BB IXR100

®
IXR100
Isolated, Self-Powered,
Temperature Sensor Conditioning
4-20mA TWO-WIRE TRANSMITTER
FEATURES
APPLICATIONS
● 1500Vrms ISOLATION
● TRUE TWO-WIRE OPERATION :
Power and Signal on One Wire Pair
● RESISTANCE OR VOLTAGE INPUT
● INDUSTRIAL PROCESS CONTROL:
All Types of Isolated Transmitters;
Pt100 RTD
Thermocouple Inputs
Current Shunt (mV) Inputs
● ISOLATED DUAL CURRENT SOURCES
● AUTOMATED MANUFACTURING
● DUAL MATCHED CURRENT SOURCES:
400µA at 7V
● WIDE SUPPLY RANGE 12V TO 36V
● PT100 RTD LINEARIZATION
● POWER PLANT/ENERGY MONITORING
● GROUND LOOP ELIMINATION
DESCRIPTION
The IXR100 is an isolated 2-wire transmitter featuring
loop powered operation and resistive temperature
sensor conditioning (excitation and linearization).
It contains a DC/DC convertor, high accuracy instrumentation amplifier with single resistor programmable
span and linearization, and dual matched excitation
current sources. This combination is ideally suited
to a range of transducers such as thermocouples,
RTDs, thermistors and strain gages. The small size
makes it ideal for use in head mounted isolated temperature transmitters as well as rack and rail mounted
equipment.
The isolated two-wire transmitter allows signal transmission and device power to be supplied on a single
wire-pair by modulating the power supply current
with the isolated signal source. The transmitter is
resistant to voltage drops from long runs and noise
from motors, relays, actuators, switches, transformers
and industrial equipment.
It can be used by OEMs producing isolated transmitter
modules or by data acquisition system manufacturers.
The IXR100 is also useful for general purpose isolated
current transmission where the elimination of ground
loops is important.
0.4mA
Optional
Offset
Adjust
0.4mA
RO
Pt100 NONLINEARITY CORRECTION
USING IXR100
4
2
+VIN
1
+ +IR
4-20mA
10
IR
4.4
11
RO R
OR
Uncorrected
Nonlinearity (%)
6
12
O
VS
28
RS
RS
IXR100
+
7
RS
RLIN
3
–VIN
Corrected
+0.1
– RLIN
Com
5
18
RL
–
9
8
RTD
–0.1
RZ
RLIN
R CM
850
–200
0.01µF
Process Temperature (°C)
International Airport Industrial Park • Mailing Address: PO Box 11400
Tel: (520) 746-1111 • Twx: 910-952-1111 • Cable: BBRCORP •
• Tucson, AZ 85734 • Street Address: 6730 S. Tucson Blvd. • Tucson, AZ 85706
Telex: 066-6491 • FAX: (520) 889-1510 • Immediate Product Info: (800) 548-6132
©
PDS-1141A
1992 Burr-Brown Corporation
Printed in U.S.A. August, 1993
VOUT
SPECIFICATIONS
ELECTRICAL
At VS = +24V, TA = +25°C, unless otherwise noted.
IXR100
PARAMETER
OUTPUT AND LOAD CHARACTERISTICS
Output Current
Output Current Limit
Loop Supply Voltage
Load Resistance
CONDITIONS
MIN
Linear Operating Region
4
TYP
UNITS
20
mA
mA
VDC
Ω
32
11.6
RLOAD = (VS –11.6)/IO
ZERO
Initial Error (1)
vs Temperature
36
VIN = 0, RS = ∞
SPAN
Output Current Equation
Span Equation
Untrimmed Error
vs Temperature
Nonlinearity : EMF Input
: Pt100 Input
INPUT
Voltage Range
Common-Mode Range
Offset Voltage
vs Temperature
vs Supply
MAX
RS in Ω, VIN in V
300
200
µA
ppm FSR/°C
0
100
0.025
A/V
%
ppm/°C
%FSR
%FSR
4
2.5
5
V
V
mV
µV/°C
dB
IO = 4mA + [0.016 + (40/RS)] (VIN)
S = [0.016 + (40/RS)]
(1)
–2.5
Excluding TCR of RS
50
0.01
0.1
(2)
(3)
RS = ∞
VIN+, VIN– with Respect to COM
1
2
0.5
3
100
CURRENT SOURCES
Magnitude
Accuracy
vs Temperature
Match
vs Temperature
0.4
50
25
DYNAMIC RESPONSE
Settling Time
To 0.1% of Span
500
TEMPERATURE RANGE
Operating
Storage
ISOLATION
Isolation Voltage
1
100
0.5
50
–20
–40
VISO
VISO
1000 JP
1500 KP
mA
%
ppm/°C
%
ppm/°C
ms
+70
+85
°C
°C
Vrms
Vrms
NOTES: (1) Can be adjusted to zero. (2) End point span non-linearity. (3) End point, corrected span non-linearity with a Pt100 RTD input operated from –200°C to
+850°C.
