HAS-Motion Software Documentation

User Tools

Site Tools

You are here: Main Page » other » dsx » DSX Overview
other:dsx:dsx_overview

Differences

This shows you the differences between two versions of the page.

Link to this comparison view

Both sides previous revisionPrevious revision
other:dsx:dsx_overview [2024/12/19 18:07] – Reorganized page, updated image references and fixed links. Put too much effort in. wikisysopother:dsx:dsx_overview [2024/12/19 18:27] (current) wikisysop
Line 12: Line 12:
  
 ^ Application ^ Purpose ^ ^ Application ^ Purpose ^
-| [[Other:DSX:xManager:xManager_Overview|XManager]] | The graphical interface to a subject file, which contains all of the information about one DSX subject, including links to all of the data files. This information is read and written by the other DSX applications (except PlanDSX). |+| [[Other:DSX:xManager:xManager_Overview|xManager]] | The graphical interface to a subject file, which contains all of the information about one DSX subject, including links to all of the data files. This information is read and written by the other DSX applications (except PlanDSX). |
 | [[Other:DSX:PlanDSX:PlanDSX_Overview|PlanDSX]] | A design tool that helps you determine the appropriate configuration of the X-ray equipment to capture high-quality images of the joint(s) of interest when planning a new study. It is essentially a CAD tool that creates a virtual lab containing the subject, X-ray equipment, motion capture cameras, and other equipment such as treadmills and force plates. The subject skeleton can be animated with motion capture data, and the bones generate simulated X-rays as they pass in front of the virtual X-ray image planes. | | [[Other:DSX:PlanDSX:PlanDSX_Overview|PlanDSX]] | A design tool that helps you determine the appropriate configuration of the X-ray equipment to capture high-quality images of the joint(s) of interest when planning a new study. It is essentially a CAD tool that creates a virtual lab containing the subject, X-ray equipment, motion capture cameras, and other equipment such as treadmills and force plates. The subject skeleton can be animated with motion capture data, and the bones generate simulated X-rays as they pass in front of the virtual X-ray image planes. |
 | [[Other:DSX:Surface3D:Surface3D_Overview|Surface3D]] | Segments objects (bones, implants, etc.) from CT data for use in model-based tracking, and it creates surface models of these objects for subsequent kinematic analysis of the tracking results. It works by labelling and segmenting CT data for each object, then saving the segmented objects to RAW or TIFF files. Then it produces polygonal surface models from the segmented objects using a marching cubes algorithm, and saves them to OBJ files. The segmented objects are used by X4D to generate [[Other:DSX:DSX_Definitions#Digitally_Reconstructed_Radiograph_(DRR)|DRRs]] for model-based tracking. The surface models are used by Orient3D to define anatomical reference frames and regions of interest (for distance map calculations), and by Visual3D for kinematic analysis. Surface3D also allows you to identify landmarks (e.g., ligament attachments) and points of interest (e.g., implanted beads) in the image data. | | [[Other:DSX:Surface3D:Surface3D_Overview|Surface3D]] | Segments objects (bones, implants, etc.) from CT data for use in model-based tracking, and it creates surface models of these objects for subsequent kinematic analysis of the tracking results. It works by labelling and segmenting CT data for each object, then saving the segmented objects to RAW or TIFF files. Then it produces polygonal surface models from the segmented objects using a marching cubes algorithm, and saves them to OBJ files. The segmented objects are used by X4D to generate [[Other:DSX:DSX_Definitions#Digitally_Reconstructed_Radiograph_(DRR)|DRRs]] for model-based tracking. The surface models are used by Orient3D to define anatomical reference frames and regions of interest (for distance map calculations), and by Visual3D for kinematic analysis. Surface3D also allows you to identify landmarks (e.g., ligament attachments) and points of interest (e.g., implanted beads) in the image data. |
other/dsx/dsx_overview.1734631647.txt.gz · Last modified: 2024/12/19 18:07 by wikisysop