Parents (Total: 49)

The searched file hash is included in 49 parent files which include package known and seen by metalookup. A sample is included below:

Key	Value
FileSize	810556
MD5	ABD50876B56AE60D90B7590BEDE7DA7C
PackageDescription	satellite constellation visualisation SaVi allows you to simulate satellite orbits and coverage, in two and three dimensions. SaVi is particularly useful for simulating satellite constellations such as Iridium and Globalstar. . SaVi can use Geomview, an optional but useful package, for 3D rendering.
PackageMaintainer	Debian GIS Project <pkg-grass-devel@lists.alioth.debian.org>
PackageName	savi
PackageSection	science
PackageVersion	1.5.1-4
SHA-1	0E411E840C61C5273483B52E7CF4728325ABA0BC
SHA-256	A512851B97B278F2113B645EFE93E7EA984E805A109CFC8BE09F0975CC854F94

Key	Value
FileSize	941316
MD5	4A1C07E8B0319374B7D1054B70B6415C
PackageDescription	Python3 tools for geographic data GeoPandas is a project to add support for geographic data to pandas objects. It currently implements `GeoSeries` and `GeoDataFrame` types which are subclasses of `pandas.Series` and `pandas.DataFrame` respectively. GeoPandas objects can act on shapely geometry objects and perform geometric operations. . GeoPandas geometry operations are cartesian. The coordinate reference system (crs) can be stored as an attribute on an object, and is automatically set when loading from a file. Objects may be transformed to new coordinate systems with the `to_crs()` method. There is currently no enforcement of like coordinates for operations, but that may change in the future. . This package contains the Python 3 version of the library.
PackageMaintainer	Debian GIS Project <pkg-grass-devel@lists.alioth.debian.org>
PackageName	python3-geopandas
PackageSection	python
PackageVersion	0.10.1-1
SHA-1	12B4CC253A95189FF87112C77AF5298B3F31612E
SHA-256	CCE0286FEC43A4E20708D9747104B2091A657807E9AB5F6C17DDD8FD4EB8DF75

Key	Value
FileSize	21852420
MD5	04071A87BA606F599E688E0C4844B234
PackageDescription	Digital Chart of the World (DCW) for GMT DCW-GMT is an enhancement to the original 1:1,000,000 scale vector basemap of the world available from the Princeton University Digital Map and Geospatial Information Center and from GeoCommunity at http://data.geocomm.com/readme/dcw/dcw.html. This data is for use by GMT, the Generic Mapping Tools.
PackageMaintainer	Debian GIS Project <pkg-grass-devel@lists.alioth.debian.org>
PackageName	gmt-dcw
PackageSection	science
PackageVersion	2.0.1-1
SHA-1	1D641CDD50A46FC20A4E1BEB9B6D6B26F78D95E7
SHA-256	4BF18C04AD68C554FC58113E239D0A1C39BFF692721BC0F104631182A3E61281

Key	Value
FileSize	8251652
MD5	DA9DD9C5851EB24E0AD4A9BE529B4FAA
PackageDescription	cartographic library for Python (package data) Cartopy is a Python package designed to make drawing maps for data analysis and visualisation easy. . It features: . - object oriented projection definitions - point, line, polygon and image transformations between projections - integration to expose advanced mapping in matplotlib with a simple and intuitive interface - powerful vector data handling by integrating shapefile reading with Shapely capabilities . This package provides common data files necessary to the library.
PackageMaintainer	Ubuntu Developers <ubuntu-devel-discuss@lists.ubuntu.com>
PackageName	python-cartopy-data
PackageSection	python
PackageVersion	0.18.0+dfsg-2build1
SHA-1	1D7F917CBE9726D271783F3B8ED056D4B7CF24BB
SHA-256	3A1CD1DD67CF34243E311FB812B8FAFA814DB6523CBB91DBA30082EF0E8419EE

Key	Value
FileSize	3222604
MD5	C878AB03456EDFD4DCB99144D3BC0FDD
PackageDescription	GRASS GIS graphical user interfaces Commonly referred to as GRASS, this is a Geographic Information System (GIS) used for geospatial data management and analysis, image processing, graphics/map production, spatial modeling, and visualization. GRASS is currently used in academic and commercial settings around the world, as well as by many government agencies and environmental consulting companies. . This package contains the GRASS GUIs.
PackageMaintainer	Debian GIS Project <pkg-grass-devel@lists.alioth.debian.org>
PackageName	grass-gui
PackageSection	science
PackageVersion	7.8.6~rc3-1~exp1
SHA-1	266823F18A795C64B72CA97ACCC899502D9A0173
SHA-256	BDE579419F909C6C3EEC7EB896108A528DC269DD5076ED9E32ACBDED4C02E40A

