Ground control point GCP - Revision history

Designing Buildings at 07:56, 30 November 2021

2021-11-30T07:56:54Z

Editor at 21:59, 29 November 2021

2021-11-29T21:59:59Z

← Older revision		Revision as of 21:59, 29 November 2021
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	* Post processed kinematic PPK.		* Post processed kinematic PPK.
	* Real time kinematic RTK.		* Real time kinematic RTK.
		+	* Universal transverse mercator projection.
	* Uses of drones in construction.		* Uses of drones in construction.

	[[Category:DCN_Product_Knowledge]] [[Category:Construction_techniques]] [[Category:Products_/_components]]		[[Category:DCN_Product_Knowledge]] [[Category:Construction_techniques]] [[Category:Products_/_components]]

Editor at 21:35, 29 November 2021

2021-11-29T21:35:31Z

← Older revision		Revision as of 21:35, 29 November 2021
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	* Construction drones.		* Construction drones.
	* Global positioning systems and global navigation satellite systems.		* Global positioning systems and global navigation satellite systems.
		+	* Ground sample distance GSD.
	* Interview with Elly Ball, co-founder Get Kids into Survey.		* Interview with Elly Ball, co-founder Get Kids into Survey.
	* Land surveying.		* Land surveying.

Editor at 20:48, 29 November 2021

2021-11-29T20:48:39Z

← Older revision		Revision as of 20:48, 29 November 2021
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	* Interview with Elly Ball, co-founder Get Kids into Survey.		* Interview with Elly Ball, co-founder Get Kids into Survey.
	* Land surveying.		* Land surveying.
		+	* Laser scanning for building design and construction.
	* Post processed kinematic PPK.		* Post processed kinematic PPK.
	* Real time kinematic RTK.		* Real time kinematic RTK.
	* Uses of drones in construction.		* Uses of drones in construction.
−	* Using satellite imagery to monitor movements in megaprojects.

	[[Category:DCN_Product_Knowledge]] [[Category:Construction_techniques]] [[Category:Products_/_components]]		[[Category:DCN_Product_Knowledge]] [[Category:Construction_techniques]] [[Category:Products_/_components]]

Editor at 20:46, 29 November 2021

2021-11-29T20:46:19Z

← Older revision		Revision as of 20:46, 29 November 2021
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−	[[File:DroneOverheadImage.jpg]]	+	[[File:DroneOverheadImage.jpg\|link=File:DroneOverheadImage.jpg]]

−	Introduction	+	= Introduction =

	A ground control point (GCP) is a place or object with a known geographic location (or GPS coordinate) that can be used as a reference point to deliver a precise aerial map for surveying purposes. GCPs are built on the principle of recording the position of an object by calculating the distance and angles between strategically selected points. GPCs can make it possible to map large areas in aerial mapping surveys.		A ground control point (GCP) is a place or object with a known geographic location (or GPS coordinate) that can be used as a reference point to deliver a precise aerial map for surveying purposes. GCPs are built on the principle of recording the position of an object by calculating the distance and angles between strategically selected points. GPCs can make it possible to map large areas in aerial mapping surveys.

−	Parameters for GCPs	+	= Parameters for GCPs =

	GPCs can be photo identifiable objects (such as a manhole cover) or a marked black and white symbol (such as the figure “X” painted on the ground or a small section of a checkerboard). Traditional surveying methods or existing maps can be used to locate the points, but other approaches - such as using LiDAR or Google Earth - can also be applied.		GPCs can be photo identifiable objects (such as a manhole cover) or a marked black and white symbol (such as the figure “X” painted on the ground or a small section of a checkerboard). Traditional surveying methods or existing maps can be used to locate the points, but other approaches - such as using LiDAR or Google Earth - can also be applied.
Line 11:		Line 11:
	From an aerial photography perspective, GCPs are a traditional method of defining a location. High contrast colours can be used to make GCPs stand out on drone maps. They should also have centrepoints that are clearly defined.		From an aerial photography perspective, GCPs are a traditional method of defining a location. High contrast colours can be used to make GCPs stand out on drone maps. They should also have centrepoints that are clearly defined.

−	There are ~~several~~ other parameters for creating GCPs, including:	+	There are other parameters for creating GCPs, including spatial reference systems. These systems are used to relay positions in GCPs by defining several parameters, including:

−	~~Spatial~~ reference ~~systems are~~ used ~~to relay~~ positions ~~in GCPs~~. ~~These systems define several parameters~~, ~~including:~~	+	* Reference ellipsoid. This is the geometric surface that represents the approximate shape of the Earth.
		+	* Reference datum. This is the reference point that is used as the basis for the measurement of all positions.
		+	* Geoid model. This representation of the Earth’s surface uses mean sea level as the reference point of measurement. This method provides a more accurate and detailed model of the Earth.
		+	* Unit of measurement. This data should be clearly stated - degrees (in latitude and longitude, metres or feet) in relation to how the GCP will be measured in relation to the reference datum.
		+	* Map projection. The method of converting the map from a 3D ellipsoid into a flat plane applies a formula referred to as coordinate transformation.

