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. Primary research
1.4.2. Secondary research
1.4.3. Analyst tools and models
CHAPTER 2: EXECUTIVE SUMMARY
2.1. CXO perspective
CHAPTER 3: MARKET OVERVIEW
3.1. Market definition and scope
3.2. Key findings
3.2.1. Top impacting factors
3.2.2. Top investment pockets
3.3. Porter’s five forces analysis
3.3.1. Low bargaining power of suppliers
3.3.2. Low threat of new entrants
3.3.3. Low threat of substitutes
3.3.4. Low intensity of rivalry
3.3.5. Low bargaining power of buyers
3.4. Market dynamics
3.4.1. Drivers
3.4.1.1. Surge in defense budget
3.4.1.2. Increase in demand for enhanced survivability and effectiveness in combat
3.4.1.3. Rise in geopolitical tension
3.4.2. Restraints
3.4.2.1. High development and maintenance costs
3.4.2.2. Technical challenges and limitations
3.4.3. Opportunities
3.4.3.1. Technological advancement
CHAPTER 4: STEALTH TECHNOLOGY MARKET, BY PLATFORM
4.1. Overview
4.1.1. Market size and forecast
4.2. Airborne
4.2.1. Key market trends, growth factors and opportunities
4.2.2. Market size and forecast, by region
4.2.3. Market share analysis by country
4.3. Naval
4.3.1. Key market trends, growth factors and opportunities
4.3.2. Market size and forecast, by region
4.3.3. Market share analysis by country
4.4. Land
4.4.1. Key market trends, growth factors and opportunities
4.4.2. Market size and forecast, by region
4.4.3. Market share analysis by country
CHAPTER 5: STEALTH TECHNOLOGY MARKET, BY TECHNOLOGY
5.1. Overview
5.1.1. Market size and forecast
5.2. Radar Cross Section
5.2.1. Key market trends, growth factors and opportunities
5.2.2. Market size and forecast, by region
5.2.3. Market share analysis by country
5.3. Plasma Cloud
5.3.1. Key market trends, growth factors and opportunities
5.3.2. Market size and forecast, by region
5.3.3. Market share analysis by country
5.4. IR Signature Emission
5.4.1. Key market trends, growth factors and opportunities
5.4.2. Market size and forecast, by region
5.4.3. Market share analysis by country
5.5. Radar Emission
5.5.1. Key market trends, growth factors and opportunities
5.5.2. Market size and forecast, by region
5.5.3. Market share analysis by country
5.6. Acoustic Emission
5.6.1. Key market trends, growth factors and opportunities
5.6.2. Market size and forecast, by region
5.6.3. Market share analysis by country
5.7. RF Emission
5.7.1. Key market trends, growth factors and opportunities
5.7.2. Market size and forecast, by region
5.7.3. Market share analysis by country
5.8. Others
5.8.1. Key market trends, growth factors and opportunities
5.8.2. Market size and forecast, by region
5.8.3. Market share analysis by country
CHAPTER 6: STEALTH TECHNOLOGY MARKET, BY MATERIAL
6.1. Overview
6.1.1. Market size and forecast
6.2. Radar Absorbent Materials
6.2.1. Key market trends, growth factors and opportunities
6.2.2. Market size and forecast, by region
6.2.3. Market share analysis by country
6.3. Non-metallic/Metallic Coating
6.3.1. Key market trends, growth factors and opportunities
6.3.2. Market size and forecast, by region
6.3.3. Market share analysis by country
CHAPTER 7: STEALTH TECHNOLOGY MARKET, BY REGION
7.1. Overview
7.1.1. Market size and forecast By Region
7.2. North America
7.2.1. Key market trends, growth factors and opportunities
7.2.2. Market size and forecast, by Platform
7.2.3. Market size and forecast, by Technology
7.2.4. Market size and forecast, by Material
7.2.5. Market size and forecast, by country
7.2.5.1. U.S.
7.2.5.1.1. Market size and forecast, by Platform
7.2.5.1.2. Market size and forecast, by Technology
7.2.5.1.3. Market size and forecast, by Material
7.2.5.2. Canada
7.2.5.2.1. Market size and forecast, by Platform
