InGaAs SWIR 900-1700nm Hyperspectral camera for DJI Matrice M350

Features

DJI Matrice 350 Drone SWIR 900-1700nm Hyperspectral Camera, 1024 Spectral Channels, 1280 Spatial Channels, with Spectral Resolution Better than 6.5nm. Combining a high diffraction efficiency holographic transmission grating spectral module with a high-sensitivity InGaAs focal plane array camera, auxiliary camera technology, achromatic lens, and ultra-lightweight body materials. It detects continuous spectral distribution for each pixel, meeting the needs of camouflage and anti-camouflage in military applications, as well as ground object and geological mineral exploration, water pollution (oil spill) monitoring, modern precision agriculture, forestry, and other ecological environmental monitoring applications.

Features:

• Spectral Method: Transmission Grating Spectral
• Spectral Range: 900-1700nm
• Spectral Bands: 1024
• Spectral Resolution: 6.5nm
• Spatial Pixel Count: 1280
• Imaging Speed: Full Spectrum: 70Hz, Maximum: 1800Hz
• Detector: InGaAs
• ROI: Multiple regions supported
• Operation: Easy operation, single-person operation possible
• Memory: 8GB RAM, 512GB/1TB SSD

SWIR hyperspectral camera Typical Applications:

• Water Pollution (Oil Spill) Monitoring
  In oil and gas leak monitoring, the hyperspectral camera detects the presence of oil and gas by identifying specific wavelengths of spectral energy emitted by the objects. Different types of oil and gas have distinct reflection and absorption characteristics on the spectrum. By analyzing these characteristics, leak events can be accurately located and quantified. Traditional leak monitoring methods often provide limited information and cannot achieve precise oil and gas leak detection.
• Camouflage Identification of Targets
  This meets the timeliness of battlefield intelligence and the foundation for effective camouflage target detection. Hyperspectral remote sensing technology observes targets from three different dimensions: space, time, and spectrum, thus providing more comprehensive and detailed information about the target. The spectral feature curves obtained from detection can help reverse-engineer the target’s composition at each pixel, distinguishing background from target based on the spectral properties of the target material.
• Geological Mineral Exploration
  Hyperspectral geological mineral exploration is a method that uses hyperspectral imaging technology to detect and identify minerals. Hyperspectral imaging can capture information beyond the visible light spectrum. By analyzing the spectral characteristics, it is possible to determine the chemical composition and mineral composition of the ore.