世界の農業用ロボット市場予測2025年:提供別、種類別、農業環境別、農産物別、用途別、地域別

MarketsandMarketsが発行した調査報告書(SE 5080)
◆英語タイトル:Agricultural Robots Market by Offering, Type (UAVs, Milking Robots, Driverless Tractors, Automated Harvesting Systems), Farming Environment, Farm Produce, Application (Harvest Management, Field Farming), Geography - Global Forecast to 2025
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MarketsandMarkets社は、農業用ロボットの世界市場規模が2020年74億ドルから2025年206億ドルまで年平均22.8%成長すると予測しています。当資料では、世界の農業用ロボット市場を統合的に調査・分析し、市場概要、提供別(ハードウェア、サービス)分析、種類別(無人航空機(UAVS)/ドローン、搾乳ロボット、ドライバーレストラクター、自動収穫システム、その他)分析、農業環境別(屋外、屋内)分析、農産物別(果物&野菜、畑作物、乳牛、家畜、その他)分析、用途別(収穫管理、フィールドファーミング、酪農および家畜管理、土壌管理、灌漑管理、剪定管理、気象追跡および監視、在庫管理、その他)分析、地域別分析、競合環境、企業概要などで構成されております。
・イントロダクション
・調査手法
・エグゼクティブサマリー
・プレミアムインサイト
・市場概要
・業界トレンド
・世界の農業用ロボット市場:提供別(ハードウェア、サービス)
・世界の農業用ロボット市場:種類別(無人航空機(UAVS)/ドローン、搾乳ロボット、ドライバーレストラクター、自動収穫システム、その他)
・世界の農業用ロボット市場:農業環境別(屋外、屋内)
・世界の農業用ロボット市場:農産物別(果物&野菜、畑作物、乳牛、家畜、その他)
・世界の農業用ロボット市場:用途別(収穫管理、フィールドファーミング、酪農および家畜管理、土壌管理、灌漑管理、剪定管理、気象追跡および監視、在庫管理、その他)
・世界の農業用ロボット市場:地域別
・競合環境
・企業概要

【レポートの概要】

“The agricultural robots market is projected to grow at a CAGR of 22.8% during 2019–2024”
The agricultural robots market is expected to grow from USD 7.4 billion in 2020 and is projected to reach USD 20.6 billion by 2025; it is expected to grow at a CAGR of 22.8% during the forecast period. A shortage of new farmers, as indicated by the rising average age of farmers is driving the further use of automated agricultural equipment as well as the development of new agricultural robots. Development is taking place in all aspects of agriculture, such as imaging, navigation, planting, weeding, and harvesting. Large farms are also collaborating with companies developing agricultural technology to drive down costs and to maintain their cost advantage in the market. Increasing requirement for food globally will also require increasing productivity, which can only be achieved through robotic automation.

“UAVs are expected to maintain its market dominance during forecast period”
UAVs are expected to maintain the largest share of the market compared to other agricultural robots. Drones are the most inexpensive agricultural robots and can be deployed in all farms regarding of their size. Different variants of drones are available for different tasks. Fixed wing drones, offered by companies such as AgEagle Aerial Systems (US) are suitable for crop and livestock imaging. Rotary blade drones, such as those offered by DJI (China) have a more stable flight and can be used for precision spraying application. Most drone manufacturers also offer specialized software for farmers to gain actionable insights from captured data.

“Hardware components are expected to have the largest share of the market”
Hardware components, consisting of automation & control Systems and sensing & monitoring devices will continue to have the largest share of the market compared to either software or services. As agricultural robots are highly specialized in their design, they require specialized mechanical components and sensors to operate. These add a significant cost to the price of a robot. A strawberry picking robot cannot be programmed to be used for kiwi harvesting. Hardware systems are paramount to productivity, through faster working speed and reduced operational errors. Increased use of sensors and navigation modules in agricultural robots also contribute to the large market share of hardware.

“The market in the US is expected to have the largest share of the market”
Large farms and focus on agricultural productivity is one of the primary reason for the US having the largest market share when compared to other regions. With increasing restrictions on immigration and shortage of farm labor, large farms are investing in companies that develop agricultural robots. HARVEST CROO (US) is one such company, and is mainly funded by large strawberry farm operators. Robotic harvesting vehicles are also being tested in Florida and California to harvest other fruits such as apples and grapes to automate labor intensive tasks. Countries such as Canada, Mexico, and Brazil are also adopting various agricultural robots. Hence, North America is expected to have the highest share of the market.

