PAN Blend tomography packages

CTSim は対話的なコンピュータ断層撮影シミュレータを提供します。コンピュータ 断層撮影は物体を透過する X 線の吸収量を計測して、その物体の内部を推定する技 法です。

CTSim にはコマンドラインツールとグラフィカルユーザインターフェースの両方が あります。CTSim には非常に教育的な追跡モードがあり、データ収集シミュレー ションと再構成を見ることができます。

This package provides HTML and PDF documentation files for the ctsim package. CTSim is a graphical computed tomography simulator. This documentation file is included in a separate package so it will not have to be include in the binary ctsim package for every architecture.

This package provides the online help file for the ctsim package. CTSim is a graphical computed tomography simulator. This help file is included in a separate package so it will not have to be include in the binary ctsim package for every architecture.

Geomview は対話的な幾何的図形ソフトウェアで、数学の研究および教育に特に適し ています。特に、geomview は双曲空間、球面空間やユークリッド空間にある物体を 表示できます。

Geomview では複数の対象物やカメラを各々独立に操作できます。動きや外観 (照明 や陰、素材感を含む)、オブジェクトや端・頂点の選択、SGI 画像ファイルまたは Renderman RIB 形式のスナップショットを対話的に制御できます。オブジェクトの 追加や削除は、マウスでの直接の操作、コントロールパネル、キーボードショート カットで行えます。(位置の変化を連続的にロードしたり、特定のオブジェクトの動 きを制御したり、といった) ビューアの望ましい機能を外部プログラムから制御し 実現できると同時に、その他あらゆる点について対話的に制御することが可能です。

The UFO data processing framework is a C library suited to build general purpose streams data processing on heterogeneous architectures such as CPUs, GPUs or clusters. It is extensively used at the Karlsruhe Institute of Technology for Ultra-fast X-ray Imaging (radiography, tomography and laminography).

A gobject-instrospection binding is also provided to write scripts or user interfaces.

This package can be used by other packages using the GIRepository format to generate dynamic bindings.

MayaVi2 is a cross-platform tool for 2-D and 3-D scientific data visualization. Its features include:

• Visualization of scalar, vector and tensor data in 2 and 3 dimensions
• Easy scriptability using Python
• Easy extendability via custom sources, modules, and data filters
• Reading several file formats: VTK (legacy and XML), PLOT3D, etc.
• Saving of visualizations
• Saving rendered visualization in a variety of image formats.

MayaVi2 has been designed with scriptability and extensibility in mind. While the mayavi2 application is usable by itself, it may be used as an Envisage plugin which allows it to be embedded in user applications natively. Alternatively, it may be used as a visualization engine for any application.

This package also provides TVTK, which wraps VTK objects to provide a convenient, Pythonic API, while supporting Traits attributes and NumPy/SciPy arrays. TVTK is implemented mostly in pure Python, except for a small extension module.

Meshio can read from and write to various data formats representing unstructured meshes, such as DOLFIN, Gmsh, H5M or VTK.

This package provides the command-line tools, and a plugin for paraview.

This package also provides Flavien Loiseau's msh2xdmf tool to convert from MSH to XDMF mesh formats.

ParaView は、小規模なものから非常に大規模なものまで様々なサイズの データセットを可視化するためのオープンソースかつ マルチプラットフォームなアプリケーションです。 ParaView プロジェクトの目標は以下に挙げたものを含みます。

* オープンソースでマルチプラットフォームな
  可視化アプリケーションを開発すること。
* 巨大なデータセットを処理するための分散計算モデルを
  サポートすること。
* オープンで柔軟、かつ直感的な
  ユーザーインターフェースを作成すること。
* オープンな標準に基づいた、拡張可能なアーキテクチャを開発すること。

ParaView は並列および単一プロセッサのシステムの 分散・共有されたメモリ上で実行できます。 また、Windows や Mac OS X、Linux や様々な Unix の ワークステーションやクラスタ、スーパーコンピュータで うまくテストされています。 内部的には、ParaView はデータ処理のためとレンダリングエンジンとして Visualization Toolkit を使っています。 また、Qt を使って書かれたユーザーインターフェースです。

ParaView is an open-source, multi-platform application designed to visualize data sets of size varying from small to very large. The goals of the ParaView project include the following:

* Develop an open-source, multi-platform visualization application.
* Support distributed computation models to process large data sets.
* Create an open, flexible, and intuitive user interface.
* Develop an extensible architecture based on open standards.

