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China Autonomous Driving Simulation Industry Chain Report, 2020-2021 (I) and (II)

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    Report

  • 406 Pages
  • April 2021
  • Region: China, Global
  • Research In China
  • ID: 5314562

Autonomous Driving Simulation Research: Foreign giants build closed-loop simulation platforms, while domestic companies focus on the construction of scenario library

In the development of high-level autonomous driving, the importance of simulation testing becomes more and more apparent. From 2020 to 2021, both foreign and domestic companies stepped up the layout in the field of autonomous driving simulation.

Foreign simulation giants are committed to building closed-loop simulation platforms for setting up industrial barriers

In the transition from industrial simulation to autonomous driving simulation, giants such as Ansys and Siemens have established various modules of autonomous driving simulation through continuous acquisition, cooperation and technological development, strengthened the closed-loop of the simulation platform, and built industrial barriers. At present, the layout of foreign leading companies has covered more than 80% of the simulation sector, and which is continuously updated.

From 2020 to 2021, top foreign simulation companies updated and optimized the following sectors:

01 More sensor models such as camera, radar, LiDAR, etc. are supported

Ansys: unified simulation with the addition of camera, LiDAR, and radar

On January 7, 2020, FLIR Systems, Inc. and ANSYS were partnering to deliver superior hazard detection capabilities for assisted driving and autonomous vehicles (AVs) - empowering automakers to deliver unprecedented vehicle safety. Through this partnership, FLIR will integrate a fully physics-based thermal sensor into ANSYS’ leading-edge driving simulator to model, test, and validate thermal camera designs within an ultra-realistic virtual world. The new solution will reduce OEM development time by optimizing thermal camera placement for use with tools such as automatic emergency braking (AEB), pedestrian detection, and within future AVs.

In January 2021, ANSYS 2021 R1 expanded sensor simulation capabilities with scanning and rotating lidar models to improve AV simulation reliability. At the same time, it used a new GPU to accelerate the radar simulation.

Siemens: addition of LiDAR simulation
In September 2020, Siemens partnered with XenomatiX to add a generic, physics-based LiDAR simulation model to its Simcenter Prescan software. The knowledge and expertise of XenomatiX’ optical team together with its advanced, true solid-state, LiDAR technology, can enable Siemens to fine-tune its simulation model and validate it with real-life measurements from XenomatiX.

At present, the LiDAR model of Prescan can accurately describe all the optical properties (including surface shape, reflection characteristics, texture, and structure) of materials.

CARLA: upgrade of LiDAR sensor
In September 2020, CARLA 0.9.10 came with the trunk packed of improvements, with notable dedication to sensors. The LIDAR sensor was upgraded, and a brand-new semantic LiDAR sensor provides with much more information of the surroundings.

02 Expansion of Cloud Simulation
Cloud computing capabilities can support large-scale simulation, cover massive driving scenarios, achieve high-concurrency running tests, and accelerate simulation running speed. Therefore, massively parallel acceleration in the cloud is one of the necessary core capabilities of autonomous driving simulation test platforms. Currently, the autonomous driving industry generally chooses Microsoft Azure as the cloud simulation partner.

For instance:


  • In October 2020, Ansys collaborated with Microsoft to offer cloud-enabled autonomous vehicle (AV) simulation capabilities to joint customers. Ansys VRXPERIENCE, an AV virtual test platform, can unlock massive scalability when run on Azure, empowering users to test drive millions of virtual miles across countless scenarios in an expedient manner - greatly optimizing safety and development costs.
  • In December 2020, AirSim added development environment deployment documents on Azure to support cloud simulation.
  • Siemens PreScan is compatible with Microsoft Azure, Amazon AWS, as well as some Chinese cloud service providers and cloud platforms.

