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세계의 자동차용 스마트 조종석 디자인 동향(2021년)

Automotive Smart Cockpit Design Trend Report, 2021

리서치사 ResearchInChina
발행일 2021년 09월 상품 코드 1028450
페이지 정보 영문 255 Pages
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세계의 자동차용 스마트 조종석 디자인 동향(2021년) Automotive Smart Cockpit Design Trend Report, 2021
발행일 : 2021년 09월 페이지 정보 : 영문 255 Pages

본 상품은 영문 자료로 한글과 영문목차에 불일치하는 내용이 있을 경우 영문을 우선합니다. 정확한 검토를 위해 영문목차를 참고해주시기 바랍니다.

조종석의 하드웨어 및 소프트웨어 기술의 끊임없는 발전과 더불어 지능형 조종석 디자인, 기능에서 사용자 경험으로 방향을 전환하여 진화하고 있습니다. 지능형 조종석은 더 안전하고 똑똑하며 편안해지고 있습니다.

조종석 디스플레이는 아직 멀티 스크린과 대형 스크린이 주류입니다. 2020년부터 2021년까지 신흥 자동차 제조 업체와 전통적인 자동차 메이커가 잇따라 멀티 스크린과 조인트 스크린을 탑재한 모델을 발표하고 있습니다.

자동차 HMI의 UI 디자인은 실용적인 기능을 기반으로 변화하고 있습니다. 기능이 많을수록 스마트 자동차를 알리고 그 기반이 되는 데이터는 점점 더 풍부해질 것입니다. 미래에는 인터페이스 상호 작용은 더 짧게, 3D 직관적으로 더 젊고 투명하며 디지털화되고 기호화된 플랫폼을 기대할 수 있습니다.

자동차용 스마트 조종석 디자인(Automotive Smart Cockpit Design) 동향을 조사했으며 스마트 조종석, HMI 스마트 표면 응용 프로그램, 앰비언트 라이트 응용 프로그램, 스마트 햅틱 피드백 기술 등 설계 동향, 주요 공급 업체 등의 정보를 제공합니다.

목차

제1장 자동차용 스마트 조종석 디자인 아이디어 및 동향

  • 스마트 조종석 디자인 레이아웃 현황
    • 자동차용 스마트 조종석 개요
    • 자동차용 스마트 조종석 개발 특성
    • 자동차 조종석의 개발 동향
    • 2021년 새롭게 출시된 주요 모델 조종석 구성 : 개념 모델
    • 2020년 새롭게 출시된 주요 모델 조종석 구성 : 개념 모델
    • 컨셉 모델 조종석 구성
    • 생산 모델 조종석 구성
  • 자동차의 스마트 조종석 설계 개발 동향
    • 스마트 조종석 설계 동향
    • 자율 주행 수준에서의 스마트 조종석 설계 동향

제2장 자동차용 스마트 조종석 디스플레이 설계 동향

  • 조종석 디스플레이 디자인 현황
    • 조종석 디스플레이 레이아웃
    • 조종석 디스플레이 디자인의 현황
    • 대기업의 조종석 디스플레이 사업 레이아웃
    • 조종석 클러스터 디스플레이 개발 방향
    • 대기업 클러스터 디스플레이 사업 레이아웃
    • 조종석 HUD 현황
    • 대기업의 AR-HUD 비즈니스 레이아웃
    • AID-홀로그램 공중 지능형 디스플레이 시스템
  • 조종석 디스플레이 디자인 동향

