全球航太扩增实境和虚拟实境市场规模（按技术类型、应用、最终用户、区域范围和预测）

航太扩增实境和虚拟实境市场规模及预测

2024 年航太扩增实境和虚拟实境市场规模价值 7.4022 亿美元，预计到 2032 年将达到 339.1844 亿美元，在 2026-2032 年预测期内的复合年增长率为 61.30%。

推动全球航太市场扩增实境和虚拟实境发展的因素

航太市场中扩增实境和虚拟实境的市场驱动因素会受到多种因素的影响。这些包括：

改进的培训和模拟能力：飞行员、维修技术人员和地勤人员都可以受益于 AR 和 VR 技术提供的身临其境型培训和模拟体验。虚拟训练环境可提高训练的有效性和安全性，使飞行员能够以安全和逼真的方式练习复杂的流程、执行模拟飞行操作和排除设备故障。

提高飞机设计和生产效率：AR 和 VR 技术可以帮助航太产业的协作设计评审、原型製作和生产流程。透过使用虚拟实境设定视觉化飞机设计、评估人体工学和组装程序，工程师和设计师可以提高生产力、降低成本并缩短新飞机模型和零件的上市时间。

MRO（维护、修理和大修）操作由 AR 和 VR 系统支持，使技术人员能够即时存取迭加在实际飞机部件上的数位资料、示意图和维护程序。具有扩增实境(AR) 功能的抬头显示器(HUD) 和智慧眼镜使技术人员能够进行检查、识别问题并更快地进行维修 - 减少停机时间并提高飞机的运转率。

借助扩增实境(AR) 技术，在分散和偏远地区工作的航太工作人员现在可以获得远端协助和支援。为了提高故障排除效率并减少对现场支援人员的需求，维护技术人员可以使用支援 AR 的设备接收即时视讯来源、迭加註释，并从其他地方的专家那里获得逐步协助。

增强乘客体验：航太领域正在采用虚拟实境 (VR) 技术，为乘客提供身临其境型的机上娱乐、虚拟客舱游览和互动体验。为了提高乘客的满意度和忠诚度，航空公司正在探索使用 VR 为乘客提供量身定制的娱乐选项、虚拟实境飞行体验以及目的地虚拟游览。

安全与情境察觉：透过将关键飞行和导航资料、地形图和障碍物警报迭加到驾驶座内飞行员和机组人员的视野中，扩增实境(AR) 技术正在提高参与者的情境察觉和安全性。具有扩增实境(AR) 功能的抬头显示器(HUD) 使飞行员无需将视线从道路上移开即可获取实时信息，从而提高了操作的有效性和安全性。

政府措施和投资：世界各地的政府机构和国防组织正在投资用于航太应用的 AR 和 VR 技术，以改善军事训练、任务规划和情境察觉。航太和国防供应商和承包商正在利用政府合约和贷款为这些行业创造尖端的 AR 和 VR 解决方案。

限制全球航太扩增实境和虚拟实境市场的因素

多种因素可能会对航太市场的扩增实境和虚拟实境造成限制和挑战。这些包括：

实施成本高：将AR和VR技术引入航太应用需要很高的前期成本。这些成本包括软体开发、硬体采购、培训、系统整合等。一些航太公司可能会因为需要大量的前期投资而不愿采用 AR 和 VR 解决方案，尤其是规模较小的组织或预算有限的组织。

技术的复杂性：由于 AR 和 VR 技术的复杂性，创建、部门和维护需要特定的知识。由于相容性问题、互通性挑战和监管限制，将 AR 和 VR 系统与当前的航太系统（例如驾驶座显示器、训练模拟器和飞机维护）相结合可能会很困难。在航太领域，技术复杂性可能会阻碍 AR 和 VR 解决方案的可扩展性和采用。

