Radar Cross Section of Chipless RFID tags and BER Performance

TL;DR

This paper analyzes how the Radar Cross Section (RCS) of chipless RFID tags affects their Bit Error Rate (BER), showing that resonator arrangement significantly influences RCS and system performance, with periodic configurations offering optimal results.

Contribution

It introduces a theoretical and experimental framework for evaluating RCS and BER in chipless RFID tags, highlighting the importance of resonator arrangement for optimal performance.

Findings

Periodic resonator arrangements maximize RCS

Higher RCS correlates with lower BER

Theoretical array theory accurately predicts RCS

Abstract

The performance of different chipless RFID tag topologies are analysed in terms of Radar Cross Section (RCS) and Bit Error Rate (BER). It is shown that the BER is mainly determined by the tag Radar Cross Section (RCS) once that a standard reading scenario is considered and a fixed size of the tag is chosen. It is shown that the arrangement of the resonators in the chipless tag plays a crucial role in determining the cross-polar RCS of the tag. The RCS of the tag is computed theoretically by using array theory where each resonator is treated as a separate scatterer completely characterized by a specific reflection coefficient. Several resonators arrangements (periodic and non-periodic) are compared, keeping the physical area of the tag fixed. Theoretical and experimental analysis demonstrate that the periodic configuration guarantees the maximum achievable RCS thus providing a global lower BER of the chipless RFID communication system. We believe that the BER is the more meaningful and fair figure of merit for comparing the performance of different tags than bit/cm2 or bit/Hz since the increase of encoded information of the tag is useful only if it can be correctly decoded.