In the process of determining and verifying the market size for several segments and subsegments gathered through secondary research, extensive primary interviews have been conducted with key industry experts in the agricultural robots marketspace. The break-up of primary participants for the report has been shown below:
• By Company Type: Tier 1 – 40%, Tier 2 – 40%, and Tier 3 – 20%
• By Designation: C-level Executives – 40%, Directors – 30%, and Others – 30%
• By Region: North America –40, APAC– 30%, Europe – 20%, and RoW – 10%

The report profiles key players in the agricultural robots market with their respective market ranking analysis. Prominent players profiled in this report are Deere & Company (US), Trimble (US), AGCO Corporation (US), AgJunction (US), DJI (China), Boumatic (Netherlands), Lely (Netherlands), DeLaval (Sweden), Topon (US), AgEagle Aerial Systems (US), YANMAR CO. (Japan), Deepfield Robotics (Germany), ecoRoborix (Switzerland), Harvest Automation (US), Naïo Technologies (France), ROBOTICS PLUS (New Zealand), CNH INDUSTRIAL N.V. (UK), KUBOTA Corporation (Japan), Harvest CROO (US), Autonomous Tractor Corporation (US), Abundant Robotics (US), Clearpath Robotics (Canada), Iron Ox (US), CLAAS KGaA mbH (Germany), and Ag Leader Technology (US).

Research Coverage:
This research report categorizes the global agricultural robots market on the basis of offering, type, farming environment, farm produce, application, and geography. The report describes the major drivers, restraints, challenges, and opportunities pertaining to the agricultural robotics market and forecasts the same till 2025. Apart from these, the report also consists of leadership mapping and analysis of all the companies included in the agricultural robots ecosystem.

Key Benefits of Buying the Report
The report would help leaders/new entrants in this market in the following ways:
1. This report segments the agricultural robotics market comprehensively and provides the closest market size projection for all subsegments across different regions.
2. The report helps stakeholders understand the pulse of the market and provides them with information on key drivers, restraints, challenges, and opportunities for market growth.
3. This report would help stakeholders understand their competitors better and gain more insights to improve their position in the business. The competitive landscape section includes competitor ecosystem, product developments and launches, partnerships, and mergers and acquisitions.
4. The analysis of the top 25 companies, based on the strength of the product portfolio as well as the business strategy will help stakeholders visualize the market positioning of these key players.
5. PESTEL analysis and technological trends that will shape the market in the coming years has also been covered in this report.

