Unmanned Aerial Vehicles Simulation Market By Component, By Drone Type, By End Use: Global Opportunity Analysis and Industry Forecast, 2021-2031

Table of Contents

CHAPTER 1: INTRODUCTION
1.1. Report description
1.2. Key market segments
1.3. Key benefits to the stakeholders
1.4. Research Methodology
1.4.1. Secondary research
1.4.2. Primary research
1.4.3. Analyst tools and models

CHAPTER 2: EXECUTIVE SUMMARY
2.1. Key findings of the study
2.2. CXO Perspective

CHAPTER 3: MARKET OVERVIEW
3.1. Market definition and scope
3.2. Key findings
3.2.1. Top investment pockets
3.3. Porter’s five forces analysis
3.4. Top player positioning
3.5. Market dynamics
3.5.1. Drivers
3.5.2. Restraints
3.5.3. Opportunities
3.6. COVID-19 Impact Analysis on the market

CHAPTER 4: UNMANNED AERIAL VEHICLES (UAVS) SIMULATION MARKET, BY COMPONENT
4.1 Overview
4.1.1 Market size and forecast
4.2 Hardware
4.2.1 Key market trends, growth factors and opportunities
4.2.2 Market size and forecast, by region
4.2.3 Market analysis by country
4.3 Software
4.3.1 Key market trends, growth factors and opportunities
4.3.2 Market size and forecast, by region
4.3.3 Market analysis by country

CHAPTER 5: UNMANNED AERIAL VEHICLES (UAVS) SIMULATION MARKET, BY DRONE TYPE
5.1 Overview
5.1.1 Market size and forecast
5.2 Fixed wing
5.2.1 Key market trends, growth factors and opportunities
5.2.2 Market size and forecast, by region
5.2.3 Market analysis by country
5.3 Rotary wing
5.3.1 Key market trends, growth factors and opportunities
5.3.2 Market size and forecast, by region
5.3.3 Market analysis by country

CHAPTER 6: UNMANNED AERIAL VEHICLES (UAVS) SIMULATION MARKET, BY END USE
6.1 Overview
6.1.1 Market size and forecast
6.2 Military
6.2.1 Key market trends, growth factors and opportunities
6.2.2 Market size and forecast, by region
6.2.3 Market analysis by country
6.3 Civil and Commercial
6.3.1 Key market trends, growth factors and opportunities
6.3.2 Market size and forecast, by region
6.3.3 Market analysis by country

CHAPTER 7: UNMANNED AERIAL VEHICLES (UAVS) SIMULATION MARKET, BY REGION
7.1 Overview
7.1.1 Market size and forecast
7.2 North America
7.2.1 Key trends and opportunities
7.2.2 North America Market size and forecast, by Component
7.2.3 North America Market size and forecast, by Drone Type
7.2.4 North America Market size and forecast, by End Use
7.2.5 North America Market size and forecast, by country
7.2.5.1 U. S.
7.2.5.1.1 Market size and forecast, by Component
7.2.5.1.2 Market size and forecast, by Drone Type
7.2.5.1.3 Market size and forecast, by End Use
7.2.5.2 Canada
7.2.5.2.1 Market size and forecast, by Component
7.2.5.2.2 Market size and forecast, by Drone Type
7.2.5.2.3 Market size and forecast, by End Use
7.2.5.3 Mexico
7.2.5.3.1 Market size and forecast, by Component
7.2.5.3.2 Market size and forecast, by Drone Type
7.2.5.3.3 Market size and forecast, by End Use
7.3 Europe
7.3.1 Key trends and opportunities
7.3.2 Europe Market size and forecast, by Component
7.3.3 Europe Market size and forecast, by Drone Type
7.3.4 Europe Market size and forecast, by End Use
7.3.5 Europe Market size and forecast, by country
7.3.5.1 Germany
7.3.5.1.1 Market size and forecast, by Component
7.3.5.1.2 Market size and forecast, by Drone Type
7.3.5.1.3 Market size and forecast, by End Use
7.3.5.2 UK
7.3.5.2.1 Market size and forecast, by Component
7.3.5.2.2 Market size and forecast, by Drone Type
7.3.5.2.3 Market size and forecast, by End Use
7.3.5.3 France
7.3.5.3.1 Market size and forecast, by Component
7.3.5.3.2 Market size and forecast, by Drone Type
7.3.5.3.3 Market size and forecast, by End Use
7.3.5.4 Italy
7.3.5.4.1 Market size and forecast, by Component
7.3.5.4.2 Market size and forecast, by Drone Type
7.3.5.4.3 Market size and forecast, by End Use
7.3.5.5 Rest of Europe
7.3.5.5.1 Market size and forecast, by Component
7.3.5.5.2 Market size and forecast, by Drone Type
7.3.5.5.3 Market size and forecast, by End Use
7.4 Asia-Pacific
7.4.1 Key trends and opportunities
7.4.2 Asia-Pacific Market size and forecast, by Component
7.4.3 Asia-Pacific Market size and forecast, by Drone Type
7.4.4 Asia-Pacific Market size and forecast, by End Use
7.4.5 Asia-Pacific Market size and forecast, by country
7.4.5.1 China
7.4.5.1.1 Market size and forecast, by Component
7.4.5.1.2 Market size and forecast, by Drone Type
7.4.5.1.3 Market size and forecast, by End Use
7.4.5.2 Japan
7.4.5.2.1 Market size and forecast, by Component
7.4.5.2.2 Market size and forecast, by Drone Type
7.4.5.2.3 Market size and forecast, by End Use
7.4.5.3 India
7.4.5.3.1 Market size and forecast, by Component
7.4.5.3.2 Market size and forecast, by Drone Type
7.4.5.3.3 Market size and forecast, by End Use
7.4.5.4 South Korea
7.4.5.4.1 Market size and forecast, by Component
7.4.5.4.2 Market size and forecast, by Drone Type
7.4.5.4.3 Market size and forecast, by End Use
7.4.5.5 Rest of Asia-Pacific
7.4.5.5.1 Market size and forecast, by Component
7.4.5.5.2 Market size and forecast, by Drone Type
7.4.5.5.3 Market size and forecast, by End Use
7.5 LAMEA
7.5.1 Key trends and opportunities
7.5.2 LAMEA Market size and forecast, by Component
7.5.3 LAMEA Market size and forecast, by Drone Type
7.5.4 LAMEA Market size and forecast, by End Use
7.5.5 LAMEA Market size and forecast, by country
7.5.5.1 Latin America
7.5.5.1.1 Market size and forecast, by Component
7.5.5.1.2 Market size and forecast, by Drone Type
7.5.5.1.3 Market size and forecast, by End Use
7.5.5.2 Middle East
7.5.5.2.1 Market size and forecast, by Component
7.5.5.2.2 Market size and forecast, by Drone Type
7.5.5.2.3 Market size and forecast, by End Use
7.5.5.3 Africa
7.5.5.3.1 Market size and forecast, by Component
7.5.5.3.2 Market size and forecast, by Drone Type
7.5.5.3.3 Market size and forecast, by End Use

