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市場調查報告書

全球農業用機器人:市場佔有率、策略與預測

Agricultural Robots: Market Shares, Strategies, and Forecasts, Worldwide, 2014 to 2020

出版商 WinterGreen Research, Inc. 商品編碼 294411
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全球農業用機器人:市場佔有率、策略與預測 Agricultural Robots: Market Shares, Strategies, and Forecasts, Worldwide, 2014 to 2020
出版日期: 2014年01月28日 內容資訊: 英文
簡介

農業用機器人,由於實行產業的自動化流程,採用於農業、擠奶、食品製造及動物管理的各方面,全球市場達成大幅度的成長。預計農業用機器人的市場規模2013年達到8億1,700萬美金,2020年達163億美元。

本報告提供全球農業用機器人市場相關分析、市場概況、市場發展推動因素,及市場佔有率調查分析、主要產品還有技術的介紹,以及市場預測,為您概述為以下內容。

第1章 農業用機器人市場說明、市場動態

  • 農業市場
  • RAS Agricultural Robotics and Automation (AgRA) Technical Committee
  • 農業用機器人的採集、種植及驅動器
  • 苗床、溫室部門
  • 苗床效率的改善
  • 農業生產者摸索產業的改善
  • cRops (Clever Robots for Crops) 機器人收穫高價的作物
  • EU的第7次組成架構計劃(FP7)
  • 草莓
  • 變形農業用機器人

第2章 農業用機器人市場佔有率、市場預測

  • 農業用機器人市場促進要素
  • 農業用機器人市場佔有率
  • 農業用機器人市場預測
  • 農業用機器人的價格
  • 農業用機器人的TCO/ROI
  • 農業用機器人的各地區分析

第3章 農業用機器人的產品說明

第4章 農業用機器人技術

  • 收穫自動化專有感應技術
  • 焊接機器人
  • 物料輸送機器人
  • 電漿切割機器人
  • 農業用機器人、自動化的領域
  • 機器人工學、自動化
  • 電子系統改善不同的農業流程

第5章 農業用機器人企業簡介

圖表清單

目錄

Worldwide markets are poised to achieve significant growth as the agricultural robots are used in every aspect of farming, milking, food production, and animal control to implement automated process for the industry.

Weed control is able to achieve crop-yield increases. Robot technology is deploying machines for weed control, promising to improve crop yields. Robots make the crops safer by eliminating or virtually eliminating herbicides. Downstream processing system solutions and robots achieve automation of process. Robots meet stringent hygiene and safety regulations, work tirelessly 24 hours a day, and relieve human workers of physically arduous tasks. Robots contribute to the freshness, variety and quality of food. Projects are ongoing.

High value crops are a target of agricultural robotic development. What could be tastier than a strawberry, perfectly formed, and perfectly ripened? New agricultural robots are able to improve the delivery of consistent quality food, and to implement efficiency in managing food production.

Strawberries are a high profit crop. A new generation of machines has just been born. Strawberry Harvesters with the world's most advanced technology to give maximum performance to a farm. Harvesting robots can optimize the productivity of the farming business. Growers can get the best results in a berry farm using automated process. Automated picking collection systems improve labor productivity, give speed and agility to harvest operations.

The robotic platforms are capable of site-specific spraying. This is targeted spraying only on foliage and selected targets. It can be used for selective harvesting of fruit. The robots detect the fruit, sense its ripeness, then move to grasp and softly detach only ripe fruit.

Agricultural robots address automation of process for agribusiness. The challenge being addressed is to guide farmers towards a new economic model. The aim is to meet demands of a global market. Harvesting is one benefit. Crop-yield increases come from weed control. Robot technology is deploying its machines for weed control, promising to improve crop yields. Robots make the crops safer by eliminating or virtually eliminating herbicides.

Machinery manufacturers and downstream processing industries look for system solutions and robots to achieve automation of process. Robots meet stringent hygiene and safety regulations, work tirelessly 24 hours a day, and relieve human workers of physically arduous tasks. Robots contribute to the freshness, variety and quality of food.

According to Susan Eustis, principal author of the market research study, "Agricultural robotic projects are ongoing. The key to industrial farm robots is keeping costs down. Adapting existing commercial vehicles instead of building new ones is the best way to build viable agricultural robots."

Agricultural robot market size at $817 million in 2013 are anticipated to reach $16.3 billion by 2020, a hefty growth for a nascent market. Agricultural robots are but part of an overall trend toward more automated process for every type of human endeavor. Robots are being used more widely than expected in a variety of sectors, and the trend is likely to continue with robotics becoming as ubiquitous as computer technology over the next 15 years.

WinterGreen Research is an independent research organization funded by the sale of market research studies all over the world and by the implementation of ROI models that are used to calculate the total cost of ownership of equipment, services, and software. The company has 35 distributors worldwide, including Global Information Info Shop, Market Research.com, Research and Markets, Electronics.CA, Bloomberg, and Thompson Financial.

