A Wireless Accelerometer-Based Automatic Vehicle Classification Prototype System

被引：79

作者：

Ma, Wenteng ^{[1
]}

Xing, Daniel ^{[1
]}

McKee, Adam ^{[1
]}

Bajwa, Ravneet ^{[1
]}

Flores, Christopher ^{[1
]}

Fuller, Brian ^{[1
]}

Varaiya, Pravin ^{[2
]}

机构：

[1] Sensys Networks Inc, Berkeley, CA 94710 USA

[2] Univ Calif Berkeley, Dept Elect Engn & Comp Sci, Berkeley, CA 94720 USA

来源：

IEEE TRANSACTIONS ON INTELLIGENT TRANSPORTATION SYSTEMS | 2014年 / 15卷 / 01期

基金：

美国国家科学基金会;

关键词：

Accelerometer; automatic vehicle classification (AVC); axle count; axle spacing; magnetometer; wireless sensor;

D O I：

10.1109/TITS.2013.2273488

中图分类号：

TU [建筑科学];

学科分类号：

0813 ;

摘要：

Automatic vehicle classification (AVC) systems provide data about vehicle classes that are used for many purposes. This paper describes a prototype axle count and spacing AVC system using wireless accelerometers and magnetometers. The accelerometers detect vehicle axles, and the magnetometers report vehicle arrivals and departures and estimate speed. The prototype system is installed on Interstate 80 at Pinole, CA, USA, and tested under various traffic conditions. Video images and reports from a nearby commercial weigh-in-motion station provide ground truth to evaluate the performance of the system, including classification, axle spacing, and vehicle counts. The results show that the prototype AVC system is reliable in classifying vehicles even under congested traffic with accuracy of 99%.

引用

页码：104 / 111

页数：8

共 50 条

[1] Vehicle Maneuver Detection with Accelerometer-Based Classification
Cervantes-Villanueva, Javier
Carrillo-Zapata, Daniel
Terroso-Saenz, Fernando
Valdes-Vela, Mercedes
Skarmeta, Antonio E.
[J]. SENSORS, 2016, 16 (10)
[2] An accelerometer-based guidance device for CT-guided procedures: an improved wireless prototype
Pedersoli, Federico
Wilkmann, Christoph
Penzkofer, Tobias
Disselhorst-Klug, Catherine
Schmitz-Rode, Thomas
Kuhl, Christiane
Bruners, Philipp
Isfort, Peter
[J]. MINIMALLY INVASIVE THERAPY & ALLIED TECHNOLOGIES, 2022, 31 (06) : 902 - 908
[3] A System for Accelerometer-Based Gesture Classification Using Artificial Neural Networks
Stephenson, Robert M.
Naik, Ganesh R.
Chai, Rifai
[J]. 2017 39TH ANNUAL INTERNATIONAL CONFERENCE OF THE IEEE ENGINEERING IN MEDICINE AND BIOLOGY SOCIETY (EMBC), 2017, : 4187 - 4190
[4] Classification of knee arthropathy with accelerometer-based vibroarthrography
Moreira, Dinis
Silva, Joana
Correia, Miguel V.
Massada, Marta
[J]. PHEALTH 2016, 2016, 224 : 33 - 39
[5] An accelerometer-based physical rehabilitation system
Milenkovic, M
Jovanov, E
Chapman, J
Raskovic, D
Price, J
[J]. PROCEEDINGS OF THE THIRTY-FOURTH SOUTHEASTERN SYMPOSIUM ON SYSTEM THEORY, 2002, : 57 - 60
[6] An accelerometer-based leak detection system
El-Zahab, Samer
Abdelkader, Eslam Mohammed
Zayed, Tarek
[J]. MECHANICAL SYSTEMS AND SIGNAL PROCESSING, 2018, 108 : 276 - 291
[7] In-Ear Accelerometer-Based Sensor for Gait Classification
Burgos, Clara Piris
Gaertner, Lea
Ballester, Miguel A. Gonzalez
Noailly, Jerome
Stoecker, Fabian
Schonfelder, Martin
Adams, Tim
Tassani, Simone
[J]. IEEE SENSORS JOURNAL, 2020, 20 (21) : 12895 - 12902
[8] Low-power wireless accelerometer-based system for wear detection of bandsaw blades
Magno, M.
Popovici, E.
Bravin, A.
Libri, A.
Storace, M.
Benini, L.
[J]. 2013 11TH IEEE INTERNATIONAL CONFERENCE ON INDUSTRIAL INFORMATICS (INDIN), 2013, : 630 - 635
[9] Angular accelerometer-based inertial navigation system
Nusbaum, Uriel
Rusnak, Ilan
Klein, Itzik
[J]. NAVIGATION-JOURNAL OF THE INSTITUTE OF NAVIGATION, 2019, 66 (04): : 681 - 693
[10] Accelerometer-based system for the detection of lameness in horses
Keegan, KG
Yonezawa, Y
Pai, PF
Wilson, DA
[J]. BIOMEDICAL SCIENCES INSTRUMENTATION, VOL 38, 2002, 38 : 107 - 112

← 1 2 3 4 5 →