제3장 자동차용 스마트 조종석 HMI 설계 동향

  • 자동차의 조종석 HMI 설계 현황
    • 자동차 HMI 개요
    • 자동차 HMI 모드 개발 내역
    • 국내 및 해외 OEM 주요 HMI 모드
    • 자동차 HMI 설계 모드
    • 자동차 HMI 설계 과정
    • 자동차 HMI 개발 과정
    • 자동차 HMI 설계 프레임 워크
    • 자동차 UX 디자인 원칙
    • 자동차 HMI 설계에 필요한 도구
    • 대기업 HMI 설계 통합 소프트웨어 도구
    • 주요 OEM의 HMI 설계 공급 업체
    • 주요 모델 HMI 공급 업체
    • 주요 OEM의 IVIUI 인터페이스 기능
    • UI 케이스
  • 조종석 HMI 디자인 동향
    • HMI 동향
    • 자동차 UI 디자인 동향
    • 조종석 HMI 도구 개발 동향
    • 케이스
  • 조종석 HMI 설계 주요 공급 업체
    • ThunderSoft
    • CANDERA
    • Altia
    • Qt Design
    • Elektrobit(EB)
    • Neusoft HMI Design
    • Valeo
    • Visteon HMI
    • Bosch HMI
    • Faurecia HMI

제4장 자동차용 스마트 표면 응용 프로그램 설계 동향

  • 스마트 표면 기술 개요
    • 스마트 표면 개요
    • 스마트 서피스 제품 기능
    • 스마트 표면 구성
    • 스마트 표면 기술 : 장식 필름 형성 과정
    • 주요 공급 업체 스마트 표면 제품
    • 스마트 표면 산업 체인
  • 스마트 표면 기술 설계 동향
    • 스마트 표면 디자인 동향
  • 스마트 서피스 애플리케이션 케이스
    • 케이스
  • 스마트 표면 기술 주요 솔루션 공급 업체
    • Covestro
    • Canatu
    • TactoTek
    • Yanfeng Automotive Interiors
    • Continental

제5장 스마트 조종석 주변광 응용 프로그램 설계의 동향

  • 인테리어 앰비언트 라이트 개발 개요
    • 자동차 앰비언트 라이트 개요
    • 자동차 앰비언트 라이트 분류
    • 자동차 앰비언트 라이트 구성
    • 자동차 앰비언트 라이트 적용 범위
    • 인테리어 앰비언트 조명 제어 기술
    • 인테리어 앰비언트 라이트 본체 네트워크 아키텍처
    • 인테리어 조명 설계 프로세스
    • 주요 OEM 모델의 광량 구성
    • 인테리어 앰비언트 라이트 개발과 진화
    • 인테리어 앰비언트 라이트 세계 시장 규모
    • 세계의 인테리어 앰비언트 라이트 유통
    • 세계의 유통 및 인테리어 앰비언트 라이트 광학 기술
    • 인테리어 주변광 산업 체인
  • 인테리어 앰비언트 라이트 개발 동향
  • 인테리어 앰비언트 라이트 인터랙티브 케이스

제6장 자동차용 스마트 햅틱 피드백 기술 응용 동향

  • 자동차용 터치 피드백 개발 개요
    • 터치 피드백 기술 개요
    • 터치 피드백 기술 수요
    • 터치 피드백 기술 모드
    • 메인 터치 피드백 기술 산업 체인
    • 터치 피드백 기술과 제품 주요 공급 업체
    • 터치 피드백 기술과 제품 주요 Tier1 공급 업체
    • OEM 터치 피드백 기술 응용 프로그램
    • 자동차용 디스플레이 터치 시스템 기술 로드맵
    • 케이스
  • 주요 자동차 환경 틱 피드백 공급 업체
    • Tanvas
    • Boreas
    • TDK PowerHap(TM) Piezo Actuator with Haptic Feedback
    • Continental
    • 기타

제7장 기타 새로운 조종석 상호 작용 기술

  • 다양한 대화형 스티어링 휠의 디자인
  • 공간 활용의 극대화
  • 자동차 음향 효과
  • 스마트하고 건강한 조종석 레이아웃
NJH 21.10.12

Smart Cockpit Design Trend Research: Moving to the third living space

With the continuous development of cockpit hardware and software technology, intelligent cockpit design is evolving, pivoting from functionality to "user experience". Intelligent cockpits are becoming more and more secure, smart and comfortable.

In terms of perception, the cockpit display is not limited to multi screens and large screens, 3D screens and high-definition screens are also emerging.

