Autonomous driving algorithms and its IC design / Jianfeng Ren, Dong Xia.
Ren, Jianfeng, author.; Xia, Dong, author.
2023
TL152.8 .R46 2023
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Title Autonomous driving algorithms and its IC design / Jianfeng Ren, Dong Xia.
Author Ren, Jianfeng, author.
ISBN 9789819928972 electronic book
9819928974 electronic book
9819928966
9789819928965
DOI https://doi.org/10.1007/978-981-99-2897-2
Published Singapore : Springer ; Beijing, China : Publishing house of Electronics Industry, [2023]
Language English
Description 1 online resource
Other Standard Identifiers 10.1007/978-981-99-2897-2 doi
Call Number TL152.8 .R46 2023
Dewey Decimal Classification 629.04/6
Summary With the rapid development of artificial intelligence and the emergence of various new sensors, autonomous driving has grown in popularity in recent years. The implementation of autonomous driving requires new sources of sensory data, such as cameras, radars, and lidars, and the algorithm processing requires a high degree of parallel computing. In this regard, traditional CPUs have insufficient computing power, while DSPs are good at image processing but lack sufficient performance for deep learning. Although GPUs are good at training, they are too power-hungry, which can affect vehicle performance. Therefore, this book looks to the future, arguing that custom ASICs are bound to become mainstream. With the goal of ICs design for autonomous driving, this book discusses the theory and engineering practice of designing future-oriented autonomous driving SoC chips. The content is divided into thirteen chapters, the first chapter mainly introduces readers to the current challenges and research directions in autonomous driving. Chapters 26 focus on algorithm design for perception and planning control. Chapters 710 address the optimization of deep learning models and the design of deep learning chips, while Chapters 11-12 cover automatic driving software architecture design. Chapter 13 discusses the 5G application on autonomous drving. This book is suitable for all undergraduates, graduate students, and engineering technicians who are interested in autonomous driving.
Note 4.2.2 Example: Dijkstraś Algorithm for Path Planning
Bibliography, etc. Note Includes bibliographical references.
Access Note Access limited to authorized users.
Source of Description Description based on online resource; title from digital title page (viewed on September 19, 2023).
Added Author Xia, Dong, author.
Available in Other Form Autonomous Driving Algorithms and Its IC Design
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Intro
Foreword
Contents
List of Figures
List of Tables
Chapter 1: Challenges of Autonomous Driving Systems
1.1 Autonomous Driving
1.1.1 Current Autonomous Driving Technology
1.2 Autonomous Driving System Challenges
1.2.1 Functional Constraints
1.2.2 Predictability Constraints
1.2.3 Storage Limitations
1.2.4 Thermal Constraints
1.2.5 Power Is Constrained
1.3 Designing an Autonomous Driving System
1.3.1 Perception Systems
1.3.2 Decision-Making
1.3.3 Vehicle Control
1.3.4 Safety Verification and Testing

1.4 The Autonomous Driving System Computing Platform
1.4.1 GPU
1.4.2 DSP
1.4.3 Field Programmable Gate Array FPGA
1.4.4 Specific Integrated Circuit ASIC
1.5 The Content of This Book
1.5.1 3D Object Detection
1.5.2 Lane Detection
1.5.3 Motion Planning and Control
1.5.4 The Localization and Mapping
1.5.5 The Autonomous Driving Simulator
1.5.6 Autonomous Driving ASICs
1.5.7 Deep Learning Model Optimization
1.5.8 Design of Deep Learning Hardware
1.5.9 Self-Driving ASICs Design
1.5.10 Operating Systems for Autonomous Driving

1.5.11 Autonomous Driving Software Architecture
1.5.12 5G C-V2X
References
Chapter 2: 3D Object Detection
2.1 Introduction
2.2 Sensors
2.2.1 Camera
2.2.2 LiDAR
2.2.3 Camera + Lidar
2.3 Datasets
2.4 3D Object Detection Methods
2.4.1 Monocular Images Based on Methods
2.4.2 Point Cloud-Based Detection Methods
2.4.2.1 Projection Methods
2.4.2.2 Volumetric Convolution Methods
2.4.2.3 Point Net Method
2.4.3 Fusion-Based Methods
2.5 Complex-YOLO: A Euler-Region-Proposal for Real-Time 3D Object Detection on Point Clouds [31]
2.5.1 Algorithm Overview

2.5.2 Point Cloud Preprocessing
2.5.3 The Proposed Architecture
2.5.4 Anchor Box Design
2.5.5 Complex Angle Regression
2.5.6 Evaluation on KITTI
2.5.7 Training
2.5.8 Birdś Eye View Detection
2.5.9 3D Object Detection
2.6 Future Research Direction
References
Chapter 3: Lane Detection
3.1 Traditional Image Processing
3.2 Example: Lane Detection Based on the Hough Transform
3.2.1 Hough Transform
3.2.2 Lane Detection
3.3 Example: RANSAC Algorithm and Fitting Straight Line
3.3.1 Overview of the RANSAC Algorithm

3.3.2 Use Python to Implement Line Fitting
3.4 Based on Deep Learning
3.5 The Multi-Sensor Integration Scheme
3.6 Lane Detection Evaluation Criteria
3.6.1 Lane Detection System Factors
3.6.2 Offline Evaluation
3.6.3 Online Evaluation
3.6.4 Evaluation Metrics
3.7 Example: Lane Detection
3.7.1 Overview
3.7.2 Loss Function
3.7.3 Experimental Results
3.7.4 Conclusion
References
Chapter 4: Motion Planning and Control
4.1 Overview
4.2 Traditional Planning and Control Solutions
4.2.1 Route Planning

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