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=== Multispectral image data (Sentinel-2) ===
 
=== Multispectral image data (Sentinel-2) ===
   
Saarland’s State Office for Surveying, Spatial Information and Land Development (LVGL) provides continuously updated data from Sentinel-2 satellites free of charge. The Sentinel-2 Mission consists of a pair of structurally identical satellites, which circle the Earth at 180° to one another on the same orbit and at a height of approximately 786 km. This arrangement ensures that Saarland is overflown '''roughly once every five days'''. Sentinel-2 is equipped with a multispectral instrument (MSI) featuring a total of 13 spectral channels (figure 1).
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Saarland’s State Office for Surveying, Geoinformation and Land Development (LVGL) provides continuously updated data from Sentinel-2 satellites free of charge. The Sentinel-2 Mission consists of a pair of structurally identical satellites, which circle the Earth at 180° to one another on the same orbit and at a height of approximately 786 km. This arrangement ensures that Saarland is overflown '''roughly once every five days'''. Sentinel-2 is equipped with a multispectral instrument (MSI) featuring a total of 13 spectral channels (figure 1).
   
 
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<li style="display: inline-block;">[[Datei:Sentinel-2_Abb4.png|thumb|Abbildung 4: Sentinel-2 Falschfarbenbild vom 02.07.2019 Ausschnitt „Saarschleife“|link=]]</li>
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<li style="display: inline-block;">[[Datei:Sentinel-2_Abb4.png|thumb|Figure 4: Sentinel-2 false-colour image taken 02/07/2019, ‘Saar Bow’ detail|link=]]</li>
<li style="display: inline-block;">[[Datei:Sentinel-2_Abb5.png|thumb|Abbildung 5: Sentinel-2 Falschfarbenbild vom 04.12.2019 Ausschnitt „Saarschleife“|link=]]</li>
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<li style="display: inline-block;">[[Datei:Sentinel-2_Abb5.png|thumb|Figure 5: Sentinel-2 false-colour image taken 04/12/2019, ‘Saar Bow’ detail|link=]]</li>
 
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==== Normierter Differenzierter Vegetationsindex (NDVI) ====
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==== Normalised difference vegetation index (NDVI) ====
   
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The NDVI is utilised as a metric for vegetation cover on a specific area and therefore visualises vegetation health. The typical reflection gradient for a healthy plant reduces reflectance in the visible red spectrum while boosting reflectance in the near-infrared spectrum. This level of boosting in the near-infrared spectrum will be stronger for healthier (greener) plants.
Der NDVI wird als Maß für die Vegetationsbedeckung einer Fläche verwendet. Er zeigt die Vitalität der Vegetation. Der typische Reflexionsverlauf einer gesunden Pflanze führt auf eine geringe Reflexion im sichtbaren roten Bereich und eine starke Reflexion im nahen infraroten Bereich zurück. Je grüner/gesünder die Pflanze ist, desto stärker ist der Anstieg der Reflexionskurve im nahen infraroten Bereich.
 
   
 
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As a normalised metric, the NDVI only accepts values in the range −1 to +1: this compensates for the influence of terrain inclination and lighting conditions.
Aufgrund der Normierung nimmt der NDVI nur Werte zwischen -1 und +1 an. Es werden dadurch Einflüsse der Geländeneigung und Beleuchtungsverhältnisse kompensiert.
 
   
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The dataset is colour-coded, with colours ranging from brown (no vegetation) to yellow and dark green (healthy vegetation). Negative values indicate surface water. A value between 0 and 0.2 indicates areas virtually free of vegetation, whereas a value close to 1 indicates an area possessing significant green plant coverage.
Der Datensatz ist farbcodiert, wobei die Farbskala von braun (keine Vegetation) über gelb bis dunkelgrün (gesunde Vegetation) reicht. Negative Werte bezeichnen Wasserflächen. Ein Wert zwischen 0 und 0.2 entspricht nahezu vegetationsfreien Flächen, während ein Wert nahe 1 auf eine hohe Vegetationsbedeckung mit grünen Pflanzen schließen lässt.
 
