自動駕駛模擬：產業鏈結構分析 (2019∼2020)：第2卷

長期來看，單一車輛智能將無法實現完全自動駕駛，車路協同系統（CVIS）正摸索如何將自動駕駛帶入實際道路。在未來2∼3年中，自動駕駛將在物流或交通等部門實用化，例如固定路線公車、無人配送、公園微循環等的實現指日可待。

自動駕駛產業發展與自動駕駛模擬直接相關。過去2年自動駕駛開發的減速，對於自動駕駛以及自動駕駛模擬初創企業而言皆是前所未有的挑戰。感測器模擬企業RightHook在兩年以來沒有任何進展；同時，2019年幾乎沒有新的自動駕駛模擬初創企業登場。

本報告研究全球及中國自動駕駛 (AD) 模擬的產業鏈結構，彙整AD模擬特徵、主要相關技術、產業相關結構、整合平台／車輛運動模擬領域主要企業 (簡介、主要產品、業務發展情況)等相關情報。

目錄

自動駕駛模擬平台與企業

• Alibaba DAMO Academy
  • 簡介
  • 自動駕駛技術ROADMAP
  • AutoDrive平台
  • 自動駕駛模擬平台
• Saimo
  • 簡介
  • 模擬測試平台
• Huawei
  • 簡介
  • 自動駕駛模擬平台
  • 模擬平台應用

道路、天氣、交通情況模擬

• 虛擬情況的建構（天氣、道路、交通等）
• 道路
• 天氣
• 交通流量
• 企業
• ESI Pro-SiVIC
• rFpro
• Cognata
• Parallel Domain
• Metamoto
• AAI
• Applied Intuition
• Ascent
• Ansible Motion
• UNITY
• 其他情況用的模擬軟體/模擬器

感測器模擬

• 感測器模擬簡介
  • Lidar模擬
  • Lidar模擬的參數組態
  • 相機模擬
  • 雷達模擬
  • 其他感測器模擬
  • 感測器模擬企業
• MonoDrive
• RightHook
• OPTIS
• Claytex

模擬介面

• 模擬系統介面簡介
  • 模擬系統介面分類
  • Hardware-in-the-Loop（HIL）模擬
  • Hardware-in-the-Loop（HIL）模擬企業
• NI
• ETAS
• Vector
• dSPACE

標準化與未來趨勢

• 自動駕駛模擬國際標準化組織
• 中國自動駕駛模擬測試標準
• 中國參與國際基準制定
• 未來開發趨勢
• OEM自動駕駛模擬佈局

Autonomous Driving Simulation (II): It Turns Out to Be a Battlefield of Giants

Alibaba DAMO Academy unveiled in early 2019 the "Top Ten Technology Trends of 2019", most of which are still credible today, including two trends about autonomous driving:

Trend 1: Autonomous driving is in a cooling-off period

Only "single-car intelligence" cannot achieve absolute autonomous driving in the long run, but cooperative vehicle infrastructure system (CVIS) is gathering way to bring autonomous driving on roads in a reality. In the next two years or three, autonomous driving will be commercialized in limited scenarios such as logistics and transportation, for example, fixed-route buses, unmanned delivery, and micro-circulation in parks are just around the corner.

Trend 2: Real-time simulation of cities becomes possible, and smart cities emerge

The perceived data of urban infrastructure and the real-time data flow of cities will be pooled on a big computing platform. The advances in algorithms and computing power will facilitate the real-time fusion of unstructured information like video and other structured information. Real-time simulation of cities becomes a possibility, and local intelligence in cities will be upgraded to global intelligence. In the future, urban brain technology R&D and application will be in full swing with the involvement of more forces. Beyond the physical cities, there will be smart cities with full spatiotemporal perception, full-factor linkage and full-cycle iteration.

The development of autonomous driving industry has a direct bearing on autonomous driving simulation. The decelerating autonomous driving in the past two years is an unprecedented challenge to startups not only in autonomous driving but in autonomous driving simulation. RightHook, a sensor simulation company, has made no progress for two years; meanwhile, new autonomous driving simulation startups rarely ever came out in 2019.

On the contrary, the giants perform strikingly.

At the Shanghai Auto Show in April 2019, Huawei launched the autonomous driving cloud service Octopus (including training, simulation and testing).

In December 2019, Waymo acquired Latent Logic to strengthen its simulation technology.

In April 2020, Alibaba DAMO Academy released the "hybrid simulation test platform" for autonomous driving.

GAC believes that a virtual simulation platform was the supplement of the real vehicle test platform before, but it is indispensable to the R&D of L3 (or above) autonomous driving. At present, virtual simulation tests share more than 60% of GAC's autonomous driving R&D, a figure projected to rise to 80% in the future.

Simulation is essential for both single-car intelligence and autonomous driving R&D in CVIS route.