03 Joint simulation has become a key development direction

Different simulation platforms have different emphasis on simulation modules. For example, Carsim, CarMaker, VI-Grade, VeDYNA, etc. focus on simulation of vehicle dynamics, while Vissim, SUMO, etc. keep an eye on simulation of traffic flow. From 2020 to 2021, more and more solution providers opened software interfaces and conduct joint simulations with other solutions.

The new version of Prescan released in January 2020 supports the generation of large-scale traffic flows. This feature is supported by the Aimsun plug-in and the PTV Vissim plug-in. The Aimsun plug-in enables the synchronization of Aimsun's micro traffic original scenarios; the Vissim plug-in can perform collaborative simulation and data transmission between TASS PreScan and PTV Vissim.

CARLA 0.9.9 released in April 2020 can realize the collaborative simulation with SUMO. In this mode, the actions or events that occur in one simulator will be automatically propagated to another simulator.

CARLA 0.9.11 released in December 2020 enables co-simulation between CarSim and CARLA, allowing users to create CarSim vehicles, taking control over dozens of parameters, including suspension systems and tires.


  • In January 2021, Mechanical Simulation Corporation announced the release of 2021.0 versions of the vehicle simulation tools CarSim®, TruckSim®, BikeSim®, and SuspensionSim®. This release focuses on scenes and scenarios to improve ease of setup and testing. The user interface and math models have improved third-party software support. In the future, the company will continue to develop tight interfaces to third-party software from technology partners like Epic Games, NVIDIA, atlatec, Foretellix, monoDrive, Siemens, and CARLA.
  • Domestic companies have embarked on autonomous driving simulation from the perspective of scenarios
  • The wider the coverage of scenarios that autonomous driving systems can handle, the wider the area that autonomous vehicles can drive. With the upgrade of autonomous driving functions, the number of scenarios that need be tested and verified has increased exponentially during the upgrade and iteration from L1 to L4/L5, and the construction of scenario libraries has become a vital part of the simulation industry chain.

At present, Chinese companies such as Tencent, CATARC, CAERI, Baidu, 51World have established their own autonomous driving simulation scenario libraries.

Tencent: More than 99% of autonomous vehicle simulation scenarios can be covered

Based on powerful game engine capabilities, Tencent's autonomous driving simulation platform TAD Sim performs excellently in the reality and accuracy of scenarios. Its scenario generation system can derive 20 million virtual scenarios based on 2,000 types of logic scenarios, covering more than 99% of automated vehicle simulation scenarios.

In June 2020, Tencent released TAD Sim 2.0, the new generation of its autonomous driving simulation platform, to improve the development and testing efficiency of autonomous driving. Compared with the previous generation, TAD Sim 2.0 fills the gap between road test data and virtual scenarios. With higher resolution in 3D scenario reconstruction and sensor simulation, the platform can make the simulation closer to reality. A huge variety of environments, weather conditions and even extreme traffic conditions can be generated by combining road test data and virtual scenarios to fulfill the needs of autonomous driving testing in TAD Sim 2.0.

However, Tencent will not stop at autonomous driving. Its further layout is to further explore its own capabilities, build virtual twin cities, and facilitate smart cities and smart transportation. Specifically, it will integrate its game technology, cloud technology, and simulation technology to create a virtual twin platform so as to realize the mapping between the real world and the virtual world, and self-learn and update in the virtual world. In the future, it will achieve iteration, prediction, decision-making and other capabilities.

CATARC: AD Scenario Generator debuts, and the built-in scenario library covers 4,000 Scenarios

CATARC’s self-developed simulation platform AD Chauffeur has a built-in scenario library covering natural driving scenarios, standard and regulatory scenarios, CIDAS dangerous accident scenarios and experience restructuring scenarios, etc.

The AD Chauffeur 2.0 released by CATARC in September 2020 adds the AD Scenario Generator, which enables scenario construction, the conversion of multi-source data formats OpenSCENARIO, logical scenario splicing and reorganization to support scenario generation. At the same time, it expands the built-in scenario library to cover 4,000 scenarios, which is convenient for clients.

