Automotive Intelligent Cockpit Platform Configuration Strategy and Industry Research Report, 2024
상품코드:1513555
리서치사:ResearchInChina
발행일:2024년 05월
페이지 정보:영문 550 Pages
라이선스 & 가격 (부가세 별도)
한글목차
진화의 추세와 기능에 따라 콕핏 플랫폼은 점차적으로 콕핏 전용, 콕핏 및 기타 도메인 통합, 콕핏 주차 통합, 콕핏 운전 주차 통합, 콕핏 운전 통합 중앙 운영 플랫폼과 같은 기술적 경로로 진화했습니다. OEM과 Tier 1 기업은 적극적으로 레이아웃을 진행하고 있습니다.
지능형 콕핏 플랫폼 솔루션 레이아웃 전략 : 유형별
(1) 콕핏 파킹 통합 : 중저 구성 모델의 제일 선택지, 2024년에 양산이 가속될 전망입니다.
콕핏 주차 통합은 주차 기능을 콕핏에 융합시켜 주차 컨트롤러의 하드웨어 비용을 절감합니다. 따라서 OEM은 사용자 경험과 비용 최적화의 관점에서 이 솔루션을 검토하고 있으며, 중저 구성 모델이 이 솔루션의 주요 시장이 되었습니다.
2024년 높은 컴퓨팅 능력을 갖춘 콕핏 SoC 제품과 멀티 카메라 하드웨어 지원으로 Bosch, Visteon, Desay SV, ADAYO, BICV, ECARX, Yuanfeng Technology 등 많은 주류 지능형 콕핏 솔루션 제공업체가 관련 콕핏 주차 통합 솔루션을 발표했습니다.
대부분의 콕핏 주차 통합 솔루션은 주로 단일 콕핏 SoC 칩을 기반으로 하며 지능형 콕핏 주차 기능을 제공합니다. Qualcomm 8255, Qualcomm 8295 등은 콕핏 주차 통합 솔루션의 주요 단일 SoC 칩으로 채택되었습니다. 이 칩 플랫폼을 기반으로 하는 제품은 시스템 연계를 강화하고, 시스템 성능을 향상시키고, 크로스 도메인 통합, 액티브 인텔리전스, 멀티모달 상호작용 등의 기능을 보다 충분히 추구하고 실현할 수 있습니다.
(2) 콕핏 운전 주차 통합 : L2 ADAS 기능을 캐빈에 통합하여 비용 절감 및 효율성 향상을위한 최적의 솔루션
콕핏 드라이빙 파킹 통합은 콕핏 기능 도메인과 드라이빙 기능, 주차 기능을 통합하는 것으로, 드라이빙 도메인은 현재 L2 미만의 운전 지원 기능을 통합하고 있습니다. 따라서 이 솔루션은 주로 L2 ADAS 기능을 갖춘 중저 구성 모델에 적합합니다. 높은 구성 모델이나 최고 구성 모델의 경우, 독립된 드라이빙 컨트롤 유닛을 탑재하는 것이 우선됩니다만, 이것은 연산 능력이나 기능 안전 레벨에 대한 요구가 높아, 콕핏에의 통합이 어려워집니다.
2024년 3월에 출시된 Leapmotor C10 모델은 최신 Four Leaf Clover 중앙 통합 EEA를 기반으로 합니다. 표준 및 중간 구성 버전에서는 하나의 SoC 칩(Qualcomm 8295/8155)과 하나의 MCU 칩(NXP S32G)을 사용하고 QNX Hypervisor를 기반으로 QNX, Android, Linux, RTOS 등 여러 시스템을 구동 콕핏 인텔리전트 드라이빙의 깊은 통합을 실현하고 L2 인텔리전트 드라이빙(ACC 등), 계기 클러스터, 인포테인먼트, 사운드 이펙트, 파워 앰프, 서라운드 뷰, 피로 모니터링, 차량 전체, 바디, 게이트웨이 등의 기능을 실현합니다.
