汽車產品開發創新的戰略洞察

Strategic Insights into Innovation in Automotive Product Development

出版日期: 2023年06月15日 | 出版商:

Frost & Sullivan | 英文 84 Pages | 商品交期: 最快1-2個工作天內

價格

簡介目錄

數位孿生、生成設計、虛擬原型和混合實境等顛覆性技術改變產品開發流程並加快上市時間。

技術發展的迅猛發展推動汽車行業的變革。本成長機會分析探討了徹底改變行業的尖端技術。人工智慧生成設計、量子模擬、混合實境、數位孿生、虛擬原型、智慧工廠、虛擬工作空間和機器視覺系統等數位促進因素加速了汽車產品開發，減少時間和成本，並提高永續性。

本報告探討了人工智慧生成設計如何幫助設計師和工程師生產最佳化的汽車零零件，同時減少多次設計迭代。分析量子模擬的影響，展示模擬和最佳化化學反應、材料特性和空氣動力學等關鍵方面的能力，最終導致更高效的引擎、電池和輕量材料的開發。它還展示了擴增實境（AR）和虛擬實境（VR）如何實現快速設計迭代和全球協作，更深入地研究智慧工廠和虛擬工作空間對汽車生產的影響，並強調這些發展如何提高效率、生產力和協作。

這份全面的分析涵蓋了在汽車產品開發中引進數位促進因素所帶來的影響、時間表和關鍵成果。總之，您將深入了解汽車行業發生的變革性創新。透過利用數位驅動器的力量，汽車原始設備製造商已經能夠徹底改變其產品開發流程。

汽車設計創新
使用人工智慧進行生成設計
汽車行業的人工智慧生成設計：10個應用領域
生成設計示例
人工智慧生成設計：領先的軟體提供商
通用汽車與 Autodesk 合作開發人工智慧生成設計
量子模擬
汽車原始設備製造商探索量子模擬
ModeFRONTIER：ESTECO 的工程
如何將客戶的意見涵蓋汽車設計
基於仿生學的汽車設計
用於虛擬產品設計的混合實境
汽車中的混合實境工具及其應用
產品設計中的混合實境：BMW案例研究
現代汽車在虛擬宇宙中的應用
產品開發中的數位孿生 (DT)
產品開發中的數位孿生合作夥伴關係
產品設計創新：要點

汽車原型階段的創新

原型設計的創新
汽車設計中的虛擬樣機
汽車設計中虛擬樣機的趨勢
虛擬樣機軟體提供商的能力
汽車原型 3D 列印
主要 OEM 利用 3D 列印進行原型開發
原型創新的關鍵要點

製造創新

製造創新
機器視覺系統
機器視覺系統OEM的努力
虛擬工作空間
虛擬工作空間OEM的努力
虛擬工作空間案例研究：福特
智慧工廠的發展
熄燈製造（全自動化製造）
製造創新關鍵

產品開發創新分析

汽車產品開發分類
技術應用時間表
永續產品開發領域
汽車產品發展階段技術狀況分析
創新對汽車價值鏈的影響：未來情景分析

充滿成長機會的宇宙

成長機會1：增強客戶參與
成長機會2：加速新產品開發
成長機會2：加速新產品開發
成長機會3：用於原型開發的虛擬工具
成長機會3：用於原型開發的虛擬工具
附件清單
免責聲明

簡介目錄

Product Code: PEBF-44

Disruptive Technologies, such as Digital Twins, Generative Design, Virtual Prototyping and Mixed Reality, to Transform Product Development Processes and Ensure Quicker Time to Market

A surge in technical developments is fueling change in the automotive sector. This growth opportunity analytics investigates cutting-edge technologies revolutionizing the industry. Digital drivers, such as AI-generative design, quantum simulation, mixed reality, digital twins, virtual prototyping, smart factories, virtual workspaces, and machine vision systems are speeding up automotive product development, reducing time and costs, and promoting sustainability.

