Agriculture Sensors Market: By Type, By Material Type, By End User and Region Forecast 2020-2031

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Agriculture Sensors Market Size, Share, Growth, Trends, and Global Industry Analysis: By Type (Soil Sensors, Climate Sensors, Crop Sensors, Water Quality Sensors, Others), By Material Type (Precision Farming, Greenhouse Monitoring, Livestock Monitoring, Irrigation Management, Crop Health Monitoring, Others), By End User (Large-Scale Farms, Small and Medium Farms, Agricultural Research Institutes, Government and Private Organizations) and Region Forecast 2020-2031

Report ID: 950515 | Published Date: Aug 2025 | No. of Pages: 202 | Format:

Agriculture Sensors Market size was valued at US$ 2,450.3 million in 2024 and is expected to reach US$ 5,383.1 million by 2031, growing at a significant CAGR of 11.2% from 2025-2031. Moreover, the U.S. Agriculture Sensors Market is projected to grow at 11.5% of CAGR by 2031. The market refers to the industry segment focused on the development, production, and deployment of sensor-based technologies designed to monitor, measure, and analyze various parameters in agricultural operations. These sensors collect real-time data on soil conditions, crop health, temperature, humidity, nutrient levels, and other environmental factors, enabling farmers to make informed decisions that enhance productivity, optimize resource use, and promote sustainable farming practices.

The market is experiencing robust growth, driven by the increasing adoption of precision farming techniques, rising demand for higher crop yields, and the global push toward sustainable agriculture. Advances in Internet of Things (IoT), wireless communication, and data analytics are enabling more efficient integration of sensors into farming systems, allowing for remote monitoring and automated decision-making. Governments and private organizations are investing heavily in smart agriculture technologies to address food security concerns, while emerging economies are rapidly embracing these solutions to improve efficiency and profitability in farming. This trend positions agriculture sensors as a vital component in the modernization of global agriculture.

Facts & Figures

In fact, Precision irrigation using soil moisture sensors can reduce water usage by up to 30% compared to traditional irrigation methods.
Farmers utilizing crop health sensors have reported yield improvements ranging from 10% to 20% due to early pest and disease detection.
The deployment of wireless sensor networks (WSNs) can cover agricultural fields spanning hundreds of hectares with minimal manual intervention.
In some smart farms, sensor data sampling rates reach up to once every 5 minutes, providing near real-time monitoring.
Adoption of sensor-based irrigation systems has led to fertilizer savings of approximately 15% through optimized nutrient application.
Remote sensing and sensor integration have reduced labor costs in monitoring crops by as much as 40% on technologically advanced farms.

Key Developments:

In February 2024, CropX Technologies, a global leader in digital agriculture solutions, announced the launch of a new product developed in partnership with Reinke Irrigation to enhance water management for farmers through field-specific Evapotranspiration (ET) measurements. The innovation, named Reinke Direct ET™ by CropX, offers affordable Actual Evapotranspiration (ETa) data via a sensor mounted on Reinke’s center pivot irrigation systems. This product is available exclusively through Reinke, aiming to provide farmers with precise, cost-effective tools to optimize irrigation and improve water efficiency.
In August 2024, OMRON Electronic Components, a global leader in innovative component solutions, announced the launch of its next-generation Weather Sensor. This new product aims to address the increasing need for reliable environmental data across sectors such as agriculture, meteorology, and smart city applications.
In November 2024, CropX, a global leader in digital agricultural solutions, launched a pioneering sensor across the Australasia region designed to monitor real-time plant water use through evapotranspiration (ET). This innovative above-canopy sensor integrates with the CropX agronomic farm management system, providing users with unparalleled insights into crop water consumption and requirements. By enabling data-driven irrigation scheduling and remote management, the technology aims to significantly enhance water-use efficiency in agricultural practices.

Agriculture Sensors Market Segmentation:

Based on the type:

Soil Sensors
Climate Sensors
Crop Sensors
Water Quality Sensors
Others

Among the various types of agriculture sensors, soil sensors are anticipated to be the leading driver of market growth. These sensors provide critical data on soil moisture, nutrient levels, and pH balance, enabling farmers to optimize irrigation and fertilization practices effectively. With increasing pressure to improve crop yields while conserving resources, soil sensors have become essential for precision farming. Their ability to deliver real-time, accurate information helps reduce water usage and prevent over-fertilization, thereby supporting sustainable agriculture. The rising demand for efficient resource management and enhanced crop productivity positions soil sensors as a key growth catalyst in the market.

