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Ad Hoc-Obstacle Avoidance-Based Navigation System Using Deep Reinforcement Learning for Self-Driving Vehicles

N.S. Manikandan, K. Ganesan, Yong Wang

2023IEEE Access18 citationsDOIOpen Access PDF

Abstract

In this research, a novel navigation method for self-driving vehicles that avoids collisions with pedestrians and ad hoc obstacles is described. The proposed approach predicts the locations of ad hoc obstacles and wandering pedestrians by using an RGB-D depth sensor. Unique ad hoc-obstacle-aware mobility rules are presented considering those environmental uncertainties. A Deep Reinforcement Learning (DRL) method is proposed as a decision-making technique (to steer the self-driving vehicle to reach the target without incident). The deep Q-network (DQN), double deep Q-network (DDQN), and dueling double deep Q-network (D3DQN) algorithms were compared, and the D3DQN had the fewest negative rewards. We tested the algorithms using the Carla simulation environment to examine the input values from the RGB-D and RGB-Lidar. The series of algorithms that make up the convoluted neural network D3DQN was consequently selected as the optimum DRL model. In the modeling of slow-moving urban traffic, RGB-D and RGB-Lidar generated essentially the same results. A self-driving version of an updated child-ride-on-car was modified to demonstrate the real-time effectiveness of the proposed algorithm.

Topics & Concepts

Computer scienceRGB color modelReinforcement learningObstacleObstacle avoidanceArtificial intelligenceWireless ad hoc networkLidarReal-time computingComputer visionDeep learningIntelligent transportation systemSimulationMobile robotEngineeringRemote sensingTransport engineeringTelecommunicationsGeographyRobotWirelessArchaeologyAutonomous Vehicle Technology and SafetyVehicular Ad Hoc Networks (VANETs)Traffic control and management
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