Autonomous Driving and Cockpit Domain Control Unit (DCU) Industry Report, 2022(II)

Table of Content

2 Evolution of Domain Controller Software and Hardware Architectures and Business Models
2.1 Domain Controller Hardware Design
2.1.1 Domain Controller Hardware Architecture
2.1.2 Hardware Architecture Upgrade: ECU Hardware Architecture Upgrade
2.1.3 Communication Architecture Upgrade: Vehicle Backbone Network Evolves to Ethernet
2.1.4 Power Architecture Upgrade: The Power Topology Is Getting More Complex
2.1.5 Challenges in Domain Controller Hardware Design: Power Integrity (PI)
2.1.6 Challenges in Domain Controller Hardware Design: Signal Integrity (SI)
2.1.7 Challenges in Domain Controller Hardware Design: EMC
2.1.8 Challenges in Domain Controller Hardware Design: Power Consumption and Heat Dissipation
2.1.9 Challenges in Domain Controller Hardware Design: Designed Service Life
2.1.10 Challenges in Domain Controller Hardware Design: Testing and Verification
2.1.11 Challenges in Domain Controller Hardware Design: Higher Requirements for Process
2.2 Domain Controller Software Design
2.2.1 Domain Controller Software Architecture
2.2.2 Domain Controller Software Architecture Upgrade: Software Architecture Is Upgraded to Adaptive AutoSAR
2.2.3 "Full-stack Self-development" System Frameworks of OEMs and Tier 1 Suppliers (1)
2.2.4 "Full-stack Self-development" System Frameworks of OEMs and Tier 1 Suppliers (2)
2.2.5 "Full-stack Self-development" Cases of OEMs and Tier 1 Suppliers (1)
2.2.6 "Full-stack Self-development" Cases of OEMs and Tier 1 Suppliers (2)
2.3 Domain Controller Design and Production Models
2.3.1 Domain Controller Design and Production: Five Procurement Models (1)
2.3.2 Domain Controller Design and Production: Five Procurement Models (2)
2.3.3 Domain Controller Design and Production: Five Procurement Models (3)
2.3.4 Domain Controller Design and Production: Three Cooperative Development Models
2.3.5 Domain Controller Design and Production: Three Profit Sharing Models
2.4 Domain Controller ODM/OEM Production Model
2.4.1 Domain Controller ODM/OEM Production Model: Mode of Cooperation
2.4.2 Domain Controller ODM/OEM Production Model: Core Players
2.4.3 Domain Controller ODM/OEM Production Model: Typical Cooperation Cases


4 Research on Intelligent Cockpit Domain Controller Technology and Market
4.1 Evolution of Intelligent Cockpit Domain
4.1.1 Development Trends of Intelligent Cockpit
4.1.2 Trend 1: Following EEA Trends, Cockpit Domain Evolves Towards Domain Fusion, Central Computing and Cloud Computing
4.1.3 Trend 2: Intelligent Cockpit Cross-Domain Fusion (1)
4.1.4 Trend 2: Intelligent Cockpit Cross-Domain Fusion (2)
4.1.5 Trend 3: in Hardware Architecture, Cockpit SoCs Evolve Towards High Computing Power, Scalability and Artificial Intelligence
4.1.6 Trend 4: in Hardware Architecture, Pluggable Hardware Interfaces Support Vehicle Head Unit Hardware System Upgrade
4.1.7 Trend 5: Software Architecture Will be SOA-based Vehicle-Cloud Integrated Platform Architecture
4.1.8 Trend 6: in Software Architecture, Cockpit Software Platforms Tend to Adopt Layered Design
4.2 Cockpit Domain Controller Software and Hardware Solutions of OEMs
4.2.1 Cockpit Domain Controller Software and Hardware Solutions of 34 OEMs (1)
4.2.2 Cockpit Domain Controller Software and Hardware Solutions of 34 OEMs (2)
4.2.3 Cockpit Domain Controller Software and Hardware Solutions of 34 OEMs (3)
