CALL FOR PAPERS


The URSI-RCRS 2022 Scientific Program Committee cordially invites you to submit papers for oral and poster presentations in the conference. Authors must electronically submit either an Extended Abstract (minimum 250 words, maximum one page) or a Summary Paper (minimum two pages, maximum four pages) by 31 August, 2022.

All the submitted papers will undergo a peer review process by experts on the subject and, if accepted, will be assigned to the appropriate session for presentations (oral/poster). One author registration will allow presentation of up to two papers in the conference. Papers presented at this URSI-RCRS 2022 will be submitted for posting to IEEE Xplore. In addition, there will be special programmes for URSI young scientists and a student paper competition for graduate students. The updated flyer of the conference can be found here.

URSI-RCRS_2022_CFP_Ex.pdf

Important Dates:

Paper Submission opens: 1 July, 2022

Paper Submission deadline: 16 August, 2022 26 August, 2022 31 August, 2022

Notification of Paper Acceptance:

20 September, 2022

Early Bird Registration: 24 October, 2022

Conference Date: 1- 4 December, 2022

Contributions are solicited in the topics that include but are not limited to, the Ten Scientific Commissions of URSI, as mentioned below. The final sessions will be configured on the basis of the submission of papers under different subtopics.

Commission A: Electromagnetic Metrology

  • A01: Antenna and Propagation Measurement Techniques

  • A02: Measurements in Advanced Communication Systems

  • A03: Characterization of Electromagnetic Properties of Materials

  • A04: Properties of Engineered Materials including Nanotechnology

  • A05: Physical constants, Primary and Secondary Standards

  • A06: Realization and Dissemination of Time Scales and Standard Frequencies

  • A07: Methodology of Electromagnetic Dosimetry

  • A08: Measurements for Health Diagnostics, Applications and Biotechnology, including Bio-sensing

  • A09: Space Metrology

  • A10: Calibration, Traceability, and Inter Comparisons of Instruments and Measurements

  • A11: Quantification of Accuracy and Uncertainty

  • A12: Smart City as a measurement hub

  • A13: Metrology Techniques and Solutions enabled by Artificial Intelligence

  • A14: Quantum Metrology

  • A15: Precision Metrology - Practice, Education and Prospects

  • A16: Microwave and Optical Frequency Standards

  • A17: Time and Frequency Metrology

  • A18: Advanced Time & Frequency Transfer Techniques and Precision Geolocation

Commission B: Fields and Waves Antenna arrays

  • B01: Antenna theory, design, and measurement

  • B02: Advanced algorithms in computational electromagnetics

  • B03: Antennas and microwave imaging for biomedical applications

  • B04: Scattering and diffraction

  • B05: Electromagnetic theory

  • B06: Materials in electromagnetics

  • B07: Machine Learning, Artificial Intelligence, and Novel Optimization Techniques in Electromagnetics

  • B08: Millimeter-wave antennas/5G communications

  • B09: Terahertz Antenna Systems

Commission C: Radiocommunication Systems and Signal Processing

  • C01 : Concepts and ideas for new future consumer wireless communications paradigms

  • C02 : 5G and future wireless systems

  • C03 : Reconfigurable intelligent surfaces

  • C04 : Advanced digital communications schemes

  • C05 : Wireless Power Transfer

  • C06 : Satellite Systems & positioning

  • C07 : Efficient & Green Communications

  • C08 : AI & Machine learning in communications

  • C09: Information Theory, Coding, Modulation and Detection

  • C10: Spectrum and Medium Utilization, including cognitive and cooperative techniques

