Real-Time Magnetic Length-Based Vehicle Classification: Case Study for Inductive Loops and Wireless Magnetometer Sensors in Oklahoma State

Balid, Walid; Refai, Hazem H.

doi:10.1177/0361198118791612

Cited by 7 publications

(4 citation statements)

References 14 publications

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“…The authors in [ 7 ] focused on the utilization of magnetometer sensors for length-based vehicle classification, where through their computationally efficient classification model reached classification accuracy of 97.70% by using of the anisotropic magnetoresistance (AMR) effect.…”

Section: Related Workmentioning

confidence: 99%

Which Digital-Output MEMS Magnetometer Meets the Requirements of Modern Road Traffic Survey?

Hodoň

Karpis

Ševčı́k

et al. 2021

Sensors

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Present systems for road traffic surveillance largely utilize MEMS magnetometers for the purpose of vehicle detection and classification. Magnetoresistive sensing or LR oscillation circuitry are technologies providing the sensors with the competitive advantage which lies in the energy efficiency and low price. There are several chip suppliers on the market who specialize in the development of these sensors. The aim of this paper is to compare available sensors from the viewpoint of their suitability for traffic measurements. A summary of the achieved results is given in the form of the score for each sensor. The introduced sensor chart should provide the audience with knowledge about pros and cons of sensors, especially if intended for the purposes of road traffic surveillance. The authors in this research focused on the specific situation of road traffic monitoring with magnetometers placed at the roadside.

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Section: Related Workmentioning

confidence: 99%

Which Digital-Output MEMS Magnetometer Meets the Requirements of Modern Road Traffic Survey?

Hodoň

Karpis

Ševčı́k

et al. 2021

Sensors

View full text Add to dashboard Cite

show abstract

“…Inductive-loop-based vehicle detectors [10] and magnetometers [11] can potentially provide some details of vehicle classification, but it can be costly to retrofit them to existing bridges. On the other hand, computer-vision-based techniques [3] do not need to contact the structure and can be deployed relatively quickly.…”

Section: Introductionmentioning

confidence: 99%

Detecting Vehicle Loading Events in Bridge Rotation Data Measured with Multi-Axial Accelerometers

Ferguson

Woods

Hester

2022

Sensors

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Structural Health Monitoring (SHM) is critical in the observation and analysis of our national infrastructure of bridges. Due to the ease of measuring bridge rotation, bridge SHM using rotation measurements is becoming more popular, as even a single DC accelerometer placed at each end of span can accurately capture bridge deformations. Event detection methods for SHM typically entail additional instrumentation, such as strain gauges or continuously recording video cameras, and thus the additional cost limits their utility in resource-constrained environments and for wider deployment. Herein, we present a more cost-effective event detection method which exploits the existing bridge rotation instrumentation (tri-axial MEMS accelerometers) to also act as a trigger for subsequent stages of the SHM system and thus obviates the need for additional vehicle detection equipment. We show how the generalised variance over a short sliding window can be used to robustly discriminate individual vehicle loading events, both in time and magnitude, from raw acceleration data. Numerical simulation results examine the operation of the event detector under varying operating conditions, including vehicle types and sensor locations. The method’s application is demonstrated for two case studies involving in-service bridges experiencing live free-flow traffic. An initial implementation on a Raspberry Pi Zero 2 shows that the proposed functionality can be realised in less than 400 ARM A32 instructions with a latency of 47 microseconds.

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“…This loop detector technology is built on a coil of wire buried beneath the road that records changes in the amplitude, phase, and frequency of the magnetic profile signal when a vehicle passes over it [6]. The loop detector technique has been widely studied, with previous works demonstrating its high accuracy (99%) for classifying large vehicles, such as cars, trucks, and vans [7][8][9][10]. The accuracy of loop detector systems has been shown to be independent of vehicle speed [11].…”

Section: Introductionmentioning

confidence: 99%

Vehicle Auto-Classification Using Machine Learning Algorithms Based on Seismic Fingerprinting

et al. 2022

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Most vehicle classification systems now use data from images or videos. However, these approaches violate drivers’ privacy and reveal their identities. Due to various disruptions, detecting automobiles using seismic ambient noise signals is challenging. This study uses seismic surface waves to compare time series data between different vehicle types. We applied various artificial intelligence approaches using raw data from three different vehicle sizes (Bus/Truck, Car, and Motorcycle) and background noise. By using vertical component seismic data, this study compares the decoding abilities of Logistic Regression, Support Vector Machine, and Naïve Bayes (NB) approaches to determine the class of automobiles. The Multiclass classifiers were trained on 4185 samples and tested on 1395 randomly chosen from actual and synthetic data sets. Additionally, we used the convolutional neural network approach as a baseline to assess the effectiveness of machine learning (ML) methods. The NB method showed relatively high classification accuracy during training for the three multiclass classification situations. Overall, we investigate an ML-based decoding technique that can be used for security and traffic analysis across large geographic areas without endangering driver privacy and is more effective and economical than conventional methods.

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Real-Time Magnetic Length-Based Vehicle Classification: Case Study for Inductive Loops and Wireless Magnetometer Sensors in Oklahoma State

Cited by 7 publications

References 14 publications

Which Digital-Output MEMS Magnetometer Meets the Requirements of Modern Road Traffic Survey?

Which Digital-Output MEMS Magnetometer Meets the Requirements of Modern Road Traffic Survey?

Detecting Vehicle Loading Events in Bridge Rotation Data Measured with Multi-Axial Accelerometers

Vehicle Auto-Classification Using Machine Learning Algorithms Based on Seismic Fingerprinting

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