无人驾驶产业报告-PDF版

极光：2020年共享汽车发展趋势研究报告（43页）.pdf

2020 2020.07 2 深圳市和讯华谷信息技术有限公司 版权所有 2011-2019 粤ICP备12056275号-13 2020126.6% 2.0 B GoFun Connect2.0 3.

2020-07-29 43页 5星级

电气设备行业：全球电动车系列海外新能源汽车政策深度解读-20200723[46页].pdf

中泰证券证券研究报告/行业深度报告2020年07月23日海外新能源汽车政策深度解读电气设备-全球电动车系列评级：增持（维持）重点公司基本状况PE简称股价PS评级分析师苏晨20192022日2020E2.

2020-07-28 46页 5星级

全国汽车标准化技术委员会：自动驾驶功能仿真测试标准化需求研究报告（2020）（66页）.pdf

自动驾驶功能仿真测试标准化需求研究项目组 自动驾驶自动驾驶功能功能仿真测试标准化需求研究报告仿真测试标准化需求研究报告 全国汽车标准化技术委员会全国汽车标准化技术委员会 智能网联汽车分技术委员会智能网.

2020-07-02 66页 5星级

工信部：2020自动驾驶数据安全白皮书（57页）.pdf

自动驾驶数据安全白皮书自动驾驶数据安全白皮书 （2020） 2020 年年 1 月月 版权版权声声明明 本白皮书版权属于国家工业信息安全发展研究中心及各参编单位共有，受法律保护。转载、摘编或利用其它.

2020-07-02 57页 5星级

全国汽车标准化技术委员会：自动驾驶实际道路测试标准化需求研究报告（2020）（52页）.pdf

上海汽车股份有限公司、北京百度网讯科技有限公司、重庆车辆检测研究院、宝马（中国）服务有限公司、北京汽车股份有限公司、北京智能车联产业创新中心有限公司、戴姆勒大中华区投资有限公司

2020-07-02 52页 5星级

中国公路学会自动驾驶工作委员会：车路协同自动驾驶发展报告（2019）（34页）.pdf

违反上述声明者，中国公路学会自动驾驶工作委员会将追究其相关法律责任。 III 车路协同自动驾驶车路协同自动驾驶发展报告发展报告 发布机构发布机构

2019-12-02 34页 5星级

中国智能网联汽车产业创新联盟：中国智能网联汽车封闭测试和开放道路测试发展情况（2019）（34页）.pdf

中国智能网联汽车封闭测试和开放道路测试发展情况中国智能网联汽车产业创新联盟李乔2019年2月22日智能网联汽车测试示范背景情况目 录国家级测试示范区发展现状调查213国家级测试示范区发展面临问题分析4.

2019-12-02 34页 5星级

中国专利保护协会：2019自动驾驶行业专利分析报告（53页）.pdf

因此本报告目的仅是为分支行业内所属企业提供专利领域的一般性提示，以供会员企业参考

2019-12-02 53页 5星级

中国软件评测中心：车载智能计算基础平台 参考架构1.0 （2019）.pdf

点击查看更多中国软件评测中心：车载智能计算基础平台 参考架构1.0 （2019）.pdf精彩内容。

2019-12-02 19页 5星级

智能车联：2019年北京市自动驾驶车辆道路测试报告（34页）.pdf

“通过搭载先进传感器等装置，运用人工智能等新技术，具有自动驾驶功能，逐步成为智能移动空间和应用终端的新一代汽车。智能汽车通常又称为智能网联汽车、自动驾驶汽车等”