   
 
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<li style="display: inline-block;">[[Datei:Sentinel-2_Abb6.png|thumb|Abbildung 6: NDVI berechnet aus Sentinel-2 Daten vom 02.07.2019 Ausschnitt „Saarschleife"|link=]]</li>
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<li style="display: inline-block;">[[Datei:Sentinel-2_Abb6.png|thumb|Figure 6: NDVI calculated from Sentinel-2 data on 02/07/2019, ‘Saar Bow’ detail|link=]]</li>
<li style="display: inline-block;">[[Datei:Sentinel-2_Abb7.png|thumb|Abbildung 7: NDVI berechnet aus Sentinel-2 Daten vom 04.12.2019 Ausschnitt „Saarschleife“|link=]]</li>
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<li style="display: inline-block;">[[Datei:Sentinel-2_Abb7.png|thumb|Figure 7: NDVI calculated from Sentinel-2 data on 04/12/2019, ‘Saar Bow’ detail|link=]]</li>
 
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== Anleitung ==
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== Instructions ==
   
 
<ul class="box" style="margin-top: 0px;">
 
<ul class="box" style="margin-top: 0px;">
<li class="download">[//{{SERVERNAME}}/mediawiki/images/a/af/Anleitung_Sentinel2.pdf Anleitung zur Nutzung der Fachanwendung]</li>
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<li class="download">[//{{SERVERNAME}}/mediawiki/images/a/af/Anleitung_Sentinel2.pdf Instructions for using the portal application]</li>
 
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== Ansprechpartner ==
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== Contacts ==
   
'''Landesamt für Vermessung, Geoinformation und Landentwicklung'''<br />
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'''State Office for Surveying, Geoinformation and Land Development'''<br />
Sach­ge­biet 2.3
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Section 2.3
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Satellite-Based Remote Sensing, InVeKoS, ZORA, IT Security<br />
Sa­tel­li­ten­ge­stütz­te Fer­ner­kun­dung, In­Ve­KoS, ZO­RA, IT-​Si­cher­heit<br />
 
 
Thomas Engel<br />
 
Thomas Engel<br />
[mailto:T.Engel@lvgl.saarland.de E-Mail-Kontakt]<br />
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[mailto:T.Engel@lvgl.saarland.de Email]<br />
Telefon: +49 681 9712-223
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Phone: +49 681 9712-223

Aktuelle Version vom 22. November 2022, 13:58 Uhr


Sentinel-2 Saarland

Sentinel

Viewer

Go to map collection for Sentinel-2 data

Description

Copernicus satellite data

Copernicus is a European Earth observation programme that is organised and conducted by the European Union (EU) in collaboration with the European Space Agency (ESA), the European Organisation for Meteorological Satellites (EUMETSAT) and the EU member states. Copernicus consists of various systems for data collection and combines remote sensing with local measurements (in-situ component). The observational data is used to derive information of relevance for the environment and security for five core services. These services primarily address the environment, climate, sustainable development, humanitarian aid and public security.

The Copernicus programme also maintains its own fleet of satellites: these Sentinel satellites are used for the global observation of the atmosphere, oceans and land surfaces. Sentinel data and the Copernicus services are available free of charge and in full for anyone to use – from public-sector personnel to researchers, commercial companies as well as charitable organisations and private citizens.

Multispectral image data (Sentinel-2)

Saarland’s State Office for Surveying, Geoinformation and Land Development (LVGL) provides continuously updated data from Sentinel-2 satellites free of charge. The Sentinel-2 Mission consists of a pair of structurally identical satellites, which circle the Earth at 180° to one another on the same orbit and at a height of approximately 786 km. This arrangement ensures that Saarland is overflown roughly once every five days. Sentinel-2 is equipped with a multispectral instrument (MSI) featuring a total of 13 spectral channels (figure 1).