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Table of Contents

Agricultural Robots Executive Summary

AGRICULTURAL ROBOT MARKET EXECUTIVE SUMMARY Agricultural Robot Market Driving Forces Agricultural Robot Target Markets Robotic Agriculture Trends Agricultural Robot Market Shares Agricultural Robot Market Forecasts

Agricultural Robots Market Description and Market Dynamics

1. MARKET AGRICULTURAL ROBOT DESCRIPTION AND MARKET DYNAMICS

  • 1.1 Agricultural Markets
    • 1.1.1 Automation Potential In The Agricultural Industry
    • 1.1.2 Robots Find A Place in the Agriculture Industry
    • 1.1.3 Agricultural Robots Make Production More Efficient
    • 1.1.4 Use Of Industrial Robots for Agriculture
    • 1.1.5 Agricultural Robotics and Automation
  • 1.2 RAS Agricultural Robotics and Automation (AgRA) Technical Committee
  • 1.3 Farm Bots Pick, Plant and Drive
    • 1.3.1 Relying On Illegal Immigrants Can Be A Legal Liability
  • 1.4 Nursery & Greenhouse Sector
    • 1.4.1 Harvest Automation Labor Process Automation
    • 1.4.2 The Growing Season Is Also The Shipping Season
  • 1.5 Improving Nursery Efficiency
    • 1.5.1 Small Mobile Robot for Plants and Shrubs
  • 1.6 Agricultural Producers Seek To Improve Operations
    • 1.6.1 Increasing Cows Days Of Grazing
  • 1.7 cRops (Clever Robots for Crops) Robots To Harvest High Value Crops
  • 1.8 European Union Seventh Framework Program
  • 1.9 Strawberries
    • 1.9.1 Strawberries in the US
  • 1.10 Transformational Agricultural Robots

Agricultural Robots Market Shares and Market Forecasts

2 AGRICULTURAL ROBOTS MARKET SHARE AND MARKET FORECASTS

  • 2.1 Agricultural Robot Market Driving Forces
    • 2.1.1 Agricultural Robot Target Markets
    • 2.1.2 Robotic Agriculture Trends
  • 2.2 Agricultural Robot Market Shares
    • 2.2.1 Lely Group Revenue
    • 2.2.2 Use Of Standard Industrial Robots In Agriculture
    • 2.2.3 Kuka 78
    • 2.2.4 Fanuc 79
    • 2.2.5 Agrobot High Value Crop Robotic Automation
    • 2.2.6 John Deere Autonomous Tractors
    • 2.2.7 Harvest Automation
    • 2.2.8 Vision Robotics
  • 2.3 Agricultural Robot Market Forecasts
    • 2.3.1 Agricultural Robot Market Segments
    • 2.3.2 Agricultural Robotics Key Economic Enabler
    • 2.3.3 High Value Fruit Crops: Strawberries
    • 2.3.4 Nursery And Garden Products
    • 2.3.5 Ornamental Plant Markets
    • 2.3.6 Golf courses Robotic Mowing
    • 2.3.7 Crop Dusting With Remote-Controlled Helicopters
    • 2.3.8 Distributed Robotics Garden
    • 2.3.9 Cultibotics
    • 2.3.10 Agricultural Robot Vision Pruning Systems
  • 2.4 Agricultural Robot Pricing
    • 2.4.1 Harvest Automation
    • 2.4.2 Shibuya Seiko Co. Strawberry Picking Robot
    • 2.4.3 Wall-Ye V.I.N. Robot Functions
    • 2.4.4 iRobot Automated Lawn Mowing
  • 2.5 Agricultural Robots TCO / ROI
    • 2.5.1 Cost Structures and Roles of Agricultural Robots
  • 2.6 Agricultural Robot Regional Analysis
    • 2.6.1 Production of Agricultural Robotics in China
    • 2.6.2 Chinese Agricultural Machinery
    • 2.6.3 Agricultural Robots in Africa