  • C11: Wireless networking

  • C12: Radar, radio localization and navigation systems

  • C13: Signal Processing

Commission D: Electronics and Photonics

  • D01 : Convergence of photonics and radio systems Towards 6G

  • D02 : Multiphysics modelling in electronics, photonics and plasmonics

  • D03 : Plasmonics, metamaterials and metasurfaces

  • D04 : Photonics and electronics for space applications

  • D05 : Electronic and photonic components for THz Communications

  • D06 : Energy Harvesting for IoT Applications

Commission E: Electromagnetic Environment and Interference

  • E01 : EMC Analytical and Numerical Modeling and stochastic analysis

  • E02: EMC Measurement Techniques and Standards

  • E03: HPEM, Intentional EMI, Radiation Hazards, Lightning

  • E04 : EMC and EMI in Wired and Wireless Communications

  • E05 : Machine Learning & Signal Processing to Analyze & Mitigate EMI

  • E06 : RFI Mitigation Techniques in Radio Astronomy

  • EFGH : Natural Electromagnetic Noise & Radio Sensing Applications in Terrestrial & Planetary Environment

  • EC1 : EM Security of Cyber-physical Systems and Wireless Technologies

  • EJ : EMC Issues in Integration of Digital and Analog Electronics

Commission F: Wave Propagation and Remote Sensing

  • F01 : Radiowave Propagation and Channel Modelling for Wireless Communication.

  • F02 : Remote Sensing of Clouds, Precipitation, and Aerosols

  • F03 : Remote Sensing of Atmospheric Composition Chemistry and Climate Aspects

  • F04 : Remote Sensing of Land, Vegetation, Biomass, Soil Moisture, Snow and Sea Surface

  • F05 : Remote Sensing of Earth and Planetary Atmospheres

  • F06 : Remote Sensing using Atmospheric Radars

  • F07 : Remote Sensing from Nano and Small Satellites

  • F08 : Remote Sensing of Severe Weather and Disaster Mitigation

  • F09 : AI for Remote Sensing

Commission G: Ionospheric Radio and Propagation

  • G01: GNSS Radio Occultation: Measurements, data assimilation and models

  • G02 : Novel radio instruments and techniques for Space Weather model validation and testing

  • G03 : Ionospheric Space Weather and Impacts on Technological Systems

  • G04: Recent advances on ionospheric perturbation indices and scales

  • G05 : Machine Learning methods for ionospheric modeling: state of the art and future actions

  • G07 : (Ionospheric) Space Weather operational services

  • G08 : Limits of predictability of ionosphere behavior

  • GBC1 : HF Radars for Science and Surveillance

Commission H: Waves in Plasma

  • H01 : Recent advances in geospace research from multi-point observations

  • H02 : Radio Diagnostics of Space Weather Plasma Processes

  • H03 : Machine learning techniques and their application to plasma waves

  • HEG : Atmospheric, Ionospheric, Magnetospheric & High Energy Effects of Lightning Discharges

  • HJ : Computer simulations in space plasmas

Commission J: Radio Astronomy

  • J01 : New Telescopes

  • J02 : VLBI

  • J03 : Time-domain astronomy - observations and instrumentation

  • J04 : Cosmological HI - observations and instrumentation

  • J05 : Wide-field radio astronomy

  • J06 : Space-based radio astronomy

  • J07 : Calibration and instrumentation

  • J08 : CEM method for radio astronomy

  • J09 : Receiving systems and their components

  • J10 : Big Data and AI in radio interferometry

  • J11: Latest new and observatory reports (open session)

  • JE : EMC issues in integration of digital and analog electronics

  • JG : Mutual Benefit between radio astronomy and ionospheric science

  • JH : Solar, heliospheric and planetary physics

Commission K: Electromagnetics in Biology and Medicine

  • K01 : Biological effects and related mechanisms of EMF exposure

  • K02 : Molecular targets in bioelectromagnetics

  • K03 : Dosimetry and exposure assessment: extremely low and intermediate frequencies

  • K04 : Recent progress and new frontiers in RF dosimetry and exposure assessment

  • K05 : Monitoring EMF exposure in vivo and in vitro.

  • K06 : Electromagnetic biomedical Imaging

  • K07 : Dielectric spectroscopy and the dielectric properties of biological matter, from molecules to tissues

  • K08 : Developments on experimental and numerical phantoms for electromagnetic biomedical applications

  • K09 : Therapeutic, Healthcare and Rehabilitative Applications of EMF

  • K10: Any other aspect of Electromagnetics in Biology and Medicine