® XTR112 XTR114 XTR 114 XTR 112 4-20mA CURRENT TRANSMITTERS with Sensor Excitation and Linearization FEATURES APPLICATIONS ● LOW UNADJUSTED ERROR ● PRECISION CURRENT SOURCES XTR112: Two 250µA XTR114: Two 100µA ● RTD OR BRIDGE EXCITATION ● LINEARIZATION ● TWO OR THREE-WIRE RTD OPERATION ● LOW OFFSET DRIFT: 0.4µV/°C ● LOW OUTPUT CURRENT NOISE: 30nAp-p ● HIGH PSR: 110dB min ● HIGH CMR: 86dB min ● WIDE SUPPLY RANGE: 7.5V TO 36V ● SO-14 SOIC PACKAGE ● ● ● ● The XTR112 and XTR114 are monolithic 4-20mA, two-wire current transmitters. They provide complete current excitation for high impedance platinum RTD temperature sensors and bridges, instrumentation amplifier, and current output circuitry on a single integrated circuit. The XTR112 has two 250µA current sources while the XTR114 has two 100µA sources for RTD excitation. Versatile linearization circuitry provides a 2nd-order correction to the RTD, typically achieving a 40:1 improvement in linearity. Instrumentation amplifier gain can be configured for a wide range of temperature or pressure measurements. Total unadjusted error of the complete current transmitter is low enough to permit use without adjustment in many applications. This includes zero output current drift, span drift and nonlinearity. The XTR112 and XTR114 operate on loop power supply voltages down to 7.5V. Both are available in an SO-14 surface-mount package and are specified for the –40°C to +85°C industrial temperature range. Pt1000 NONLINEARITY CORRECTION USING XTR112 and XTR114 5 4 Nonlinearity (%) DESCRIPTION INDUSTRIAL PROCESS CONTROL FACTORY AUTOMATION SCADA REMOTE DATA ACQUISITION REMOTE TEMPERATURE AND PRESSURE TRANSDUCERS 3 Uncorrected RTD Nonlinearity 2 Corrected Nonlinearity 1 0 –1 –200°C +850°C Process Temperature (°C) IR IR VLIN VREG 7.5V to 36V + VPS 4-20 mA XTR112 XTR114 RG VO RL RTD – XTR112: IR = 250µA XTR114: IR = 100µA International Airport Industrial Park • Mailing Address: PO Box 11400, Tucson, AZ 85734 • Street Address: 6730 S. Tucson Blvd., Tucson, AZ 85706 • Tel: (520) 746-1111 Twx: 910-952-1111 • Internet: http://www.burr-brown.com/ • Cable: BBRCORP • Telex: 066-6491 • FAX: (520) 889-1510 • Immediate Product Info: (800) 548-6132 ® © SBOS101 1998 Burr-Brown Corporation PDS-1473A 1 Printed in U.S.A. December, 1998 XTR112, XTR114 SPECIFICATIONS At TA = +25°C, V+ = 24V, and TIP29C external transistor, unless otherwise noted. XTR112U XTR114U PARAMETER CONDITIONS OUTPUT Output Current Equation Output Current, Specified Range Over-Scale Limit Under-Scale Limit: XTR112 XTR114 ZERO OUTPUT(1) Initial Error vs Temperature vs Supply Voltage, V+ vs Common-Mode Voltage vs VREG Output Current Noise: 0.1Hz to 10Hz SPAN Span Equation (transconductance) Initial Error (3) vs Temperature(3) Nonlinearity: Ideal Input (4) INPUT(5) Offset Voltage vs Temperature vs Supply Voltage, V+ vs Common-Mode Voltage, RTI (CMRR) Common-Mode Input Range(2) Input Bias Current vs Temperature Input Offset Current vs Temperature Impedance: Differential Common-Mode Noise: 0.1Hz to 10Hz IREG = 0 MIN 4 24 0.9 0.6 VIN = 0V, RG = ∞ Full Scale (VIN) = 50mV Full Scale (VIN) = 50mV VCM = 2V V+ = 7.5V to 36V VCM = 1.25V to 3.5V(2) MAX MIN TYP IO = VIN • (40/RG) + 4mA, VIN in Volts, RG in Ω 20 ✻ 27 30 ✻ ✻ 1.3 1.7 ✻ ✻ 1 1.4 ✻ ✻ 4 ±5 ±0.07 0.04 0.02 0.3 0.03 V+ = 7.5V to 36V VCM = 1.25V to 3.5V(2) CURRENT SOURCES Current: XTR112 XTR114 Accuracy vs Temperature vs Power Supply, V+ Matching vs Temperature vs Power Supply, V+ Compliance Voltage, Positive Negative(2) Output Impedance: XTR112 XTR114 Noise: 0.1Hz to 10Hz: XTR112 XTR114 TYP XTR112UA XTR114UA ✻ ✻ ✻ ✻ ✻ ✻ ✻ ±25 ±0.5 0.2 MAX UNITS ✻ ✻ ✻ ✻ A mA mA mA mA ±50 ±0.9 ✻ S = 40/RG ±0.05 ±3 0.003 ±0.2 ±25 0.01 ✻ ✻ ✻ ✻ ±0.4 ✻ ✻ A/V % ppm/°C % ±50 ±0.4 ±0.3 ±10 ±100 ±1.5 ±3 ±50 ✻ ✻ ✻ ✻ ±250 ±3 ✻ ±100 µV µV/°C µV/V µV/V ✻ 50 V nA pA/°C nA pA/°C GΩ || pF GΩ || pF µVp-p 1.25 5 20 ±0.2 5 0.1 || 1 5 || 10 0.6 3.5 25 ✻ ✻ ✻ ✻ ✻ ✻ ✻ ✻ ±3 ±10 VO = 2V(6) V+ = 7.5V to 36V V+ = 7.5V to 36V (V+) –3 0 VREG(2) Accuracy vs Temperature vs Supply Voltage, V+ Output Current: XTR112 XTR114 Output Impedance 250 100 ±0.05 ±15 ±10 ±0.02 ±3 1 (V+) –2.5 –0.2 500 1.2 0.001 0.0004 5.1 ±0.02 ±0.2 1 –1, +2.1 –1, +2.4 75 LINEARIZATION RLIN (internal) Accuracy vs Temperature 1 ±0.2 ±25 POWER SUPPLY Specified Voltage Operating Voltage Range TEMPERATURE RANGE Specification, TMIN to TMAX Operating /Storage Range Thermal Resistance, θJA SO-14 Surface-Mount mA µA µA/°C µA/V µA/V µA/mA µAp-p ±0.2 ±35 ±25 ±0.1 ±15 10 ✻ ✻ ✻ ✻ ✻ ✻ ✻ ✻ ✻ ✻ ✻ ✻ ✻ ✻ ✻ ✻ ✻ ✻ ✻ ✻ ✻ ✻ ✻ ±0.1 ✻ ✻ ✻ ±0.5 ±100 ±0.4 ±75 ✻ ±0.2 ±30 ✻ ✻ V V mV/°C mV/V mA mA Ω ±1 ✻ kΩ % ppm/°C ✻ +24 µA µA % ppm/°C ppm/V % ppm/°C ppm/V V V MΩ GΩ µAp-p µAp-p +7.5 +36 ✻ ✻ V V –40 –55 +85 +125 ✻ ✻ ✻ ✻ °C °C 100 ✻ °C/W ✻ Specification same as XTR112U, XTR114U. NOTES: (1) Describes accuracy of the 4mA low-scale offset current. Does not include input amplifier effects. Can be trimmed to zero. (2) Voltage measured with respect to IRET pin. (3) Does not include initial error or TCR of gain-setting resistor, RG. (4) Increasing the full-scale input range improves nonlinearity. (5) Does not include Zero Output initial error. (6) Current source output voltage with respect to IRET pin. ® XTR112, XTR114 2 ABSOLUTE MAXIMUM RATINGS(1) PIN CONFIGURATION Top View Power Supply, V+ (referenced to IO pin) .......................................... 