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ATCOR

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Atmospheric & Topographic Correction (ATCOR)

ATCOR is a method used to reduce atmospheric and illumination effects on satellite image data to retrieve physical parameters of the earth’s surface such as atmospheric conditions emissivity, temperature, thermal, atmospheric radiance, and transmittance functions to simulate the simplified properties of a 3D atmosphere.

The method is restricted to high-resolution satellite imagery. Artificial Intelligence (AI) and Machine Learning (ML) algorithms can be utilized for producing large amounts of image data for multispectral and panchromatic imagery. The objective of this method is important for the analysis to:

  • Remove or reduce the influence of atmospheric and solar illumination, and cloud cover.
  • Be able to compare multi-temporal satellite images with different times of acquisition. After time atmospheric correction, changes observed are due to different features on the earth’s surface rather than differences of the atmospheric condition.
  • Improve the results of change detection and classification algorithms.
  • Be able to compare multi-sensor images with similar spectral bands.
  • Compare ground reflectance data retrieved from satellite imagery to the ground reflectance from measurements in the field.

ATCOR method is used for various applications such as:

Left scene without ATCOR – Right scene with ATCOR

ATCOR method is used for various applications such as:

ATCOR 2 - Correction of Flat Terrain

Solar Region

Processing of bands consists of the total signal at the sensor by path radiance, reflected radiation from the viewed pixel, and radiation from the neighborhood (topological space). The atmospheric condition such as water vapor content, aerosol type, and visibility for a scene can be estimated with the SPECTRA module, followed by the surface reflectance spectrum of the primary area in the scene which can be viewed as a function of the selected atmospheric parameters.

Thermal Region

Processing of bands by path radiance emitted by the atmosphere between ground and sensor emitted ground radiance (temperature and emissivity), and reflected downwelling thermal atmosphere flux. Scattered radiation from the neighborhood is usually neglected in the thermal region due to the scattering efficiency of the atmosphere decreases strongly with wavelength.

Schematic sketch of radiation components for a flat terrain

Copyright © DLR – German Aerospace Center and ReSe Applications. All rights reserved.

ATCOR 3 - Mountainous Terrain

ATCOR3 is atmospheric correction and haze removal software used to correct changes in the spectral reflectance of materials on the earth’s surface. ATCOR3 includes all of the capabilities of ATCOR2 and can be integrated with a DEM for atmospheric correction of images depicting rugged terrain.

Features:

  • Produce sharp and brilliant satellite imagery
  • Reduce the shadow effect in mountainous terrain
  • Obtain better classification results by using real reflectance values
  • Compare multi-temporal and multi-sensor values
  • Calculate value-added products such as sky view factor and cast shadow calculation

Schematic sketch of radiation components for rugged terrain

Copyright © DLR – German Aerospace Center and ReSe Applications. All rights reserved.

Consultancy

Ongoing Satellite remote sensing and GIS consultancy services are provided to our clients, including the set-up of reliable source coordinate databases in support of computerized mapping, exploration, and development of projects around the world and to clients implementing AI/ CV or GIS management systems, utilizing a variety of source data. For more information or for a consultation, please contact us.

30cm Pan & 1.2m Multispectral Sensors:

Pleiades-Neo*
SuperView-Neo
WorldView-3
WorldView-4 (Decommissioned)

40cm Pan & 1.6m Multispectral Sensors:

KOMPSAT-3A

50cm Pan & 2.0m Multispectral Sensors:

GeoEye-1
KOMPSAT-3
Pleiades-1*
SuperView-1
WorldView-1
WorldView-2

80cm Pan & 3.2m Multispectral Sensor:

TripleSat

1.0m Pan & 4.0m Multispectral Sensors:

KOMPSAT-2

1.5m Pan & 6.0m Multispectral Sensors:

SPOT-6*
SPOT-7*

*These sensors can also provide Tri-Stereo imagery providing the best stereo imagery for rugged terrain.

For more information on any of our products and services or for a consultation, please contact us.

services include

Our services include:

Geographic Information Systems

Satellite Image Processing

3D Digital Elevation Models (DEMs)

ATCOR (Atmospheric and Topographic Correction)

ATCOMP (Atmospheric Compensation)

3D Digital Terrain Models (DTMs)

Orthorectification

Mosaicing

Feature Extraction

Satellite Sensor

IMAGING Corporation Satellite Sensors

Other Satellite Sensors

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Jilin-1 4HD Smart Video Satellite

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Jilin-1 Hyperspectral Satellite

(2m)
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Jilin-1 Optical Satellite

(50cm)
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BlackSky

(0.8cm-1m)
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SuperView Neo

(30cm)
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Beijing-3

(30cm)
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Gaofen-2

(0.8m)
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KOMPSAT-3

(0.7m)
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KOMPSAT-3A

(0.55m)
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TripleSat

(0.8m)
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SkySat

(50cm)
Learn More

TerraSAR-X

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SPOT-6

(1.5m)
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SPOT-7

(1.5m)
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Jilin-1

(50cm)
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IKONOS Stereo

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IKONOS

(0.80m)
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Satellogic

(0.7m)
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QuickBird

(0.65m)
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SuperView-1

(0.5m)
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Pelican

(30cm)
Learn More

Pleiades-1B

(0.5m)
Learn More

Pleiades-1A

(0.5m)
Learn More

Pleiades Neo

(30cm)
Learn More

GeoEye-1

(0.50m)
Learn More

WorldView-3

(30cm)
Learn More

EROS NG

(30cm)
Learn More

WorldView Legion

(30cm)
Learn More

WorldView-2

(0.50m)
Learn More

WorldView-1

(0.50m)
Learn More
DISCOVER MORE Sensor

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TESTIMONIALS

Stories & Experiences

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FAQ’S

Frequently Asked Questions

How to find Geographic Coordinates in Google maps?

