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市場調查報告書

農業用無人機的市場佔有率·市場策略·市場預測 2016-2022年

Agricultural Drones Market Shares, Market Strategies, and Market Forecasts, 2016 to 2022

出版商 WinterGreen Research, Inc. 商品編碼 355763
出版日期 內容資訊 英文 288 Pages, 127 Tables and Figures
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農業用無人機的市場佔有率·市場策略·市場預測 2016-2022年 Agricultural Drones Market Shares, Market Strategies, and Market Forecasts, 2016 to 2022
出版日期: 2016年04月05日 內容資訊: 英文 288 Pages, 127 Tables and Figures
簡介

預測全球農業用無人機市場規模到2022年前將達到36億9,000萬美元。

本報告提供全球農業用無人機市場相關調查,提供市場概要,佔有率,預測,及主要產品的說明,技術趨勢等分析,再加上主要企業公司簡介,為您概述為以下內容。

摘要整理

第1章 農業用無人機:市場說明·市場動態

  • 農業用無人機的風險投資
  • 智慧無人機:商業用無人駕駛航空器系統 (UAS) 的說明
  • 無人機的強化功能·有效負載
  • 奈米無人機應用
  • following me無人機
  • 無人駕駛航空器系統的有效負載
  • 加州葡萄酒行業用途無人機改善葡萄園的採樣
  • Agri-Informatics (農業資訊科學)

第2章 農業用無人機:市場佔有率·市場預測

  • 農業用無人機市場促進要素
  • 無人機的農業檢驗·播種航空系統市場佔有率
  • 農業用無人機市場預測
  • 無人機的出貨量
  • 農業用無人機的價格
  • 無人機系統:各應用領域
  • 農業用無人機的地區市場分析

第3章 農業用無人機:產品說明

  • Yamaha 的撒農藥用無人機
  • AeroVironment
  • DJI Inspire
  • 3D Robotics
  • FT Sistemas
  • AgEagle
  • Raven Industries
  • HoneyComb AgDrones
  • Parrot / SenseFly
  • Precision Drones
  • PrecisionHawk Lancaster

第4章 農業用無人機:技術·研究

  • 農業研究·技術
  • 農業用無人機產業上法規
  • 農業用無人機感測器·功能

第5章 企業簡介

  • 3D Robotics
  • AeroVironment
  • AgEagle
  • Airogisitic
  • Airware
  • Aviation Industry Corporation of China (AVIC)
  • China Aerospace CASC Space Technology
  • Deveron Resources Ltd
  • DJI
  • FT Sistemas
  • Honeycomb
  • HUVRData, LLC
  • Parrot / Sensefly
  • Precision Drone
  • Raven Industries
  • Skycatch
  • Tekever Drones To Detect Vine Disease
  • Topcon Positioning Group
  • Yahama
  • Yuneec

關於WinterGreen Research

圖表

目錄
Product Code: SH26664999

Worldwide agricultural drone markets are poised to achieve significant growth with the use of cameras on stable flying platforms that are used to help implement precision farming. Crop visualization lets farmers better control and isolate areas for spraying and lets the drones do the spraying.

Agricultural drones use automated process to make farming more productive. Drones provide better, more flexible visualization. Smart drone agricultural uses cameras and provide the prospect of trillions of dollars in farming economic growth. Smart commercial drones connect seamlessly and securely to the Internet and to each other.

Agricultural drone technology has reached a level of maturity that has put these systems at the forefront of farming modernization. Farmers around the entire world are adapting to drone availability, using aerial cameras to visualize plants. Use cases are evolving rapidly. Video, specialized video, targeted video, and agricultural spraying systems are offered.

Agricultural Drones Use Technology for Spraying, Mapping, Pest Control, Seeding, Remote Sensing, and Precision Agriculture

Agricultural technology uses drones to leverage a data-driven future. Inexpensive sensors, cloud computing and intelligent software used in a drone system hold the potential to transform agriculture and help feed the world's growing population.

Venture investment in agricultural drones has been strong. Investment of venture capital in agricultural technology start-ups reached $2.06 billion in the first half of 2015, 4.25 billion in 2015 doubling the amount of capital invested in this area in 2014.

