Presentation is loading. Please wait.

Presentation is loading. Please wait.

1 Overview (Part 1) Background notions A reference framework for multiresolution meshes Classification of multiresolution meshes An introduction to LOD.

Published byWalter Chase Modified over 9 years ago

Similar presentations

Presentation on theme: "1 Overview (Part 1) Background notions A reference framework for multiresolution meshes Classification of multiresolution meshes An introduction to LOD."— Presentation transcript:

1 1 Overview (Part 1) Background notions A reference framework for multiresolution meshes Classification of multiresolution meshes An introduction to LOD queries

2 2 Level-Of-Detail Queries on a Multiresolution Mesh Extract from a multiresolution model a mesh satisfying some application-dependent requirement based on LOD Selective refinement queries: Result: a mesh covering the whole spatial object Multiresolution mesh as a virtual simplification tool Spatial selection queries: Result: a mesh describing the portion of the object which interferes in space with a given query entity Multiresolution mesh as a spatial index

3 3 Examples of Selective Refinement uniform high resolution uniform low resolution high resolution just in the legs high resolution just in the head

4 4 Examples of Spatial Selection Some meshes describing details of the bunny

5 5 Level-Of-Detail LOD criterion  : Boolean function defined over the n-cells of a multiresolution mesh  (  ) =True if  satisfies the LOD requirements A mesh satisfies a given LOD criterion  iff  (  )= True for all n-cells  of  An approximation error is usually associated with the n- cells of a multiresolution mesh: distance, according to some norm, with respect to a reference surface or hypersurface

6 6 Examples of LOD Criteria Uniform LOD: –  (  )= True if the error associated with  is less or equal to a constant threshold  Variable LOD: –  (  )= True if the error associated with  is less or equal to the maximum over  of a threshold function  defined at each point of the domain (e.g., a view-dependent function) Special case of variable LOD for scalar fields: –the threshold function  depends on the value of the field at each point of the domain (e.g,  (p) small at a set of interesting field values, large otherwise)

7 7 Examples of LOD Criteria on a Terrain Variable LOD on the field range (top of the mountain) Uniform LODs Variable LOD on the domain (lower left angle)

8 8 Selective Refinement Query Given a multiresolution mesh M and a LOD criterion  extract from M the mesh of minimum size  S satisfying 

9 9 Spatial Selection Query Given a multiresolution mesh M, a Region Of Interest (ROI) R in space, and a LOD criterion , extract from M a mesh  of minimum size such that –  satisfies  –  covers the part of the domain of M that interferes with R Examples of ROIs: –An n-dimensional axis-aligned box: window query –An n-dimensional ball: range query

10 10 Examples of ROIs Window and range queries at different resolutions on a terrain

Download ppt "1 Overview (Part 1) Background notions A reference framework for multiresolution meshes Classification of multiresolution meshes An introduction to LOD."

Similar presentations

1 INTRODUCTIONINTRODUCTION Multiresolution Meshes in Surface Modeling Leila De Floriani DISI - University of Genova (Italy) and UMIACS Joint work with.

1 INTRODUCTIONINTRODUCTION Multiresolution Meshes in Surface Modeling Leila De Floriani DISI - University of Genova (Italy) and UMIACS Joint work with.
Surface Simplification Using Quadric Error Metrics Speaker: Fengwei Zhang September 20. 2007.

Surface Simplification Using Quadric Error Metrics Speaker: Fengwei Zhang September
Yang Yang, Miao Jin, Hongyi Wu Presenter: Buri Ban The Center for Advanced Computer Studies (CACS) University of Louisiana at Lafayette 3D Surface Localization.

Yang Yang, Miao Jin, Hongyi Wu Presenter: Buri Ban The Center for Advanced Computer Studies (CACS) University of Louisiana at Lafayette 3D Surface Localization.
Presented By: Vennela Sunnam

Presented By: Vennela Sunnam
Topology-Based Analysis of Time-Varying Data Scalar data is often used in scientific data to represent the distribution of a particular value of interest,

Topology-Based Analysis of Time-Varying Data Scalar data is often used in scientific data to represent the distribution of a particular value of interest,
Spatial Mining.

Spatial Mining.
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.
4.4. L EVEL OF D ETAIL Exploration of 3D mesh level-of-detail approaches.

4.4. L EVEL OF D ETAIL Exploration of 3D mesh level-of-detail approaches.
1 Displaced Subdivision Surfaces Aaron Lee Princeton University Henry Moreton Nvidia Hugues Hoppe Microsoft Research.

1 Displaced Subdivision Surfaces Aaron Lee Princeton University Henry Moreton Nvidia Hugues Hoppe Microsoft Research.
Smooth View-Dependent Level-of- Detail Control and its Application to Terrain Rendering Hugues Hoppe Microsoft Research.

Smooth View-Dependent Level-of- Detail Control and its Application to Terrain Rendering Hugues Hoppe Microsoft Research.
1 Abstract This paper presents a novel modification to the classical Competitive Learning (CL) by adding a dynamic branching mechanism to neural networks.

1 Abstract This paper presents a novel modification to the classical Competitive Learning (CL) by adding a dynamic branching mechanism to neural networks.
Simplification of Arbitrary Polyhedral Meshes Shaun D. Ramsey* Martin Bertram Charles Hansen University of Utah University of Kaiserslautern University.

Simplification of Arbitrary Polyhedral Meshes Shaun D. Ramsey* Martin Bertram Charles Hansen University of Utah University of Kaiserslautern University.
A Confidence Limit for Hilbert Spectrum Through stoppage criteria.

A Confidence Limit for Hilbert Spectrum Through stoppage criteria.
Procedural Shape Synthesis on Subdivision Surfaces

Procedural Shape Synthesis on Subdivision Surfaces
Indexing of Network Constrained Moving Objects Dieter Pfoser Christian S. Jensen Chia-Yu Chang.

Indexing of Network Constrained Moving Objects Dieter Pfoser Christian S. Jensen Chia-Yu Chang.
Visual Querying By Color Perceptive Regions Alberto del Bimbo, M. Mugnaini, P. Pala, and F. Turco University of Florence, Italy Pattern Recognition, 1998.

Visual Querying By Color Perceptive Regions Alberto del Bimbo, M. Mugnaini, P. Pala, and F. Turco University of Florence, Italy Pattern Recognition, 1998.
11/08/00 Dinesh Manocha, COMP258 Subdivision Curves & Surfaces Work of G. de Rham on Corner Cutting in 40’s and 50’s Work of Catmull/Clark and Doo/Sabin.

11/08/00 Dinesh Manocha, COMP258 Subdivision Curves & Surfaces Work of G. de Rham on Corner Cutting in 40’s and 50’s Work of Catmull/Clark and Doo/Sabin.
Visualization and graphics research group CIPIC January 21, 2003Multiresolution (ECS 289L) - Winter 20031 Surface Simplification Using Quadric Error Metrics.

Visualization and graphics research group CIPIC January 21, 2003Multiresolution (ECS 289L) - Winter Surface Simplification Using Quadric Error Metrics.
Visualization and graphics research group CIPIC February 13, 2003ECS289L – Multiresolution Methods – Winter 20031 Illumination Dependent Refinement of.

Visualization and graphics research group CIPIC February 13, 2003ECS289L – Multiresolution Methods – Winter Illumination Dependent Refinement of.
Geometric Modeling and Computer Graphics GROUP

Geometric Modeling and Computer Graphics GROUP

Similar presentations

Ads by Google