For cockpit display, multi screens and large screens still prevail. From 2020 to 2021, emerging automakers and traditional automakers have successively launched a number of models equipped with multiple screens and joint screens. For example, Hongqi E-HS9 was equipped with 8 screens at the end of 2020. In 2021, Human Horizons mass-produced and delivered HiPhi X equipped with 9 screens. At the same time, the screen size in the car is getting larger and larger. The center console of Xingyue L, launched in July 2021, has a 1-meter IMAX screen. The center console of Ford EVOS that is planned to be launched in October 2021 will feature a 27-inch 4K display. Cadillac Lyriq to be launched in 2022 will have a 33-inch all-in-one display.

In addition, the screen layout has become more novel and unique. In early 2021, Mercedes-Benz revealed the MBUX Hyperscreen, whose three displays merge almost seamlessly into one another to create an impressive screen band over 141 centimeters wide: Driver display (screen diagonal: 12.3 inch), central display (17.7 inch) and front passenger display (12.3 inch) appear as one visual unit. Three screens sit under a common bonded irregular curved cover glass. For particularly brilliant display quality OLED technology is used for the central and front passenger displays. The MBUX Hyperscreen embodies a strong sense of technology.

The IM L7, which is planned to be mass-produced in 2022, is equipped with a 39-inch smart scenario screen and a 12.8-inch AMOLED center console screen. The 39-inch screen is composed of two joint screens, which can be raised and lowered separately with multiple display modes and allow the content to be switched without boundaries.

Driven by high-definition mobile phone displays, consumers have more views on the resolution of automotive displays. Low-resolution displays can no longer meet the needs of the current users. Automotive displays tend to feature higher resolution, higher contrast, wider field of view, more optical indicators, and faster response. In the BMW iX scheduled to be launched at the end of 2021, the new iDrive 8 will come with horizontal curved dual screens: a 12.3-inch LCD cluster screen and 14.9-inch IVI screen (the angle is slightly inclined towards the driver). BMW says screens used in the new system will have a pixel density of 206 pixels per inch (PPI).

HMI capabilities develop from functional perception interaction to cognitive and active interaction

The HMI UI interface design for automobiles is changing on the basis of practical functions. With more and more functions, smart cars are getting cleverer, and the underlying data is more and more abundant. In the future, interface interactions will be more concise, 3D intuitive, younger, transparent, digitized, and symbolized, flattened and the like. In June 2020, Banma SmartDrive released the Venus Intelligent System whose UI interface adopts the design concept of A-B parallel worlds. World A takes a "map as a desktop", while World B uses a waterfall layout. Users can intuitively find commonly used functions on the interface, and even set the display interface as what they want.

MBUX Hyperscreen can display the desired personalized functions for users on the main interface of the central screen at an appropriate time, enabling "zero-layer" operation without scrolling or turning pages, bringing relaxed and intimate HMI experience.

Innovation and breakthroughs in UI interface design are inseparable from the development of HMI design tools. In terms of HMI design and development tools, many companies have released the latest products. Lately, HMI design and development tools feature multiple platforms, multiple algorithms, reusable software framework, 3D interface design, etc. In addition, with the creation of the third space of the smart cockpit and the continuous improvement of entertainment, technology HMI design companies such as web game companies like Eptic Games have dabbled in the automotive market.

Through the fusion applications of AI, smart atmosphere lights, smart surface materials, fragrance systems, smart seats and other products and technologies, voice, AI assistants, face recognition, gestures, face, fingerprint, vital signs detection and other HMI technologies and models have been available in cars. The smart cockpit has certain HMI experience and scenario-based capabilities, and the cockpit scenario interaction is more intelligent, emotional, and humane. HiPhi X, which was mass-produced and delivered in 2021, can recognize the driver's expression, voice, heart rate, blood oxygen, blood pressure, breathing rate, etc. through 52 biosensors, and then adjust music and temperature, or take over the vehicle in dangerous situations.

At CES 2021, Samsung exhibited a digital cockpit equipped with Automotive Samsung Health, which analyzes passengers' health status before boarding by utilizing a combination of cameras and wearable and mobile devices installed in the vehicle. In the car, it also regularly monitors passengers' stress levels and will adjust the vehicle's lighting, scent, or music in an effort to help them relax.

With the HMI design concept focusing on "user experience", HMI is developing from basic functional perception interaction to cognitive and active interaction through AI, in-car and out-of-car perception technologies.