Agricultural drones leverage the Internet of things (IoT). IoT brings sensors to supplement images of the land from above, making it possible to communicate and use analytics to understand changes in vegetation.

Digital electronics brings significant change to the ancient manual processes of farming. Markets portend to reach multitrillion-dollar payoff from the emerging technology that increases the production and distribution of food. There are technical and policy issues to leverage the potential of the drone use of the Internet of Things (IoT). Challenges include security, privacy and standards. Hackers can enter apparently secure networks to remotely control engines, brakes and steering. This could create a problem on a farm if the network was hacked.

Agricultural industrialization has been brought in some measure by tractors and columbines. Drones bring far greater automated process. Preindustrial agriculture, dating from before Christ to about 1920, consisted of labor-intensive, essentially subsistence farming on small farms. This took two acres to feed one person. With industrial agriculture, from 1920 to 2010, tractors and combine harvesters, chemical fertilizers and seed science opened commercialization of farms. Gains in productivity achieved one acre feeding five people.

Digital agriculture brought by drones is part of the next stage in industrialization of agriculture. It involves exploiting data from many sources - sensors on farm equipment and plants, satellite images and weather tracking. The use of water and fertilizer is measured and monitored. Growing can be monitored on a plant-by-plant basis.

Plant factories are being implemented worldwide that use 97% less water than an outdoor growing environment. Drones are anticipated to be used in those environments indoors.

The data-rich approach to decision making represented a sharp break with tradition. It is a totally different world than walking out on the farmland, kicking the dirt and making a decision based on intuition.

Transparency is a significant aspect of sensor use in farming logistics. Consumers care that their food is cared for in the proper manner: end to end.

According to Susan Eustis, lead author of the study, “Transparency is one of the benefits of IoT that drones bring to digital farming. The benefits of digital farming are higher productivity and more efficient use of land, water and fertilizer. Transparency in farming is being asked for by consumers. Consumers want to know where their food came from, how much water and chemicals were used, and when and how the food was harvested. They want to know about consistent refrigeration during transport.”

“Use of drones represents a key milestone in provision of value to every industry. Customized cameras are used to take photos and videos with stunning representations. Digital controls will further automate flying, making ease of use and flight stability a reality. New materials and new designs are bringing that transformation forward. By furthering innovation, continued growth is assured.”

The worldwide market for agricultural drones is $494 million anticipated to reach $3.69 billion by 2022. The complete report provides a comprehensive analysis of drones in different categories, illustrating the diversity of uses for remote flying devices in farming. Analytics makes the images more cogent to farmers, letting them anticipate problems that only become visible to human farmers days or weeks after the drone images detect issues.

Table of Contents

Agricultural Drone Executive Summary

  • Agricultural Drone Market Driving Forces
    • Agricultural Drones For Crop Surveillance
  • Drone Agricultural Inspection and Planting Aerial Systems Market Shares
  • Agricultural Drone Market Forecasts

1. Agricultural Drones: Market Description and Market Dynamics

  • 1.1. Venture Investment In Agricultural Drones
    • 1.1.1. Agricultural Industrialization
    • 1.1.2. Transparency Benefits Of IoT and Digital Farming
  • 1.2. Smart Drones: Commercial Unmanned Aerial Systems (UAS) Description
  • 1.3. Drone Enhanced Capability and Payloads
  • 1.4. Nano Drones Applications
    • 1.4.1. Drone Miniaturization
  • 1.5. Follow Me Drones
    • 1.5.1. US FAA Commercial Drone Permits
  • 1.6. Unmanned Aerial Systems Payloads
    • 1.6.1. Composites Key to Utility
    • 1.6.2. Unmanned Aerial Systems (UAS) Agriculture Mapping
  • 1.7. Californian Wine Industry Uses Drones to Refine Sampling of the Vineyard
  • 1.8. Agri-Informatics
    • 1.8.1. Drones Geo-Tag Images And Wirelessly Transmit
    • 1.8.2. Drones Used in Japan for Agriculture

