3D-Printed All-Dielectric Electromagnetic Encoders with Synchronous Reading for Measuring Displacements and Velocities

In this paper, 3D-printed electromagnetic (or microwave) encoders with synchronous reading based on permittivity contrast, and devoted to the measurement of displacements and velocities, are reported for the first time. The considered encoders are based on two chains of linearly shaped apertures made on a 3D-printed high-permittivity dielectric material. One such aperture chain contains the identification (ID) code, whereas the other chain provides the clock signal. Synchronous reading is necessary in order to determine the absolute position if the velocity between the encoder and the sensitive part of the reader is not constant. Such absolute position can be determined as long as the whole encoder is encoded with the so-called de Bruijn sequence. For encoder reading, a splitter/combiner structure with each branch loaded with a series gap and a slot resonator (each one tuned to a different frequency) is considered. Such a structure is able to detect the presence of the apertures when the encoder is displaced, at short distance, over the slots. Thus, by injecting two harmonic signals, conveniently tuned, at the input port of the splitter/combiner structure, two amplitude modulated (AM) signals are generated by tag motion at the output port of the sensitive part of the reader. One of the AM envelope functions provides the absolute position, whereas the other one provides the clock signal and the velocity of the encoder. These synchronous 3D-printed all-dielectric encoders based on permittivity contrast are a good alternative to microwave encoders based on metallic inclusions in those applications where low cost as well as major robustness against mechanical wearing and aging effects are the main concerns.

[1]  Javier Mata-Contreras,et al.  Differential Microfluidic Sensors Based on Dumbbell-Shaped Defect Ground Structures in Microstrip Technology: Analysis, Optimization, and Applications , 2019, Sensors.

[2]  Derek Abbott,et al.  Rotation Sensor Based on Horn-Shaped Split Ring Resonator , 2013, IEEE Sensors Journal.

[3]  Cristian Herrojo,et al.  Near-Field Chipless-RFID System With High Data Capacity for Security and Authentication Applications , 2017, IEEE Transactions on Microwave Theory and Techniques.

[4]  Cristian Herrojo,et al.  Enhancing the Per-Unit-Length Data Density in Near-Field Chipless-RFID Systems With Sequential Bit Reading , 2019, IEEE Antennas and Wireless Propagation Letters.

[5]  Derek Abbott,et al.  Metamaterial-Inspired Rotation Sensor With Wide Dynamic Range , 2014, IEEE Sensors Journal.

[6]  Christophe Fumeaux,et al.  Rotation sensing based on the symmetry properties of an open-ended microstrip line loaded with a split ring resonator , 2015, 2015 German Microwave Conference.

[7]  Cristian Herrojo,et al.  An approach for Synchronous Reading of Near-Field Chipless-RFID Tags , 2019, 2019 IEEE International Conference on RFID Technology and Applications (RFID-TA).

[8]  Cristian Herrojo,et al.  Double-Stub Loaded Microstrip Line Reader for Very High Data Density Microwave Encoders , 2019, IEEE Transactions on Microwave Theory and Techniques.

[9]  Maurizio Bozzi,et al.  Design of Microwave-Based Angular Displacement Sensor , 2019, IEEE Microwave and Wireless Components Letters.

[10]  Cristian Herrojo,et al.  Near-Field Chipless-RFID System With Erasable/Programmable 40-bit Tags Inkjet Printed on Paper Substrates , 2018, IEEE Microwave and Wireless Components Letters.

[11]  Cristian Herrojo,et al.  On the Sensitivity of Microwave Sensors based on Slot Resonators and Frequency Variation , 2019, 2019 International Conference on Electromagnetics in Advanced Applications (ICEAA).

[12]  Wai-Wa Choi,et al.  An Angular Displacement Sensor Based on Microstrip Wideband Impedance Transformer With Quasi-Chebyshev Frequency Response , 2020, IEEE Sensors Journal.

[13]  Cristian Herrojo,et al.  Time-Domain-Signature Chipless RFID Tags: Near-Field Chipless-RFID Systems With High Data Capacity , 2019, IEEE Microwave Magazine.

[14]  Cristian Herrojo,et al.  High data density and capacity in chipless radiofrequency identification (chipless-RFID) tags based on double-chains of S-shaped split ring resonators (S-SRRs) , 2017 .

