Difference between revisions of "Optical remote sensing"

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{{Definition|title=Passive optical remote sensing
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This article provides an introduction of optical [[remote sensing]] techniques. This technique can be used to detect all kind of in-water properties. This article describes the general principles of optical remote sensing, the way data can be processed and the restrictions with respect to the application of optical remote sensing.  
|definition= ''Passive optical sensors detect natural energy (radiation) that is emitted or reflected by the object or scene being observed. Reflected sunlight is the source of radiation measured by passive optical sensors.''
 
<ref> WIKIPEDIA (From Wikipedia, the free encyclopedia) </ref> [http://en.wikipedia.org/wiki/Remote_sensing].
 
}}
 
  
Remote sensing of coastal zones using satellite or airborne sensors became a powerfull monitoring instrument, because large scale and synoptically environmental information are essential for the understanding and management of the system. Optical multi- or hyperspectral sensors enable the detection of in-water properties such as suspended matter, phytoplankton concentrations, benthic surface and vegetation properties and bathymetry in optically shallow water areas (see “Applications”).   
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==Introduction==
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[[Remote sensing]] using satellite and airborne sensors is a powerful, operational tool for monitoring coastal zones. This technology can provide accurate, large-scale, synoptic environmental information essential for understanding and managing marine ecosystems.  
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Optical multi- or hyperspectral sensor data allows the assessment of in-water properties, such as suspended matter or phytoplankton concentration, benthic substrate type, vegetation composition, and [[bathymetry]] in (optically-)shallow waters.   
  
==See also==
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===Principles===
[[Optical remote sensing: habitat mapping, SPM maps, chlorophyll maps, bathymetry]]
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In the broadest sense, remote sensing is the measurement or acquisition of information of an object or phenomenon, by a recording device that is not in physical or intimate contact with the object. In practice, remote sensing is the utilization at a distance (as from aircraft, spacecraft, satellite, or ship) of any device for gathering information about the environment <ref name="multiple">[http://www.wikipedia.org From Wikipedia, the free encyclopaedia]</ref>.
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Passive optical sensors detect natural energy (radiation) that is emitted or reflected by the object or scene being observed. Reflected sunlight is the source of radiation measured by passive optical sensors.
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In marine and aquatic environments, the sunlight spectrum is modified on its way through the atmosphere, the water surface, and the water body. In each of these boundary layers sunlight is absorbed, scattered, and reflected in a specific manner, depending on the wavelength. As a result, the reflected light carries spectral information about the particular composition of these matters.
  
...
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[[Image:Reflection.jpg |thumb|250px|right| Remote sensing process of water bodies (airborne)]]
  
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===Sensors===
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Each sensor has its own technical characteristics in terms of temporal, spatial, spectral, and radiometric resolution. Depending on specific requirements of a project, such as area size, availability or thematic specifications, multi- or hyperspectral detectors on space- or airborne platforms are applied.
  
==Principles==
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The space agencies NASA ([[SeaWiFS]], [[MODIS]]) and ESA ([[MERIS]]) operate the main optical remote sensing satellites currently used for aquatic and coastal remote sensing.
Optical remote sensing using passive satellite or airborne sensors is the spatial resolved detection and utilization of sunlight, which has been transmitted trough the atmosphere and which is reflected from the earth surface or the water body backward to the sensor.  
 
  
<references/>
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==Data processing==
The sunlight spectrum is modified on its way from the sun though the atmosphere, the sea surface and the water body. Matter in atmosphere, water and at the boundary layers is absorbing, scattering and reflecting the light in a very specific way and in dependency on wavelength.  As result, the light is carrying spectral information about the composition of matter.  
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Different [[remote sensing]] data processing methods are available to retrieve thematic information from remote sensing data. With mathematical and statistical methods the spectral information is analysed. Pixels are compared to specific class signatures and assigned depending on the similarity.
  