ELECTROSTATIC
DISCHARGE SENSITIVITY
ABSOLUTE MAXIMUM RATINGS
Power Supply (+VS –IOUT) .................................................................. 40V
Input Voltage (Com to VIN) .................................................................... 9V
Storage Temperature Range ........................................... –40°C to +85°C
Lead Temperature (soldering 10s) ................................................ +300°C
Output Current Limit Duration ................................................. Continuous
Power Dissipation ......................................................................... 500mW
Electrostatic discharge can cause damage ranging from
performance degradation to complete device failure. BurrBrown Corporation recommends that this integrated circuit
be handled and stored using appropriate ESD protection
methods.
PACKAGE INFORMATION
MODEL
PACKAGE
PACKAGE DRAWING
NUMBER(1)
IXR100
2-wire Transmitter
901
NOTE: (1) For detailed drawing and dimension table, please see end of data
sheet, or Appendix D of Burr-Brown IC Data Book.
The information provided herein is believed to be reliable; however, BURR-BROWN assumes no responsibility for inaccuracies or omissions. BURR-BROWN assumes
no responsibility for the use of this information, and all use of such information shall be entirely at the user’s own risk. Prices and specifications are subject to change
without notice. No patent rights or licenses to any of the circuits described herein are implied or granted to any third party. BURR-BROWN does not authorize or warrant
any BURR-BROWN product for use in life support devices and/or systems.
®
IXR100
2
PIN CONFIGURATION
Top View
IREF1
1
28 +VS
VIN+
2
27
*
VIN–
3
26
*
IREF2
4
25
*
Com
5
24
*
RS1
6
23
*
RS2
7
22
*
RL1
8
21
*
RL2
9
20
*
OS1 10
19
*
OS2 11
18 IOUT
OS3 12
17
*
*
13
16
*
*
14
15
*
* = No Pin
DISCUSSION
OF PERFORMANCE
FUNCTIONAL DESCRIPTION
The IXR100 comprises of several functions:
• Sensor excitation
The IXR100 makes the design of isolated two wire 4 to
20mA transmitters easy and provides exceptional performance at very low cost. It combines several unique features
not previously available in a single package. These include
galvanic isolation, sensor excitation and linearization, excellent DC performance, and low zero and span drift. The
IXR100 functions with voltages as low as 11.6V at the
device. This allows operation with power supplies at or
below 15V. When used with the RCV420 the complete 4 to
20mA current loop requires only 13.1V. If series diode
protection is desired the minimum loop supply voltage is
still only about 13.7V. This is especially useful in systems
where the available supplies are only 15V.
• Internal voltage regulator
• Input amplifier and V/I converter
• Linearization circuit
• DC/DC Converter
SENSOR EXCITATION
Sensor Excitation consists of two matched 0.4mA current
sources. One is used to excite the resistive sensor and the
other is used to excite the zero balance resistor RZ. When the
linearity correction feature is used these current sources are
modulated together so that three wire operation of a Pt100
RTD is possible.
BASIC CONNECTION
The basic connection of the IXR100 is shown in Figure 1. A
differential voltage applied between pins 2 and 3 will cause
a current of 4 to 20mA to circulate in the two wire output
loop pins 28 and 18. Pins 1 and 4 supply the current
excitation for resistive sensors. Pins 6 and 7 are provided for
the connection of an external span resistor which increases
the gain. Pins 8 and 9 provide linearity correction. Pins 10,
11 and 12 adjust the output offset current.
INTERNAL VOLTAGE REGULATOR
The circuitry within the IXR100 regulates the supply voltage
to the DC/DC Converter, Input Amplifier, Linearization
Amplifier and V/I Converter and removes the normal variations in VS from these stages as the output spans from 4 to
20mA.
®
3
IXR100
0.4mA
IO = 4mA + (0.016 + 40 ) VIN
RS
Optional
Offset
Adjust
0.4mA
RO
VIN = IREF (RTD – RZ)
4
2
+VIN
1
+ +IR
4-20mA
10
IR
11
RO R
12
OR
O
6
VS
28
RS
(2)
RS
IXR100
+
7
RS
RLIN
3
–VIN
RL
–
18
Com
5
VOUT
9
– RLIN
8
RTD
RZ
(1)
RLIN
(3)
R CM
NOTES: (1) RZ = RTD resistance at the minimum process temperature.