4.3 Cockpit Domain Controller Solutions of Tier 1 Suppliers
4.3.1 Summary of Cockpit Domain Controller Solutions of 24 Tier 1 Suppliers (1)
4.3.2 Summary of Cockpit Domain Controller Solutions of 24 Tier 1 Suppliers (2)
4.3.3 Summary of Cockpit Domain Controller Solutions of 24 Tier 1 Suppliers (3)
4.3.4 Summary of Cockpit Domain Controller Solutions of 24 Tier 1 Suppliers (4)
4.4 Solutions of Cockpit Domain Controller Software Suppliers
4.4.1 Summary of Cockpit Domain Controller Software Solutions of 16 Suppliers (1)
4.4.2 Summary of Cockpit Domain Controller Software Solutions of 16 Suppliers (2)
4.4.3 Summary of Cockpit Domain Controller Software Solutions of 16 Suppliers (3)
4.5 Cockpit Domain Controller SoC Solutions
4.5.1 Development Trends of Intelligent Cockpit SoCs
4.5.2 Development Plans of Intelligent Cockpit SoC Vendors
4.5.3 Comparison of Performance Indicators between Intelligent Cockpit SoCs (1)
4.5.4 Comparison of Performance Indicators between Intelligent Cockpit SoCs (2)
4.5.5 Comparison of Performance Indicators between Intelligent Cockpit SoCs (3)
4.6 Cockpit Domain Controller Market Size
4.6.1 China’s Intelligent Cockpit Market Size
4.6.2 China’s Intelligent Cockpit Domain Controller Shipments (10,000 Units), 2021-2025E
4.6.3 Competitive Landscape of Intelligent Cockpit Domain Controller Market (Roles Three-Party Players Pursue)


6 Chinese Domain Controller Manufacturers
6.1 Huawei
6.1.1 CC Architecture
6.1.2 Based on the CC Architecture, Launched Three Domain Controller Computing Platforms: MDC+CDC+VDC
6.1.3 CDC Intelligent Cockpit Computing Platform
6.1.4 HarmonyOS Intelligent Cockpit Platform and Pluggable Head Unit Modules
6.1.5 Kirin 990A Automotive Cockpit Chip
6.1.6 Harmony Cockpit HOS-A Software Platform (1)
6.1.7 Harmony Cockpit HOS-A Software Platform (2)
6.1.8 Intelligent Cockpit Domain Controller Platform: Some Mass Production Cases (1)
6.1.9 Intelligent Cockpit Domain Controller Platform: Some Mass Production Cases (2)
6.1.10 MDC Autonomous Driving Computing Platform: Product Portfolios
6.1.11 MDC Autonomous Driving Computing Platform: Technical Features
6.1.12 MDC Autonomous Driving Computing Platform: Software and Hardware Architecture
6.1.13 ADS Full-Stack Solution for Advanced Autonomous Driving
6.1.14 MDC Autonomous Driving Computing Platform: Technical Features
6.1.15MDC Autonomous Driving Computing Platform: Application Fields
6.1.16 MDC Autonomous Driving Computing Platform: MDC810
6.1.17 MDC Autonomous Driving Computing Platform: Parameters of MDC 210 and MDC 610
6.1.18 MDC Autonomous Driving Computing Platform: Platform Framework
6.1.19 MDC Autonomous Driving Computing Platform: Hardware Platform
6.1.20 MDC Autonomous Driving Computing Platform: Software Architecture
6.1.21 MDC Autonomous Driving Computing Platform: Software and Toolchain (1)
6.1.22 MDC Autonomous Driving Computing Platform: Software and Toolchain (2)
6.1.23 MDC Autonomous Driving Computing Platform: Software and Toolchain (3)
6.1.24 MDC Autonomous Driving Computing Platform: Software and Toolchain (4)
6.1.25 MDC Autonomous Driving Computing Platform: Automotive Security Platform
6.1.26 MDC Autonomous Driving Computing Platform: ISO26262 and ASPICE Certifications
6.1.27 MDC Computing Platform: Customers and Partners
6.1.28 MDC Computing Platform: Some Mass Production Cases
6.2 PATEO CONNECT+