Based on the application:

Precision Farming
Greenhouse Monitoring
Livestock Monitoring
Irrigation Management
Crop Health Monitoring
Others

Among the application segments, precision farming is anticipated to be the leading driver of growth in the market. Precision farming relies heavily on sensor technologies to gather detailed data on soil, weather, and crop conditions, allowing farmers to make data-driven decisions that enhance productivity and resource efficiency. This approach helps reduce input costs by optimizing the use of water, fertilizers, and pesticides, while increasing crop yields. The growing need to feed a rising global population and minimize environmental impact is accelerating the adoption of precision farming techniques, positioning it as the foremost application driving demand for agriculture sensors worldwide.

Based on the end user:

Large-Scale Farms
Small and Medium Farms
Agricultural Research Institutes
Government and Private Organizations

Among the end-user segments, large-scale farms are anticipated to be the leading driver of growth in the market. These farms have the financial capacity and operational scale to invest in advanced sensor technologies that enhance precision agriculture practices. By integrating sensors for soil, climate, and crop monitoring, large-scale farms can optimize resource utilization, improve crop yields, and reduce operational costs. The increasing emphasis on sustainable and efficient farming methods among large agricultural enterprises is accelerating the adoption of sensor technologies, making this segment the primary contributor to market expansion and technological innovation within the agriculture sensors landscape.

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Agriculture Sensors Market Summary

Study Period

2025 - 2031

Base Year

2024

CAGR

11.2%

Largest Market

North-America

Fastest Growing Market

Asia-Pacific

Agriculture Sensors Market Dynamics

Drivers

One of the key drivers of the market is the growing adoption of precision farming practices. Precision farming relies on accurate, real-time data to optimize agricultural inputs such as water, fertilizers, and pesticides, and agriculture sensors play a critical role in delivering this data. Farmers are increasingly turning to soil moisture sensors, nutrient sensors, and climate monitoring devices to make data-driven decisions that enhance crop yield and reduce waste. With global food demand on the rise due to population growth, there is heightened pressure on the agriculture sector to maximize productivity on limited arable land. By using sensors to monitor conditions at the micro level, farmers can apply resources exactly where and when they are needed, significantly improving efficiency.

Moreover, advancements in wireless connectivity and IoT integration have made it easier for even small and medium-scale farmers to adopt these technologies, further accelerating market growth.

Restraints

A significant restraining factor for the market is the high initial investment cost associated with deploying advanced sensor-based systems. Modern agriculture sensors, especially those integrated with IoT and AI capabilities, can be expensive to procure, install, and maintain. Many smallholder farmers in developing countries find these costs prohibitive, as the return on investment may take several growing seasons to materialize. In addition, the deployment of these systems often requires supplementary infrastructure, such as data management platforms, wireless networks, and trained personnel to interpret sensor data.

For regions with limited technological infrastructure, the cost burden is even higher. While government subsidies and agricultural modernization programs are helping to offset expenses in some markets, the affordability barrier continues to slow widespread adoption, particularly in rural and resource-constrained areas, thereby limiting the full growth potential of the market.

Opportunities

The integration of Artificial Intelligence (AI) and the Internet of Things (IoT) into agriculture presents a significant opportunity for the market. By combining advanced sensor technologies with AI-powered analytics, farmers can gain predictive insights into crop health, pest infestations, and irrigation requirements. IoT-enabled sensors can transmit real-time data to centralized systems, where AI algorithms process the information to recommend precise actions. For example, predictive irrigation systems can analyze soil moisture patterns and weather forecasts to determine optimal watering schedules, conserving water while improving yields.

This opportunity is especially relevant for regions facing climate variability and water scarcity, where efficient resource use is critical. As technology costs continue to decline and cloud-based platforms become more accessible, the AI-IoT integration in agriculture is expected to drive innovation and expand the adoption of smart farming systems globally, unlocking new revenue streams for sensor manufacturers.