40
(2) RS =
Ω.
0.016/(∆VIN) – 0.016
(3) RLIN = 500Ω to 1500Ω or ∞ if linearization is not required.
0.01µF
FIGURE 1. Basic Connection for RTD.
INPUT AMPLIFIER AND V/I CONVERTER
DC/DC CONVERTER
The Input Amplifier is an instrumentation amplifier whose
gain is set by RS, it drives the V/I Converter to produce a 4
to 20mA output current. The Input Amplifier has a common
mode voltage range of 2 to 4V with respect to COM (pin 5).
Normally this requirement is satisfied by returning the
currents from the RTD and zero balance resistor RZ to COM
through a common mode resistor RCM. For most applications a single value of 3.9kΩ may be used. When used with
RTDs having large values of resistance RCM must be chosen
so that the inputs of the amplifier remain within its rated
common mode range. RCM should be bypassed with a
0.01µF or larger capacitor.
The DC/DC Converter transfers power from the 2 wire
current loop across the barrier to the circuitry used on the
input side of the isolation barrier.
PIN DESCRIPTIONS
IREF1, IREF2
These pins provide a matched pair of current sources for
sensor excitation. These current sources provide excellent
thermal tracking, and when the linearization feature is used,
are modulated by an equal amount. Their nominal current
value is 0.4mA and their compliance voltage is:
VIN+ < VIREF < (Com + 7V)
LINEARIZATION CIRCUIT
The Linearity Correction Circuit is unique in several ways.
A single external resistor will provide up to 50 times
improvement in the basic RTD linearity. Terminal based
non-linearity can be reduced to less than ±0.1% for all RTD
temperature spans. The Linearization circuit also contains an
instrumentation amplifier internally connected to the ±VIN
pins. The gain of this stage is set by RLIN. The output
controls the excitation current sources to produce an increasing excitation current as VIN increases. An important feature
is that the Linearity Correction is made directly to the RTD
output independent of the gain of the Input Amplifier. This
provides minimal interaction between RS and RZ. This
feature can be useful at the systems level by reducing data
acquisition system processor overhead previously used to
linearize sensor response in software/firmware.
IREF = 400µA +
+VIN, –VIN
These are the inputs to both the input amplifier and the
linearization amplifier. Because the IXR100 has been
optimized for RTD applications, the two sets of inputs are
internally connected.
RS1, RS2
The resistor connected across these terminals determines the
gain of the IXR100. For normal 4-20mA outputs:
40
Ω
(1)
R =
S
0.016/(∆VIN) – 0.016
®
IXR100
VREF
2RLIN
4
RL1, RL2
The resistor connected between these terminals determines
the gain of the linearization circuit and the amount of
correction applied to the RTD. Its value may be determined
in several ways. Two of which are shown as follows.
–
1. Empirically by interactively adjusting RLIN, RS and RZ to
achieve best fit 4 to 20mA output. RZ is used to set 4mA
at minimum input, RS is adjusted for 12mA with a half
span input, and RLIN is adjusted to give 20mA with a full
span input. This may require a few iterations but is
probably the most practical method for field calibration.
RLIN will range between 500Ω and 1500Ω for 100Ω
sensors (Pt100, D100, SAMA). Initially it may seem a
little strange adjusting RS for 12mA and RLIN for 20mA.
However, convergence is achieved much more quickly as
the linearized curve passes through zero and has less
effect at the mid span and the linearity trim resistor tends
to adjust the transfer function more at the full span than
the mid point.
IXR100
11
+
(a)
12
10
10kΩ
±400µA adjust range
–
2. Using Table I and linear interpolation for values of span
not given in the table. This will yield very accurate results
for the Pt100 sensor and acceptable results for D100 and
SAMA sensors.
IXR100
ZERO ADJUST (OPTIONAL) OS1, OS2, OS3
The IXR100 has provision for adjusting the output offset
current as shown in Figure 2. In many applications the
already low offset will not need to be known at all. This trim
effects the V/I converter stage and does not introduce VOS
drift errors that occur when the trim is performed at the input
stage. If possible use RZ to trim sensor output error to zero
and use the offset control to trim the output to 4mA when
VIN = 0V. The offset adjustment can be made with a
11
+
(b)
12
10
5kΩ
5kΩ
±40µA adjust range
FIGURE 2. Basic Connection for Zero Adjust.