40V + – Input Voltage, VIN, VIN (referenced to IO pin) ............................ 0V to V+ Storage Temperature Range ....................................... –55°C to +125°C Lead Temperature (soldering, 10s) .............................................. +300°C Output Current Limit ............................................................... Continuous Junction Temperature ................................................................... +165°C SO-14 XTR112 and XTR114 1 14 IR2 – VIN 2 13 VIN RG 3 12 VLIN RG 4 11 VREG NC 5 10 V+ IRET 6 9 B (Base) IO 7 8 E (Emitter) IR1 NOTE: (1) Stresses above these ratings may cause permanent damage. Exposure to absolute maximum conditions for extended periods may degrade device reliability. + ELECTROSTATIC DISCHARGE SENSITIVITY This integrated circuit can be damaged by ESD. Burr-Brown recommends that all integrated circuits be handled with appropriate precautions. Failure to observe proper handling and installation procedures can cause damage. NC = No Connection ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more susceptible to damage because very small parametric changes could cause the device not to meet its published specifications. PACKAGE/ORDERING INFORMATION PACKAGE PACKAGE DRAWING NUMBER(1) SPECIFIED TEMPERATURE RANGE ORDERING NUMBER(2) TRANSPORT MEDIA 2 x 250µA " 2 x 250µA " SO-14 Surface Mount " SO-14 Surface Mount " 235 " 235 " –40°C to +85°C " –40°C to +85°C " XTR112U XTR112U/2K5 XTR112UA XTR112UA/2K5 Rails Tape and Reel Rails Tape and Reel 2 x 100µA " 2 x 100µA " SO-14 Surface Mount " SO-14 Surface Mount " 235 " 235 " –40°C to +85°C " –40°C to +85°C " XTR114U XTR114U/2K5 XTR114UA XTR114UA/2K5 Rails Tape and Reel Rails Tape and Reel PRODUCT CURRENT SOURCES XTR112U " XTR112UA " XTR114U " XTR114UA " NOTES: (1) For detailed drawing and dimension table, please see end of data sheet, or Appendix C of Burr-Brown IC Data Book. (2) Models with a slash (/) are available only in Tape and Reel in the quantities indicated (e.g., /2K5 indicates 2500 devices per reel). Ordering 2500 pieces of “XTR112UA/2K5” will get a single 2500-piece Tape and Reel. For detailed Tape and Reel mechanical information, refer to Appendix B 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. ® 3 XTR112, XTR114 FUNCTIONAL BLOCK DIAGRAM VLIN XTR112: IR1 = IR2 = 250µA XTR114: IR1 = IR2 = 100µA IR1 12 1 IR2 14 VREG V+ IR2 IR1 11 10 + VIN 13 5.1V 4 B RLIN 1kΩ Q1 9 100µA RG 3 – VIN E I = 100µA + 2 VIN 8 RG 975Ω 25Ω 7 IO = 4mA + VIN • 6 IRET ® XTR112, XTR114 4 ( R40 ) G TYPICAL PERFORMANCE CURVES At TA = +25°C, and V+ = 24V, unless otherwise noted. TRANSCONDUCTANCE vs FREQUENCY STEP RESPONSE RG = 125Ω RG = 500Ω RG = 2kΩ 40 20mA 30 4mA/div Transconductance (20 Log mA/V) 50 20 RG = 125Ω RG = 2kΩ 4mA 10 0 100 1k 10k 25µs/div 1M 100k Frequency (Hz) COMMON-MODE REJECTION RATIO vs FREQUENCY POWER-SUPPLY REJECTION RATIO vs FREQUENCY 110 Power Supply Rejection Ratio (dB) 140 Common-Mode Rejection Ratio (dB) 100 90 80 RG = 125Ω 70 60 RG = 2kΩ 50 40 30 120 RG = 125Ω 100 80 60 RG = 2kΩ 40 20 0 10 20 10 100 1k 10k 100k 100 1k 10k 100k 1M Frequency (Hz) 1M Frequency (Hz) OVER-SCALE CURRENT vs TEMPERATURE UNDER-SCALE CURRENT vs TEMPERATURE 29 1.45 1.4 Under-Scale Current (mA) Over-Scale Current (mA) With External Transistor 28 27 V+ = 36V 26 V+ = 7.5V 25 V+ = 24V 24 1.35 XTR112 1.3 1.25 1.2 1.15 1.1 1.05 XTR114 1 23 0.95 –75 –50 –25 0 25 50 75 100 125 –75 Temperature (°C) –50 –25 0 25 50 75 100 125 Temperature (°C) ® 5 XTR112, XTR114 TYPICAL PERFORMANCE CURVES (CONT) At TA = +25°C, and V+ = 24V, unless otherwise noted. INPUT VOLTAGE AND CURRENT NOISE DENSITY vs FREQUENCY ZERO OUTPUT AND REFERENCE CURRENT NOISE vs FREQUENCY 10k 10k 1k Current Noise 100 100 Voltage Noise 10 1 10 100 1k Zero Output Current Noise (pA/√Hz) 1k Input Current Noise (fA/√Hz) Input Voltage Noise (nV/√Hz) 10k XTR112 1 10 100 1k 10k Frequency (Hz) Frequency (Hz) INPUT BIAS AND OFFSET CURRENT vs TEMPERATURE ZERO OUTPUT CURRENT ERROR vs TEMPERATURE 100k 4 Zero Output Current Error (µA) Input Bias and Offset Current (nA) XTR114 10 25 20 +IB 15 10 –IB 5 IOS 2 0 –2 –4 –6 –8 –10 –12 0 –75 –50 –25 0 25 50 75 100 –75 125 25 50 75 ZERO OUTPUT DRIFT PRODUCTION DISTRIBUTION 40 35 Percent of Units (%) 60 50 40 30 20 15 10 0 0.025 0.05 0.075 0.1 0.125 0.15 0.175 0.2 0.225 0.25 0.275 0.3 0.325 0.35 0.375 0.4 0.425 0.45 0.475 0.5 3.0 2.8 2.6 2.4 2.2 2.0 1.8 1.6 1.4 1.2 1.0 0 0.8 Typical production distribution of packaged units. XTR112 and XTR114 included. 