The state-of-the-art commercially available radio-frequency identification (RFID) transponders are usually composed of an antenna and an application specific integrated circuit chip, which still makes them very costly compared to the well-established barcode technology. Therefore, a novel low-cost RFID system solution based on passive chipless RFID transponders manufactured using conductive strips on flexible substrates is proposed in this work. The chipless RFID transponders follow a specific structure design, which aim is to modify the shape of the impinged electromagnetic wave to embed anidentification code in it and then backscatter the encoded signal to the reader.
This dissertation comprises a multidisciplinary research encompassing the design of low-cost chipless RFID transponders with a novel frequency coding technique, unlike usually disregarded in literature, this approach considers the communication channel effects and assigns a unique frequency response to each transponder. Hence, the identification codes are different enough, to reduce the detection error and improve their automatic recognition by the reader while working under normal conditions. The chipless RFID transponders are manufactured using different materials and state-of-the-art mass production fabrication processes, like printed electronics. Moreover, two different reader front-ends working in the ultra-wideband (UWB) frequency range are used to interrogate the chipless RFID transponders. The first one is built using high-performance off-theshelf components following the stepped frequency modulation (SFM) radar principle, and the second one is a commercially available impulse radio (IR) radar.
Finally, the two readers are programmed with algorithms based on the conventional minimum distance and maximum likelihood detection techniques, considering the whole transponder radio frequency (RF) response, instead of following the commonly used approach of focusing on specific parts of the spectrum to detect dips or peaks. The programmed readers automatically identify when a chipless RFID transponder is placed within their interrogation zones and proceed to the successful recognition of its embedded identification code. Accomplishing in this way, two novel fully automatic SFM- and IRRFID readers for chipless transponders. The SFM-RFID system is capable to successfully decode up to eight different chipless RFID transponders placed sequentially at a maximum reading range of 36 cm. The IR-RFID system up to four sequentially and two simultaneously placed different chipless RFID transponders within a 50 cm range.:Acknowledgments
Abstract
Kurzfassung
Table of Contents
Index of Figures
Index of Tables
Index of Abbreviations
Index of Symbols
1 Introduction
1.1 Motivation
1.2 Scope of Application
1.3 Objectives and Structure
Fundamentals of the RFID Technology
2.1 Automatic Identification Systems Background
2.1.1 Barcode Technology
2.1.2 Optical Character Recognition
2.1.3 Biometric Procedures
2.1.4 Smart Cards
2.1.5 RFID Systems
2.2 RFID System Principle
2.2.1 RFID Features
2.3 RFID with Chipless Transponders
2.3.1 Time Domain Encoding
2.3.2 Frequency Domain Encoding
2.4 Summary
Manufacturing Technologies
3.1 Organic and Printed Electronics
3.1.1 Substrates
3.1.2 Organic Inks
3.1.3 Screen Printing
3.1.4 Flexography
3.2 The Printing Process
3.3 A Fabrication Alternative with Aluminum or Copper Strips
3.4 Fabrication Technologies for Chipless RFID Transponders
3.5 Summary
UWB Chipless RFID Transponder Design
4.1 Scattering Theory
4.1.1 Radar Cross-Section Definition
4.1.2 Radar Absorbing Material’s Principle
4.1.3 Dielectric Multilayers Wave Matrix Analysis
4.1.4 Frequency Selective Surfaces
4.2 Double-Dipoles UWB Chipless RFID Transponder
4.2.1 An Infinite Double-Dipole Array
4.2.2 Double-Dipoles UWB Chipless Transponder Design
4.2.3 Prototype Fabrication
4.3 UWB Chipless RFID Transponder with Concentric Circles
4.3.1 Concentric Circles UWB Chipless Transponder
4.3.2 Concentric Rings UWB Chipless RFID Transponder
4.4 Concentric Octagons UWB Chipless Transponders
4.4.1 Concentric Octagons UWB Chipless Transponder Design 1
4.4.2 Concentric Octagons UWB Chipless Transponder Design 2
4.5 Summary
5. RFID Readers for Chipless Transponders
5.1 Background
5.1.1 The Radar Range Equation
5.1.2 Range Resolution
5.1.3 Frequency Band Selection
5.2 Frequency Domain Reader Test System
5.2.1 Stepped Frequency Waveforms
5.2.2 Reader Architecture
5.2.3 Test System Results
5.3 Time Domain Reader
5.3.1 Novelda Radar
5.3.2 Test System Results
5.4 Summary
Detection of UWB Chipless RFID Transponders
6.1 Background
6.2 The Communication Channel
6.2.1 AWGN Channel Modeling and Detection
6.2.2 Free-Space Path Loss Modeling and Normalization
6.3 Detection and Decoding of Chipless RFID Transponders
6.3.1 Minimum Distance Detector
6.3.2 Maximum Likelihood Detector
6.3.3 Correlator Detector
6.3.4 Test Results
6.4 Simultaneous Detection of Multiple UWB Chipless Transponders
6.5 Summary
System Implementation
7.1 SFM-UWB RFID System with CR-Chipless Transponders
7.2 IR-UWB RFID System with COD1-Chipless Transponders
7.3 Summary
Conclusion and Outlook
References
Publications
Appendix A
RCS Calculation
Measurement Setups
Appendix B
Resistance and Skin Depth Calculation
Appendix C
List of Videos
Test Videos
Consortium Videos
Curriculum Vita