowest impedance
ground point for GND SENSE.
The most straightforward method to shift the output voltage
incorporates the use of the GND SENSE as shown in Figure 29.
To shift output voltage range apply a potential equal to the necessary shift on the GND SENSE pin. For example, to shift the output voltage, OUTIA, up to 1 V to GND SENSE, apply 1 V to
GND SENSE. When applying a potential to GND SENSE, care
should be taken to ensure that the voltage source is capable of driving 2 kΩ and does not introduce excessive noise. Figure 29 uses the
on-board 2.5 V voltage reference for a low noise source. This reference is then divided to 1 V and buffered by the on-board op amp
to drive GND SENSE at a low impedance. A small 500 Ω potentiometer can be used to calibrate the initial offset error to zero.
NULLA
NULLB
BIAS
This brief section on ADT70 single supply operation has focused
on simple techniques to bias the ADT70 such that all output voltages are within operational range. However, these techniques may
not be useful in all single supply applications. For example, in Figure 3 the additional on-board op amp is operating at near ground
potential which will create problems in a single supply application
ADT70
2.5VREFOUT
+VS
OUTOA
IOUTA
IOUTB
15k⍀
MATCHED
CURRENT
SOURCES
+INOA
ⴚINOA
2.5V
REF
9.76k⍀
500⍀
POT
ⴚINIA
1k⍀
REF
RESISTOR
RG
INST
AMP
49.9k⍀
SHUTDOWN
RG
TO CONTROLLER
SHUTDOWN
+INIA
1k⍀
PRTD
SENSOR
GND
SENSE
DGND
OUTIA
Figure 29. A Single Supply Application with Shifted Ground Sense Pin
+5V
ADT70
NULLA
NULLB
BIAS
2.5VREFOUT
+VS
IOUTA
IOUTB
OUTOA
MATCHED
CURRENT
SOURCES
VREF
+INOA
2.5V
REF
ⴚINOA
ⴚINIA
RG
768⍀
RESISTOR
49.9k⍀
INST
AMP
SHUTDOWN
RG
1K⍀
PRTD
+INIA
1K⍀
REF
RESISTOR
ⴚVS
GND
SENSE
TO CONTROLLER
SHUTDOWN
DGND
TO A/D CONVERTER
Figure 30. A Basic Single Supply Operational Diagram with Bias Resistor in Sensor Path
REV. 0
–11–
ADT70
because the input voltage range of the on-board op amp only extends to about 1 V above the negative rail. If the application requires the inputs of either the on-board amp or instrumentation
amplifier to operate within 1 V of ground, it will be necessary to
generate a “pseudo-ground.” Figure 31 illustrates a typical
ADT70 “pseudo-ground” application. The Analog Devices’
ADR290, a 2.048 V reference, is being used to generate the
“pseudo-ground.” The ADR290 was selected for the following
reasons: low noise, ability to drive the required 5 mA in this
application, good temperature stability, which is usually important in a PRTD application. However, one undesired effect of
introducing the pseudo-ground is the loss in voltage range at
high temperature. In our example, the PRTD will only operate
from –200°C to +400°C corresponding to an input voltage
range of 1 V to 4 V.
a 100 Ω PRTD 0.00385 sensor, change RG to 4.99 kΩ as illustrated in Figure 32. In single supply application, with a 100 Ω
PRTD sensor, a “pseudo-ground” will be necessary because the
inputs of the instrumentation amplifier will be within 1 V of the
negative rail. See the section on single supply applications for
more information.
ⴚINIA
RG
INST
AMP
4.99k⍀
RG
+INIA
GND
SENSE
100 ⍀ PRTD Application Circuit
A 1000 Ω PRTD sensor scales by 3.85 Ωs/°C, which is exactly
ten times the scale of the 100 Ω PRTD sensor. The ADT70
has been designed to allow for 1000 Ω or 100 Ω PRTD sensors. Only the gain setting resistor RG needs to be altered. For
NULLA
1k⍀
REF
RESISTOR NODE C
IOUTA
NODE D
NULLB
OUT
Figure 32. 100␣ Ω 0.00385 PRTD Application Showing
New Value for RG
BIAS
2.5VREFOUT
ADT70
+5V
+VS
OUTOA
MATCHED
CURRENT
SOURCES
+INOA
IOUTB
2.5V
REF
ⴚINOA
ⴚINIA
RG
49.9k⍀
INST
AMP
SHUTDOWN
SHUTDOWN
RG
+INIA
1k⍀
PRTD
10␮F
+5V
GND
SENSE
ADR290
0.1␮F
IN OUT
GND
OUT
AGND
ⴚVS
DGND
0.1␮F
Figure 31. Single Supply Application with an ADR290 “Pseudo-Ground”
–12–
REV. 0
ADT70
American PRTD Application Circuit
The majority of PRTD sensors use a scale factor of 0.00385 Ω/Ω/°C.