2. Agricultural Drone Market Shares and Forecasts

  • 2.1. Agricultural Drone Market Driving Forces
    • 2.1.1. Agricultural Drones For Crop Surveillance
  • 2.2. Drone Agricultural Inspection and Planting Aerial Systems Market Shares
    • 2.2.1. Agriculture Commercial Drone Market Vertical Growth:
    • 2.2.2. Yamaha RMAX
    • 2.2.3. DJI Agricultural Spraying Drone
    • 2.2.4. Prox Dynamics PD-100 Black Hornet
    • 2.2.5. Draganfly Draganflyer X4-P
    • 2.2.6. AscTec Firefly
    • 2.2.7. 3D Robotics
    • 2.2.8. AgEagle Aerial Systems Agricultural Crop Map Functions
  • 2.3. Agricultural Drone Market Forecasts
    • 2.3.1. Agricultural Drone Unit Analysis and Unit Forecasts
    • 2.3.2. Agricultural Drone Unit Shipments
    • 2.3.1. Agriculture Surveying Via Drones
    • 2.3.2. Drone Agricultural Surveying
    • 2.3.3. Agricultural Crop Dusting Drones
    • 2.3.4. Agricultural Drone Trends
    • 2.3.5. Agricultural Drones Provide Farmers With Detailed Views
  • 2.4. Drone Shipments
    • 2.4.1. Drone Market Shares and Sector Forecasts
    • 2.4.2. Drone Market Forecasts
  • 2.5. Agricultural Drone Prices
  • 2.6. Drone Systems by Application
  • 2.7. Agricultural Drone Regional Market Analysis
    • 2.7.1. Smart Drone Commercial (UAV) Industry Regional Summary
    • 2.7.2. U.S Accounts for 73 Percent of The Worldwide Research, Development, Test, And Evaluation (RDT&E) Spending On Smart Drone Technology
    • 2.7.3. U.S. State Department Drone Export Guidelines
    • 2.7.4. Canada
    • 2.7.5. Europe
    • 2.7.6. UK Trade in Drones
    • 2.7.7. Drones for the Netherlands
    • 2.7.8. Japan
    • 2.7.9. Sony Drone Services
    • 2.7.10. Japanese Drone Works Inside the Nuclear Power Plant
    • 2.7.11. China
    • 2.7.12. Chinese Smog-Fighting Drones That Spray Chemicals To Capture Air Pollution 127
    • 2.7.13. China Desires Exports, Steps Up Research In Drones
    • 2.7.14. Chinese Commercial Drones
    • 2.7.15. Singapore
    • 2.7.16. Africa
    • 2.7.17. East Africa
    • 2.7.18. Expansion of US Drone Base in Africa
    • 2.7.19. Ethiopia
    • 2.7.20. Brazil
    • 2.7.21. Morocco
    • 2.7.22. India
    • 2.7.23. Australian Research on Agricultural Drones

3. Agricultural Drone Product Description

  • 3.1. Yamaha Crop Dusting Drones
    • 3.1.1. Yahama
    • 3.1.2. Yamaha RMAX
    • 3.1.3. Yamaha Unmanned Helicopters For Industrial And Research Applications 153
    • 3.1.4. Yamaha Rmax Helicopter Agricultural Drone For Crop Spraying
  • 3.2. AeroVironment
    • 3.2.1. AeroVironment: RQ-11B Raven for Agriculture
    • 3.2.2. AeroVironment: RQ-11B Raven
    • 3.2.3. AeroVironment Raven Specifications
    • 3.2.4. AeroVironment RQ-20A Puma AE
    • 3.2.5. AeroVironement Ground Control System
    • 3.2.6. BP and AeroVironment FAA-Approved, Commercial Drone Operations Presage Agricultural Applications
    • 3.2.7. AeroVironment Integrated LiDAR Sensor Payload
    • 3.2.8. AeroVironment AV's Family of Small UAS
  • 3.3. DJI Inspire 1
    • 3.3.1. DJI Technology Chinese Crop Spraying Drone
    • 3.3.2. DJI Technology Turning to the Rural Market
    • 3.3.3. DJI Phantom
    • 3.3.4. DJI Ronin
  • 3.4. 3D Robotics
    • 3.4.1. 3D Robotics Launches Line of Mapping Drones
    • 3.4.2. 3D Robotics
  • 3.5. FT Sistemas
    • 3.5.1. FT Sistemas Drone Applications
  • 3.6. AgEagle
    • 3.6.1. AgEagle Aerial Systems
  • 3.7. Raven Industries
    • 3.7.1. Raven and AgEagle Partner on UAS Solutions for Agriculture
  • 3.8. HoneyComb AgDrones
  • 3.9. Parrot / SenseFly
  • 3.10. Precision Drones
  • 3.11. PrecisionHawk Lancaster Drone Monitors Livestock Temperature To Check For Fever