==Sensors==
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===Physics-based retrieval algorithms===
Multi- or hyperspectral satellite- or airborne sensors are detecting this spectral information with a distinct accuracy in terms of temporal, spatial, spectral and radiometric resolution that is different and characteristic for each sensor.  
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Physics-based retrieval algorithms model the complex light interactions with the atmosphere and the water body based on physical principles. Once set up, these optical models do not require manual adaptation in order to generate map products and are often independent of ground truth measurements. These algorithms are very flexible and may be applied world wide and are very under all conditions covered by the optical models upon which they are based.
  
==Data processing==
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===Empirical algorithms===
Different remote sensing data processing methods are evaluating the spectral information in order to retrieve the content information with regard to space and time.  
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Empirical algorithms are powerful analytical tools, which rely on ground truth measurements and are typically not transferable between different aquatic and marine ecosystems.  
  
===Physics based retrieval algorighms===
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===Generic processing systems===
Physics based retrieval algorithms can be applied generally world wide and very flexible under all those conditions covered by the implemented optical models. Once set up, they do not rely on manual adaptations in order to generate products and frequently are completely independent on inputs from ground truth measurements.  
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Generic processing systems cover a wide range of applications and can be applied to new sites, applications, and sensors due to a systematic, modular approach and easy adaptations for sensor- and site-specific properties.
  
=== Empirical algorithms ===
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===Geo-rectification===
Nevertheless, the integration of the sometimes very multi-layered complex natural conditions in the physics based models is not always useful, although the remote sensing imageries clearly reflect effects of demanding properties such as species composition. This frequently is of importance to exploit also the potential of sensors, which are strictly speaking not perfect suitable for the independent detection of a environmental property. Here, also empirical algorithms are powerfull to exploit remote sensing data. But, empirical approaches usually rely on accompanied ground truth measurements and are typically not transferable to different types of aquatic systems.  
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Geo-rectification procedures are applied to remote sensing data in order to assign each spatially-resolved pixel with a geographic coordinate. Accurate, geo-coded maps can be produced and incorporated into Geographical Information System (GIS) software.
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Complex trigonometric principles and procedures for geo-referencing are operational, therefore, sub-pixel accuracies can be achieved given adequate navigation data were available during collection. In practice, the spatial accuracy of operational geo-coded products depends on the accuracy of the satellite or airborne platform‘s navigation system. Therefore, for high-precision tasks, many satellite or airborne images have to be refined using manual geo-rectification approaches or automatic matching algorithms.
  
=== Generic processing systems ===
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==Restrictions==
Generic processing systems cover a wide range of applications and frequently can be applied to new sites, applications and sensors due to a systematic modular approach and easy adaptations for sensor and site specific properties.
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Restrictions occur whenever the object-specific signals are masked or interfered with in any ambiguous manner, with regards to both the sensor resolution and retrieval methods. Therefore only few general restrictions can be identified and most restrictions can only be determined with site-specific observations, sensors used, or algorithms applied.  
  
=== Geo-rectification ===
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===General restrictions===  
Geo-rectification procedures for imaging data are applied in order to connect the spatial resolved pixel values with geographical coordinates and to deliver geo-coded maps, which can be implemented into Geographical Information Systems GIS.
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Examples of general restrictions are clouds masking optical signals reflected from the earth surface or direct reflections from the water surface  resulting in intense contributions to the recorded signal [[sun glitter]].
The trigonometric principles and procedures for operational geo-referencing are essentially developed and operational so far. Therefore, sub-pixel accuracies can be achieved for the condition that sufficient navigation data are available. However, in practice the attainable spatial accuracy of operational geo-coded products depends on the accuracy of the satellites or airborne navigation or metadata. Therefore, for high-precision tasks many satellite or airborne imageries have to be spatially refined using manual geo-rectification approaches or automatic matching algorithms.  
 
