An analytical calculation and applications of the kinematic characteristics of the motor vehicle movement at an oblique hitting the side of a cable barrier

The authors of this paper focus on the simulation of the motor vehicle movement (taking into consideration motor vehicle dynamics, motor vehicle hydraulic brake system influence on motor vehicle movement, interaction between its wheels with road pavements, road guardrail characteristics, interaction between motor vehicle and road guardrail) on a certain road section and propose their specific solution of this problem. The presented results, illustrating the motor vehicle movement trajectories (motor vehicle braking and interaction between motor vehicle and road guardrail at various initial conditions and at various certain pavement surface of the road section under investigation) and work of a motor vehicle hydraulic brake system. Taking into consideration the presented general mathematical model and computer aided test results it is possible to investigate various road transport traffic situations as well as to investigate various transport traffic safety problems.

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Light Rail Accident Involvement and Severity

Transportation Research Record Journal of the Transportation Research Board ◽

10.1177/0361198196152100119 ◽

1996 ◽

Vol 1521 (1) ◽

pp. 147-155

Author(s):

T. Chira-Chavala ◽

B. Coifman ◽

C. Porter ◽

M. Hansen

Keyword(s):

Motor Vehicle ◽

Light Rail ◽

Peak Period ◽

Transit System ◽

Santa Clara County ◽

Accident Causation ◽

Accident Severity ◽

Binary Logit ◽

Causation Analysis ◽

Vehicle Movement

Accident causation and accident severity analyses for a light rail transit system are presented, with a view to providing input for the identification and development of accident and severity countermeasures. Accident reports of the Santa Clara County Transit Authority were used in both analyses. In the accident causation analysis, patterns of critical events for various types of light rail accident involvement were determined. The accident severity model is a binary logit model expressing the probability of injury accident as a function of speeds before collision of both the light rail vehicle and the motor vehicle, movement of the motor vehicle before collision, and peak and off-peak period.

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EXPERIMENTAL RESEARCH INTO MOTOR VEHICLE OSCILLATIONS IN THE CASE OF CHANGEABLE DECELERATION

Transport ◽

10.3846/16484142.2005.9638016 ◽

2005 ◽

Vol 20 (5) ◽

pp. 171-175 ◽

Cited By ~ 3

Author(s):

Robertas Pečeliūnas ◽

Olegas Prentkovskis ◽

Giedrius Garbinčius ◽

Saulius Nagurnas ◽

Saugirdas Pukalskas

Keyword(s):

Experimental Research ◽

Motor Vehicle ◽

Electronic Device ◽

Processing System ◽

Experimental Investigations ◽

Road Accidents ◽

Bearing Surface ◽

Mathematical Algorithms ◽

Synchronous Operation ◽

Vehicle Movement

In this paper processes of oscillation of flexible mounted and inflexible mounted masses are analysed. The tangential effect of the wheel contact with bearing surface is given, thus enabling more precise calculus of vehicle braking parameters. The methodology of research includes the development of mathematical algorithms and theoretical calculus of the analysed processes as well as the presentation of the influence of various factors on vehicle oscillations during braking. Analytical methods and those in figures have been applied for the research. Experimental investigations were carried out applying the electronic device VZM 100 measuring the acceleration of deceleration adapted for synchronous operation together with vibration processing system VAS‐21. The expert opportunities for modelling of vehicle movement are extended with the help of the created mathematical models used for the examination of road accidents related to vehicle braking.

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Monte Carlo Modelling of Secondary Electron Yield from Rough Surfaces

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100180860 ◽

1990 ◽

Vol 48 (1) ◽

pp. 422-423

Author(s):

John C. Russ

Keyword(s):

Monte Carlo ◽

Energy Loss ◽

Secondary Electron ◽

Secondary Electron Emission ◽

Analytical Calculation ◽

Mean Free Path ◽

Single Scattering ◽

High Energy ◽

Secondary Electron Yield ◽

Electron Yield

Monte-Carlo programs are well recognized for their ability to model electron beam interactions with samples, and to incorporate boundary conditions such as compositional or surface variations which are difficult to handle analytically. This success has been especially powerful for modelling X-ray emission and the backscattering of high energy electrons. Secondary electron emission has proven to be somewhat more difficult, since the diffusion of the generated secondaries to the surface is strongly geometry dependent, and requires analytical calculations as well as material parameters. Modelling of secondary electron yield within a Monte-Carlo framework has been done using multiple scattering programs, but is not readily adapted to the moderately complex geometries associated with samples such as microelectronic devices, etc.This paper reports results using a different approach in which simplifying assumptions are made to permit direct and easy estimation of the secondary electron signal from samples of arbitrary complexity. The single-scattering program which performs the basic Monte-Carlo simulation (and is also used for backscattered electron and EBIC simulation) allows multiple regions to be defined within the sample, each with boundaries formed by a polygon of any number of sides. Each region may be given any elemental composition in atomic percent. In addition to the regions comprising the primary structure of the sample, a series of thin regions are defined along the surface(s) in which the total energy loss of the primary electrons is summed. This energy loss is assumed to be proportional to the generated secondary electron signal which would be emitted from the sample. The only adjustable variable is the thickness of the region, which plays the same role as the mean free path of the secondary electrons in an analytical calculation. This is treated as an empirical factor, similar in many respects to the λ and ε parameters in the Joy model.

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Case Exercise: Biomechanics in Rearend Motor Vehicle Collisions

Guides Newsletter ◽

10.1001/amaguidesnewsletters.2007.mayjun02 ◽

2007 ◽

Vol 12 (3) ◽

pp. 4-7

Author(s):

Charles N. Brooks ◽

Christopher R. Brigham

Keyword(s):

Motor Vehicle ◽

Body Position ◽

Motor Vehicle Collisions ◽

Time Curve ◽

Vehicle Collisions ◽

Need For Treatment ◽

Multiple Factors ◽

Bodily Injury ◽

Vehicle Collision ◽

Physical Findings

Abstract Multiple factors determine the likelihood, type, and severity of bodily injury following a motor vehicle collision and, in turn, influence the need for treatment, extent of disability, and likelihood of permanent impairment. Among the most important factors is the change in velocity due to an impact (Δv). Other factors include the individual's strength and elasticity, body position at the time of impact, awareness of the impending impact (ie, opportunity to brace, guard, or contract muscles before an impact), and effects of braking. Because Δv is the area under the acceleration vs time curve, it combines force and duration and is a useful way to quantify impact severity. The article includes a table showing the results of a literature review that concluded, “the consensus of human subject research conducted to date is that a single exposure to a rear-end impact with a Δv of 5 mph or less is unlikely to result in injury” in most healthy, restrained occupants. Because velocity incorporates direction as well as speed, a vehicular occupant is less likely to be injured in a rear impact than when struck from the side. Evaluators must consider multiple factors, including the occupant's pre-existing physical and psychosocial status, the mechanism and magnitude of the collision, and a variety of biomechanical variables. Recommendations based solely on patient history and physical findings (and, perhaps, imaging studies) may be ill-informed.

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