4. Agricultural Drone Research and Technology

  • 4.1. Agricultural Research and Technology
  • 4.2. Regulations in the Agricultural Drone Industry
    • 4.2.1. Drone Regulation Exemptions
    • 4.2.2. FAA Plans Final Regulation on Commercial Drone Use by Mid-2016
    • 4.2.3. FAA Approved Drone Projects
  • 4.3. Agricultural Drone Sensors & Capabilities

5. Agricultural Company Profiles

  • 5.1. 3D Robotics
    • 5.1.1. 3D Robotics Acquisition of Sifteo
  • 5.2. AeroVironment
    • 5.2.1. AeroVironment Revenue 2015
  • 5.3. AgEagle
  • 5.4. Airogisitic
  • 5.5. Airware
    • 5.5.1. Airware Components of its Aerial Information Platform
    • 5.5.2. Airware's AIP Business Model
    • 5.5.3. Airware Investment from Intel Capital
  • 5.6. Aviation Industry Corporation of China (AVIC)
  • 5.7. China Aerospace CASC Space Technology
    • 5.7.1. China Aerospace CASC Revenue
  • 5.8. Deveron Resources Ltd
    • 5.8.1. Eagle Scout Drone Imaging
  • 5.9. DJI
    • 5.9.1. DJI Agricultural Spraying Drone
    • 5.9.2. DJI Inspire 1
    • 5.9.3. DJI Technology Chinese Crop Spraying Drone
  • 5.10. FT Sistemas
  • 5.11. Honeycomb
  • 5.12. HUVRData, LLC
  • 5.13. Parrot / Sensefly
    • 5.13.1. Parrot / Sensefly
    • 5.13.2. Parrot/senseFly
    • 5.13.3. Parrot Group / senseFly
    • 5.13.4. Parrot Group senseFly CTI Certified
    • 5.13.5. Parrot Drone First Quarter Sales For 2015 Up 356 Percent
  • 5.14. Precision Drone
  • 5.15. Raven Industries
  • 5.16. Skycatch
  • 5.17. Tekever Drones To Detect Vine Disease
    • 5.17.1. TEKEVER Group drone Project In The Wine-Growing Region Of Minho North of Portugal)
    • 5.17.2. TEKEVER
  • 5.18. Topcon Positioning Group
  • 5.19. Yahama
    • 5.19.1. Yamaha Crop Dusting Drones
  • 5.20. Yuneec

