Comparison of morphological pyramids for multiresolution MIP volume rendering
VISSYM '02 Proceedings of the symposium on Data Visualisation 2002
An Extension of Fourier-Wavelet Volume Rendering by View Interpolation
Journal of Mathematical Imaging and Vision
Shading for Fourier Volume Rendering
VVS '02 Proceedings of the 2002 IEEE symposium on Volume visualization and graphics
Interactive Transfer Function Control for Monte Carlo Volume Rendering
VV '04 Proceedings of the 2004 IEEE Symposium on Volume Visualization and Graphics
Morphological Pyramids in Multiresolution MIP Rendering of Large Volume Data: Survey and New Results
Journal of Mathematical Imaging and Vision
Proceedings of the 14th IEEE Visualization 2003 (VIS'03)
Fourier Volume Rendering on GPGPU
ISNN 2009 Proceedings of the 6th International Symposium on Neural Networks: Advances in Neural Networks - Part III
A new class of morphological pyramids for multiresolution image analysis
Proceedings of the 11th international conference on Theoretical foundations of computer vision
Mathematical morphology in computer graphics, scientific visualization and visual exploration
ISMM'11 Proceedings of the 10th international conference on Mathematical morphology and its applications to image and signal processing
High-quality volume rendering with resampling in the frequency domain
EUROVIS'05 Proceedings of the Seventh Joint Eurographics / IEEE VGTC conference on Visualization
Multiresolution maximum intensity volume rendering by morphological pyramids
EGVISSYM'01 Proceedings of the 3rd Joint Eurographics - IEEE TCVG conference on Visualization
Multiresolution MIP rendering of large volumetric data accelerated on graphics hardware
EUROVIS'07 Proceedings of the 9th Joint Eurographics / IEEE VGTC conference on Visualization
Accelerating Fourier volume rendering by polar coordinate data representation
Computer Methods and Programs in Biomedicine
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We describe a wavelet based X-ray rendering method in the frequency domain with a smaller time complexity than wavelet splatting. Standard Fourier volume rendering is summarized and interpolation and accuracy issues are briefly discussed. We review the implementation of the fast wavelet transform in the frequency domain. The wavelet X-ray transform is derived, and the corresponding Fourier-wavelet volume rendering algorithm (FWVR) is introduced, FWVR uses Haar or B-spline wavelets and linear or cubic spline interpolation. Various combinations are tested and compared with wavelet splatting (WS). We use medical MR and CT scan data, as well as a 3-D analytical phantom to assess the accuracy, time complexity, and memory cost of both FWVR and WS. The differences between both methods are enumerated