WHEATSTONE BRIDGE CIRCUIT DESIGN AND SIMULATION FOR TEMPERATURE SENSOR�
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The document presents the design and simulation of a Wheatstone bridge circuit for a temperature sensor as part of an embedded systems project. It outlines the objectives, technical concepts, simulation results in LTSpice, LabVIEW, and MATLAB, and includes PCB design considerations. The project concludes with a verified voltage output and adherence to design rules.
![RESISTANCE TEMPERATURE DETECTOR
Seminar Automotive Sensors
Univ.-Prof. Dr.-Ing. O. Kanoun
Chair for Measurement and Sensor Technology
Relation between temperature and resistance:
RT = R0[1 + AT + BT2
+ CT3
(T – 100)] (-200°C < T < 0°C)
RT = R0[1 + AT + BT2
] (0°C < T < 850°C)
Where RT = Resistance of the wire at temperature T°C
Ro = Resistance of the wire at temperature 0°C
α = 0.00385 (°C-1
)
A = 3.9083 X 10 -3
°C-1
B = -5.775 X 10 -7
°C-1
C = -4.183 X 10-12
°C-1](https://image.slidesharecdn.com/finalpresentation4a1-160104214450/85/WHEATSTONE-BRIDGE-CIRCUIT-DESIGN-AND-SIMULATION-FOR-TEMPERATURE-SENSOR-10-320.jpg)
WHEATSTONE BRIDGE CIRCUIT DESIGN AND SIMULATION FOR TEMPERATURE SENSOR�
- 1. 1/xx Group 01 <Please adapt this in the slide master> MEASUREMENT AND SENSOR TECHNOLOGY WHEATSTONE BRIDGE CIRCUIT DESIGN AND SIMULATION FOR TEMPERATURE SENSOR Group – 4A PROJECT LAB EMBEDDED SYSTEMS Chemnitz, 06/25/2015
- 2. CONTENTS Introduction & Motivation Objective General Concept Project Description Conclusion References Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology
- 3. INTRODUCTION & MOTIVATION Temperature plays an important role in many industries both electrical & non-electrical for analyzing properties and behavior of various objects. Industrial Instrumentations. Hot Wire Anemometers. Lab Quality Measurements. Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology
- 4. INTRODUCTION & MOTIVATION Air, Gas & Liquid Monitoring. Petrochemicals. Air Conditioning & Refrigeration. Textile Production Plastics Processing Remote temperature Sensing for Automation Systems. Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology
- 5. OBJECTIVE To Design a Bridge circuit to simulate temperature sensor. To Simulate in LTSpice, Labview & Matlab to analyze the behavior of the temperature sensor. To design a PCB considering all the given design rules. Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology
- 6. GENERAL CONCEPT – TEMPERATURE SENSOR Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology Feature Thermistor RTD Thermocouples Temperature Range (in °C) -90 to 130 -200 to 850 -185 to 2300 Material Used Ceramic or polymer Pure Metals Alloys Accuracy/Linearity Poor Highly Accurate Fairly Good Sensitivity Several Ω /°C 0.00385 Ω /°C (for Platinum) Tens of Micro-volts per degree Figure
- 7. BLOCK DIAGRAM Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology Resistance Change RTD Wheatstone Bridge Difference Amplifier Voltage Change Temperature Change Voltage Response
- 8. RESISTANCE TEMPERATURE DETECTOR Available in 2-wire, 3-wire & 4-wire configuration. Variety of packages - wire-round and thin-film Excellent stability and reproducibility Very good Linearity Extremely accurate Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology
- 9. RESISTANCE TEMPERATURE DETECTOR RT = Resistance of the wire at temperature T°C Ro = Resistance of the wire at temperature 0°C T = Temperature in °C α = Temperature co-efficient of resistance (°C-1 ) For Platinum wire RTD Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology
- 10. RESISTANCE TEMPERATURE DETECTOR Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology Relation between temperature and resistance: RT = R0[1 + AT + BT2 + CT3 (T – 100)] (-200°C < T < 0°C) RT = R0[1 + AT + BT2 ] (0°C < T < 850°C) Where RT = Resistance of the wire at temperature T°C Ro = Resistance of the wire at temperature 0°C α = 0.00385 (°C-1 ) A = 3.9083 X 10 -3 °C-1 B = -5.775 X 10 -7 °C-1 C = -4.183 X 10-12 °C-1
- 11. WHEATSTONE BRIDGE Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology
- 12. DIFFERENTIAL AMPLIFIER Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology
- 13. CIRCUIT DIAGRAM Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology Wheatstone Bridge Buffer Difference Amplifier Voltage Response Temperature Change
- 14. LTSPICE SIMULATION RESULT Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology Temperature (°C) OutputVoltage (volts)
- 15. LABVIEW SIMULATION BLOCK DIAGRAM Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology LabVIEW Block Diagram
- 16. LABVIEW SIMULATION RESULT Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology LabVIEW front panel
- 17. MATLAB SIMULATION RESULTS Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology
- 18. MATLAB SIMULATION RESULTS Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology
- 19. PCB DESIGN Single Sided PCB PCB Size – 0.96 X 1.91 inch Space Between copper layers – 0.2mm Smallest Track Width – 0.2mm Layer thickness – 35µm Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology
- 20. CONCLUSION Bridge circuit was designed to simulate the temperature sensor. Simulation completed in LTSpice, Labview and Matlab. The voltage output was verified. PCB was designed adhering to rules and guidelines. Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology
- 21. REFERENCES Ramon Pallas-Areny, John G. Webster. “Sensors and signal conditioning” – 2nd ed. A Wiley – Interscience Publication. H S Kalsi, “Electronic Instrumentation” Tata McGraw-Hill, 2009 D.Patranabis, “Sensors and Transducers” – 2nd ed. PHI Learning Pvt. Ltd., 2003. A.K. Shawney, Puneet Sawhney, “A Course in Electrical and Electronic Measurements and Instrumentation” – Dhanpat Rai Publications, 2012. Bela G. Liptak, “Instrument Engineers’ Handbook: Process Measurement and Analysis” – 3rd ed., CRC Press, 1995. Doeblin, “Measurement Systems Applications and Design” – 4th ed., Mcgraw-Hill College, 1989. Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology
- 22. Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology
- 23. Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology ADDITIONAL INFORMATION THEORETICAL CALCULATIONS Temperature (°C) Resistance (Ω) Voltage (volts) Amplifier Gain Output Voltage (Volts) -200 18.52 -3.437394533 2.2 -7.56227 -150 39.72 -2.157171486 2.2 -4.74578 -100 60.26 -1.239860227 2.2 -2.72769 -50 80.31 -0.546004104 2.2 -1.20121 0 100 0 2.2 0 50 119.4 0.442114859 2.2 0.972653 100 138.51 0.807303677 2.2 1.776068 150 157.33 1.1139393 2.2 2.450666 200 175.86 1.374972812 2.2 3.02494 250 194.1 1.599795988 2.2 3.519551 300 212.05 1.795385355 2.2 3.949848
- 24. Seminar Automotive Sensors Univ.-Prof. Dr.-Ing. O. Kanoun Chair for Measurement and Sensor Technology ADDITIONAL INFORMATION THEORETICAL CALCULATIONS Temperature (°C) Resistance (Ω) Voltage (volts) Amplifier Gain Output Voltage (Volts) 350 229.72 1.96712362 2.2 4.327672 400 247.09 2.118902878 2.2 4.661586 450 264.18 2.254105113 2.2 4.959031 500 280.98 2.375190299 2.2 5.225419 550 297.49 2.484213439 2.2 5.46527 600 313.71 2.582847889 2.2 5.682265 650 329.64 2.672469975 2.2 5.879434 700 345.28 2.754222063 2.2 6.059289 750 360.64 2.829107329 2.2 6.224036 800 375.7 2.89783477 2.2 6.375236 850 390.48 2.961180884 2.2 6.514598