Summary
Geometry
Debian Science geometry packages
This metapackage will install Debian Science packages related to
geometry. You might also be interested in the field::mathematics
debtag and, depending on your focus, in the education-mathematics
metapackage.
Description
For a better overview of the project's availability as a Debian package, each head row has a color code according to this scheme:
If you discover a project which looks like a good candidate for Debian Science
to you, or if you have prepared an unofficial Debian package, please do not hesitate to
send a description of that project to the Debian Science mailing list
Links to other tasks
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Debian Science Geometry packages
Official Debian packages with high relevance
carmetal
dynamic geometry software with highly ergonomic UI
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Versions of package carmetal |
Release | Version | Architectures |
sid | 4.3-2 | all |
trixie | 4.3-2 | all |
bookworm | 3.5.2+dfsg-2 | all |
bullseye | 3.5.2+dfsg-1.2 | all |
buster | 3.5.2+dfsg-1.1 | all |
stretch | 3.5.2+dfsg-1.1 | all |
jessie | 3.5.2+dfsg-1.1 | all |
Debtags of package carmetal: |
role | program |
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License: DFSG free
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Based on the C.a.R. (Compass and Ruler) project, CaRMetal includes
all of its functionalities - or almost. It propose a different approach
from the graphical interface point of view.
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Ruler and compass constructions can be changed by dragging one of the
basic construction points. The construction follows immediately. The
student can check the correctness of the construction and gain new
insight.
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Tracks of points and animated constructions can help to understand
geometric relations. Tracks can be used as new objects to explore.
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With the macros of C.a.R. very complicated constructions become
possible. Macros are also a way to organize the geometric thinking.
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Hiding construction details and using colors make constructions
clearer to read. In C.a.R. lines and circles can also be reduced to the
relevant points.
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Arithmetic computations, numerical solutions, curves and functions
go beyond classical constructions. It is even possible to construct in 3D
using advanced macros.
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Other geometries, hyperbolic or elliptic, can be explored.
- Scripting (javascript based) of figures.
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geogebra-kde
??? missing short description for package geogebra-kde :-(
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Versions of package geogebra-kde |
Release | Version | Architectures |
jessie | 1.0-1 | amd64,armel,armhf,i386 |
stretch | 1.0-1 | amd64,arm64,armel,armhf,i386,mips,mips64el,mipsel,ppc64el,s390x |
Debtags of package geogebra-kde: |
uitoolkit | qt |
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License: DFSG free
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python3-gengeo
??? missing short description for package python3-gengeo :-(
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Versions of package python3-gengeo |
Release | Version | Architectures |
sid | 1.4-6 | amd64,arm64,armel,armhf,i386,mips64el,ppc64el,riscv64,s390x |
trixie | 1.4-6 | amd64,arm64,armel,armhf,i386,mips64el,ppc64el,riscv64,s390x |
bookworm | 1.4-4.1 | amd64,arm64,armel,armhf,i386,mips64el,mipsel,ppc64el,s390x |
bullseye | 1.4-3 | amd64,arm64,armel,armhf,i386,mips64el,mipsel,ppc64el,s390x |
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License: DFSG free
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Official Debian packages with lower relevance
libcgal-dev
??? missing short description for package libcgal-dev :-(
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Versions of package libcgal-dev |
Release | Version | Architectures |
sid | 6.0.1-1 | amd64,arm64,armhf,i386,mips64el,ppc64el,riscv64,s390x |
trixie | 6.0.1-1 | amd64,arm64,armhf,i386,mips64el,ppc64el,riscv64,s390x |
bookworm | 5.5.1-2 | amd64,arm64,armhf,i386,mips64el,mipsel,ppc64el,s390x |
bullseye | 5.2-3 | amd64,arm64,armhf,i386,mips64el,mipsel,ppc64el,s390x |
buster-security | 4.13-1+deb10u1 | amd64,arm64,armhf,i386 |
buster | 4.13-1 | amd64,arm64,armhf,i386 |
stretch-security | 4.9-1+deb9u1 | amd64,arm64,armhf,i386 |
stretch | 4.9-1 | amd64,arm64,armhf,i386,mips,mips64el,mipsel,ppc64el,s390x |
jessie | 4.5-2 | amd64,armhf,i386 |
Debtags of package libcgal-dev: |
devel | library |
role | devel-lib |
uitoolkit | qt |
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License: DFSG free
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libgeometry-primitive-perl
module to represent geometric entities
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Versions of package libgeometry-primitive-perl |
Release | Version | Architectures |
jessie | 0.24-1 | all |
stretch | 0.24-1 | all |
buster | 0.24-2 | all |
bullseye | 0.24-2 | all |
bookworm | 0.24-3 | all |
trixie | 0.24-3 | all |
sid | 0.24-3 | all |
Debtags of package libgeometry-primitive-perl: |
devel | lang:perl, library |
role | shared-lib |
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License: DFSG free
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Geometry::Primitive is a device- and library-agnostic system for representing
geometric entities such as points, lines, and shapes. It provides some simple
objects and many convenience methods you would expect from a simple geometry
library.
