access icon openaccess Improving performance of pedestrian positioning by using vehicular communication signals

Pedestrian-to-vehicle communications, where pedestrian devices transmit their position information to nearby vehicles to indicate their presence, help to reduce pedestrian accidents. Satellite-based systems are widely used for pedestrian positioning, but have much degraded performance in urban canyon, where satellite signals are often obstructed by roadside buildings. The authors propose a pedestrian positioning method, which leverages vehicular communication signals and uses vehicles as anchors. The performance of pedestrian positioning is improved from three aspects: (i) channel state information instead of received signal strength indicator (RSSI) is used to estimate pedestrian-vehicle distance with higher precision. (ii) Only signals with line-of-sight path are used, and the property of distance error is considered. (iii) Fast mobility of vehicles is used to get diverse measurements, and Kalman filter is applied to smooth positioning results. Extensive evaluations, via trace-based simulation, confirm that (i) fixing rate of positions can be much improved. (ii) Horizontal positioning error can be greatly reduced, nearly by one order compared with off-the-shelf receivers, by almost half compared with RSSI-based method, and can be reduced further to about 80 cm when vehicle transmission period is 100 ms and Kalman filter is applied. Generally, positioning performance increases with the number of available vehicles and their transmission frequency.

Inspec keywords: pedestrians; Kalman filters; Global Positioning System; vehicular ad hoc networks

Other keywords: diverse measurements; pedestrian positioning method; line-of-sight path; channel state information; Kalman filter; satellite signals; trace-based simulation; vehicular communication signals; distance error; performance improvement; urban canyon; transmission frequency; pedestrian-to-vehicle communications; roadside buildings; pedestrian-vehicle distance

Subjects: Radionavigation and direction finding; Filtering methods in signal processing; Mobile radio systems

http://iet.metastore.ingenta.com/content/journals/10.1049/iet-its.2017.0134
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content/journals/10.1049/iet-its.2017.0134
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