Trends

A prominent trend in the market is the rising adoption of wireless and remote monitoring technologies. Farmers are increasingly opting for wireless sensor networks (WSNs) that allow them to track soil conditions, crop growth, and environmental parameters without manual intervention. This shift is largely driven by the need for real-time, location-specific data that can be accessed through smartphones or cloud-based dashboards. Wireless technologies eliminate the need for complex wiring systems, reducing installation costs and making it easier to deploy sensors across large or hard-to-reach farmland.

Additionally, advancements in low-power wide-area networks (LPWAN) and satellite connectivity are enabling reliable sensor performance in remote rural areas. This trend aligns with the broader digital transformation of agriculture, where connectivity and automation are key to improving efficiency and sustainability. As connectivity solutions continue to evolve, wireless sensor adoption is expected to accelerate, becoming a standard feature in modern farming operations.

North-America Got Significant Share

Agriculture Sensors Market Regional Analysis

Largest Share of the Region: North America is anticipated to hold the largest share of the market due to its well-established precision farming practices and advanced technological infrastructure. The region benefits from high adoption rates of sensor technologies supported by substantial investments from both government bodies and private enterprises. For instance, the U.S. Department of Agriculture has funded numerous initiatives to integrate smart farming tools, including soil moisture sensors and climate monitoring systems, to boost crop productivity and sustainability.

Additionally, the presence of major agriculture sensor manufacturers and technology providers in North America further strengthens the market position. The region’s robust IoT and data analytics ecosystem enables seamless integration of sensor data for informed decision-making, aligning with the market driver of precision agriculture. These factors collectively position North America as the dominant market in terms of revenue share and technological advancement in agriculture sensors.

Fastest Growing/ Emerging Region: The Asia-Pacific region is emerging as the fastest-growing market for agriculture sensors, driven by increased awareness of precision farming and rising demand for food due to rapid population growth. Countries such as India, China, and Australia are investing heavily in modernizing agricultural practices to enhance yield and resource efficiency. For example, India’s government has launched several initiatives promoting smart farming technologies, including subsidized sensors for soil and water monitoring.

The trend of wireless and remote monitoring solutions is also gaining traction, supported by expanding mobile network coverage and IoT adoption in rural areas. This growth is fuelled by the dual pressure of ensuring food security and coping with climate variability. As sensor costs decrease and digital infrastructure improves, the Asia-Pacific market is expected to outpace other regions in terms of adoption rate and innovation, reflecting the broader trend toward connected agriculture.

Latin America

Europe

Asia Pacific

Middle East

North America

Agriculture Sensors Market Segmentation Analysis

Report Benchmarks	Details
Report Study Period	2025 - 2031
Market Size in 2024	US$ 2,450.3 million
Market Size in 2031	US$ 5,383.1 million
Market CAGR	11.2%
By Type	Soil Sensors Climate Sensors Crop Sensors Water Quality Sensors Others
By Application	Precision Farming Greenhouse Monitoring Livestock Monitoring Irrigation Management Crop Health Monitoring Others
By End User	Large-Scale Farms Small and Medium Farms Agricultural Research Institutes Government and Private Organizations
By Region	North America (U.S., Canada) Europe (Germany, U.K., France, Italy, Russia, Spain, Rest of Europe) Asia-Pacific (China, India, Japan, Australia, Southeast Asia, Rest of Asia Pacific) Latin America (Mexico, Brazil, Argentina, Columbia, Rest of Latin America) Middle East & Africa (GCC, Egypt, Nigeria, South Africa, Rest of Middle East and Africa)

Analyst Review

According to PBI Analyst, the market is witnessing significant growth driven by the increasing adoption of precision farming and smart agriculture technologies worldwide. These sensors enable real-time monitoring of critical parameters such as soil moisture, nutrient levels, climate conditions, and crop health, empowering farmers to make data-driven decisions that improve productivity and resource efficiency. Advancements in IoT, wireless connectivity, and data analytics have further accelerated market expansion by enabling seamless integration and remote monitoring. Additionally, rising global food demand and the need for sustainable farming practices are fueling investments in sensor technologies, positioning the market as a vital component of modern agricultural transformation.

Key Features of the Report

The agriculture sensors market report provides granular level information about the market size, regional market share, historic market (2020-2024), and forecast (2025-2031)
The report covers in-detail insights about the competitor’s overview, company share analysis, key market developments, and key strategies
The report outlines drivers, restraints, unmet needs, and trends that are currently affecting the market
The report tracks recent innovations, key developments, and start-up details that are actively working in the market
The report provides a plethora of information about market entry strategies, regulatory framework, and reimbursement scenario
The report analyses the impact of the socio-political environment through PESTLE Analysis and competition through Porter Five Force Analysis.

