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市場調查報告書

農業用機器人:市場佔有率、策略、預測 (2017-2023年)

Agricultural Robots: Market Shares, Strategies, and Forecasts, 2017 to 2023

出版商 WinterGreen Research, Inc. 商品編碼 294411
出版日期 內容資訊 英文 668 Pages
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農業用機器人:市場佔有率、策略、預測 (2017-2023年) Agricultural Robots: Market Shares, Strategies, and Forecasts, 2017 to 2023
出版日期: 2017年05月02日 內容資訊: 英文 668 Pages
簡介

全球農業用機器人的市場預計從2016年的17億美元,成長到2023年的271億美元的規模。

本報告提供全球農業用機器人的市場調查,市場定義和概要,市場的各種影響因素分析,主要企業的市場佔有率,產品/系統類型、功能、工作用途等各種區分的趨勢與市場規模的變化與預測,主要產品以及主要企業的簡介等彙整。

摘要整理

第1章 市場概要、市場動態

  • 農業市場數位化
  • 農業用機器人的課題
  • 農業的自動化
  • 精密農業機器人的大群
  • 農業用機器人和無人機:技術、市場預測
  • AgRA (RAS Agricultural Robotics and Automation) Technical Committee
  • FarmBot
  • 育苗效率的改善
  • 尋求運用改善的農業生產者
  • 農業工作用廉價的機器人
  • 收穫高價值作物用cRops (Clever Robots for Crops)
  • 草莓
  • 變形農業用機器人

第2章 市場佔有率、市場預測

  • 市場促進因素
  • 主要企業的市場佔有率
  • 市場預測
    • 目標市場
    • 農業用機器人
      • 無人曳引機
      • 擠奶系統
      • 精密工作架構
      • 灌溉系統
    • 精密工作機器人
      • 小麥、米、玉米的收穫
      • 葡萄、其他整枝、收穫
      • 高爾夫球場、割草
      • 育苗管理
      • 播種、種植、施肥
      • 噴霧
      • 無人機農藥散佈
    • 高價值水果:草莓
    • 育苗、庭園產品
    • 欣賞植物市場
    • 遠距離操縱直升機的農藥散佈
    • 分散式機器人園藝
    • Cultibotics
    • 機器人視覺的修剪系統
    • 機器魚
    • 農場技術
    • 高爾夫球場的機器人割草機
    • 自動駕駛曳引機機器人
    • 主要的經濟實現因素
    • 擠奶機器人的市場佔有率、市場預測
    • Lely Astronaut的擠奶機器人
    • 農業灌溉用機器人市場預測
  • 農業、氣象IoT
  • 價格
  • TCO / ROI
  • 地區分析

第3章 主要產品概要

第4章 自動收穫專用感應技術

  • 自動收穫機器人系統結構
  • 精密農業的各種技術
  • 灌溉
  • IoT
  • 感測器
  • 可變率播種
  • 氣象建模
  • 氮建模
  • 標準化
  • FarmBot DIY農業機器人
  • 焊接機器人
  • 物料搬運機器人
  • 電漿切割機器人
  • 農業用機器人與自動化的展望
  • 機器人工學與自動化
  • 電子系統的各種農業流程的改善

第5章 主要企業概要

圖表

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目錄
Product Code: #27035999

Agriculture is the second greatest source of employment worldwide, and the least automated of all industries. Agriculture is the largest remaining opportunity for automation. Agriculture has become more mechanized so that many crops are harvested using machinery worldwide. Agricultural continues its declining employment trend as robotics are adopted.

Lely robotic cow milking systems target large dairy farms implement innovation in agriculture. Successful robotic milking on farms with more than 500 cows is supported. Agriculture faces enormous challenges over the coming decades. Agricultural entrepreneurs have to keep pace with rapid population growth and the need to deliver food at progressively more competitive prices.

Lely supports technical revolutions that help evolve automated process, ranging from forage harvesting machines to milking, feeding and barn equipment. Lely equipment allows successfully increasing the scale of operations.

Safeguarding optimum animal welfare and return on investment is the aim. By partnering with Lely on the milking automation journey, creates benefit from a unique set of management instruments to monitor milk quality, feed/milk conversion ratio for the individual cow or the complete herd. Lely continues to develop knowledge and products for the future. A basic requirement for profitable robotic milking includes attention to feed/milk efficiency.

Freedoms include permitting cows to achieve well-being by achieving more freedom, making it so that the farmers get the most out of their herd. Lely discovered that farmers who use free cow traffic are more successful with robotic milking.

According to Susan Eustis, principal author of the study, "Using cow milking systems, ore milk per cow and more milk per robot is being achieved. Systems work with less difficulty and with the possibility of working more sociable hours. Many farmers who used to use forced systems have changed over to free cow traffic flow in order to benefit from the advantages of robotic milking."

Robots are used for harvesting. 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.

Employment opportunity will come from human implementation of digitation, building APIs that make digital connections and building algorithms that make sense of digital data collected. There is plenty of work for humans to figure out how to react to alerts generated by digital algorithms.

The market for agricultural robots at $1.7 billion in 2016 is expected to grow to $27.1 billion by 2023. Agricultural Robots: users harness robots to plow, plant, spray, prune, milk, pick, shear, and harvest. As economies of scale are achieved, markets will grow rapidly.

Table of Contents

Agricultural Robot Market Executive Summary

  • Agricultural Robot Market Driving Forces
  • Agricultural Robot Target Markets
  • Robotic Agriculture Trends
  • Agriculture as Part of the Global Economy
  • Role of Agricultural Robots
  • Agricultural Robot Technologies
  • Agricultural Robotic Use of Global Positioning
  • Agricultural Robot Market Shares

1. Agricultural Robot Market Description and Market Dynamics

  • 1.1 Digitization of Agricultural Markets
    • 1.1.1 Shift to Digital Agriculture
    • 1.1.2 Digital Farms a Reality
  • 1.2 Challenges of Agricultural Robots
  • 1.3 Automation In The Agricultural Industry
    • 1.3.1 Robots Find A Place in the Agriculture Industry
    • 1.3.2 Agricultural Robots Make Production More Efficient
    • 1.3.3 Use Of Industrial Robots for Agriculture
    • 1.3.4 Agricultural Robotics and Automation
    • 1.3.5 Precision Agriculture Info, Analysis, Tools
    • 1.3.6 Automatic Guidance
    • 1.3.7 Autonomous Machines
    • 1.3.8 Drones
    • 1.3.9 Breeding + Sensors + Robots
  • 1.4 Swarms of Precision Agriculture Robots
  • 1.5 Agricultural Robots and Drones: Technologies, Markets, Forecasts
  • 1.6 RAS Agricultural Robotics and Automation (AgRA) Technical Committee
  • 1.7 Farm Bots Pick, Plant and Drive
    • 1.7.1 Relying On Illegal Immigrants Can Be A Legal Liability
    • 1.7.2 Harvest Automation Labor Process Automation
    • 1.7.3 The Growing Season Is Also The Shipping Season
  • 1.8 Improving Nursery Efficiency
    • 1.8.1 Small Mobile Robot for Plants and Shrubs
  • 1.9 Agricultural Producers Seek To Improve Operations
    • 1.9.1 Increasing Cows Days Of Grazing
  • 1.10 Inexpensive Robots For Farm Jobs
  • 1.11 cRops (Clever Robots for Crops) Robots To Harvest High Value Crops
  • 1.12 Strawberries
    • 1.12.1 Strawberries in the US
  • 1.13 Transformational Agricultural Robots