Agricultural Robots Product Description

3 AGRICULTURAL ROBOTS PRODUCT DESCRIPTION

  • 3.1 John Deere Autonomous Tractor
    • 3.1.1 John Deere Crop Spraying
  • 3.2 Kuka
    • 3.2.1 Kuka Robots in the Agricultural Industry
    • 3.2.2 Kuka Robots in the Food Processing Industry
    • 3.2.3 Kuka Automation in Agriculture
  • 3.3 FANUC
    • 3.3.1 Fanuc Vegetable Sorting Robot
    • 3.3.2 FANUC Robodrill DiA5 Series
  • 3.4 ABB Robots
    • 3.4.1 ABB Symphony Plus
  • 3.5 Yaskawa
    • 3.5.1 Yaskawa Industrial AC Drives 1/8 thru 1750 Horsepower
    • 3.5.2 Yaskawa Specialty Pump Drives 3/4 thru 500 Horsepower
    • 3.5.3 Yaskawa Servo Systems and Motion Controllers
    • 3.5.4 Motoman Robot Handling and Palletizing Bags of Livestock Feed
    • 3.5.5 Motoman Agriculture Robotics Palletizing Bags Solution
    • 3.5.6 Motoman Robotics Agricultural Robot Palletizing Bags Fixtures / Tooling Details
    • 3.5.7 Motoman Agricultural Grain Bin Dryer Fan Wheels
    • 3.5.8 Motoman Robotics Fixtures/Tooling Details
    • 3.5.9 Motoman Agricultural Irrigation Pipe
    • 3.5.10 Motoman Robotics Fixtures/Tooling Details
    • 3.5.11 Motoman Agricultural Equipment
    • 3.5.12 Motoman Robotics Fixtures/Tooling Details
    • 3.5.13 Motoman Round Baler Pickup Frames for Agricultural Equipment
    • 3.5.14 Motoman Robotics Fixtures/Tooling Details
    • 3.5.15 Motoman Skid Steer Loader Mount Plates
    • 3.5.16 Motoman Bags of Livestock Feed
    • 3.5.17 Motoman Robotics Fixtures/Tooling Details
  • 3.6 Harvest Automation
    • 3.6.1 Harvest Automation Technology
    • 3.6.2 Harvest Automation Behavior-Based Robotics
  • 3.7 Robotic Harvesting
    • 3.7.1 Robotic Harvesting Strawberry Harvester
  • 3.8 Agrobot SW 6010
    • 3.8.1 Agrobot AGB: Harvesting High Level System
    • 3.8.2 Agrobot AG Vision
  • 3.9 Blue River Technology
    • 3.9.1 Blue River Precision Lettuce Thinning - 40/42" Beds
    • 3.9.2 Blue River Precision Lettuce Thinning - 80/84" Beds
    • 3.9.3 Lettuce Bot, Blue River Technology
  • 3.10 cRops (Clever Robot for Crops)
    • 3.10.1 cRops European Project, Made Up Of Universities And Labs
  • 3.11 Jaybridge Robotics Agriculture
    • 3.11.1 Jaybridge Robotics Kinze Partnering, Autonomous Vehicle Row Crop Harvesting
    • 3.11.2 Jaybridge Software Expertise
  • 3.12 Nano Ganesh
  • 3.13 Aqua Spy
  • 3.14 8 Villages
  • 3.15 IBM / Bari Fishing Market App
  • 3.16 M Farm
  • 3.17 Sustainable Harvest
  • 3.18 Tractor Harvesting
  • 3.19 Spensa Technology Pest Control
  • 3.20 The Pebble Watch
  • 3.21 Louisiana State University AgBot
    • 3.21.1 AgBot Uses Autonomous, Advanced GPS System
    • 3.21.2 Agbot Small Robots Versatility
    • 3.21.3 Delivery Robot
  • 3.22 Harvard Robobee
    • 3.22.1 Harvard Robobee Practical Applications
    • 3.22.2 Harvard Robobee Vision and Aims
    • 3.22.3 Harvard Robobee Body, Brain, and Colony
    • 3.22.4 Harvard Robobee Body
    • 3.22.5 Harvard Robobee Flexible Insect Wings And Flight Stability In Turbulent Airflow
    • 3.22.6 Harvard Robobee Sensor Networks
    • 3.22.7 Harvard Robobee Colony
    • 3.22.8 Harvard Robobee Sensor Network Development
  • 3.23 iRobot's Automatic Lawn Mower
  • 3.24 MIT Autonomous Gardener Equipment Mounted On The Base of a Roomba
  • 3.25 Carnegie Mellon University's National Robotics Engineering Center
    • 3.25.1 Carnegie Mellon. Self-Guided Farm Equipment
  • 3.26 Cesar the LettuceBot
  • 3.27 Universidad Politécnica de Madrid Rosphere
    • 3.27.1 Rosphere Spherical Shaped Robot
  • 3.28 Shibuya Seiko Co.
    • 3.28.1 Shibuya Seiko Co. Strawberry Picking Robot
    • 3.28.2 Shibuya Seiko Robot Can Pick Strawberry Fields
  • 3.29 University of California, Davis Robots For Harvesting Strawberries
  • 3.30 Wall-Ye V.I.N. Robot
    • 3.30.1 Wall-Ye V.I.N. Robot Functions
    • 3.30.2 Wall-Ye V.I.N. Robot Security System
    • 3.30.3 Wall-Ye V.I.N. Robot Prunes 600 Vines Per Day
  • 3.31 Vision Robotics
    • 3.31.1 Vision Robotics Automated Tractors
  • 3.32 Nogchui Autonomous Tractor
    • 3.32.1 Professor Nogchui Agricultural Tractor Robot Uses Navigation Sensor Called AGI-3 GPS Compass Made by TOPCON
    • 3.32.2 Professor Nogchui Agricultural Tractor Robot Mapping System
    • 3.32.3 Nogchui Autonomous Tractor Robot Management Systems
  • 3.33 Microsoft Agricultural Robot Software
  • 3.34 Australian Centre for Field Robotics Herder Robot
    • 3.34.1 Robotic Rover Herds Cows
  • 3.35 Chinese Agricultural Robots
  • 3.36 Oracle Robot
  • 3.37 3D Robotics
  • 3.38 Lely Automatic Milking Robots
    • 3.38.1 Lely Astronaut Milking Robots
    • 3.38.2 Lely Concept and Management
    • 3.38.3 Lely Correct Feed Management
    • 3.38.4 Lely Milk Robots At Large Dairy Farms
    • 3.38.5 Lely Free Cow Traffic
  • 3.39 Kyoto University Tomato Harvesting Robot
  • 3.40 Yamaha Crop Dusting Drones
  • 3.41 RHEA Robot Fleets for Accuracy
    • 3.41.1 RHEA Synchronoized Weeding
    • 3.41.2 Synchronized Spraying
  • 3.42 Precise Path Robotics