SPAN ∆T (°C)
TMIN (°C)
50
100
200
300
400
500
600
700
800
900
1000
–200
–150
–100
–50
573
745
983
1233
653
855
1105
1284
839
1059
1228
1286
995
1158
1251
1262
1083
1197
1249
1236
1131
1206
1231
1208
1152
1205
1207
1180
1159
1196
1182
1152
1159
1175
1156
1125
1154
1151
1129
1097
1140
1127
0
50
100
150
1302
1263
1225
1188
1287
1249
1211
1174
1273
1220
1183
1146
1229
1192
1155
1119
1201
1164
1127
1091
1173
1136
1100
1064
1145
1108
1073
1038
1117
1081
1046
1011
1089
1054
200
250
300
350
1151
1114
1079
1044
1137
1101
1066
1031
1110
1074
1039
1005
1083
1048
1013
979
1056
1021
987
954
1030
995
962
928
1003
969
400
450
500
550
1009
975
942
909
996
963
930
897
971
938
905
873
946
913
881
849
921
888
600
650
700
750
800
877
845
814
784
754
865
834
803
773
841
810
NOTES: (1) Linear interpolation between two horizontal
or vertical values yields acceptable values. (2) Although
not optimum, these values will also yield acceptable
results with D100 and SAMA 100Ω nominal sensors.
(3) Double RLIN value for PT200.
TABLE I. RLIN Values for Pt100 Sensor.
®
5
IXR100
the effects of non-uniform fields existing in heterogeneous
dielectric material during barrier degradation. In the case of
void non-uniformities, electric field stress begins to ionize
the void region before bridging the entire high voltage
barrier.
potentiometer connected as shown in Figures 2a and 2b. The
circuit shown in Figure 2a provides more range while the
circuit in Figure 2b provides better resolution. Note, it is not
recommended to use this adjusting procedure for zero elevation or suppression. See the signal suppression and elevation
section for the proper techniques.
The transient conduction of charge during and after the
ionization can be detected externally as a burst of
0.01µs-0.1µs current pulses that repeat on each AC voltage
cycle. The minimum AC barrier voltage that initiates partial
discharge is defined as the “inception voltage”. Decreasing
the barrier voltage to a lower level is required before partial
discharge ceases and is defined as the “extinction voltage”.
COM
This is the return for the two excitation currents IREF1 and
IREF2 and is the reference point for the inputs.
VS, IOUT
These are the connections for the current loop VS being the
most positive connection. For correct operation these pins
should have 11.6 to 36V between them.
We have designed and characterized the package to yield an
inception voltage in excess of 2400Vrms so that transient
overvoltages below this level will not cause any damage.
The extinction voltage is above 1500Vrms so that even
overvoltage-induced partial discharge will cease once the
barrier voltage is reduced to the rated level. Older high
voltage test methods relied on applying a large enough
overvoltage (above rating) to catastrophically break down
marginal parts, but not so high as to damage good ones. Our
new partial discharge testing gives us more confidence in
barrier reliability than breakdown/no breakdown criteria.
HIGH VOLTAGE TESTING
Burr-Brown Corporation has adopted a partial discharge test
criterion that conforms to the German VDE0884 Optocoupler
Standards. This method requires the measurement of minute
current pulses (< 5pC) while applying 2400rms, 60Hz highvoltage stress across every devices isolation barrier. No
partial discharge may be initiated to pass this test. This
criterion confirms transient overvoltage (1.6 x VRATED)
protection without damage. Life-test results verify the absence of failure under continuous rated voltage and maximum temperature.
APPLYING THE IXR100
The IXR100 has been designed primarily to correct
nonlinearities inherent in RTD sensors. It may also be used
in other applications where its excellent performance makes
it superior to other devices available. Examples are shown in
the Applications Section.
This new test method represents the “state-of-the-art” for
nondestructive high voltage reliability testing. It is based on
Optional Input
Filtering
0.4mA
0.4mA
1
(1)
R1
3
4
–
28 1N4148
7
C1
TRANZORB
VS
RS
IXR100
CBYPASS
+
RL
–
6
18
(1)
R2
2
CBYPASS
+
9
5
8
R LIN
CBYPASS
0.01µF
RZ
RTD
= Transmitter Case
3.9kΩ
NOTE: (1) R1 and R 2 should be made equal if used (±1% resistors are adequate).
FIGURE 3. Transient and RFI Protection Circuit.