20 0 0.6 125 25 5 Input Offset Voltage Drift (µV/°C) Zero Output Drift (µA/°C) ® XTR112, XTR114 100 30 10 0.4 0 INPUT OFFSET VOLTAGE DRIFT PRODUCTION DISTRIBUTION 70 0 –25 Temperature (°C) Typical production distribution of packaged units. XTR112 and XTR114 included. 0.2 –50 Temperature (°C) 80 Percent of Units (%) 100 Reference Current 10 100k 10k 1k 6 TYPICAL PERFORMANCE CURVES (CONT) At TA = +25°C, and V+ = 24V, unless otherwise noted. CURRENT SOURCE DRIFT PRODUCTION DISTRIBUTION CURRENT SOURCE MATCHING DRIFT PRODUCTION DISTRIBUTION 40 90 Typical production distribution of packaged units. XTR112 and XTR114 included. Typical production distribution of packaged units. XTR112 and XTR114 included. 80 Percent of Units (%) 30 25 20 15 10 70 60 50 40 30 Current Source Matching Drift (ppm/°C) XTR114 VREG OUTPUT VOLTAGE vs VREG OUTPUT CURRENT XTR112 VREG OUTPUT VOLTAGE vs VREG OUTPUT CURRENT 30 28 26 24 22 20 18 16 14 12 8 10 6 Current Source Drift (ppm/°C) 5.35 5.35 125°C 125°C 5.30 VREG Output Voltage (V) 5.30 5.25 25°C 5.20 5.15 –55°C 5.10 NOTE: Above 2.4mA, zero output degrades 5.05 25°C 5.25 5.20 5.15 –55°C NOTE: Above 2.1mA, zero output degrades 5.10 5.05 5.00 5.00 –1 –0.5 0 0.5 1 1.5 2 2.5 3 –1 –0.5 VREG Output Current (mA) 0 0.5 1 1.5 2 2.5 3 VREG Output Current (mA) REFERENCE CURRENT ERROR vs TEMPERATURE +0.05 Reference Current Error (%) VREG Output Voltage (V) 4 0 75 70 65 60 55 50 45 40 35 30 25 20 15 5 0 10 10 0 2 20 5 0 Percent of Units (%) 35 0 –0.05 –0.10 –0.15 –0.20 –75 –50 –25 0 25 50 75 100 125 Temperature (°C) ® 7 XTR112, XTR114 APPLICATION INFORMATION The transfer function through the complete instrumentation amplifier and voltage-to-current converter is: Figure 1 shows the basic connection diagram for the XTR112 and XTR114. The loop power supply, VPS, provides power for all circuitry. Output loop current is measured as a voltage across the series load resistor, RL. IO = 4mA + VIN • (40/RG) (VIN in volts, RG in ohms) where VIN is the differential input voltage. As evident from the transfer function, if RG is not used the gain is zero and the output is simply the XTR’s zero current. The value of RG varies slightly for two-wire RTD and three-wire RTD connections with linearization. RG can be calculated from the equations given in Figure 1 (two-wire RTD connection) and Table I (three-wire RTD connection). Two matched current sources drive the RTD and zerosetting resistor, RZ. These current sources are 250µA for the XTR112 and 100µA for the XTR114. Their instrumentation amplifier input measures the voltage difference between the RTD and RZ. The value of RZ is chosen to be equal to the resistance of the RTD at the low-scale (minimum) measurement temperature. RZ can be adjusted to achieve 4mA output at the minimum measurement temperature to correct for input offset voltage and reference current mismatch of the XTR112 and XTR114. The IRET pin is the return path for all current from the current sources and VREG. The IRET pin allows any current used in external circuitry to be sensed by the XTR112 and XTR114 and to be included in the output current without causing an error. RCM provides an additional voltage drop to bias the inputs of the XTR112 and XTR114 within their common-mode input range. RCM should be bypassed with a 0.01µF capacitor to minimize common-mode noise. Resistor RG sets the gain of the instrumentation amplifier according to the desired temperature range. RLIN1 provides second-order linearization correction to the RTD, typically achieving a 40:1 improvement in linearity. An additional resistor is required for threewire RTD connections, see Figure 3. The VREG pin provides an on-chip voltage source of approximately 5.1V and is suitable for powering external input circuitry (refer to Figure 6). It is a moderately accurate voltage reference—it is not the same reference used to set the precision current references. VREG is capable of sourcing approximately 2.1mA of current for the XTR112 and 2.4mA for the XTR114. Exceeding these values may affect the 4mA zero output. Both products can sink approximately 1mA. IR2 Possible choices for Q1 (see text). IR1 12 13 4 VLIN + VIN 1 IR1 TO-225 TO-220 TO-220 7.5V to 36V 14 11 IR2 10 VREG V+ IO 4-20 mA (2) RLIN1(3) PACKAGE RG RG XTR112 XTR114 3 TYPE 2N4922 TIP29C TIP31C RG B 9 Q1 0.01µF VO E 8 RL IO 2 – VIN + VPS – 7 IRET (1) RTD RZ 6 IO = 4mA + VIN • ( 40 ) RG NOTES: (1) RZ = RTD resistance at minimum measured temperature. RCM (2) RG = 2.5 • IREF [R1(R2 + RZ) – 2(R2RZ)] (3) RLIN1 = 0.01µF R2 – R1 0.4 • RLIN(R2 – R1) IREF (2R1 – R2 – RZ) where R1 = RTD Resistance at (TMIN + TMAX)/2 R2 = RTD Resistance at TMAX RLIN = 1kΩ (Internal) IREF = 0.25 for XTR112 IREF = 0.1 for XTR114 XTR112: IR1 = IR2 = 250µA, RCM = 3.3kΩ XTR114: IR1 = IR2 = 100µA, RCM = 8.2kΩ FIGURE 1. Basic Two-Wire RTD Temperature Measurement Circuit with Linearization. ® XTR112, XTR114 8 A negative