Agricultural Robots Technology

4. AGRICULTURAL ROBOTS TECHNOLOGY

  • 4.1 Harvest Automation Proprietary Sensor Technology
    • 4.1.1 Harvest Automation Robot System Architecture
    • 4.1.2 Harvest Automation Technology
    • 4.1.3 Behavior-Based Robotics
    • 4.1.4 Proprietary Sensor Technology
    • 4.1.5 System Design & Architecture
  • 4.2 Welding Robots
  • 4.3 Material Handling Robots:
  • 4.4 Plasma Cutting Robots:
  • 4.5 Agricultural Robotics and Automation Scope:
    • 4.5.1 IEEE Standards Initiatives
    • 4.5.2 Delft Robotics Institute
  • 4.6 Robotics and Automation
  • 4.7 An Electronic System Improves Different Agriculture Processes

Agricultural Robots Company Profiles

5 AGRICULTURAL ROBOTS COMPANY DESCRIPTION

  • 5.1 ABB Robotics
    • 5.1.1 ABB Revenue
    • 5.1.2 ABB Strategy
    • 5.1.3 ABB Global Leader In Power And Automation Technologies
    • 5.1.4 ABB and IO Deliver Direct Current-Powered Data Center Module
    • 5.1.5 ABB / Validus DC Systems DC Power Infrastructure Equipment
    • 5.1.6 ABB Technology
    • 5.1.7 ABB Global Lab Power
    • 5.1.8 ABB Global Lab Automation
  • 5.2 Agile Planet
  • 5.3 AgRA: RAS Agricultural Robotics and Automation (AgRA
  • 5.4 Agrobot
    • 5.4.1 Agrobot Innovation and Technology for Agribusiness
  • 5.5 Astronaut
  • 5.6 Australian Centre for Field Robotics
  • 5.7 Blue River Technology
    • 5.7.1 Blue River / Khosla Ventures
  • 5.8 CNH Industrial / Fiat / Case IH
    • 5.8.1 Case IH Customers Work Directly With Design Engineers
  • 5.9 cRops
  • 5.10 Fanuc
    • 5.10.1 FANUC Corporation
    • 5.10.2 Fanuc Revenue
  • 5.11 Georgia Tech Agricultural Robots
  • 5.12 Google
    • 5.12.1 Google / Boston Dynamics
    • 5.12.2 Boston Dynamics LS3 - Legged Squad Support Systems
    • 5.12.3 Boston Dynamics CHEETAH - Fastest Legged Robot
    • 5.12.4 Boston Dynamics Atlas - The Agile Anthropomorphic Robot
    • 5.12.5 Boston Dynamics BigDog
    • 5.12.6 Boston Dynamics LittleDog - The Legged Locomotion Learning Robot
    • 5.12.7 Google Robotic Division
    • 5.12.8 Google Self-Driving Car
    • 5.12.9 Google Cars Address Vast Majority Of Vehicle Accidents Due To Human Error
    • 5.12.10 Google Business
    • 5.12.11 Google Corporate Highlights
    • 5.12.12 Google Search
    • 5.12.13 Google Revenue
    • 5.12.14 Google Second Quarter 2013 Results
    • 5.12.15 Google Revenues by Segment and Geography
    • 5.12.16 Google / Motorola Headcount
    • 5.12.17 Google / Motorola
  • 5.13 Harvard Robobee
    • 5.13.1 Harvard Robobee Funding
    • 5.13.2 Harvard Robobee Main Area Of Research
    • 5.13.3 Harvard Robobee OptRAD is used as an Optimizing Reaction-Advection-Diffusion system.
    • 5.13.4 Harvard Robobee The Team
  • 5.14 Harvest Automation
    • 5.14.1 Harvest Automation Ornamental Horticulture
    • 5.14.2 Harvest Automation M Series C Financing
    • 5.14.3 Harvest Robotic Solutions For The Agricultural Market
    • 5.14.4 Harvest Automation Robots
  • 5.15 IBM
    • 5.15.1 IBM Strategy
    • 5.15.2 IBM Business Partners
    • 5.15.3 IBM Messaging Extension for Web Application Pattern
    • 5.15.4 IBM MobileFirst
    • 5.15.5 IBM Business Analytics and Optimization Strategy
    • 5.15.6 IBM Growth Market Initiatives
    • 5.15.7 IBM Business Analytics and Optimization
    • 5.15.8 IBM Strategy
    • 5.15.9 IBM Smarter Planet
    • 5.15.10 IBM Cloud Computing
    • 5.15.11 IBM Business Model
    • 5.15.12 IBM Business Revenue Segments And Capabilities
  • 5.16 iRobot
    • 5.16.1 iRobot Home Robots:
    • 5.16.2 iRobot Defense and Security: Protecting Those in Harm's Way
    • 5.16.3 iRobot Role In The Robot Industry
    • 5.16.4 iRobot SPARK (Starter Programs for the Advancement of Robotics Knowledge)
    • 5.16.5 iRobot Revenue
    • 5.16.6 iRobot Acquires Evolution Robotics, Inc.
    • 5.16.7 iRobot / Evolution Robotics
  • 5.17 Jaybridge Robotics
    • 5.17.1 Jaybridge Robotics Software Solutions
    • 5.17.2 Jaybridge Systems Integration for Autonomous Vehicles
    • 5.17.3 Jaybridge Robotics Rigorous Quality Processes
    • 5.17.4 Jaybridge Robotics Professional, Experienced Team
    • 5.17.5 Jaybridge Robotics Seamless Working Relationship with Client Teams 377
  • 5.18 Kuka
    • 5.18.1 Kuka Revenue
    • 5.18.2 Kuka Competition
    • 5.18.3 Kuka Innovative Technology
    • 5.18.4 Kuka Well Positioned With A Broad Product Portfolio In Markets With Attractive Growth Prospects
    • 5.18.5 Kuka Strategy
    • 5.18.6 Kuka Corporate Policy
  • 5.19 KumoTek
    • 5.19.1 KumoTek Robotics Software Specialists
  • 5.20 Kyoto University
  • 5.21 Lely
    • 5.21.1 Lely Group Business Concepts
    • 5.21.2 Lely Group Revenue
  • 5.22 Millennial Net
    • 5.22.1 Millennial Net Wireless Sensor Network:
    • 5.22.2 Millennial Net 1000-Node MeshScape GO Wireless Sensor Network (WSN) Agricultural Sensors
    • 5.22.3 Millennial Net's MeshScape GO WSN Technology
  • 5.23 National Agriculture and Food Research Organization
    • 5.23.1 NARO, a Japanese Incorporated Administrative Agency
    • 5.23.2 National Agriculture and Food Research Organization (NARO) third mid-term plan (from 2011 to 2015)
    • 5.23.3 National Agriculture and Food Research Organization Stable Food Supply
    • 5.23.4 National Agriculture and Food Research Organization Development For Global-Scale Issues And Climate Change
    • 5.23.5 National Agriculture and Food Research Organization Development To Create Demand For New Food Products
    • 5.23.6 National Agriculture and Food Research Organization Development For Utilizing Local Agricultural Resources
    • 5.23.7 Japanese National Agriculture and Food Research Organization
  • 5.24 Ossian Agro Automation / Nano Ganesh
  • 5.25 Precise Path Robotics
  • 5.26 Robotic Harvesting
  • 5.27 Sicily Tractor Harvesting
  • 5.28 Shibuya Seiki
    • 5.28.1 Shibuya Kogyo Pharmaceutical Application Examples
    • 5.28.2 Shibuya Kogyo Robotic System For Handling Soft Infusion Bags
    • 5.28.3 Shibuya Kogyo Robotic Cell Culture System "CellPRO"
    • 5.28.4 Shibuya Kogyo Robotic System For Leaflet & Spoon Placement
    • 5.28.5 Shibuya Kogyo Robotic Collating System
    • 5.28.6 Shibuya Kogyo Automated Aseptic Environmental Monitoring System
  • 5.29 Universidad Politécnica de Madrid
  • 5.30 University of California, Davis
  • 5.31 Wall-Ye V.I.N. Robot
  • 5.32 Yamaha
  • 5.33 Yaskawa
    • 5.33.1 Yaskawa Revenue
    • 5.33.2 Yaskawa Business
    • 5.33.3 YASKAWA Electric Motion Control
    • 5.33.4 YASKAWA Electric Robotics
    • 5.33.5 YASKAWA Electric System Engineering
    • 5.33.6 YASKAWA Electric Information Technology
    • 5.33.7 Yaskawa / Motoman
  • 5.34 Agricultural Robotic Research Labs
    • 5.34.1 Outdated links
    • 5.34.2 Agricultural Robotic Companies
    • 5.34.3 IEEE Agricultural Technical Committee
    • 5.34.4 Agricultural Robotic Conferences
    • 5.34.5 Agricultural Robotic Publications
    • 5.34.6 Selected VC Funding In Robotics