7.2.5.2.2. Market size and forecast, by Technology
7.2.5.2.3. Market size and forecast, by Material
7.2.5.3. Mexico
7.2.5.3.1. Market size and forecast, by Platform
7.2.5.3.2. Market size and forecast, by Technology
7.2.5.3.3. Market size and forecast, by Material
7.3. Europe
7.3.1. Key market trends, growth factors and opportunities
7.3.2. Market size and forecast, by Platform
7.3.3. Market size and forecast, by Technology
7.3.4. Market size and forecast, by Material
7.3.5. Market size and forecast, by country
7.3.5.1. UK
7.3.5.1.1. Market size and forecast, by Platform
7.3.5.1.2. Market size and forecast, by Technology
7.3.5.1.3. Market size and forecast, by Material
7.3.5.2. Germany
7.3.5.2.1. Market size and forecast, by Platform
7.3.5.2.2. Market size and forecast, by Technology
7.3.5.2.3. Market size and forecast, by Material
7.3.5.3. France
7.3.5.3.1. Market size and forecast, by Platform
7.3.5.3.2. Market size and forecast, by Technology
7.3.5.3.3. Market size and forecast, by Material
7.3.5.4. Italy
7.3.5.4.1. Market size and forecast, by Platform
7.3.5.4.2. Market size and forecast, by Technology
7.3.5.4.3. Market size and forecast, by Material
7.3.5.5. Russia
7.3.5.5.1. Market size and forecast, by Platform
7.3.5.5.2. Market size and forecast, by Technology
7.3.5.5.3. Market size and forecast, by Material
7.3.5.6. Turkey
7.3.5.6.1. Market size and forecast, by Platform
7.3.5.6.2. Market size and forecast, by Technology
7.3.5.6.3. Market size and forecast, by Material
7.3.5.7. Rest of Europe
7.3.5.7.1. Market size and forecast, by Platform
7.3.5.7.2. Market size and forecast, by Technology
7.3.5.7.3. Market size and forecast, by Material
7.4. Asia-Pacific
7.4.1. Key market trends, growth factors and opportunities
7.4.2. Market size and forecast, by Platform
7.4.3. Market size and forecast, by Technology
7.4.4. Market size and forecast, by Material
7.4.5. Market size and forecast, by country
7.4.5.1. China
7.4.5.1.1. Market size and forecast, by Platform
7.4.5.1.2. Market size and forecast, by Technology
7.4.5.1.3. Market size and forecast, by Material
7.4.5.2. Japan
7.4.5.2.1. Market size and forecast, by Platform
7.4.5.2.2. Market size and forecast, by Technology
7.4.5.2.3. Market size and forecast, by Material
7.4.5.3. India
7.4.5.3.1. Market size and forecast, by Platform
7.4.5.3.2. Market size and forecast, by Technology
7.4.5.3.3. Market size and forecast, by Material
7.4.5.4. South Korea
7.4.5.4.1. Market size and forecast, by Platform
7.4.5.4.2. Market size and forecast, by Technology
7.4.5.4.3. Market size and forecast, by Material
7.4.5.5. Rest of Asia-Pacific
7.4.5.5.1. Market size and forecast, by Platform
7.4.5.5.2. Market size and forecast, by Technology
7.4.5.5.3. Market size and forecast, by Material
7.5. LAMEA
7.5.1. Key market trends, growth factors and opportunities
7.5.2. Market size and forecast, by Platform
7.5.3. Market size and forecast, by Technology
7.5.4. Market size and forecast, by Material
7.5.5. Market size and forecast, by country
7.5.5.1. Latin America
7.5.5.1.1. Market size and forecast, by Platform
7.5.5.1.2. Market size and forecast, by Technology
7.5.5.1.3. Market size and forecast, by Material
7.5.5.2. Middle East
7.5.5.2.1. Market size and forecast, by Platform
7.5.5.2.2. Market size and forecast, by Technology
7.5.5.2.3. Market size and forecast, by Material
7.5.5.3. Africa
7.5.5.3.1. Market size and forecast, by Platform
7.5.5.3.2. Market size and forecast, by Technology
7.5.5.3.3. Market size and forecast, by Material
CHAPTER 8: COMPETITIVE LANDSCAPE
8.1. Introduction
8.2. Top winning strategies
8.3. Product mapping of top 10 player
8.4. Competitive dashboard