ParaView runs on distributed and shared memory parallel as well as single processor systems and has been successfully tested on Windows, Mac OS X, Linux and various Unix workstations, clusters and supercomputers. Under the hood, ParaView uses the Visualization Toolkit as the data processing and rendering engine and has a user interface written using Qt. Development header files

ParaView is an open-source, multi-platform application designed to visualize data sets of size varying from small to very large. The goals of the ParaView project include the following:

* Develop an open-source, multi-platform visualization application.
* Support distributed computation models to process large data sets.
* Create an open, flexible, and intuitive user interface.
* Develop an extensible architecture based on open standards.

ParaView runs on distributed and shared memory parallel as well as single processor systems and has been successfully tested on Windows, Mac OS X, Linux and various Unix workstations, clusters and supercomputers. Under the hood, ParaView uses the Visualization Toolkit as the data processing and rendering engine and has a user interface written using Qt. Comprehensive documentation.

Plastimatch is an open source software for deformable image registration. It is designed for high-performance volumetric registration of medical images, such as X-ray computed tomography (CT), magnetic resonance imaging (MRI), and positron emission tomography(PET). Software features include:

• B-spline method for deformable image registration (GPU and multicore accelerated), including support for image masking, landmark penalties, and regularization
• Demons method for deformable image registration (GPU accelerated)
• Multi-atlas segmentation
• ITK-based algorithms for translation, rigid, affine, multiple demons methods, and B-spline registration
• Pipelined, multi-stage registration framework with seamless conversion between most algorithms and transform types
• Landmark-based deformable registration using thinplate splines for global registration
• Landmark-based deformable registration using radial basis functions for local corrections
• Broad support for 3D image file formats (using ITK), including DICOM, Nifti, NRRD, MetaImage, and Analyze

• Extensive toolchain for radiotherapy research, including support for DICOM, DICOM-RT, DICOM SRO, XiO file format, gamma analysis, contour manipulation, contour overlap analysis, and vector field analysis Plastimatch also features two handy utilities which are not directly related to image registration:

• FDK cone-beam CT reconstruction (GPU and multicore accelerated)

• Digitally reconstructed radiograph (DRR) generation (GPU and multicore accelerated)

Freeart is a tomographic image reconstruction library using Algebraic Reconstruction Technique (ART). It is able to deal with absorption and emission sinograms. Freeart core is written in C++ using template classes to have simple or double precision. A python interface is provided to access the core functionalities. A set of utils such as configuration files, interpreter to run reconstruction from configuration files are provided in python.

Nabu can be used in several ways:

• As a Python library, by features like Backprojector, FlatField, etc
• As a standalone application with the command line interface
• From Tomwer (https://gitlab.esrf.fr/tomotools/tomwer/)

ParaView is an open-source, multi-platform application designed to visualize data sets of size varying from small to very large. The goals of the ParaView project include the following:

* Develop an open-source, multi-platform visualization application.
* Support distributed computation models to process large data sets.
* Create an open, flexible, and intuitive user interface.
* Develop an extensible architecture based on open standards.

ParaView runs on distributed and shared memory parallel as well as single processor systems and has been successfully tested on Windows, Mac OS X, Linux and various Unix workstations, clusters and supercomputers. Under the hood, ParaView uses the Visualization Toolkit as the data processing and rendering engine and has a user interface written using Qt. Enables python support.

scikit-image is a collection of image processing algorithms for Python. It performs tasks such as image loading, filtering, morphology, segmentation, color conversions, and transformations.

This package provides the Python 3 module.

Tomogui offers a Graphical User Interface to run tomographic reconstruction based on freeart and silx algorithms

Tomogui contains two main applications:

• tomogui project : to create a new project from scratch
• tomogui recons : to run reconstruction from a configuration file created by 'tomogui project'

This library is offering an abstraction to access tomography data from various file formats.