2. Agricultural Robots Market Shares and Market Forecasts

  • 2.1 Agricultural Robot Market Driving Forces
    • 2.1.1 Agricultural Robot Target Markets
    • 2.1.2 Robotic Agriculture Trends
    • 2.1.3 Agriculture as Part of the Global Economy
    • 2.1.4 Role of Agricultural Robots
    • 2.1.5 Agricultural Robot Technologies
    • 2.1.6 Agricultural Robotic Use of Global Positioning
  • 2.2 Agricultural Robot Market Shares
    • 2.2.1 Lely Group Revenue
    • 2.2.2 Kuka Use Of Standard Industrial Robots In Agriculture
    • 2.2.3 Kuka
    • 2.2.4 Fanuc
    • 2.2.5 Agrobot High Value Crop Robotic Automation
    • 2.2.6 Farmers Business Network
    • 2.2.7 Granular
    • 2.2.8 John Deere
    • 2.2.9 Harvest Automation
    • 2.2.10 Vision Robotics
    • 2.2.11 Blue River Technology
    • 2.2.12 Blue River
    • 2.2.13 ecoRobotix
    • 2.2.14 Tetra Laval / DeLaval
  • 2.3 Agricultural Robot Market Forecasts
    • 2.3.1 Agricultural Robot Target Markets
    • 2.3.2 Agricultural Robot Market Segments Driverless Tractors, Cow Milking Systems, Process Precision Architecture, and Irrigation Systems
    • 2.3.3 Process Precision Agricultural Robot Segments, Wheat, Rice, and Corn Harvesting, Grape and Other Pruning and Harvesting, Golf Course and Lawn Mowing, Nursery Management, Seeding, Planting, Fertilizing, Spraying, Drone Crop Dusting
    • 2.3.4 High Value Fruit Crops: Strawberries
    • 2.3.5 Nursery And Garden Products
    • 2.3.6 Ornamental Plant Markets
    • 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
    • 2.3.11 Robot Fish
    • 2.3.12 Farm Technologies
    • 2.3.13 Golf Courses Robotic Mowing
    • 2.3.14 Agricultural Self Driving Tractor Robot Market Forecasts
    • 2.3.15 Agricultural Robotics Key Economic Enablers
    • 2.3.16 Agricultural Cow Milking Robot Market Shares and Market Forecasts
    • 2.3.17 Lely Astronaut Milking Robots
    • 2.3.18 Agricultural Irrigation Robots Market Forecasts
  • 2.4 Agricultural and Weather IoT
    • 2.4.1 Agricultural Internet of Things (IoT)
    • 2.4.2 Agriculture IoT Food Production Increases
    • 2.4.3 Agriculture IoT: Global Shift to Use of Sensors
    • 2.4.4 Agriculture Internet of Things: Venture Investment
    • 2.4.5 Agriculture Internet of Things (IoT) Technology
    • 2.4.6 IoT Crop Water Management
    • 2.4.7 Precision Agriculture
    • 2.4.8 Agricultural Drone Sensors
    • 2.4.9 Integrated Pest Management or Control (IPM/C)
    • 2.4.10 Food Production and Food Safety
    • 2.4.11 Agriculture IoT Animal Monitoring
    • 2.4.12 Agriculture Internet of Things (IoT) Applications
    • 2.4.13 CLAAS IoT Equipment
  • 2.5 Agricultural Robot Pricing
    • 2.5.1 Harvest Automation
    • 2.5.2 Shibuya Seiko Co. Strawberry Picking Robot
    • 2.5.3 Wall-Ye V.I.N. Robot Functions
    • 2.5.4 iRobot Automated Lawn Mowing
  • 2.6 Agricultural Robots TCO / ROI
    • 2.6.1 Cost Structures and Roles of Agricultural Robots
  • 2.7 Agricultural Robot Regional Analysis
    • 2.7.1 European Union Seventh Framework Program
    • 2.7.2 Netherlands Agricultural Robots
    • 2.7.3 Production of Agricultural Robotics in China
    • 2.7.4 Chinese Agricultural Machinery
    • 2.7.5 Japanese Robot Farm Vegetables
    • 2.7.6 Agricultural Robots in Africa