List of Tables and Figures

Agricultural Robots Executive Summary

  • Figure ES-1 Agrobot Strawberry Picker
  • Table ES-2 Agricultural Robot Market Driving Forces
  • Table ES-3 Agricultural Robot Target Markets
  • Table ES-4 Robotic Agricultural Trends
  • Table ES-5 Agriculture Robotic Activities
  • Table ES-6 Market Forces for Agricultural Modernization
  • Table ES-7 Robotics - State of the Art Advantages
  • Table ES-8 Agricultural Robot Challenges
  • Figure ES-9 Agricultural Robot Market Shares, Dollars, Worldwide, 2013
  • Figure ES-10 Agricultural Robot Market Forecasts Dollars, Worldwide, 2014-2020

Agricultural Robots Market Description and Market Dynamics

  • Table 1-1 Aspects of Agricultural Sector Modernization
  • Figure 1-2 Agricultural Robotics Positioned To Meet The Increasing Demands For Food And Bioenergy Source: John Deere.
  • Figure 1-3 Autonomous Orchard Vehicle
  • Figure 1-4 Automated Picker Machine
  • Table 1-5 Nursery Robot Benefits
  • Figure 1-6 Cows Grazing
  • Figure 1-7 European Union Seventh Framework Program cRops Clever Robots for Crops) Focus On Harvesting High Value Crops
  • Figure 1-8 Transformational Agricultural Robots