Smart cockpits realize custom programming through SOA software

Since smart cockpits are designed as per human-oriented user experience, personalization will become a major development trend of smart cockpits in the future. In addition to the basic personalized custom settings such as the initial IVI system and buttons, the software architecture can help realize the personalized custom settings of multiple scenarios in the car. For example, the WM W6, which was launched at the Shanghai Auto Show in 2021, WM W6 realizes personalized combinations and settings of scenarios based on SOA software and through APP custom programming.

Table of Contents

1 Ideas and Trends of Automotive Smart Cockpit Design

  • 1.1 Status Quo of Smart Cockpit Design Layout
    • 1.1.1 Overview of Automotive Smart Cockpits
    • 1.1.2 Development Characteristics of Automotive Smart Cockpits
    • 1.1.3 Development Trends of Automotive Cockpits
    • 1.1.4 Cockpit Configuration of Main Newly Released Models in 2021: Concept Models
    • 1.1.5 Cockpit Configuration of Main Newly Released Models in 2020: Concept Models
    • 1.1.6 Cockpit Configuration of Concept Models (1)
    • 1.1.7 Cockpit Configuration of Concept Models (2)
    • 1.1.8 Cockpit Configuration of Concept Models (3)
    • 1.1.9 Cockpit Configuration of Production Models (1)
    • 1.1.10 Cockpit Configuration of Production Models (2)
    • 1.1.11 Cockpit Configuration of Production Models (3)
    • 1.1.12 Cockpit Configuration of Production Models (4)
    • 1.1.13 Cockpit Configuration of Production Models (5)
    • 1.1.14 Cockpit Configuration of Production Models (6)
    • 1.1.15 Cockpit Configuration of Production Models (7)
    • 1.1.16 Cockpit Configuration of Production Models (8)
    • 1.1.17 Cockpit Configuration of Production Models (9)
    • 1.1.18 Cockpit Configuration of Production Models (10)
    • 1.1.19 Cockpit Configuration of Production Models (11)
    • 1.1.20 Cockpit Configuration of Production Models (12)
  • 1.2 Development Trends of Automotive Smart Cockpit Design
    • 1.2.1 Smart Cockpit Design Trends (1)
    • 1.2.2 Smart Cockpit Design Trends (2)
    • 1.2.3 Smart Cockpit Design Trends (3)
    • 1.2.4 Smart Cockpit Design Trends (4)
    • 1.2.5 Smart Cockpit Design Trends (5)
    • 1.2.6 Smart Cockpit Design Trends (6)
    • 1.2.7 Smart Cockpit Design Trends under Autonomous Driving Levels

2 Automotive Smart Cockpit Display Design Trends

  • 2.1 Status Quo of Cockpit Display Design
    • 2.1.1 Cockpit Display Layout
    • 2.1.2 Status Quo of Cockpit Display Design
    • 2.1.3 Cockpit Display Business Layout of Major Companies
    • 2.1.4 Development Direction of Cockpit cluster Display
    • 2.1.5 Cluster Display Business Layout of Major Companies
    • 2.1.6 Status Quo of Cockpit HUD
    • 2.1.7 AR-HUD Business Layout of Major Companies
    • 2.1.8 AID - Holographic Aerial Intelligent Display System
  • 2.2 Cockpit Display Design Trends
    • 2.2.1 Cockpit Display Design Trends (1)
    • 2.2.2 Cockpit Display Design Trends (2)
    • 2.2.3 Cockpit Display Design Trends (3)
    • 2.2.4 Cockpit Display Design Trends (4)
    • 2.2.5 Cockpit Display Design Trends (5)
    • 2.2.6 Cockpit Display Design Trends (6)
    • 2.2.7 Cockpit Display Design Trends (7)
    • 2.2.8 Cockpit Display Design Trends (8)
    • 2.2.9 Cockpit Display Design Trends (9)
    • 2.2.10 Cockpit Display Design Trends (10)
    • 2.2.11 Cockpit Display Design Trends (11)
    • 2.2.12 Cockpit Display Design Trends (12)
    • 2.2.13 Cockpit Display Design Trends (13)
    • 2.2.14 Cockpit Display Design Trends (14)
    • 2.2.15 Cockpit Display Design Trends (15)
    • 2.2.16 Cockpit Display Design Trends (16)