2019-12-02 34页 5星级

联网自动驾驶汽车高速公路 (CAVH)：大规模自动驾驶系统 (ADS) 部署的愿景和发展报告 (2019)（英文版）（42页）.pdf

Connected Automated Vehicle Highway (CAVH): A Vision and Development Report for Large-Scale Automated Driving System (ADS) Deployment Version 1.0 Working Committee of Automated Driving China Highway and Transportation Society June 2019 I Copyright Statement The copyright of this report belongs to the Working Committee of Automated Driving of China Highway and Transportation Association and is protected by law. Where the texts or viewpoints of this report are reproduced, extracted or used in other ways, the source shall be indicated as Source: Working Committee of Automated Driving of China Highway and Transportation Association. Those who violate the above statement will be investigated for legal responsibility. III Contributors Publication Agency: Working Committee on Automated Driving, China Highway and Transportation Society Contributing Institutes: 1. Institute on Internet of Mobility, Southeast University and University of Wisconsin-Madison 2. Southeast University 3. Tsinghua University 4. Beihang University 5. Beijing Jiaotong University 6. Beijing University of Technology 7. Traffic Management Research Institute, Ministry of Public Security Contributing Authors: 1. Yang CHENG 2. Yuan ZHENG 3. Huachun TAN 4. Jianbo YI 5. Xu QU 6. Shen LI 7. Shuyan HE 8. Qiang TU 9. Haijian LI 10. Zhenlong LI 11. Yongming HE 12. Zhihong YAO 13. Yangxin LIN 14. Yanjin LI 15. Tengfei YUAN 16. Haoran WU 17. Fan DING 18. Danya YAO 19. Shanglu HE 20. Haiyang GU 21. Zhijun CHEN 22. Kegang ZHAO 23. Yikang RUI 24. Fan YANG 25. Jian ZHANG 26. Dazhi JIANG 27. Jun BI IV 28. Yuanli GU 29. Steven PARKER 30. Shawn LEIGHT 31. Peter JIN 32. David NOYCE 33. Soyoung (Sue) AHN 34. Jianqiang WANG 35. Yugong LUO 36. Shengbo LI 37. Mingyuan BIAN 38. Guizhen YU 39. Guangquan LU 40. Daxin TIAN 41. Haiyang YU 42. Li LI 43. Jianming HU 44. Wenjie LU 45. Min WANG 46. Wei SUN 47. Jianhua YUAN 48. Zhigang XU 49. Siyuan GONG Advisory Committee of Experts: 1. Mengyong WENG 2. Song PANG 3. Bin RAN 4. Keqiang LI 5. Yunpeng WANG 6. Yi ZHANG 7. Changjun WANG 8. Xiaohui SHI 9. Xiangmo ZHAO 10. Shanzhi CHEN 11. Jinquan ZHANG 12. Ling JIN 13. Guangsu SHANG 14. Xiaojing WANG 15. Yanqing CEN 16. Gang WANG 17. Bo NIU 18. Yongjian ZHONG V Introduction Intelligent Transportation Systems (ITS) has been considered instrumental methods to alleviate traffic congestions and improve traffic safety when the construction of new infrastructure or capacity increase are not viable. With the rapid development of artificial intelligence, mobile internet, big data, and other innovative information technologies, the next generation of ITS will feature the Automated Driving System (ADS) technologies and become the essential approach to ultimately address traffic problems. The vehicle-based ADS solutions are lead by Google, Tesla, Uber, and Baidu. Vehicle-based ADS systems use onboard high-resolution sensors to detect real-time driving conditions, and use on-board edge computing and Artificial Intelligence (AI) algorithms for driving decision making and vehicle control to achieve automated driving. The main limitations of the vehicle-based technologies are the high concentration of onboard technologies and sensors, which make the large-scale deployment of technologies financially and societally difficult. The industry has come to realize that the large-scale deployment of ADS needs to take advantage of intelligent road infrastructure. Vehicle-based ADS sensing and computing systems can also be deployed along intelligent infrastructures to achieve ADS for all vehicles with less intensive resource deployment on the vehicle end compared with the vehicle-based approach. The interaction and coupling between the intelligent road infrastructures and intelligent vehicles have the potentials of facilitating or even replacing vehicle-based ADS technologies in large-scale deployment. Under such vehicle-infrastructure integration paradigm, the development of the Connected Automated Vehicle Highway (CAVH) technologies will take the advantage of the rapid development and commercialization of ADS technologies, next-generation wireless communication, artificial intelligence(AI), Internet of Things (IoT), Cloud and Edge computing, Electric Vehicles and highway electrification, smart sensor and infrastructure, smart city, and other technologies to achieve ADS in large scales. The CAVH approach can also enable deep integration across different industrial sectors, including information technologies, intelligent manufacturing, transportation and logistics, and automobile industries to establish cross-industry ecosystems and supply chains for new scientific, technological, and industrial revolutions. CAVH extends the existing applications of Connected Automated Vehicle (CAV) technologies into system-wide integration between vehicles and infrastructure. The development and deployment of the CAVH-based ADS technologies could be classified as