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libmath-geometry-voronoi-perl
Perl module to compute Voronoi diagrams from sets of points
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Versions of package libmath-geometry-voronoi-perl |
Release | Version | Architectures |
stretch | 1.3-2 | amd64,arm64,armel,armhf,i386,mips,mips64el,mipsel,ppc64el,s390x |
sid | 1.3-4 | amd64,arm64,armel,armhf,i386,mips64el,ppc64el,riscv64,s390x |
trixie | 1.3-4 | amd64,arm64,armel,armhf,i386,mips64el,ppc64el,riscv64,s390x |
bookworm | 1.3-4 | amd64,arm64,armel,armhf,i386,mips64el,mipsel,ppc64el,s390x |
bullseye | 1.3-3 | amd64,arm64,armel,armhf,i386,mips64el,mipsel,ppc64el,s390x |
buster | 1.3-3 | amd64,arm64,armhf,i386 |
jessie | 1.3-2 | amd64,armel,armhf,i386 |
Debtags of package libmath-geometry-voronoi-perl: |
devel | lang:perl, library |
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License: DFSG free
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Math::Geometry::Voronoi computes Voronoi diagrams from a set of input points.
This module is a wrapper around a C implementation by Steve Fortune, the
inventor of the algorithm used (Fortune's algorithm), that was further
modified by Derek Bradley.
Info on Voronoi diagrams can be found here:
http://en.wikipedia.org/wiki/Voronoi_diagram
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libopengv-dev
Computer vision methods for solving geometric vision problems.
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Versions of package libopengv-dev |
Release | Version | Architectures |
sid | 1.0+1git91f4b1-8 | amd64,arm64,armel,armhf,i386,mips64el,ppc64el,riscv64,s390x |
bookworm | 1.0+1git91f4b1-7 | amd64,arm64,armel,armhf,i386,mips64el,ppc64el,s390x |
trixie | 1.0+1git91f4b1-8 | amd64,arm64,armel,armhf,i386,mips64el,ppc64el,riscv64,s390x |
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License: DFSG free
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Contains absolute-pose, relative-pose, triangulation, and point-cloud alignment
methods for the calibrated case. All problems can be solved with central or
non-central cameras, and embedded into a random sample consensus or nonlinear
optimization context. Matlab and Python interfaces are implemented as well
This package contains the build-time libraries
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octave-geometry
extension of MatGeom functionality in Octave
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Versions of package octave-geometry |
Release | Version | Architectures |
bookworm | 4.0.0-6 | amd64,arm64,armel,armhf,i386,mips64el,mipsel,ppc64el,s390x |
jessie | 1.7.0-2 | amd64,armel,armhf,i386 |
stretch | 2.1.1-1 | all |
trixie | 4.1.0-1 | amd64,arm64,armel,armhf,i386,mips64el,ppc64el,riscv64,s390x |
buster | 3.0.0-9 | amd64,arm64,armhf,i386 |
sid | 4.1.0-1 | amd64,arm64,armel,armhf,i386,mips64el,ppc64el,riscv64,s390x |
bullseye | 4.0.0-2 | amd64,arm64,armel,armhf,i386,mips64el,mipsel,ppc64el,s390x |
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License: DFSG free
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This package extends the MatGeom functions for Octave, a scientific
computing software. It is useful to create, transform, manipulate and
display geometric primitives in 2D. It also contains functions for
performing boolean operations between two polygons and to manipulate files
in SVG and gmsh formats.