This analysis investigates how AI-generative design enables designers and engineers to produce optimized automobile components while reducing multiple design iterations. The impact of quantum simulation is analyzed, showcasing its ability to simulate and optimize critical aspects, such as chemical reactions, material properties, and aerodynamics, ultimately leading to the development of more efficient engines, batteries, and lightweight materials. It explores mixed reality's disruptive potential, demonstrating how augmented reality (AR) and virtual reality (VR) enable quick design iteration and worldwide collaboration, and deep dives into the influence of smart factories and virtual workspaces on automotive production, highlighting how these developments improve efficiency, productivity, and collaboration.

This comprehensive analysis covers the impact, timeline, and major outcomes achieved through the implementation of digital drivers in automotive product development. In conclusion, it offers a profound understanding of the transformative innovations taking place in the automotive industry. By harnessing the power of digital drivers, automotive OEMs have been able to revolutionize their product development processes.

Strategic Imperatives

Why Is It Increasingly Difficult to Grow?
The Strategic Imperative 8™
The Impact of the Top 3 Strategic Imperatives on Innovation in Automotive Product Development
Growth Opportunities Fuel the Growth Pipeline Engine™

Growth Opportunity Analysis

Scope of Analysis
Growth Drivers
Growth Restraints

Growth Environment

Select OEM's Product Development Innovation Activities
Technology Application Timeline
Sustainable Product Development Areas
Technology Landscape Analysis Across Automotive Product Development Phases
Select Examples of Generative Design
Automotive OEMs Exploring Quantum Simulation
Mixed Reality Tools and their Application Areas in Automotive
Virtual Prototyping Software Provider Capabilities
Machine Vision Systems: OEM Initiatives

Automotive Product Development Overview

Innovation in Automotive Product Development: An Overview
Product Development Areas and Key Digital Technologies
Transformation in Product Development: Present to Future
Existing Challenges in Automotive Product Development
Addressing Challenges in Product Development
Product Development Innovation Activities of Select OEMs

Innovation in the Automotive Design Phase

Innovation In Automotive Design
AI-enabled Generative Design
Ten Application Areas of AI-generative Design in Automotive Industry
Examples of Generative Design
AI-generative Design: Select Software Providers
General Motors & Autodesk AI-generative Design Partnership
Quantum Simulation
Automotive OEMs Exploring Quantum Simulation
ModeFRONTIER: ESTECO Engineering
Methods to Receive Customer Input for Vehicle Design
Biomimicry-based Automotive Design
Mixed Reality for Virtual Product Design
Mixed Reality Tools and their Application Areas in Automotive
BMW Case Study of Mixed Reality for Product Design
Hyundai in Metaverse Applications
Digital Twins (DT) in Product Development
Select Partnerships in Digital Twins Related to Product Development
Innovation in Product Design: Key Takeaways

Innovation in Automotive Prototyping Phase

Innovation in Prototyping
Virtual Prototyping in Automotive Design
Trends in Virtual Prototyping in Automotive Design
Virtual Prototyping Software Provider Capabilities
3D Printing for Vehicle Prototype
Select OEMs Leveraging 3D Printing for Prototype Development
Innovation in Prototyping: Key Takeaways

Innovation in Manufacturing Phase

Innovation in Manufacturing Segmentation
Machine Vision Systems
Machine Vision Systems: OEM Initiatives
Virtual Workspaces
Virtual Workspaces: OEM Initiatives
Virtual Workspaces Case Study: Ford
Growth of Smart Factories
Lights-out Manufacturing
Innovation In Manufacturing: Key Takeaways

Analysis of Product Development Innovation

Automotive Product Development Categorization
Technology Application Timeline
Sustainable Product Development Areas
Technology Landscape Analysis Across Automotive Product Development Phases
Future Scenario Analysis of the Effect of Innovation on the Automotive Value Chain