input voltage, VIN, will cause the output current to be less than 4mA. Increasingly negative VIN will cause the output current to limit at approximately 1.3mA for the XTR112 and 1mA for the XTR114. Refer to the typical curve “Under-Scale Current vs Temperature.” range from 7.5V to 36V. The loop supply voltage, VPS, will differ from the applied voltage according to the voltage drop on the current sensing resistor, RL (plus any other voltage drop in the line). If a low loop supply voltage is used, RL (including the loop wiring resistance) must be made a relatively low value to assure that V+ remains 7.5V or greater for the maximum loop current of 20mA: Increasingly positive input voltage (greater than the fullscale input) will produce increasing output current according to the transfer function, up to the output current limit of approximately 27mA. Refer to the typical curve “OverScale Current vs Temperature.” R L max = (V+) – 7.5V – R WIRING 20mA EXTERNAL TRANSISTOR It is recommended to design for V+ equal or greater than 7.5V with loop currents up to 30mA to allow for out-ofrange input conditions. Transistor Q1 conducts the majority of the signal-dependent 4-20mA loop current. Using an external transistor isolates the majority of the power dissipation from the precision input and reference circuitry of the XTR112 and XTR114, maintaining excellent accuracy. The low operating voltage (7.5V) of the XTR112 and XTR114 allow operation directly from personal computer power supplies (12V ±5%). When used with the RCV420 Current Loop Receiver (Figure 7), load resistor voltage drop is limited to 3V. Since the external transistor is inside a feedback loop its characteristics are not critical. Requirements are: VCEO = 45V min, β = 40 min and PD = 800mW. Power dissipation requirements may be lower if the loop power supply voltage is less than 36V. Some possible choices for Q1 are listed in Figure 1. ADJUSTING INITIAL ERRORS Many applications require adjustment of initial errors. Input offset and reference current mismatch errors can be corrected by adjustment of the zero resistor, RZ. Adjusting the gain-setting resistor, RG, corrects any errors associated with gain. The XTR112 and XTR114 can be operated without this external transistor, however, accuracy will be somewhat degraded due to the internal power dissipation. Operation without Q1 is not recommended for extended temperature ranges. A resistor (R = 3.3kΩ) connected between the IRET pin and the E (emitter) pin may be needed for operation below 0°C without Q1 to guarantee the full 20mA full-scale output, especially with V+ near 7.5V. TWO-WIRE AND THREE-WIRE RTD CONNECTIONS In Figure 1, the RTD can be located remotely simply by extending the two connections to the RTD. With this remote two-wire connection to the RTD, line resistance will introduce error. This error can be partially corrected by adjusting the values of RZ, RG, and RLIN1. LOOP POWER SUPPLY The voltage applied to the XTR112 and XTR114, V+, is measured with respect to the IO connection, pin 7. V+ can A better method for remotely located RTDs is the three-wire RTD connection shown in Figure 3. This circuit offers improved accuracy. RZ’s current is routed through a third wire to the RTD. Assuming line resistance is equal in RTD lines 1 and 2, this produces a small common-mode voltage which is rejected by the XTR112 and XTR114. A second resistor, RLIN2, is required for linearization. 10 V+ E XTR112 XTR114 Note that although the two-wire and three-wire RTD connection circuits are very similar, the gain-setting resistor, RG, has slightly different equations: 8 0.01µF Two-wire: R G = 2.5 • I REF [ R1 ( R 2 + R Z ) – 2( R 2 R Z )] R 2 – R1 IO 7 Three-wire: R G = IRET 6 RQ = 3.3kΩ For operation without external transistor, connect a 3.3kΩ resistor between pin 6 and pin 8. See text for discussion of performance. 2.5 • I REF ( R 2 – R Z )( R1 – R Z ) R 2 – R1 where RZ = RTD resistance at TMIN R1 = RTD resistance at (TMIN + TMAX)/2 R2 = RTD resistance at TMAX IREF = 0.25 for XTR112 IREF = 0.1 for XTR114 FIGURE 2. Operation Without External Transistor. ® 9 XTR112, XTR114 LINEARIZATION RTD temperature sensors are inherently (but predictably) nonlinear. With the addition of one or two external resistors, RLIN1 and RLIN2, it is possible to compensate for most of this nonlinearity resulting in 40:1 improvement in linearity over the uncompensated output. Table I summarizes the resistor equations for two-wire and three-wire RTD connections. An example calculation is also provided. To maintain good accuracy, at least 1% (or better) resistors should be used for RG. Table II provides standard 1% RG values for a three-wire Pt1000 RTD connection with linearization for the XTR112. Table III gives RG values for the XTR114. TWO-WIRE THREE-WIRE RG General Equations = XTR112 (IREF = 0.25) (see Table II) = XTR114 (IREF = 0.1) (see Table III) = IREF • 2.5 [R1 (R2 + RZ) – 2 (R2RZ)] (R2 – R1) 0.625 • [R1 (R2 + RZ) – 2 (R2RZ)] (R2 – R1) 0.25 • [R1 (R2 + RZ) – 2 (R2RZ)] (R2 – R1) RLIN1 = = = 0.4 • RLIN (R2 – R1) IREF • (2R1 – R2 – RZ) 1.6 • RLIN (R2 – R1) (2R1 – R2 – RZ) 4 • RLIN (R2 – R1) (2R1 – R2 – RZ) RG = = = RLIN1 IREF • 2.5 (R2 – RZ) (R1 – RZ)] = (R2 – R1) 0.625 • (R2 – RZ) (R1 – RZ)] = (R2 – R1) 0.25 • (R2 – RZ) (R1 – RZ)] (R2 – R1) = 0.4 • RLIN (R2 – R1) RLIN2 = IREF • (2R1 – R2 – RZ) 1.6 • RLIN (R2 – R1) = (2R1 – R2 – RZ) 4 • RLIN (R2 – R1) (2R1 – R2 – RZ) = 0.4 • (RLIN + RG)(R2 – R1) IREF • (2R1 – R2 – RZ) 1.6 • (RLIN + RG)(R2 – R1) (2R1 – R2 – RZ) 4 • (RLIN + RG)(R2 – R1) (2R1 – R2 – RZ) where RZ = RTD resistance at the minimum measured temperature, TMIN R1 = RTD resistance at the midpoint measured temperature, TMID = (TMIN + TMAX)/2 R2 = RTD resistance at maximum measured temperature, TMAX RLIN = 1kΩ (internal) XTR112 RESISTOR EXAMPLE: The measurement range is –100°C to +200°C for a 3-wire Pt100 RTD connection. Determine the values for RS, RG, RLIN1, and RLIN2. Look up the values from the chart or calculate the values according to the equations provided. METHOD 1: TABLE LOOK UP TMIN = –100°C and ∆T = 300°C (TMAX = +200°C), Using Table II the 1% values are: RZ = 604Ω RLIN1 = 33.2kΩ RG = 750Ω RLIN2 = 59kΩ Calculation of Pt1000 Resistance Values (according to DIN IEC 751) Equation (1) Temperature range from –200°C to 0°C: R(T) = 1000 [1 + 3.90802 • 10–3 • T – 0.5802 • 10–6 • T2 – 4.27350 • 10–12 • (T – 100) • T3] METHOD 2: CALCULATION Step 1: Determine RZ, R1, and R2. RZ is the RTD resistance at the minimum measured temperature, TMIN = –100°C. Using Equation (1) at right gives RZ = 602.5Ω (1% value is 604Ω). R2 is the RTD resistance at the maximum measured temperature, TMAX = 200°C. Using Equation (2) at right gives R2 = 1758.4Ω. R1 is the RTD resistance at the midpoint measured temperature, TMID = (TMIN + TMAX) /2 = (–100 + 200)/2 = 50°C. R1 is NOT the average of RZ and R2. Using Equation (2) at right gives R1 = 1194Ω. Step 2: Calculate RG, RLIN1, and RLIN2 using equations above. Equation (2) Temperature range from 0°C to +850°C: R(T) = 1000 (1 + 3.90802 • 10–3 • T – 0.5802 • 10–6 • T2) where: R(T) is the resistance in Ω at temperature T. T is the temperature in °C. NOTE: Most RTD manufacturers provide reference tables for resistance values at various temperatures. Resistor values for other RTD types (such as Pt2000) can be calculated using the XTR resistor selection program in the Applications Section on Burr-Brown’s web site (www.burrbrown.com) RG = 757Ω (1% value is 750Ω) RLIN1 = 33.322kΩ (1% value is 33.2kΩ) RLIN2 = 58.548kΩ (1% value is 59kΩ) TABLE I. Summary of Resistor Equations for Two-Wire and Three-Wire Pt1000 RTD Connections. ® XTR112, XTR114 10 XTR112 1% RESISTOR VALUES FOR A THREE-WIRE RTD CONNECTION MEASUREMENT TEMPERATURE SPAN ∆T (°C) TMIN 100°C 200°C 300°C 400°C 500°C 600°C 700°C 800°C 900°C 1000°C –200°C 187/267 48700 61900 604/255 86600 110000 187/536 31600 48700 604/499 49900 75000 187/806 25500 46400 604/4750 33200 59000 187/1050 21500 44200 604/1000 24900 49900 187/1330 17800 41200 604/1270 19600 44200 187/1580 15000 39200 604/1500 15800 40200 187/1820 13000 36500 604/1780 13300 37400 187/2100 11300 34800 604/2050 11500 34800 187/2370 9760 33200 604/2260 10000 32400 187/2670 8660 31600 1000/243 105000 130000 1370/237 102000 127000 1000/487 51100 76800 1370/475 49900 73200 1000/732 33200 57600 1370/715 32400 56200 1000/976 1000/1210 1000/1470 1000/1740 1000/1960 24300 19100 15400 13000 11000 48700 42200 38300 35700 33200 1370/953 1370/1180 1370/1430 1370/1690 23700 18700 15000 12400 46400 40200 36500 33200 1740/232 100000 121000 2100/221 95300 118000 1740/464 48700 69800 2100/442 46400 68100 1740/698 31600 53600 2100/665 30100 51100 2490/215 93100 113000 2800/210 887000 107000 2490/432 45300 64900 2800/412 43200 61900 2490/649 29400 48700 2800/619 28000 45300 1740/931 1740/1150 1740/1400 23200 17800 14300 44200 38300 34800 2100/887 2100/1130 22100 17400 NOTE: The values listed in the table are 1% resistors (in Ω). 42200 36500 Exact values may be calculated from the following equations: 2490/866 RZ = RTD resistance at minimum measured temperature, TMIN. 21500 40200 0.625 • (R 2 – R Z ) (R1 – R Z ) RG = (R 2 – R1) 3160/200 86600 102000 3480/191 82500 100000 3160/402 42200 59000 –100°C 0°C 100°C 200°C 300°C 400°C 500°C 600°C 700°C 800°C RZ /RG RLIN1 RLIN2 RLIN1 = 1.6 • RLIN (R 2 – R1) (2R1 – R 2 – R Z ) RLIN2 = 1.6 • (RLIN + RG ) (R 2 – R1) (2R1 – R 2 – R Z ) where R1 = RTD resistance at the midpoint measured temperature, (TMIN + TMAX)/2 R2 = RTD resistance at TMAX 3740/187 80600 95300 RLIN = 1kΩ (Internal) TABLE II. XTR112 RZ, RG, RLIN1, and RLIN2 Standard 1% Resistor Values for Three-Wire Pt1000 RTD Connection with Linearization. XTR114 1% RESISTOR VALUES FOR A THREE-WIRE RTD CONNECTION MEASUREMENT TEMPERATURE SPAN ∆T (°C) TMIN 100°C 200°C 300°C 400°C 500°C 