four different stages: Stage I, information exchange and interaction: establish the Vehicle to Infrastructure & Infrastructure to Vehicle (V2I & I2V) connectivity. Stage II, collaborative sensing, prediction, and decision-making: share and integrate the sensing and prediction results between vehicles and infrastructure and execute coordinated VI decision-making. Stage III, coordinated control: coordinate the real-time vehicle and infrastructure control with collaborative sensing, prediction, and decision-making results. Stage IV, vehicle-infrastructure integration: based on stage I, II and III, vehicles and infrastructure could achieve overall coordination and complete system functions to achieve global planning, control, and optimization of vehicle-infrastructure operations for ADS. The CAVH-based ADS uses the advanced sensor, network, computing, and control technologies, to achieve the comprehensive sensing for the road and traffic environment, and the wide range and large capacity data sharing between multiple systems facilitating different vehicles and different traffic automation system at various integration levels. Based on CAVH, automated driving systems can be constructed from three dimensions: vehicle automation, network interconnection, and system integration. Such systems can efficiently execute the essential automated driving functions of sensing, prediction, decision-making, and control, and eventually forms intelligent systems that can integrate, coordinate, control, manage, and optimize all vehicles, information services, facilities, equipment, intelligent traffic management, and control. The CAVH is composed of four key subsystems, including traffic management subsystem, smart roadside infrastructure subsystem, intelligent vehicle subsystem, and intelligent communication subsystem, and four key functional modules: sensing module, prediction module, decision-making module, and control module. From a generalized perspective, the CAVH system covers the CAV system and the intelligent road infrastructure system. That is, the intelligent network vehicles, the Internet of vehicles, the active traffic management systems, the automated highway systems, and transportation entities are all included. The advanced CAVH is a more advanced stage of CAVH, which further enhances the intelligence of road infrastructure, which therefore accelerates the commercialization of automated driving, and eventually, achieves the integrated development of vehicles and roads for the automated driving. Traditional technologies and industries are facing reconstruction and reengineering due to continuous innovations. As an emerging system, CAVH is bound to generate new technologies, industries, and businesses. The CAVH system covers automated vehicles, transportation environment, communication facilities, traffic management, and control system, and other entities, related to technologies of computer vision, communication, network security, vehicle collaboration with road, active control, human-vehicle-road-center collaborative service management, highway automation system, and system integration. These technologies are key to vehicle road collaborative automated driving toward commercialization. CAVH involves many industries, which are of multiple roles, complementing advantages, and prominent characteristics. Developing CAVH systems and promoting CAVH technology applications can advance the chip, software, information communication, data service, and other industry development and transformation, who are the suppliers of vehicle and infrastructure industries. The CAVH based automated driving ecosystem can enable the deployment of intelligent VII transportation and smart city solutions, a system of systems integration, and shared digital economy, to foster new economic growth. This report presents the strategic plans and development directions of key technologies in CAVH, analyzes the development trends and CAVH industry positioning, and puts forward suggestions for the development of CAVH that is suitable for China based on an in-depth understanding of the concepts and connotation of CAVH. IX Contents Copyright Statement . I Introduction . V Contents . IX 1 Automated Driving . 1 1.1 Connotation of Automated Driving . 1 1.1.1 Principle of Automated Driving . 1 1.1.2 Automated Driving Classification . 1 1.2 Concept of Vehicle-Road Cooperative Automated Driving . 3 1.2.1 Vehicle Automation . 4 1.2.2 Connectivity . 5 1.2.3 System Integration . 5 1.3 Development Level of Vehicle-Infrastructure Cooperative Automated Driving . 6 1.4 Key Sub-systems and Modules . 7 1.4.1 Key Sub-systems . 7 1.4.2 Key Modules . 8 2 Key Technology and Development Trend of CAVH. 11 2.1 Key Technology Analysis of CAVH . 11 2.1.1 Environment Sensing Technology . 11 2.1.2 Data Fusion and Prediction Technology . 11 2.1.3 Intelligent Decision Technology . 11 2.1.4 Control Execution Technology . 12 2.1.5 I2X and V2X Communication Technology . 12 2.1.6 Network Security Technology . 