As autonomous driving is heading from single-car intelligence to CVIS, autonomous driving simulation has evolved from dynamics simulation, sensor simulation and road simulation (static) to traffic flow simulation (dynamic) and smart city simulation.

51VR, which has raised hundreds of millions of yuan, changed its name to 51WORLD after experiencing the VR bubble, and set about digital twin cities and autonomous driving simulation. 51WORLD signed a contract to settle in the Liangjiang New Area of Chongqing in November 2019, and will focus on expanding innovative applications of digital twin cities in Chongqing as well as autonomous driving simulation.

In fact, the combination of VR and autonomous driving simulation is not the last resort of 51WORLD. VR/AR plays a growing role in autonomous driving simulation. The technologies for building virtual scenarios are generally based on modeling software, completed games, VR / AR, and HD maps.

In August 2019, rFpro launched an autonomous driving simulation training system based on VR scenarios, featured as follows:

• (1) A multitude of autonomous driving simulation operations can be fulfilled in the software.

• (2) rFpro also allows the import of models from 3rd party maps, including IPG ROAD5, .max, .fbx, OpenFlight, Open Scene Graph, .obj., featured with ultra-HIDEF graphical fidelity.

Given the importance of autonomous driving simulation, the formulation of simulation standards has kicked off.

Association for Standardization of Automation and Measuring Systems (ASAM) is a global leader in autonomous driving simulation test standards (mainly OpenX Standards). Since the launch by ASAM, OpenX Standards has attracted more than 100 companies worldwide (including major automakers in Europe, America and Japan, and Tier1 suppliers) to participate in the formulation of the standards.

In ASAM simulation verification, OpenX Standards cover Open-DRIVE, OpenSCENARIO, Open Simulation Interface (OSI), Open-LABEL and OpenCRG.

OpenDRIVE and OpenSCENARIO unify different data formats for simulation scenarios.

OpenLABEL provides a unified calibration method for initial data and scenarios.

OSI is a generic interface that allows users to connect any sensor with a standardized interface to any automated driving function or driving simulator tool.

OpenCRG realizes the interaction between road physical information and static road scenarios.

In September 2019, China Automotive Technology & Research Center (CATARC) and ASAM jointly established the C-ASAM Working Group whose early members included Huawei, SAIC, CATARC Data Resource Center, Tencent, 51VR, Baidu, to name a few.

Table of Contents

2. Autonomous Driving Simulation Platforms and Companies (added)

• 2.16. Alibaba DAMO Academy
  • 2.16.1. Profile
  • 2.16.2. Autonomous Driving Technology Roadmap
  • 2.16.3. AutoDrive Platform
  • 2.16.4. Autonomous Driving Simulation Platform
• 2.17. Saimo
  • 2.17.1. Profile
  • 2.17.2. Simulation Test Platform
  • 2.17.3. Cooperation
• 2.18. Huawei
  • 2.18.1. Profile
  • 2.18.2. Autonomous Driving Simulation Platform
  • 2.18.3. Application of Simulation Platform

4. Simulation of Road, Weather and Traffic Scenarios

• 4.1.1. Construction of Virtual Scenarios (Weather, Roads, Traffic, etc.)
• 4.1.2. Roads
• 4.1.3. Weather
• 4.1.4. Traffic Flow
• 4.1.5. Companies
• 4.2. ESI Pro-SiVIC
  • 4.2.1. Profile of ESI
  • 4.2.2. Products of ESI
  • 4.2.3. Acquisitions and Integration of ESI
  • 4.2.4. Introduction to ESI Pro-SiVIC
  • 4.2.5. Simulation Platform of ESI Pro-SiVIC
  • 4.2.6. Application of ESI Pro-SiVIC
  • 4.2.7. Procedures of ESI Pro-SiVIC
  • 4.2.8. Technical Competence of ESI Pro-SiVIC
• 4.3. rFpro
  • 4.3.1. Profile
  • 4.3.2. Autonomous Driving Simulation Platform
  • 4.3.3. Simulation Test Process and Platform Advantages
  • 4.3.4. Autonomous Driving Test in VR
  • 4.3.5. Partners
  • 4.3.6. Application
• 4.4. Cognata
  • 4.4.1. Profile
  • 4.4.2. Introduction to Simulation Platform
  • 4.4.3. Process and Features of Autonomous Driving Simulation
  • 4.4.4. Partners
• 4.5. Parallel Domain
  • 4.5.1. Profile
  • 4.5.2. Simulation Platform
  • 4.5.3. Advantages of Simulation Platform
  • 4.5.4. Application of Simulation Platform
• 4.6. Metamoto
  • 4.6.1. Profile
  • 4.6.2. Introduction to Simulation Platform
  • 4.6.3. Editing of Simulation Platform
  • 4.6.4. Operation of Simulation Platform
  • 4.6.5. Analysis of Simulation Platform
  • 4.6.6. Cooperation
• 4.7. AAI
  • 4.7.1. Profile
  • 4.7.2. Main Products & Solutions
  • 4.7.3. Application
  • 4.7.4. Cooperation
• 4.8. Applied Intuition
  • 4.8.1. Profile
  • 4.8.2. Simulation Platform
  • 4.8.3. Application Case 1
  • 4.8.4. Application Case 2
  • 4.8.5. Application Case 3
• 4.9. Ascent
  • 4.9.1. Profile
  • 4.9.2. Simulator Platform
• 4.10. Ansible Motion
  • 4.10.1. Profile
  • 4.10.2. Main Products
  • 4.10.3. Solutions
• 4.11. UNITY
  • 4.11.1. Profile
  • 4.11.2. Autonomous Driving Simulation Solutions
  • 4.11.3. Cooperation
• 4.12. Simulation Software / Simulator for Other Scenarios
  • 4.12.1. SUMO
  • 4.12.2. PTV-VISSIM
  • 4.12.3. RoadRunner