®
IXR100
6
VOUT
RFI AND TRANSIENT SUPPRESSION
Radio frequency interference and transients are a common
occurrence in 4-20mA loops, especially when long wiring
lengths are involved. RFI usually appears as a temporary
change in output and results from rectification of the radio
signal by one or more stages in the amplifier. For sensors
which are closely coupled to the IXR100 and are contained
in a common metal housing, the usual entry for RFI is via the
4-20mA loop wiring. Coaxial bypass capacitors may be used
with great effectiveness to bring these leads into the transducer housing while suppressing the RFI. Values of 100 to
1000pF are generally recommended. For sensors remote
from the IXR100, coaxial capacitors can also be used to
filter the excitation and signal leads. Additional low-pass
filtering at the IXR100 input helps suppress RFI. The easiest
way to do this is with the optional differential RC filter
shown in Figure 4. Typical values for R1 and R2 are
100-1000Ω, and for C1 are 100-1000pF.
INPUT BANDWIDTH LIMITING
Filtering at the input to the IXR100 is recommended where
possible and can be done as shown in Figure 4. C1 connected
to pins 3 and 4 will reduce the bandwidth with a f–3dB
frequency given by:
f–3dB = 0.159/(R1 + R2 + RTD + RZ) (C1 + 3pF)
This method has the disadvantage of having f–3dB vary with
R1, R2, RTD, and RZ may require large values of R1, and R2.
R1 and R2 should be matched to prevent zero errors due to
input bias current.
SIGNAL SUPPRESSION AND ELEVATION
In some applications it is desired to have suppressed zero
range (span elevation) or elevated zero range (span suppression). This is easily accomplished with the IXR100 by using
the current sources to create the suppression/elevation
voltage. The basic concept is shown in Figure 5. In this
example the sensor voltage is derived from RT (a thermistor,
RTD or other variable resistance element) excited by one of
the 0.4mA current sources. The other current source is used
to create the elevated zero range voltage. Figures 6a, 6b, 6c
and 6d show some of the possible circuit variations. These
circuits have the desirable feature of noninteractive span and
suppression/elevation adjustments.
Transient suppression for negative voltages can be provided
by the reverse-polarity protection diodes discussed later.
However, positive transients cannot be handled by these
diodes and do frequently occur in field-mounted loops. A
shunt zener diode is of some help, but most zener diodes
suffer from limited current-handling capacity and slow turnon. Both of these characteristics can lead to device failure
before the zener conducts. One type of zener, called the
TRANZORB and available from General Semiconductor
Industries, is especially effective in protecting against highenergy transients such as those induced by lightning or
motor contactors. Choose a TRANZORB with a voltage
rating close to, but exceeding, the maximum VS which the
IXR100 will see. In combination, the coaxial bypass capacitors and TRANZORB provide a very high level of protection against transients and RFI.
0.4mA
0.4mA
NOTE: Use of the optional offset null (pins 10, 11, and 12)
for elevation or suppression is not recommended. This trim
technique is used only to trim the IXR100’s output offset
current.
MAJOR POINTS TO CONSIDER
WHEN USING THE IXR100
1. The leads to RS and RLIN should be kept as short as
possible to reduce noise pick-up and parasitic resistance.
If the linearity correction feature is not desired, the RLIN
pins are left open.
2. +VS should be bypassed with a 0.01µF capacitor as close
to the unit as possible (pins 18 to 28).
1
(1)
R1
3
4
3. Always keep the input voltages within their range of
linear operation, +2V to +4V (±VIN measured with
respect to pin 5).
–
7
C1
RS
20
IXR100
Span Adjust
6
15
2
9
+
i 0 (mA)
(1)
R2
5
10
8
R LIN
5
0.01µF
RZ
Elevated
Zero
Range
Suppressed
Zero
Range
RTD
3.9kΩ
0
– 0 +
NOTE: (1) R 1 and R 2 should be made equal if used.
VIN
Figure 4. Optional Bandwidth-Limiting Circuitry.
Figure 5. Elevation and Suppression Graph.
®
7
IXR100
0.4mA
0.4mA
0.4 mA
–
VIN
+
+
e'2
+
V4
+
R4
e'2
–
0.4mA
–
RT
RT
+
V4
–
–
VIN
+
R4
–
0.8mA
0.8mA
VIN = (e'2 –V4)
V4 = 0.4mA X R4
e'2 = 0.4mA X RT
VIN = (e'2 +V4)
V4 = 0.4mA X R4
e'2 = 0.4mA X RT
(a) Elevated Zero Range
(b) Suppressed Zero Range
0.8mA
0.8mA
–
VIN
+
–
e'2
–
VIN
+
+
+
V4
R4
–
+
+
e'2
–
V4
R4
–
0.8mA
0.8mA
VIN = (e'2 –V4)
VIN = (e'2 +V4)
V4 = 0.8mA X R4
V4 = 0.8mA X R4
(c) Elevated Zero Range
(d) Suppressed Zero Range
FIGURE 6. Elevation and Suppression Circuits.
