Product Code: 2110
Title:
Military Robots Market Size By Platform (Aerial, Naval, Land-based), By Mode of Operation (Automated, Human-operated), By Application (Search & Rescue, Explosive Ordnance Disposal (EOD), Intelligence, Surveillance, and Reconnaissance (ISR), Transportation, Combat Support), Industry Analysis Report, Regional Outlook, Growth Potential, Price Trends, Competitive Market Share & Forecast, 2021 - 2027.
The military robots market is projected to witness a lucrative growth rate in the forthcoming years due to increasing investment by the U.S. government in unmanned systems, increasing need of replacing human troops with military robots to lessen the number of casualties in warzone, and providing high resolution photos as well as videos with 3-D maps and interactive 3-D models.
Robots, particularly military robots, can be designed to execute unsafe, recurrent or murky tasks with continuous precision as well as regular accuracy. Hence, it is no exception that numerous other industries are also starting to adopt robots for various other applications. This can mainly be attributed to their usefulness.
The military robots market is segmented in terms of mode of operation, platform, application and regional landscape. Based on mode of operation, the market is divided into human-operated and automated. Automated segment is expected to grow at a high rate between 2021-2027 owing to the increasing need of replacing human troops with military robots to reduce the number of casualties in warzone.
Military robots are known to be lifesaving, since they can perform duties which are quite similar to that of human being without any danger to humans. These are also easily disposable at a cost. Military robots can withstand damage done by bombs or other kinds of weaponry that might destroy the human body.
These robots differ in their applications, features, and uses. These come in various models and have a lot of new features like the amount of payload it can house, the distance it can cover, as well as number of axes their jointed arm comprises. At present, military robots aid to carry out an investigation and perform patrol tasks. Military robots further make it quite easy for soldiers to firmly spy places or break open targets of enemies.
With respect to platform, the military robots market is classified into land-based, naval, and aerial. Among these, aerial platform segment is expected to grow steadily through 2027 owing to the increasing need for navigating the hard-to-access areas as well as to provide high resolution photos and videos with 3-D maps and interactive 3-D models.
In terms of application, the overall military robots market is bifurcated into combat support, transportation, intelligence, surveillance, and reconnaissance (ISR), EOD (Explosive ordnance disposal), search & rescue, and others. Among these, combat support segment is anticipated to dominate the overall market by 2027 due to increasing need of providing battlefield intelligence and target locking. Robots help to lessen the casualties by eliminating human warfighters from risky missions, acting as a force multiplier, thus a smaller number of warfighters are required for a particular mission.
From a regional frame of reference, military robots market in North America will witness high market growth over the same forecast period owing to the increasing investment by the U.S. government in unmanned systems.
Table of Contents
Chapter 1 Methodology and Scope
- 1.1 Definitions & forecast parameters
- 1.1.1 Definitions
- 1.1.2 Methodology and forecast parameters
- 1.2 Data Sources
- 1.2.1 Secondary
- 1.2.2 Primary
Chapter 2 Executive Summary
- 2.1 Military robots industry 360 degree synopsis, 2016 - 2027
- 2.1.1 Business trends
- 2.1.2 Platform trends
- 2.1.3 Mode of operation trends
- 2.1.4 Application trends
- 2.1.5 Regional trends
Chapter 3 Industry Insights
- 3.1 Industry segmentation
- 3.2 Impact of COVID-19 on military robots industry landscape
- 3.2.1 Global outlook
- 3.2.2 Regional impact
- 3.2.2.1 North America
- 3.2.2.2 Europe
- 3.2.2.3 Asia Pacific
- 3.2.2.4 Latin America
- 3.2.2.5 MEA
- 3.2.3 Industry value chain
- 3.2.3.1 Research & development
- 3.2.3.2 Manufacturing
- 3.2.3.3 Marketing
- 3.2.3.4 Supply
- 3.2.4 Competitive landscape
- 3.2.4.1 Strategy
- 3.2.4.2 Distribution network
- 3.2.4.3 Business growth
- 3.3 Industry ecosystem analysis
- 3.3.1 Component Providers
- 3.3.2 Technology providers
- 3.3.3 Manufacturers
- 3.3.4 Distribution channel analysis
- 3.3.5 Vendor matrix
- 3.4 Technology & innovation landscape
- 3.5 Regulatory landscape
- 3.5.1 North America
- 3.5.2 Europe
- 3.5.3 Asia Pacific
- 3.5.4 Latin America
- 3.5.5 MEA
- 3.6 Defense budget, by country
- 3.7 Industry impact forces
- 3.7.1 Growth drivers
- 3.7.1.1 Increasing government investments in unmanned systems in North America
- 3.7.1.2 Emerging demand for UGVs for counter insurgency operations in Asia-Pacific
- 3.7.1.3 Rising adoption of UAVs in Europe
- 3.7.1.4 Increasing demand of unmanned systems for search & rescue operations in MEA
- 3.7.1.5 Rising need of automated unmanned systems in Latin America
- 3.7.2 Industry pitfalls & challenges
- 3.7.2.1 High cost associated with advanced technologies
- 3.7.2.2 Lack of advanced visual capabilities in unmanned ground vehicles (UGV)
- 3.8 Growth potential analysis
- 3.9 Porter's analysis
- 3.9.1 Supplier power
- 3.9.2 Buyer power
- 3.9.3 Threat of new entrants
- 3.9.4 Threat of substitutes
- 3.9.5 Internal rivalry
- 3.10 PESTEL analysis
Chapter 4 Competitive Landscape
- 4.1 Introduction
- 4.2 Company market share analysis
- 4.3 Key player analysis
- 4.4 Competitive analysis of major market players