CAERI: typical accident scenarios, autonomous driving accident scenarios, and expected functional safety scenarios are added

In December 2020, CAERI released the ""i-VISTA China Typical Driving Scenario Library V3.0"". Based on the natural driving scenarios, standard and regulatory scenarios, experience scenarios and a small number of accident scenarios in the previous version, CAERI added typical accident scenarios, autonomous driving accident scenarios, and expected functional safety scenarios. It supports autonomous driving simulation test and evaluation, and application to simulation systems such as MIL, SIL, and HIL.

In addition to the above-mentioned companies, Baidu exploits Apollo technology to establish a simulation scenario library. 51World’s ""Urban All-Element Scenario Automation Platform (AES2021)"" has improved the coverage and accuracy of scenarios.

Generally speaking, Chinese companies are still fighting their own way in the construction of scenario libraries, facing problems such as inconsistent data on scenarios, difficulty in establishing an evaluation and certification system of autonomous driving simulation & test. Therefore, the establishment of scenario library standards has become one of the current concerns in the field of simulation.




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Table of Contents

1. Introduction to Autonomous Driving Simulation
1.1 Overview of Simulation Technology
1.2 Significance of Simulation Testing to Autonomous Driving R&D
1.3 Types of Autonomous Driving Simulation Technology
1.4 Composition of Autonomous Driving Simulation Software
1.5 International Autonomous Driving Simulation Standardization Organization
1.5.1 Introduction to ASAM
1.5.2 Dynamic of ASAM
1.5.3 C-ASAM Working Group
1.5.4 Standards and Roadmap of ASAM
1.5.5 ASAM's OpenX Series Standards
1.5.6 ASAM's New Standards for Advanced Autonomous Driving
1.6 Status Quo of China's Autonomous Driving Simulation Test Standards
1.6.1 National Autonomous Driving Road Test Standards
1.6.2 Provincial and Municipal Autonomous Driving Road Test Standards
1.7 Status Quo of China's Participation in the Development of International Standards for Autonomous Driving Test Scenarios
1.8 Autonomous Driving Simulation Layout of OEMs