安全和认证问题：在航太领域，安全至关重要。所有新技术都必须经过严格的测试、检验和认证程序，以确保符合行业最佳实践和监管标准。航空当局必须核准用于飞行员训练、飞机维修和飞行支援的 AR 和 VR 系统。这些系统也必须遵守严格的安全标准。安全和认证问题可能会增加航空业 AR 和 VR 应用的开发时间和成本。

资料安全和隐私风险：航太领域的 AR 和 VR 系统可能会收集、处理和传输敏感数据，例如操作数据、维护日誌和飞机性能数据。保护资料安全和隐私对于阻止可能危及飞机安全和运行完整性的未授权存取、资料外洩和网路攻击至关重要。解决资料安全和隐私风险需要强有力的网路安全保障、加密程序以及遵守 CCPA 和 GDPR 等资料保护法。

内容和应用类型有限：与其他行业相比，航太领域针对扩增实境和虚拟实境设计的内容和应用可能较少。创建互动式驾驶座显示器、虚拟维护流程和身临其境型训练模拟需要专门的内容开发工具和特定领域的知识。缺乏多样化和适应性强的 AR 和 VR 用例可能会阻碍它们的采用并限制其在航空业务中的潜力。

抵制变革和需要培训：习惯于传统航太工作流程的相关人员可能会抵制采用 ​​AR 和 VR 技术。员工可能需要接受重新培训和再教育，以使用 AR 和 VR 技术进行维护、检查和培训。在航空营运中采用和利用 AR 和 VR 技术需要克服变革阻力并满足培训需求。

与旧有系统的整合：在设计、製造、维护和操作飞机时，航太企业通常依赖专有软体和旧有系统。将 AR 和 VR 技术与旧有系统结合可能会对资料交换、相容性和互通性造成障碍。维修现有的飞机系统以适应 AR 和 VR 功能需要仔细规划、客製化以及与软体供应商和系统整合商的合作。

市场教育和认知有限：儘管 AR 和 VR 在航太应用方面具有潜在优势，但监管者、决策者和航太专业人士可能不像他们应该的那样熟悉这些技术。为了推动市场采用、投资和创新，相关人员需要了解 AR 和 VR 技术在航太营运中的可能性、优点和限制。

目录

第一章 引言

• 市场定义
• 市场区隔
• 调查方法

第二章执行摘要

• 主要发现
• 市场概览
• 市集亮点

第三章市场概述

• 市场规模和成长潜力
• 市场趋势
• 市场驱动因素
• 市场限制
• 市场机会
• 波特五力分析

第四章航太市场中的扩增实境和虚拟实境（按技术类型）

• 扩增实境（AR）
• 虚拟实境（VR）

第 5 章航太市场中的扩增实境和虚拟实境（按应用）

• 训练与模拟
• 设计和原型製作
• 维护、修理和大修（MRO）
• 远端支援
• 飞行营运
• 乘客体验

第六章航太市场中的扩增实境和虚拟实境（按最终用户）

• 民航
• 军事/国防
• 通用航空
• 太空探勘

第七章区域分析

• 北美洲
• 美国
• 加拿大
• 墨西哥
• 欧洲
• 英国
• 德国
• 法国
• 义大利
• 亚太地区
• 中国
• 日本
• 印度
• 澳洲
• 拉丁美洲
• 巴西
• 阿根廷
• 智利
• 中东和非洲
• 南非
• 沙乌地阿拉伯
• 阿拉伯聯合大公国

第八章市场动态

• 市场驱动因素
• 市场限制
• 市场机会
• COVID-19 市场影响

第九章 竞争态势

• 主要企业
• 市场占有率分析

第十章 公司简介

• 微软公司（美国）
• 谷歌公司（美国）
• Eon Reality（美国）
• Aero Glass（美国）
• Upskill（美国）
• Oculus VR（美国）
• 贾索伦（美国）
• IMB（美国）
• Fountx（澳洲）
• 索尼（日本）

第十一章 市场展望与机会

• 新兴技术
• 未来市场趋势
• 投资机会

第十二章 附录

• 简称列表
• 来源和参考文献

Augmented Reality And Virtual Reality In Aerospace Market Size And Forecast

Augmented Reality And Virtual Reality In Aerospace Market size was valued at USD 740.22 Million in 2024 and is projected to reach USD 33918.44 Million by 2032, growing at a CAGR of 61.30% during the forecast period 2026-2032.