(3) 콕핏 드라이빙 통합(중앙 연산 플랫폼) : 콕핏과 통합된 첨단 지능형 운전, One Box와 통합 차량 OS 플랫폼 실현, 2025년 상륙 예정
콕핏 드라이빙 통합은 One Box, One Board, One Chip(멀티 SoC의 칩 간 캐스케이드 포함)을 실현하는 중앙 연산 플랫폼이며, 그 중에서도 One Chip은 지능형 드라이빙 도메인과 인텔리전트 콕피트 도메인 모두를 1칩 위에서 실행되는 콕핏 운전 통합의 "궁극적인 솔루션"으로 널리 알려져 있습니다.
이 보고서는 중국 자동차 산업에 대한 조사 분석을 통해 지능형 콕핏 플랫폼 구성 전략 및 개발 정책, 주요 공급업체 솔루션, 국내외 시스템 통합사업자 등의 정보를 제공합니다.
목차
제1장 지능형 콕핏 플랫폼의 구성 전략 및 개발 정책 분석
요약(1)
요약(2)
자동차용 지능형 콕핏 플랫폼 개발 동향의 요약
주류 레이아웃용 콕핏 플랫폼과 아키텍처(2024년)
지능형 콕핏 플랫폼 개발 정책(1) : 콕핏 전용 플랫폼
지능형 콕핏 플랫폼 개발 정책(2) : 콕핏 및 주차 통합 솔루션의 레이아웃과 동향
지능형 콕핏 플랫폼 개발 정책(3) : 저중급 콕핏, 주행 및 주차 통합 솔루션 레이아웃 및 동향
지능형 콕핏 플랫폼 개발 정책(4) : 연결성 및 기타 기능 도메인을 통합한 콕핏 솔루션
지능형 콕핏 플랫폼 개발 정책(5) : 콕핏 및 운전 통합 중앙 연산 플랫폼
지능형 콕핏 플랫폼 시장 규모와 보급률의 동향 : 유형별
제2장 지능형 콕핏 플랫폼 공급업체 솔루션 및 경쟁력
요약(1)
요약(2)
요약(3)
요약(4)
중국 주요 공급업체의 지능형 콕핏 플랫폼 개발 레이아웃과 경쟁력
국외 주요 공급업체의 지능형 콕핏 플랫폼 개발 레이아웃과 경쟁력
최신 솔루션 및 주요 기능 : 주요 공급업체의 지능형 콕핏 플랫폼 솔루션 : 플랫폼 카테고리별
지능형 콕핏 플랫폼 개발 및 공급 방식의 진화
해외용 콕핏 플랫폼 레이아웃
지능형 콕핏 플랫폼의 현지화
제3장 지능형 콕핏 플랫폼을 지원하는 OEM 각사의 관계와 개발 동향
요약(1)
요약(2)
요약(3)
요약(4)
주요 OEM과의 관계를 지원하는 지능형 콕핏 플랫폼
OEM의 콕핏 플랫폼 레이아웃 계획
OEM의 지능형 콕핏 플랫폼 개발의 새로운 동향(1) : 콕핏에 응용되는 AI 기반 모델
OEM의 지능형 콕핏 플랫폼 개발의 새로운 동향(2) : 전화와 자동차 연결
4장 OEM의 지능형 콕핏 플랫폼 레이아웃
Tesla
Mercedes-Benz
BMW
Volkswagen
Audi
Volvo
Ford
Stellantis
BYD
Great Wall Motor
SAIC
GAC
Geely
FAW Hongqi
BAIC
Changan Automobile
Neta Auto
Li Auto
Xpeng Motor
Xiaomi Auto
Xiaomi Auto
Leapmotor
제5장 세계 지능형 콕핏 시스템 통합사업자
Harman
Visteon
FORVIA
Aptiv
Bosch
Continental
Denso
Marelli
제6장 중국 지능형 콕핏 시스템 통합사업자
PATEO CONNECT
Desay SV
Hangsheng Electronics
Joyson Electronics
Huawei
ThunderSoft
Navinfo
ArcherMind Technology
Kotei Information
BICV
ADAYO
ECARX
BJH
영문 목차
영문목차
According to the evolution trends and functions, the cockpit platform has gradually evolved into technical paths such as cockpit-only, cockpit integrated with other domains, cockpit-parking integration, cockpit-driving-parking integration, and cockpit-driving integrated central computing platform. OEMs and Tier1s are actively laying out.