12 2.1.7 Collaborative Optimization Technology . 13 2.1.8 Integrated Optimization Technology for Transportation System . 13 2.2 Future Direction of CAVH . 13 2.2.1 Integrating High-Resolution and High-Reliability Positioning with RoadSide Unit based CAVH Applications . 13 2.2.2 Visual Recognition and LiDAR Becoming the Core of Sensing Technologies . 14 2.2.3 Cloud Platform Technologies . 14 2.2.4 Connected Automated Vehicle Technologies . 15 2.2.5 CAVH Traffic System Optimization Technologies . 15 3 Development Trend and Roles of CAVH . 17 3.1 Development Trend of CAVH . 17 3.1.1 Key Technologies and Infrastructures (Upstream) . 18 3.1.2 Intelligent Manufacturing and System Integration (Middle) . 21 3.1.3 Application Services and Value-Added Services (Downstream) . 22 3.1.4 CAVH Standardization . 24 3.2 Roles of Organizations, Agencies, and Enterprises in the Development of CAVH . 25 3.2.1 Government Agencies . 25 X 3.2.2 Industry . 25 3.2.3 Universities and Research Institutes . 26 3.2.4 Associations . 26 3.2.5 Financial Capital and Investment Institutions. 27 4 Policies and Suggestions . 29 4.1 Government . 29 4.1.1 Policies . 29 4.1.2 Standards. 29 4.1.3 Laws and Regulations . 29 4.2 Enterprises . 30 4.3 Universities and Research Institutes . 30 5 Terminology . 31 6 References . 33 Working Committee of Automated Driving, CHTS Development Report of CAVH (2019) 1 1 Automated Driving 1.1 Connotation of Automated Driving 1.1.1 Principle of Automated Driving Automated driving means that the vehicle senses the surrounding environment through the sensors onboard, makes control decisions based on the information collected and fused, and makes vehicle control decisions, including both longitudinal control and lateral control. The process of automated driving mainly includes three stages: information collection, information processing, and instruction execution. In the information collection stage, the automated vehicles detect the surrounding environment through the radar and camera mounted on the vehicle and collects information such as the position, speed, acceleration as well as pedestrians and vehicles nearby. Information processing stage: the autonomous vehicle transmits the collected information to the automotive electronic control unit (ECU) for analysis, calculation, and control decision. Instruction execution phase: the autonomous vehicle transmits the control decisions provided by the vehicles electronic control unit to the engine/motor management system and the electric power steering system (EPS) to achieve vehicle acceleration, deceleration, and steering operations. 1.1.2 Automated Driving Classification The SAE level of classification for automated driving is adopted in this report 1, as is shown in Figure 1 and Table 1. Figure 1 Automation Levels 1 Working Committee of Automated Driving, CHTS Development Report of CAVH (2019) 2 Table 1 Classification of Self-Driving Vehicles 1 NHTSA SAE The degree of automation Specific definition Driving performance Monitoring Take over Application scenes 0 0 No Automation Zero autonomy; the driver performs all driving tasks. Human driver Human driver Human driver None 1 1 Driver Assistance Vehicle is controlled by the driver, but some driving assist features may be included in the vehicle design. Human driver and vehicle Human driver Human driver Qualified scenes 2 2 Partial Automation Vehicle has combined automated functions, like acceleration and steering, but the driver must remain engaged with the driving task and monitor the environment at all times. Vehicle Human driver Human driver 3 3 Conditional Automation Driver is a necessity but is not required to monitor the environment. The driver must be ready to take control of the vehicle at all times with notice. Vehicle Vehicle Human driver 4 4 Highly Automation The vehicle is capable of performing all driving functions under certain conditions. The driver may have the option to control the vehicle. Vehicle Vehicle Vehicle Working Committee of Automated Driving, CHTS Development Report of CAVH (2019) 3 5 Fully Automation The vehicle is capable of performing all driving functions under all conditions. The driver may have the option to control the vehicle. Vehicle Vehicle Vehicle All scenes Level 0: The human driver does all the driving. Level 1: An Advanced Driver Assistance System (ADAS) on the vehicle can sometimes assist the human driver with either steering or braking/accelerating, but not both simultaneously. Level 2: An Advanced Driver Assistance System (ADAS) on the vehicle can itself actually control both steering and braking/accelerating simultaneously under some circumstances. The human driver must continue to pay full attention (“monitor the driving environment”) at all times and perform the rest of the driving task. Level 3: An Automated Driving System (ADS) on the vehicle can itself perform all aspects of the driving task under some circumstances. In those circumstances, the human driver must be ready to take back control at any t

