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Novel Analog Ratio-Metric Optical Rotary Encoder for Avionic Applications | IEEE Journals & Magazine | IEEE Xplore
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Journals & Magazines >IEEE Sensors Journal >Volume: 16 Issue: 17

Novel Analog Ratio-Metric Optical Rotary Encoder for Avionic Applications

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Tahereh Ahmadi Tameh; Mohamad Sawan; Raman Kashyap
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Abstract:

In this paper, an optical, analog, self-referencing, ratio-metric, smart displacement sensor is proposed for avionic applications. The position of rotation is determined ...Show More

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Abstract:

In this paper, an optical, analog, self-referencing, ratio-metric, smart displacement sensor is proposed for avionic applications. The position of rotation is determined by the ratio of the transmitted and reflected light powers, which makes the sensor independent of power fluctuations. A single multi-gradient encoder design compensates for the use of a non-uniform source. An anti-reflection coated glass window with the outer diameter of 27 mm is used with an encoder pattern mapped on it by aluminum deposition. The experimental results show that the ratio of the transmitted and reflected powers has an accuracy of 0.53% over the full range, matching the specifications for avionic applications. It is also experimentally proved that the sensor operates ratio-metrically and not affected by the change in the source power, which makes it highly reliable for the avionic application. Further optimization of the design will make this type of sensor an excellent choice for future lightweight and greener aircraft technology.
Published in: IEEE Sensors Journal ( Volume: 16, Issue: 17, September 2016)
Page(s): 6586 - 6595
Date of Publication: 07 July 2016

ISSN Information:

DOI: 10.1109/JSEN.2016.2588981

Funding Agency:

Citations are not available for this document.
Contents

I. Introduction

Rotary sensors are key components in several systems, such as motion capture devices [1], [2], industrial control application to monitor rotation of mechanical parts [1], [3]–[5], and automotive sensors for tracking steering-angle [1], [6], [7]. Rotary displacement sensors are widely employed in fly-by-wire aircraft and avionics systems for flight control purposes [8]–[12].

Cites in Papers - |

Cites in Papers - IEEE (20)

Select All
1.
Shuang Du, Yu Liang, Kai Wang, Dongning Hao, Wei Zhang, Tingting Wu, Yingxu Zhou, "Absolute Optical Encoder Chip With Self-Reference Compensation", IEEE Sensors Journal, vol.25, no.4, pp.6261-6268, 2025.
Show Article
Google Scholar
2.
Min Fu, Shuang Qiu, Ge Zhu, Baokang Xiang, Xiangyun Zhang, Kuo Luo, "Research on a Long-Range and Single-Track Absolute Displacement Sensor With Simple Graphic Shift Coding", IEEE Sensors Journal, vol.24, no.10, pp.16563-16575, 2024.
Show Article
Google Scholar
3.
Zahra Mehrjoo, Amir Ebrahimi, Grzegorz Beziuk, Ferran Martín, Kamran Ghorbani, "Microwave Rotation Sensor Based on Reflection Phase in Transmission Lines Terminated With Lumped Resonators", IEEE Sensors Journal, vol.23, no.7, pp.6571-6580, 2023.
Show Article
Google Scholar
4.
Liantan Luo, Xianghua Huang, Tianhong Zhang, "Simulation and Experiment on a Novel Integrated Measurement System of Pitch Angle, Phase Angle, and Speed of Turboprop Engine", IEEE Sensors Journal, vol.22, no.8, pp.8123-8133, 2022.
Show Article
Google Scholar
5.
Chi-Hung Lee, Hsin-Jung Huang, Jui-Ping Chang, Yi-Cheng Chen, "Incremental Optical Encoder Based on a Sinusoidal Transmissive Pattern", IEEE Photonics Journal, vol.14, no.1, pp.1-6, 2022.
Show Article
Google Scholar
6.
Bikram Bhandari, Bikrant Poudel, Ebrahim Amiri, Parviz Rastgoufard, "A Novel Variable Reluctance Resolver With Simplified Winding Arrangement and Adaptive PI Controller", 2021 IEEE International Electric Machines & Drives Conference (IEMDC), pp.1-6, 2021.
Show Article
Google Scholar
7.
Fan Zhang, Li Wang, Jianhui Zhang, "A Visual-Based Angle Measurement Method Using the Rotating Spot Images: Mathematic Modeling and Experiment Validation", IEEE Sensors Journal, vol.21, no.15, pp.16576-16583, 2021.
Show Article
Google Scholar
8.
A. S. Anil Kumar, Boby George, Subhas Chandra Mukhopadhyay, "Technologies and Applications of Angle Sensors: A Review", IEEE Sensors Journal, vol.21, no.6, pp.7195-7206, 2021.
Show Article
Google Scholar
9.
Xu Gao, Shuhang Li, Qinglin Ma, "Subdivided Error Correction Method for Photoelectric Axis Angular Displacement Encoder Based on Particle Swarm Optimization", IEEE Transactions on Instrumentation and Measurement, vol.69, no.10, pp.8372-8382, 2020.
Show Article
Google Scholar
10.
Nandapurkar Kishor Bhaskarrao, Chandrika Sreekantan Anoop, Pranab Kumar Dutta, "Oscillator-Less Direct-Digital Front-End Realizing Ratiometric Linearization Schemes for TMR-Based Angle Sensor", IEEE Transactions on Instrumentation and Measurement, vol.69, no.6, pp.3005-3014, 2020.
Show Article
Google Scholar
11.
Zhuoling Zeng, Fan Zhang, Weiqing Huang, "The Method for Measuring Center Coordinates of the Out-of-Focus Spot", 2019 4th International Conference on Mechanical, Control and Computer Engineering (ICMCCE), pp.510-5103, 2019.
Show Article
Google Scholar
12.
Rahul Kumar, British Ashok Sontakke, C.S. Anoop, "A Hall Effect Based Through Shaft Angle Sensor - Analysis and Signal Conditioning", 2019 IEEE International Instrumentation and Measurement Technology Conference (I2MTC), pp.1-6, 2019.
Show Article
Google Scholar
13.
Shigeru Oho, Yuto Kaneko, Masaharu Hara, Yoshiji Oose, Jun Fukuda, "Practical Aspects of Ultrasonic Rotary Encoder—Probe Placing, Real-Time Operation, and Automotive Bench Test", IEEE Transactions on Instrumentation and Measurement, vol.68, no.7, pp.2335-2345, 2019.
Show Article
Google Scholar
14.
Narendiran Anandan, Aditya Varma Muppala, Boby George, "A Flexible, Planar-Coil-Based Sensor for Through-Shaft Angle Sensing", IEEE Sensors Journal, vol.18, no.24, pp.10217-10224, 2018.
Show Article
Google Scholar
15.
Sarbajit Paul, Junghwan Chang, John Edward Fletcher, Subhas Mukhopadhyay, "A Novel High-Resolution Optical Encoder With Axially Stacked Coded Disk for Modular Joints: Physical Modeling and Experimental Validation", IEEE Sensors Journal, vol.18, no.14, pp.6001-6008, 2018.
Show Article
Google Scholar
16.
Masaharu Hara, Shigeru Oho, Yuto Kaneko, "An ultrasonic rotary encoder and its application to torque estimation", 2018 IEEE Sensors Applications Symposium (SAS), pp.1-6, 2018.
Show Article
Google Scholar
17.
Tahereh Ahmadi Tameh, Raman Kashyap, Mohamad Sawan, "Self-Referenced Broad-Range Optical Rotation Sensor for Flight Control Applications", Journal of Lightwave Technology, vol.36, no.10, pp.2000-2009, 2018.
Show Article
Google Scholar
18.
Subir Das, Badal Chakraborty, "Design and Realization of an Optical Rotary Sensor", IEEE Sensors Journal, vol.18, no.7, pp.2675-2681, 2018.
Show Article
Google Scholar
19.
Tahereh Ahmadi Tameh, Mohamad Sawan, Raman Kashyap, "Smart Integrated Optical Rotation Sensor Incorporating a Fly-by-Wire Control System", IEEE Transactions on Industrial Electronics, vol.65, no.8, pp.6505-6514, 2018.
Show Article
Google Scholar
20.
Srinivas Rana, Boby George, V. Jagadeesh Kumar, "Non-contact inductive displacement-to-digital converter", 2017 IEEE International Instrumentation and Measurement Technology Conference (I2MTC), pp.1-6, 2017.
Show Article
Google Scholar