3 Automotive Smart Cockpit HMI Design Trends

  • 3.1 Status Quo of Automotive Cockpit HMI Design
    • 3.1.1 Overview of Automotive HMI
    • 3.1.2 Development History of Automotive HMI modes
    • 3.1.3 Main HMI Modes of domestic and foreign OEMs
    • 3.1.4 Design Modes of Automotive HMI
    • 3.1.5 Design Process of Automotive HMI
    • 3.1.6 Development Process of Automotive HMI
    • 3.1.7 Design Framework of Automotive HMI
    • 3.1.8 Design Principles of Automotive UX
    • 3.1.9 Tools Required for Automotive HMI Design
    • 3.1.10 HMI Design Integrated Software Tools of Major Companies
    • 3.1.11 HMI Design Suppliers of Main OEMs
    • 3.1.12 HMI Suppliers of Main Models
    • 3.1.13 IVI UI interface features of Main OEMs (1)
    • 3.1.14 IVI UI interface features of Main OEMs (2)
    • 3.1.15 UI Cases (1)
    • 3.1.16 UI Cases (2)
    • 3.1.17 UI Cases (3)
  • 3.2 Cockpit HMI Design Trends
    • 3.2.1 HMI Trends (1)
    • 3.2.2 HMI Trends (2)
    • 3.2.3 HMI Trends (3)
    • 3.2.4 HMI Trends (4)
    • 3.2.5 HMI Trends (5)
    • 3.2.6 Automotive UI Design Trends
    • 3.2.7 Development Trends of Cockpit HMI Tools
    • 3.2.8 Cases (1)
    • 3.2.9 Cases (2)
    • 3.2.10 Cases (3)
  • 3.3 Cockpit HMI Design of Main Suppliers
    • 3.3.1 ThunderSoft
      • 3.3.1.1 Development of KANZI
      • 3.3.1.2 Introduction to KANZI HMI
      • 3.3.1.3 KANZI HMI Products
      • 3.3.1.4 Architecture of KANZI HMI
      • 3.3.1.5 Design Process to KANZI HMI
      • 3.3.1.6 Platforms Supported by KANZI
      • 3.3.1.7 KANZI® HYBRID
      • 3.3.1.8 KANZI's Latest News
    • 3.3.2 CANDERA
      • 3.3.2.1 CGI: HMI Interface Design based on CGI Studio
      • 3.3.2.2 CGI Studio: 3.10
      • 3.3.2.3 Main Software, Hardware and Ecosystem Supported by CGI
      • 3.3.2.4 Cases (1)
      • 3.3.2.5 Cases (2)
      • 3.3.2.6 Dynamic
    • 3.3.3 Altia
      • 3.3.3.1 Altia - Model-based HMI Design and Development Software (1)
      • 3.3.3.2 Altia - Model-based HMI Design and Development Software (2)
      • 3.3.3.3 Altia-3D Design
    • 3.3.4 Qt Design
      • 3.3.4.1 Qt Products
      • 3.3.4.2 QtAutomotive Suite: Qt Automotive Suite
      • 3.3.4.3 Components and Tools of Qt Automotive Suite
      • 3.3.4.4 Components of Qt Automotive Suite (1)
      • 3.3.4.5 Components of Qt Automotive Suite (2)
      • 3.3.4.6 Functional Safety Qt Architecture
      • 3.3.4.7 Qt Design Tools (1)
      • 3.3.4.8 Qt Design Tools (2)
      • 3.3.4.9 Qt Development Tools
      • 3.3.4.10 Qt for MCU
      • 3.3.4.11 Qt Quick 3D
      • 3.3.4.12 Qt for Android Automotive
      • 3.3.4.13 Qt Digital Cockpit Solutions (1)
      • 3.3.4.14 Qt Digital Cockpit Solutions (2)
      • 3.3.4.15 Main Automotive Customers of Qt
    • 3.3.5 Elektrobit (EB)
      • 3.3.5.1 EB GUIDE
      • 3.3.5.2 EB GUIDE Frame
      • 3.3.5.3 EB GUIDE arware
      • 3.3.5.4 Cases (1)
      • 3.3.5.5 Cases (2)
      • 3.3.5.6 Cases (3)
    • 3.3.6 Neusoft HMI Design
      • 3.3.6.1 HMI Design Solution
      • 3.3.6.2 Smart Connected Ecological Platform Based on AI and Voice Interaction
      • 3.3.6.3 Full LCD Cluster Design Solution
    • 3.3.7 Valeo
      • 3.3.7.1 HMI Business (1)
      • 3.3.7.2 HMI Business (2)
      • 3.3.7.3 HMI Business (3)
    • 3.3.8 Visteon HMI
      • 3.3.8.1 HMI Business (1)
      • 3.3.8.2 HMI Business (2)
    • 3.3.9 Bosch HMI
      • 3.3.9.1 HMI Products: HMI Solution
      • 3.3.9.2 HMI Products: Business Mode (1)
      • 3.3.9.3 HMI Products: Business Mode (2)
    • 3.3.10 Faurecia HMI
      • 3.3.10.1 HMI Business (1)
      • 3.3.10.2 HMI Business (2)
      • 3.3.10.3 HMI Business (3)
      • 3.3.10.4 HMI Business (4)
      • 3.3.10.5 Zhi*Zhen Cockpit