4. The maximum input signal level (∆VIN) is 1V with RS
open and is less as RS decreases in value.
important if the receiving equipment has particularly low
resistance or uses higher voltage supplies. In general, the
series diode is recommended unless 12V operation is
necessary. In either case a 1N4148 diode is suitable.
5. Always return the current references to COM (pin 5)
through an appropriate value of RCM to keep VCM within
its operating range. Also, operate the current sources
within their rated compliance voltage:
VIN + ≤ VIREF ≤ (Com + 7V)
8. Use a layout which minimizes parasitic inductance and
capacitance, especially in high gain.
RECOMMENDED HANDLING
PROCEDURES FOR INTEGRATED CIRCUITS
All semiconductor devices are vulnerable, in varying
degrees, to damage from the discharge of electrostatic
energy. Such damage can cause performance degradation or
failure, either immediate or latent. As a general practice, we
recommend the following handling procedures to reduce the
risk of electrostatic damage.
6. Always choose RL, (including line resistance) so that the
voltage between pins 18 and 28 (+VS) remains within the
11.6V to 36V range as the output changes between 4mA
and 20mA.
7. It is recommended that a reverse polarity protection diode
be used. This will prevent damage to the IXR100 caused
by a transient or long-term reverse bias between pins 18
and 28. This diode can be connected in either of the two
positions shown in Figure 7, but each connection has its
trade-off. The series-connected diode will add to the
minimum voltage at which the IXR100 will operate but
offers loop and device protection against both reverse
connections and transients. The reverse-biased diode in
parallel with the IXR100 preserves 11.6V minimum
operation and offers device protection, but could allow
excessive current flow in the receiving instrument if the
field leads are accidently reversed. This is particularly
1. Remove static-generating materials, such as untreated
plastic, from all areas where microcircuits are handled.
2. Ground all operators, equipment, and work stations.
3. Transport and ship microcircuits, or products incorporating microcircuits, in static-free, shielded containers.
4. Connect together all leads of each device by means of a
conductive material, when the device is not connected
into a circuit.
®
IXR100
8
5. Control relative humidity to as high a value as practical
(50% recommended).
equally, so that use of the linearity correction does not affect
the cancellation. This action is true so long as the three wires
are of the same length and gauge. Because most RTD leads
are twisted and bundled, this requirement is usually met with
no difficulty. Care must be taken that intermediate connections such as screw terminals do not violate this assumption
by introducing unequal line resistances.
RTD APPLICATIONS
The IXR100 has been designed with RTD applications
specifically in mind. The following information provides
additional information for those applications.
RTD ZERO ELEVATION AND SUPPRESSION
The IXR100 may be operated in zero-elevated and zerosuppressed ranges by simply offsetting RZ. It may also be
used in increase-decrease applications by interchanging the
physical locations of the RTD and RZ as shown in Figure 8.
Use the same values of RZ, RLIN and RS. Again, because the
current sources are matched and are modulated equally, this
connection has no effect on IXR100 performance, especially
in three-wire applications.
TWO- AND THREE-WIRE CONNECTIONS
The IXR100 performs well with two-wire and three-wire
RTD connections commonly encountered in industrial monitoring and control.
In two-wire applications, the voltage drop between the RTD
and the IXR100 can be nulled by proper adjustment of RZ,
but care must be taken that this voltage drop does not vary
with ambient conditions. Such variation will appear as an
apparent variation in the RTD resistance and therefore as a
change in measured temperature. Also, the linearity correction will interpret this change as a variation and attempt to
linearize both the actual RTD signal and the resistance
changes in the signal lines. For these reasons, the line
resistance between the RTD and the IXR100 should be
minimized by keeping line lengths short and/or using largegauge wires. This limitation does not apply for three-wire
connections.
OPEN CIRCUIT DETECTION
In some applications of the IXR100, the RTD will be located
remotely. In these cases, it is possible for open circuits to
develop. The IXR100 responds in the following manner to
breaks in each lead. The following connections refer to the
RTD connections shown in Figure 7.
In three-wire applications, shown in Figure 7, the RTD and
RZ lead arrangements set up a pseudo-Kelvin connection to
the RTD. This occurs because the currents through the three
wires are set up in opposing directions and cancel IR drops
in the RTD leads. The current sources are both modulated
TERMINAL OPEN
IOUT(1)
1
2
3
32mA
3.6mA
32mA
NOTE: (1) Approximate value.