Layout strategy of intelligent cockpit platform solution (by type)
(1) Cockpit-parking integration: the first choice for mid- to low-configured models, mass production is expected to accelerate in 2024
Cockpit-parking integration fuses parking functions into the cockpit, saving hardware costs for parking controllers. Therefore, OEMs consider it from the perspective of user experience and cost optimization, and mid- to low-configured models are the main market for this solution.
In 2024, with the support of high-computing power cockpit SoC products and multi-camera hardware, many mainstream intelligent cockpit solution providers such as Bosch, Visteon, Desay SV, ADAYO, BICV, ECARX, and Yuanfeng Technology have launched relevant cockpit-parking integration solutions.
Most cockpit-parking integration solutions are mainly based on a single cockpit SoC chip to realize intelligent cockpit and parking functions. Qualcomm 8255, Qualcomm 8295, etc. have become the preferred chips for cockpit-parking integration's main single SoC solutions. Products based on this chip platform can enhance system collaboration, improve system performance, and more fully explore and realize cross-domain integration, active intelligence, multimodal interaction, and other functions.
(2) Cockpit-driving-parking integration: the optimal solution for cost reduction and efficiency improvement, with L2 ADAS functions integrated in the cabin
Cockpit-driving-parking integration integrates the cockpit functional domain with driving and parking functions, while driving domain currently integrates assisted driving functions at L2 and below. Therefore, this solution is mainly suitable for mid- to low-configured models equipped with L2 ADAS functions. High- or top-configured models will still give priority to being equipped with independent driving control units, which have higher requirements for computing power and functional safety levels, and are more difficult to integrate into the cockpit.
Leapmotor C10 model, launched in March 2024, is based on the latest "Four Leaf Clover" central integrated EEA. In standard- and mid-configured versions, it uses one SoC chip (Qualcomm 8295/8155) and one MCU chip (NXP S32G), based on QNX Hypervisor to drive multiple systems such as QNX, Android, Linux, and RTOS, achieving deep integration of cockpit and intelligent driving, and realizing L2 intelligent driving (e.g. ACC), instrument cluster, infotainment, sound effects, power amplifier, surround view, fatigue monitoring, whole vehicle, body, gateway, and other functions.
(3) Cockpit-driving integration (central computing platform): Advanced intelligent driving integrated with cockpit, realizing One Box + unified vehicle OS platform, expected to be landed in 2025
Cockpit-driving integration is a central computing platform dedicated to achieving One Box, One Board, One Chip (including multi-SoC inter-chip cascading), among which One Chip is widely regarded as the "ultimate solution" for cockpit-driving integration, which runs both intelligent driving domain and intelligent cockpit domain on a single chip.
Currently, multiple suppliers or OEMs have announced the next-generation single-chip cockpit-driving integration layout, but there are slight differences.
Among them, mainstream cockpit Tier1 suppliers such as Bosch, Autolink, ThunderX Auto, Hangsheng Electronics, ADAYO, Zhuoyu Technology, BICV, and Megatronix have announced the creation of cockpit-driving integration solutions based on Qualcomm Snapdragon Ride(TM) Flex 8775. Some suppliers have even implemented a product layout that integrates software and hardware with cockpit-driving integration, aiming at OEMs' demands for cost reduction on intelligence.
ThunderX Auto, a subsidiary of ThunderSoft, created RazorDCX Tarkine, a single-SoC cockpit-driving integration solution based on Qualcomm Snapdragon Ride(TM) Flex SoC. Equipped with ThunderSoft's Dishui OS cockpit-driving integration system, it supports a through-type 8K long screen, displays a full-scenario, immersive, and full 3D interface, and can realize 360° surround view, driver monitoring, game audio & video entertainment, interconnection and other cockpit functions. Meanwhile, it can also support automatic parking, L2++ intelligent driving functions for highways and urban areas, planned to achieve mass production from 2024 to 2025.