Agricultural Robots Market Shares and Market Forecasts

  • Figure 2-1 Agrobot Strawberry Picker
  • Table 2-2 Agricultural Robot Market Driving Forces
  • Table 2-3 Agricultural Robot Target Markets
  • Table 2-4 Robotic Agricultural Trends
  • Table 2-5 Agriculture Robotic Activities
  • Table 2-6 Market Forces for Agricultural Modernization
  • Table 2-7 Robotics - State of the Art Advantages
  • Table 2-8 Agricultural Robot Challenges
  • Figure 2-9 Agricultural Robot Market Shares, Dollars, Worldwide, 2013
  • Table 2-10 Agricultural Robot Market Shares, Dollars, Worldwide, 2013
  • Figure 2-11 Agrobot Strawberry Picker
  • Figure 2-12 John Deere Autonomous Tractors
  • Figure 2-13 Agricultural Robot Market Forecasts Dollars, Worldwide, 2014-2020
  • Table 2-14 Agricultural Robot Market Forecast, Shipments, Dollars, Worldwide, 2014-2020
  • Table 2-15 Agricultural Robot Market Industry Segments, Cow Milking and Barn Systems, Strawberries and High Value Crops, Wheat, Rice, Corn Harvesting, Grape Pruning and Harvesting, Nursery Management, Golf Course and Lawn Mowing, Drone Crop Dusting Segments, Dollars, Worldwide, 2014-2020
  • Table 2-16 Agricultural Robot Market Industry Segments, Cow Milking and Barn Systems, Strawberries and High Value Crops, Wheat, Rice, Corn Harvesting, Grape Pruning and Harvesting, Nursery Management, Golf Course and Lawn Mowing, Drone Crop Dusting Segments, Percent , Worldwide, 2014-2020
  • Figure 2-17 Multiple Small Intelligent Machines Replace Large Manned Tractors
  • Table 2-18 Agricultural Robots for Ornamental Plant Handling Benefits
  • Figure 2-19 UC Davis Using Yahama Helicopter Drones For Crop Dusting
  • Figure 2-20 Yahama Crop Duster
  • Figure 2-21 Distributed Robotics Garden
  • Figure 2-22 Modernized Agriculture Telegarden, As Installed At Ars Electronica
  • Table 2-23 Voluntary Cow Traffic Benefits
  • Table 2-24 Cow Traffic System Cubicles ROI Metrics
  • Table 2-25 Lely Example of Herd Size and Robots / Farm Worker
  • Table 2-26 Roles of Agricultural Robots
  • Figure 2-27 Cost Structures and Roles of Agricultural Robots
  • Figure 2-28 Agricultural Robotic Regional Market Segments, 2013
  • Table 2-29 Agricultural Robot Regional Market Segments, 2013