1
3
4
–
D1
+VS
28 1N4148
7
4-20mA
–
0.4mA
0.4mA
VIN
RS
IXR100
VOUT
+
6
+
18
2
+
9
RL
–
5
8
1
RLIN
RZ
2
RTD
3
R CM = 3.9kΩ
Three-wire Connection
0.01µF
FIGURE 7. Basic 3-Wire RTD Connection for Increase-Increase Action.
®
9
IXR100
1
3
4
–
D1
+VS
28 1N4148
7
4-20mA
–
0.4mA
0.4mA
VIN
RS
IXR100
VOUT
+
6
+
18
2
9
+
RL
–
5
8
1
RLIN
RZ
RTD
2
3
RCM = 3.9kΩ
Three-wire Connection
0.01µF
FIGURE 8. Basic 3-Wire RTD Connection for Increase-Decrease Action.
OTHER APPLICATIONS
From Equation (1), RS = 48.5Ω. Span adjustment (calibration) is accomplished by trimming RS.
In instances where the linearization capability of the IXR100
is not required, it can still provide improved performance in
several applications. Its small size, wide compliance
voltage, low zero and span drift, high PSRR, high CMRR
and excellent linearity makes the IXR100 ideal for a variety
of other isolated two-wire transmitter applications. It can be
used by OEMs producing different types of isolated transducer transmitter modules and by data acquisition systems
manufacturers who gather transducer data. Current mode
transmission greatly reduces noise interference. The twowire nature of the device allows economical signal conditioning at the transducer. Thus, the IXR100 is, in general,
very suitable for a wide variety of applications. Some
examples, including an isolated non-linearized Pt100 case,
follow.
In order to make the lower range limit of 25°C correspond
to the output lower range limit at 4mA, the input circuitry
shown in Figure 9 is used. VIN must be 0V at 25°C and RZ
is chosen to be equal to the RTD resistance at 25°C, or
109.73Ω. Computing RCM and checking CMV:
At +25°C, VIN+ = 43.9mV
At +150°C, VIN+ = 62.9mV
Since both VIN+ and VZ are small relative to the desired 2V
common-mode voltage, they may be ignored in computing
RCM as long as the CMV is met.
RCM = 3V/0.8mA = 3.75kΩ
VIN+ min = 3V + 0.0439V
VIN+ max = 3V + 0.0629V
EXAMPLE 1
VIN– = 3V + 0.0439V
Pt100 RTD without linearization shown in Figure 9.
EXAMPLE 2
Given a process with temperature limits of +25°C and
+150°C, configure the IXR100 to measure the temperature
with a Pt100 RTD which produces 109.73Ω at 25°C and
157.31Ω at 150°C (obtained from standard RTD tables).
Transmit 4mA for +25°C and 20mA for +150°C. The
change in resistance of the RTD is 47.6Ω. When excited
with a 0.4mA current source ∆VIN is 0.4mA x 47.6Ω =
19mV.
Thermocouple shown in Figure 10.
RS =
40
Ω
0.016/(∆VIN) – 0.016
Given a process with temperature (Tl) limits of 0°C and
+1000°C, configure the IXR100 to measure the temperature
with a Type J thermocouple that produces a 58mV change
for 1000°C change. Use a semiconductor diode for a cold
junction compensation to make the measurement relative to
0°C. This is accomplished by supplying a compensating
voltage, equal to that normally produced by the thermocouple with its “cold junction” (T2) at ambient. At +25°C
this is 1.28mV (from thermocouple tables with reference
junction at 0°C). Typically, at T2 = +25°C, VD = 0.6V and
(1)
®
IXR100
10
∆VD/∆T = –2mV/°C. R5 and R6 form a voltage divider for
the diode voltage VD. The divider values are selected so that
the gradient ∆VD/∆T equals the gradient of the thermocouple at the reference temperature. At +25°C this is
approximately –52µV/°C (obtained from standard thermocouple table); therefore,
∆VTC /∆T = (∆VD /∆T)(R6 /(R5 + R6 ))
VD(25°C) = 600mV
VIN(25°C) = 600mV (100/3740) = 16.0mV
VIN = VIN+ – VIN– = VTC + V4 – VIN–
With VIN = 0 and VTC = –1.28mV,
V4 = VIN+ – VTC
(2)
V4 = 16.0mV – (–1.28mV)
–52µV/°C = (–2000µV/°C)(R6 /(R5+R6 ))
0.4mA (R4) = 17.28mV
R5 is chosen as 3.74kΩ to be much larger than the resistance
of the diode. Solving for R6 yields 100Ω.