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Frequently Asked Questions

The agriculture sensors market size was valued at US$ 2,450.3 million in 2024 and is projected to grow at a significant CAGR of 11.2% from 2025-2031.

Agriculture sensors are devices that collect data on various environmental and crop-related factors such as soil moisture, temperature, humidity, and nutrient levels. They use technologies like IoT, wireless networks, and data analytics to provide real-time insights, helping farmers optimize resource use and improve crop yields.

The most common types include soil sensors (moisture, pH, nutrient), climate sensors (temperature, humidity), crop sensors (disease detection, growth monitoring), and water quality sensors. Soil sensors are particularly vital for precision irrigation and fertilization.

Key drivers include the rising demand for precision farming, increasing need to improve crop productivity, advancements in IoT and data analytics, and the growing emphasis on sustainable and resource-efficient agriculture practices globally.

North America currently leads the market due to advanced agricultural technologies and strong infrastructure, while Asia-Pacific is the fastest-growing region, driven by increasing food demand, government initiatives, and expanding digital connectivity in rural areas.

Market research is segmented based on type, application, end user and region.

Content Updated Date: Aug 2025

Author

Manoj Kumar

Manoj Kumar is a postgraduate in Life Sciences with over seven years of dedicated experience in the fields of anima.....

1.Executive Summary

2.Global Agriculture Sensors Market Introduction

2.1.Global Agriculture Sensors Market - Taxonomy

2.2.Global Agriculture Sensors Market - Definitions

2.2.1.Type

2.2.2.Application

2.2.3.End User

2.2.4.Region

3.Global Agriculture Sensors Market Dynamics

3.1. Drivers

3.2. Restraints

3.3. Opportunities/Unmet Needs of the Market

3.4. Trends

3.5. Product Landscape

3.6. New Product Launches

3.7. Impact of COVID 19 on Market

4.Global Agriculture Sensors Market Analysis, 2020 - 2024 and Forecast 2025 - 2031

4.1. Market Analysis, 2020 - 2024 and Forecast, 2025 - 2031, (Sales Value USD Million)

4.2. Year-Over-Year (Y-o-Y) Growth Analysis (%)

4.3. Market Opportunity Analysis

5.Global Agriculture Sensors Market By Type , 2020 - 2024 and Forecast 2025 - 2031 (Sales Value USD Million)

5.1. Soil Sensors

5.1.1. Market Analysis, 2020 - 2024 and Forecast, 2025 - 2031, (Sales Value USD Million)

5.1.2. Year-Over-Year (Y-o-Y) Growth Analysis (%) and Market Share Analysis (%)

5.1.3. Market Opportunity Analysis

5.2. Climate Sensors

5.2.1. Market Analysis, 2020 - 2024 and Forecast, 2025 - 2031, (Sales Value USD Million)

5.2.2. Year-Over-Year (Y-o-Y) Growth Analysis (%) and Market Share Analysis (%)

5.2.3. Market Opportunity Analysis

5.3. Crop Sensors

5.3.1. Market Analysis, 2020 - 2024 and Forecast, 2025 - 2031, (Sales Value USD Million)

5.3.2. Year-Over-Year (Y-o-Y) Growth Analysis (%) and Market Share Analysis (%)

5.3.3. Market Opportunity Analysis

5.4. Water Quality Sensors

5.4.1. Market Analysis, 2020 - 2024 and Forecast, 2025 - 2031, (Sales Value USD Million)

5.4.2. Year-Over-Year (Y-o-Y) Growth Analysis (%) and Market Share Analysis (%)

5.4.3. Market Opportunity Analysis

5.5. Others

5.5.1. Market Analysis, 2020 - 2024 and Forecast, 2025 - 2031, (Sales Value USD Million)

5.5.2. Year-Over-Year (Y-o-Y) Growth Analysis (%) and Market Share Analysis (%)

5.5.3. Market Opportunity Analysis

6.Global Agriculture Sensors Market By Application, 2020 - 2024 and Forecast 2025 - 2031 (Sales Value USD Million)

