Fabio Marton scite author profile

We describe an efficient technique for out-of-core management and interactive rendering of planet sized textured terrain surfaces. The technique, called P-Batched Dynamic Adaptive Meshes (P-BDAM), extends the BDAM approach by using as basic primitive a general triangulation of points on a displaced triangle. The proposed framework introduces several advances with respect to the state of the art: thanks to a batched host-to-graphics communication model, we outperform current adaptive tessellation solutions in terms of rendering speed; we guarantee overall geometric continuity, exploiting programmable graphics hardware to cope with the accuracy issues introduced by single precision floating points; we exploit a compressed out of core representation and speculative prefetching for hiding disk latency during rendering of out-of-core data; we efficiently construct high quality simplified representations with a novel distributed out of core simplification algorithm working on a standard PC network.

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Interactive Multiscale Tensor Reconstruction for Multiresolution Volume Visualization

Suter

Guitián

Marton

et al. 2011

IEEE Trans. Visual. Comput. Graphics

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Abstract-Large scale and structurally complex volume datasets from high-resolution 3D imaging devices or computational simulations pose a number of technical challenges for interactive visual analysis. In this paper, we present the first integration of a multiscale volume representation based on tensor approximation within a GPU-accelerated out-of-core multiresolution rendering framework. Specific contributions include (a) a hierarchical brick-tensor decomposition approach for pre-processing large volume data, (b) a GPU accelerated tensor reconstruction implementation exploiting CUDA capabilities, and (c) an effective tensor-specific quantization strategy for reducing data transfer bandwidth and out-of-core memory footprint. Our multiscale representation allows for the extraction, analysis and display of structural features at variable spatial scales, while adaptive level-of-detail rendering methods make it possible to interactively explore large datasets within a constrained memory footprint. The quality and performance of our prototype system is evaluated on large structurally complex datasets, including gigabyte-sized micro-tomographic volumes.

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C‐BDAM – Compressed Batched Dynamic Adaptive Meshes for Terrain Rendering

Gobbetti

Marton

Cignoni

et al. 2006

Computer Graphics Forum

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Fabio Marton

BDAM — Batched Dynamic Adaptive Meshes for High Performance Terrain Visualization

A single-pass GPU ray casting framework for interactive out-of-core rendering of massive volumetric datasets

Planet-sized batched dynamic adaptive meshes (P-BDAM)

Interactive Multiscale Tensor Reconstruction for Multiresolution Volume Visualization

C‐BDAM – Compressed Batched Dynamic Adaptive Meshes for Terrain Rendering

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