3. Agricultural Robots Product Description

  • 3.1 John Deere
    • 3.1.1 John Deere Autonomous Mower
    • 3.1.2 Deere Smaller Tractors Autonomous Driving in Groups
    • 3.1.3 John Deere Autonomous Tractor
    • 3.1.4 John Deere Crop Spraying
    • 3.1.5 John Deere Autonomous Tractors
  • 3.2 AGCO
  • 3.3 CNH Industrial Case IH Tractors
  • 3.4 Kuka
    • 3.4.1 Kuka Robots in the Agricultural Industry
    • 3.4.2 Kuka Robots in the Food Processing Industry
  • 3.5 FANUC
    • 3.5.1 Fanuc Vegetable Sorting Robot
    • 3.5.2 FANUC Robodrill DiA5 Series
  • 3.6 ABB Robots
    • 3.6.1 ABB Automation Solutions for the Agriculture Industry
    • 3.6.2 ABB Agricultural Robot Products
    • 3.6.3 ABB Agricultural Robot Benefits
    • 3.6.4 ABB Symphony Plus
  • 3.7 Bosch Deepfield Robotics
    • 3.7.1 Bosch BoniRob
    • 3.7.2 Bosch Deepfield Connect
    • 3.7.3 Bosch: Field Testing Automation For Better Seeds
    • 3.7.4 Bosch Seed Field Testing Challenges:
    • 3.7.5 Bosch Weeding
  • 3.8 Yaskawa
    • 3.8.1 Yaskawa Bottling System with Motoman HP20F
    • 3.8.2 Yaskawa Industrial AC Drives 1/8 thru 1750 Horsepower
    • 3.8.3 Yaskawa Specialty Pump Drives 3/4 thru 500 Horsepower
    • 3.8.4 Yaskawa Servo Systems and Motion Controllers
    • 3.8.5 Motoman Robot Handling and Palletizing Bags of Livestock Feed
    • 3.8.6 Motoman Agriculture Robotics Palletizing Bags Solution
    • 3.8.7 Motoman Robotics Agricultural Robot Palletizing Bags Fixtures / Tooling Details
    • 3.8.8 Motoman Agricultural Grain Bin Dryer Fan Wheels
    • 3.8.9 Motoman Robotics Fixtures/Tooling Details
    • 3.8.10 Motoman Agricultural Irrigation Pipe
    • 3.8.11 Motoman Robotics Fixtures/Tooling Details
    • 3.8.12 Motoman Agricultural Equipment
    • 3.8.13 Motoman Robotics Fixtures/Tooling Details
    • 3.8.14 Motoman Round Baler Pickup Frames for Agricultural Equipment
    • 3.8.15 Motoman Robotics Fixtures/Tooling Details
    • 3.8.16 Motoman Skid Steer Loader Mount Plates
    • 3.8.17 Motoman Bags of Livestock Feed
    • 3.8.18 Motoman Robotics Fixtures/Tooling Details
  • 3.9 Harvest Automation
    • 3.9.1 Harvest Automation HV-100
    • 3.9.2 Harvest Automation Technology
    • 3.9.3 Harvest Automation Behavior-Based Robotics
  • 3.10 Robotic Harvesting
    • 3.10.1 Robotic Harvesting Strawberry Harvester
  • 3.11 Agrobot
    • 3.11.1 Agrobot AGSHydro
    • 3.11.2 Agrobot Mechanization And Hydroponics Synergy
    • 3.11.3 Agrobot SW 6010
    • 3.11.4 Agrobot AGB: Harvesting High Level System
    • 3.11.5 Agrobot AG Vision
  • 3.12 Blue River Technology
    • 3.12.1 Blue River Remote Sensing Technology
    • 3.12.2 Blue River Technology High-Throughput, Field-Based Phenotyping
    • 3.12.3 Blue River Technology Zea
    • 3.12.4 Blue River Technology Drone-Based Phenotyping
    • 3.12.5 Blue River Technology Agricultural Robot
    • 3.12.6 Blue River Precision Lettuce Thinning - 80/84" Beds
    • 3.12.7 Lettuce Bot, Blue River Technology
  • 3.13 LemnaTec Phenomics Plant Phenotyping
    • 3.13.1 LemnaTec Scanalyzer Field High Content Data Acquisition
  • 3.14 cRops (Clever Robot for Crops)
    • 3.14.1 cRops European Project, Made Up Of Universities And Labs
  • 3.15 University of Missouri Field-Deployed Robotic System to Study Parched Corn Plants
  • 3.16 Jaybridge Robotics for Agriculture
    • 3.16.1 Jaybridge Robotics Assisted Spotting
    • 3.16.2 Jaybridge Robotics LDX Haul Truck Automation
    • 3.16.3 Jaybridge Robotics Agricultural Automation
    • 3.16.4 Jaybridge Robotics - Kinze Partnering on Autonomous Vehicle Row Crop Harvesting
    • 3.16.5 Jaybridge Software Expertise
  • 3.17 Nano Ganesh
  • 3.18 AquaSpy
  • 3.19 8 Villages
  • 3.20 Agribotix Enduro
    • 3.20.1 Agribotix Hornet
  • 3.21 Clearpath Robotics Grizzly RUV
  • 3.22 Rowbot
    • 3.22.1 Rowbot In-Season Nitrogen And Cover Crop Seeding
    • 3.22.2 Rowbot Seeding Cover Crops Before The Corn Harvest
  • 3.23 ecoRobotix
    • 3.23.1 ecoRobotix Ecological And Economical Weeding
  • 3.24 Frank Poulsen Engineering
    • 3.24.1 Frank Poulsen Engineering Robovator
    • 3.24.2 Frank Poulsen Field Vision System - For Plant Breeders
    • 3.24.3 Frank Poulsen Steering System
  • 3.25 Parrot / SenseFly Agriculture
    • 3.25.1 Parrot / senseFly eBee SQ
    • 3.25.2 Parrot senseFly eBee:
  • 3.26 AutoProbe
    • 3.26.1 AutoProbe Precision Agriculture High Quality Soil Sample
  • 3.27 IBM Precision Agriculture
    • 3.27.1 IBM Precision Agriculture Using Predictive Weather Analytics
    • 3.27.2 IBM Addresses Precision Agriculture
    • 3.27.3 IBM Precision Architecture Optimizing Planting, Harvesting, and Distribution
    • 3.27.4 IBM Precision Agriculture
    • 3.27.5 IBM / Bari Fishing Market App
  • 3.28 M Farm
  • 3.29 Sustainable Harvest
    • 3.29.1 Sustainable Harvest Origin Engagement
    • 3.29.2 Sustainable Harvest Mobile Technology Project
  • 3.30 Tractor Harvesting
  • 3.31 Spensa Technology
    • 3.31.1 Spensa Technology OpenScout
    • 3.31.2 Spensa Technology OpenScout Insights
    • 3.31.3 Spensa Technology Pest Control
  • 3.32 The Pebble Watch
  • 3.33 Louisiana State University AgBot
    • 3.33.1 AgBot Uses Autonomous, Advanced GPS System
    • 3.33.2 Agbot Small Robots Versatility
    • 3.33.3 AgBotDelivery Robot
  • 3.34 Harvard Robobee
    • 3.34.1 Harvard Robobee Practical Applications
    • 3.34.2 Harvard Robobee Vision and Aims
    • 3.34.3 Harvard Robobee Body, Brain, and Colony
    • 3.34.4 Harvard Robobee Body
    • 3.34.5 Harvard Robobee Flexible Insect Wings And Flight Stability In Turbulent Airflow
    • 3.34.6 Harvard Robobee Sensor Networks
    • 3.34.7 Harvard Robobee Colony
    • 3.34.8 Harvard Robobee Sensor Network Development
  • 3.35 iRobot's Automatic Lawn Mower
  • 3.36 MIT Autonomous Gardener Equipment Mounted On The Base of a Roomba
  • 3.37 Carnegie Mellon University's National Robotics Engineering Center
    • 3.37.1 Carnegie Mellon. Self-Guided Farm Equipment
  • 3.38 Cesar the LettuceBot
  • 3.39 Universidad Politécnica de Madrid Rosphere
    • 3.39.1 Rosphere Spherical Shaped Robot
  • 3.40 Shibuya Seiko Co.
    • 3.40.1 Shibuya Seiko Co. Strawberry Picking Robot
    • 3.40.2 Shibuya Seiko Robot Can Pick Strawberry Fields
  • 3.41 University of California, Davis Robots For Harvesting Strawberries
  • 3.42 Wall-Ye V.I.N. Robot
    • 3.42.1 Wall-Ye V.I.N. Robot Functions
    • 3.42.2 Wall-Ye V.I.N. Robot Security System
    • 3.42.3 Wall-Ye V.I.N. Robot Prunes 600 Vines Per Day
  • 3.43 Vision Robotics
    • 3.43.1 Vision VR Lettuce Thinner
    • 3.43.2 Vision Intelligent Autonomous Grapevine Pruner
    • 3.43.3 Vision Weeding / Targeted Spot Spraying
    • 3.43.4 Vision Crop Load Estimation
    • 3.43.5 Vision Robotics Automated Tractors
  • 3.44 Nogchui Autonomous Tractor
    • 3.44.1 Professor Nogchui Agricultural Tractor Robot Uses Navigation Sensor Called AGI-3 GPS Compass Made by TOPCON
    • 3.44.2 Professor Nogchui Agricultural Tractor Robot Mapping System
    • 3.44.3 Nogchui Autonomous Tractor Robot Management Systems
  • 3.45 Microsoft Agricultural Robot Software
  • 3.46 Australian Centre for Field Robotics Herder Robot
    • 3.46.1 Robotic Rover Herds Cows
  • 3.47 Chinese Agricultural Robots
  • 3.48 3D Robotics
  • 3.49 Lely Automatic Milking Robots
    • 3.49.1 Lely Astronaut Milking Robots
    • 3.49.2 Lely Concept and Management
    • 3.49.3 Lely Correct Feed Management
    • 3.49.4 Lely Milk Robots At Large Dairy Farms
    • 3.49.5 Lely Free Cow Traffic
  • 3.50 Kyoto University Tomato Harvesting Robot
  • 3.51 Yamaha Crop Dusting Drones
  • 3.52 RHEA Robot Fleets for Accuracy
    • 3.52.1 RHEA Synchronized Weeding
    • 3.52.2 Synchronized Spraying
  • 3.53 Precise Path Robotics
  • 3.54 FarmBot
    • 3.54.1 FarmBot Real-Time Control
  • 3.55 Adigo Field Flux Robot
  • 3.56 SAGA - Swarm Robotics for Agricultural Applications
    • 3.56.1 Advanced UAV for Swarm Operations
    • 3.56.2 Saga Onboard Weed Recognition
    • 3.56.3 Saga Collective Field Mapping
  • 3.57 DJI Innovations AGRAS MG-1
  • 3.58 HoneyComb
  • 3.59 Trimble Agriculture Field Solutions
  • 3.60 AeroVironment Precision Agriculture
  • 3.61 Cyphy Works PARC
    • 3.61.1 Cyphy Works Pocket Flyer
  • 3.62 Sentera Phoenix 2 UAV
    • 3.62.1 Sentera Omni UAV
    • 3.62.2 Sentera AgVault
    • 3.62.3 Sentera AgVault Mobile
    • 3.62.4 AgVault 2.0 Battery Swap And Flight Planning
    • 3.62.5 Sentera LiveNDVI Video
  • 3.63 Tetra Laval / DeLaval
  • 3.64 Harvard University Agile Robotic Insects RoboBees
  • 3.65 Agribotix Hornet Performs Field Scouting
  • 3.66 Adigo
  • 3.67 Autonomous Tractor Corp. (ATC)