6.1. Precision Farming

6.1.1. Market Analysis, 2020 - 2024 and Forecast, 2025 - 2031, (Sales Value USD Million)

6.1.2. Year-Over-Year (Y-o-Y) Growth Analysis (%) and Market Share Analysis (%)

6.1.3. Market Opportunity Analysis

6.2. Greenhouse Monitoring

6.2.1. Market Analysis, 2020 - 2024 and Forecast, 2025 - 2031, (Sales Value USD Million)

6.2.2. Year-Over-Year (Y-o-Y) Growth Analysis (%) and Market Share Analysis (%)

6.2.3. Market Opportunity Analysis

6.3. Livestock Monitoring

6.3.1. Market Analysis, 2020 - 2024 and Forecast, 2025 - 2031, (Sales Value USD Million)

6.3.2. Year-Over-Year (Y-o-Y) Growth Analysis (%) and Market Share Analysis (%)

6.3.3. Market Opportunity Analysis

6.4. Irrigation Management

6.4.1. Market Analysis, 2020 - 2024 and Forecast, 2025 - 2031, (Sales Value USD Million)

6.4.2. Year-Over-Year (Y-o-Y) Growth Analysis (%) and Market Share Analysis (%)

6.4.3. Market Opportunity Analysis

6.5. Crop Health Monitoring

6.5.1. Market Analysis, 2020 - 2024 and Forecast, 2025 - 2031, (Sales Value USD Million)

6.5.2. Year-Over-Year (Y-o-Y) Growth Analysis (%) and Market Share Analysis (%)

6.5.3. Market Opportunity Analysis

6.6. Others

6.6.1. Market Analysis, 2020 - 2024 and Forecast, 2025 - 2031, (Sales Value USD Million)

6.6.2. Year-Over-Year (Y-o-Y) Growth Analysis (%) and Market Share Analysis (%)

6.6.3. Market Opportunity Analysis

7.Global Agriculture Sensors Market By End User, 2020 - 2024 and Forecast 2025 - 2031 (Sales Value USD Million)

7.1. Large-Scale Farms

7.1.1. Market Analysis, 2020 - 2024 and Forecast, 2025 - 2031, (Sales Value USD Million)

7.1.2. Year-Over-Year (Y-o-Y) Growth Analysis (%) and Market Share Analysis (%)

7.1.3. Market Opportunity Analysis

7.2. Small and Medium Farms

7.2.1. Market Analysis, 2020 - 2024 and Forecast, 2025 - 2031, (Sales Value USD Million)

7.2.2. Year-Over-Year (Y-o-Y) Growth Analysis (%) and Market Share Analysis (%)

7.2.3. Market Opportunity Analysis

7.3. Agricultural Research Institutes

7.3.1. Market Analysis, 2020 - 2024 and Forecast, 2025 - 2031, (Sales Value USD Million)

7.3.2. Year-Over-Year (Y-o-Y) Growth Analysis (%) and Market Share Analysis (%)

7.3.3. Market Opportunity Analysis

7.4. Government and Private Organizations

7.4.1. Market Analysis, 2020 - 2024 and Forecast, 2025 - 2031, (Sales Value USD Million)

7.4.2. Year-Over-Year (Y-o-Y) Growth Analysis (%) and Market Share Analysis (%)

7.4.3. Market Opportunity Analysis

8.Global Agriculture Sensors Market By Region, 2020 - 2024 and Forecast 2025 - 2031 (Sales Value USD Million)