6.2.1 Profile
6.2.2 Business Product Lines
6.2.3 Production and R&D Layout
6.2.4 Cockpit Products and Development History
6.2.5 Cockpit Platform Technology Evolution Direction
6.2.6 Intelligent Cockpit Domain Controllers: Product Lines
6.2.7 Intelligent Cockpit Domain Controllers: Qinggan 8155 Intelligent Cockpit Platform
6.2.8 Intelligent Cockpit Domain Controller Application Cases: Voyah FREE (1)
6.2.9 Intelligent Cockpit Domain Controller Application Cases: Voyah FREE (2)
6.2.10 Intelligent Cockpit Domain Controller Application Cases: Voyah Dreamer (1)
6.2.11 Intelligent Cockpit Domain Controller Application Cases: Voyah Dreamer (2)
6.2.12 Intelligent Cockpit Domain Controller Application Cases: NETA U Pro
6.2.13 Intelligent Cockpit Domain Controller Application Cases: BEIJING-X7
6.2.14 Intelligent Cockpit Platform: Layout of Forward-looking Technologies
6.3 Neusoft Reach
6.3.1 Autonomous Driving Domain Controllers: Product Lines (1)
6.3.2 Autonomous Driving Domain Controllers: Product Lines (2)
6.3.3 New-Generation Autonomous Driving Central Computing Platform: Equipped with Journey?5 Chip
6.3.4 Autonomous Driving Domain Controllers: X-BOX 3.0
6.3.5 Autonomous Driving Domain Controllers: Driving and Parking Integrated Domain Controller for Autonomous Driving
6.3.6 Autonomous Driving Domain Controllers: ADAS Domain Controller M-box
6.3.7 Commercial Vehicle ADAS Domain Controllers
6.3.8 General Domain Controllers: Platform Features
6.3.9 General Domain Controllers: Performance Characteristics and Application Areas
6.3.10 Domain Controller Software: Software Middleware and Ecological Software Package
6.3.11 Domain Controller Software: Adopting Open SOA
6.3.12 Domain Controller Software: NeuSAR DS Domain Controller Software Development Platform
6.3.13 Domain Controller Software: What NeuSAR DS Can Bring to OEMs?
6.3.14 Domain Controller Software: Technical Advantages of NeuSAR DS
6.3.15 NeuSAR: Next-Generation Automotive "Operating System" - NeuSAR Automotive Basic Software Platform
6.3.16 Basic Software: Software Architecture for SDV (Software Defined Vehicle)
6.3.17 Basic Software: SDV-oriented Series Solutions
6.3.18 Basic Software: NeuSAR System Architecture
6.3.19 Basic Software: NeuSAR Acquired ASIL-D Functional Safety Certificate
6.4 Desay SV
6.4.1 Latest Developments in the Three Major Businesses in 2021 (1)
6.4.2 Latest Developments in the Three Major Businesses in 2021 (2)
6.4.3 Intelligent Cockpit Domain Controllers: Product Development Planning
6.4.4 Third-Generation Intelligent Cockpit Domain Controllers
6.4.5 Third-Generation Cockpit Domain Controller Application Cases: Li ONE
6.4.6 Third-Generation Cockpit Domain Controller Application Cases: Tiggo 8 PLUS
6.4.7 Desay SV Cooperated with Huawei on HUAWEI HiCar Intelligent Connectivity Solution
6.4.8 Desay SV’s Intelligent Cockpit Domain Controller Project Passed ASPICE CL2 Evaluation
6.4.9 IPU Autonomous Driving Domain Controllers: Product Development Planning
6.4.10 IPU Autonomous Driving Domain Controllers: Revenue Expectation
6.4.11 IPU Autonomous Driving Domain Controllers: Software and Hardware Architecture and Division of Labor Logic
6.4.12 IPU Autonomous Driving Domain Controllers: Technology Roadmap
6.4.13 IPU Autonomous Driving Domain Controllers: Product Comparison (1)
6.4.14 IPU Autonomous Driving Domain Controllers: Product Comparison (2)
