세계의 자율주행 선박 시장 규모 : 제품 유형별, 서브시스템별, 유형별, 용도별 - 예측(2024-2032년)

Global Autonomous Marine Vehicle Market will witness a 5.6% CAGR between 2024 and 2032, driven by continuous innovations and launches from industry leaders. These vehicles, equipped with advanced artificial intelligence and navigation systems, are revolutionizing maritime operations in sectors such as shipping, defense, offshore energy, and scientific research. Companies are developing autonomous vessels capable of performing tasks traditionally done by manned ships, including surveillance, oceanographic research, and cargo transportation.

For instance, in November 2023, Saildrone, a pioneer in ocean data collection through autonomous vehicles, for the first time, a classification for an autonomous, uncrewed surface vehicle from the American Bureau of Shipping. The Saildrone Voyager, a 10-meter USV utilized for near-shore bathymetry and maritime security, demonstrated its reliability as a platform that enhances data collection in near-real-time across global oceans.

Leading firms are investing in cutting-edge technologies to enhance vessel autonomy, safety, and operational efficiency. This includes integrating sensor arrays, communication systems, and predictive analytics to navigate unpredictable maritime environments autonomously. As maritime industries seek to reduce operating costs, increase sustainability, and improve safety at sea, the demand for autonomous marine vehicles is expected to grow, driving further innovation and market expansion in this dynamic sector.

The overall Autonomous Marine Vehicle Industry is classified based on the product type, sub-system, type, application, and region.

The autonomous marine vehicle market is seeing increased demand for surface vehicles due to their versatility and applications in various maritime sectors. Surface autonomous vehicles, equipped with advanced navigation systems and sensors, are used for oceanographic research, environmental monitoring, surveillance, and offshore operations. They offer cost-effective solutions by eliminating the need for onboard crews while improving operational efficiency and safety at sea. As industries prioritize efficiency and sustainability, surface autonomous vehicles are becoming essential tools for data collection, maritime security, and exploring remote marine environments. This trend is driving market growth as companies innovate to meet diverse industry needs and regulatory requirements.

The Autonomous Marine Vehicle (AMV) market is experiencing heightened demand from the oil and gas industry, driven by the need to enhance operational efficiency and safety in offshore operations. AMVs, equipped with advanced navigation and sensing technologies, are deployed for pipeline inspection, offshore platform monitoring, and environmental surveys. They offer cost-effective solutions by reducing operational downtime and mitigating risks associated with manned missions in harsh marine environments. As oil and gas companies prioritize cost efficiency and environmental sustainability, the adoption of AMVs continues to grow. These autonomous vessels help optimize offshore operations while adhering to stringent safety and regulatory standards.

In Europe, there is a rising demand for Autonomous Marine Vehicles (AMVs) driven by increasing investments in marine research, environmental monitoring, and maritime security. AMVs with advanced technology, such as autonomous navigation systems and remote sensing capabilities, are crucial for conducting efficient and sustainable oceanographic surveys and inspections. European countries focusing on sustainable development and marine conservation are leveraging AMVs to enhance their capabilities in offshore energy exploration, fisheries management, and climate research. As regulations support technological advancements and industries seek to minimize environmental impact, the demand for AMVs in Europe continues to expand, fostering innovation and collaboration across the maritime sector.

Table of Contents

Chapter 1 Methodology & Scope

• 1.1 Research design
  • 1.1.1 Research approach
  • 1.1.2 Data collection methods
• 1.2 Base estimates and calculations
  • 1.2.1 Base year calculation
  • 1.2.2 Key trends for market estimates
• 1.3 Forecast model
• 1.4 Primary research & validation
  • 1.4.1 Primary sources
  • 1.4.2 Data mining sources
• 1.5 Market definitions

