Presentation is loading. Please wait.

Presentation is loading. Please wait.

National Energy Research Scientific Computing Center (NERSC) Visualization Highlights Cristina Siegerist NERSC Center Division, LBNL October 4, 2005.

Published byMagdalen McDaniel Modified over 9 years ago

Similar presentations

Presentation on theme: "National Energy Research Scientific Computing Center (NERSC) Visualization Highlights Cristina Siegerist NERSC Center Division, LBNL October 4, 2005."— Presentation transcript:

1 National Energy Research Scientific Computing Center (NERSC) Visualization Highlights Cristina Siegerist NERSC Center Division, LBNL October 4, 2005

2 Visualization Highlights: Visualization of 3D Reconstructions of Electron Tomography Data Ken Downing, Life Sciences Division, LBNL

3 The Science Bacteria contain a wealth of mechanisms that organize their internal and external structure. Electron tomography offers the possibility to localize the cell components at a resolution that allows a better understanding of their structure and function. The 3D reconstruction of whole cells should lead to the ability to model spatial and temporal relationships between sub- cellular structures, organelles and macromolecular complexes

4 The Science Electron Tomography consists of obtaining a three- dimensional reconstruction of an object from a series of projection images. Resolution depends on the resolution of the tilt angles and the dose.

5 From Images to Volume Reconstruction of dividing Caulobacter Crescentus cells

6 From Images to Volume Reconstruction of dividing Caulobacter Crescentus cells: isosurface after filtering

7 From Volumes to Surfaces AVS/Express Model builder application: –Provide an interactive interface to build a model of 2D features (membranes for example) in noisy data.

8 From Volumes to Surfaces AVS/Express Model builder application: –Select points along a membrane for each slice in the z direction

9 From Volumes to Surfaces AVS/Express Model builder application: –Add the sets

10 From Volumes to Surfaces AVS/Express Model builder application: –Build splines for each set and make a polyline field.

11 From Volumes to Surfaces AVS/Express Model builder application: –Triangulate the surface

12 From Volumes to Surfaces AVS/Express Model builder application: –Triangulate the surface

13 From Volumes to Surfaces

14 Start with the points selected on a membrane for each slice along the Z axis.

15 From Volumes to Surfaces Constructing the splines.

16 From Volumes to Surfaces Triangulation

17 From Volumes to Surfaces Triangulation

18 From Volumes to Surfaces

19 Journal of Bacteriology October 2005 Cover

20 From Volumes to Surfaces Problems: easy to solve: smoothing the surface. not so easy: stitching and bifurcations.

21 Another Approach: Point Clouds to surfaces Reconstruction of surfaces with boundaries from point clouds without the restriction of dense sampling: Normfet, AMLS and Co- Cone software provided by Dr.Tamal Dey, Ohio State University. References: –T. K. Dey and J. Sun. Normal and Feature Estimations from Noisy Point Clouds. Technical Report OSU-CISRC-7/50-TR50, July, 2005.Normal and Feature Estimations from Noisy Point Clouds –T. K. Dey and J. Sun. Adaptive MLS Surfaces for Reconstruction with Guarantees. Proc. Eurographics Symposium on Geometry Processing (2005), 43--52.Adaptive MLS Surfaces for Reconstruction with Guarantees –N. Amenta, S. Choi, T. K. Dey and N. Leekha. A simple algorithm for homeomorphic surface reconstruction. Intl. J. Comput. Geom. Appl., Vol. 12 (2002), 125--141.A simple algorithm for homeomorphic surface reconstruction –http://www.cse.ohio-state.edu/~tamaldey/cocone.html

22 Point Clouds to surfaces Start with the points selected on a membrane for each slice along the Z axis.

23 Point Clouds to surfaces Estimate the normals

24 Point Clouds to surfaces Smooth the cloud

25 Point Clouds to surfaces Smooth the cloud

26 Point Clouds to surfaces Reconstruct the surface with boundaries

27 Point Clouds to surfaces

28 Smoothing the point cloud using AMLS, Co-cone rescontruction (T.Dey Ohio State University)

29 Use of the Model

Download ppt "National Energy Research Scientific Computing Center (NERSC) Visualization Highlights Cristina Siegerist NERSC Center Division, LBNL October 4, 2005."

Similar presentations

An Adaptive MLS Surface for Reconstruction with Guarantees

An Adaptive MLS Surface for Reconstruction with Guarantees
Reconstruction from Voxels (GATE-540)

Reconstruction from Voxels (GATE-540)
1 st Meeting, Industrial Geometry, 2005 Approximating Solids by Balls (in collaboration with subproject: Applications of Higher Geometrics) Bernhard.