6.4.15 IPU Autonomous Driving Domain Controllers: Ecosystem Building
6.4.16 Cross-Domain Fusion Intelligent Computing Platform (ICP): "Aurora"
6.4.17 "Aurora" Domain Fusion Central Computing Platform: Performance Characteristics
6.4.18 "Aurora" Domain Fusion Central Computing Platform: Design Scheme (1)
6.4.19 "Aurora" Domain Fusion Central Computing Platform: Design Scheme (2)
6.4.20 IPU04 Autonomous Driving Domain Controller: Hardware Architecture
6.4.21 IPU04 Autonomous Driving Domain Controller: Software Architecture
6.4.22 IPU03 Domain Controller: Forged Strategic Partnerships with Xpeng Motors and NVIDIA
6.4.23 IPU02 Driving and Parking Integrated Controller: Using TI Jacinto 7 TDA4 SoC
6.4.24 Desay SV Bought in Momenta and MAXIEYE to Improve Its Intelligent Driving Strategy
6.5 ADAYO
6.5.1 Intelligent Cockpit Layout: Four Elements
6.5.2 Cockpit Domain Controllers: Highlights of the Fourth-Generation Products
6.5.3 Cockpit Domain Controllers: Developed Based on ADAYO AAOP 2.0
6.5.4 Cockpit Domain Controllers: Three Solutions
6.6 Haomo AI
6.6.1 Profile
6.6.2 Three Core Product Lines
6.6.3 "Little Magic Box" Intelligent Driving Domain Controller: Product Development Planning
6.6.4 Autonomous Driving Domain Controller: "Little Magic Box 3.0" (IDC 3.0)
6.6.5 Hpilot Autonomous Driving Product Roadmap
6.6.6 Hpilot Autonomous Driving Solutions: Products and Partners
6.6.7 Collecting Data via the "Little Magic Box" for Intelligent Training
6.6.8 Haomo AI Will Become One of the Largest Autonomous Driving Solution Suppliers in China
6.6.9 Data Intelligence System Product: MANA (Snow Lake)
6.6.10 "Data Intelligence System MANA" (1)
6.6.11 "Data Intelligence System MANA" (2)
6.6.12 Haomo AI Uses the Fundamental Model to Automatically Diagnose the Domain Model
6.6.13 New Technologies: Transformer-based Visual Recognition Technology
6.6.14 New Technologies: Cognitive Security Model CSS
6.6.15 Customers and Partners
6.7 Nobo Automotive Technology
6.7.1 Intelligent Cockpit Service Positioning
6.7.2 Three-Step Development Strategy
6.7.3 Business Divisions and Product Lines
6.7.4 Layout of R&D and Production Centers
6.7.5 Cockpit Domain Controllers: Product Lines (1)
6.7.6 Cockpit Domain Controllers: Product Lines (2)
6.7.7 Cockpit Domain Controllers: Product Development Roadmap (1)
6.7.8 Cockpit Domain Controllers: Product Development Roadmap (2)
6.7.9 IN9.0 Cockpit Domain Controller (Based on Qualcomm 8155)
6.7.10 IN9.0 Cockpit Domain Controller: Block Diagram
6.7.11 IN9.0 Cockpit Domain Controller: Technical Features
6.7.12 IN7.0 Cockpit Domain Controller (Based on Qualcomm 6155)
6.7.13 Cockpit Domain Controller Software Solutions
6.8 Freetech
6.8.1 Autonomous Driving Domain Controllers: Product Lines (1)
6.8.2 Autonomous Driving Domain Controllers: Product Lines (2)
6.8.3 Autonomous Driving Domain Controllers: Product Roadmap
6.8.4 Autonomous Driving Domain Controllers: ADC20 for Cost-Effective Driving and Parking Integrated Solutions (1)
6.8.5 Autonomous Driving Domain Controllers: ADC20 for Cost-Effective Driving and Parking Integrated Solutions (2)
6.8.6 Autonomous Driving Domain Controllers: ADC25 for Enhanced Parking and Parking Integrated Solutions
6.8.7 Autonomous Driving Domain Controllers: ADC30 for L3 Advanced Autonomous Driving Solutions (1)
6.8.8 Autonomous Driving Domain Controllers: ADC30 for L3 Advanced Autonomous Driving Solutions (2)