【レポートの目次】

1 Introduction (Page No. – 21)
1.1 Study Objectives
1.2 Market Definition and Scope
1.2.1 Inclusions and Exclusions
1.3 Study Scope
1.3.1 Years Considered
1.4 Currency
1.5 Stakeholders
2 Research Methodology (Page No. – 25)
2.1 Research Data
2.1.1 Secondary Data
2.1.1.1 Major Secondary Sources
2.1.1.2 Key Data From Secondary Sources
2.1.2 Primary Data
2.1.2.1 Key Data From Primary Sources
2.1.2.2 Breakdown of Primaries
2.1.3 Secondary and Primary Research
2.1.3.1 Key Industry Insights
2.2 Market Size Estimation
2.2.1 Bottom-Up Approach
2.2.2 Top-Down Approach
2.2.3 Market Projections
2.3 Market Breakdown and Data Triangulation
2.4 Research Assumptions and Limitations
2.4.1 Assumptions
2.4.2 Limitations
3 Executive Summary (Page No. – 36)
4 Premium Insights (Page No. – 40)
4.1 Attractive Opportunities in Agricultural Robots Market
4.2 Agricultural Robots Market, By Type
4.3 Agricultural Robots Market, By Offering
4.4 Agricultural Robots Market, By Farm Produce
4.5 Agricultural Robots Market in APAC, By Industry and By Country
4.6 Agricultural Robots Market, By Country
5 Market Overview (Page No. – 44)
5.1 Market Evolution
5.2 Market Dynamics
5.2.1 Drivers
5.2.1.1 Growing Population and Increasing Labor Shortage Encouraging Automation
5.2.1.2 Maturing IoT and Navigation Technologies are Driving Down Cost of Automation
5.2.2 Restraints
5.2.2.1 High Cost of Automation for Small Farms (10–1,000 Acres)
5.2.2.2 Technological Barriers Pertaining to Fully Autonomous Robots
5.2.3 Opportunities
5.2.3.1 Untapped Scope and Market Potential for Automation in Agriculture
5.2.3.2 Use of Real-Time Multimodal Robot Systems in Field
5.2.4 Challenges
5.2.4.1 Concerns Over Data Privacy and Regulations
5.2.4.2 High Cost and Complexity of Fully Autonomous Robots
6 Industry Trends (Page No. – 51)
6.1 Introduction
6.2 Value Chain Analysis
6.2.1 Major Players in Agricultural Robots Market
6.2.1.1 Robot OEMs
6.2.1.2 Suppliers
6.2.1.3 IT/Big Data Companies
6.2.1.4 Software Solution Providers
6.2.1.5 Startups
6.2.1.6 Research Centers
6.3 Technology Roadmap
6.4 Pestle Analysis
6.4.1 Political Factors
6.4.2 Economic Factors
6.4.3 Social Factors
6.4.4 Technological Factors
6.4.4.1 Agricultural IoT
6.4.4.2 AI in Agriculture
6.4.5 Legal Factors
6.4.6 Environmental Factors
7 Agricultural Robots Market, By Offering (Page No. – 58)
7.1 Introduction
7.2 Hardware
7.2.1 Automation & Control Systems
7.2.1.1 Displays
7.2.1.1.1 Farmers Can View Location, Fuel, and Steering Angle of Tractors Through Displays
7.2.1.2 Guidance & Steering
7.2.1.2.1 Many Tractors That Operate in Large Fields Utilize Automated Steering Or Auto-Steering
7.2.1.3 GPS/GNSS Systems
7.2.1.3.1 GPS/GNSS Systems are Used in Tractors and Autonomous Vehicles at Farms
7.2.1.4 Cameras
7.2.1.4.1 Spectral Imaging Allows Extraction of Information That Human Eyes Fail to Capture
7.2.1.4.2 Accumulation of Pests and Changes in Plant Color Appear in Infrared Frequencies Long Before They are Seen in Visible Spectrum
7.2.1.4.3 Thermal Cameras Can Identify Stress Caused in Crops Due to Improper Water Supply
7.2.1.4.4 Main Benefit of Lidar Cameras in Agriculture is 3D Mapping of Ground Elevation
7.2.1.4.5 High-Resolution Cameras Capture Detailed and Colored Photographs of Crops That Help in Studying Plant Health
7.2.1.5 Mobile Devices/Handheld Computers
7.2.1.5.1 Handheld Displays are Used to Guide Operators By Providing Real-Time Information on Various Inputs Such as Fertilizers, Pesticides, and Seeding
7.2.1.6 Flow & Application Control Devices
7.2.1.6.1 Flow & Application Control Devices Operate on Variable Rate Technology (VRT)
7.2.1.7 Others
7.2.2 Sensing & Monitoring Devices
7.2.2.1 Yield Monitors
7.2.2.1.1 Yield Monitoring Systems Can Detect Weed Levels in Crops
7.2.2.2 Soil Sensors
7.2.2.2.1 Electrochemical Sensors are Used to Measure Soil Nutrient Levels and Ph Concentrations
7.2.2.2.2 Moisture Sensors are Used to Manage Irrigation Systems Optimally
7.2.2.2.3 Thermistors, Thermocouples, Thermocouple Wires, and Averaging Thermocouples are Standard Soil Temperature Sensors
7.2.2.3 Water Sensors
7.2.2.3.1 Flow Sensors are Used for Water Sensing and Detecting Flow
7.2.2.4 Climate Sensors
7.2.2.4.1 Climate Sensors are Mostly Used for Indoor Applications in Greenhouses and Vertical Farms
