Your search keyword '"Kordani, Ali Abdi"' showing total 3 results

1. Improving superelevation in spiral transitions based on lateral acceleration rate.

Author

Pourkhani, Hossein and Kordani, Ali Abdi

Subjects

*SPORT utility vehicles, *ACCELERATION (Mechanics), *PICKUP trucks, *TRAFFIC engineering, *MOTOR vehicle driving

Abstract

High collision rates on horizontal curves compared with other roadway elements make them one of the most critical elements in a transportation network and thus good candidates for new studies, especially of the stability of a vehicle driving on a horizontal curve. In this regard, spiral transition curves as facilities to enter horizontal alignments are very important. While the superelevation changes in these curves have always been linear, the aim of this study was to evaluate non-linearity in the superelevation attainment function (SAF). Various scenarios were used in order to cover different situations. As a simulation tool, the CarSim software package was used to model three kinds of passenger cars (sport utility vehicle, utility truck and sedan). In addition, 16 types of spiral–curve–spiral road plans for three different conditions of road slope, six types of warping in the SAF and two types of functional speed were examined (a total of 1728 scenarios). The results showed that non-linearity might produce better results than other proposed methods; for example, it was found that a parabolic function reduced the lateral acceleration rate by over 50% for high superelevation and design speed. [ABSTRACT FROM AUTHOR]

Published

2024

2. Follower behavioural change based on natural patterns in traffic oscillation.

Author

Salehikalam, Arsalan and Kordani, Ali Abdi

Subjects

*TRAFFIC patterns, *ARTIFICIAL neural networks, *INTELLIGENT transportation systems, *OSCILLATIONS, *ACCELERATION (Mechanics), *SPEED

Abstract

An understanding of the change in follower behaviour as a driver characteristic in traffic simulations is necessary because these behavioural changes are frequently observed in traffic oscillations. The change in follower behaviour due to traffic acceleration and deceleration waves can be classified according to different behavioural patterns resulting from different driver reactions. Combinations of existing behavioural patterns (under-reaction–timid, over-reaction–timid and constant over-reaction–timid patterns) were thus analysed. The method of analysis was based on an artificial neural network model at the microscopic level in order to simulate the extent to which follower behaviour deviates from Newell's car-following model. The most influential parameters of all the behavioural patterns were determined. Based on the under-reaction–timid pattern, decreasing the reaction speed resulted in a change in behaviour due to the development of safe spacing at the reaction point. In addition, follower spacing was the most influential in the over-reaction–timid pattern, resulting in increasing and then decreasing behavioural change. In the constant over-reaction–timid pattern, the follower's speed resulted in increasing and then decreasing the change in behaviour. The application of behavioural change to an intelligent transportation system would improve safety. [ABSTRACT FROM AUTHOR]

Published

2021

3. Predicting operating speed: comparison of linear regression and structural equation models.

Author

Bamdad Mehrabani, Behzad, Mirbaha, Babak, Sgambi, Luca, and Kordani, Ali Abdi

Subjects

*STRUCTURAL equation modeling, *REGRESSION analysis, *SPEED, *LATENT variables, *SPEED limits, *FORECASTING

Abstract

The aim of this research was to predict operating speed by considering geometric and roadside factors. Although most previous studies have employed linear regression modelling (LRM) to predict operating speed, this study recommends structural equation modelling (SEM) for the prediction of operating speed on rural multi-lane highways. In addition to geometric variables, LRM takes roadside variables into account. When employing SEM in this work, two latent variables were defined, namely 'roadside effects' and 'geometric effects'. The first latent variable was the combination of land-use type, land-use density and number of accesses per segment, while the second was extracted from the segment length, highway grade, curvature, the presence of a guardrail and flat roadside slope, and the posted speed limits. The residual analysis and R2 values for LRM and SEM suggest that SEM demonstrates superior modelling performance compared with LRM. These results show the significant role of latent variables in predicting speed, which cannot be achieved through ordinary LRM. [ABSTRACT FROM AUTHOR]

Published

2023