It can read:

• acquisitions from spec (.edf) and bliss (.hdf5)
• volumes:
• single frame file: EDF, JP2K, tiff
• multi frame: HDF5, multitiff

This repository contains Python data processing scripts to be used with the UFO framework. At the moment they are targeted at high-performance reconstruction of tomographic data sets.

Vispy is a high-performance interactive 2D/3D data visualization library.

Vispy leverages the computational power of modern Graphics Processing Units (GPUs) through the OpenGL library to display very large datasets.

This package provides VisPy for the Python 3 interpreter.

Rheolef is a computer environment that serves as a convenient laboratory for computations in applied mathematics involving finite element-like methods. It provides a set of commands and C++ algorithms and containers.

Most basically, containers cover the classic graph data structure for sparse matrix formats and finite element meshes. At a higher level of abstraction, they can handle approximate finite element spaces, discrete fields. Flexible and powerful expressions are used to specify bilinear forms.

Current applications include:

• massively distributed memory finite element environment, based on MPI;
• elasticity, Stokes and Navier-Stokes problems in 2D and 3D;
• complex fluids applications: viscoplasticity, viscoelasticity, wall slip;
• nonlinear problems with fixed-point, Newton and continuation methods;
• high order polynomials, mixed elements and discontinuous Galerkin methods;
• auto-adaptive mesh approaches;
• axisymmetric problems;
• multi-regions and variable coefficient problems.

This package provides the rheolef commands. These support input and output in various file formats for mesh-generators and numerical data visualization systems such as paraview, and gnuplot.

The UFO data processing framework is a C library suited to build general purpose streams data processing on heterogeneous architectures such as CPUs, GPUs or clusters. It is extensively used at the Karlsruhe Institute of Technology for Ultra-fast X-ray Imaging (radiography, tomography and laminography).

A gobject-instrospection binding is also provided to write scripts or user interfaces.

This package provides the documentation for libufo.

The UFO data processing framework is a C library suited to build general purpose streams data processing on heterogeneous architectures such as CPUs, GPUs or clusters. It is extensively used at the Karlsruhe Institute of Technology for Ultra-fast X-ray Imaging (radiography, tomography and laminography).

This package contains average',backproject', bin',blur', buffer',calculate', camera',clip', contrast',crop', denoise',duplicate', fftmult',fft', filter',flatten', flip',forwardproject', gemm',ifft', interpolate',loop', measure',merge', metaballs',monitor', null',opencl', ordfilt',pad', read',reduce', refeed',replicate', rescale',ringwriter', sleep',slice', stack',stdin', stdout',subtract', transpose',write' and `zeropad' plugins

The UFO data processing framework is a C library suited to build general purpose streams data processing on heterogeneous architectures such as CPUs, GPUs or clusters. It is extensively used at the Karlsruhe Institute of Technology for Ultra-fast X-ray Imaging (radiography, tomography and laminography).

This package provides the documentation for the plugins

It supports 2D parallel and fan beam geometries, and 3D parallel and cone beam. All of them have highly flexible source/detector positioning.

A large number of 2D and 3D algorithms are available, including FBP, SIRT, SART, CGLS.

The basic forward and backward projection operations are GPU-accelerated, and directly callable from Octave and Python to enable building new algorithms.

This is the Octave library.

It supports 2D parallel and fan beam geometries, and 3D parallel and cone beam. All of them have highly flexible source/detector positioning.

A large number of 2D and 3D algorithms are available, including FBP, SIRT, SART, CGLS.

The basic forward and backward projection operations are GPU-accelerated, and directly callable from Octave and Python to enable building new algorithms.

This is the Python3 library.

PyHST is a Python program for Tomographic data reconstruction based on direct filtered back-projection algorithm

This is the CUDA version

Features:

• Image reconstruction algorithms for tomography.
• Various filters, ring removal algorithms, phase retrieval algorithms.
• Forward projection operator for absorption and wave propagation.

RabbitCT provides an open platform for worldwide performance-comparison of backprojection implementations on different architectures using one specific, clinical, high resolution C-arm CT dataset of a rabbit. This includes a sophisticated benchmark interface, a prototype implementation in C++, and image quality measures.

provided prior to the tomography experiment.