8.5. Competitive heatmap
8.6. Top player positioning, 2023
CHAPTER 9: COMPANY PROFILES
9.1. BAE Systems
9.1.1. Company overview
9.1.2. Key executives
9.1.3. Company snapshot
9.1.4. Operating business segments
9.1.5. Product portfolio
9.1.6. Business performance
9.2. Northrop Grumman
9.2.1. Company overview
9.2.2. Key executives
9.2.3. Company snapshot
9.2.4. Operating business segments
9.2.5. Product portfolio
9.2.6. Business performance
9.3. Saab
9.3.1. Company overview
9.3.2. Key executives
9.3.3. Company snapshot
9.3.4. Operating business segments
9.3.5. Product portfolio
9.3.6. Business performance
9.3.7. Key strategic moves and developments
9.4. Boeing
9.4.1. Company overview
9.4.2. Key executives
9.4.3. Company snapshot
9.4.4. Operating business segments
9.4.5. Product portfolio
9.4.6. Business performance
9.4.7. Key strategic moves and developments
9.5. General Dynamics Corporation
9.5.1. Company overview
9.5.2. Key executives
9.5.3. Company snapshot
9.5.4. Operating business segments
9.5.5. Product portfolio
9.5.6. Business performance
9.6. Leonardo S.p.A.
9.6.1. Company overview
9.6.2. Key executives
9.6.3. Company snapshot
9.6.4. Operating business segments
9.6.5. Product portfolio
9.6.6. Business performance
9.7. Thales
9.7.1. Company overview
9.7.2. Key executives
9.7.3. Company snapshot
9.7.4. Operating business segments
9.7.5. Product portfolio
9.7.6. Business performance
9.8. FACC AG
9.8.1. Company overview
9.8.2. Key executives
9.8.3. Company snapshot
9.8.4. Operating business segments
9.8.5. Product portfolio
9.8.6. Business performance
9.9. Lockheed Martin Corporation
9.9.1. Company overview
9.9.2. Key executives
9.9.3. Company snapshot
9.9.4. Operating business segments
9.9.5. Product portfolio
9.9.6. Business performance
9.9.7. Key strategic moves and developments
9.10. Kratos Defense & Security Solutions, Inc.
9.10.1. Company overview
9.10.2. Key executives
9.10.3. Company snapshot
9.10.4. Operating business segments
9.10.5. Product portfolio
9.10.6. Business performance
9.11. BAYKAR TECH
9.11.1. Company overview
9.11.2. Key executives
9.11.3. Company snapshot
9.11.4. Operating business segments
9.11.5. Product portfolio
9.12. Sukhoi
9.12.1. Company overview
9.12.2. Key executives
9.12.3. Company snapshot
9.12.4. Operating business segments
9.12.5. Product portfolio
9.13. RTX
9.13.1. Company overview
9.13.2. Key executives
9.13.3. Company snapshot
9.13.4. Operating business segments
9.13.5. Product portfolio
9.13.6. Business performance
ステルス技術の世界市場2023-2033 |
【英語タイトル】Stealth Technology Market Size, Share, Competitive Landscape and Trend Analysis Report, by Platform, by Technology, by Material : Global Opportunity Analysis and Industry Forecast, 2023 - 2033 | |
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ステルス技術の主な目的は、軍事資産(航空機、艦船、潜水艦、ミサイルなど)の“シグネチャ(探知可能な痕跡)”を低減し、敵のセンサーによる探知・追跡・攻撃を困難にすることにあります。ステルス技術は、対象物の表面形状を工夫し、レーダー波を吸収・散乱させてレーダー反射断面積(RCS)を減らすことで可視性を下げ、特殊な塗料や素材を用いて周囲に溶け込ませることで肉眼からの視認も抑制します。 近年注目される技術の一つが「プラズマステルス」で、これはイオン化されたガス(プラズマ)を対象物の周囲に発生させることで、レーダー波の吸収や屈折、さらには周波数の変換までも可能にするという新しいアプローチです。従来の形状や素材に依存する方法と異なり、リアルタイムで調整可能な柔軟性が特徴です。2024年には中国の研究者が航空機に適用可能なプラズマステルス技術の開発を発表し、業界に大きな衝撃を与えました。 また、赤外線(IR)シグネチャの低減も極めて重要です。赤外線センサーは対象物の熱放射を検出するため、これを抑えることでステルス性能をさらに高められます。これには高度な素材、塗料、熱管理システムが活用され、特に現代の赤外線技術が高度化する中で、生存性を維持するための鍵となります。米海軍は2020年に、バージニア級潜水艦にSWIR(短波赤外線)センサー搭載のフォトニクスマストを導入し、霧や煙の中でも探知を回避できる能力を強化しました。 さらに、レーダー放射の管理もステルス性に直結します。敵レーダーへの露出を減らすため、自己のレーダー放射を抑制または制御する技術が重視されています。例えば、2023年にはロシア国営企業Rostecが金属芯入りガラス繊維を用いた新たなステルス素材を発表し、レーダー波の最大95%を吸収する能力を備えており、航空機のRCS低減に大きく寄与しています。 このような多様な技術領域にまたがるステルス技術市場は、プラットフォーム別(航空・艦船・陸上)、技術別(RCS低減、プラズマクラウド、IR・レーダー・音響・RF放射制御など)、素材別(レーダー吸収材、金属・非金属コーティング)で構成され、地域別には北米、欧州、アジア太平洋、LAMEA(中東・アフリカ・中南米)に分類されます。 主な企業には、Lockheed Martin、Northrop Grumman、BAE Systems、Raytheon、Boeing、General Dynamics、Leonardo、Thales、サーブ、スホーイ、Baykarなどが含まれます。市場は今後も各国の軍事近代化やセンサー技術の高度化に対応する形で拡大が見込まれ、2023年から2033年までの市場動向、機会、課題を定量的・定性的に評価するためのレポートも発行されています。これにより、関係者は効果的な意思決定や戦略策定が可能となるでしょう。 |