In 2024, companies such as Desay SV, Xpeng Motor, Li Auto, ZEEKR, Jiyue, BYD, and Xiaomi announced that they will create cockpit-driving integration products based on NVIDIA Thor, which can provide "cockpit-driving integration" technical solutions for high-level autonomous driving above L4, and through systematic integration, the software and hardware are fully integrated, shortening the development cycle, significantly reducing costs and improving efficiency.
At GTC 2024, Nvidia announced that BYD will adopt Nvidia's next-generation intelligent vehicle chip Thor, which is expected to be used in the central brain of BYD's newly released Xuanji architecture to achieve a cockpit-driving integration layout, while also being compatible with deploying various AI models.
In addition, cockpit-driving integration solutions based on local chips from Black Sesame Technologies and SemiDrive Technology are also being laid out. In April 2024, NESINEXT cooperated with Black Sesame Technologies to release the CoreFusion, a cockpit-driving integration software open platform based on Black Sesame Technologies' automotive cross-domain computing chip Wudang C1296, providing developers with efficient operating system-level software base, development tool chain and complete ecology.
It can be seen that major suppliers and OEMs have accelerated the layout of single-chip cockpit-driving integration solutions, and are expected to achieve mass production as soon as 2025.
(4) High-end cockpit AI solution: running AI foundation model in the cabin to achieve 4K/8K HD display and 3D immersive high-performance experiences
As generative AI, 4K/8K HD display, 3D immersive experience, multimodal interaction, multi-scenario integration, etc. continue to be introduced into cars, the demand for higher computing power and high-performance cockpit platforms continues to grow, especially in the high-end car market, where market competition is becoming more intense.
Beginning in 2023, AI foundation models have become popular. Both emerging and conventional OEMs have introduced them into cockpits. AI foundation models to create future cockpits have become the current mainstream development trend.
However, current intelligent cockpit relies more on cloud AI in terms of computing power. Although it can run foundation models with more than 100 billion parameters, the car side currently only has 1 billion parameters or even less, and the performance level is still insufficient.
Considering that the cloud-side foundation model is subject to privacy security, latency, stability, cost and other issues, part of calculation and storage during the use of foundation model needs to be completed by vehicle-side computing resources, so the vehicle-side AI foundation model needs to be added. In the future intelligent cockpit, it is necessary to support an AI large language model with more than 7 billion parameters to achieve strong end-side intelligence. In addition, it will also have a full-time online foundation model in-car assistant, full-scenario multimodal interaction and other performance experiences, all of which place higher requirements on intelligent cockpit platform.
In 2024, many OEMs begin to introduce end-side foundation models into their cars. How to match capabilities of end-side foundation models will become one of the key development directions of new intelligent cockpit platforms in the future. Suppliers such as BICV, ECARX, and Shanghai Ruicheng have launched cockpit solution products with high AI performance.
In April 2024, BICV announced the creation of MARS06 cockpit solution product based on MediaTek 3nm chip MT8678, which can support end-side running of a 13 billion parameter AI large language model. It is outstanding in performance, multimedia, security technology facilities, audio and video processing capabilities, end-side AI foundation model, etc. And can meet the needs of intelligent vehicles for infotainment and intelligent driving assistance systems, and bring safer, more comfortable and smarter mobility experiences to occupants.
And CT-Y1 chip cockpit solution product based on MediaTek's 4nm sub-flagship chip supports a 7 billion parameter foundation model and can generate AI images within 1s. It also supports up to 12 cameras, up to 32MP, as well as multi-screen display and built-in 5G.
In March 2024, ECARX has released Qogir intelligent cockpit computing platform product, which uses flagship 4nm mobile phone chip Qualcomm Snapdragon 8 Gen3 and is equipped with Flyme Auto + WiFi 7 system. Its hybrid end-side AI reaches 60 TOPS, supports up to 10 billion parameter foundation model platform operation, supports up to 8K display, and hardware supports light tracing technology, providing the ultimate phone-car connectivity experience.
