Click Here For More

1. What is hyperspectral imaging?
Hyperspectral imaging analyzes detailed spectral data across numerous continuous wavelength bands for each pixel, offering comprehensive insights into material properties based on light reflection, absorption, and emission.

2. How does spectral sensing work?
Spectral sensing measures how materials interact with light at different wavelengths to identify their properties and detect specific features or anomalies.

3. What are the main applications of hyperspectral imaging?
Applications include agriculture, environmental management, mineral exploration, urban planning, and cultural heritage preservation.

4. What are spatial resolution and spectral resolution?
  • Spatial Resolution: Refers to the size of one pixel’s footprint on the ground, calculated as the Instantaneous Field of View (IFOV) multiplied by the flight height.
  • Spectral Resolution: Indicates the ability to differentiate between closely spaced wavelengths. Higher spectral resolution means narrower wavelength bands and improved discrimination.


5. What are the advantages of hyperspectral imaging?
  • Enhanced Detail: Provides high-resolution spectral data across many bands.
  • Subtle Feature Detection: Identifies fine differences and features.
  • Non-Destructive: Analyzes samples without causing damage.
  • Wide Application: Useful in various fields from agriculture to environmental monitoring.


6. Hyperspectral vs multispectral/RGB cameras
  • RGB cameras: Capture images in three color channels with limited spectral detail.
  • Multispectral cameras: Capture data in a few discrete bands, offering more spectral detail than RGB.
  • Hyperspectral cameras: Provide continuous spectral data across hundreds of bands for detailed analysis.


7. What types of hyperspectral imaging systems are available?
  • Pushbroom systems: Collect data line by line as the platform moves.
  • Whiskbroom systems: Use point scanners and mirrors to collect line-of-sight data.
  • Staring systems: Use filters to capture data at various wavelengths simultaneously.


8. What should be considered when setting up a hyperspectral camera?
  • Spatial and spectral resolution: Required level of detail.
  • Field of view (FOV): Area to be imaged.
  • Wavelength range: Spectral features of interest.
  • Environmental conditions: Impact of weather and lighting.


9. What are the benefits of hyperspectral imaging for research?
Offers detailed, non-destructive analysis with high-resolution data, enabling precise material identification and comprehensive studies.

10. What is VNIR hyperspectral imaging?
VNIR imaging captures data from 400 to 1000 nm, covering visible and near-infrared light, and is used for applications such as vegetation analysis and mineral exploration.

Sort By:
Show:
Chinese first imaging camera
Drone Hyperspectral Imaging System(ATHL9010P)
0.00″W x 0.00″D x 0.00″H
ATHL9010P
    ATHL9010 series is the 3rd generation hyperspectral imager integrated LiDAR system. Th..
$0.00
Availability In Stock
Chinese first imaging camera
Drone Hyperspectral Imaging System(ATHL9010W)
0.00″W x 0.00″D x 0.00″H
ATHL9010W
    ATHL9010 series is the 3rd generation hyperspectral imager integrated LiDAR system. Th..
$0.00
Availability In Stock
Chinese first imaging camera
Multirotor Unmanned Aircraft System
0.00″W x 0.00″D x 0.00″H
ATH9010-A
  Optosky electric hexacopter drone, available on demand to quickly change different payload eq..
$0.00
Availability In Stock
hyperspectral imager
Drone crop monitoring system
0.00″W x 0.00″D x 0.00″H
ATH9010NY
The ATH9010NY series drone-borne early crop inspection system is based on the th..
$0.00
Availability In Stock
hyperspectral imager
Drone Forest Health Monitor
0.00″W x 0.00″D x 0.00″H
ATH9010SXC
The ATH9010SXC series UAV-borne early pine nematode inspection system has the ch..
$0.00
Availability In Stock
Showing 46 to 50 of 50 (4 Pages)