2019-12-02 42页 5星级

中国自动驾驶仿真技术研究报告（2019）（110页）.pdf

摘要自动驾驶系统的计算机仿真是自动驾驶车辆测试和试验的基础关键技术，也是未来行业定义自动驾驶车辆相关开发与准入技术标准的基础工具。计算机仿真测试与真实物理测试互为补充，缺一不可。2019 中国自动驾驶.

2019-12-02 110页 5星级

AUVSI：2019无人驾驶汽车调研报告（13页）.pdf

2019 无人驾驶汽车调研报告2019 年 1 月1Perkins Coie LLP | AUSVI |2019 年 1 月目录执行摘要 . 2 主要结论 . 4 调研结果 . 5 调研方法与人口统计.

2019-12-02 13页 5星级

佐思汽研：2019年ADAS与自动驾驶市场发展蓝皮书（87页）（1）.pdf

2019 年 ADAS 与自动驾驶市场发展蓝皮书 2 目录 前言 . 3 第一章 感知系统篇. 5 1.1 车载摄像头. 6 1.2 2019Q1 前视单目安装量同比增长 71.7% . 10 1.

2019-12-01 85页 5星级

科达：2019-2020年中国汽车数字营销产业战略发展研究报告（93页）.pdf

点击查看更多科达：2019-2020年中国汽车数字营销产业战略发展研究报告（93页）.pdf精彩内容。

2019-12-01 93页 5星级

智能车联：2018年北京市自动驾驶车辆道路测试报告（24页）.pdf

/ 1/ 1未来交通之路，从现在开始为推动智能网联汽车自动驾驶产业化，北京市以“安全第一、有序创新”为核心原则，从自动驾驶车辆道路测试入手，在政策制定、标准研制、路网开放、牌照申领、测试监管及应用示范.

2018-12-02 24页 5星级

参照系：2017年无人驾驶行业研究报告（47页）.pdf

无人驾驶行业报告2017.09无人驾驶行业研究报告 附140家关联企业介绍Business Report 基于参照系企业数据库2017.09无人驾驶行业报告2017.09参照系研究报告成果3D打印3D.

2017-12-02 47页 5星级

今日头条：2017年奔向2025——自动驾驶潜在消费者报告（15页）.pdf

奔向2025自动驾驶潜在消费者报告目录Content引言引言1 1核心发现核心发现谁在关注自动驾驶谁在关注自动驾驶用户画像评论热度总体趋势评论热度迁移地图媒体态度及用户分享倾向公众如何看待自动驾驶公众.

2017-12-02 15页 5星级