2. Autonomous Driving Simulation Platforms and Companies
2.1 Typical Components of Integrated Simulation Platform
2.2 Overview of Simulation Software System
2.3 Comparison of Key Foreign Companies
2.4 Comparison of Key Domestic Enterprises
2.5 ANSYS
2.5.1 Profile
2.5.2 Product Distribution
2.5.3 Simulation Capabilities Enhanced by Investment and Acquisition
2.5.4 Investment and Acquisition
2.5.5 Autonomous Driving Simulation Tool Chain
2.5.6 ANSYS SCADE
2.5.7 ANSYS SCADE Suite
2.5.8 ANSYS VRXPERIENCE
2.5.9 Update of ANSYS 2021 R1
2.5.10 Partners
2.5.11 Cooperation
2.5.12 Planning - 5G on Autonomous Vehicles
2.6 Siemens
2.6.1 Profile
2.6.2 Autonomous Vehicle Solutions
2.6.3 Expansion in ADAS and Autonomous Driving Simulation - Acquisition of Tass
2.6.4 PreScan
2.6.5 Sensor Model of Prescan
2.6.6 Sensor Types and Some Scenarios Supported by PreScan
2.6.7 PreScan Autonomous Driving Simulation and Detailed Functions
2.6.8 Update of PreScan in 2020
2.6.9 PreScan Autonomous Driving Simulation and Detailed Functions-- Applications
2.6.10 PAVE360
2.6.11 Customers
2.6.12 Cooperation
2.7 NVIDIA
2.7.1 Profile
2.7.2 Simulation Solution: DRIVE Constellation
2.7.3 Drive Sim Software
2.7.4 Computing Module: DRIVE AGX Pegasus
2.7.5 NVIDIA DRIVE PX Pegasus AI Computing Platform
2.7.6 Cooperation
2.8 CARLA
2.8.1 Profile
2.8.2 Basic Structure
2.8.3 Product Features
2.8.4 Carla 0.9.11
2.8.5 Update in 2020
2.9 AVSimulation
2.9.1 Profile
2.9.2 Simulation Software: SCANeR
2.9.3 SCANeR studio 1.9
2.9.4 SCANeR studio 2021.1
2.9.5 Cooperation
2.10 LGSVL
2.10.1 Open-source Simulation Solution: LGSVL
2.10.2 LGSVL 2020.06
2.11 Panosim
2.11.1 Profile
2.11.2 Simulation Solution: PanoSim
2.12 AirSim
2.12.1 Open-source Simulation Solution: AirSim
2.12.2 Update of AirSim in 2020
2.13 51World
2.13.1 Profile
2.13.2 51Sim-One1.3
2.13.3 Update of 51Sim-One 2.0
2.13.4 Cooperation
2.14 Huawei
2.14.1 Profile
2.14.2 Autonomous Driving Simulation Platform: Octopus
2.14.3 Octopus -- Combination of cloud + AI + software and hardware + chips
2.14.4 Ascend 910 AI Chip
2.15 Baidu
2.15.1 Apollo Simulation Platform
2.15.2 Apollo Scenario Library
2.15.3 AADS
2.15.4 Cooperation
2.16 Tencent
2.16.1 Autonomous Driving Layout
2.16.2 TAD Sim Simulation Platform -- Comprehensive Combination of Game Technology and Autonomous Driving Simulation
2.16.3 TAD Sim Environment Simulation
2.16.4 TAD Sim Sensor Simulation
2.16.5 TAD Sim2.0
2.16.6 Autonomous Driving Simulation Derivation --- Urban Simulation Platform
2.16.7 Cooperation
2.17 Alibaba
2.17.1 Autonomous Driving Layout
2.17.2 AutoDrive Platform
2.17.3 Hybrid Simulation Test Platform
2.18 BATH Simulation Business Comparison
2.19 China Automotive Technology & Research Center (CATARC)
2.19.1 Profile
2.19.2 Driving Scenario Simulation Platform
2.19.3 Autonomous Driving Simulation Cloud Platform: AD Chauffeur2.0
2.20 China Automotive Engineering Research Institute Co., Ltd. (CAERI)
2.20.1 Profile
2.20.2 Integrated Solutions of Scenario Library and Simulation system
2.20.3 Virtual Simulation Scenario Library: i-Scenario
2.20.4 i-VISTA Typical Driving Scenario Library in China
2.20.5 Self-developed Software Toolchain --- Smart Driving Scenario Generate Software, Smart Driving Test and Evaluation Software
2.20.6 i-STAR Data Processing Cloud Platform
2.20.7 Data Collection: i-Collector
2.20.8 Cooperation
2.21 Saimo
2.21.1 Profile
2.21.2 Simulation Test Platform Construction

3. Vehicle Dynamics Simulation
3.1 Vehicle Dynamics Simulation
3.2 Vehicle Dynamics Enterprises
3.3 IPG Carmaker
3.3.1 IPG Automotive
3.3.2 CarMaker
3.3.3 Application of CarMaker in ADAS Development
3.3.4 Customers of CarMaker
3.3.5 CarMaker 9.0
3.3.6 Cooperation
3.4 Carsim
3.4.1 Kinetics Simulation Software: CarSim
3.4.2 Update of CarSim
3.5 AVL
3.5.1 Profile
3.5.2 AVL CRUISE
3.5.3 AVL Smart ADAS Analyzer
3.5.4 Cooperation
3.6 Simpack
3.6.1 Products
3.6.2 Automotive Application
3.6.3 Update of SIMPACK 2021X
3.7 TESIS DYNAware
3.7.1 TESIS and Products
3.7.2 TESIS DYNAware
3.7.3 Application Scenarios of DYNA4
3.7.4 Update of DYNA4 4.0
3.8 MATLAB/Simulink
3.8.1 Products
3.8.2 Automotive Solutions
3.8.3 Vehicle Dynamics Blockset
3.8.4 Automated Driving Toolbox
3.9 VI-Grade
3.9.1 Profile
3.9.2 VI-CarRealTime
3.9.3 DiM DYNAMIC Simulator