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 Technologies In Precision Agriculture
    • 4.2.1 Mobile Devices
    • 4.2.2 Robotics
  • 4.3 Irrigation
  • 4.4 Internet Of Things
  • 4.5 Sensors
  • 4.5.1 Variable Rate Seeding
  • 4.6 Weather Modeling
  • 4.7 Nitrogen Modeling
  • 4.8 Standardization
  • 4.9 FarmBot DIY Agriculture Robot
  • 4.10 Welding Robots
  • 4.11 Material Handling Robots:
  • 4.12 Plasma Cutting Robots:
  • 4.13 Agricultural Robotics and Automation Scope:
    • 4.13.1 IEEE Standards Initiatives
    • 4.13.2 Delft Robotics Institute
  • 4.14 Robotics and Automation
  • 4.15 An Electronic System Improves Different Agriculture Processes

5 Agricultural Robots Company Description

  • 5.1 8Villages
  • 5.2 ABB Robotics
    • 5.2.1 ABB Revenue
    • 5.2.2 ABB Strategy
    • 5.2.3 ABB Global Leader In Power And Automation Technologies
    • 5.2.4 ABB and IO Deliver Direct Current-Powered Data Center Module
    • 5.2.5 ABB / Validus DC Systems DC Power Infrastructure Equipment
    • 5.2.6 ABB Technology
    • 5.2.7 ABB Global Lab Power
    • 5.2.8 ABB Global Lab Automation
  • 5.3 Adigo
  • 5.4 AeroVironment
  • 5.5 Agile Planet
  • 5.6 AgRA: RAS Agricultural Robotics and Automation (AgRA
  • 5.7 Agribotix
  • 5.8 Agrobot
    • 5.8.1 Agrobot Innovation and Technology for Agribusiness
  • 5.9 AquaSpy
  • 5.10 Australian Centre for Field Robotics
  • 5.11 Autonomous Tractor Corp. (ATC)
  • 5.12 Avular B.V
  • 5.13 Blue River Technology
    • 5.13.1 Blue River / Khosla Ventures
  • 5.14 Bosch Deepfield Robotics
  • 5.15 Clearpath Robotics
  • 5.16 Rowbot
  • 5.17 CNH Industrial / Fiat / Case IH
    • 5.17.1 Case IH Customers Work Directly With Design Engineers
  • 5.18 cRops
  • 5.19 Cyphy Works
    • 5.19.1 Cyphy Research Technology
    • 5.19.2 Cyphy Microfilament Technology
    • 5.19.3 CyPhy Works Microfilament
  • 5.20 Digital Harvest
  • 5.21 DJI Innovations
    • 5.21.1 DJI Revenue
    • 5.21.2 DJI Positioning
  • 5.22 ecoRobotix
  • 5.23 Fanuc
    • 5.23.1 FANUC Corporation
    • 5.23.2 Fanuc Revenue
  • 5.24 FarmBot
  • 5.25 Frank Poulsen Engineering
  • 5.26 Georgia Tech Agricultural Robots
  • 5.27 Google
    • 5.27.1 Google / Boston Dynamics
    • 5.27.2 Boston Dynamics LS3 - Legged Squad Support Systems
    • 5.27.3 Boston Dynamics CHEETAH - Fastest Legged Robot
    • 5.27.4 Boston Dynamics Atlas - The Agile Anthropomorphic Robot
    • 5.27.5 Boston Dynamics BigDog
    • 5.27.6 Boston Dynamics LittleDog - The Legged Locomotion Learning Robot
    • 5.27.7 Google Robotic Division
    • 5.27.8 Google Self-Driving Car
    • 5.27.9 Google Cars Address Vast Majority Of Vehicle Accidents Due To Human Error
    • 5.27.10 Google Business
    • 5.27.11 Google Corporate Highlights
  • 5.28.12 Google Search
    • 5.28.13 Google Revenue
    • 5.28.14 Google Third Quarter 2016 Results
  • 5.29 Harvard Robobee
    • 5.29.1 Harvard Robobee Funding
    • 5.29.2 Harvard Robobee Main Area Of Research
    • 5.29.3 Harvard Robobee OptRAD is used as an Optimizing Reaction-Advection-Diffusion system.
    • 5.29.4 Harvard Robobee The Team
  • 5.30 Harvest Automation
    • 5.30.1 Harvest Automation Ornamental Horticulture
    • 5.30.2 Harvest Automation M Series C Financing
    • 5.30.3 Harvest Robotic Solutions For The Agricultural Market
    • 5.30.4 Harvest Automation Robots
  • 5.31 HoneyComb
  • 5.32 IBM Corporation
    • 5.32.1 IBM IoT Strategy
    • 5.32.2 IBM Cloud Computing
    • 5.32.3 IBM Business Model
    • 5.32.4 IBM
    • 5.32.5 IBM Messaging Extension for Web Application Pattern
    • 5.32.6 IBM MobileFirst
    • 5.32.7 IBM Business Analytics and Optimization Strategy
    • 5.32.8 IBM Growth Market Initiatives
    • 5.32.9 IBM Business Analytics and Optimization
    • 5.32.10 IBM Strategy Addresses Volatility of Information Technology (IT) Systems
    • 5.32.11 IBM Smarter Planet
  • 5.33 iRobot
    • 5.33.1 iRobot Home Robots:
    • 5.33.2 iRobot Role In The Robot Industry
    • 5.33.3 iRobot SPARK (Starter Programs for the Advancement of Robotics Knowledge)
  • 5.34 Jaybridge Robotics
    • 5.34.1 Jaybridge Robotics Software Solutions
    • 5.34.2 Jaybridge Systems Integration for Autonomous Vehicles
    • 5.34.3 Jaybridge Robotics Rigorous Quality Processes
    • 5.34.4 Jaybridge Robotics Professional, Experienced Team
    • 5.34.5 Jaybridge Robotics Seamless Working Relationship with Client Teams
  • 5.35 John Deere
    • 5.35.1 John Deere Revenue
    • 5.35.2 John Deere Patents Hybrid Harvesters And Mobile Robots
  • 5.36 Kinze Manufacturing
  • 5.37 Kuka
    • 5.37.1 Kuka Revenue
    • 5.37.2 Kuka Competition
    • 5.37.3 Kuka Innovative Technology
    • 5.37.4 Kuka Well Positioned With A Broad Product Portfolio In Markets With Attractive Growth Prospects
    • 5.37.5 Kuka Strategy
    • 5.37.6 Kuka Corporate Policy
  • 5.38 KumoTek
    • 5.38.1 KumoTek Robotics Software Specialists
  • 5.39 Kyoto University
  • 5.40 Lely
    • 5.40.1 Large Cow Farm Management
    • 5.40.2 Lely Astronaut
    • 5.40.3 Lely Group Business Concepts
    • 5.40.4 Lely Group Revenue
  • 5.41 LemnaTec Phenomics
    • 5.41.1 LemnaTec Leads the Global Development Of Research Platforms For Digital Plant Phenotyping
  • 5.42 Millennial Net
    • 5.42.1 Millennial Net Wireless Sensor Network:
    • 5.42.2 Millennial Net 1000-Node MeshScape GO Wireless Sensor Network (WSN) Agricultural Sensors
    • 5.42.3 Millennial Net's MeshScape GO WSN Technology
  • 5.43 National Agriculture and Food Research Organization
    • 5.43.1 NARO, a Japanese Incorporated Administrative Agency
    • 5.43.2 National Agriculture and Food Research Organization (NARO) third mid-term plan (from 2011 to 2015)
    • 5.43.3 National Agriculture and Food Research Organization Stable Food Supply
    • 5.43.4 National Agriculture and Food Research Organization Development For Global-Scale Issues And Climate Change
    • 5.43.5 National Agriculture and Food Research Organization Development To Create Demand For New Food Products
    • 5.43.6 National Agriculture and Food Research Organization Development For Utilizing Local Agricultural Resources
    • 5.43.7 Japanese National Agriculture and Food Research Organization
  • 5.44 Ossian Agro Automation / Nano Ganesh
  • 5.45 Parrot/senseFly
    • 5.45.1 Parrot Group / senseFly
    • 5.45.2 Parrot Group senseFly CTI Certified
    • 5.45.3 Parrot Drone First Quarter Sales For 2015 Up 356 Percent
    • 5.45.4 Parrot / SenseFly
  • 5.46 Precise Path Robotics
  • 5.47 Robotic Harvesting
  • 5.48 SAGA - Swarm Robotics for Agricultural Applications
  • 5.49 Sentera
  • 5.50 Sicily Tractor Harvesting
  • 5.51 Shibuya Seiki
    • 5.51.1 Shibuya Kogyo Pharmaceutical Application Examples
    • 5.51.2 Shibuya Kogyo Robotic System For Handling Soft Infusion Bags
    • 5.51.3 Shibuya Kogyo Robotic Cell Culture System "CellPRO"
    • 5.51.4 Shibuya Kogyo Robotic System For Leaflet & Spoon Placement
    • 5.51.5 Shibuya Kogyo Robotic Collating System
    • 5.51.6 Shibuya Kogyo Automated Aseptic Environmental Monitoring System
  • 5.52 Spread
  • 5.53 Sustainable Harvest
  • 5.54 Tetrelaval
    • 5.54.1 DeLaval Sustainable Dairy Farming
  • 5.55 Trimble
    • 5.55.1 Trimble Business
  • 5.56 Universidad Politécnica de Madrid
  • 5.57 University of California, Davis
  • 5.58 Vision Robotics
  • 5.59 Wall-Ye V.I.N. Robot
  • 5.60 Yamaha
  • 5.61 Yaskawa
    • 5.61.1 Yaskawa Revenue
    • 5.61.2 Yaskawa Business
    • 5.61.3 YASKAWA Electric Motion Control
    • 5.61.4 YASKAWA Electric Robotics
    • 5.61.5 YASKAWA Electric System Engineering
    • 5.61.6 YASKAWA Electric Information Technology
    • 5.61.7 Yaskawa / Motoman
  • 5.62 Agricultural Robotic Research Labs
    • 5.62.1 Agricultural Robotic Companies
    • 5.62.2 IEEE Agricultural Technical Committee
    • 5.62.3 Agricultural Robotic Conferences
    • 5.62.4 Agricultural Robotic Publications
    • 5.62.5 Selected VC Funding In Robotics