Chapter 2 Executive Summary

• 2.1 Industry 360° synopsis, 2021 - 2032

Chapter 3 Industry Insights

• 3.1 Industry ecosystem analysis
• 3.2 Supplier landscape
  • 3.2.1 Component suppliers
  • 3.2.2 Vehicle manufacturers
  • 3.2.3 Software developers
  • 3.2.4 System integrators
  • 3.2.5 After-sales service providers
• 3.3 Profit margin analysis
• 3.4 Technology & innovation landscape
• 3.5 Patent analysis
• 3.6 Key news & initiatives
• 3.7 Regulatory landscape
• 3.8 Impact forces
  • 3.8.1 Growth drivers
    • 3.8.1.1 Growing demand for oceanographic and environmental data
    • 3.8.1.2 Focus on maritime safety and security
    • 3.8.1.3 Applications in the oil and gas industry that relies on underwater infrastructure inspection and maintenance
    • 3.8.1.4 Advancements in sensor, AI, and autonomous navigation technology
    • 3.8.1.5 Efficiency and cost savings of AMV's
  • 3.8.2 Industry pitfalls & challenges
    • 3.8.2.1 High initial investment in developing and deploying AMVs
    • 3.8.2.2 Limited operational range and autonomy
• 3.9 Growth potential analysis
• 3.10 Porter's analysis
• 3.11 PESTEL analysis

Chapter 4 Competitive Landscape, 2023

• 4.1 Introduction
• 4.2 Company market share analysis
• 4.3 Competitive positioning matrix
• 4.4 Strategic outlook matrix

Chapter 5 Market Estimates & Forecast, By Product Type, 2021 - 2032 ($Bn, Units)

• 5.1 Key trends
• 5.2 Surface vehicles
• 5.3 Underwater vehicles

Chapter 6 Market Estimates & Forecast, By Type, 2021 - 2032 ($Bn, Units)

• 6.1 Key trends
• 6.2 Semi-Autonomous
• 6.3 Autonomous

Chapter 7 Market Estimates & Forecast, By Sub-System, 2021 - 2032 ($Bn, Units)

• 7.1 Key trends
• 7.2 Propulsion
• 7.3 Drive system
• 7.4 Collision avoidance
• 7.5 Payloads & imaging
• 7.6 Communication & navigation

Chapter 8 Market Estimates & Forecast, By Application, 2021 - 2032 ($Bn, Units)

• 8.1 Key trends
• 8.2 Military & defense
• 8.3 Oil & gas
• 8.4 Environment monitoring
• 8.5 Oceanography
• 8.6 Archaeology & exploration
• 8.7 Search & salvage operation

Chapter 9 Market Estimates & Forecast, By Region, 2021 - 2032 ($Bn, Units)

• 9.1 Key trends
• 9.2 North America
  • 9.2.1 U.S.
  • 9.2.2 Canada
• 9.3 Europe
  • 9.3.1 UK
  • 9.3.2 Germany
  • 9.3.3 France
  • 9.3.4 Spain
  • 9.3.5 Italy
  • 9.3.6 Russia
  • 9.3.7 Nordics
  • 9.3.8 Rest of Europe
• 9.4 Asia Pacific
  • 9.4.1 China
  • 9.4.2 India
  • 9.4.3 Japan
  • 9.4.4 South Korea
  • 9.4.5 ANZ
  • 9.4.6 Southeast Asia
  • 9.4.7 Rest of Asia Pacific
• 9.5 Latin America
  • 9.5.1 Brazil
  • 9.5.2 Mexico
  • 9.5.3 Argentina
  • 9.5.4 Rest of Latin America
• 9.6 MEA
  • 9.6.1 UAE
  • 9.6.2 South Africa
  • 9.6.3 Saudi Arabia
  • 9.6.4 Rest of MEA

Chapter 10 Company Profiles

• 10.1 Kongsberg Maritime
• 10.2 Teledyne Marine
• 10.3 L3Harris Technologies
• 10.4 Ocean Infinity
• 10.5 General Dynamics Mission Systems
• 10.6 Saab Seaeye
• 10.7 Atlas Elektronik
• 10.8 Liquid Robotics (a Boeing Company)
• 10.9 ECA Group
• 10.10 Bluefin Robotics (a General Dynamics company)
• 10.11 Oceanscan
• 10.12 Subsea 7
• 10.13 Saipem
• 10.14 Sonardyne International Ltd
• 10.15 Hydroid (a subsidiary of Huntington Ingalls Industries)
• 10.16 iXblue
• 10.17 ASV Global (now part of L3Harris Technologies)
• 10.18 Eelume AS
• 10.19 Seabotix (a Teledyne Marine company)
• 10.20 SeaRobotics Corporation