WinterGreen Research

  • WinterGreen Research Methodology

List of Tables and Figures

  • Table ES-1: Agricultural Drone Market Driving Forces
  • Table ES-2: Agricultural Drone Market Factors
  • Table ES-3: Agricultural Drone Geo-Referenced Image Advantages
  • Table ES-4: Benefits of Agricultural Drones
  • Figure ES-5: Commercial Drones Took to the Skies First for the Agricultural Industry
  • Figure ES-6: Agricultural Drone Market Shares, Dollars, 2015
  • Figure ES-7: Smart Commercial Drone Agriculture Aerial Systems Forecasts, Dollars, Worldwide, 2016-2022
  • Table 1-1: Ability Of Commercial Drones To Perform Delivery Function in Agriculture
  • Table 1-2: Nano Drones Applications
  • Figure 1-3: DJI Share of FAA Drone Operations Exceptions
  • Table 1-4: Drones Used in Japan for Agriculture Access Benefits
  • Table 1-5: Drone Farming Plot Infrastructure Access Barriers
  • Table 2-1: Agricultural Drone Market Driving Forces
  • Table 2-2: Agricultural Drone Market Factors
  • Table 2-3: Agricultural Drone Geo-Referenced Image Advantages
  • Table 2-4: Benefits of Agricultural Drones
  • Figure 2-5: Commercial Drones Took to the Skies First for the Agricultural Industry
  • Figure 2-6: Agricultural Drone Market Shares, Dollars, 2015
  • Table 2-7: Agricultural Inspection and Planting Drone Unmanned Aerial Systems (UAS) Market Shares, Dollars, Worldwide, 2015
  • Table 2-8: Drone Uses in Agriculture
  • Figure 2-9: Yamaha Helicopter Drone Spraying
  • Figure 2-10: Yamaha RMAX Helicopter Drones
  • Figure 2-11: DJI Agricultural Spraying Drone
  • Figure 2-12: Draganfly Draganflyer X4-P
  • Figure 2-13: AscTec Firefly
  • Table 2-14: Technical Data - AscTec Firefly
  • Table 2-15: AgEagle Aerial Systems Agricultural Crop Map Functions
  • Figure 2-16: Smart Commercial Drone Agriculture Aerial Systems Forecasts, Dollars, Worldwide, 2016-2022
  • Table 2-17: Agricultural Drone Markets Worldwide, 2016-2022
  • Table 2-18: Agricultural Inspection and Planting Smart Drone Aerial Systems (UAS) Market Shares, Units, Worldwide, 2015
  • Figure 2-19: Agricultural Drone Market Forecasts, Units, Worldwide, 2016-2022
  • Table 2-20: Small and Mid-Size Agricultural Drone Systems, Dollars and Units, Worldwide, 2015-2021
  • Figure 2-21: Agriculture Surveying Via Drones
  • Figure 2-22:
  • Table 2-23: Drone Systems Market Share Units, 2015
  • Figure 2-24: Drone Aerial Systems Market Forecasts, Units, Worldwide, 2016-2022
  • Figure 2-25: DJI Overcomes Technological Barriers to Drone Manufacture
  • Figure 2-26: Agriculture, Business, Environmental and Entertainment Use of Drones
  • Figure 2-27: Drone Systems Market Shares, 2015
  • Figure 2-28: Drone Aerial Systems Forecasts, Dollars, Worldwide, 2016-2022
  • Table 2-29: Drone Aerial Systems by Sector, Military, Agriculture, Oil and Gas, Border Patrol, Law Enforcement, Homeland Security, Disaster Response, Package Delivery, Photography, Videography, Dollars, Worldwide, 2016-2022
  • Table 2-30: Drone Systems by Application, Military, Law Enforcement, Homeland Security, and Border Patrol, Agricultural, Package Delivery, Consumer Photo Drones, Utility Infrastructure Inspection, and Mapping, Market Shares, Dollars, Worldwide, 2015 108
  • Figure 2-31: Drone Aerial Systems (UAS) Regional Market Segments, Dollars, 2015
  • Table 2-32: Drone Aerial Systems (UAS) Regional Market Segments, 2015
  • Figure 2-33: Japanese Hexacopter Smart Commercial Drone
  • Figure 2-34: Sony Commercial Drone
  • Figure 2-35: Drone Model Envisaged For Work Inside The Reactor Buildings At The Crippled Fukushima No. 1 Nuclear Power Plant
  • Figure 2-36: Chinese Vendors Seeks to Sell Drones to China
  • Figure 2-37: Expansion of US Drone Base in Africa
  • Figure 2-38: Australian Research on Agricultural Drones
  • Figure 3-1:
  • Figure 3-2: UC Davis Using Yahama Helicopter Drones For Crop Dusting
