A Taxonomy of WiFi Sensing: CSI vs Passive WiFi Radar

Wenda Li; Mohammud Z. J. Bocus; Chong Tang; Shelly Vishwakarma; Robert J. Piechocki; Karl Woolbridge; Kevin Chetty

doi:10.1109/gcwkshps50303.2020.9367546

A Taxonomy of WiFi Sensing: CSI vs Passive WiFi Radar

Wenda Li, Mohammud Z. J. Bocus, Chong Tang, Shelly Vishwakarma, Robert J. Piechocki, Karl Woolbridge, Kevin Chetty

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

26 Citations (Scopus)

Abstract

WiFi sensing has shown promising potentials in a number of applications such as healthcare, smart transportation and home automation. Human activity recognition without the use of any cooperative device such as phones or wearable technologies can be achieved by two WiFi based approaches: Channel State Information (CSI) and Passive WiFi Radar (PWR). CSI systems rely directly on WiFi as a communications system, whilst PWR treats the WiFi signal as an illuminator for use in a radar signal processing. However, there has not been a comprehensive comparative study on the similarities and differences between the two systems. To examine the performance of both systems we implement two hardware platforms for CSI and PWR, and use them concurrently to capture the human movements. In this paper, we present Doppler measurements from the two systems and compare their performance using a dataset obtained from five subjects undergoing six activity classes. It is observed that both systems have very different Doppler signatures, and are sensitive to the transmitter-target-receiver geometries. CSI has a better performance in Line-of-Sight (LoS) configurations, whereas PWR has better performance in bistatic configurations where the WiFi access point and radar receiver are spatially separated. It is envisioned that a more robust system should leverage strengths of both the CSI and PWR systems jointly to maximize their benefits in wireless sensing.

Original language	English
Title of host publication	2020 IEEE Globecom Workshops (GC Wkshps)
Publisher	IEEE
ISBN (Electronic)	9781728173078
ISBN (Print)	9781728173085
DOIs	https://doi.org/10.1109/gcwkshps50303.2020.9367546
Publication status	Published - 5 Mar 2021
Event	IEEE Globecom Workshops 2020 - virtual, Taepei, Taiwan, Province of China Duration: 7 Dec 2020 → 11 Dec 2020 https://globecom2020.ieee-globecom.org/index.html

Conference

Conference	IEEE Globecom Workshops 2020
Abbreviated title	GC Wkshps 2020
Country/Territory	Taiwan, Province of China
City	Taepei
Period	7/12/20 → 11/12/20
Internet address	https://globecom2020.ieee-globecom.org/index.html

Keywords

Geometry
Passive Radar
Layout
Hardware
Sensors
Doppler effect
Wireless fidelity
Activity Recognition
CSI
Passive WiFi Radar
Wireless Sensing

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10.1109/gcwkshps50303.2020.9367546

Cite this

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title = "A Taxonomy of WiFi Sensing: CSI vs Passive WiFi Radar",

abstract = "WiFi sensing has shown promising potentials in a number of applications such as healthcare, smart transportation and home automation. Human activity recognition without the use of any cooperative device such as phones or wearable technologies can be achieved by two WiFi based approaches: Channel State Information (CSI) and Passive WiFi Radar (PWR). CSI systems rely directly on WiFi as a communications system, whilst PWR treats the WiFi signal as an illuminator for use in a radar signal processing. However, there has not been a comprehensive comparative study on the similarities and differences between the two systems. To examine the performance of both systems we implement two hardware platforms for CSI and PWR, and use them concurrently to capture the human movements. In this paper, we present Doppler measurements from the two systems and compare their performance using a dataset obtained from five subjects undergoing six activity classes. It is observed that both systems have very different Doppler signatures, and are sensitive to the transmitter-target-receiver geometries. CSI has a better performance in Line-of-Sight (LoS) configurations, whereas PWR has better performance in bistatic configurations where the WiFi access point and radar receiver are spatially separated. It is envisioned that a more robust system should leverage strengths of both the CSI and PWR systems jointly to maximize their benefits in wireless sensing.",

keywords = "Geometry, Passive Radar, Layout, Hardware, Sensors, Doppler effect, Wireless fidelity, Activity Recognition, CSI, Passive WiFi Radar, Wireless Sensing",

author = "Wenda Li and Bocus, {Mohammud Z. J.} and Chong Tang and Shelly Vishwakarma and Piechocki, {Robert J.} and Karl Woolbridge and Kevin Chetty",

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AU - Li, Wenda

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AU - Tang, Chong

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AU - Piechocki, Robert J.

AU - Woolbridge, Karl

AU - Chetty, Kevin

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N2 - WiFi sensing has shown promising potentials in a number of applications such as healthcare, smart transportation and home automation. Human activity recognition without the use of any cooperative device such as phones or wearable technologies can be achieved by two WiFi based approaches: Channel State Information (CSI) and Passive WiFi Radar (PWR). CSI systems rely directly on WiFi as a communications system, whilst PWR treats the WiFi signal as an illuminator for use in a radar signal processing. However, there has not been a comprehensive comparative study on the similarities and differences between the two systems. To examine the performance of both systems we implement two hardware platforms for CSI and PWR, and use them concurrently to capture the human movements. In this paper, we present Doppler measurements from the two systems and compare their performance using a dataset obtained from five subjects undergoing six activity classes. It is observed that both systems have very different Doppler signatures, and are sensitive to the transmitter-target-receiver geometries. CSI has a better performance in Line-of-Sight (LoS) configurations, whereas PWR has better performance in bistatic configurations where the WiFi access point and radar receiver are spatially separated. It is envisioned that a more robust system should leverage strengths of both the CSI and PWR systems jointly to maximize their benefits in wireless sensing.

AB - WiFi sensing has shown promising potentials in a number of applications such as healthcare, smart transportation and home automation. Human activity recognition without the use of any cooperative device such as phones or wearable technologies can be achieved by two WiFi based approaches: Channel State Information (CSI) and Passive WiFi Radar (PWR). CSI systems rely directly on WiFi as a communications system, whilst PWR treats the WiFi signal as an illuminator for use in a radar signal processing. However, there has not been a comprehensive comparative study on the similarities and differences between the two systems. To examine the performance of both systems we implement two hardware platforms for CSI and PWR, and use them concurrently to capture the human movements. In this paper, we present Doppler measurements from the two systems and compare their performance using a dataset obtained from five subjects undergoing six activity classes. It is observed that both systems have very different Doppler signatures, and are sensitive to the transmitter-target-receiver geometries. CSI has a better performance in Line-of-Sight (LoS) configurations, whereas PWR has better performance in bistatic configurations where the WiFi access point and radar receiver are spatially separated. It is envisioned that a more robust system should leverage strengths of both the CSI and PWR systems jointly to maximize their benefits in wireless sensing.

KW - Geometry

KW - Passive Radar

KW - Layout

KW - Hardware

KW - Sensors

KW - Doppler effect

KW - Wireless fidelity

KW - Activity Recognition

KW - CSI

KW - Passive WiFi Radar

KW - Wireless Sensing

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DO - 10.1109/gcwkshps50303.2020.9367546

M3 - Conference contribution

SN - 9781728173085

BT - 2020 IEEE Globecom Workshops (GC Wkshps)

PB - IEEE

T2 - IEEE Globecom Workshops 2020

Y2 - 7 December 2020 through 11 December 2020

ER -

A Taxonomy of WiFi Sensing: CSI vs Passive WiFi Radar

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Conference

Keywords

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