−	~~Reference ellipsoid. This is the geometric surface that represents the approximate shape of the Earth.~~	+	= Advances in drone surveillance =
−		+
−	~~Reference datum. This is the reference point that is used as the basis for the measurement of all positions.~~	+
−		+
−	~~Geoid model. This representation of the Earth’s surface uses mean sea level as the reference point of measurement. This method provides a more accurate and detailed model of the Earth.~~	+
−		+
−	~~Unit of measurement. This data should be clearly stated - degrees (in latitude and longitude, metres or feet) in relation to how the GCP will be measured in relation to the reference datum.~~	+
−		+
−	~~Map projection. The method of converting the map from a 3D ellipsoid into a flat plane applies a formula referred to as coordinate transformation.~~	+
−		+
−	Advances in drone surveillance	+

	While GCPs have been a tested method of aerial mapping, there are some inefficiencies associated with the method. With GCPs, there can be logistical challenges when obtaining authorisation for access. In some cases, it may not be possible to gain physical access to the area once permission has been granted, due to dangerous terrain or hazardous or remote locations.		While GCPs have been a tested method of aerial mapping, there are some inefficiencies associated with the method. With GCPs, there can be logistical challenges when obtaining authorisation for access. In some cases, it may not be possible to gain physical access to the area once permission has been granted, due to dangerous terrain or hazardous or remote locations.
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	The most commonly used options are real time kinematic (RTK) and post processed kinematic (PPK). RTK makes real time corrections to images captured by GPS while PTK corrects location data after it has been collected and uploaded. In some instances, it can be helpful to use GCPs to enhance information gathered by RTK or PPK enabled technologies, particularly in instances where it is important to capture certain types of precise data regarding accuracy of scale, orientation and so on.		The most commonly used options are real time kinematic (RTK) and post processed kinematic (PPK). RTK makes real time corrections to images captured by GPS while PTK corrects location data after it has been collected and uploaded. In some instances, it can be helpful to use GCPs to enhance information gathered by RTK or PPK enabled technologies, particularly in instances where it is important to capture certain types of precise data regarding accuracy of scale, orientation and so on.

−	~~USGS~~, ~~https://www~~.~~usgs~~.~~gov~~/~~core-science-systems/nli/landsat/ground-control-points?qt-science_support_page_related_con=0#qt-science_support_page_related_con~~	+	= Related articles on Designing Buildings =
		+
		+	* Construction drones.
		+	* Global positioning systems and global navigation satellite systems.
		+	* Interview with Elly Ball, co-founder Get Kids into Survey.
		+	* Land surveying.
		+	* Post processed kinematic PPK.
		+	* Real time kinematic RTK.
		+	* Uses of drones in construction.
		+	* Using satellite imagery to monitor movements in megaprojects.
		+
		+	[[Category:DCN_Product_Knowledge]] [[Category:Construction_techniques]] [[Category:Products_/_components]]

Editor: Created page with "File:DroneOverheadImage.jpg Introduction A ground control point (GCP) is a place or object with a known geographic location (or GPS coordinate) that can be used as a refere..."

2021-11-29T19:19:25Z

Created page with "File:DroneOverheadImage.jpg Introduction A ground control point (GCP) is a place or object with a known geographic location (or GPS coordinate) that can be used as a refere..."

New page

[[File:DroneOverheadImage.jpg]]

Introduction

A ground control point (GCP) is a place or object with a known geographic location (or GPS coordinate) that can be used as a reference point to deliver a precise aerial map for surveying purposes. GCPs are built on the principle of recording the position of an object by calculating the distance and angles between strategically selected points. GPCs can make it possible to map large areas in aerial mapping surveys.

Parameters for GCPs

GPCs can be photo identifiable objects (such as a manhole cover) or a marked black and white symbol (such as the figure “X” painted on the ground or a small section of a checkerboard). Traditional surveying methods or existing maps can be used to locate the points, but other approaches - such as using LiDAR or Google Earth - can also be applied.

From an aerial photography perspective, GCPs are a traditional method of defining a location. High contrast colours can be used to make GCPs stand out on drone maps. They should also have centrepoints that are clearly defined.

There are several other parameters for creating GCPs, including:

Spatial reference systems are used to relay positions in GCPs. These systems define several parameters, including:

Reference ellipsoid. This is the geometric surface that represents the approximate shape of the Earth.

Reference datum. This is the reference point that is used as the basis for the measurement of all positions.

Geoid model. This representation of the Earth’s surface uses mean sea level as the reference point of measurement. This method provides a more accurate and detailed model of the Earth.

Unit of measurement. This data should be clearly stated - degrees (in latitude and longitude, metres or feet) in relation to how the GCP will be measured in relation to the reference datum.

Map projection. The method of converting the map from a 3D ellipsoid into a flat plane applies a formula referred to as coordinate transformation.

Advances in drone surveillance

While GCPs have been a tested method of aerial mapping, there are some inefficiencies associated with the method. With GCPs, there can be logistical challenges when obtaining authorisation for access. In some cases, it may not be possible to gain physical access to the area once permission has been granted, due to dangerous terrain or hazardous or remote locations.