[15]  de Ng Dick Bruijn,et al.  Acknowledgement of priority to C. Flye Sainte-Marie on the counting of circular arrangements of $2^n$ zeros and ones that show each n-letter word exactly once , 1975 .

[16]  Xin Li,et al.  Bias-tunable dual-mode ultraviolet photodetectors for photoelectric tachometer , 2014 .

[17]  Cristian Herrojo,et al.  Very low-cost 80-Bit chipless-RFID tags inkjet printed on ordinary paper , 2018 .

[18]  Cristian Herrojo,et al.  Application of Split Ring Resonator (SRR) Loaded Transmission Lines to the Design of Angular Displacement and Velocity Sensors for Space Applications , 2017, IEEE Transactions on Microwave Theory and Techniques.

[19]  F. Martín,et al.  Near-field chipless-RFID tags with sequential bit reading implemented in plastic substrates , 2017, Journal of Magnetism and Magnetic Materials.

[20]  Cristian Herrojo,et al.  High-Density Microwave Encoders for Motion Control and Near-Field Chipless-RFID , 2019, IEEE Sensors Journal.

[21]  Ferran Martin,et al.  Application of broadside-coupled split ring resonator (BC-SRR) loaded transmission lines to the design of rotary encoders for space applications , 2016, 2016 IEEE MTT-S International Microwave Symposium (IMS).

[22]  Cristian Herrojo,et al.  Near-field chipless RFID encoders with sequential bit reading and high data capacity , 2017, 2017 IEEE MTT-S International Microwave Symposium (IMS).

[23]  Cristian Herrojo,et al.  Chipless-RFID Sensors for Motion Control Applications , 2020, 2020 XXXIIIrd General Assembly and Scientific Symposium of the International Union of Radio Science.

[24]  Cristian Herrojo,et al.  All-dielectric Electromagnetic Encoders based on Permittivity Contrast for Displacement/Velocity Sensors and Chipless-RFID Tags , 2019, 2019 IEEE MTT-S International Microwave Symposium (IMS).

[25]  Cristian Herrojo,et al.  Time-Domain Signature Barcodes for Chipless-RFID and Sensing Applications , 2020, Lecture Notes in Electrical Engineering.

[26]  Cristian Herrojo,et al.  Electromagnetic Rotary Encoders based on Split Ring Resonators (SRR) Loaded Microstrip Lines , 2018, 2018 IEEE/MTT-S International Microwave Symposium - IMS.

[27]  Cristian Herrojo,et al.  3-D-Printed High Data-Density Electromagnetic Encoders Based on Permittivity Contrast for Motion Control and Chipless-RFID , 2020, IEEE Transactions on Microwave Theory and Techniques.

[28]  Cristian Herrojo,et al.  Detecting the Rotation Direction in Contactless Angular Velocity Sensors Implemented With Rotors Loaded With Multiple Chains of Resonators , 2018, IEEE Sensors Journal.

[29]  Rolf Jakoby,et al.  Passive chipless wireless sensor for two-dimensional displacement measurement , 2011, 2011 41st European Microwave Conference.

[30]  Cristian Herrojo,et al.  Microwave Encoders with Synchronous Reading and Direction Detection for Motion Control Applications , 2020, 2020 IEEE/MTT-S International Microwave Symposium (IMS).

[31]  Douglas M. Considine,et al.  Process Instruments and Controls Handbook , 1957 .

[32]  Ozgur Kurc,et al.  A Wireless Metamaterial-Inspired Passive Rotation Sensor With Submilliradian Resolution , 2018, IEEE Sensors Journal.

[33]  Ferran Martín,et al.  Artificial Transmission Lines for RF and Microwave Applications: Martín/Artificial Transmission Lines for RF and Microwave Applications , 2015 .

[34]  Cristian Herrojo,et al.  Microwave Encoders for Chipless RFID and Angular Velocity Sensors Based on S-Shaped Split Ring Resonators , 2017, IEEE Sensors Journal.

[35]  Cristian Herrojo,et al.  High Data Density Near-Field Chipless-RFID Tags With Synchronous Reading , 2020, IEEE Journal of Radio Frequency Identification.