WinterGreen Research,

  • WinterGreen Research Research Methodology

List of Figures

  • Figure 1. Agricultural Robots Functions
  • Figure 2. Agricultural Robot Market Driving Forces Employment Opportunity
  • Figure 3. Agrobot Strawberry Picker
  • Figure 4. Agricultural Robot Market Driving Forces
  • Figure 5. Agricultural Robot Target Markets
  • Figure 6. Robotic Agricultural Trends
  • Figure 7. Agriculture Robotic Activities
  • Figure 8. Market Forces for Agricultural Modernization
  • Figure 9. Robotics - State of the Art Advantages
  • Figure 10. Agricultural Robot Challenges
  • Figure 11. Agricultural Robot Market Segments
  • Figure 12. Agricultural Robot Technologies
  • Figure 13. Agricultural Robot Market Shares, Dollars, Worldwide, 2016
  • Figure 14. Digital Farms a Reality
  • Figure 15. Transitioning To Precision Agricultural Methods
  • Figure 16. Precision Agricultural Functions
  • Figure 17. Precision Agricultural Vehicles
  • Figure 18. Digital Farm Characteristics
  • Figure 19. Precision Agriculture Data Types
  • Figure 20. Aspects of Agricultural Sector Modernization
  • Figure 21. Agricultural Robotics Positioned To Meet The Increasing Demands For Food And Bioenergy
  • Figure 22. Autonomous Orchard Vehicle
  • Figure 23. Automated Picker Machine
  • Figure 24. Nursery Robot Benefits
  • Figure 25. Cows Grazing
  • Figure 26. European Union Seventh Framework Program cRops (Clever Robots for Crops) Focus On Harvesting High Value Crops
  • Figure 27. Transformational Agricultural Robots
  • Figure 28. Agricultural Robots Functions
  • Figure 29. Agricultural Robot Market Driving Forces Employment Opportunity
  • Figure 30. Agrobot Strawberry Picker
  • Figure 31. Agricultural Robot Market Driving Forces
  • Figure 32. Agricultural Robot Target Markets
  • Figure 33. Robotic Agriculture Trends
  • Figure 34. Agriculture Robotic Activities
  • Figure 35. Market Forces for Agricultural Modernization
  • Figure 36. Robotics - State of the Art Advantages
  • Figure 37. Agricultural Robot Challenges
  • Figure 38. Agricultural Robot Market Segments
  • Figure 39. Agricultural Robot Technologies
  • Figure 40. Agricultural Robot Market Shares, Dollars, Worldwide, 2016
  • Figure 41. Agricultural Robot Market Shares, Dollars, Worldwide, 2016
  • Figure 42. A Cow Exits the Lely Astronaut A4 Milking Machine
  • Figure 43. Agrobot Strawberry Picker
  • Figure 44. John Deere Autonomous Tractors 120
  • Figure 45. Agricultural Robot Market Forecasts Dollars, Worldwide, 2017-2023126
  • Figure 46. Agricultural Robot Market Forecast Worldwide, 2017-2023
  • Figure 47. Agricultural Robot Target Markets 129
  • Figure 48. Agricultural Robot Market Segments, Dollars, Worldwide, 2016
  • Figure 49. Agricultural Robot Market Segments, Dollars, Worldwide, 2016
  • Figure 50. Agricultural Robot Market Segments, Dollars, Worldwide, 2023
  • Figure 51. Agricultural Robot Market Segments, Driverless Tractors, Cow Milking Systems, Process Precision Architecture, and Irrigation Systems Dollars, Worldwide, 2016
  • Figure 52. Agricultural Robot Market Segments, Percent, Worldwide, 2016
  • Figure 53. Process Precision Agricultural Robots Market Forecasts Dollars, Worldwide, 2017-2023
  • Figure 54. Process Precision Agricultural Robot Segments, Wheat, Rice, and Corn Harvesting, Grape and Other Pruning and Harvesting, Golf Course and Lawn Mowing, Nursery Management, Seeding, Planting, Fertilizing, Spraying, Drone Crop Dusting , Dollars, Forecasts, Worldwide, 2017-2023
  • Figure 55. Process Precision Agricultural Robot Segments, Wheat, Rice, and Corn Harvesting, Grape and Other Pruning and Harvesting, Golf Course and Lawn Mowing, Nursery Management, Seeding, Planting, Fertilizing, Spraying, Drone Crop Dusting , Percent , Forecasts, Worldwide, 2017-2023
  • Figure 56. Agricultural Robots for Ornamental Plant Handling Benefits
  • Figure 57. UC Davis Using Yahama Helicopter Drones For Crop Dusting
  • Figure 58. Yahama Crop Duster
  • Figure 59. Distributed Robotics Garden
  • Figure 60. Modernized Agriculture Telegarden, As Installed At Ars Electronica
  • Figure 61. Agricultural Robot Self Driving Tractor Market Forecasts Dollars, Worldwide,
  • Figure 62. Multiple Small Intelligent Machines Replace Large Manned Tractors154
  • Figure 63. Agricultural Cow Milking Robot Market Shares, Dollars, Worldwide, 2016
  • Figure 64. Lely Automatic Milking
  • Figure 65. Agricultural Irrigation Robots Market Forecasts Dollars, Worldwide, 2017-2023
  • Figure 66. Agriculture and Weather Internet of Things (IoT) Market Forecasts, Dollars, Worldwide, 2017-2024
  • Figure 67. Agriculture and Weather, Internet of Things Market Segments, Dollars, Forecast, Worldwide, 2017-2023
  • Figure 68. Two Billion Sensors Used In Farms Globally by End of Forecast Period
  • Figure 69. Agriculture Internet of Things: Venture Investment
  • Figure 70. Agricultural Sector The Technological Development of Internet of Things
  • Figure 71. Drone Low Altitude Tracking and Avoidance Systems
  • Figure 72. IoT Integrated Pest Management or Control
  • Figure 73. Pest Management & Control Fundamental Modules -
  • Figure 74. IoT Apple Sensing
  • Figure 75. Phenonet Project by Open IoT Performance Goals
  • Figure 76. CLAAS IoT Equipment
  • Figure 77. Voluntary Cow Traffic Benefits
  • Figure 78. Cow Traffic System Cubicles ROI Metrics
  • Figure 79. Lely Example of Herd Size and Robots / Farm Worker
  • Figure 80. Roles of Agricultural Robots
  • Figure 81. Cost Structures and Roles of Agricultural Robots
  • Figure 82. Agricultural Robotic Regional Market Segments, 2016
  • Figure 83. Agricultural Robot Regional Market Segments, 2016
  • Figure 84. John Deere Autonomous Mower
  • Figure 85. John Deere Autonomous Tractors
  • Figure 86. John Deere Autonomous Flexible Use Tractor
  • Figure 87. John Deere Crop Spraying
  • Figure 88. John Deere Autonomous Tractor
  • Figure 89. CNH Industrial Case IH Magnum Autonomous Tractor In Field With A Planter Implement.
  • Figure 90. Kuka Agricultural Robots
  • Figure 91. Kuka Material Handling Robots
  • Figure 92. Kuka Industry Standard Robots Used in Agriculture
  • Figure 93. Kuka Welding Robots in the Agricultural Industry
  • Figure 94. Kuka Robots in the Agricultural Industry
  • Figure 95. Kuka Robots in the Food Processing Industry
  • Figure 96. Kuka Plasma Cutting Robot
  • Figure 97. Fanuc M-3iA Robots Sorting Boxes
  • Figure 98. FANUC Robodrill DiA5 Series
  • Figure 99. FANUC Welding Robots
  • Figure 100. FANUC Material Handling Robots
  • Figure 101. FANUC Plasma Cutting Robot
  • Figure 102. ABB Agricultural Robot Automation Solution
  • Figure 103. ABB Agricultural Robot Benefits
  • Figure 104. ABB Agricultural Robot IoT Sensor Measurements
  • Figure 105. ABB Agricultural Robot IoT Sensor Measurement Tracking
  • Figure 106. ABB Welding Robots
  • Figure 107. ABB Material Handling Robots
  • Figure 108. Bosch BoniRob
  • Figure 109. Bosch BoniRob Robot Functions
  • Figure 110. Bosch BoniRob Features