Cites in Papers - Other Publishers (9)

1.
Yao Huang, Shuangliang Che, Weibin Zhu, Cheng Ma, Yi Zhou, Wei Zou, Zi Xue, "An Eccentricity Error Separation Method for Rotary Table Based on Phase Feature of Moiré Signal of Single Reading Head", Photonics, vol.10, no.11, pp.1267, 2023.
CrossRef Google Scholar
2.
Han Hou, Guohua Cao, Hongchang Ding, Kun Li, "Research on Particle Swarm Compensation Method for Subdivision Error Optimization of Photoelectric Encoder Based on Parallel Iteration", Sensors, vol.22, no.12, pp.4456, 2022.
CrossRef Google Scholar
3.
Jianwei Shi, Abdul Ghaffar, Yongwei Li, Irfan Mehdi, Rehan Mehdi, Fayaz A. Soomro, Sadam Hussain, Mujahid Mehdi, Qiang Li, Zhiqiang Li, "Dynamic Rotational Sensor Using Polymer Optical Fiber for Robot Movement Assessment Based on Intensity Variation", Polymers, vol.14, no.23, pp.5167, 2022.
CrossRef Google Scholar
4.
Xi Wang, Yu Liang, Wei Zhang, Xue Yang, Dongning Hao, "An Optical Encoder Chip with Area Compensation", Electronics, vol.11, no.23, pp.3997, 2022.
CrossRef Google Scholar
5.
Jiaqi Jiang, Jiahai Dai, Hongbo Zhang, Yusong Mu, Yunchun Chang, "Improving the subdivision accuracy of photoelectric encoder using particle swarm optimization algorithm", Optical and Quantum Electronics, vol.54, no.2, 2022.
CrossRef Google Scholar
6.
Ferran Paredes, Cristian Herrojo, Ferran Martín, "Position Sensors for Industrial Applications Based on Electromagnetic Encoders", Sensors, vol.21, no.8, pp.2738, 2021.
CrossRef Google Scholar
7.
Guobo Zhao, Guoyong Ye, Zeze Wu, Hongwen Xing, Siren Liu, Xiaojun Fan, Yingjiang Li, Pingping Wei, Hongzhong Liu, "On-line angle self-correction strategy based on a cobweb-structured grating scale", Measurement Science and Technology, vol.32, no.5, pp.055001, 2021.
CrossRef Google Scholar
8.
Debao Zhang, Guanjun You, "Miniaturization design of all-optical encoder based on surface design and radiation source control", Physica E: Low-dimensional Systems and Nanostructures, vol.127, pp.114469, 2021.
CrossRef Google Scholar
9.
Yirga Belay Muna, Cheng-Chien Kuo, "Magnetic field distribution of magnetic encoder with TMR sensor using finite element analysis", Microsystem Technologies, vol.26, no.8, pp.2683, 2020.
CrossRef Google Scholar
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