To find geographic coordinates in Google Maps, you can follow these steps:

  1. Open Google Maps in your web browser or on your mobile device.

  2. Search for the location you want to find the geographic coordinates for by entering the address, landmark, or name of the place in the search bar at the top of the page.

  3. Once the location is displayed on the map, right-click (or long-press on mobile) the exact point on the map where you want to find the coordinates. This will open a small menu.

  4. In the menu that appears, click on “What’s here?” or “What’s here? – Coordinates” option. On mobile devices, you may need to tap on the location marker first to reveal the menu options.

  5. A small information box will appear at the bottom of the screen, displaying the latitude and longitude coordinates of the selected point. The coordinates will be shown in decimal degrees format.

  6. You can click on the coordinates in the information box to expand it and see the coordinates in different formats, such as degrees, minutes, and seconds (DMS) or Universal Transverse Mercator (UTM) format.

To create a KML (Keyhole Markup Language) file in Google Earth, you can follow these steps:

  1. Download Google Earth Pro and Open on your computer.

  2. Navigate to the location or area you want to create a KML file for by using the search bar, zooming in/out, and panning on the map.

  3. Customize the view and layers in Google Earth Pro to include the specific data or elements you want to include in your KML file. This can include placemarks, paths, polygons, overlays, images, and more.

  4. Once you have set up the desired view and layers, go to the “Add” menu at the top of the screen and select the type of element you want to add (e.g., placemark, path, polygon, image overlay).

  5. Follow the prompts to add the specific element and provide the necessary information, such as location coordinates, name, description, and any additional properties or styling options.

  6. Repeat the previous step if you want to add more elements to your KML file.

  7. After adding all the desired elements, go to the “File” menu and select “Save Place As.”

  8. In the “Save Place As” dialog box, choose a location on your computer where you want to save the KML file.

  9. Specify the name of the KML file, ensuring it has the .kml extension (e.g., myfile.kmL), you may need to select KML as GoogleEarth defaults to KMZ formats.

  10.  Click the “Save” button to save the KMZ file to the specified location on your computer.

Ordering commercial high-resolution and medium-resolution satellite maps process:

  1. Identify your requirements: Determine the specific needs for the satellite maps, including the desired resolution, geographic coverage, acquisition date, and any additional specifications such as spectral bands or cloud cover constraints.

  2. Contact Us: Reach out to us to inquire about our imaging product and services. Provide us with the details of your requirements, including the area of interest, resolution, and any other specifications.

  3. If there is high urgency for imagery, please let us know that this is a time sensitive project. Any project deadlines should be included with your initial contact.

  4. Request a quote: Ask for a formal quote for the satellite maps you need. The quote should include information such as the cost, delivery timeline, licensing terms, and any additional services like data processing or analysis.

  5. Review the quote: Evaluate the quote provided by us and if needed, we can negotiate the terms, pricing, or any specific requirements that may not be fully covered.

  6. Confirm the order: Once you are satisfied with the quote and have reached an agreement, confirm your order. We will guide you through the necessary steps for payment and delivery.

  7. Receive the satellite maps: After the order is confirmed and payment is processed, you will receive the satellite map data in the specified format. This may include downloading the data from a secure portal or receiving physical media, depending on delivery method.

  8. Utilize the satellite maps: With the satellite maps that you receive, you can utilize it for your intended purposes, such as GIS data, 3D terrain maps, disaster, geospatial data, and other applications as needed.

Satellite map raw files refer to the unprocessed and unedited data captured by satellite sensors. These files contain the raw data received by the satellite sensors, including the reflected or emitted electromagnetic radiation from the Earth’s surface.

Satellite map raw files typically come in specialized formats specific to each satellite sensor or provider. These formats may include formats like GeoTIFF (georeferenced Tagged Image File Format) or ENVI (Environment for Visualizing Images). The raw files preserve the original sensor readings, which can include various spectral bands, radiometric information, and geometric parameters.

Raw files require processing to convert them into usable formats, such as georeferenced images or digital elevation model(DEM). Processing steps may involve radiometric and geometric corrections, atmospheric compensation, calibration, orthorectification, and mosaicking, among others.

Once processed, raw files can provide valuable information for various GIS data applications, including 3D terrain maps, agriculture production maps, vegetation maps, and disaster maps.

To download satellite maps from an FTP (File Transfer Protocol) server, you can follow these general steps:

  1. Obtain the FTP server information: Get the FTP server details from the satellite maps provider or the source you are accessing. This includes the FTP server address, username, password, and potentially the directory path to the imagery files.

  2. Choose an FTP client: Select an FTP client software or application that allows you to connect to the FTP server and perform file transfers. Some popular options include FileZilla, WinSCP, Cyberduck, or the built-in FTP functionality of certain web browsers.

  3. If you are unable to download an FTP client due to software locks, Windows has a built in FTP Protocol that can be accessed by copying the URL of the FTP server in your Windows File Explorer.

  4. Depending on the method to connect to the FTP, you will need credentials including a Username and Password to access these file.

  5. Most FTP clients will allow you to Copy and Paste or Drag and Drop the files from the client window to your local files.

Remember to comply with any terms and conditions associated with the satellite map data, including usage restrictions, licensing agreements, and any attribution requirements specified by the provider.

For any other questions or for a consultation, please contact us.

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