Differential Global Positioning System (DGPS)
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Some of the [[Global_Positioning_System_(GPS)#Accuracy of GPS positioning|interference factors]] cannot be definitely quantified (e.g. the current state of the [[atmosphere]] and it's influence on the signal runtime). | Some of the [[Global_Positioning_System_(GPS)#Accuracy of GPS positioning|interference factors]] cannot be definitely quantified (e.g. the current state of the [[atmosphere]] and it's influence on the signal runtime). | ||
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+ | Still, these interferences equally effect ''neighboring points''; thus, the relative positioning (the position of the points to each other) is far more precise than the absolute position (in the [[WGS 84]]). Here, “neighboring” means distances to about 100 km. The functional principle of DGPS is to quantify the deviation of the measured position to the actual coordinates on the earth's surface. | ||
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+ | For this reason, a GPS positioning to a point with known absolute coordinates is conducted simultaneously to the current GPS positioning. From the difference of the known (correct) coordinates and those obtained from the measuring to the reference point, the deviation can be calculated and used for the correction of other points. | ||
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+ | The accuracy gained through DGPS depends on the receiver, the applied DGPS method and the distance to the reference station. | ||
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+ | There are three available methods for DGPS measurement: | ||
+ | # Real-time positioning: Fixed positioning of the [[GPS]] receiver on a defined point and registration of the position. Direct radio contact to the [[GPS]] as the two mensurations have to take place simultaneously. | ||
+ | # Use of fixed reference stations (providers are available in many regions and usually with costs) | ||
+ | ## Real-time: reception of the correcting information via radio broadcasting and instant, corrected positioning in the field. | ||
+ | ## Postprocessing: Measuring with [[GPS]], recording of all points with the exact time of measurement. Subsequent correction of all points based on this information, which is recorded by fixed referenced stations. | ||
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+ | An example of a [[GPS]] reference service is [[wikipedia:de:SAPOS|SAPOS]] ('''Sa'''telliten'''pos'''itionierungsdienst der deutschen Landesvermessung (''ger.'' satellite positioning service of the german ordnance survey)) | ||
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+ | The service provides a real-time connection for the most regions, which is broadcasted via the radio broadcasting network for defined frequencies ([[wikipedia:VHF|VHF]] and [[wikipedia:long_wave|long wave]]). The density of the stations account for up to 60 km. Sapos provides different data sets, which may be used for real-time correction or postprocessing, depending on format and transmission. | ||
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==Related articles== | ==Related articles== | ||
* [[Global Positioning System (GPS)]] | * [[Global Positioning System (GPS)]] | ||
* [[Garmin GPS]] | * [[Garmin GPS]] | ||
− | [[Category: | + | |
+ | ==External links== | ||
+ | * [http://www.sapos.de sapos.de] - Satellitenpositionierungsdienst der deutschen Landesvermessung (german) | ||
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+ | [[Category: Survey]] |
Latest revision as of 16:44, 6 June 2011
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This section is still under construction! This article was last modified on 06/6/2011. If you have comments please use the Discussion page or contribute to the article! |
Some of the interference factors cannot be definitely quantified (e.g. the current state of the atmosphere and it's influence on the signal runtime).
Still, these interferences equally effect neighboring points; thus, the relative positioning (the position of the points to each other) is far more precise than the absolute position (in the WGS 84). Here, “neighboring” means distances to about 100 km. The functional principle of DGPS is to quantify the deviation of the measured position to the actual coordinates on the earth's surface.
For this reason, a GPS positioning to a point with known absolute coordinates is conducted simultaneously to the current GPS positioning. From the difference of the known (correct) coordinates and those obtained from the measuring to the reference point, the deviation can be calculated and used for the correction of other points.
The accuracy gained through DGPS depends on the receiver, the applied DGPS method and the distance to the reference station.
There are three available methods for DGPS measurement:
- Real-time positioning: Fixed positioning of the GPS receiver on a defined point and registration of the position. Direct radio contact to the GPS as the two mensurations have to take place simultaneously.
- Use of fixed reference stations (providers are available in many regions and usually with costs)
- Real-time: reception of the correcting information via radio broadcasting and instant, corrected positioning in the field.
- Postprocessing: Measuring with GPS, recording of all points with the exact time of measurement. Subsequent correction of all points based on this information, which is recorded by fixed referenced stations.
An example of a GPS reference service is SAPOS (Satellitenpositionierungsdienst der deutschen Landesvermessung (ger. satellite positioning service of the german ordnance survey))
The service provides a real-time connection for the most regions, which is broadcasted via the radio broadcasting network for defined frequencies (VHF and long wave). The density of the stations account for up to 60 km. Sapos provides different data sets, which may be used for real-time correction or postprocessing, depending on format and transmission.
[edit] Related articles
[edit] External links
- sapos.de - Satellitenpositionierungsdienst der deutschen Landesvermessung (german)