In addition, in 2024, high-performance cockpit platform products based on Qualcomm 8295 from Neusoft Group, Aptiv, Desay SV, Harman and other suppliers have been installed and achieved mass production on models from OEMs such as Jiyue, Geely Galaxy, ZEEKR, Li Auto, Xiaomi, Mercedes-Benz, etc. Its AI computing power reaches 30TOPS (the high-performance version reaches 60TOPS) and adopts a dual NPU architecture, which can effectively improve the speed and performance of foundation model calculations and help the efficient operation of end-side AI foundation models.
Furthermore, products based on cockpit-only platform solutions such as Samsung V920, Intel and Qualcomm consumer chips will also be mass-produced from 2024 to 2025, making market competition more intense.
Mainstream next-generation cockpit platform supplier layout: high computing power, focus on AI, flexible and customizable
Qualcomm 8255 cockpit platform solution: booming in 2024, may be the next-generation mainstream automotive solution
From the perspective of supplier layout, Qualcomm remains the main product in the market, mainly Qualcomm 8295 and Qualcomm 8255. Especially the Qualcomm 8255 product, highly recommended by Qualcomm, many OEMs who used to make 8295 intelligent cockpits have begun to access to 8255. However, performance of SA8255 is lower than that of SA8295, especially in terms of GPU performance. CPU performance is also slightly lower than SA8295. But in AI, SA8255 can reach up to 48TOPS, and the price is significantly lower than SA8295.
Beginning in 2024, many mainstream Tier 1 companies have launched their cockpit platform products based on Qualcomm 8255 chip, positioned as an upgraded version of Qualcomm 8155, which can directly undertake Qualcomm 8155 cockpit system ecology and shorten the development cycle for vehicle installations. At the same time, based on high computing power of 8255, cockpit integration solutions such as cockpit-parking integration can also be realized. It is expected that in 2024-2025, Qualcomm 8255 cockpit platform products are expected to inherit the Qualcomm 8155 market and become the mainstream solution in the market.
Samsung V920 platform solution: mainly deployed by Harman, Visteon and other foreign Tier1s, and Hyundai is the first to mass-produce and install it
In 2024, Harman launched the latest Ready Upgrade Advanced cockpit domain controller, which provides optimized solutions for high-end models or OEMs who want to add more displays, richer safety functions, and connectivity services to existing vehicles. Provide superior in-car experience through new Samsung Exynos processor, and introduce new features and service capabilities for on-demand access through Harman Ignite Store app and third-party applications. Meanwhile, Harman also collaborates with TE Connectivity to achieve easier hardware upgradability via patented NET-AX + modular hybrid connectors.
AMD V2000A platform solution: creating the ultimate cockpit for PC-level performance
ECARX builds Makalu computing platform, based on AMD Ryzen embedded V2000 processor and Radeon RX6600 series GPU. Equipped with ECARX Cloudpeak cross-domain system, it can provide console game-level graphics and image rendering capabilities. It also supports the latest graphics processing interface of PC-level computing platform and Unreal Engine 5, which can realize real-time rendering of 3D environment and 7.X.4 panoramic spatial audio. Comprehensively empower partners to create full-scenario 3D immersive cockpit functions and provide a complete soft and hard capability base for the next-generation intelligent cockpit products. It will be mass-produced in Smart models in 2024.
