A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Incorporating Uncertainty into the Estimation of the Passing Sight Distance Requirements
Abstract: Passing sight distance (PSD) is provided to ensure the safety of passing maneuvers on two lane two way roads. Many random variables determine the minimum length required for a safe passing maneuver. Current PSD design practices replace these random variables by single‐value means in the calculation process, disregarding their inherent variations, which results in a single‐value PSD design criteria. The main objective of the article is to derive a PSD distribution that accounts for the variations in the contributing random variables. Two models are devised, a Monte‐Carlo simulation model used to obtain the PSD distribution and a closed form analytical estimation model used for verification purposes. The Monte‐Carlo simulation model uses random sampling to select the values of the contributing parameters from their corresponding distributions in each run. The analytical model accounts for each parameter variation by using their means and standard deviations in a closed form estimation method. The means and standard deviations of the PSD using both models are compared for verification purposes. Both models use the same PSD formulation. The analysis is conducted for a design speed of 80 Km/h (50 mph). A PSD distribution is developed accordingly. The results of both models differ only by less than 2%. The obtained distribution is used to estimate the reliability index of the current PSD standards at a design speed of 80 Km/h (50 mph).
Incorporating Uncertainty into the Estimation of the Passing Sight Distance Requirements
Abstract: Passing sight distance (PSD) is provided to ensure the safety of passing maneuvers on two lane two way roads. Many random variables determine the minimum length required for a safe passing maneuver. Current PSD design practices replace these random variables by single‐value means in the calculation process, disregarding their inherent variations, which results in a single‐value PSD design criteria. The main objective of the article is to derive a PSD distribution that accounts for the variations in the contributing random variables. Two models are devised, a Monte‐Carlo simulation model used to obtain the PSD distribution and a closed form analytical estimation model used for verification purposes. The Monte‐Carlo simulation model uses random sampling to select the values of the contributing parameters from their corresponding distributions in each run. The analytical model accounts for each parameter variation by using their means and standard deviations in a closed form estimation method. The means and standard deviations of the PSD using both models are compared for verification purposes. Both models use the same PSD formulation. The analysis is conducted for a design speed of 80 Km/h (50 mph). A PSD distribution is developed accordingly. The results of both models differ only by less than 2%. The obtained distribution is used to estimate the reliability index of the current PSD standards at a design speed of 80 Km/h (50 mph).
Incorporating Uncertainty into the Estimation of the Passing Sight Distance Requirements
Khoury, John El (author) / Hobeika, Antoine (author)
Computer‐Aided Civil and Infrastructure Engineering ; 22 ; 347-357
2007-07-01
11 pages
Article (Journal)
Electronic Resource
English
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