Chapter 5 Military Robots Market, By Platform (Revenue & Shipment)
- 5.1 Key trends by platform
- 5.2 Aerial
- 5.2.1 Market estimates and forecast, 2016 - 2027
- 5.3 Naval
- 5.3.1 Market estimates and forecast, 2016 - 2027
- 5.4 Land-based
- 5.4.1 Market estimates and forecast, 2016 - 2027
Chapter 6 Military Robots Market, By Mode of Operation (Revenue & Shipment)
- 6.1 Key trends by mode of operation
- 6.2 Automated
- 6.2.1 Market estimates and forecast, 2016 - 2027
- 6.3 Human-operated
- 6.3.1 Market estimates and forecast, 2016 - 2027
Chapter 7 Military Robots Market, By Application (Revenue & Shipment)
- 7.1 Key trends by application
- 7.2 Search & rescue
- 7.2.1 Market estimates and forecast, 2016 - 2027
- 7.3 Explosive ordnance disposal (EOD)
- 7.3.1 Market estimates and forecast, 2016 - 2027
- 7.4 Intelligence, Surveillance, And Reconnaissance (ISR)
- 7.4.1 Market estimates and forecast, 2016 - 2027
- 7.5 Transportation
- 7.5.1 Market estimates and forecast, 2016 - 2027
- 7.6 Combat support
- 7.6.1 Market estimates and forecast, 2016 - 2027
- 7.7 Others
- 7.7.1 Market estimates and forecast, 2016 - 2027
Chapter 8 Military Robots Market, By Region (Revenue & Shipment)
- 8.1 Key trends by region
- 8.2 North America
- 8.2.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.2.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.2.3 Market estimates and forecast, by application, 2016 - 2027
- 8.2.4
- 8.2.5 U.S.
- 8.2.5.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.2.5.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.2.5.3 Market estimates and forecast, by application, 2016 - 2027
- 8.2.6 Canada
- 8.2.6.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.2.6.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.2.6.3 Market estimates and forecast, by application, 2016 - 2027
- 8.3 Europe
- 8.3.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.3.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.3.3 Market estimates and forecast, by application, 2016 - 2027
- 8.3.4 Germany
- 8.3.4.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.3.4.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.3.4.3 Market estimates and forecast, by application, 2016 - 2027
- 8.3.5 UK
- 8.3.5.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.3.5.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.3.5.3 Market estimates and forecast, by application, 2016 - 2027
- 8.3.6 France
- 8.3.6.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.3.6.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.3.6.3 Market estimates and forecast, by application, 2016 - 2027
- 8.3.7 Italy
- 8.3.7.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.3.7.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.3.7.3 Market estimates and forecast, by application, 2016 - 2027
- 8.3.8 Russia
- 8.3.8.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.3.8.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.3.8.3 Market estimates and forecast, by application, 2016 - 2027
- 8.3.8.4
- 8.4 Asia-Pacific
- 8.4.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.4.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.4.3 Market estimates and forecast, by application, 2016 - 2027
- 8.4.4 China
- 8.4.4.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.4.4.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.4.4.3 Market estimates and forecast, by application, 2016 - 2027
- 8.4.5 India
- 8.4.5.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.4.5.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.4.5.3 Market estimates and forecast, by application, 2016 - 2027
- 8.4.6 Japan
- 8.4.6.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.4.6.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.4.6.3 Market estimates and forecast, by application, 2016 - 2027
- 8.4.7 South Korea
- 8.4.7.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.4.7.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.4.7.3 Market estimates and forecast, by application, 2016 - 2027
- 8.5 Latin America
- 8.5.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.5.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.5.3 Market estimates and forecast, by application, 2016 - 2027
- 8.5.4 Brazil
- 8.5.4.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.5.4.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.5.4.3 Market estimates and forecast, by application, 2016 - 2027
- 8.5.5 Mexico
- 8.5.5.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.5.5.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.5.5.3 Market estimates and forecast, by application, 2016 - 2027
- 8.6 MEA
- 8.6.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.6.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.6.3 Market estimates and forecast, by application, 2016 - 2027
- 8.6.4
- 8.6.5 UAE
- 8.6.5.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.6.5.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.6.5.3 Market estimates and forecast, by application, 2016 - 2027
- 8.6.6 Saudi Arabia
- 8.6.6.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.6.6.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.6.6.3 Market estimates and forecast, by application, 2016 - 2027
- 8.6.7 South Africa
- 8.6.7.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.6.7.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.6.7.3 Market estimates and forecast, by application, 2016 - 2027
- 8.6.8 Israel
- 8.6.8.1 Market estimates and forecast, by platform, 2016 - 2027
- 8.6.8.2 Market estimates and forecast, by mode of operation, 2016 - 2027
- 8.6.8.3 Market estimates and forecast, by application, 2016 - 2027
Chapter 9 Company Profiles
- 9.1 AeroVironment, Inc.
