Satellite Agriculture Monitoring For Field Analytics

What does it mean? GeoPard provides access to 30+ years of an archive of processed, calibrated, and cleaned satellite image data with comprehensive sets of views. The views are calculated against every satellite image in the blink of an eye. 

Deep in-season and historical field analytics is the basis of the GeoPard solution.

What is satellite agriculture monitoring?

Satellite agriculture monitoring refers to the use of satellite-based remote sensing technologies to gather information about agricultural crops and the land they are grown on.

This technology allows farmers and researchers to track crop growth, detect changes in vegetation health, measure the extent of land use, and monitor environmental conditions from a distance.

By analyzing satellite images, farmers can detect problems early, such as nutrient deficiencies, pests, and diseases, and take corrective actions before they cause significant damage to crops.

The data obtained from satellite imagery can also be used to optimize irrigation schedules, predict yield, and estimate crop production.

Satellite agriculture monitoring can provide valuable insights for agricultural management, allowing farmers to make more informed decisions and improve their yield and profitability.

It also plays an important role in food security and sustainability by enabling more efficient use of natural resources and reducing the environmental impact of agriculture.

How can you use satellite agriculture monitoring?

In near-real-time, you can monitor crop development including retrospective analysis and condition assessment, scout for areas with different levels of growth, detect anomalies and, for sure, compare your farm with neighboring fields and areas.

Further, it can be used in several ways to benefit farmers and researchers. Here are a few examples:

• Crop monitoring: Satellite imagery can be used to monitor crop growth and development over time. By analyzing satellite images, farmers can track the health of their crops, identify areas of stress or disease, and adjust their management practices accordingly.
• Yield prediction: Satellite data can be used to estimate crop yields based on vegetation indices, soil moisture, and other parameters. This information can help farmers make informed decisions about harvest schedules and marketing strategies.
• Irrigation management: Satellite imagery can be used to monitor soil moisture levels and crop water use, allowing farmers to optimize their irrigation schedules and reduce water waste.
• Soil mapping: Satellite imagery can be used to map soil properties such as texture, organic matter content, and nutrient availability. This information can help farmers make more informed decisions about fertilization and other soil management practices.
• Pest and disease monitoring: Satellite imagery can be used to detect areas of pest and disease infestation, allowing farmers to take preventive measures before significant damage occurs.
• Land use mapping: Satellite imagery can be used to map land use patterns and changes over time. This information can help policymakers and researchers better understand land use dynamics and develop more effective land use policies.

Overall, satellite agriculture monitoring provides a wealth of information that can help farmers and researchers make more informed decisions and improve agricultural productivity and sustainability.