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市場調查報告書
商品編碼
1725105
2032年農業衛星影像市場預測:按農場類型、產品、部署模式、技術、應用、最終用戶和地區進行的全球分析Satellite Imaging for Agriculture Market Forecasts to 2032 - Global Analysis By Farm Type, Offering, Deployment Mode, Technology, Application, End User and By Geography |
根據 Stratistics MRC 的數據,全球農業衛星圖像市場預計在 2025 年達到 6.776 億美元,到 2032 年將達到 12.7901 億美元,預測期內的複合年成長率為 9.5%。
農業衛星影像利用衛星遙感探測技術來監測和管理農業活動。它提供有關作物健康、土壤條件、灌溉水平、天氣影響等的詳細數據。這些資訊有助於農民做出明智的決定,提高產量並減少資源浪費。透過實現精密農業,衛星影像支持永續農業,並能夠提前發現大面積農田的病蟲害和乾旱脅迫等問題。
智慧農業的普及率不斷提高
精密農業的需求日益成長,推動了衛星影像在農業管理中的廣泛應用。農民正在使用高解析度衛星資料來更有效地監測作物健康、土壤條件和灌溉需求。世界各國政府正推行智慧農業計劃,以加強糧食安全並最佳化資源利用。先進的衛星分析可以實現即時決策、改善產量預測並減少浪費。因此,衛星圖像正成為現代農業的重要工具。
初期投資高
部署衛星影像技術需要在硬體、軟體和資料合約方面投入大量的前期成本。中小型農場通常無法承受這種先進的系統,從而限制了它們的市場滲透。此外,需要熟練的人力來解釋衛星數據,這也增加了營運成本。維護和定期升級進一步增加了整體擁有成本。這些經濟障礙阻礙了衛星影像在農業領域的廣泛應用,尤其是在發展中地區。
永續農業意識不斷增強
日益成長的環境問題正在推動農民走向永續農業,並為衛星圖像創造新的機會。利用衛星資料實現的精密農業技術可以幫助減少用水量、最大限度地減少化學品投入並減少碳排放。各國政府和非政府組織正在資助利用衛星監測來鼓勵環保農業的計畫。消費者對永續生產食品的偏好日益增強,將進一步推動對這些技術的需求。提供具有成本效益的衛星解決方案的公司將從這個不斷擴大的市場中受益。
缺乏標準化的資料格式
缺乏統一的數據標準使得衛星圖像與其他農業技術的結合變得複雜。不同的提供者使用不同的格式,這使得農民難以整合和有效分析數據。這種不一致性也限制了農場管理軟體和衛星平台之間的互通性。如果沒有全行業的標準化,用戶可能會面臨相容性挑戰,採用率也可能會放緩。解決這個問題對於多樣化農業系統的無縫實施至關重要。
COVID-19的影響
新冠疫情最初為農業衛星影像市場帶來了挑戰。封鎖和經濟不確定性可能會推遲衛星發射,影響一些農民的投資能力,並可能減緩技術採用。但由於旅行限制和勞動力短缺,疫情也凸顯了遠端監控在農業中的重要性。因此,衛星影像越來越被認為是作物健康監測和產量預測的重要工具。因此,由於對永續和高效農業實踐的需求,預計疫情過後農業對衛星影像的需求將會增加。
預計資訊服務部門將成為預測期內最大的部門
由於對加工和可操作的農業見解的需求不斷增加,預計資訊服務部門將在預測期內佔據最大的市場佔有率。農民依靠服務供應商獲取基於衛星影像的分析、作物健康報告和產量預測。基於訂閱的模型無需大量的基礎設施投資即可提供經濟高效的即時數據存取。公司也正在整合人工智慧來提高數據準確性和預測能力。
預計在預測期內,研究機構部門的複合年成長率最高。
受精密農業、氣候監測和永續農業方法需求不斷成長的推動,研究機構部門預計將在預測期內見證最高成長率。政府資金、遙感探測技術的進步以及與航太機構日益加強的合作正在進一步推動創新。這些機構專注於作物健康監測、產量預測和資源最佳化,以支援糧食安全工作,並協助政策制定者和相關企業進行數據主導的決策,以實現高效的農業管理。
在預測期內,亞太地區預計將佔據最大的市場佔有率,這得益於其龐大的農業部門和政府對農業技術的支持力度不斷增加。印度和中國等國家正在利用衛星影像來提高其龐大人口的糧食產量。促進數位農業發展的優惠政策和對小農戶的補貼正在加速實施。該地區注重透過更好的監測來減少收穫後的損失,這也促進了經濟成長。
在先進的農業基礎設施和強大的研發投資的推動下,北美地區預計將在預測期內呈現最高的複合年成長率。美國和加拿大是早期採用衛星技術進行大規模精密農業。私人公司正在開發適合當地作物需求的高解析度成像解決方案。對永續農業實踐的支持性法規和財政援助進一步推動了市場成長。
According to Stratistics MRC, the Global Satellite Imaging for Agriculture Market is accounted for $677.60 million in 2025 and is expected to reach $1279.01 million by 2032 growing at a CAGR of 9.5% during the forecast period. Satellite imaging for agriculture uses remote sensing technology from satellites to monitor and manage farming activities. It provides detailed data on crop health, soil conditions, irrigation levels, and weather impacts. This information helps farmers make informed decisions, improve yields, and reduce resource waste. By enabling precision farming, satellite imaging supports sustainable agriculture and early detection of issues such as pests, diseases, or drought stress across large agricultural areas.