- 9.1.1 Business Overview
- 9.1.2 Financial Data
- 9.1.3 Product Landscape
- 9.1.4 Strategic Outlook
- 9.1.5 SWOT Analysis
- 9.2 BAE Systems
- 9.2.1 Business Overview
- 9.2.2 Financial Data
- 9.2.3 Product Landscape
- 9.2.4 Strategic Outlook
- 9.2.5 SWOT Analysis
- 9.3 Boston Dynamics
- 9.3.1 Business Overview
- 9.3.2 Financial Data
- 9.3.3 Product Landscape
- 9.3.4 Strategic Outlook
- 9.3.5 SWOT Analysis
- 9.4 ECA Group
- 9.4.1 Business Overview
- 9.4.2 Financial Data
- 9.4.3 Product Landscape
- 9.4.4 Strategic Outlook
- 9.4.5 SWOT Analysis
- 9.5 Elbit Systems Ltd.
- 9.5.1 Business Overview
- 9.5.2 Financial Data
- 9.5.3 Product Landscape
- 9.5.4 Strategic Outlook
- 9.5.5 SWOT Analysis
- 9.6 FLIR Systems Inc.
- 9.6.1 Business Overview
- 9.6.2 Financial Data
- 9.6.3 Product Landscape
- 9.6.4 Strategic Outlook
- 9.6.5 SWOT Analysis
- 9.7 General Atomics
- 9.7.1 Business Overview
- 9.7.2 Financial Data
- 9.7.3 Product Landscape
- 9.7.4 Strategic Outlook
- 9.7.5 SWOT Analysis
- 9.8 IAI
- 9.8.1 Business Overview
- 9.8.2 Financial Data
- 9.8.3 Product Landscape
- 9.8.4 Strategic Outlook
- 9.8.5 SWOT Analysis
- 9.9 Kratos Defense & Security Solutions, Inc.
- 9.9.1 Business Overview
- 9.9.2 Financial Data
- 9.9.3 Product Landscape
- 9.9.4 Strategic Outlook
- 9.9.5 SWOT Analysis
- 9.10 Leonardo S.p.A.
- 9.10.1 Business Overview
- 9.10.2 Financial Data
- 9.10.3 Product Landscape
- 9.10.4 Strategic Outlook
- 9.10.5 SWOT Analysis
- 9.11 Lockheed Martin Corporation
- 9.11.1 Business Overview
- 9.11.2 Financial Data
- 9.11.3 Product Landscape
- 9.11.4 Strategic Outlook
- 9.11.5 SWOT Analysis
- 9.12 Northrop Grumman Corporation
- 9.12.1 Business Overview
- 9.12.2 Financial Data
- 9.12.3 Product Landscape
- 9.12.4 Strategic Outlook
- 9.12.5 SWOT Analysis
- 9.13 QinetiQ
- 9.13.1 Business Overview
- 9.13.2 Financial Data
- 9.13.3 Product Landscape
- 9.13.4 Strategic Outlook
- 9.13.5 SWOT Analysis
- 9.14 Raytheon Technologies
- 9.14.1 Business Overview
- 9.14.2 Financial Data
- 9.14.3 Product Landscape
- 9.14.4 Strategic Outlook
- 9.14.5 SWOT Analysis
- 9.15 Roboteam
- 9.15.1 Business Overview
- 9.15.2 Financial Data
- 9.15.3 Product Landscape
- 9.15.4 Strategic Outlook
- 9.15.5 SWOT Analysis
- 9.16 Thales Group
- 9.16.1 Business Overview
- 9.16.2 Financial Data
- 9.16.3 Product Landscape
- 9.16.4 Strategic Outlook
- 9.16.5 SWOT Analysis
比較リスト