1 st Meeting, Industrial Geometry, 2005 Approximating Solids by Balls (in collaboration with subproject: "Applications of Higher Geometrics") Bernhard.
Games, Movies and Virtual Worlds – An Introduction to Computer Graphics Ayellet Tal Department of Electrical Engineering Technion.

Games, Movies and Virtual Worlds – An Introduction to Computer Graphics Ayellet Tal Department of Electrical Engineering Technion.
Surface Reconstruction From Unorganized Point Sets

Surface Reconstruction From Unorganized Point Sets
Analysis of Contour Motions Ce Liu William T. Freeman Edward H. Adelson Computer Science and Artificial Intelligence Laboratory Massachusetts Institute.

Analysis of Contour Motions Ce Liu William T. Freeman Edward H. Adelson Computer Science and Artificial Intelligence Laboratory Massachusetts Institute.
Junjie Cao 1, Andrea Tagliasacchi 2, Matt Olson 2, Hao Zhang 2, Zhixun Su 1 1 Dalian University of Technology 2 Simon Fraser University Point Cloud Skeletons.

Junjie Cao 1, Andrea Tagliasacchi 2, Matt Olson 2, Hao Zhang 2, Zhixun Su 1 1 Dalian University of Technology 2 Simon Fraser University Point Cloud Skeletons.
Flow Complex Joachim Giesen Friedrich-Schiller-Universität Jena.

Flow Complex Joachim Giesen Friedrich-Schiller-Universität Jena.
Computing 3D Geometry Directly From Range Images Sarah F. Frisken and Ronald N. Perry Mitsubishi Electric Research Laboratories.

Computing 3D Geometry Directly From Range Images Sarah F. Frisken and Ronald N. Perry Mitsubishi Electric Research Laboratories.
Non-Manifold Medial Surface Reconstruction from Volumetric Data 12010/6/16 Takashi Michikawa and Hiromasa Suzuki Research Center for Advanced Science and.

Non-Manifold Medial Surface Reconstruction from Volumetric Data 12010/6/16 Takashi Michikawa and Hiromasa Suzuki Research Center for Advanced Science and.
GATE-540 1 3D Object Representations (GATE-540) Dr.Çağatay ÜNDEĞER Instructor Middle East Technical University, GameTechnologies & General Manager SimBT.

GATE D Object Representations (GATE-540) Dr.Çağatay ÜNDEĞER Instructor Middle East Technical University, GameTechnologies & General Manager SimBT.
Surface Reconstruction from 3D Volume Data. Problem Definition Construct polyhedral surfaces from regularly-sampled 3D digital volumes.

Surface Reconstruction from 3D Volume Data. Problem Definition Construct polyhedral surfaces from regularly-sampled 3D digital volumes.
Direct Methods for Visual Scene Reconstruction Paper by Richard Szeliski & Sing Bing Kang Presented by Kristin Branson November 7, 2002.

Direct Methods for Visual Scene Reconstruction Paper by Richard Szeliski & Sing Bing Kang Presented by Kristin Branson November 7, 2002.
Tamal K. Dey The Ohio State University Delaunay Meshing of Surfaces.

Tamal K. Dey The Ohio State University Delaunay Meshing of Surfaces.
Shape Modeling International 2007 – University of Utah, School of Computing Robust Smooth Feature Extraction from Point Clouds Joel Daniels ¹ Linh Ha ¹.

Shape Modeling International 2007 – University of Utah, School of Computing Robust Smooth Feature Extraction from Point Clouds Joel Daniels ¹ Linh Ha ¹.
Surface Reconstruction Some figures by Turk, Curless, Amenta, et al.

Surface Reconstruction Some figures by Turk, Curless, Amenta, et al.
Surface Reconstruction with MLS Tobias Martin CS7960, Spring 2006, Feb 23.

Surface Reconstruction with MLS Tobias Martin CS7960, Spring 2006, Feb 23.
T. J. Peters, University of Connecticut www.cse.uconn.edu/~tpeters K. Abe, J. Bisceglio, A. C. Russell Computational Topology on Approximated Manifolds.

T. J. Peters, University of Connecticut K. Abe, J. Bisceglio, A. C. Russell Computational Topology on Approximated Manifolds.
Tamal K. Dey The Ohio State University Computing Shapes and Their Features from Point Samples.

Tamal K. Dey The Ohio State University Computing Shapes and Their Features from Point Samples.
Scientific Data Representation and Mapping

Scientific Data Representation and Mapping

Similar presentations

Ads by Google