William Bortles scite author profile

Previous work demonstrated that the orientation of tire mark striations can be used to infer the braking actions of the driver [1]. An equation that related tire mark striation angle to longitudinal tire slip, the mathematical definition of braking, was presented. This equation can be used to quantify the driver's braking input based on the physical evidence. Braking input levels will affect the speed of a yawing vehicle and quantifying the amount of braking can increase the accuracy of a speed analysis. When using this technique in practice, it is helpful to understand the sensitivity and uncertainties of the equation. The sensitivity and uncertainty of the equation are explored and presented in this study. The results help to formulate guidelines for the practical application of the method and expected accuracy under specified conditions. A case study is included that demonstrates the analysis of tire mark striations deposited during a real-world accident.

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Evaluation of Discrete Vehicle Accident Sounds for use in Accident Reconstruction

Neale¹,

Terpstra²,

Bortles³

2009

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A Compendium of Passenger Vehicle Event Data Recorder Literature and Analysis of Validation Studies

Bortles¹,

Biever²,

Carter³

et al. 2016

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Application of 3D Visualization in Modeling Wheel Stud Contact Patterns with Rotating and Stationary Surfaces

Bortles¹,

Hessel²,

Neale³

2017

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When a vehicle with protruding wheel studs makes contact with another vehicle or object in a sideswipe configuration, the tire sidewall, rim and wheel studs of that vehicle can deposit distinct geometrical damage patterns onto the surfaces it contacts. Prior research has demonstrated how relative speeds between the two vehicles or surfaces can be calculated through analysis of the distinct contact patterns. This paper presents a methodology for performing this analysis by visually modeling the interaction between wheel studs and various surfaces, and presents a method for automating the calculations of relative speed between vehicles. This methodology also augments prior research by demonstrating how the visual modeling and simulation of the wheel stud contact can extend to almost any surface interaction that may not have any previous prior published tests, or test methods that would be difficult to setup in real life. Specifically, the modeling and simulating of wheel stud contact is evaluated on more complex geometry, stationary objects, and the sidewall of another rotating tire.

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William Bortles

An Introduction to the Forensic Acquisition of Passenger Vehicle Infotainment and Telematics Systems Data

Tire Mark Striations: Sensitivity and Uncertainty Analysis

Evaluation of Discrete Vehicle Accident Sounds for use in Accident Reconstruction

A Compendium of Passenger Vehicle Event Data Recorder Literature and Analysis of Validation Studies

Application of 3D Visualization in Modeling Wheel Stud Contact Patterns with Rotating and Stationary Surfaces

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