  
==Resctrictions==
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===Case-dependent restrictions===
Restrictions apply, wherever the object specific signals are masked by others or interfered in ambiguous way with regard to both the sensor resolution and the retrieval methods. Therefore, only few restrictions can be stated in general, but many restrictions can be determined only with regard to the specific site to be observed, the sensors used and algorithms applied.  
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Examples of case-dependent restrictions are:
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# Intermediate [[sun glitter]] sun glitter effects can be corrected only if the radiometric and spectral resolution of the sensor is adequate and the processing approach supports respective correction procedures (> example).  
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# The spatial resolution of the [[sensor]] must be higher than the spatial heterogeneity of the target areas to be mapped. Sub-pixel classification of surfaces is only possible for a very restricted number of spectral end members. At the very least, every contribution of members not implemented into the model will create inaccuracies.
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# The spectral behaviour of optical classes must differ significantly from each other with respect to the sensor’s spectral resolution. E.g. Chlorophyll and dissolved organic matter (Gelbstoff) cannot be estimated independently if the sensor’s spectral and radiometric resolution is insufficient and/or the ecosystem specific absorption spectra are too similar for an independent, quantitative estimate.
  
===Examples for general restrictions===  
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==See also==
General restrictions are the masking of clouds for optical signals reflected from the earth surface or geometric recording conditions that effect strong sun glitter
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* [[Optical measurements in coastal waters]]
<ref> Sun glitter is defined as (spatial usually very variable) contribution of direct sunlight, that is reflected at the water surface and increasing substantially the intensity of radiance measured at the sensor. It appears at specific geometric recording conditions between sun, the water surface and the sensor and is affecting approximate 30-70% of all earth observation imageries. </ref>
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* [[HyMap: Hyperspectral seafloor mapping and direct bathymetry calculation in littoral zones]]
contributions to the signal from the water surface.
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* [[Light fields and optics in coastal waters]]
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* [[Optical backscatter point sensor (OBS)]]
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* [[General principles of optical and acoustical instruments]]
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* [[Optical Laser diffraction instruments (LISST)]]
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* [[Use of Lidar for coastal habitat mapping]]
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* [[data processing and output of Lidar]]
  
===Examples of case dependent restrictions===
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==Notes and references==
a) Intermediate sun glitter conditions can be treated with only if the radiometric, spectral (and in dependency on the algorithm also spatial) resolution of the sensor is sufficient and the processing approach supports such a correction or consideration of this effect (> example).
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<references/>
  
b) The spatial resolution of the sensor in most cases must better than the spatial heterogeneity of the target areas to be mapped. Subpixel classification of surfaces is only possible for a very restricted number of spectral endmembers. At least, every contribution of members not implemented into the model will create errors.
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----
  
c) The spectral behaviour of optical classes must significant differ to each other with respect to the spectral resolution of the sensor. E.g. Chlorophyll and Gelbstoff can not be estimated independently, if the sensor spectral and radiometrical resolution is unsufficient and/or the aquatic system specific absorption spectra are to simular for an independend quantitative estimation.
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{{author
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|AuthorID=12962
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|AuthorFullName=Thomas Heege
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|AuthorName=Thomas Heege}}
  
==References==
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[[Category:Coastal and marine observation and monitoring]]
<references/>
 

Latest revision as of 12:12, 7 December 2023

This article provides an introduction of optical remote sensing techniques. This technique can be used to detect all kind of in-water properties. This article describes the general principles of optical remote sensing, the way data can be processed and the restrictions with respect to the application of optical remote sensing.

Introduction

Remote sensing using satellite and airborne sensors is a powerful, operational tool for monitoring coastal zones. This technology can provide accurate, large-scale, synoptic environmental information essential for understanding and managing marine ecosystems. Optical multi- or hyperspectral sensor data allows the assessment of in-water properties, such as suspended matter or phytoplankton concentration, benthic substrate type, vegetation composition, and bathymetry in (optically-)shallow waters.

Principles

In the broadest sense, remote sensing is the measurement or acquisition of information of an object or phenomenon, by a recording device that is not in physical or intimate contact with the object. In practice, remote sensing is the utilization at a distance (as from aircraft, spacecraft, satellite, or ship) of any device for gathering information about the environment [1]. Passive optical sensors detect natural energy (radiation) that is emitted or reflected by the object or scene being observed. Reflected sunlight is the source of radiation measured by passive optical sensors.