  • Figure 111. Bosch Deepfield® Connect App Features
  • Figure 112. Bosch Deepfield Connect Image
  • Figure 113. Bosch Deepfield Connect Functions
  • Figure 114. Bosch Deepfield Connect Issues Addressed
  • Figure 115. Bosch Deepfield Connect IoT Temperature Management
  • Figure 116. Bosch Seed Field Testing Automation Process
  • Figure 117. Bosch Seed Field Testing Automation Functions
  • Figure 118. Bosch Seed Field Testing Challenges:
  • Figure 119. Bosch Weeding
  • Figure 120. Bosch Weeding Solutions Advantages:
  • Figure 121. Bosch Recognition of Herbicide Challenges
  • Figure 122. Bosch Solutions Target Weeding Challenges
  • Figure 123. Yaskawa Bottling System with Motoman HP20F
  • Figure 124. Yaskawa Plasma Cutting Robot
  • Figure 125. Yaskawa Robots Used in Agriculture
  • Figure 126. Yaskawa Industrial AC Drives 1/8 thru 1750 Horsepower
  • Figure 127. Yaskawa Specialty Pump Drives 3/4 thru 500 Horsepower
  • Figure 128. Motoman Robot Handling and Palletizing Bags of Livestock Feed
  • Figure 129. Motoman Robot Handling and Palletizing Bags of Livestock Feed Project Challenges
  • Figure 130. Motoman Agriculture Robotics Palletizing Bags Solution
  • Figure 131. Motoman Agricultural Grain Bin Dryer Fan Wheels Project Challenges
  • Figure 132. Motoman Agricultural Grain Bin Dryer Fan Wheels Robotics Solution
  • Figure 133. Motoman Agricultural Irrigation Pipe
  • Figure 134. Motoman Agricultural Irrigation Pipe Project Challenges
  • Figure 135. Motoman Agricultural Irrigation Pipe Robotics Solution
  • Figure 136. Motoman Agricultural Equipment
  • Figure 137. Motoman Agricultural Equipment Project Challenges
  • Figure 138. Motoman Agricultural Equipment Robotics Solution
  • Figure 139. Motoman Round Baler Pickup Frames for Agricultural Equipment
  • Figure 140. Motoman Round Baler Pickup Frames for Agricultural Equipment Project Challenges
  • Figure 141. Motoman Round Baler Pickup Frames for Agricultural Equipment Robotics Solution
  • Figure 142. Motoman Skid Steer Loader Mount Plates
  • Figure 143. Motoman Skid Steer Loader Mount Plates Project Challenges
  • Figure 144. Motoman Skid Steer Loader Mount Plates Robotics Solution
  • Figure 145. Motoman Bags of Livestock Feed
  • Figure 146. Motoman Bags of Livestock Feed Project Challenges
  • Figure 147. Motoman Bags of Livestock Feed Robotics Solution
  • Figure 148. Harvest Automation HV-100
  • Figure 149. Harvest Automation's HV-100 Features
  • Figure 150. Harvest Automation Shrub Robot
  • Figure 151. Harvest Automation Shrub Robot In Garden
  • Figure 152. Harvest Automation Robot Provides Marketplace Sustainability
  • Figure 153. Harvest Automation Shrub Robot Features:
  • Figure 154. Harvest Automation Shrub Robot Functions:
  • Figure 155. Robotic Harvesting of Strawberries
  • Figure 156. Agrobot AGSHydro
  • Figure 157. Agrobot AGSHydro® Fruit Issue Solutions Benefits
  • Figure 158. Agrobot AGSHydro Fruit Growing and Harvesting Functions
  • Figure 159. Agrobot SW 6010
  • Figure 160. Agrobot AGB: Harvesting High Level System
  • Figure 161. Agrobot AG Vision
  • Figure 162. Blue River Technology Visualization Spray Tractor Can Identify Plants And Weeds To Spray Chemicals
  • Figure 163. Blue River Technology High-Throughput, Field-Based Phenotyping Functions
  • Figure 164. Blue River Technology Zea Measurement Functions
  • Figure 165. Blue River Technology Drone-Based Phenotyping Functions
  • Figure 166. Blue River All-In-One Drone Service Functions
  • Figure 167. Blue River All-In-One Drone Measurement Functions
  • Figure 168. Blue River Technology Agricultural Robot
  • Figure 169. Blue River Precision Lettuce Thinning 40/42" Beds Agricultural Robot
  • Figure 170. Blue River Technology Agricultural Robot Functions 285
  • Figure 171. Blue River Precision Lettuce Thinning - 80/84" beds
  • Figure 172. Blue River Technology Delicate Crop Weeding And Harvesting Machine Functions
  • Figure 173. Blue River Technology Delicate Crop Weeding And Harvesting Machine Benefits
  • Figure 174. LemnaTec Plant Phenotyping Provides Data On Individual Plants
  • Figure 175. LemnaTec Scanalyzer Field Features
  • Figure 176. cRops Robotic Platform Functions
  • Figure 177. cRops Robot System European Project Supporters
  • Figure 178. cRops Robot System
  • Figure 179. cRops Robot Target System
  • Figure 180. Vinobot Robot, with Vinoculer Tower Visible At Right
  • Figure 181. Jaybridge Robotics Assisted Spotting
  • Figure 182. Jaybridge Robotics LDX Haul Truck Automation Advantages
  • Figure 183. Jaybridge Robotics Driverless Tractor
  • Figure 184. Clearpath Robotics Grizzly RUV
  • Figure 185. Clearpath Robotics Grizzly Robot Workhorse Functions
  • Figure 186. Rowbot
  • Figure 187. Rowbot Seeding Cover Crops Functions
  • Figure 188. ecoRobotix Row Weeder
  • Figure 189. Frank Poulsen Engineering Robovator
  • Figure 190. Frank Poulsen Engineering Robovator Specifications
  • Figure 191. Frank Poulsen Engineering Robovator Features
  • Figure 192. Frank Poulsen Engineering Robovator Components
  • Figure 193. Parrot / senseFly eBee SQ
  • Figure 194. senseFly eBee SQ
  • Figure 195. Parrot senseFly eBee Agricultural Drone Functions:
  • Figure 196. AutoProbe Soil Core Sampling Confidence Levels for Nitrogen, Potassium, and Phosphorus
  • Figure 197. IBM / Bari Fishing Market App
  • Figure 198. IBM / Bari Real Time Fishing Market App
  • Figure 199. IBM / Bari Fishing Market Need Matching App
  • Figure 200. Small Tractor Used For Manual Artichokes Harvesting
  • Figure 201. Spensa Technology OpenScout
  • Figure 202. Spensa Technology OpenScout Insights
  • Figure 203. LSU AgBot
  • Figure 204. Harvard Robobee Robot Applications
  • Figure 205. Nature-Inspired Robotic Research Aims
  • Figure 206. Robobee Boby, Brain, Colony
  • Figure 207. Harvard Robobee Propulsive Efficiency
  • Figure 208. Robobee Boby, Brain, Colony
  • Figure 209. Harvard Robobee Studies of Stability And Control In Unsteady, Structured Wakes
  • Figure 210. Harvard Robobee Sensor Networks
  • Figure 211. Harvard Robobee Computationally-Efficient Control System
  • Figure 212. Harvard Robobee Sensor Network Design Challenges
  • Figure 213. Harvard Robobee Challenges In Development Of A Sensor Network
  • Figure 214. Harvard Robobee Sensor Network Context Challenges
  • Figure 215. Harvard Robobee Sensor Network Elements
  • Figure 216. Harvard Robobee Sensor Network Limitations
  • Figure 217. Harvard Robobee Software Language Limitations
  • Figure 218. Harvard Robobee Software Language Current Efforts
  • Figure 219. Robomow RL850 Automatic Lawn Mower
  • Figure 220. MIT Smart Gardener Robot
  • Figure 221. Carnegie Mellon Self-Guided Farm Equipment
  • Figure 222. Carnegie Mellon Self-Guided Equipment Running on Farm
  • Figure 223. Cesar the LettuceBot
  • Figure 224. Benefits of Lettuce Harvesting Robot
  • Figure 225. Rosphere
  • Figure 226. Rosphere Induction Of Forward/Backward And Turning Movements