The primary goal of stealth technology is to reduce the signature of an object, making it difficult for enemy sensors to detect, track, and engage it effectively. Stealth technology aims to reduce the radar cross section (RCS) of an object by shaping its surfaces to scatter radar waves away from the radar receiver, rather than reflecting them back. This often involves using smooth, curved surfaces and special coatings to absorb or deflect radar energy. Stealth technology also considers reducing the visibility of an object to the naked eye, which involves using specialized paints, colors, and materials to minimize reflection and blending the object with its surroundings.
A plasma cloud is a stealth technology that includes the collection of ionized gas containing free electrons and ions. Often referred to as the fourth state of matter, plasma is created by heating a gas or subjecting it to a strong electromagnetic field, energizing the atoms and causing them to lose electrons. This state of matter is characterized by high electrical conductivity, responsiveness to magnetic and electric fields, and the ability to emit light. Unlike traditional stealth technologies that rely on specific shapes and materials to deflect radar waves, plasma stealth offers dynamic adjustability. The plasma field can be controlled and modulated in real-time to counter various radar frequencies and detection systems.
Recent advancements in plasma generation and control technologies have made it possible to create stable and controllable plasma fields on aircraft surfaces. For instance, in February 2024, Chinese scientists claimed that they developed plasma stealth technology, which could revolutionize the design and capabilities of stealth aircraft. This new technology involves the use of plasma—a highly ionized gas—that can absorb, refract, or even alter the frequency of electromagnetic waves emitted by radar systems. By manipulating radar signals in this way, the plasma cluster can effectively confuse enemy radars, making it much harder for them to detect stealth aircraft. Moreover, the enhanced understanding and study of plasma physics has led to the development of more efficient and practical plasma stealth systems
IR (Infrared) Signature Emission refers to the heat and infrared radiation emitted by objects, which can be detected by infrared sensors. In the stealth technology market, minimizing IR signature emissions is crucial for reducing the visibility of military assets such as aircraft, ships, and vehicles to infrared detection systems used by adversaries. By managing and reducing these emissions, stealth technology enhances the ability of these assets to operate undetected, thereby increasing their survivability and effectiveness in hostile environments.
Techniques to reduce IR signatures include advanced materials and coatings, thermal management systems, and design strategies that dissipate heat more efficiently. These innovations are vital for maintaining a tactical advantage in modern warfare, where infrared detection and targeting systems are increasingly sophisticated. There is a growing demand for advanced stealth solutions that can minimize detection by infrared sensors. Furthermore, advancements in materials science and engineering have led to the development of innovative coatings, materials, and thermal management systems designed specifically to reduce IR signatures.