7.2.2.5 Others
7.2.3 Software
7.2.3.1 Local/Web-Based Software
7.2.3.1.1 Web-Based Software are Popular Because They are Easy to Maintain and Update
7.2.3.2 Cloud-Based Software
7.2.3.2.1 Advantages Offered By Cloud-Based Farm Management Solutions Include Optimized Performance and Ease of Access
7.3 Services
7.3.1 System Integration & Consulting
7.3.1.1 System Integrators are Involved in Troubleshooting and Diagnosing Farm Management Solutions
7.3.2 Managed Services
7.3.2.1 Farm Operation Services
7.3.2.1.1 Farm Operation Services Help Generate Records and Integrate Unstructured Data
7.3.2.2 Data Services
7.3.2.2.1 Data Services Provide A Common Platform and Integrate Demand and Supply Side Participants
7.3.2.3 Analytics Services
7.3.2.3.1 Analytics Services Help Analyze Acquired Farm Data and Provide Real-Time Information
7.3.3 Connectivity Services
7.3.3.1 Connectivity Service Providers Provide Proper Connectivity Between Device Domain and End User Through Network Channel
7.3.4 Assisted Professional Services
7.3.4.1 Supply Chain Management Services
7.3.4.1.1 Service Providers Can Help Optimize Agricultural Supply Chain Facilities and Transportation
7.3.4.2 Climate Information Services
7.3.4.2.1 Climate Information Service Providers Keep Farmers Updated About Weather Condition
7.3.4.3 Others
7.3.5 Maintenance & Support Services
7.3.5.1 Maintenance & Support Services Include Troubleshooting Problems Related to Farming Software Solutions
8 Agricultural Robots Market, By Type (Page No. – 78)
8.1 Introduction
8.2 Unmanned Aerial Vehicles (UAVS)/Drones
8.2.1 Fixed-Wing Drones
8.2.1.1 Advantages of Fixed-Wing Drones Include Maximum Flying Time, Long Distance Coverage, and High Speed
8.2.2 Rotary Blade Drones
8.2.2.1 Rotary Blade Drones are Comparatively Smaller in Size and Cheaper Than Fixed-Wing Drones
8.2.3 Hybrid Drones
8.2.3.1 Hybrid Drones Can Hover, Fly at Fast Speed, and Remain Steady
8.3 Milking Robots
8.3.1 Milking Robots are Also Known as Voluntary Milking Systems
8.4 Driverless Tractors
8.4.1 Driverless Tractors Can Perform Seeding and Planting Autonomously
8.5 Automated Harvesting Systems
8.5.1 Automated Harvesting Systems Use A Combination of Cameras, Sensors, and Machine Vision to Harvest
8.6 Others
9 Agricultural Robots Market, By Farming Environment (Page No. – 104)
9.1 Introduction
9.2 Outdoor
9.2.1 UAVS Dominate Outdoor Farming Market as They Were Commercialized Earlier Than Other Robots
9.3 Indoor
9.3.1 Milking Robots are Expected to have Leading Share in Indoor Farming
10 Agricultural Robots Market, By Farm Produce (Page No. – 109)
10.1 Introduction
10.2 Fruits & Vegetables
10.2.1 Automated Harvesting Systems Dominate Agricultural Robots Market for Fruits & Vegetables
10.3 Field Crops
10.3.1 Driverless Tractors Dominate Agricultural Robots Market for Field Crops
10.4 Dairy & Livestock
10.4.1 Milking Robots are the Most Used Robots in Dairy & Livestock Produce Segment
10.5 Others
11 Agricultural Robots Market, By Application (Page No. – 117)
11.1 Introduction
11.2 Harvest Management
11.2.1 Harvest Management Applications Utilize UAVS and Automated Harvesting Systems
11.3 Field Farming
11.3.1 Crop Monitoring
11.3.1.1 Crop Monitoring is Performed Aerially Using Agricultural Drones
11.3.2 Plant Scouting
11.3.2.1 Agv Platforms are Used for Crop Scouting in Indoor and Outdoor Environments
11.3.3 Crop Scouting
11.3.3.1 Robots for Crop Scouting Application Monitor Plants in Real Time
11.4 Dairy & Livestock Management
11.4.1 Dairy Farm Management
11.4.1.1 Milking Robots Automate Manual Processes in Dairy Farms
11.4.2 Livestock Monitoring
11.4.2.1 Smart Tags Placed in Farm Animals Continuously Transmit Data for Remote Monitoring
11.4.3 Precision Fish Farming
11.4.3.1 Precision Fish Farming Leverages Ai-Based Image Processing to Perform Various Farm Operations
11.5 Soil Management
11.5.1 Moisture Monitoring
11.5.1.1 Moisture Monitoring Systems are Fitted With IoT Sensors for Data Transmission
11.5.2 Nutrient Monitoring
11.5.2.1 Nutrient Monitoring Systems are Mostly Used in Hydroponic Farming
11.6 Irrigation Management
11.6.1 Irrigation Management is Performed Using Drones Flying at Regular Intervals
11.7 Pruning Management