4 Automotive Smart Surface Application Design Trends

  • 4.1 Overview of Smart Surface Technology
    • 4.1.1 Overview of Smart Surface
    • 4.1.2 Features of Smart Surface Products
    • 4.1.3 Composition of Smart Surface
    • 4.1.4 Smart Surface Technology: Decorative Film Forming Process
    • 4.1.5 Smart Surface Products of Main Suppliers
    • 4.1.6 Smart Surface Industry Chain
  • 4.2 Design Trends of Smart Surface Technology
    • 4.2.1 Smart Surface Design Trends (1)
    • 4.2.2 Smart Surface Design Trends (2)
    • 4.2.3 Smart Surface Design Trends (3)
    • 4.2.4 Smart Surface Design Trends (4)
    • 4.2.5 Smart Surface Design Trends (5)
  • 4.3 Smart Surface Application Cases
    • 4.3.1 Cases (1)
    • 4.3.2 Cases (2)
    • 4.3.3 Cases (3)
    • 4.3.4 Cases (4)
    • 4.3.5 Cases (5)
  • 4.4 Main Solution Suppliers of Smart Surface Technology
    • 4.4.1 Covestro
      • 4.4.1.1 Smart Surface Solution
      • 4.4.1.2 Cases (1)
      • 4.4.1.3 Cases (2)
    • 4.4.2 Canatu
      • 4.4.2.1 Profile
      • 4.4.2.2 Smart Surface Solution
      • 4.4.2.3 CANATU 3D Touch with Translucent Fabric
      • 4.4.2.4 CANATU 3D Touch Transparent Control Switch
      • 4.4.2.5 3D Touch Sensor
      • 4.4.2.6 Origo Concept Steering Wheel
      • 4.4.2.7 Cases (1)
      • 4.4.2.8 Cases (2)
    • 4.4.3 TactoTek
      • 4.4.3.1 Smart Surface Products
      • 4.4.3.2 Smart Surface Technology
      • 4.4.3.3 Main Partners and Customers in the Automotive Field
    • 4.4.4 Yanfeng Automotive Interiors
      • 4.4.4.1 Smart Surface Technology (1)
      • 4.4.4.2 Smart Surface Technology (2)
      • 4.4.4.3 Smart Surface Technology (3)
      • 4.4.4.4 Smart Surface Application of XiM21 Smart Cockpit
    • 4.4.5 Continental
      • 4.4.5.1 Smart Surface
      • 4.4.5.2 Smart Surface Materials
      • 4.4.5.3 R & D Direction of Smart Surface Materials
      • 4.4.5.4 Cooperation with CU-BX in Automotive Non-contact Occupant Health and Safety Detection System