CHAPTER 8: COMPANY LANDSCAPE
8.1. Introduction
8.2. Top winning strategies
8.3. Product Mapping of Top 10 Players
8.4. Competitive Dashboard
8.5. Competitive Heatmap
8.6. Key developments

CHAPTER 9: COMPANY PROFILES
9.1 SIMLAT UAS SIMULATION
9.1.1 Company overview
9.1.2 Company snapshot
9.1.3 Operating business segments
9.1.4 Product portfolio
9.1.5 Business performance
9.1.6 Key strategic moves and developments
9.2 SINGAPORE TECHNOLOGIES ELECTRONICS LIMITED
9.2.1 Company overview
9.2.2 Company snapshot
9.2.3 Operating business segments
9.2.4 Product portfolio
9.2.5 Business performance
9.2.6 Key strategic moves and developments
9.3 BLUEHALO
9.3.1 Company overview
9.3.2 Company snapshot
9.3.3 Operating business segments
9.3.4 Product portfolio
9.3.5 Business performance
9.3.6 Key strategic moves and developments
9.4 Quantum3D
9.4.1 Company overview
9.4.2 Company snapshot
9.4.3 Operating business segments
9.4.4 Product portfolio
9.4.5 Business performance
9.4.6 Key strategic moves and developments
9.5 Raytheon Technologies
9.5.1 Company overview
9.5.2 Company snapshot
9.5.3 Operating business segments
9.5.4 Product portfolio
9.5.5 Business performance
9.5.6 Key strategic moves and developments
9.6 L3Harris Technologies, Inc.
9.6.1 Company overview
9.6.2 Company snapshot
9.6.3 Operating business segments
9.6.4 Product portfolio
9.6.5 Business performance
9.6.6 Key strategic moves and developments
9.7 CAE Inc.
9.7.1 Company overview
9.7.2 Company snapshot
9.7.3 Operating business segments
9.7.4 Product portfolio
9.7.5 Business performance
9.7.6 Key strategic moves and developments
9.8 General Atomics Aeronautical Systems, Inc.
9.8.1 Company overview
9.8.2 Company snapshot
9.8.3 Operating business segments
9.8.4 Product portfolio
9.8.5 Business performance
9.8.6 Key strategic moves and developments
9.9 Israel Aerospace Industries Ltd.
9.9.1 Company overview
9.9.2 Company snapshot
9.9.3 Operating business segments
9.9.4 Product portfolio
9.9.5 Business performance
9.9.6 Key strategic moves and developments
9.10 Leonardo S. p. A.
9.10.1 Company overview
9.10.2 Company snapshot
9.10.3 Operating business segments
9.10.4 Product portfolio
9.10.5 Business performance
9.10.6 Key strategic moves and developments
9.11 HAVELSAN A. S.
9.11.1 Company overview
9.11.2 Company snapshot
9.11.3 Operating business segments
9.11.4 Product portfolio
9.11.5 Business performance
9.11.6 Key strategic moves and developments
9.12 Indra Sistema
9.12.1 Company overview
9.12.2 Company snapshot
9.12.3 Operating business segments
9.12.4 Product portfolio
9.12.5 Business performance
9.12.6 Key strategic moves and developments

Executive Summary

According to this report, titled, 'Unmanned Aerial Vehicles (UAVs) Simulation Market,' the unmanned aerial vehicles (UAVs) simulation market was valued at $0.6 billion in 2021, and is estimated to reach $2.5 billion by 2031, growing at a CAGR of 14.6% from 2022 to 2031.