Global Augmented Reality And Virtual Reality In Aerospace Market Drivers

The market drivers for the Augmented Reality And Virtual Reality In Aerospace Market can be influenced by various factors. These may include:

Improved Training and Simulation Capabilities: Pilots, maintenance technicians, and ground crew can all benefit from immersive training and simulation experiences provided by AR and VR technology. Enhancing training efficacy and safety, virtual training environments enable students to practice intricate processes, run flight operations simulations, and troubleshoot equipment in a safe and realistic way.

Efficiency in Aircraft Design and Production: AR and VR technologies help the aerospace industry's collaborative design reviews, prototyping, and production processes. By visualizing aircraft designs, evaluating ergonomics, and streamlining assembly procedures using virtual reality settings, engineers and designers may increase productivity, cut costs, and shorten the time it takes to launch new aircraft models and componentry.

MRO (maintenance, repair, and overhaul) operations are aided by AR and VR systems, which give technicians instant access to digital data, schematics, and maintenance instructions superimposed on actual aircraft parts. Heads-up displays (HUDs) and smart glasses with augmented reality (AR) capabilities enable technicians to carry out inspections, identify issues, and carry out repairs more quickly, decreasing downtime and increasing aircraft availability.

Aerospace workers operating in dispersed or remote places can now receive remote assistance and support thanks to augmented reality technologies. In order to improve troubleshooting productivity and lessen the need for onsite support personnel, maintenance technicians can employ AR-equipped devices to receive live video feeds, overlay annotations, and receive step-by-step help from specialists stationed elsewhere.

Improved Passenger Experience: Virtual reality (VR) technology is being employed in the aerospace sector to provide immersive in-flight entertainment, virtual cabin tours, and interactive experiences for passengers. In order to increase passenger pleasure and loyalty, airlines are investigating VR applications to provide tailored entertainment options, virtual reality in-flight experiences, and virtual tours of destinations.

Safety and Situational Awareness: By superimposing vital flight data, navigational data, terrain maps, and obstacle alerts onto pilots' and aircrew members' fields of vision in the cockpit, augmented reality (AR) technology improves situational awareness and safety for participants. Head-up displays (HUDs) with augmented reality (AR) capabilities give pilots access to real-time information without forcing them to take their eyes off the road, enhancing both operational effectiveness and safety.

Government Initiatives and Investments: To improve military training, mission planning, and situational awareness, government agencies and defense organizations throughout the world are investing in AR and VR technologies for aerospace applications. Government contracts and financing are being used by aerospace and defense vendors and contractors to create cutting-edge AR and VR solutions for these industries.

Global Augmented Reality And Virtual Reality In Aerospace Market Restraints

Several factors can act as restraints or challenges for the Augmented Reality And Virtual Reality In Aerospace Market. These may include:

High Implementation Costs: There are a lot of upfront expenses associated with implementing AR and VR technologies in aerospace applications. These costs include software development, hardware acquisition, training, and system integration. Some aerospace companies may be discouraged from adopting AR and VR solutions due to the large initial investment necessary, especially smaller organizations or those operating on limited budgets.

Technological Complexity: The creation, deployment, and maintenance of AR and VR technologies call for specific knowledge due to their complexity. It can be difficult to integrate AR and VR systems with current aerospace systems, such as cockpit displays, training simulators, and aircraft maintenance, because of compatibility problems, interoperability issues, and regulatory constraints. In the aerospace sector, technological complexity could hinder the scalability and adoption of AR and VR solutions.

