Bayesian curved lane estimation for autonomous driving

Fakhfakh, Mohamed; Chaâri, Lotfi; Fakhfakh, Nizar

doi:10.1007/s12652-020-01688-7

Cited by 12 publications

(9 citation statements)

References 58 publications

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“…Following that, a massive contribution to lane and curve detection along with tracking was presented by studies where 95.5% road scene extraction was demonstrated, for example, in [79], for lane edge segmentation without manual labelling using a modified CNN architecture. As discussed in previous sections, challenges such as higher computational cost [81], insufficient for far field of view [82], not testing in complex scenarios [79] and poor luminance made some proposals tough for practical implementation in present AVS.…”

Section: Discussionmentioning

confidence: 99%

“…The Bayesian method for estimating multihyperbola parameters splitting frames in multiple patches was demonstrated by Fakhfakh et al to recognize curved lanes under difficult conditions using [82]. The lane line was represented on each component by a hyperbola which was determined using the proposed Bayesian hierarchical model with an average of 91.83% true positive rate (TPR) on the ROMA dataset.…”

Section: Lane Detection and Trackingmentioning

confidence: 99%

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Vision-Based Autonomous Vehicle Systems Based on Deep Learning: A Systematic Literature Review

2022

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In the past decade, autonomous vehicle systems (AVS) have advanced at an exponential rate, particularly due to improvements in artificial intelligence, which have had a significant impact on social as well as road safety and the future of transportation systems. However, the AVS is still far away from mass production because of the high cost of sensor fusion and a lack of combination of top-tier solutions to tackle uncertainty on roads. To reduce sensor dependency and to increase manufacturing along with enhancing research, deep learning-based approaches could be the best alternative for developing practical AVS. With this vision, in this systematic review paper, we broadly discussed the literature of deep learning for AVS from the past decade for real-life implementation in core fields. The systematic review on AVS implementing deep learning is categorized into several modules that cover activities including perception analysis (vehicle detection, traffic signs and light identification, pedestrian detection, lane and curve detection, road object localization, traffic scene analysis), decision making, end-to-end controlling and prediction, path and motion planning and augmented reality-based HUD, analyzing research works from 2011 to 2021 that focus on RGB camera vision. The literature is also analyzed for final representative outcomes as visualization in augmented reality-based head-up display (AR-HUD) with categories such as early warning, road markings for improved navigation and enhanced safety with overlapping on vehicles and pedestrians in extreme visual conditions to reduce collisions. The contribution of the literature review includes detailed analysis of current state-of-the-art deep learning methods that only rely on RGB camera vision rather than complex sensor fusion. It is expected to offer a pathway for the rapid development of cost-efficient and more secure practical autonomous vehicle systems.

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Section: Discussionmentioning

confidence: 99%

Section: Lane Detection and Trackingmentioning

confidence: 99%

Vision-Based Autonomous Vehicle Systems Based on Deep Learning: A Systematic Literature Review

2022

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“…For example, machine learning and deep learning are the AI algorithms that detect lanes. Unfortunately, most traditional lane detection systems suffer from either processing time that does not meet real-time needs or inefficiency in a complex environment that also fails to meet the total availability restriction of such a core function [45]. The two branches of AI-based methodology described in this paper are machine learning and deep learning-based techniques.…”

Section: ) Geometric Modelling/traditional Methodsmentioning

confidence: 99%

Lane Detection in Autonomous Vehicles: A Systematic Review

et al. 2023

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One of the essential systems in autonomous vehicles for ensuring a secure circumstance for drivers and passengers is the Advanced Driver Assistance System (ADAS). Adaptive Cruise Control, Automatic Braking/Steer Away, Lane-Keeping System, Blind Spot Assist, Lane Departure Warning System, and Lane Detection are examples of ADAS. Lane detection displays information specific to the geometrical features of lane line structures to the vehicle's intelligent system to show the position of lane markings. This article reviews the methods employed for lane detection in an autonomous vehicle. A systematic literature review (SLR) has been carried out to analyze the most delicate approach to detecting the road lane for the benefit of the automation industry. One hundred and two publications from well-known databases were chosen for this review. The trend was discovered after thoroughly examining the selected articles on the method implemented for detecting the road lane from 2018 until 2021. The selected literature used various methods, with the input dataset being one of two types: self-collected or acquired from an online public dataset. In the meantime, the methodologies include geometric modeling and traditional methods, while AI includes deep learning and machine learning. The use of deep learning has been increasingly researched throughout the last four years. Some studies used stand-alone deep learning implementations for lane detection problems. Meanwhile, some research focuses on merging deep learning with other machine learning techniques and classical methodologies. Recent advancements imply that attention mechanism has become a popular combined strategy with deep learning methods. The use of deep algorithms in conjunction with other techniques showed promising outcomes. This research aims to provide a complete overview of the literature on lane detection methods, highlighting which approaches are currently being researched and the performance of existing state-of-the-art techniques. Also, the paper covered the equipment used to collect the dataset for the training process and the dataset used for network training, validation, and testing. This review yields a valuable foundation on lane detection techniques, challenges, and opportunities and supports new research works in this automation field. For further study, it is suggested to put more effort into accuracy improvement, increased speed performance, and more challenging work on various extreme conditions in detecting the road lane.

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“…In this case, MCMC techniques are generally used to sample coefficients from the target posterior (Fakhfakh et al. 2020b ). The main limitation of such techniques lies in the high complexity level, especially when multidimensional data are handled.…”

Section: Related Workmentioning

confidence: 99%

“…However, the main difficulty is to derive analytical closed-form expressions of the estimators because of the posterior distribution form which can be complex if sophisticated priors are used, such as those promoting sparsity. In this case, MCMC techniques are generally used to sample coefficients from the target posterior Fakhfakh et al (2020b). The main limitation of such techniques lies in the high complexity level, especially when multidimensional data are handled.…”

Section: Related Workmentioning

confidence: 99%

Non-smooth Bayesian learning for artificial neural networks

Fakhfakh

Chaâri

Bouaziz

et al. 2022

J Ambient Intell Human Comput

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Artificial neural networks (ANNs) are being widely used in supervised machine learning to analyze signals or images for many applications. Using an annotated learning database, one of the main challenges is to optimize the network weights. A lot of work on solving optimization problems or improving optimization methods in machine learning has been proposed successively such as gradient-based method, Newton-type method, meta-heuristic method. For the sake of efficiency, regularization is generally used. When non-smooth regularizers are used especially to promote sparse networks, such as the norm, this optimization becomes challenging due to non-differentiability issues of the target criterion. In this paper, we propose an MCMC-based optimization scheme formulated in a Bayesian framework. The proposed scheme solves the above-mentioned sparse optimization problem using an efficient sampling scheme and Hamiltonian dynamics. The designed optimizer is conducted on four (4) datasets, and the results are verified by a comparative study with two CNNs. Promising results show the usefulness of the proposed method to allow ANNs, even with low complexity levels, reaching high accuracy rates of up to . The proposed method is also faster and more robust concerning overfitting issues. More importantly, the training step of the proposed method is much faster than all competing algorithms.

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Bayesian curved lane estimation for autonomous driving

Cited by 12 publications

References 58 publications

Vision-Based Autonomous Vehicle Systems Based on Deep Learning: A Systematic Literature Review

Vision-Based Autonomous Vehicle Systems Based on Deep Learning: A Systematic Literature Review

Lane Detection in Autonomous Vehicles: A Systematic Review

Non-smooth Bayesian learning for artificial neural networks

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