5. Sensor Simulation

• 5.1. Introduction to Sensor Simulation
  • 5.1.1. Lidar Simulation
  • 5.1.2. Parameter Configuration of Lidar Simulation
  • 5.1.3. Camera Simulation (1)
  • 5.1.4. Camera Simulation (2)
  • 5.1.5. Radar Simulation (1)
  • 5.1.6. Radar Simulation (2)
  • 5.1.7. Simulation of Other Sensors
  • 5.1.8. Sensor Simulation Companies
• 5.2. MonoDrive
  • 5.2.1. Profile
  • 5.2.2. Sensor Simulator
  • 5.2.3. Workflow
• 5.3. RightHook
  • 5.3.1. Profile
  • 5.3.2. Simulation
  • 5.3.3. Simulation Workflow
  • 5.3.4. Solutions
• 5.4. OPTIS
  • 5.4.1. Profile
  • 5.4.2. Main Products
  • 5.4.3. Application
  • 5.4.4. Customers and Partners
• 5.5. Claytex

6. Simulation Interface

• 6.1. Introduction to Simulation System Interface
  • 6.1.1. Classification of Simulation System Interface
  • 6.1.2. Hardware-in-the-Loop (HIL) Simulation
  • 6.1.3. Hardware-in-the-Loop (HIL) Simulation Companies
• 6.2. NI
  • 6.2.1. Profile
  • 6.2.2. Application
  • 6.2.3. VRTS
  • 6.2.4. HIL System
  • 6.2.5. Camera and V2X HIL Test
  • 6.2.6. The Solution Combining ADAS Sensors with HIL Tests
• 6.3. ETAS
  • 6.3.1. Profile
  • 6.3.2. COSYM
  • 6.3.3. LABCAR System Components
  • 6.3.4. LABCAR Software
  • 6.3.5. LABCAR Simulation Models
  • 6.3.6. LABCAR Simulation Models
• 6.4. Vector
  • 6.4.1. Profile
  • 6.4.2. Introduction to DYNA4
  • 6.4.3. Features of DYNA4
  • 6.4.4. Application of DYNA4
  • 6.4.5. Simulation Interface
• 6.5. dSPACE
  • 6.5.1. Profile
  • 6.5.2. Real-time Simulation System
  • 6.5.3. High-performance Simulation Environment
  • 6.5.4. Real-time Simulation System Solutions
  • 6.5.5. SCALEXIO
  • 6.5.6. Application of Test V2N/V2Cloud
  • 6.5.7. Simulation Tool Chain
  • 6.5.8. Simulation Interface Software
  • 6.5.9. Uhnder Uses dSPACE's Automotive Radar Target Simulator
  • 6.5.10. Partners

7. Standardization and Future Trends

• 7.1. International Standardization Organization for Autonomous Driving Simulation
  • 7.1.1. Profile of ASAM
  • 7.1.2. ASAM's OpenX Standards
  • 7.1.3. C-ASAM Working Group
  • 7.1.4. IAMTS
• 7.2. Autonomous Driving Simulation Test Standards in China
  • 7.2.1. National Autonomous Driving Road Test Standards (1)
  • 7.2.2. National Autonomous Driving Road Test Standards (2)
  • 7.2.3. Provincial and Municipal Autonomous Driving Road Test Standards (1)
  • 7.2.4. Provincial and Municipal Autonomous Driving Road Test Standards (2)
• 7.3. China Participates in the Formulation of International Standards
  • 7.3.1. China's Active Involvement in International Standards
  • 7.3.2. Formulation of International Standards for Autonomous Driving Test Scenarios
• 7.4. Future Development Trends
• 7.5. Autonomous Driving Simulation Layout of OEMs