Increased adoption of smart farming
The rising need for precision agriculture is driving widespread adoption of satellite imaging in farming operations. Farmers are leveraging high-resolution satellite data to monitor crop health, soil conditions, and irrigation needs more effectively. Governments worldwide are promoting smart farming initiatives to enhance food security and optimize resource usage. Advanced satellite analytics enable real-time decision-making, improving yield predictions and reducing waste. As a result, satellite imaging is becoming an essential tool in modern agricultural practices.
High initial investment
The deployment of satellite imaging technology requires significant upfront costs for hardware, software, and data subscriptions. Small and medium-sized farms often struggle to afford these advanced systems, limiting market penetration. Additionally, the need for skilled personnel to interpret satellite data adds to operational expenses. Maintenance and periodic upgrades further increase the total cost of ownership. These financial barriers hinder the widespread adoption of satellite imaging in agriculture, particularly in developing regions.
Rising awareness of sustainable farming practices
Growing environmental concerns are pushing farmers toward sustainable agriculture, creating new opportunities for satellite imaging. Precision farming techniques enabled by satellite data help reduce water usage, minimize chemical inputs, and lower carbon footprints. Governments and NGOs are funding programs to encourage eco-friendly farming with satellite-based monitoring. Consumers' increasing preference for sustainably produced food further drives demand for these technologies. Companies offering cost-effective satellite solutions stand to benefit from this expanding market.
Lack of standardized data formats
The absence of uniform data standards complicates the integration of satellite imaging with other agricultural technologies. Different providers use varying formats, making it difficult for farmers to consolidate and analyze data efficiently. This inconsistency also limits interoperability between farm management software and satellite platforms. Without industry-wide standardization, adoption rates may slow as users face compatibility challenges. Addressing this issue is crucial for seamless implementation across diverse agricultural systems.
Covid-19 Impact
The COVID-19 pandemic initially presented challenges for the Satellite Imaging for Agriculture market. Lockdowns and economic uncertainties led to potential delays in satellite launches and impacted the investment capacity of some farmers, possibly delaying technology adoption. However, the pandemic also highlighted the importance of remote monitoring in agriculture due to restricted movement and labour shortages. This increased the recognition of satellite imaging as a crucial tool for crop health monitoring, yield forecasting. Consequently, the demand for satellite imaging in agriculture is expected to have grown post-pandemic, driven by the need for sustainable and efficient farming practices.
The data services segment is expected to be the largest during the forecast period
The data services segment is expected to account for the largest market share during the forecast period, due to increasing demand for processed and actionable agricultural insights. Farmers rely on service providers for analytics, crop health reports, and yield forecasting derived from satellite imagery. Subscription-based models offer cost-effective access to real-time data without heavy infrastructure investments. Companies are also integrating AI to enhance data accuracy and predictive capabilities.
The research institutes segment is expected to have the highest CAGR during the forecast period
Over the forecast period, the research institutes segment is predicted to witness the highest growth rate, fuelled by rising demand for precision farming, climate monitoring, and sustainable agricultural practices. Government funding, technological advancements in remote sensing, and increasing collaborations with space agencies further fuel innovation. These institutes focus on crop health monitoring, yield prediction, and resource optimization, supporting food security initiatives and aiding policymakers and agribusinesses in data-driven decision-making for efficient agricultural management.
During the forecast period, the Asia Pacific region is expected to hold the largest market share due to its vast agricultural sector and increasing government support for agri-tech. Countries like India and China are deploying satellite imaging to enhance food production for their large populations. Favourable policies promoting digital farming and subsidies for smallholders accelerate adoption. The region's focus on reducing post-harvest losses through better monitoring also contributes to growth.
Over the forecast period, the North America region is anticipated to exhibit the highest CAGR, fuelled by advanced farming infrastructure and strong R&D investments. The U.S. and Canada are early adopters of satellite technology for large-scale precision agriculture. Private sector players are developing high-resolution imaging solutions tailored to regional crop needs. Supportive regulations and funding for sustainable farming practices further propel market growth.
Key players in the market
Some of the key players profiled in the Satellite Imaging for Agriculture Market include Planet Labs PBC, Airbus Defence and Space, Maxar Technologies, EOS Data Analytics (EOSDA), Farmonaut, Pixxel, ICEYE, Satellogic, European Space Imaging, Satellite Imaging Corporation (SIC), L3Harris Technologies, Esri, GEOSAT, Syngenta, and Farmers Edge Inc.
In April 2025, L3Harris Technologies has signed a strategic Memorandum of Understanding (MOU) between its SAMI-L3Harris Joint Venture (JV) and Zamil Shipyards, a leading maritime company based in Saudi Arabia. The MOU will advance local maritime engineering by incorporating autonomous technology into existing and next-generation vessels.
In November 2024, McDonald's USA and Syngenta North America, a leader in agricultural technology, announced a collaboration that aims to increase feed efficiency and help reduce the amount of greenhouse gas emissions released per pound of meat produced, as part of efforts to improve the sustainability of beef production.
Note: Tables for North America, Europe, APAC, South America, and Middle East & Africa Regions are also represented in the same manner as above.