R4 = 43.2Ω
Transmit 4mA for Tl = 0°C and 20mA for Tl = +1000°C.
Note: VlN = VIN+ – VIN– indicates that Tl is relative to T2.
The input full scale span is 58mV. RS is found from
Equation (1) and equals 153.9Ω.
THERMOCOUPLE BURN-OUT INDICATION
In process control applications it is desirable to detect when
a thermocouple has burned out. This is typically done by
forcing the two-wire transmitter current to the upper or
lower limit when the thermocouple impedance goes very
high. The circuits of Figures 10, 11 and 12 inherently have
down scale indication. When the impedance of the thermocouple gets very large (open) the bias current flowing into
the + input (large impedance) will cause IO to go to its lower
range limit value (about 3.6mA). If up scale indication is
desired, the circuit of Figure 13 should be used. When the TC
opens, the output will go to its upper range limit value (about
32mA or higher).
R4 is chosen to make the output 4mA at TTC = 0°C (VTC =
1.28mV) and TD = 25°C (VD = 0.6V).
VTC will be –1.28mV when TTC = 0°C and the reference
junction is at +25°C. V4 must be computed for TD = +25°C
to make VIN = 0V.
1
3
0.4mA
4
–
D1
0.4mA
+VS
28 1N4148
7
4-20mA
–
VIN
RS
IXR100
VOUT
+
6
+
18
2
RZ
+
RL
–
5
RTD
RCM
0.01µF
FIGURE 9. Pt100 RTD Without Linearization.
®
11
IXR100
0.4mA
0.4mA
R5
3.74kΩ
1
3
+
VD
–
1N4148
4
–
+VS
28
7
+
VIN–
–
RS
R6
100Ω
IXR100
153.9Ω
6
18
Thermocouple
TTC
2
VTC
–
IOUT
0.01µF
VIN+
+ V4 –
5
+
+
+
–
R4
43.2Ω
3.9kΩ
Temperature T1
Temperature T2 = TD
FIGURE 10. Thermocouple Input Circuit with Two Temperature Regions and Diode (D) Cold Junction Compensation.
0.4mA
0.4mA
3.9kΩ
This circuit has down
scale burn-out indication.
1
3
4
–
D1
Type J
+
–
+VS
28 1N4148
7
4-20mA
Zero Adjust
50Ω
100Ω
RS
IXR100
VOUT
6
+
18
2
RL
–
5
+
3.9kΩ
0.01µF
FIGURE 11. Thermocouple Input with Diode Cold Junction Compensation and Down Scale Burn-out Indication.
®
IXR100
12
0.4mA
0.4mA
This circuit has down
scale burn-out indication.
1
3
4
–
D1
Type J
51Ω
7
+
–
RTD
100Ω
50Ω
+VS
28 1N4148
4-20mA
RS
IXR100
VOUT
Zero
Adjust
6
+
RL
–
18
2
5
+
3.9kΩ
0.01µF
FIGURE 12. Thermocouple Input with RTD Cold Junction Compensation and Down Scale Burn-out Indication.
This circuit has up
scale burn-out indication.
Type J
0.4mA
0.4mA
1
+
–
3
4
–
D1
7
51Ω
50Ω
4-20mA
RS
RTD
100Ω
+VS
28 1N4148
IXR100
VOUT
Zero
Adjust
6
+
RL
–
18
2
Zero
5
+
3.9kΩ
0.01µF
FIGURE 13. Thermocouple Input with RTD Cold Junction Compensation and Up Scale Burn-out Indication.
RLIN
14V to 38V
1 4
8
2
0.4mA
0.4mA
7
IXR100
16
3
10
3
18
–
1µF
+
6
RZ
+VS
28
RS
RTD
1N4148
9
+
11
12
15
5
RCV420
2
3.9kΩ
4
0.01µF
14
13
VOUT
0 - 5V
5
1µF
+
–VS
FIGURE 14. Isolated 4-20mA Instrument Loop.
®
13
IXR100
+VS
1
–VS
4
REF200
100µA
IR
2
VIN
OPA177
R3
19.5kΩ
IXR100
I IN
4-20mA
–VS
0.01µF
400Ω
R1
R2
3
100Ω
COM
IO
R
(1)
= I IN( I + 2 ) + I R ( R 1 + R 2 + R 3) / R 1 = 1.25IIN – 5mA
R1
IO
0-20mA
NOTE: (1) Other conversions are readily achievable by changing the
R1, R2, and R3 ratios (see Burr-Brown Application Bulletin AB-031).
FIGURE 15. 4-20mA to 0-20mA Output Converter.
®
IXR100
14