For instance, in June 2020, the U.S. Navy announced the advancement of the stealth capabilities and survivability of its Virginia-class fast-attack submarines by equipping them with improved electro-optical sensor photonics masts, specifically the Low Profile Photonics Mast (LPPM). The LPPM includes short-wave infrared (SWIR) sensors, which are adept at penetrating fog, haze, and other obscurants. These sensors help in reducing the likelihood of detection by enemy forces that might use infrared detection methods. As infrared sensors become more sophisticated and widely available, there is a greater emphasis on developing stealth solutions capable of evading detection across the full spectrum of infrared wavelengths.
Radar emission refers to the transmission of electromagnetic signals by radar systems for the purpose of detecting and tracking objects in the surrounding airspace. In the stealth technology market, radar emission plays a crucial role in both offensive and defensive capabilities. Stealth platforms utilize radar emission reduction techniques to minimize their detectability by enemy radar systems, thereby enhancing their survivability and mission effectiveness in contested environments.
By reducing radar cross-section and emission, stealth technology allows military assets such as aircraft, ships, and ground vehicles to evade detection or delay enemy engagement, providing a tactical advantage on the battlefield. As nations invest in modernizing their military capabilities, there is a growing demand for radar emission solutions that can provide superior stealth characteristics across a range of defense platforms, including aircraft, ships, and ground vehicles.
Stealth aircraft are primarily designed to minimize their Radar Cross Section (RCS) in the X-Band frequency range. For instance, in March 2023, Rostec, a Russian state corporation, through its subsidiary Ruselectronics holding, developed a new stealth material designed to significantly enhance the radar invisibility of aircraft. The new material is composed of metal-core glass filaments. This new stealth material can absorb up to 95% of incident electromagnetic radiation from radars, significantly reducing the radar cross-section (RCS) of the aircraft. Such developments are expected to drive the growth of the radar stealth technology during the forecast period.
For the purpose of analysis, the stealth technology market scope covers segmentation based on platform, technology, material, and region. The report provides information about various technology of stealth technology such as radar cross section, plasma cloud, IR signature emission, radar emission, acoustic emission, RF emission, and others. In addition, it highlights the details about the platform, including airborne, naval and land. Furthermore, radar absorbent materials, and non-metallic/ metal coating are the materials covered in the study. Moreover, it analyzes the current market trends of stealth technology across different regions such as North America, Europe, Asia-Pacific, and LAMEA and suggests future growth opportunities.
Some major companies operating in the market include BAE Systems, Northrop Grumman Corporation, Saab AB, Boeing, General Dynamics Corporation, Raytheon Company, Leonardo S.p.A, Thales Group, FACC AG, Lockheed Martin, Krartos, Baykar, and Sukhoi.
Key Benefits For Stakeholders
This report provides a quantitative analysis of the market segments, current trends, estimations, and dynamics of the stealth technology market analysis from 2023 to 2033 to identify the prevailing stealth technology market opportunities.
The market research is offered along with information related to key drivers, restraints, and opportunities.
Porter’s five forces analysis highlights the potency of buyers and suppliers to enable stakeholders make profit-oriented business decisions and strengthen their supplier-buyer network.
In-depth analysis of the stealth technology market segmentation assists to determine the prevailing market opportunities.
Major countries in each region are mapped according to their revenue contribution to the global market.
Market player positioning facilitates benchmarking and provides a clear understanding of the present position of the market players.
The report includes the analysis of the regional as well as global stealth technology market trends, key players, market segments, application areas, and market growth strategies.
Key Market Segments
By Platform
Airborne
Naval
Land
By Technology
Others
Radar Cross Section
Plasma Cloud
IR Signature Emission
Radar Emission
Acoustic Emission
RF Emission
By Material
Radar Absorbent Materials
Non-metallic/Metallic Coating
By Region
North America
U.S.
Canada
Mexico
Europe
UK
Germany
France
Italy
Russia
Turkey
Rest of Europe
Asia-Pacific
China
Japan
India
South Korea
Rest of Asia-Pacific
LAMEA
Latin America
Middle East
Africa
Key Market Players
BAE Systems
BAYKAR TECH
Boeing
FACC AG
General Dynamics Corporation
Kratos Defense & Security Solutions, Inc.
Leonardo S.p.A.
Lockheed Martin Corporation
Northrop Grumman
RTX
Saab
Sukhoi
Thales
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