North America is expected to dominate the global unmanned aerial vehicles simulation market. The region has seen a significant surge in the use of advanced UAVs simulation technologies to reduce human labor and improve output quality in military and agriculture sector. The North American countries are investing heavily toward the advancement of UAVs simulation to augment the performance of their operations and improve the time management in security and supply chain. The increase in investment by the North American countries propel the development of advanced drone equipment and software across the North American region.

Helicopter drones can carry a wide variety of payloads, including daytime and IR cameras, environmental sensors, LiDAR scanning systems and radio relay equipment, as well as missiles and other offensive capabilities. In addition, companies are introducing virtual reality based simulation systems to reduce the training period of pilot, supplementing the growth of the UAV simulation market. For instance, in 2021, Indra developed a virtual reality-based simulation system, namely, SIMCUI. It is a new multi-purpose and inter-operable simulation system which can halve the time required to train a civil or military pilot of any type of plane or unmanned aerial vehicles.

The global unmanned aerial vehicles (UAVs) simulation market is experiencing growth, due to rising adoption of UAVs in military and commercial applications, and less number of skilled and trained pilots. However, high cost of UAV simulation systems hampers the growth of the market. Furthermore, rise in defense expenditure globally, and contracts & agreements with military forces are expected to offer growth opportunities during the forecast period.

COVID-19 Impact Analysis

The spread of the COVID-19 pandemic has impacted the global unmanned aerial vehicle (UAV) simulation market, owing to disruption in the supply chain, tighten budgets of the end users and is expected to weaken the financial performance of the market players in 2020. In addition, governments of several countries such as the U.S. and Canada have maintained their defense spending levels. For instance, the U.S. defense spending reached $778 billion in 2020, with a yearly increase on 4.4%. This led numerous UAV manufacturers, weapon and combat system manufacturers to expedite the procurement rate of simulation systems.

Various countries with the foundations of a drone-friendly environment, such as the U.S., the UK, China, Germany, and others, were able to quickly mobilize the technology from the start of the pandemic. These countries were able to incorporate unmanned aerial vehicle (UAV) into the COVID-19 response activities, due to enabling factors such as favourable regulations, skilled workforce, presence of vital resources, high adoption, and others.

KEY FINDINGS OF THE STUDY

By component, the software segment is anticipated to exhibit significant growth in the near future.

By drone type, the rotary wing segment is anticipated to exhibit significant growth in the near future.

By end-use, the civil and commercial segment is anticipated to exhibit significant growth in the near future.

By region, Asia-Pacific is anticipated to register the highest CAGR during the forecast period.

Key players operating in the global unmanned aerial vehicle (UAV) simulation market include Bluehalo, CAE Inc., General Atomic Aeronautical System Inc., Havelsan A.S., Indra Sistemas, Israel Aerospace Industries Ltd., Leonardo S.P.A, L3Harris Technologies Inc., Quantum 3D, Raytheon Technologies Corporation, Simlat UAS Simulation, and Singapore Technologies Electronic Limited.

Companies Mentioned

• Simlat UAS Simulation
• Singapore Technologies Electronics Limited
• Bluehalo
• Quantum3D
• Raytheon Technologies
• L3Harris Technologies, Inc.
• Cae Inc.
• General Atomics Aeronautical Systems, Inc.
• Israel Aerospace Industries Ltd.
• Leonardo S.P.A.
• Havelsan A.S.
• Indra Sistema

Methodology

The analyst offers exhaustive research and analysis based on a wide variety of factual inputs, which largely include interviews with industry participants, reliable statistics, and regional intelligence. The in-house industry experts play an instrumental role in designing analytic tools and models, tailored to the requirements of a particular industry segment. The primary research efforts include reaching out participants through mail, tele-conversations, referrals, professional networks, and face-to-face interactions.

They are also in professional corporate relations with various companies that allow them greater flexibility for reaching out to industry participants and commentators for interviews and discussions.

They also refer to a broad array of industry sources for their secondary research, which typically include; however, not limited to:

• Company SEC filings, annual reports, company websites, broker & financial reports, and investor presentations for competitive scenario and shape of the industry
• Scientific and technical writings for product information and related preemptions
• Regional government and statistical databases for macro analysis
• Authentic news articles and other related releases for market evaluation
• Internal and external proprietary databases, key market indicators, and relevant press releases for market estimates and forecast

Furthermore, the accuracy of the data will be analyzed and validated by conducting additional primaries with various industry experts and KOLs. They also provide robust post-sales support to clients.