Agricultural Robots Product Description

  • Figure 3-1 John Deere Autonomous Tractors
  • Figure 3-2 John Deere Autonomous Tractor Flexible Uses
  • Figure 3-3 John Deere Crop Spraying
  • Figure 3-4 Kuka Agricultural Robots
  • Figure 3-5 Kuka Material Handling Robots
  • Figure 3-6 Kuka Industry Standard Robots Used in Agriculture
  • Figure 3-7 Kuka Welding Robots in the Agricultural Industry
  • Figure 3-8 Kuka Robots in the Agricultural Industry
  • Figure 3-9 Kuka Robots in the Food Processing Industry
  • Figure 3-10 Kuka Agricultural Robots
  • Figure 3-11 Kuka Plasma Cutting Robot
  • Figure 3-12 Fanuc M-3iA Robots Sorting Boxes
  • Figure 3-13 FANUC Robodrill DiA5 Series
  • Figure 3-14 FANUC Welding Robots
  • Figure 3-15 FANUC Material Handling Robots
  • Figure 3-16 FANUC Plasma Cutting Robot
  • Figure 3-17 ABB Welding Robots
  • Figure 3-18 ABB Material Handling Robots
  • Figure 3-19 Yaskawa Plasma Cutting Robot
  • Figure 3-20 Yaskawa Robots Used in Agriculture
  • Figure 3-21 Yaskawa Industrial AC Drives 1/8 thru 1750 Horsepower
  • Figure 3-22 Yaskawa Specialty Pump Drives 3/4 thru 500 Horsepower
  • Figure 3-23 Motoman Robot Handling and Palletizing Bags of Livestock Feed
  • Table 3-24 Motoman Robot Handling and Palletizing Bags of Livestock Feed Project Challenges
  • Table 3-25 Motoman Agriculture Robotics Palletizing Bags Solution
  • Table 3-26 Motoman Agricultural Grain Bin Dryer Fan Wheels Project Challenges
  • Table 3- 27 Motoman Agricultural Grain Bin Dryer Fan Wheels Robotics Solution
  • Figure 3-28 Motoman Agricultural Irrigation Pipe
  • Table 3-29 Motoman Agricultural Irrigation Pipe Project Challenges
  • Table 3-30 Motoman Agricultural Irrigation Pipe Robotics Solution
  • Figure 3-31 Motoman Agricultural Equipment
  • Table 3-32 Motoman Agricultural Equipment Project Challenges
  • Table 3-33 Motoman Agricultural Equipment Robotics Solution
  • Figure 3-34 Motoman Round Baler Pickup Frames for Agricultural Equipment
  • Table 3-35 Motoman Round Baler Pickup Frames for Agricultural Equipment Project Challenges
  • Table 3-36 Motoman Round Baler Pickup Frames for Agricultural Equipment Robotics Solution
  • Figure 3-37 Motoman Skid Steer Loader Mount Plates
  • Table 3-38 Motoman Skid Steer Loader Mount Plates Project Challenges
  • Table 3-39 Motoman Skid Steer Loader Mount Plates Robotics Solution
  • Figure 3-40 Motoman Bags of Livestock Feed
  • Table 3-41 Motoman Bags of Livestock Feed Project Challenges
  • Table 3-42 Motoman Bags of Livestock Feed Robotics Solution
  • Figure 3-43 Harvest Automation Shrub Robot
  • Figure 3-44 Harvest Automation Shrub Robot In Garden
  • Figure 3-45 Harvest Automation Robot Provides Marketplace Sustainability
  • Table 3-46 Harvest Automation Shrub Robot Features:
  • Table 3-47 Harvest Automation Shrub Robot Functions:
  • Figure 3-48 Robotic Harvesting of Strawberries
  • Figure 3-49 Agrobot SW 6010
  • Figure 3-50 Agrobot AGB: Harvesting High Level System
  • Figure 3-51 Agrobot AG Vision
  • Figure 3-60 Blue River Technology Agricultural Robot
  • Figure 3-61 Blue River Precision Lettuce Thinning Agricultural Robot
  • Table 3-62 Blue River Technology Agricultural Robot Functions
  • Figure 3-63 Blue River Precision Lettuce Thinning - 80/84" beds
  • Table 3-64 cRops Robotic Platform Functions
  • Table 3-65 cRops Robot System European Project Supporters
  • Figure 3-66 cRops Robot System
  • Figure 3-67 cRops Robot Target System
  • Figure 3-68 Jaybridge Robotics Driverless Tractor
  • Figure 3-69 IBM / Bari Fishing Market App
  • Figure 3-70 IBM / Bari Real Time Fishing Market App
  • Figure 3-71 IBM / Bari Fishing Market Need Matching App
  • Figure 3-72 Small Tractor Used For Manual Artichokes Harvesting
  • Figure 3-73 LSU AgBot
  • Table 3-74 Harvard Robobee Robot Applications
  • Table 3-75 Nature-Inspired Robotic Research Aims
  • Figure 3-76 Robobee Boby, Brain, Colony
  • Figure 3-77 Harvard Robobee Propulsive Efficiency
  • Figure 3-78 Robobee Boby, Brain, Colony
  • Figure 3-79 Harvard Robobee Studies of Stability And Control In Unsteady, Structured Wakes
  • Table 3-80 Harvard Robobee Sensor Networks
  • Figure 3-81 Harvard Robobee Computationally-Efficient Control System
  • Table 3-82 Harvard Robobee Sensor Network Design Challenges
  • Table 3-83 Harvard Robobee Challenges In Development Of A Sensor Network
  • Table 3-84 Harvard Robobee Sensor Network Context Challenges
  • Table 3-85 Harvard Robobee Sensor Network Elements
  • Table 3-86 Harvard Robobee Sensor Network Limitations
  • Table 3-87 Harvard Robobee Software Language Limitations
  • Table 3-88 Harvard Robobee Software Language Current Efforts
  • Figure 3-89 Robomow RL850 Automatic Lawn Mower
  • Figure 3-90 MIT smart gardener robot
  • Figure 3-91 Carnegie Mellon Self-Guided Farm Equipment
  • Figure 3-92 Carnegie Mellon Self-Guided Equipment Running on Farm
  • Figure -3-93 Cesar the LettuceBot
  • Figure 3-94 Benefits of Lettuce Harvesting Robot
  • Figure 3-95 Rosphere
  • Figure 3-96 Rosphere Induction Of Forward/Backward And Turning Movements
  • Figure 3-97 University of California, Davis Robot For Harvesting Strawberries
  • Table 3-98 Wall-Ye V.I.N. Robot Functions
  • Table 3-99 Wall-Ye V.I.N. Robot Technology
  • Table 3-100 Wall-Ye V.I.N. Robot Features
  • Figure 3-101 Vision Robotics Snippy Robotic Vine Pruner
  • Figure 3-102 Nogchui Autonomous Tractor Grading
  • Figure 3-103 Nogchui Autonomous Tractor Working Field
  • Figure 3-104 Professor Nogchui Autonomous Tractor Navigation Map Information
  • Figure 3-105 Microsoft Agricultural Robot Software
  • Figure 3-106 Herder Robotic Rover
  • Figure 3-107 Chinese Farmbot Tractor Image
  • Figure 3-108 3D Robotics
  • Figure 3-109 3D Robotics Drone Spray Application
  • Figure 3-110 3D Robotics Uses Pesticides And Fungicides Only When Needed
  • Figure 3-111 3D Robotics Data For Marketing
  • Figure 3-112 3D Robotics Aerial Views of Crops
  • Figure 3-113 3D Robotics Aerial Views Multicopter To Fly Over Vineyards
  • Figure 3-114 Lely Automatic Milking
  • Figure 3-115 Astronaut Milking Robot
  • Figure 3-116 Lely Milking System Farm
  • Figure 3-117 Lely Cattle Feeding System Farm
  • Figure 3-118 Lely Automated Process for Managing Milking and Farm
  • Figure 3-119 Lely Correct Cattle Feeding Management
  • Figure 3-120 Lely Automated Process Cattle Feeding Management
  • Figure 3-121 Lely Multi-Barn Cattle Feeding Management
  • Figure 3-122 Lely Cattle Milking Management
  • Figure 3-123 Kyoto University Tomato Harvesting Robot
  • Figure 3-124 Kyoto University Fruit Harvesting Robots In Greenhouse
  • Figure 3-125 Kyoto University Tomato Cluster Harvesting Robot
  • Figure 3-126 Kyoto University Strawberry Harvesting Robot In Plant Factory
  • Figure 3-127 RHEA Robot Fleets for Seeding
  • Figure 3-128 RHEA Robot Fleet Mapping for Seeding
  • Figure 3-129 Robot Fleet Deterministic Route Planning for Seeding
  • Figure 3-130 Orthogonal Inter Row Mechanical Weeding for Organic Farming
  • Table 3-131 HGCA Laser Weeding
  • Figure 3-132 RHEA Laser Weeding
  • Figure 3-133 RHEA Horibot Cutter and Sprayer
  • Figure 3-134 RHEA Broad leafed Weed Sensing And Spraying
  • Table 3-135 RHEA Broad Leafed Weed Sensing And Spraying
  • Figure 3-136 RHEA Multiple Small Intelligent Machines Replace Large Manned Tractors
  • Figure 3-137 RHEA Cooperative Fleet Of Robots
  • Figure 3-138 RHEA Hexacopter (Aerial Mobile Unit)