Key	Value
FileSize	3222616
MD5	DF2BCF3EA900039348571C25E78241FF
PackageDescription	GRASS GIS graphical user interfaces Commonly referred to as GRASS, this is a Geographic Information System (GIS) used for geospatial data management and analysis, image processing, graphics/map production, spatial modeling, and visualization. GRASS is currently used in academic and commercial settings around the world, as well as by many government agencies and environmental consulting companies. . This package contains the GRASS GUIs.
PackageMaintainer	Debian GIS Project <pkg-grass-devel@lists.alioth.debian.org>
PackageName	grass-gui
PackageSection	science
PackageVersion	7.8.6~rc3-1~exp1
SHA-1	37FFF04FAABE53F9FF0B5450189722D3BC2B3C06
SHA-256	006C45C6931DEC44CD0B4EAF9D55ABEEFD6B8605B329816432604E484773596B

Key	Value
FileSize	3222964
MD5	C64385FC49C7D4EE7FFD64840FD0923E
PackageDescription	GRASS GIS graphical user interfaces Commonly referred to as GRASS, this is a Geographic Information System (GIS) used for geospatial data management and analysis, image processing, graphics/map production, spatial modeling, and visualization. GRASS is currently used in academic and commercial settings around the world, as well as by many government agencies and environmental consulting companies. . This package contains the GRASS GUIs.
PackageMaintainer	Debian GIS Project <pkg-grass-devel@lists.alioth.debian.org>
PackageName	grass-gui
PackageSection	science
PackageVersion	7.8.6-1
SHA-1	3816088910BEDDE47238B9A98F67E6AD19B591DB
SHA-256	173B64F621BFC817790EE335AB1F02B279383A070744835B42CA07AD448E9742

