Related papers: An Enhanced Analysis of Traffic Intelligence in Smart Cities Using Sustainable Deep Radial Function

An Enhanced Analysis of Traffic Intelligence in Smart Cities Using Sustainable Deep Radial Function

URL: http://arxiv.org/abs/2402.09432v1
Date: Wed, 24 Jan 2024 22:28:14 GMT
Title: An Enhanced Analysis of Traffic Intelligence in Smart Cities Using Sustainable Deep Radial Function
Authors: Ayad Ghany Ismaeel, S.J. Jereesha Mary, C. Anitha, Jaganathan Logeshwaran, Sarmad Nozad Mahmood, Sameer Alani, and Akram H. Shather
Abstract summary: This paper describes a novel strategy for enhancing traffic intelligence in smart cities using deep radial basis function (RBF) networks. Deep RBF networks combine the generalization and capabilities of deep learning with the discriminative capability of radial basis functions. The proposed method can effectively learn intricate relationships and nonlinear patterns in traffic data by leveraging the hierarchical structure of deep neural networks.
Score: 0.6282171844772422
License: http://creativecommons.org/licenses/by-nc-nd/4.0/
Abstract: Smart cities have revolutionized urban living by incorporating sophisticated technologies to optimize various aspects of urban infrastructure, such as transportation systems. Effective traffic management is a crucial component of smart cities, as it has a direct impact on the quality of life of residents and tourists. Utilizing deep radial basis function (RBF) networks, this paper describes a novel strategy for enhancing traffic intelligence in smart cities. Traditional methods of traffic analysis frequently rely on simplistic models that are incapable of capturing the intricate patterns and dynamics of urban traffic systems. Deep learning techniques, such as deep RBF networks, have the potential to extract valuable insights from traffic data and enable more precise predictions and decisions. In this paper, we propose an RBF based method for enhancing smart city traffic intelligence. Deep RBF networks combine the adaptability and generalization capabilities of deep learning with the discriminative capability of radial basis functions. The proposed method can effectively learn intricate relationships and nonlinear patterns in traffic data by leveraging the hierarchical structure of deep neural networks. The deep RBF model can learn to predict traffic conditions, identify congestion patterns, and make informed recommendations for optimizing traffic management strategies by incorporating these rich and diverse data To evaluate the efficacy of our proposed method, extensive experiments and comparisons with real world traffic datasets from a smart city environment were conducted. In terms of prediction accuracy and efficiency, the results demonstrate that the deep RBF based approach outperforms conventional traffic analysis methods. Smart city traffic intelligence is enhanced by the model capacity to capture nonlinear relationships and manage large scale data sets.

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