5 Application and Design Trends of Ambient Lights in Smart Cockpits

  • 5.1 Development Overview of Interior Ambient Lights
    • 5.1.1 Overview of Automotive Ambient Lights
    • 5.1.2 Classification of Automotive Ambient Lights
    • 5.1.3 Composition of Automotive Ambient Lights
    • 5.1.4 Application Scope of Automotive Ambient Lights
    • 5.1.5 Control Technology of Interior Ambient Lights
    • 5.1.6 Main Body Network Architecture of Interior Ambient Lights (1)
    • 5.1.7 Main Body Network Architecture of Interior Ambient Lights (2)
    • 5.1.8 Main Body Network Architecture of Interior Ambient Lights (3)
    • 5.1.9 Design Process of Interior Lighting
    • 5.1.10 Ambient Light Configuration of Main OEM Models
    • 5.1.11 Development and Evolution of Interior Ambient Lights (1)
    • 5.1.12 Development and Evolution of Interior Ambient Lights (2)
    • 5.1.13 Global Market Scale of Interior Ambient Lights
    • 5.1.14 Global Distribution of Interior Ambient Lights
    • 5.1.15 Global Distribution and Optics Technology of Interior Ambient Lights
    • 5.1.16 Industry Chain of Interior Ambient Lights
  • 5.2 Development Trends of Interior Ambient Lights
    • 5.2.1 Development Trends of Interior Ambient Lights (1)
    • 5.2.2 Development Trends of Interior Ambient Lights (2)
    • 5.2.3 Development Trends of Interior Ambient Lights (3)
    • 5.2.4 Development Trends of Interior Ambient Lights (4)
    • 5.2.5 Development Trends of Interior Ambient Lights (5)
  • 5.3 Interactive Cases of Interior Ambient Lights
    • 5.3.1 Cases (1)
    • 5.3.2 Cases (2)
    • 5.3.3 Cases (3)
    • 5.3.4 Cases (4)

6 Application Trends of Automotive Smart Haptic Feedback Technology

  • 6.1 Overview of Automotive Touch Feedback Development
    • 6.1.1 Overview of Touch Feedback Technology
    • 6.1.2 Demand for Touch Feedback Technology
    • 6.1.3 Touch Feedback Technology Mode (1)
    • 6.1.4 Touch Feedback Technology Mode (2)
    • 6.1.5 Touch Feedback Technology Mode (3)
    • 6.1.6 Industry Chain of Main Touch Feedback Technology
    • 6.1.7 Main Suppliers of Touch Feedback Technology and Products
    • 6.1.8 Main Tier1 Suppliers of Touch Feedback Technology and Products
    • 6.1.9 Touch Feedback Technology Application of OEMs
    • 6.1.10 Automotive Display Touch System Technology Roadmap
    • 6.1.11 Cases (1)
    • 6.1.12 Cases (2)
    • 6.1.13 Cases (3)
  • 6.2 Main Automotive Haptic Feedback Suppliers
    • 6.2.1 Tanvas
      • 6.2.1.1 Multifunctional Surface Haptics Technology
      • 6.2.1.2 Automotive Solutions
    • 6.2.2 Boreas
      • 6.2.2.1 Piezo-Capdrive Technology
      • 6.2.2.2 BOS1211
    • 6.2.3 TDK PowerHap™ Piezo Actuator with Haptic Feedback
      • 6.2.3.1 PowerHap™ Piezo Actuator (Square Type) with Haptic Feedback
      • 6.2.3.2 PowerHap™ Products
      • 6.2.3.3 PowerHap™ Product Planning
    • 6.2.4 Continental
  • 6.2.4.1Haptic Feedback Technology
      • 6.2.4.2 Tactile Interactive Display
      • 6.2.4.3 HMI Business
    • 6.2.5 Others
      • 6.2.5.1 Haptic Feedback Technology of Bosch
      • 6.2.5.2 Haptic Feedback Technology of Joyson Electronics

7 Other Emerging Cockpit Interaction Technology

  • 7.1 Diversified and Interactive Steering Wheel Design
  • 7.2 Maximization of Space Utilization
  • 7.3 Automotive Sound Effects
  • 7.4 Smart Healthy Cockpit Layout
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