Key	Value
FileSize	5023628
MD5	7BFDCA4C3A1645C30C1650904B0E7234
PackageDescription	RDNAP grid correction files for PROJ Kadaster and Rijkswaterstaat CIV, working together under the name RDNAP, developed RDNAPTRANS™2008, the precise and official transformation between ETRS89 and the dutch national horizontal and vertical coordinate reference systems the Stelsel van de Rijksdriehoeksmeting (RD) and the Normaal Amsterdams Peil (NAP). A ‘simplified’ procedure has been developed which uses a NTv2-grid for the transformation between ETRS89 and RD as well as a VDatum-grid for the transformation between ETRS89 and NAP. This ‘simplified’ procedure has the following limitations: . 1) The rdtrans2008 NTv2-grid can only give identical results to RDNAPTRANS™2008 within 1 millimeter at ground level onshore and at mean sea level offshore. The horizontal deviation is approximately 1 millimeter per 50 meter height difference from ground level or mean sea level. 2) An exception to 1) is the border of the RDNAPTRANS™2008 correction grid. Transformation results within cells of the rdtrans2008 NTv2-grid that are intersected by the border of the RDNAPTRANS™2008 correction grid can result in deviations of up to 20 centimeter. 3) The naptrans2008 VDatum-grid cannot be used to determine deflections of the vertical. For this the NLGEO2004 geoid model has to be used. 4) The naptrans2008 VDatum-grid is referenced to the Bessel-1841 ellipsoid and cannot be used stand-alone, it has to be used in combination with the rdtrans2008 NTv2-grid. . Taking into account the limitations listed above, the rdtrans2008 NTv2-grid and naptrans2008 VDatum-grid can be used as an alternative to RDNAPTRANS™2008 to transform geographic ETRS89-coordinates to projected RD-coordinates with grid correction applied and NAP-heights. . Note that, although the resulting RD/NAP and ETRS89 coordinates from the transformation will be correct, geographic Bessel-1841 coordinates will differ in both procedures and should only be considered as an intermediate result. . RDNAPTRANS™2018 contains a new datum transformation based on the updated ETRS89 coordinates of realisation ETRF2000(R14). Next to this, a new and slightly more precise quasi-geoid grid model is used. This NLGEO2018 quasi-geoid model covers a larger area including a large part of the North Sea. A change with big impact is the use of a new data format of the grid files and a corresponding transformation procedure that changes the order of the steps of the transformation and uses a fixed height in the datum transformation. As a result, the transformation is now possible conform a de facto standard by including the datum transformation in the correction grid (variant 2). This allows straightforward implementation in software like GIS packages and can resolve current problems due to incorrect implementations of the transformation. . Within the administrative borders of the Netherlands, the differences in the resulting horizontal coordinates due to the changes from version 2008 to 2018 of RDNAPTRANS™ are at maximum 0.010 m at sea level (zero NAP height), and at maximum an additional 0.001 m per 50 m height above or below zero NAP height. The maximum change in the transformed height coordinates due to the slightly more precise new quasi-geoid grid model is about 0.025 m. The new correction grid has a different sampling in ellipsoidal coordinates. With this resampling, discontinuities in the correction grid are smoothed, especially outside the administrative borders of the Netherlands, to allow bilinear interpolation. As a result, changes in the resulting horizontal coordinates up to 0.05 m occur occasionally in Belgium, Germany and the Dutch EEZ. To use the same bounding box around the Netherlands including the Dutch EEZ of the North Sea of the quasi-geoid grid model for the correction grid, the correction grid has been faded out to zero correction for a seamless land-sea transition. This introduces latitude and longitude corrections up to 0.25 m in areas outside the former validity area of RDNAPTRANS™ where no corrections were defined before. . There are two variants for the implementation of RDNAPTRANS™2018. Implementation variant 1 applies the datum transformation as a separate step using a 3D similarity transformation. Implementation variant 2 includes the datum transformation in the correction grid and a different quasi-geoid grid for the height transformation is used. The advantage of implementation variant 1 is that it has no strict bounds for the area where horizontal coordinates can be transformed correctly. The disadvantage is that many software packages do not support implementation variant 1. Implementation variant 2 is supported by more software but can only be used within the bounds of the correction grid. The difference in the resulting coordinates between the two variants is well below 0.0010 m within the bounds of the RDNAPTRANS™2008 grids. Although transformation at sea and even outside the grid bounds is possible, the scale factor of the map projection increases rapidly and also the precision of transformation back and forth deteriorates. There are bounds to the recommended use of RD and NAP at sea and outside the Netherlands.
PackageMaintainer	Debian GIS Project <pkg-grass-devel@lists.alioth.debian.org>
PackageName	proj-rdnap
PackageSection	non-free/science
PackageVersion	2008+2018-5
SHA-1	46F29A488B07F3D695A1FFF83BA45C0EB4497BF9
SHA-256	0EED8AE376E8BFFFCC9E562312702FDD4F8A755F419FC9A619FA4BA5D38015EE

Key	Value
FileSize	941416
MD5	70D94E84D8765EE06113EF0F82D3A50B
PackageDescription	Python3 tools for geographic data GeoPandas is a project to add support for geographic data to pandas objects. It currently implements `GeoSeries` and `GeoDataFrame` types which are subclasses of `pandas.Series` and `pandas.DataFrame` respectively. GeoPandas objects can act on shapely geometry objects and perform geometric operations. . GeoPandas geometry operations are cartesian. The coordinate reference system (crs) can be stored as an attribute on an object, and is automatically set when loading from a file. Objects may be transformed to new coordinate systems with the `to_crs()` method. There is currently no enforcement of like coordinates for operations, but that may change in the future. . This package contains the Python 3 version of the library.
PackageMaintainer	Debian GIS Project <pkg-grass-devel@lists.alioth.debian.org>
PackageName	python3-geopandas
PackageSection	python
PackageVersion	0.10.2-1
SHA-1	5496B12E11B3E14624F82F68CAD20D88AD708CC0
SHA-256	DC5EB79D9690E56660036C2D6C1A00BB682607CC491C955FE5244CF57345DAD1

Key	Value
FileSize	808648
MD5	419A62CD7F36E009DCF2C2B3EC99D7C5
PackageDescription	satellite constellation visualisation SaVi allows you to simulate satellite orbits and coverage, in two and three dimensions. SaVi is particularly useful for simulating satellite constellations such as Iridium and Globalstar. . SaVi can use Geomview, an optional but useful package, for 3D rendering.
PackageMaintainer	Debian GIS Project <pkg-grass-devel@lists.alioth.debian.org>
PackageName	savi
PackageSection	science
PackageVersion	1.5.1-4
SHA-1	55D9AD9DED4ADE4221B5AA06B45FD3A6C3DCAF40
SHA-256	EBC125B4972B8C6654DBC94C9050DD8231CD9843E8693339ADC36DD1B3E5B484