4 Road and Weather Environments and Traffic Scene Simulation
4.1 Traffic Scene Simulation (Traffic Flow Simulation)
4.1.1 Overview
4.1.2 Classification
4.1.3 Companies
4.1.4 PTV-VISSIM
4.1.4.1 Profile and Main Products
4.1.4.2 Simulation Solution: VISSIM
4.1.4.3 VISSIM Platooning Model
4.1.4.4 VISSIM Product Updates
4.1.4.5 Application of VISSIM in Autonomous Driving
4.1.5 CorSim
4.1.5.1 Overview of Products
4.1.5.2 Version Updates
4.1.6 PARAMICS
4.1.6.1 Profile
4.1.6.2 Features
4.1.6.3 Version Updates
4.1.7 Transmodeler
4.1.7.1 Profile
4.1.7.2 Main Features
4.1.7.3 Historical Versions
4.1.7.4 Version Updates
4.1.7.5 Lane-level Networks
4.1.8 AIMSUN
4.1.8.1 Profile
4.1.8.2 Aimsun Next
4.1.8.3 Aimsun Next: Features
4.1.8.4 Aimsun Next: Version Updates
4.1.8.5 Aimsun Next: Functional Module Configurations in New Versions
4.1.9 SUMO
4.1.9.1 Profile
4.1.9.2 Functional Modules
4.1.9.3 Features
4.1.9.4 Version Updates
4.2 Construction of Virtual Scenes (Weather, Roads, Traffic, etc.)
4.2.1 Overview
4.2.2 Road Environment Simulation & Weather Environment Simulation
4.2.3 Overview of Virtual Scene Construction Companies
4.2.4 ESI Pro-SiVIC
4.2.4.1 Profile of ESI
4.2.4.2 Acquisitions and Integrations of ESI
4.2.4.3 Product Distribution of ESI Group
4.2.4.4 Profile of Pro-SiVIC
4.2.4.5 Application of Pro-SiVIC
4.2.4.6 Operation Process and Element Library of Pro-SiVIC
4.2.4.7 Historical Versions
4.2.4.8 Version Updates
4.2.5 rFpro
4.2.5.1 Profile
4.2.5.2 ADAS & Autonomous Solutions
4.2.5.3 Autonomous Driving Testing in VR and Introduction of Map Models
4.2.5.4 Digital Road Model
4.2.5.5 Virtual Environment Cooperated with NVIDIA
4.2.5.6 Partners
4.2.6 Cognata
4.2.6.1 Profile
4.2.6.2 Simulation Platform
4.2.6.3 Large-scale Scene Generation
4.2.6.4 Dynamics in Cooperation
4.2.7 Parallel Domain
4.2.7.1 Profile
4.2.7.2 Simulation Platform
4.2.7.3 Series A Funding Round
4.2.8 AAI
4.2.8.1 Profile
4.2.8.2 Main Products & Solutions
4.2.8.3 Application
4.2.8.4 Replicar
4.2.8.5 Scene Cloning and Extraction
4.2.8.6 Sensor Simulation
4.2.8.7 Dynamics in Cooperation
4.2.9 Applied Intuition
4.2.9.1 Profile
4.2.9.2 Simulation Platform
4.2.9.3 Application Cases
4.2.9.4 Toyota & Applied Intuition
4.2.9.5 Recent Dynamics
4.2.10 Ansible Motion
4.2.10.1 Profile
4.2.10.2 Solutions
4.2.10.3 Solutions for Passenger Cars
4.2.11 UNITY
4.2.11.1 Profile
4.2.11.2 Unity SimViz
4.2.11.3 AirSim on Unity
4.2.12 VectorZero-RoadRunner
4.2.13 CityEngine
4.2.13.1 Profile
4.2.13.2 Version Updates
4.2.14 VTD
4.2.14.1 MSC Software