6.8.9 Autonomous Driving Domain Controllers: ADC30 for L3 Advanced Autonomous Driving Solutions (3)
6.8.10 Autonomous Driving Domain Controllers: Comparison between Product Lines
6.8.11 Autonomous Driving Product Roadmap
6.8.12 End-to-end Full-Stack Process Solutions
6.8.13 Advanced Autonomous Driving Solutions (1)
6.8.14 Advanced Autonomous Driving Solutions (2)
6.8.15 Advanced Autonomous Driving Solutions (3)
6.8.16 Advanced Autonomous Driving Solutions (4)
6.9 Technomous
6.9.1 Autonomous Driving Domain Controllers: Product Portfolios (1)
6.9.2 Autonomous Driving Domain Controllers: Product Portfolios (2)
6.9.3 Intelligent Driving Domain Controller iECU1.5: Based on TI TDA4VM SoC
6.9.4 Intelligent Driving Domain Controller iECU1.5: Technical Features
6.9.5 Autonomous Driving Domain Controllers: MotionWise Software Platform
6.9.6 Autonomous Driving Domain Controllers: Software Platform Solutions
6.9.7 Autonomous Driving Domain Controllers: Typical Customer Applications
6.10 iMotion
6.10.1 Profile
6.10.2 Autonomous Driving Domain Controllers: Customers
6.10.3 iMotion Introduced "End-To-End" Integrated Solutions and Domain Controller Products
6.10.4 Driving and Parking Integrated Domain Controllers: IDC MID and IDC HIGH
6.10.5 Driving and Parking Integrated Solutions: Hardware Configuration and Functional Highlights
6.10.6 iMotion Big Data Closed-Loop System Facilitates the Implementation of All Scenarios
6.11 Hong Jing Drive
6.11.1 Profile
6.11.2 Autonomous Driving Domain: L4-oriented, Application Dimensionality Reduced to L2, L2+ and L3 Products
6.11.3 Autonomous Driving Domain Controllers: Product Line Layout (1)
6.11.4 Autonomous Driving Domain Controllers: Product Line Layout (2)
6.11.5 Autonomous Driving Domain Controllers: Product Lines
6.11.6 Autonomous Driving Domain Controllers: IPM Smart Camera Module and APA/IDDC Domain Controller
6.11.7 Autonomous Driving Domain Controllers: High-Level Autonomous Driving Control Unit (ADCU)
6.11.8 "Gemini" Computing Platform and Autonomous Driving Full-Stack Technology Capabilities
6.11.9 Autonomous Driving System Architecture
6.11.10 The L3 Heavy Truck Jointly Developed by Hong Jing Drive and JAC Will Be Mass-Produced in H1 2022
6.11.11 Hong Jing Drive Provided Domain Controllers and Intelligent Driving Engineering Services for Li ONE
6.11.12 Domain Controller Capacity: Building A Smart Factory
6.12 Unlimited AI
6.12.1 Profile
6.12.2 Intelligent Driving Domain Controllers: Mode of Cooperation
6.12.3 Intelligent Driving Domain Controllers: Product Lines
6.12.4 Software-Defined ADAS All-in-One
6.12.5 L2.99 Multifunctional Intelligent Driving Domain Controller: "Wukong No.1"
6.12.6 L2.99 Intelligent Driving Domain Controller: Mass-Produced and Mounted on Chery Big Ant
6.12.7 L2.99 Intelligent Driving Domain Controller: Technical Advantages
6.12.8 L2.99 Intelligent Driving Domain Controller: Hardware Architecture
6.12.9 L2.99 Intelligent Driving Domain Controller: Specifications and Interface Capabilities
6.12.10 Dual J3+X9H High Performance Multi-Domain Controller
6.12.11 Dual J3 Intelligent Driving Domain Controller
6.12.12 Vehicle Central Computer (HPC)
6.13 In-Driving
6.13.1 Profile
6.13.2 Business Model and Core Businesses
6.13.3 Autonomous Driving Domain Controller Iteration and Cost Reduction Path
6.13.4 Autonomous Driving Domain Controllers: Product Line Layout (1)
6.13.5 Autonomous Driving Domain Controllers: Product Line Layout (2)