Table of Contents
1 Analysis of Intelligent Cockpit Platform Configuration Strategy and Development Direction
Summary (1)
Summary (2)
1.1 Summary of Automotive Intelligent Cockpit Platform Development Trends
1.1.1 Definition of Automotive Intelligent Cockpit Platform
1.1.2 Current Cockpit Platform Hardware is Dominated by SoC External with MCU Architecture
1.1.3 Composition of Intelligent Cockpit Software Platform
1.1.4 Evolution of Intelligent Cockpit Software Platform
1.1.5 Evolution Routes of Intelligent Cockpit Platform
1.1.6 Forecast of Time to Implement Various Cockpit Platforms
1.2 Cockpit Platforms and Architectures for Mainstream Layouts in 2024
1.2.1 Classification of Mainstream Cockpit Platform Solutions
1.2.2 Mainstream Cockpit Platform Solutions in 2024
1.2.3 Market Share of Mainstream Cockpit Platform Solutions in Mass Production
1.2.4 Cockpit Platform Architecture (1)
1.2.5 Cockpit Platform Architecture (1)
1.2.6 Cockpit Platform Architecture (2)
1.2.7 Cockpit Platform Architecture (3)
1.2.8 Cockpit Platform Architecture (3)
1.2.9 Cockpit Platform Architecture (4)
1.2.10 Cockpit Platform Architecture (5)
1.2.11 Cockpit Platform Architecture (6)
1.2.12 Cockpit Platform Architecture (7)
1.2.13 Cockpit Platform Architecture (8)
1.3 Development Direction of Intelligent Cockpit Platform (1): Cockpit-only Platform
1.3.1 Demand Drivers for Cockpit-only Platform Solution
1.3.2 Latest Cockpit-only Platform Solution in 2024 (1)
1.3.3 Latest Cockpit-only Platform Solution in 2024 (2)
1.3.4 Cockpit-only Platform Product (1)
1.3.5 Cockpit-only Platform Product (2)
1.3.6 Cockpit-only Platform Product (3)
1.3.7 Cockpit-only Platform Product (4):
1.4 Development Direction of Intelligent Cockpit Platform (2): Layout and Trends of Cockpit-parking Integration Solution
1.4.1 Status Quo and Trends of Cockpit-parking Integration Solution
1.4.2 Major Cockpit-parking Integration Solution (1)
1.4.3 Major Cockpit-parking Integration Solution (2)
1.4.4 Major Cockpit-parking Integration Solution (3)
1.4.5 Architecture of Cockpit-parking Integration Solution (1)
1.4.6 Architecture of Cockpit-parking Integration Solution (2)
1.4.7 Architecture of Cockpit-parking Integration Solution (3)
1.4.8 Architecture of Cockpit-parking Integration Solution (4)
1.5 Development Direction of Intelligent Cockpit Platform (3): Layout and Trends of Low- and Mid-level Cockpit-driving-parking Integration Solution
1.5.1 Layout Modes and Positioning of Cockpit-driving-parking Integration
1.5.2 Major Cockpit-driving-parking Integration Solutions
1.5.3 Cases of Released Model with Cockpit-driving-parking Integration
1.5.4 Architecture of Cockpit-driving-parking Integration Solution (1)
1.5.5 Architecture of Cockpit-driving-parking Integration Solution (2)
1.5.6 Architecture of Cockpit-driving-parking Integration Solution (3)
1.5.7 Architecture of Cockpit-driving-parking Integration Solution (4)
1.5.8 Major Case (1)
1.5.9 Major Case (2)
1.5.10 Major Case (3)
1.6 Development Direction of Intelligent Cockpit Platform (4): Solutions of Cockpit Integrated with Connectivity and other Functional Domains
1.6.1 Layout of Cockpit Integrated with Connectivity Domain
1.6.2 Product Solution Architecture
1.6.3 Product Case (1)
1.6.4 Product Case (2)
1.7 Development Direction of Intelligent Cockpit Platform (5): Cockpit-driving integrated Central Computing Platform
1.7.1 Major Layout Method of Cockpit-driving Integration
1.7.2 Vehicle Central Computing Platform Architecture Solution 1
1.7.3 Vehicle Central Computing Platform Architecture Solution 2
1.7.4 Intelligent Cockpit Development Form under the Trend of Cockpit-driving Integration
1.7.5 Evolution of Intelligent Cockpit Development under the Trend of Cross-domain Integration
1.7.6 Cockpit-driving Integration Solution of Major Companies (1)
1.7.7 Cockpit-driving Integration Solution of Major Companies (2)
1.7.8 Optional SOC for Single-chip Cockpit-driving Integration Solution