4.2.14.2 Profile of VTD
4.2.14.3 VTD Components
4.2.14.4 VTD Application
4.2.14.5 OpenDRIVE Scene Editor
5 Sensor Simulation
5.1 Overview
5.2 Examples
5.3 Companies
5.4 MonoDrive
5.4.1 Profile
5.4.2 Sensor Simulator
5.4.3 Simulator Performance
5.4.4 Test Mode
5.4.5 Product Workflow
5.4.6 Camera Simulator
5.5 RightHook
5.5.1 Profile
5.5.1 Overview of Simulation
5.5.2 Supported Sensors
5.5.3 Simulation Workflow
5.5.4 Solutions
5.6 Metamoto
5.6.1 Profile
5.6.2 Simulation Platform
5.6.3 Cooperation Events
5.6.4 Acquired
5.7 OTSL
5.7.1 Profile
5.7.2 COSMOSIM
5.7.3 Cooperation Events
6 Simulation Interface and HIL
6.1 Overview of Simulation System Interface
6.2 Classification of Simulation System Interface
6.3 Overview of Hardware-in-the-Loop (HIL) Simulation
6.4 HIL Simulation Companies
6.5 National Instruments (NI)
6.5.1 Profile
6.5.2 Software-connected Solutions
6.5.3 Simulation Revenue, 2023E
6.5.4 Industry Application
6.5.5 Vehicle Radar Test System (VRTS)
6.5.6 Modular Test Platform
6.5.7 Camera and V2X HIL Test
6.5.8 ADAS Sensor Integrated with HIL Test Solution
6.5.9 Powertrain HIL Test Solution
6.6 ETAS
6.6.1 Profile
6.6.2 Testing and Verification Services-LABCAR
6.6.3 Testing and verification services-COSYM Co-simulation Platform
6.7 Vector
6.7.1 Profile
6.7.2 Closed-loop Test System
6.7.3 HIL Application Cases
6.7.4 VT System
6.8 dSPACE
6.8.1 Profile
6.8.2 Solution Combinations
6.8.3 Real-time Simulation System Solutions
6.8.4 Sensor Simulation
6.8.5 ASM Used in ADAS and Automated Driving (AD)
6.8.6 Sensor Model
6.8.7 Sensor Model Integration Examples
6.8.8 Cloud Solutions
6.8.9 Dynamics in Cooperation
6.8.10 Partners
6.8.11 Dynamics
7 Trends and Forecast

Companies Mentioned

  • 51World
  • AAI
  • AIMSUN
  • AirSim
  • Alibaba
  • Ansible Motion
  • ANSYS
  • Applied Intuition
  • AVL
  • AVSimulation
  • Baidu
  • CARLA
  • Carsim
  • China Automotive Engineering Research Institute Co., Ltd. (CAERI)
  • China Automotive Technology & Research Center (CATARC) 
  • CityEngine
  • Cognata
  • CorSim
  • dSPACE
  • ESI Pro-SiVIC
  • ETAS
  • Huawei
  • IPG Carmaker
  • LGSVL
  • MATLAB/Simulink
  • Metamoto
  • MonoDrive
  • National Instruments (NI)
  • NVIDIA
  • OTSL
  • Panosim
  • Parallel Domain
  • PARAMICS
  • PTV-VISSIM
  • rFpro
  • RightHook
  • Saimo
  • Siemens
  • Simpack
  • SUMO
  • Tencent
  • TESIS DYNAware
  • Transmodeler
  • UNITY
  • Vector
  • VectorZero-RoadRunner
  • VI-Grade
  • VTD

Methodology

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