8.1. North America

8.1.1. Market Analysis, 2020 - 2024 and Forecast, 2025 - 2031, (Sales Value USD Million)

8.1.2. Year-Over-Year (Y-o-Y) Growth Analysis (%) and Market Share Analysis (%)

8.1.3. Market Opportunity Analysis

8.2. Europe

8.2.1. Market Analysis, 2020 - 2024 and Forecast, 2025 - 2031, (Sales Value USD Million)

8.2.2. Year-Over-Year (Y-o-Y) Growth Analysis (%) and Market Share Analysis (%)

8.2.3. Market Opportunity Analysis

8.3. Asia Pacific (APAC)

8.3.1. Market Analysis, 2020 - 2024 and Forecast, 2025 - 2031, (Sales Value USD Million)

8.3.2. Year-Over-Year (Y-o-Y) Growth Analysis (%) and Market Share Analysis (%)

8.3.3. Market Opportunity Analysis

8.4. Middle East and Africa (MEA)

8.4.1. Market Analysis, 2020 - 2024 and Forecast, 2025 - 2031, (Sales Value USD Million)

8.4.2. Year-Over-Year (Y-o-Y) Growth Analysis (%) and Market Share Analysis (%)

8.4.3. Market Opportunity Analysis

8.5. Latin America

8.5.1. Market Analysis, 2020 - 2024 and Forecast, 2025 - 2031, (Sales Value USD Million)

8.5.2. Year-Over-Year (Y-o-Y) Growth Analysis (%) and Market Share Analysis (%)

8.5.3. Market Opportunity Analysis

9.North America Agriculture Sensors Market ,2020 - 2024 and Forecast 2025 - 2031 (Sales Value USD Million)

9.1. Type Analysis 2020 - 2024 and Forecast 2025 - 2031 by Sales Value USD Million, Y-o-Y Growth (%), and Market Share (%)

9.1.1.Soil Sensors

9.1.2.Climate Sensors

9.1.3.Crop Sensors

9.1.4.Water Quality Sensors

9.1.5.Others

9.2. Application Analysis 2020 - 2024 and Forecast 2025 - 2031 by Sales Value USD Million, Y-o-Y Growth (%), and Market Share (%)

9.2.1.Precision Farming

9.2.2.Greenhouse Monitoring

9.2.3.Livestock Monitoring

9.2.4.Irrigation Management

9.2.5.Crop Health Monitoring

9.2.6.Others

9.3. End User Analysis 2020 - 2024 and Forecast 2025 - 2031 by Sales Value USD Million, Y-o-Y Growth (%), and Market Share (%)

9.3.1.Large-Scale Farms

9.3.2.Small and Medium Farms

9.3.3.Agricultural Research Institutes

9.3.4.Government and Private Organizations

9.4. Country Analysis 2020 - 2024 and Forecast 2025 - 2031 by Sales Value USD Million, Y-o-Y Growth (%), and Market Share (%)

9.4.1.United States of America (USA)

9.4.2.Canada

10.Europe Agriculture Sensors Market ,2020 - 2024 and Forecast 2025 - 2031 (Sales Value USD Million)

10.1. Type Analysis and Forecast by Sales Value USD Million, Y-o-Y Growth (%), and Market Share (%)

10.1.1.Soil Sensors

10.1.2.Climate Sensors

10.1.3.Crop Sensors

10.1.4.Water Quality Sensors

10.1.5.Others

10.2. Application Analysis 2020 - 2024 and Forecast 2025 - 2031 by Sales Value USD Million, Y-o-Y Growth (%), and Market Share (%)

10.2.1.Precision Farming

10.2.2.Greenhouse Monitoring

10.2.3.Livestock Monitoring

10.2.4.Irrigation Management

10.2.5.Crop Health Monitoring

10.2.6.Others

10.3. End User Analysis 2020 - 2024 and Forecast 2025 - 2031 by Sales Value USD Million, Y-o-Y Growth (%), and Market Share (%)

10.3.1.Large-Scale Farms

10.3.2.Small and Medium Farms

10.3.3.Agricultural Research Institutes

10.3.4.Government and Private Organizations

10.4. Country Analysis 2020 - 2024 and Forecast 2025 - 2031 by Sales Value USD Million, Y-o-Y Growth (%), and Market Share (%)

10.4.1.Germany

10.4.2.France

10.4.3.Italy

10.4.4.United Kingdom (UK)

10.4.5.Spain

11.Asia Pacific (APAC) Agriculture Sensors Market ,2020 - 2024 and Forecast 2025 - 2031 (Sales Value USD Million)

11.1. Type Analysis and Forecast by Sales Value USD Million, Y-o-Y Growth (%), and Market Share (%)

11.1.1.Soil Sensors

11.1.2.Climate Sensors

11.1.3.Crop Sensors

11.1.4.Water Quality Sensors

11.1.5.Others

11.2. Application Analysis 2020 - 2024 and Forecast 2025 - 2031 by Sales Value USD Million, Y-o-Y Growth (%), and Market Share (%)

11.2.1.Precision Farming

11.2.2.Greenhouse Monitoring

11.2.3.Livestock Monitoring

11.2.4.Irrigation Management

11.2.5.Crop Health Monitoring

11.2.6.Others

11.3. End User Analysis 2020 - 2024 and Forecast 2025 - 2031 by Sales Value USD Million, Y-o-Y Growth (%), and Market Share (%)