  • Figure 1: Sentinel-2 spectral channels with 10 m spatial resolution: B2 (blue: 490 nm), B3 (green: 560 nm), B4 (red: 665 nm) and B8 (NIR: 842 nm) [©ESA2020 Sentinel Online User Guides ]

Cloud cover means that a clear view of the Earth’s surface is often unavailable. Accordingly, the State Office views the current data and provides images of Saarland that are clear of clouds.

The image data provided features a spatial resolution of 10 m x 10 m and is post-processed to the ‘Level-2A’ data standard, i.e. georeferenced, radiometrically optimised and atmosphere-corrected. We recommend viewing the data at a 1:50,000 or smaller scale. Data can be provided via GeoPortal Saarland as well as the ZORA cartographic information system. Data can also be obtained using a web map service (WMS).

The image data is particularly suited to use in large-scale topography applications, where changes in topography, vegetation or land use can be visualised immediately. This availability of up-to-date topographic datasets is a novel development.

The following products are currently offered by the LVGL:

True-colour images (TrueColorImage, TCI)

As the name suggests, a true-colour image faithfully represents the original colours and is therefore equivalent to a photograph. The image data represents a combination of the spectral channels B4 (red), B3 (green) and B2 (blue).

  • Figure 2: Sentinel-2 true-colour image taken 02/07/2019, ‘Saar Bow’ detail
  • Figure 3: Sentinel-2 true-colour image taken 04/12/2019, ‘Saar Bow’ detail

False-colour images (Colored InfraRed, CIR)

A CIR false-colour image (Colored InfraRed) can be used to visualise the health of biomass, such as grasses, leaves on bushes, etc. The channel used for these images is the near-infrared (NIR) channel. Green (healthy) vegetation has a particular ‘spectral fingerprint’: the pigments in this vegetation, such as chlorophyll, are reflected in the green visible spectrum by incident light and this effect is further reinforced in the infrared spectrum. As a result of the high reflectance in the infrared spectrum, healthy plants are therefore especially prominent in infrared.

Accordingly, this data can be used to interpret a range of potential manifestations of vegetation, such as mapping forest damage or surveying different types of biotopes.

The image data represents a combination of the spectral channels B8 (NIR), B4 (green) and B3 (blue).

  • Figure 4: Sentinel-2 false-colour image taken 02/07/2019, ‘Saar Bow’ detail
  • Figure 5: Sentinel-2 false-colour image taken 04/12/2019, ‘Saar Bow’ detail

Normalised difference vegetation index (NDVI)

The NDVI is utilised as a metric for vegetation cover on a specific area and therefore visualises vegetation health. The typical reflection gradient for a healthy plant reduces reflectance in the visible red spectrum while boosting reflectance in the near-infrared spectrum. This level of boosting in the near-infrared spectrum will be stronger for healthier (greener) plants.

  • Sentinel-2 Formel1.PNG


As a normalised metric, the NDVI only accepts values in the range −1 to +1: this compensates for the influence of terrain inclination and lighting conditions.

The dataset is colour-coded, with colours ranging from brown (no vegetation) to yellow and dark green (healthy vegetation). Negative values indicate surface water. A value between 0 and 0.2 indicates areas virtually free of vegetation, whereas a value close to 1 indicates an area possessing significant green plant coverage.

  • Figure 6: NDVI calculated from Sentinel-2 data on 02/07/2019, ‘Saar Bow’ detail
  • Figure 7: NDVI calculated from Sentinel-2 data on 04/12/2019, ‘Saar Bow’ detail

Instructions

Contacts

State Office for Surveying, Geoinformation and Land Development
Section 2.3 Satellite-Based Remote Sensing, InVeKoS, ZORA, IT Security
Thomas Engel
Email
Phone: +49 681 9712-223