600°C 700°C 800°C 900°C 1000°C –200°C 187/107 121000 133000 604/102 221000 243000 187/215 78700 95300 604/200 124000 150000 187/316 64900 84500 604/301 84500 110000 187/422 53600 76800 604/402 61900 86600 187/523 45300 68100 604/511 48700 73200 187/634 38300 68100 604/604 40200 63400 187/732 32400 56200 604/715 33200 57600 187/845 28000 52300 604/806 28700 52300 187/953 24900 47500 604/909 24900 47500 187/1050 21500 45300 1000/97.6 261000 287000 1370/95.3 255000 280000 1000/196 130000 154000 1370/191 124000 147000 1000/294 84500 107000 1370/287 80600 105000 1000/392 61900 84500 1370/383 59000 82500 1000/487 47500 71500 1370/475 46400 68100 1000/590 39200 61900 1370/576 37400 59000 1000/681 32400 54900 1370/665 31600 52300 1000/787 27400 49900 1740/90.9 249000 267000 2100/88.9 237000 261000 1740/182 121000 143000 2100/178 118000 137000 1740/274 78700 100000 2100/267 75000 95300 1740/365 57600 78700 2100/357 54900 75000 1740/464 44200 64900 2100/348 43200 61900 1740/549 36500 56200 2490/86.6 232000 249000 2800/82.5 221000 243000 2490/174 113000 133000 2800/165 110000 127000 2490/261 73200 93100 2800/49 69800 88700 2490/249 53600 71500 3160/80.6 215000 215000 3480/76.8 205000 221000 3160/162 105000 121000 –100°C 0°C 100°C 200°C 300°C 400°C 500°C 600°C 700°C 800°C 3740/75 200000 215000 RZ /RG RLIN1 RLIN2 NOTE: The values listed in the table are 1% resistors (in Ω). Exact values may be calculated from the following equations: RZ = RTD resistance at minimum measured temperature, TMIN. RG = 0.25 • (R 2 – R Z ) (R1 – R Z ) (R 2 – R1) RLIN1 = 4 • RLIN (R 2 – R1) (2R1 – R 2 – R Z ) RLIN2 = 4 • (RLIN + RG ) (R 2 – R1) (2R1 – R 2 – R Z ) where R1 = RTD resistance at the midpoint measured temperature, (TMIN + TMAX)/2 R2 = RTD resistance at TMAX RLIN = 1kΩ (Internal) TABLE III. XTR114 RZ, RG, RLIN1, and RLIN2 Standard 1% Resistor Values for Three-Wire Pt1000 RTD Connection with Linearization. ® 11 XTR112, XTR114 A typical two-wire RTD application with linearization is shown in Figure 1. Resistor RLIN1 provides positive feedback and controls linearity correction. RLIN1 is chosen according to the desired temperature range. An equation is given in Figure 1. RCM can be adjusted to provide an additional voltage drop to bias the inputs of the XTR112 and XTR114 within their common-mode input range. In three-wire RTD connections, an additional resistor, RLIN2, is required. As with the two-wire RTD application, RLIN1 provides positive feedback for linearization. RLIN2 provides an offset canceling current to compensate for wiring resistance encountered in remotely located RTDs. RLIN1 and RLIN2 are chosen such that their currents are equal. This makes the voltage drop in the wiring resistance to the RTD a commonmode signal which is rejected by the XTR112 and XTR114. The nearest standard 1% resistor values for RLIN1 and RLIN2 should be adequate for most applications. Tables II and III provide the 1% resistor values for a three-wire Pt1000 RTD connection. Table IV shows how to calculate the effect various error sources have on circuit accuracy. A sample error calculation for a typical RTD measurement circuit (Pt1000 RTD, 200°C measurement span) is provided. The results reveal the XTR112’s and XTR114’s excellent accuracy, in this case 1% unadjusted for the XTR112, 1.16% for the XTR114. Adjusting resistors RG and RZ for gain and offset errors improves the XTR112’s accuracy to 0.28% (0.31% for the XTR114). Note that these are worst-case errors; guaranteed maximum values were used in the calculations and all errors were assumed to be positive (additive). The XTR112 and XTR114 achieve performance which is difficult to obtain with discrete circuitry and requires less space. ERROR ANALYSIS If no linearity correction is desired, the VLIN pin should be left open. With no linearization, RG = 2500 • VFS, where VFS = full-scale input range. OPEN-CIRCUIT PROTECTION The optional transistor Q2 in Figure 3 provides predictable behavior with open-circuit RTD connections. It assures that if any one of the three RTD connections is broken, the XTR’s output current will go to either its high current limit (≈ 27mA) or low current limit (≈ 1.3mA for XTR112 and ≈ 1mA for XTR114). This is easily detected as an out-of-range condition. RTDs The text and figures thus far have assumed a Pt1000 RTD. With higher resistance RTDs, the temperature range and input voltage variation should be evaluated to ensure proper common-mode biasing of the inputs. As mentioned earlier, RLIN1(1) 12 1 VLIN IR1 13 RLIN2(1) + VIN 4 IO 14 IR2 11 10 VREG V+ RG XTR112 XTR114 (1) RG 3 2 B 9 E RG Q1 0.01µF 8 IO – VIN 7 IRET EQUAL line resistances here creates a small common-mode voltage which is rejected by XTR112 and XTR114. RZ(1) 1 2 RCM (RLINE2) RTD NOTES: (1) See Table I for resistor equations and 1% values. (2) Q2 optional. Provides predictable output current if any one RTD connection is broken: Q2(2) 2N2222 OPEN RTD TERMINAL 1 2 3 3 FIGURE 3. Three-Wire Connection for Remotely Located RTDs. ® XTR112, XTR114 0.01µF (RLINE1) (RLINE3) Resistance in this line causes a small common-mode voltage which is rejected by XTR112 and XTR114. IO 6 12 XTR112 XTR114 IO IO ≈ 1.3mA ≈ 27mA ≈ 1.3mA ≈ 1mA ≈ 27mA ≈ 1mA SAMPLE ERROR CALCULATION FOR XTR112(1) RTD value at 4mA Output (RRTD MIN) RTD Measurement Range Ambient Temperature Range (∆TA) Supply Voltage Change (∆V+) Common-Mode Voltage Change (∆CM) ERROR SOURCE UNADJ. ADJUST. 