This type of sensor is known as the European PRTD and is the most
common PRTD sensor. However, there is also an American PRTD
sensor that uses a scale factor of 0.00392 Ω/Ω/°C. Figure 33 illustrates the input section of the ADT70 configured for the American PRTD. The ideal value for RG is 50.98 kΩ when yielding a
5 mV/°C ADT70 output.
Strain Gauge Sensor Application Circuit
Figure 34 illustrates a typical strain gauge bridge circuit. The
versatility of the ADT70 allows the part to be used with most
bridge circuits that are within the 50 kΩ to 5 kΩ impedance
range. The sensor used in this circuit has two elements varying.
If a constant current is driven into the sensor, a linear VOUT is
obtained. In addition, the ADT70 will work with most bridge
circuits whether one-, two-, or all-element varying.
Securing Additional Current from the Current Sources
Some sensor applications need a higher excitation current to increase sensor sensitivity. There are two methods to increase the
current from the on-board current sources of the ADT70. The
most flexible method involves changing the voltage at the BIAS
node. The equation for determining the BIAS potential vs. Output current is 2.5 V for roughly 1 mA, or in other words, to
double the current output simply put 5 V into BIAS. The BIAS
node should be driven with a low-noise source, such as a reference, because output current is directly dependent on BIAS voltage. Directly tying BIAS to the positive supply rail may produce
too much current noise especially if the positive rail is not well
regulated. The second method involves tying the two ADT70
current outputs together which doubles the current. Of course,
this technique is most useful if, as illustrated in Figure 34, the application requires only one current source.
IOUTA
IOUTB
ⴚINIA
RG
INST
AMP
49.9k⍀
2k⍀
1k⍀
PRTD
1k⍀
REF
RESISTOR
RG
+INIA
NOTE: IDEAL VALUE
FOR RG =˜ 51k⍀
GND
SENSE
OUT
Figure 33. Typical PRTD Application with American
0.003916 Ω / Ω / °C Scale; 1 kΩ Scale
NULLA
NULLB
BIAS
2.5VREFOUT
+5V
ADT70
+VS
IOUTA
IOUTB
R
OUTOA
MATCHED
CURRENT
SOURCES
+INOA
R
2.5V
REF
ⴚINOA
ⴚINIA
R
R
RG
INST
AMP
SHUTDOWN
RG
SHUTDOWN
+INIA
COLUMBIA RESEARCH LAB
MODEL DT3617
STRAIN SENSOR
R = 1k⍀
DGND
ⴚ5V
Figure 34. Typical Strain Sensor Application (Two Element Varying)
REV. 0
–13–
ADT70
OUTLINE DIMENSIONS
Dimensions shown in inches and (mm).
C3395–8–7/98
20-Lead Plastic DIP
(P-Suffix)
1.060 (26.90)
0.925 (23.50)
20
11
1
10
0.280 (7.11)
0.240 (6.10)
0.060 (1.52)
0.015 (0.38)
PIN 1
0.210 (5.33)
MAX
0.325 (8.25)
0.300 (7.62) 0.195 (4.95)
0.115 (2.93)
0.130
(3.30)
MIN
0.160 (4.06)
0.115 (2.93)
0.022 (0.558)
0.014 (0.356)
0.100
(2.54)
BSC
0.015 (0.381)
0.008 (0.204)
0.070 (1.77) SEATING
0.045 (1.15) PLANE
20-Lead SOIC
(S-Suffix)
11
1
10
0.0118 (0.30)
0.0040 (0.10)
0.1043 (2.65)
0.0926 (2.35)
0.0291 (0.74)
x 45°
0.0098 (0.25)
8°
0.0500 0.0192 (0.49)
0°
(1.27) 0.0138 (0.35) SEATING 0.0125 (0.32)
PLANE
BSC
0.0091 (0.23)
0.0500 (1.27)
0.0157 (0.40)
PRINTED IN U.S.A.
PIN 1
0.4193 (10.65)
0.3937 (10.00)
20
0.2992 (7.60)
0.2914 (7.40)
0.5118 (13.00)
0.4961 (12.60)
–14–
REV. 0