FEKT-MRFIAcad. year: 2015/2016
Radio frequency identification is a technology, which has recently experienced a rapid growth. The course will focus on linking of knowledge of radio systems and communication and on developing relationships for the RFID use case. Students will find themselves confronted with the topics of RF hardware design, digital signal processing and efficient and secure wireless communication. Knowledge gained in the course will help students in seeking for opportunities in the industrial sector.
Learning outcomes of the course unit
Students passing the course will be able to:
• Explain fundamental operating principles of passive, semi-passive and active RFID.
• Describe the operation of a transponder in an electromagnetic field.
• Describe the architecture of Electronic Data Carriers, Transponder with Memory Function and Microprocessors-based RFID
• Describe the architecture of an analog frontend of reader and tag and the architecture of the control unit.
• Discuss the properties of the RFID technology in individual frequency bands.
• Design algorithms for digital signal processing (signal shaping, filtering, spectral analysis) in the module of an RFID reader modulator and demodulator.
• Apply the radar equation for signal propagation in real-world scenarios.
The subject knowledge on the Master´s degree level is required.
Recommended optional programme components
Recommended or required reading
Klaus Finkenzeller, RFID Handbook: Fundamentals and Applications in Contactless Smart Cards, Radio Frequency Identification and Near-Field Communication (EN)
Jari-Pascal Curty, Michel Declercq, Catherine Dehollain, Norbert Joehl, Design and Optimization of Passive UHF RFID Systems (EN)
Dominique Paret, RFID at Ultra and Super High Frequencies: Theory and application (EN)
ŽALUD, V., Softwarové a kognitivní rádio (CS)
Planned learning activities and teaching methods
Teaching methods depend on the type of course unit as specified in the article 7 of BUT Rules for Studies and Examinations. Techning methods include lectures, computer laboratories and practical laboratories. Course is taking advantage of e-learning (Moodle) system.
Assesment methods and criteria linked to learning outcomes
Requirements for completion of a course are specified by a regulation issued by the lecturer responsible for the course and they are updated every year. Laboratory mesurements are evaluated with 36 points; final written exam with 64 points. Maximum is 100 points.
Language of instruction
1. Fundamental principles of operation, 1-bit transponder, full-duplex and half-duplex procedures, sequential procedures
2. Inductive coupling, electromagnetic coupling with backscatter, close coupling, electrical coupling, data transfer between a tag and a reader
3. Physical Principles of RFID Systems, Magnetic Field, transponder operation in magnetic field, transponder-reader system, magnetic materials
4. Electromagnetic waves, polarization, principle of microwave transponder in electric field, SAW-transponder
5. Frequency Ranges and Radio Licensing Regulations, coding and modulation, data integrity and security, Standardization, radio interface, protocol structure, coding, anticollision algorithms
6. Antennas from the perspective of tag and reader
7. The Architecture of Electronic Data Carriers, Transponder with Memory Function, Microprocessors-based RFID, Memory Technology
8. Architecture of an analog frontend, control unit, algorithms for performance optimization
9. Sources of noise and methods of its minimization, sensitivity, monostatic and bi-static system, direct coupling of transmitter and receiver
10. Measurement of systems parameters, performance, conformance, LLRP protocol
11. RFID in Wireless Sensor Networks, UWB, Rangin, Practical aspects of RFID systems, application, manufacturing, and internet of things
1. Design of a model of modulator, signal shaping, filtration, spectral analysis, simulation on Labview or Matlab
2. Design of a model of demodulator, signal detection, symbol recognition, simulation on Labview or Matlab
3. Design of parts of the state machine for the EPC Class 1 Gen 2 protocol, simulation on Labview or Matlab. Implementation for a tag and a reader.
4. Linking of previously designed components into a simulation model of the complete system, verification of functionality.
5. Implementation of simulation model of a reader-tag system and verification of functionality of individual modules. Optimization of parameters.
6. Implementation of the designed demodulator for measurements in the HF band using a SW-defined radio platform.
7. Measurement of parameters in HF band, sideband analysis, bits identification and protocol flow.
8. Implementation of the designed UHF demodulator for measurements using software=defined radio
9. Measurement of signals in the UHF band using the designed demodulator, spectral analysis.
10. Analysis of functions of a commercial reader, tracking of the processes of modulation and demodulation, symbol shaping, signal distortion, control of the RF frontend.
The aim of the course is to make students familiar with the use of RF technologies in the radio frequency identification and to strengthen relationships in RF hardware design, digital signal processing and efficient and secure wireless communication.
Specification of controlled education, way of implementation and compensation for absences
The content and forms of instructions in the evaluated course are specified by a regulation issued by the lecturer responsible for the course and they are updated for every academic year. Labs are compulsory.
Classification of course in study plans
- Programme EEKR-M Master's
branch M-EST , 1. year of study, winter semester, 5 credits, optional specialized
- Programme EEKR-M1 Master's
branch M1-EST , 1. year of study, winter semester, 5 credits, optional specialized
- Programme EEKR-CZV lifelong learning
branch ET-CZV , 1. year of study, winter semester, 5 credits, optional specialized