Another significant issue with GCPs is with set up, which can involve a significant amount of time, labour and equipment. There are several types of equipment that use differential correction technology to provide better data location information; this essentially removes the need for GCP set up.

The most commonly used options are real time kinematic (RTK) and post processed kinematic (PPK). RTK makes real time corrections to images captured by GPS while PTK corrects location data after it has been collected and uploaded. In some instances, it can be helpful to use GCPs to enhance information gathered by RTK or PPK enabled technologies, particularly in instances where it is important to capture certain types of precise data regarding accuracy of scale, orientation and so on.

USGS, https://www.usgs.gov/core-science-systems/nli/landsat/ground-control-points?qt-science_support_page_related_con=0#qt-science_support_page_related_con

← Older revision		Revision as of 07:56, 30 November 2021
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	= Parameters for GCPs =		= Parameters for GCPs =

−	GPCs can be photo identifiable objects (such as a manhole cover) or a marked black and white symbol (such as the figure “X” painted on the ground or a small section of a checkerboard). Traditional surveying methods or existing maps can be used to locate the points, but other approaches - such as ~~using~~ LiDAR or Google Earth - can also be ~~applied~~.	+	GPCs can be photo identifiable objects (such as a manhole cover) or a marked black and white symbol (such as the figure “X” painted on the ground or a small section of a checkerboard). Traditional surveying methods or existing maps can be used to locate the points, but other approaches - such as LiDAR or Google Earth - can also be used.

−	From an aerial photography perspective, GCPs are a traditional method of defining a location. High contrast colours can be used to make GCPs stand out on drone maps. They should ~~also~~ have centrepoints that are clearly defined.	+	From an aerial photography perspective, GCPs are a traditional method of defining a location. High contrast colours can be used to make GCPs stand out on drone maps. They should have centrepoints that are clearly defined.

	There are other parameters for creating GCPs, including spatial reference systems. These systems are used to relay positions in GCPs by defining several parameters, including:		There are other parameters for creating GCPs, including spatial reference systems. These systems are used to relay positions in GCPs by defining several parameters, including:
Line 15:		Line 15:
	* Reference ellipsoid. This is the geometric surface that represents the approximate shape of the Earth.		* Reference ellipsoid. This is the geometric surface that represents the approximate shape of the Earth.
	* Reference datum. This is the reference point that is used as the basis for the measurement of all positions.		* Reference datum. This is the reference point that is used as the basis for the measurement of all positions.
−	* Geoid model. This representation of the Earth’s surface uses mean sea level as the reference point of measurement~~. This method provides a more accurate and detailed model of the Earth~~.	+	* Geoid model. This representation of the Earth’s surface uses mean sea level as the reference point of measurement.
	* Unit of measurement. This data should be clearly stated - degrees (in latitude and longitude, metres or feet) in relation to how the GCP will be measured in relation to the reference datum.		* Unit of measurement. This data should be clearly stated - degrees (in latitude and longitude, metres or feet) in relation to how the GCP will be measured in relation to the reference datum.
	* Map projection. The method of converting the map from a 3D ellipsoid into a flat plane applies a formula referred to as coordinate transformation.		* Map projection. The method of converting the map from a 3D ellipsoid into a flat plane applies a formula referred to as coordinate transformation.
Line 21:		Line 21:
	= Advances in drone surveillance =		= Advances in drone surveillance =

−	While GCPs have been a tested method of aerial mapping, there are some inefficiencies associated with the method. ~~With GCPs, there~~ can be logistical challenges when obtaining authorisation for access. In some cases, it may not be possible to gain physical access to the area once permission has been granted, due to dangerous terrain or hazardous or remote locations.	+	While GCPs have been a tested method of aerial mapping, there are some inefficiencies associated with the method. There can be logistical challenges when obtaining authorisation for access. In some cases, it may not be possible to gain physical access to the area, even once permission has been granted, due to dangerous terrain or hazardous or remote locations.

−	~~Another significant issue with GCPs is with~~ set up~~, which~~ can involve a significant amount of time, labour and equipment~~. There are several types of equipment that use differential correction technology to provide better data location information; this essentially removes the need for GCP set up~~.	+	In addition, set up can involve a significant amount of time, labour and equipment.

−	The most commonly used options are real time kinematic (RTK) and post processed kinematic (PPK). RTK makes real time corrections to images captured by GPS while PTK corrects location data after it has been collected and uploaded. In some instances, it can be helpful to use GCPs to enhance information gathered by RTK or PPK enabled technologies, particularly in instances where it is important to capture certain types of precise data regarding accuracy of scale, orientation and so on.	+	There are several types of equipment that use differential correction technology to provide better data location information; this essentially removes the need for GCP set up. The most commonly used options are real time kinematic (RTK) and post processed kinematic (PPK). RTK makes real time corrections to images captured by GPS while PTK corrects location data after it has been collected and uploaded. In some instances, it can be helpful to use GCPs to enhance information gathered by RTK or PPK enabled technologies, particularly in instances where it is important to capture certain types of precise data regarding accuracy of scale, orientation and so on.

	= Related articles on Designing Buildings =		= Related articles on Designing Buildings =