UHF-RFID Backscatter Channel Analysis for Accurate Wideband Ranging

Stefan Josef Grebien; J. Kulmer; M. Goller; F. Galler; H. Arthaber; K. Witrisal

doi:10.1109/RFID.2017.7945596

UHF-RFID Backscatter Channel Analysis for Accurate Wideband Ranging

Stefan Josef Grebien, J. Kulmer, M. Goller, F. Galler, H. Arthaber, K. Witrisal

Institute of Signal Processing and Speech Communication (4420)

Research output: Chapter in Book/Report/Conference proceeding › Conference paper › peer-review

Abstract

Positioning and ranging within UHF RFID are highly dependent on the channel characteristics. The accuracy of time-of-flight based ranging systems is fundamentally limited by the available bandwidth. This paper first analyzes the UHF RFID backscatter channel formed by convolution of the individual constituent channels. For this purpose, we present comprehensive wideband channel measurements in two representative scenarios and an analysis with respect to the Rician K-factor for the line-of-sight component, the root-mean-square delay spread, and the coherence distance, which all influence the potential positioning performance. Based on these measurements, we validate the Cramér Rao lower bound for time-of-flight based ranging under the influence of dense multipath and present two types of range estimators, a maximum likelihood and a matched filter approach. The resulting range estimates highlight the need for an increased bandwidth for UHF RFID systems with respect to time-of-flight based ranging.

Original language	English
Title of host publication	2017 IEEE International Conference on RFID, RFID 2017
Publisher	Institute of Electrical and Electronics Engineers
Pages	117-123
Number of pages	7
DOIs	https://doi.org/10.1109/RFID.2017.7945596
Publication status	Published - 1 May 2017

Keywords

matched filters
maximum likelihood estimation
radiofrequency identification
Rician K-factor
UHF-RFID backscatter channel analysis
coherence distance
comprehensive wideband channel measurements
line-of-sight component
matched filter approach
root-mean-square delay spread
time-of-flight based ranging
wideband ranging
Antenna measurements
Distance measurement
Maximum likelihood estimation
Radiofrequency identification
Signal to noise ratio
Wideband

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10.1109/RFID.2017.7945596

Cite this

UHF-RFID Backscatter Channel Analysis for Accurate Wideband Ranging. / Grebien, Stefan Josef; Kulmer, J.; Goller, M.; Galler, F.; Arthaber, H.; Witrisal, K.

2017 IEEE International Conference on RFID, RFID 2017. Institute of Electrical and Electronics Engineers, 2017. p. 117-123.

Research output: Chapter in Book/Report/Conference proceeding › Conference paper › peer-review

@inproceedings{109b968a32e749c39a691b8c46e5bb4d,

title = "UHF-RFID Backscatter Channel Analysis for Accurate Wideband Ranging",

abstract = "Positioning and ranging within UHF RFID are highly dependent on the channel characteristics. The accuracy of time-of-flight based ranging systems is fundamentally limited by the available bandwidth. This paper first analyzes the UHF RFID backscatter channel formed by convolution of the individual constituent channels. For this purpose, we present comprehensive wideband channel measurements in two representative scenarios and an analysis with respect to the Rician K-factor for the line-of-sight component, the root-mean-square delay spread, and the coherence distance, which all influence the potential positioning performance. Based on these measurements, we validate the Cram{\'e}r Rao lower bound for time-of-flight based ranging under the influence of dense multipath and present two types of range estimators, a maximum likelihood and a matched filter approach. The resulting range estimates highlight the need for an increased bandwidth for UHF RFID systems with respect to time-of-flight based ranging.",

keywords = "matched filters, maximum likelihood estimation, radiofrequency identification, Rician K-factor, UHF-RFID backscatter channel analysis, coherence distance, comprehensive wideband channel measurements, line-of-sight component, matched filter approach, root-mean-square delay spread, time-of-flight based ranging, wideband ranging, Antenna measurements, Distance measurement, Maximum likelihood estimation, Radiofrequency identification, Signal to noise ratio, Wideband",

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AU - Grebien, Stefan Josef

AU - Kulmer, J.

AU - Goller, M.

AU - Galler, F.

AU - Arthaber, H.

AU - Witrisal, K.

PY - 2017/5/1

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N2 - Positioning and ranging within UHF RFID are highly dependent on the channel characteristics. The accuracy of time-of-flight based ranging systems is fundamentally limited by the available bandwidth. This paper first analyzes the UHF RFID backscatter channel formed by convolution of the individual constituent channels. For this purpose, we present comprehensive wideband channel measurements in two representative scenarios and an analysis with respect to the Rician K-factor for the line-of-sight component, the root-mean-square delay spread, and the coherence distance, which all influence the potential positioning performance. Based on these measurements, we validate the Cramér Rao lower bound for time-of-flight based ranging under the influence of dense multipath and present two types of range estimators, a maximum likelihood and a matched filter approach. The resulting range estimates highlight the need for an increased bandwidth for UHF RFID systems with respect to time-of-flight based ranging.

AB - Positioning and ranging within UHF RFID are highly dependent on the channel characteristics. The accuracy of time-of-flight based ranging systems is fundamentally limited by the available bandwidth. This paper first analyzes the UHF RFID backscatter channel formed by convolution of the individual constituent channels. For this purpose, we present comprehensive wideband channel measurements in two representative scenarios and an analysis with respect to the Rician K-factor for the line-of-sight component, the root-mean-square delay spread, and the coherence distance, which all influence the potential positioning performance. Based on these measurements, we validate the Cramér Rao lower bound for time-of-flight based ranging under the influence of dense multipath and present two types of range estimators, a maximum likelihood and a matched filter approach. The resulting range estimates highlight the need for an increased bandwidth for UHF RFID systems with respect to time-of-flight based ranging.

KW - matched filters

KW - maximum likelihood estimation

KW - radiofrequency identification

KW - Rician K-factor

KW - UHF-RFID backscatter channel analysis

KW - coherence distance

KW - comprehensive wideband channel measurements

KW - line-of-sight component

KW - matched filter approach

KW - root-mean-square delay spread

KW - time-of-flight based ranging

KW - wideband ranging

KW - Antenna measurements

KW - Distance measurement

KW - Maximum likelihood estimation

KW - Radiofrequency identification

KW - Signal to noise ratio

KW - Wideband

U2 - 10.1109/RFID.2017.7945596

DO - 10.1109/RFID.2017.7945596

M3 - Conference paper

SP - 117

EP - 123

BT - 2017 IEEE International Conference on RFID, RFID 2017

PB - Institute of Electrical and Electronics Engineers

ER -

UHF-RFID Backscatter Channel Analysis for Accurate Wideband Ranging

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Keywords

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