11.3.1.Large-Scale Farms

11.3.2.Small and Medium Farms

11.3.3.Agricultural Research Institutes

11.3.4.Government and Private Organizations

11.4. Country Analysis 2020 - 2024 and Forecast 2025 - 2031 by Sales Value USD Million, Y-o-Y Growth (%), and Market Share (%)

11.4.1.China

11.4.2.India

11.4.3.Australia and New Zealand (ANZ)

11.4.4.Japan

11.4.5.Rest of APAC

12.Middle East and Africa (MEA) Agriculture Sensors Market ,2020 - 2024 and Forecast 2025 - 2031 (Sales Value USD Million)

12.1. Type Analysis and Forecast by Sales Value USD Million, Y-o-Y Growth (%), and Market Share (%)

12.1.1.Soil Sensors

12.1.2.Climate Sensors

12.1.3.Crop Sensors

12.1.4.Water Quality Sensors

12.1.5.Others

12.2. Application Analysis 2020 - 2024 and Forecast 2025 - 2031 by Sales Value USD Million, Y-o-Y Growth (%), and Market Share (%)

12.2.1.Precision Farming

12.2.2.Greenhouse Monitoring

12.2.3.Livestock Monitoring

12.2.4.Irrigation Management

12.2.5.Crop Health Monitoring

12.2.6.Others

12.3. End User Analysis 2020 - 2024 and Forecast 2025 - 2031 by Sales Value USD Million, Y-o-Y Growth (%), and Market Share (%)

12.3.1.Large-Scale Farms

12.3.2.Small and Medium Farms

12.3.3.Agricultural Research Institutes

12.3.4.Government and Private Organizations

12.4. Country Analysis 2020 - 2024 and Forecast 2025 - 2031 by Sales Value USD Million, Y-o-Y Growth (%), and Market Share (%)

12.4.1.GCC Countries

12.4.2.South Africa

12.4.3.Rest of MEA

13.Latin America Agriculture Sensors Market ,2020 - 2024 and Forecast 2025 - 2031 (Sales Value USD Million)

13.1. Type Analysis and Forecast by Sales Value USD Million, Y-o-Y Growth (%), and Market Share (%)

13.1.1.Soil Sensors

13.1.2.Climate Sensors

13.1.3.Crop Sensors

13.1.4.Water Quality Sensors

13.1.5.Others

13.2. Application Analysis 2020 - 2024 and Forecast 2025 - 2031 by Sales Value USD Million, Y-o-Y Growth (%), and Market Share (%)

13.2.1.Precision Farming

13.2.2.Greenhouse Monitoring

13.2.3.Livestock Monitoring

13.2.4.Irrigation Management

13.2.5.Crop Health Monitoring

13.2.6.Others

13.3. End User Analysis 2020 - 2024 and Forecast 2025 - 2031 by Sales Value USD Million, Y-o-Y Growth (%), and Market Share (%)

13.3.1.Large-Scale Farms

13.3.2.Small and Medium Farms

13.3.3.Agricultural Research Institutes

13.3.4.Government and Private Organizations

13.4. Country Analysis 2020 - 2024 and Forecast 2025 - 2031 by Sales Value USD Million, Y-o-Y Growth (%), and Market Share (%)

13.4.1.Brazil

13.4.2.Mexico

13.4.3.Rest of LA

14. Competition Landscape

14.1. Market Player Profiles (Introduction, Brand/Product Sales, Financial Analysis, Product Offerings, Key Developments, Collaborations, M & A, Strategies, and SWOT Analysis)

14.2.1.John Deere

14.2.2.Trimble Inc.

14.2.3.AGCO Corporation

14.2.4.Raven Industries, Inc.

14.2.5.Hexagon AB

14.2.6.Sentera

14.2.7.Sensoterra

14.2.8.CropX

14.2.9.PrecisionHawk

14.2.10.Libelium

15. Research Methodology

16. Appendix and Abbreviations

Key Market Players

John Deere
Trimble Inc.
AGCO Corporation
Raven Industries, Inc.
Hexagon AB
Sentera
Sensoterra
CropX
PrecisionHawk
Libelium

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