Concerns about Safety and Certification: In the aerospace sector, safety is of utmost importance. To guarantee conformity with industry best practices and regulatory standards, all new technologies must go through stringent testing, validation, and certification procedures. Aviation authorities must approve AR and VR systems that are used for pilot training, aircraft maintenance, and operational support. These systems must also adhere to strict safety standards. Concerns about safety and certification may cause development times and prices to rise for AR and VR applications in the aircraft industry.

Risks to Data Security and Privacy: AR and VR systems in the aerospace sector have the potential to gather, handle, and send sensitive data, such as operational data, maintenance logs, and aircraft performance data. To stop illegal access, data breaches, and cyberattacks that could jeopardize aircraft safety and operational integrity, it is imperative to protect data security and privacy. Strong cybersecurity protections, encryption procedures, and adherence to data protection laws like the CCPA and GDPR are necessary to address risks to data security and privacy.

Restricted Variety of Content and Apps: Compared to other industries, the aerospace sector may have less content and apps designed for augmented reality and virtual reality. Specialized content development tools and domain-specific knowledge are needed to create interactive cockpit displays, virtual maintenance processes, and immersive training simulations. The absence of varied and adaptable AR and VR applications could impede their uptake and restrict their potential in flight operations.

Resistance to Change and Training Needs: Stakeholders used to traditional aerospace workflows may be resistant to the introduction of AR and VR technology. To use AR and VR technologies for maintenance, inspection, and training, employees might need to be retrained or trained. Adopting and utilizing AR and VR technology in aircraft operations requires overcoming opposition to change and resolving training requirements.

Integration with Legacy Systems: For the design, manufacture, maintenance, and operation of aircraft, aerospace businesses frequently rely on proprietary software and legacy systems. The integration of AR and VR technologies with legacy systems may present obstacles to data interchange, compatibility, and interoperability. Careful planning, customization, and cooperation with software providers and system integrators are necessary when retrofitting current aircraft systems to accommodate AR and VR functions.

Limited Market Education and Awareness: Despite the potential advantages of AR and VR in aerospace applications, regulators, decision-makers, and aerospace experts may not be as knowledgeable about these technologies as they should be. Driving market adoption, investment, and innovation requires educating stakeholders on the potential, advantages, and constraints of AR and VR technology in aerospace operations.

Global Augmented Reality And Virtual Reality In Aerospace Market Segmentation Analysis

The Global Augmented Reality And Virtual Reality In Aerospace Market is Segmented on the basis of Technology Type, Application, End-User, and Geography.

Augmented Reality And Virtual Reality In Aerospace Market, By Technology Type

• Augmented Reality (AR): Technology that overlays digital information, such as graphics, text, or animations, onto the real-world environment, enhancing the user's perception and interaction with physical objects.
• Virtual Reality (VR): Technology that immerses users in a simulated, computer-generated environment, allowing for interactive experiences and simulations that can be used for training, design, and visualization.

Augmented Reality And Virtual Reality In Aerospace Market, By Application

• Training and Simulation: AR/VR technologies are used for training pilots, maintenance technicians, and ground crews through immersive simulations of flight operations, maintenance procedures, emergency scenarios, and cockpit familiarization.
• Design and Prototyping: AR/VR technologies are used for designing and prototyping aircraft components, cabin interiors, and cockpit layouts, enabling engineers and designers to visualize and iterate on designs in a virtual environment.
• Maintenance, Repair, and Overhaul (MRO): AR/VR technologies are used to assist maintenance technicians in performing inspections, repairs, and troubleshooting tasks by providing digital overlays of technical data, instructions, and schematics overlaid onto physical aircraft components.
• Remote Assistance: AR technologies are used for providing remote assistance and support to field technicians and maintenance crews by enabling experts to visualize and guide maintenance procedures and troubleshooting tasks in real time.
• Flight Operations: AR technologies are used for enhancing situational awareness and decision-making during flight operations by overlaying navigation data, flight parameters, and alerts onto the pilot's field of view.
• Passenger Experience: AR/VR technologies are used to enhance the passenger experience through interactive entertainment, virtual tours, and personalized services during flight.