6.13.6 Fifth-Generation Domain Controller: TITAN5
6.13.7 Autonomous Driving Domain Controller: TITAN 4
6.13.8 Autonomous Driving Domain Controller: TITAN 3
6.13.9 Autonomous Driving Domain Controllers: Technical Parameters and Architecture of TITAN 3
6.13.10 Autonomous Driving Domain Controllers: System Framework of TITAN 3
6.13.11 Autonomous Driving Domain Controllers: Performance Parameters of TITAN 3
6.13.12 Autonomous Driving Software Platform: Athena
6.13.13 TITAN and PALLAS: Verified in a Real Vehicle with a Full Visual Perception Solution
6.13.14 TITAN and PALLAS: Verified in a Real Vehicle with a Full Visual Perception Solution
6.13.15 In-Driving Cooperated with Huawei: Jointly Released a Minibus Solution with Huawei MDC
6.14 Yihang.AI
6.14.1 Autonomous Driving Mass Production Path
6.14.2 NOA Driving and Parking Integrated Solution (1)
6.14.3 NOA Driving and Parking Integrated Solution (2)
6.14.4 All-Scenario Full Self-Driving (FSD) Solution
6.15 Baidu
6.15.1 Autonomous Driving Domain Controllers: Roadmap
6.15.2 Autonomous Driving Domain Controllers: Product Layout
6.15.3 Technical Features of Autonomous Driving Computing Platform 1.0 (Wuren)/2.0 (Sixi)/3.0 (Sanxian)
6.15.4 Autonomous Driving Computing Platform: Cooperated with NVIDIA on Use of DRIVE Orin Chip in “Sanxian” Domain Controller
6.15.5 Autonomous Driving Computing Platform ACU (Sixi)
6.15.6 Autonomous Driving Computing Platform ACU (Sixi) Uses TI TDA4 Processor
6.15.7 Apollo Focuses on Promoting ANP+AVP Global Intelligent Driving System
6.15.8 Apollo 6.0 Autonomous Driving Solution
6.15.9 Apollo’s Fifth-Generation Robotaxi Model - Apollo Moon
6.15.10 Apollo Autonomous Driving Scenario Was Implemented
6.15.11 Intelligent Cockpit: Apollo Internet of Vehicles
6.16 Jingwei Hirain
6.16.1 Profile
6.16.2 Autonomous Driving Domain Controllers: Product Line Layout
6.16.3 Intelligent Driving Domain Controller (ADCU) and Vehicle High Performance Computing Platform (HPC)
6.16.4 ADAS Domain Controllers
6.16.5 ADAS Domain Controllers: Performance Characteristics
6.17 Joynext
6.17.1 Cockpit Domain Controllers: Business
6.17.2 Cockpit Domain Controllers: Software Architecture (1)
6.17.3 Cockpit Domain Controllers: Software Architecture (2)
6.17.4 Intelligent Cockpit Evolution Route
6.17.5 Human-Machine Copilot System: Intelligent Cockpit HMI for High-Level Autonomous Driving
6.17.6 Cockpit and Autonomous Driving Domain Controllers: Development Progress
6.18 Hangsheng Electronics
6.18.1 Product Layout
6.18.2 Intelligent Cockpit Ecosystem
6.18.3 Intelligent Cockpit Rapid Iteration Capability
6.18.4 New-Generation Cockpit Domain Controllers Based on Qualcomm 8155
6.18.5 Cockpit Domain Controllers: Product Planning
6.19 BICV
6.19.1 Profile
6.19.2 Business Layout of Parent Company BDStar Navigation
6.19.3 Intelligent Cockpit Domain Controllers
6.19.4 Visual Controller (CVBOX)
6.20 UAES
6.20.1 XE and UAES Software Platform (USP) of Cross-Domain Control Business Division
6.20.2 Vehicle Computing Platform (VCP)
6.20.3 Zone Controllers
6.20.4 Scalable Domain Controller Platform: XCU 8.0
6.20.5 AUTOSAR-based Open Software Platform
6.20.6 SOA Application under New EEA (1)
6.20.7 SOA Application under New EEA (2)
6.20.8 SOA Software and Conventional Embedded Software
6.20.9 Vehicle Computing Platform Software Architecture and USP Software Platform
6.21 Youkong Zhixing
6.21.1 Profile