Agricultural Robots Technology

  • Table 4-1 Harvest Automation Proprietary Sensor Technology Functions
  • Table 4-2 Harvest Automation Robot System Architecture
  • Table 4-3 Proprietary Sensor Technology
  • Table 4-4 System Design & Architecture
  • Table 4-5 Tight Scientific Collaboration Between Different Disciplines
  • Figure 4-6 IEEE Agricultural Robots
  • Figure 4-7 IEEE Orchard Robots
  • Figure 4-8 IEEE Automated Agricultural Robot

Agricultural Robots Company Profiles

  • Table 5-1 ABB Product Launches
  • Table 5-2 ABB Global Lab Target Technologies
  • Table 5-3 ABB's Global Lab Automation Target Solutions
  • Table 5-4 ABB Active Current Research Areas
  • Figure 5-5 Agrobot Strawberry Picker
  • Figure 5-6 Agrobot Strawberry Picker
  • Figure 5-7 Agrobot Robot for Agriculture
  • Table 5-8 Agrobot Innovation and Technology for Agribusiness
  • Figure 5-9 Agrobot Innovation and Technology for Agribusiness
  • Table 5-10 Agrobot SW6010 Support
  • Table 5-11 cRops technology Functions
  • Table 5-12 cRops Intelligent Tools
  • Table 5-13 cRops Target Markets
  • Table 5-14 cRops Robotic Platform Customized Automated Processes
  • Figure 5-15 Fanuc Revenue
  • Figure 5-16 Fanuc Revenue
  • Figure 5-17 Boston Dynamic LS3
  • Figure 5-18 Boston Dynamic CHEETAH
  • Figure 5-19 Boston Dynamic Atlas
  • Figure 5-20 Boston Dynamic BigDog
  • Figure 5-21 Boston Dynamics LittleDog -
  • Table 5-22 Google Autonomous Vehicles Technology
  • Table 5-23 Harvard Robobee Project Characteristics
  • Figure 5-24 Harvard Robobee Kilobot Robot Group
  • Table 5-25 Harvest Automation Robot Navigation
  • Table 5-26 Harvest Automation Robot Sensor Network Functions
  • Table 5-27 IBM Systems Target Industries
  • Table 5-28 Jaybridge Robotics Software Solutions
  • Table 5-29 Jaybridge Robotics Software Functions
  • Figure 5-30 Kuka Positioning with Smart Tools
  • Figure 5-31 Lely's Astronaut A4 Milking Robot
  • Table 5-32 Millennial Net's MeshScape System Functions
  • Table 5-33 MeshScape GO Deployment Components:
  • Table 5-34 National Agriculture and Food Research Organization (NARO) Plan Goals
  • Figure 5-35 Precise Path Robotics
  • Figure 5-36 Sicily Small Tractor Used For Manual Artichoke Harvesting
  • Figure 5-37 Shibuya Kogyo Robotic System For Leaflet & Spoon Placement
  • Figure 5-38 Shibuya Kogyo Robotic Collating System
  • Figure 5-39 Shibuya Kogyo Automated Aseptic Environmental Monitoring System
  • Table 5-40 Universidad Politécnica de Madrid Projects
  • Figure 5-41 UC Davis Using Yahama Helicopter Drones For Crop Dusting
  • Figure 5-42 Yamaha Crop Dusting Initiatives
  • Figure 5-43 YASKAWA Electric Group Businesses
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