526 26 100 16 668 0 26 0 0 26 0.2%/100% • 106 25ppm/V • 5V 0.1%/100% • 250µA • 1000Ω/(250µA • 3.8Ω/°C • 200°C) • 106 2000 125 1316 0 125 0 10ppm/V • 5V • 250µA • 1000Ω/(250µA • 3.8Ω/°C • 200°C) 66 66 Total Excitation Error: 3507 191 Total Gain Error: 2000 100 2100 0 100 100 Total Output Error: 1563 63 1626 0 63 63 158 2 0.5 700 395 500 626 2382 158 2 0.5 700 395 500 626 2382 3 16 2 21 3 16 2 21 10304 (1.03%) 2783 (0.28%) VOS/(VIN MAX) • 106 CMRR • ∆CM/(VIN MAX) • 106 IB/IREF • 106 IOS • RRTD MIN/(VIN MAX) • 106 EXCITATION Current Reference Accuracy vs Supply Current Reference Matching IREF Accuracy (%)/100% • 106 (IREF vs V+) • ∆V+ IREF Matching (%)/100% • IREF • RRTD MIN/(VIN MAX) • 106 (IREF matching vs V+) • ∆V+ • RRTD MIN/(VIN MAX) vs Supply GAIN Span Nonlinearity ERROR (ppm of Full Scale) SAMPLE ERROR CALCULATION(2) ERROR EQUATION INPUT Input Offset Voltage vs Common-Mode Input Bias Current Input Offset Current OUTPUT Zero Output vs Supply 1000Ω 200°C 20°C 5V 0.1V 100µV/(250µA • 3.8Ω/°C • 200°C) • 106 50µV/V • 0.1V/(250µA • 3.8Ω/°C • 200°C) • 106 0.025µA/250µA • 106 3nA • 1000Ω/(250µA • 3.8Ω/°C • 200°C) • 106 Total Input Error: Span Error (%)/100% • 106 Nonlinearity (%)/100% • 106 0.2%/100% • 106 0.01%/100% • 106 (IZERO - 4mA)/16000µA • 106 (IZERO vs V+) • ∆V+/16000µA • 106 25µA/16000µA • 106 0.2µA/V • 5V/16000µA • 106 DRIFT (∆TA = 20°C) Input Offset Voltage Input Bias Current (typical) Input Offset Current (typical) Current Reference Accuracy Current Reference Matching Span Zero Output Drift • ∆TA/(VIN MAX) • 106 Drift • ∆TA/IREF • 106 Drift • ∆TA • RRTD MIN/(VIN MAX) • 106 Drift • ∆TA Drift • ∆TA • IREF • RRTD MIN/(VIN MAX) Drift • ∆TA Drift • ∆TA/16000µA • 106 1.5µV/°C • 20°C/(250µA • 3.8Ω/°C • 200°C) • 106 20pA/°C • 20°C/250µA • 106 5pA/°C • 20°C • 1000Ω/(250µA • 3.8Ω/°C • 200°C) • 106 35ppm/°C • 20°C 15ppm/°C • 20°C • 250µA • 1000Ω/(250µA • 3.8Ω/°C • 200°C) 25ppm/°C • 20°C 0.5µA/°C • 20°C/16000µA • 106 Total Drift Error: NOISE (0.1Hz to 10Hz, typ) Input Offset Voltage Current Reference Zero Output vn/(VIN MAX) • 106 IREF Noise • RRTD MIN/(VIN MAX) • 106 IZERO Noise/16000µA • 106 0.6µV/(250µA • 3.8Ω/°C • 200°C) • 106 3nA • 1000Ω/(250µA • 3.8Ω/°C • 200°C) • 106 0.03µA/16000µA • 106 Total Noise Error: TOTAL ERROR: NOTES: (1) For XTR114, IREF = 100µA. Total unadjusted error is 1.16%, adjusted error 0.31%. (2) All errors are min/max and referred to input, unless otherwise stated. TABLE IV. Error Calculation. REVERSE-VOLTAGE PROTECTION SURGE PROTECTION The XTR112’s and XTR114’s low compliance rating (7.5V) permits the use of various voltage protection methods without compromising operating range. Figure 4 shows a diode bridge circuit which allows normal operation even when the voltage connection lines are reversed. The bridge causes a two diode drop (approximately 1.4V) loss in loop supply voltage. This results in a compliance voltage of approximately 9V—satisfactory for most applications. If 1.4V drop in loop supply is too much, a diode can be inserted in series with the loop supply voltage and the V+ pin. This protects against reverse output connection lines with only a 0.7V loss in loop supply voltage. Remote connections to current transmitters can sometimes be subjected to voltage surges. It is prudent to limit the maximum surge voltage applied to the XTR to as low as practical. Various zener diode and surge clamping diodes are specially designed for this purpose. Select a clamp diode with as low a voltage rating as possible for best protection. For example, a 36V protection diode will assure proper transmitter operation at normal loop voltages, yet will provide an appropriate level of protection against voltage surges. Characterization tests on three production lots showed no damage to the XTR112 or XTR114 within loop supply voltages up to 65V. ® 13 XTR112, XTR114 Most surge protection zener diodes have a diode characteristic in the forward direction that will conduct excessive current, possibly damaging receiving-side circuitry if the loop connections are reversed. If a surge protection diode is used, a series diode or diode bridge should be used for protection against reversed connections. If the RTD sensor is remotely located, the interference may enter at the input terminals. For integrated transmitter assemblies with short connection to the sensor, the interference more likely comes from the current loop connections. Bypass