An Introduction to Soil Moisture Monitoring

What is Soil Moisture Monitoring?

Soil moisture monitoring involves measuring the amount of water present in the soil, typically using sensors or manual tools. It helps farmers, landscapers, and researchers make informed decisions about irrigation, crop health, and soil management. Accurate soil moisture data supports water conservation and improves agricultural efficiency by preventing overwatering or under-watering.

Importance

Soil moisture monitoring is important because it ensures crops receive the right amount of water, promoting healthy growth and higher yields. It helps conserve water resources by preventing unnecessary irrigation, which is especially critical in areas facing drought or water restrictions. When integrated with agricultural machinery, soil moisture data can automate irrigation systems for more precise and efficient field management.

Common Ways to Measure Soil Moisture

There are various ways for teams to monitor soil moisture, and each approach comes with its own set of benefits and limitations. Organizations looking to monitor soil moisture must figure out the best method for their needs and resources. Here’s a look at some of the key methods companies use to measure and monitor soil moisture:

Gravimetric Method

The gravimetric method is a traditional, highly accurate technique for measuring soil moisture. This involves collecting a soil sample, weighing it, drying it in an oven to remove all moisture, and then weighing it again. The recorded difference in weight represents the amount of water originally present in the soil. While precise, this method is labor-intensive, time-consuming, and not suitable for real-time monitoring.

Monitoring Sensors

Soil moisture sensors are electronic devices placed directly in the soil to measure water content in real time. Common types of sensors include Internet-of-Things (IoT) moisture monitoring sensors, capacitive sensors, , Time-Domain Reflectometry (TDR) sensors, and gypsum block sensors. These provide continuous data that can be used to automate irrigation systems or inform manual watering decisions. They are efficient, scalable, and widely used in modern agriculture due to their ability to integrate with digital platforms and agricultural machinery.

Remote Sensing

Remote sensing uses satellite imagery, drones, or aerial photography to estimate soil moisture across large areas. It typically relies on analyzing surface reflectance and temperature to infer moisture levels without physical contact with the soil. This method is useful for covering vast agricultural regions quickly and identifying moisture trends over time. This type of moisture monitoring method is often used in combination with other methods for best results.

Challenges

Soil moisture monitoring can be a complex task, and teams often run into challenges when trying to conduct it. Understanding the common challenges faced during the monitoring process can help teams plan and prepare better. Below are some common challenges teams face during soil moisture monitoring processes:

Environmental Variability

Environmental variability, such as changes in temperature, rainfall, and soil composition, can significantly affect soil moisture levels and lead to inconsistent readings. These fluctuations make it difficult to establish reliable irrigation schedules and can reduce the accuracy of moisture monitoring systems. Seasonal shifts and microclimates also further complicate the process. Soil sensors that gather data across different zones in different weather conditions may be a solution to this.

Resource Constraints

Many farms, especially small or remote ones, face limitations in funding, labor, and technical expertise needed to implement advanced soil moisture monitoring systems. These constraints can prevent the adoption of sensor-based or automated solutions. As a result, manual methods may still be relied upon despite their inefficiency.

Data Management

Managing the vast amount of data generated by soil moisture sensors and remote sensing systems can be challenging, particularly without proper tools. Farmers may struggle to interpret raw data or integrate it into decision-making processes. Modern technology addresses this by offering cloud-based platforms, mobile apps, and AI-driven analytics that organize and visualize data for easier use. These tools help transform raw readings into actionable insights.

Equipment Maintenance

Soil moisture monitoring systems, particularly sensors and electronic components, require regular maintenance to ensure accuracy and prevent breakdowns. Exposure to weather, soil conditions, and pests can degrade equipment performance over time. Modern technology helps overcome this challenge through digital checklists, automatic maintenance reminders, and predictive maintenance scheduling tools. These innovations reduce downtime and extend equipment life.

Best Practices for Efficient Soil Moisture Monitoring

While teams are encouraged to build soil moisture monitoring workflows that fit their specific needs and requirements, there are some best practices that they should follow. Here are some of the best practices for monitoring soil moisture effectively:

Best Practices for Efficient Soil Moisture Monitoring

Use Reliable Sensors

Using high-quality, reliable sensors is essential for collecting accurate soil moisture data. Inexpensive or poorly made sensors can give inconsistent readings, leading to over- or under-watering. Investing in trusted brands and proven sensor technologies ensures dependable performance. Keep track of these sensors with an asset management platform to identify maintenance times, inspections, and issues to ensure their reliability.

Calibrate Equipment Regularly

Calibration involves comparing sensor readings against a known standard and making adjustments as needed. Regular calibration in coordination with inspections and proper asset management practices ensures that soil moisture monitoring equipment remains accurate over time. Environmental factors, soil type, and wear can cause sensors to drift from their original accuracy.

Monitor at Multiple Depths

Soil moisture levels can vary significantly at different depths, especially in layered or sandy soils. Monitoring at multiple depths allows for a more comprehensive understanding of root-zone moisture and helps prevent surface-only readings from misleading irrigation decisions. Sensors placed at shallow, medium, and deep levels provide a full profile of soil water availability.

Integrate with Weather Data

Combining soil moisture readings with local weather data like rainfall, temperature, and humidity on a cloud-based platform offers a more complete picture of field conditions accessible anytime and anywhere. This integration helps predict moisture trends and informs irrigation planning more effectively. Weather-aware systems can delay irrigation during rainy periods or adjust watering schedules during heat waves.

Establish Moisture Thresholds

Defining upper and lower moisture thresholds allows for targeted irrigation based on actual crop needs. These thresholds help avoid overwatering, which can lead to root rot or nutrient leaching, and under-watering, which stresses plants. Moisture thresholds can be set by crop type, soil composition, and growth stage. Monitor these thresholds with regular inspections, and identify instances of noncompliance for future corrective actions to implement.