Augmented Reality And Virtual Reality In Aerospace Market, By End-User

• Commercial Aviation: AR/VR technologies are used by commercial airlines, aircraft manufacturers, and MRO service providers for training, design, maintenance, and passenger experience applications.
• Military and Defense: AR/VR technologies are used by military organizations, defense contractors, and aerospace companies for pilot training, mission planning, simulation, and maintenance of military aircraft and systems.
• General Aviation: AR/VR technologies are used by general aviation pilots, flight schools, and small aircraft manufacturers for training, navigation, and cockpit instrumentation.
• Space Exploration: AR/VR technologies are used by space agencies, aerospace companies, and researchers for astronaut training, mission planning, simulation, and public engagement in space exploration initiatives.

Augmented Reality And Virtual Reality In Aerospace Market, By Geography

• North America: The AR/VR in aerospace market in North America is driven by factors such as technological innovation, the strong presence of aerospace industry players, government investments in defense and space programs, and demand for advanced training and simulation solutions.
• Europe: Europe has a significant market for AR/VR in aerospace, with demand driven by aerospace manufacturing hubs, defense contracts, and investments in research and development of next-generation aviation technologies.
• Asia-Pacific: The Asia-Pacific region is experiencing growth in the AR/VR in the aerospace market due to increasing investments in commercial aviation, defense modernization programs, and the adoption of advanced training and simulation technologies.
• Rest of the World: These regions offer opportunities for market growth due to expanding aviation industries, infrastructure development, and demand for training and simulation solutions in defense and commercial sectors.

Key Players

• The major players in the Augmented Reality And Virtual Reality In Aerospace Market are:
• Microsoft Corporation (US)
• Google Inc. (US)
• Eon Reality (US)
• Aero Glass (US)
• Upskill (US)
• Oculus VR (US)
• Jasoren (US)
• IMB (US)
• Fountx (Australia)
• Sony (Japan)

TABLE OF CONTENTS

1. Introduction

• Market Definition
• Market Segmentation
• Research Methodology

2. Executive Summary

• Key Findings
• Market Overview
• Market Highlights

3. Market Overview

• Market Size and Growth Potential
• Market Trends
• Market Drivers
• Market Restraints
• Market Opportunities
• Porter's Five Forces Analysis

4. Augmented Reality And Virtual Reality In Aerospace Market, By Technology Type

• Augmented Reality (AR)
• Virtual Reality (VR)

5. Augmented Reality And Virtual Reality In Aerospace Market, By Application

• Training and Simulation
• Design and Prototyping
• Maintenance, Repair, and Overhaul (MRO)
• Remote Assistance
• Flight Operations
• Passenger Experience

6. Augmented Reality And Virtual Reality In Aerospace Market, By End-User

• Commercial Aviation
• Military and Defense
• General Aviation
• Space Exploration

7. Regional Analysis

• North America
• United States
• Canada
• Mexico
• Europe
• United Kingdom
• Germany
• France
• Italy
• Asia-Pacific
• China
• Japan
• India
• Australia
• Latin America
• Brazil
• Argentina
• Chile
• Middle East and Africa
• South Africa
• Saudi Arabia
• UAE

8. Market Dynamics

• Market Drivers
• Market Restraints
• Market Opportunities
• Impact of COVID-19 on the Market

9. Competitive Landscape

• Key Players
• Market Share Analysis

10. Company Profiles

• Microsoft Corporation (US)
• Google Inc. (US)
• Eon Reality (US)
• Aero Glass (US)
• Upskill (US)
• Oculus VR (US)
• Jasoren (US)
• IMB (US)
• Fountx (Australia)
• Sony (Japan)

11. Market Outlook and Opportunities

• Emerging Technologies
• Future Market Trends
• Investment Opportunities

12. Appendix

• List of Abbreviations
• Sources and References