6.21.2 Domain Controllers: Planned Business Directions
6.21.3 Autonomous Driving Domain Controllers: Hardware Platform (1)
6.21.4 Autonomous Driving Domain Controllers: Hardware Platform (2)
6.21.5 Autonomous Driving Domain Controllers: Software Platform Architecture
6.21.6 Autonomous Driving Domain Controllers: Implementation of Software Functions
6.21.7 Autonomous Driving Domain Controllers: Technical Highlights or Differentiation
6.21.8 Autonomous Driving Domain Controllers: Product Development Planning
6.21.9 Autonomous Driving Domain Controllers: Performance Parameters of EAXVA04 / EAXVA05
6.21.10 Autonomous Driving Domain Controllers: Performance Parameters of EAXVA03
6.21.11 Autonomous Driving Domain Controllers: Cooperative Customers
6.21.12 Autonomous Driving Domain Controller Application Cases: Meituan Autonomous Delivery Vehicle
6.21.13 Autonomous Driving Domain Controller Application Cases: Yutong L4 Autonomous Bus
6.21.14 Youkong Zhixing and Black Sesame Technologies Developed an Intelligent Driving Computing Platform
6.22 Idriverplus
6.22.1 Three Core Business Lines
6.22.2 Autonomous Driving Brains: AVDC+AVOS+BBOX (1)
6.22.3 Autonomous Driving Brains: AVDC+AVOS+BBOX (2)
6.22.4 Autonomous Driving Brains: Application Cases
6.22.5 Autonomous Driving Brains: AVOS and AVCU
6.22.6 Autonomous Driving Brains: AVOS Software System Architecture
6.23 DJI Automotive
6.23.1 Profile
6.23.2 Three Major Solutions for Intelligent Driving
6.23.3 Autonomous Driving Domain Controllers: Features
6.23.4 Autonomous Driving Domain Controllers: Middleware
6.23.5 Autonomous Driving Domain Controllers: Mass-produced and Mounted on SAIC-GM-Wuling Baojun
6.24 EnjoyMove Technology
6.24.1 Profile and Products
6.24.2 Intelligent Domain Controller: DCU3.0
6.24.3 DCU3.0: Technical Features
6.24.4 DCU3.0: System Architecture Design
6.24.5 DCU3.0: Adopting L3 Functional Safety Design
6.24.6 DCU3.0: Driving and Parking Integrated System Architecture Design
6.24.7 High Performance Computing Software Platform: EMOS1.0
6.24.8 High Performance Computing Software Platform: Technical Features of EMOS1.0
6.24.9 High Performance Computing Software Platform: Multi-Domain Fusion Software Platform
6.24.10 Multi-Domain Fusion Computing Platform
6.24.11 Business Model
6.25 Novauto
6.25.1 Profile
6.25.2 Computing Platform for High-Level Advanced Autonomous Driving: NOVA30P
6.25.3 NOVA30P: Technical Architecture and Features
6.25.4 Automatic Compression Tool: NOVA-Slim
6.25.5 Training and Acceleration Tool: NOVA-3D
6.25.6 NOVA-Box Intelligent Driving Computing Platform
6.25.7 NOVA-Box Computing Platform Solutions (1)
6.25.8 NOVA-Box Computing Platform Solutions (2)
6.25.9 NOVA-Box Computing Platform Solutions (3)
6.25.10 Partners
6.26 Intron Technology
6.26.1 Intron Technology and Horizon Robotics Jointly Developed an Autonomous Driving Domain Controller
6.26.2 L3 and above Autonomous Driving Domain Controllers: System Architecture (1)
6.26.3 L3 and above Autonomous Driving Domain Controllers: System Architecture (2)
6.26.4 CAELUS Autonomous Driving Domain Controller Solution: Based on Xilinx MPSoC
6.27 Yuanfeng Technology
6.27.1 Profile
6.27.2 Mass-Produced Qualcomm 8155-based Intelligent Cockpit Domain Controller
6.28 AutoLink
6.28.1 Profile
6.28.2 Layout of Intelligent Cockpit Domain Controller Capacity
6.28.3 AutoLink and Bosch Jointly Developed a Cockpit Domain Controller