This Octave add-on package is part of the Octave-Forge project.
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python3-opengv
Computer vision methods for solving geometric vision problems.
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Versions of package python3-opengv |
Release | Version | Architectures |
trixie | 1.0+1git91f4b1-8 | amd64,arm64,armel,armhf,i386,mips64el,ppc64el,riscv64,s390x |
sid | 1.0+1git91f4b1-8 | amd64,arm64,armel,armhf,i386,mips64el,ppc64el,riscv64,s390x |
bookworm | 1.0+1git91f4b1-7 | amd64,arm64,armel,armhf,i386,mips64el,ppc64el,s390x |
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License: DFSG free
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Contains absolute-pose, relative-pose, triangulation, and point-cloud alignment
methods for the calibrated case. All problems can be solved with central or
non-central cameras, and embedded into a random sample consensus or nonlinear
optimization context. Matlab and Python interfaces are implemented as well
This package contains the Python interface
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rubiks
Small collection of Rubik's cube solvers
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Versions of package rubiks |
Release | Version | Architectures |
stretch | 20070912-2 | amd64,arm64,armel,armhf,i386,mips,mips64el,mipsel,ppc64el,s390x |
buster | 20070912-3 | amd64,arm64,armhf,i386 |
bullseye | 20070912-5 | amd64,arm64,armel,armhf,i386,mips64el,mipsel,ppc64el,s390x |
bookworm | 20070912-5 | amd64,arm64,armel,armhf,i386,mips64el,mipsel,ppc64el,s390x |
trixie | 20070912-7 | amd64,arm64,armel,armhf,i386,mips64el,ppc64el,riscv64,s390x |
sid | 20070912-7 | amd64,arm64,armel,armhf,i386,mips64el,ppc64el,riscv64,s390x |
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License: DFSG free
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This package contains several different Rubik's cube solvers,
either useful directly on the command-line or through sagemath.
Michael Reid's "optimal" uses pre-computed tables to find an optimal solution
to the 3x3x3 Rubik's cube.
Dik T.Winter's "dikcube" uses Kociemba's algorithm to iteratively
find a short solution to the 3x3x3 cube.
Eric Dietz' "cubex" has fast non-optimal solver for the 3x3x3 cube.
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Packaging has started and developers might try the packaging code in VCS
libgismo-dev
Geometry plus simulatiom modules development files
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Versions of package libgismo-dev |
Release | Version | Architectures |
VCS | 0.8.3-2 | all |
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License: MPL-2.0
Debian package not available
Version: 0.8.3-2
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G+Smo (Geometry + Simulation Modules, pronounced "gismo") is a new
open-source C++ library that brings together mathematical tools for
geometric design and numerical simulation. This package contains
inlude headers, cmake configuration files and other development utils.
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salome-geom
Numerical simulation pre- and post-processor - geometry module
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Versions of package salome-geom |
Release | Version | Architectures |
VCS | 6.5.0-6 | all |
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License: free
Debian package not available
Version: 6.5.0-6
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Salomé is a pre- and post-processor for numerical simulations. It can import
CAD files in IGES and STEP formats, facilitates component integration in
heterogeneous systems, and has a user-friendly GUI as well as a Python console
with all of the platform functionality.
This package contains the Salomé geometry module.
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