  • Figure 3-3: Yamaha Crop Dusting Initiatives
  • Figure 3-4: Yamaha Helicopter Drone Spraying
  • Figure 3-5: Yamaha RMAX Helicopter Drones
  • Figure 3-6: Yamaha Agricultural Spraying
  • Figure 3-7: Yamaha Rmax Drone
  • Figure 3-8: Yamaha Unmanned Helicopters For Industrial And Research Applications
  • Table 3-9: Yamaha Drone Unmanned Helicopters Agricultural Applications
  • Figure 3-10: Yamaha R-Max Agricultural Robot Spraying
  • Figure 3-11: Yamaha Rmax Spraying
  • Figure 3-12: AeroVironment Raven Used for Agriculture
  • Figure 3-13: AeroVironment Agricultural Inspection
  • Figure 3-14: AeroVironment Raven Features
  • Figure 3-15: AeroVironment Raven Specifications
  • Figure 3-16: AeroVironment Raven Flight
  • Figure 3-17: AeroVironment Agricultural Drone Applications
  • Figure 3-18: AeroVironement RQ-20A Puma AE
  • Figure 3-19: AeroVironement Ground Control System
  • Figure 3-20: BP and AeroVironment Drone for Comprehensive GIS Services
  • Table 3-21: AeroVironment BP Services
  • Table 3-22: AeroVironement Inspection of Critical Infrastructure
  • Figure 3-23: AeroVironment Raven
  • Figure 3-24: DJI Inspire 1
  • Figure 3-25: DJI Crop Spraying Agricultural Drone
  • Table 3-26: DJI Agras Agricultural Drone Features
  • Table 3-27: DJI Agras Agricultural Drone Functions
  • Figure 3-28: DJI Technology Farm Drone Can Spray Pesticides Over Up To 4hectares Of Land Every Hour-40 Times More Efficient Than Manual Spraying
  • Figure 3-29: DJI Phantom
  • Figure 3-30: DJI Phantom Series
  • Figure 3-31: DJI Ronin
  • Table 3-32: DJI Agras MG-1 Worldwide Large Farm Challenges
  • Table 3-33: DJI Agras MG-1 Drone Challenges
  • Figure 3-34: 3D Robotics
  • Figure 3-35:
  • Figure 3-36: 3D Robotics Vineyard Inspection
  • Figure 3-37:
  • Figure 3-38: FT Sistemas Drone Designs
  • Figure 3-39: FT Sistemas Naval Drone Designs
  • Figure 3-40: FT Sistemas RGB Drone Perspectives
  • Figure 3-41: FT Sistemas Drone Applications
  • Figure 3-42: FT Sistemas Brazilian Military Drones
  • Table 3-43: Brazilian Land Force FT100 Mission Targets 3.6 AgEagle
  • Figure 3-44: AgEagle
  • Table 3-45: AgEagle Aerial Systems Agricultural Crop Map Functions
  • Figure 3-46: AgEagle Agricultural Drone
  • Figure 3-47: HoneyComb AgDrone
  • Figure 3-48: HoneyComb AgDrone System Controller
  • Figure 3-49: HoneyComb AgDrone Flying
  • Table 3-50: Parrot Sensefly eXom Drone Functions
  • Figure 3-51: Parrot Sensefly Agricultural Drone
  • Figure 3-52: Precision Drone on Farm
  • Figure 3-53: Precision Drone For Agriculture
  • Figure 3-54: Precision Drones Mapping View of Cornfield
  • Figure 3-55: PrecisionHawk Lancaster Drone Monitors Livestock
  • Figure 4-1: US FAA Drone Exceptions by Use Case
  • Table 4-2: AeroVironment Integration Of Sensors And Capabilities For Delivering Actionable Intelligence 5.3 AgEagle
  • Figure 5-1: AgEagle NIR Camera Proprietary Index Filter
  • Figure 5-2: AgEagle Transport Van
  • Figure 5-3: AgEagle Dependable Component Of A Precision Agriculture Program
  • Figure 5-4: Airogistic Drones
  • Table 5-5: Eagle Scout Drone State-Of-The-Art Camera, Sensor And Software Technology Applications
  • Figure 5-6: DJI Phantom
  • Figure 5-7: DJI Agricultural Spraying Drone
  • Figure 5-8: DJI Inspire 1
  • Figure 5-9: DJI Crop Spraying Agricultural Drone
  • Table 5-10: DJI Agras Agricultural Drone Features 5.10 FT Sistemas
  • Table 5-11: HoneyComb AgDrones Mission
  • Table 5-12: HUVD Drone Services Industries Targeted
  • Figure 5-13: Parrot Consumer Drone
  • Figure 5-14: Tekevervines
  • Figure 5-15: UC Davis Using Yahama Helicopter Drones For Crop Dusting
  • Figure 5-16: Yamaha Crop Dusting Initiatives
  • Figure 5-17:
  • Figure 5-18: Yuneec Drone
  • Table 5-19: Yuneec Hobby RC Fixed Wing Aircraft
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