11.7.1 Pruning Management is Performed Mainly By Processing Data From Vision Systems
11.8 Weather Tracking & Monitoring
11.8.1 Drones are Mainly Adopted for Weather Tracking & Monitoring Applications
11.9 Inventory Management
11.9.1 Inventory Management is Mainly Performed Through Software Applications
11.10 Others
12 Geographic Analysis (Page No. – 134)
12.1 Introduction
12.2 Americas
12.2.1 North America
12.2.1.1 US
12.2.1.1.1 US is One of the Largest Markets for Agricultural Automation in North America
12.2.1.2 Canada
12.2.1.2.1 Drones are Increasingly Being Used in Canada for Agricultural Applications
12.2.1.3 Mexico
12.2.1.3.1 Crop Mapping Using Drones is Gaining Popularity in Mexico
12.2.2 South America
12.2.2.1 Brazil
12.2.2.1.1 Brazil is an Important Market for Automated Harvesting Systems
12.2.2.2 Argentina
12.2.2.2.1 Small Drones are Expected to Be Used in Small and Medium-Sized Farms in Argentina
12.2.2.3 Rest of South America
12.3 Europe
12.3.1 UK
12.3.1.1 Universities in UK are Involved in Development of Various Agricultural Robots
12.3.2 Germany
12.3.2.1 Germany is Largest Market for Agricultural Robots in Europe
12.3.3 France
12.3.3.1 French Agricultural Robots Market Expected to have Highest Growth Among Other European Countries
12.3.4 Italy
12.3.4.1 Increase in Agricultural Activities Leading to Adoption and Acceptance of Agricultural Robots
12.3.5 Netherlands
12.3.5.1 Netherlands Represents One of the Largest Markets for Milking Robots
12.3.6 Rest of Europe
12.4 APAC
12.4.1 China
12.4.1.1 Pesticide and Herbicide Spraying are Popular Applications for Agriculture Drones in China
12.4.2 Japan
12.4.2.1 Japan Expected to Be One of the First Markets to Commercialize Driverless Tractors in APAC
12.4.3 Australia
12.4.3.1 Australia Expected to Be the Largest Market for Agricultural Robots During Forecast Period
12.4.4 India
12.4.4.1 India has Very Low Penetration of Agricultural Robots at Present
12.4.5 South Korea
12.4.5.1 South Korean Government is Subsidizing Milking Robots to Make Them Affordable to Farmers
12.4.6 Rest of APAC
12.5 RoW
12.5.1 Africa
12.5.1.1 South Africa has Been Recently Granted Clearance to Fly Agricultural Drones
12.5.2 Middle East
12.5.2.1 Feasibility of Drones in Middle East is Being Studied
12.5.3 Russia
12.5.3.1 Russia is A Growing Market for Various Agricultural Robots
13 Adoption of Agricultural Robots Based on Farm Size (Page No. – 158)
13.1 Introduction
13.2 Small Farms
13.3 Medium-Sized Farms
13.4 Large Farms
14 Competitive Landscape (Page No. – 160)
14.1 Overview
14.2 Market Share Analysis: Agricultural Robots Market, 2019
14.3 Competitive Leadership Mapping
14.3.1 Visionary Leaders
14.3.2 Dynamic Differentiators
14.3.3 Innovators
14.3.4 Emerging Companies
14.3.5 Strength of Product Portfolio (25 Players)
14.3.6 Business Strategy Excellence (25 Players)
14.4 Startup Scenario
14.4.1 Startup Categorization Based on Solutions Provided
14.4.1.1 Hardware Providers
14.4.1.2 Software and Service Providers
14.5 Competitive Situations and Trends
14.5.1 Product Launches
14.5.2 Partnerships and Collaborations
14.5.3 Expansions
14.5.4 Acquisitions
14.5.5 Contracts and Agreements
15 Company Profiles (Page No. – 173)
(Business Overview, Products Offered, Recent Developments, SWOT Analysis, and MnM View)*
15.1 Key Players
15.1.1 Deere & Company
15.1.2 Trimble
15.1.3 Agco Corporation
15.1.4 Delaval
15.1.5 DJI
15.1.6 Boumatic Robotics
15.1.7 Lely
15.1.8 Agjunction
15.1.9 Topcon Positioning System
15.1.10 Ageagle Aerial Systems
15.2 Right to Win
15.2.1 Deere & Company
15.2.2 DJI
15.2.3 Trimble
15.2.4 Agco Corporation
15.2.5 Delaval
15.3 Other Key Players
15.3.1 Yanmar Co.
15.3.2 Deepfield Robotics
15.3.3 Ecorobotix
15.3.4 Harvest Automation
15.3.5 Naïo Technologies
15.3.6 Robotics Plus
15.3.7 Cnh Industrial N.V.
15.3.8 Kubota Corporation
15.3.9 Harvest Croo
15.3.10 Autonomous Tractor Corporation
*Details on Business Overview, Products Offered, Recent Developments, SWOT Analysis, and MnM View Might Not Be Captured in Case of Unlisted Companies.
16 Appendix (Page No. – 205)
16.1 Discussion Guide
16.2 Knowledge Store: Marketsandmarkets’ Subscription Portal
16.3 Available Customizations
16.4 Related Reports
16.5 Author Details



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