  • Figure 227. University of California, Davis Robot For Harvesting Strawberries
  • Figure 228. Wall-Ye V.I.N. Robot Functions
  • Figure 229. Wall-Ye V.I.N. Robot Technology
  • Figure 230. Wall-Ye V.I.N. Robot Features
  • Figure 231. Vision VR Lettuce Thinner
  • Figure 232. Vision Robotics Snippy Robotic Vine Pruner
  • Figure 233. Nogchui Autonomous Tractor Grading, Japan
  • Figure 234. Nogchui Autonomous Tractor Working Field
  • Figure 235. Professor Nogchui Autonomous Tractor Navigation Map Information
  • Figure 236. Microsoft Agricultural Robot Software
  • Figure 237. Herder Robotic Rover
  • Figure 238. Chinese Farmbot Tractor Image
  • Figure 239. 3D Robotics
  • Figure 240. 3D Robotics Drone Spray Application
  • Figure 241. 3D Robotics Uses Pesticides And Fungicides Only When Needed
  • Figure 242. 3D Robotics Data For Marketing
  • Figure 243. 3D Robotics Aerial Views of Crops
  • Figure 244. 3D Robotics Aerial Views Multicopter To Fly Over Vineyards
  • Figure 245. Lely Automatic Milking
  • Figure 246. Astronaut Milking Robot
  • Figure 247. Lely Milking System Farm
  • Figure 248. Lely Cattle Feeding System Farm
  • Figure 249. Lely Automated Process for Managing Milking and Farm
  • Figure 250. Lely Correct Cattle Feeding Management
  • Figure 251. Lely Automated Process Cattle Feeding Management
  • Figure 252. Lely Multi-Barn Cattle Feeding Management
  • Figure 253. Lely Cattle Milking Management
  • Figure 254. Kyoto University Tomato Harvesting Robot
  • Figure 255. Kyoto University Fruit Harvesting Robots In Greenhouse
  • Figure 256. Kyoto University Tomato Cluster Harvesting Robot
  • Figure 257. Kyoto University Strawberry Harvesting Robot In Plant Factory
  • Figure 258. RHEA Robot Fleets for Seeding
  • Figure 259. RHEA Robot Fleet Mapping for Seeding
  • Figure 260. Robot Fleet Deterministic Route Planning for Seeding
  • Figure 261. Orthogonal Inter Row Mechanical Weeding for Organic Farming
  • Figure 262. HGCA Laser Weeding
  • Figure 263. RHEA Laser Weeding
  • Figure 264. RHEA Horibot Cutter and Sprayer
  • Figure 265. RHEA Broad leafed Weed Sensing And Spraying
  • Figure 266. RHEA Broad Leafed Weed Sensing And Spraying
  • Figure 267. RHEA Multiple Small Intelligent Machines Replace Large Manned Tractors
  • Figure 268. RHEA Cooperative Fleet Of Robots
  • Figure 269. RHEA Hexacopter (Aerial Mobile Unit)
  • Figure 270. FarmBot
  • Figure 271. Adigo Field Flux Robot
  • Figure 272. Adigo Field Flux Robot Features
  • Figure 273. SAGA Concept
  • Figure 274. DJI Innovations AGRAS MG-1
  • Figure 275. HoneyComb
  • Figure 276. Drones Use in Agriculture
  • Figure 277. Cyphy Works PARC
  • Figure 278. Cyphy Works Pocket Flyer
  • Figure 279. Sentera Phoenix 2 UAV
  • Figure 280. Sentera Omni UAV
  • Figure 281. Sentera AgVault Drones Supported
  • Figure 282. Adigo Autonomous Robot Determines the Amount of N2O Emitted From Fertilizers As Greenhouse Gases
  • Figure 283. Harvest Automation Proprietary Sensor Technology Functions
  • Figure 284. Harvest Automation Robot System Architecture
  • Figure 285. Proprietary Sensor Technology
  • Figure 286. System Design & Architecture
  • Figure 287. GPS/GNSS
  • Figure 288. Follow Me Robotic Tractors
  • Figure 289. Irrigation Innovation
  • Figure 290. Precision Irrigation Robotic Technologies Functions
  • Figure 291. GreenSeeker Sensors
  • Figure 292. Variable-Rate Application (VRA) Seeding
  • Figure 293. Weather Modeling
  • Figure 294. Tight Scientific Collaboration Between Different Disciplines
  • Figure 295. IEEE Agricultural Robots
  • Figure 296. IEEE Orchard Robots
  • Figure 297. IEEE Automated Agricultural Robot
  • Figure 298. ABB Product Launches
  • Figure 299. ABB Global Lab Target Technologies
  • Figure 300. ABB's Global Lab Automation Target Solutions
  • Figure 301. ABB Active Current Research Areas
  • Figure 302. Agrobot Strawberry Picker
  • Figure 303. Agrobot Strawberry Picker
  • Figure 304. Agrobot Robot for Agriculture
  • Figure 305. Agrobot Innovation and Technology for Agribusiness
  • Figure 306. Agrobot Innovation and Technology for Agribusiness
  • Figure 307. Agrobot SW6010 Support
  • Figure 308. Autonomous Tractors Traverse Fields
  • Figure 309. Clearpath Farm Robot
  • Figure 310. Clearpath Robots
  • Figure 311. Rowbots Work In Teams To Apply Nitrogen Fertilizer In Sync With Corn Needs
  • Figure 312. Crops Technology Functions
  • Figure 313. cRops Intelligent Tools
  • Figure 314. cRops Target Markets
  • Figure 315. cRops Robotic Platform Customized Automated Processes
  • Figure 316. CyPhy Works PARC Drone
  • Figure 317. Cyphy Drone FLyer
  • Figure 318. Cyphy Pocket Flyer Key Benefits
  • Figure 319. Cyphy Pocket Flyer Specifications
  • Figure 320. Cyphy Spooling MicroFilament
  • Figure 321. DJI Phantom
  • Figure 322. Fanuc Revenue
  • Figure 323. FarmBot Open Source Functions
  • Figure 324. FarmBot Weather Tools
  • Figure 325. FarmBot Off-Grid Capability
  • Figure 326. FarmBot Agricultural Lights
  • Figure 327. Frank Poulsen Weed Robots
  • Figure 328. Boston Dynamic LS3
  • Figure 329. Boston Dynamic CHEETAH
  • Figure 330. Boston Dynamic Atlas
  • Figure 331. Boston Dynamic BigDog
  • Figure 332. Boston Dynamics LittleDog -
  • Figure 333. Google Autonomous Vehicles Technology
  • Figure 334. Harvard Robobee Project Characteristics
  • Figure 335. Harvard Robobee Kilobot Robot Group
  • Figure 336. Harvest Automation Robot Navigation
  • Figure 337. Harvest Automation Robot Sensor Network Functions
  • Figure 338. iRobot Fourth-Quarter and Full-Year Financial Results
  • Figure 339. Jaybridge Robotics Software Solutions
  • Figure 340. Jaybridge Robotics Software Functions
  • Figure 341. Deere Seed Spreading Machine
  • Figure 342. Kuka Global Presence
  • Figure 343. Kuka Positioning with Smart Tools
  • Figure 344. A cow exits the Lely Astronaut A4 Milking Machine
  • Figure 345. Lely's Astronaut A4 Milking Robot
  • Figure 346. Lely Astronaut Milking Robot
  • Figure 347. LemnaTec Plant Phenotyping Provides Data On Individual Plants, LemnaTec Phenomics
  • Figure 348. LemnaTec Customer References
  • Figure 349. Millennial Net's MeshScape System Functions
  • Figure 350. MeshScape GO Deployment Components:
  • Figure 351. National Agriculture and Food Research Organization (NARO) Plan Goals
  • Figure 352. Parrot Consumer Drone
  • Figure 353. Precise Path Robotics
  • Figure 354. Sicily Small Tractor Used For Manual Artichoke Harvesting
  • Figure 355. Shibuya Kogyo Robotic System For Leaflet & Spoon Placement
  • Figure 356. Shibuya Kogyo Robotic Collating System
  • Figure 357. Shibuya Kogyo Automated Aseptic Environmental Monitoring System
  • Figure 358. Universidad Politécnica de Madrid Projects
  • Figure 359. Vision Robotics Provides Assistance In Developing Robots
  • Figure 360. UC Davis Using Yahama Helicopter Drones For Crop Dusting
  • Figure 361. Yamaha Crop Dusting Initiatives
  • Figure 362. YASKAWA Electric Group Businesses
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