In marine and aquatic environments, the sunlight spectrum is modified on its way through the atmosphere, the water surface, and the water body. In each of these boundary layers sunlight is absorbed, scattered, and reflected in a specific manner, depending on the wavelength. As a result, the reflected light carries spectral information about the particular composition of these matters.

Remote sensing process of water bodies (airborne)

Sensors

Each sensor has its own technical characteristics in terms of temporal, spatial, spectral, and radiometric resolution. Depending on specific requirements of a project, such as area size, availability or thematic specifications, multi- or hyperspectral detectors on space- or airborne platforms are applied.

The space agencies NASA (SeaWiFS, MODIS) and ESA (MERIS) operate the main optical remote sensing satellites currently used for aquatic and coastal remote sensing.

Data processing

Different remote sensing data processing methods are available to retrieve thematic information from remote sensing data. With mathematical and statistical methods the spectral information is analysed. Pixels are compared to specific class signatures and assigned depending on the similarity.

Physics-based retrieval algorithms

Physics-based retrieval algorithms model the complex light interactions with the atmosphere and the water body based on physical principles. Once set up, these optical models do not require manual adaptation in order to generate map products and are often independent of ground truth measurements. These algorithms are very flexible and may be applied world wide and are very under all conditions covered by the optical models upon which they are based.

Empirical algorithms

Empirical algorithms are powerful analytical tools, which rely on ground truth measurements and are typically not transferable between different aquatic and marine ecosystems.

Generic processing systems

Generic processing systems cover a wide range of applications and can be applied to new sites, applications, and sensors due to a systematic, modular approach and easy adaptations for sensor- and site-specific properties.

Geo-rectification

Geo-rectification procedures are applied to remote sensing data in order to assign each spatially-resolved pixel with a geographic coordinate. Accurate, geo-coded maps can be produced and incorporated into Geographical Information System (GIS) software. Complex trigonometric principles and procedures for geo-referencing are operational, therefore, sub-pixel accuracies can be achieved given adequate navigation data were available during collection. In practice, the spatial accuracy of operational geo-coded products depends on the accuracy of the satellite or airborne platform‘s navigation system. Therefore, for high-precision tasks, many satellite or airborne images have to be refined using manual geo-rectification approaches or automatic matching algorithms.

Restrictions

Restrictions occur whenever the object-specific signals are masked or interfered with in any ambiguous manner, with regards to both the sensor resolution and retrieval methods. Therefore only few general restrictions can be identified and most restrictions can only be determined with site-specific observations, sensors used, or algorithms applied.

General restrictions

Examples of general restrictions are clouds masking optical signals reflected from the earth surface or direct reflections from the water surface resulting in intense contributions to the recorded signal sun glitter.

Case-dependent restrictions

Examples of case-dependent restrictions are:

  1. Intermediate sun glitter sun glitter effects can be corrected only if the radiometric and spectral resolution of the sensor is adequate and the processing approach supports respective correction procedures (> example).
  2. The spatial resolution of the sensor must be higher than the spatial heterogeneity of the target areas to be mapped. Sub-pixel classification of surfaces is only possible for a very restricted number of spectral end members. At the very least, every contribution of members not implemented into the model will create inaccuracies.
  3. The spectral behaviour of optical classes must differ significantly from each other with respect to the sensor’s spectral resolution. E.g. Chlorophyll and dissolved organic matter (Gelbstoff) cannot be estimated independently if the sensor’s spectral and radiometric resolution is insufficient and/or the ecosystem specific absorption spectra are too similar for an independent, quantitative estimate.

See also

Notes and references


The main author of this article is Thomas Heege
Please note that others may also have edited the contents of this article.

Citation: Thomas Heege (2023): Optical remote sensing. Available from http://www.coastalwiki.org/wiki/Optical_remote_sensing [accessed on 23-11-2024]