capacitors on the input reduce or eliminate this input interference. Connect these bypass capacitors to the IRET terminal as shown in Figure 5. Although the dc voltage at the IRET terminal is not equal to 0V (at the loop supply, VPS) this circuit point can be considered the transmitter’s “ground.” The 0.01µF capacitor connected between V+ and IO may help minimize output interference. RADIO FREQUENCY INTERFERENCE The long wire lengths of current loops invite radio frequency interference. RF can be rectified by the sensitive input circuitry of the XTR112 and XTR114 causing errors. This generally appears as an unstable output current that varies with the position of loop supply or input wiring. NOTE: (1) Zener Diode 36V: 1N4753A or General Semiconductor TransorbTM 1N6286A. Use lower voltage zener diodes with loop power supply voltages less than 30V for increased protection. See “Over-Voltage Surge Protection.” 10 V+ XTR112 XTR114 0.01µF B E D1(1) 9 1N4148 Diodes RL 8 VPS IO Maximum VPS must be less than minimum voltage rating of zener diode. The diode bridge causes a 1.4V loss in loop supply voltage. 7 IRET 6 FIGURE 4. Reverse Voltage Operation and Over-Voltage Surge Protection. 12 1kΩ 13 4 RLIN1 VLIN + VIN 1 IR1 14 11 IR2 VREG RG RLIN2 XTR112 XTR114 RG 3 10 V+ B E RG 9 8 IO 1kΩ 2 – VIN 7 IRET RZ 0.01µF 6 0.01µF RTD (1) RCM 0.01µF NOTE: (1) Bypass capacitors can be connected to either the IRET pin or the IO pin. FIGURE 5. Input Bypassing Technique with Linearization. ® XTR112, XTR114 14 0.01µF IREG < 2mA Isothermal Block 5V 12 V+ VLIN 13 OPA277 Type J + VIN 1 IR1 14 IR2 11 VREG V– 4 1MΩ(1) 10 V+ RG 1MΩ RG 1250Ω 0.01µF 3 1N4148 XTR112 XTR114 E RG 9 8 IO 20kΩ 2 1kΩ – VIN 7 IRET 6 50Ω 25Ω B + – IO = 4mA + (VIN –VIN) 40 RG RCM(2) NOTES: (1) For burn-out indication. (2) XTR112, RCM = 3.3kΩ XTR114, RCM = 8.2kΩ FIGURE 6. Thermocouple Low Offset, Low Drift Loop Measurement with Diode Cold-Junction Compensation. 12 13 4 VLIN + VIN 3 1N4148 14 11 IR2 10 VREG V+ +12V 1µF RG RG 1270Ω RLIN1 18.7kΩ 1 IR1 XTR112 RG B 9 Q1 0.01µF 16 2 RTD RZ 1370Ω 6 12 RCV420 2 7 IO = 4mA – 20mA VO = 0 to 5V 14 13 IRET Pt1000 100°C to 600°C 11 15 IO – VIN 10 3 E 8 5 4 1µF –12V RCM 0.01µF NOTE: A two-wire RTD connection is shown. For remotely located RTDs, a three-wire RTD conection is recommended. RG becomes 1180Ω, RLIN2 is 40.2kΩ. See Figure 3 and Table II. FIGURE 7. ±12V Powered Transmitter/Receiver Loop. ® 15 XTR112, XTR114 12 RLIN1 RLIN2 13 4 1 IR1 VLIN + VIN 1N4148 14 11 IR2 10 VREG V+ 0 RG 1µF XTR112 XTR114 RG 3 +15V 1µF B E RG 9 Q1 –15V 0.01µF 16 10 3 8 11 12 – 2 VIN IRET 2 7 6 13 4 IO = 4mA – 20mA 14 V+ 1 15 RCV420 IO RZ Isolated Power from PWS740 9 15 ISO124 5 10 7 8 VO 0 – 5V 2 16 RTD V– NOTE: A three-wire RTD connection is shown. For a two-wire RTD connection, eliminate RLIN2. RCM 0.01µF FIGURE 8. Isolated Transmitter/Receiver Loop. 200µA (XTR114) 500µA (XTR112) 12 VLIN + 13 VIN 4 1 IR1 14 IR2 11 VREG 10 V+ RG XTR112 XTR114 RG 3 2 B E RG – VIN 9 8 7 IRET 6 RCM (1) NOTE: (1) Use RCM to adjust the common-mode voltage to within 1.25V to 3.5V. FIGURE 9. Bridge Input, Current Excitation. ® XTR112, XTR114 16 PACKAGE OPTION ADDENDUM www.ti.com 16-Jan-2009 PACKAGING INFORMATION Orderable Device Status (1) Package Type Package Drawing Pins Package Eco Plan (2) Qty XTR112U ACTIVE SOIC D 14 50 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR XTR112UA ACTIVE SOIC D 14 50 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR XTR112UAE4 ACTIVE SOIC D 14 50 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR XTR112UE4 ACTIVE SOIC D 14 50 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR XTR114U ACTIVE SOIC D 14 50 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR XTR114UA ACTIVE SOIC D 14 50 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR XTR114UAE4 ACTIVE SOIC D 14 50 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR XTR114UE4 ACTIVE SOIC D 14 50 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR Lead/Ball Finish MSL Peak Temp (3) (1) The marketing status values are defined as follows: ACTIVE: Product device recommended for new designs. LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect. NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design. PREVIEW: Device has been announced but is not in production. Samples may or may not be available. OBSOLETE: TI has discontinued the production of the device. (2) Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability information and additional product content details. TBD: The Pb-Free/Green conversion plan has not been defined. Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes. Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above. Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material) (3) MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature. Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. 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