Sven Steckmann scite author profile

Sven Steckmann

5Publications

60Citation Statements Received

22Citation Statements Given

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University of Erlangen-Nuremberg

Publications

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High performance cone-beam spiral backprojection with voxel-specific weighting

2009

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Cone-beam spiral backprojection is computationally highly demanding. At first sight, the backprojection requirements are similar to those of cone-beam backprojection from circular scans such as it is performed in the widely used Feldkamp algorithm. However, there is an additional complication: the illumination of each voxel, i.e. the range of angles the voxel is seen by the x-ray cone, is a complex function of the voxel position. In general, one needs to multiply a voxel-specific weight w(x, y, z, alpha) prior to adding a projection from angle alpha to a voxel at position x, y, z. Often, the weight function has no analytically closed form and must be numerically determined. Storage of the weights is prohibitive since the amount of memory required equals the number of voxels per spiral rotation times the number of projections a voxel receives contributions and therefore is in the order of up to 10(12) floating point values for typical spiral scans. We propose a new algorithm that combines the spiral symmetry with the ability of today's 64 bit operating systems to store large amounts of precomputed weights, even above the 4 GB limit. Our trick is to backproject into slices that are rotated in the same manner as the spiral trajectory rotates. Using the spiral symmetry in this way allows one to exploit data-level paralellism and thereby to achieve a very high level of vectorization. An additional postprocessing step rotates these slices back to normal images. Our new backprojection algorithm achieves up to 17 giga voxel updates per second on our systems that are equipped with four standard Intel X7460 hexa core CPUs (Intel Xeon 7300 platform, 2.66 GHz, Intel Corporation). This equals the reconstruction of 344 images per second assuming that each slice consists of 512 x 512 pixels and receives contributions from 512 projections. Thereby, it is an order of magnitude faster than a highly optimized code that does not make use of the spiral symmetry. In its present version, the spiral backprojection algorithm is pixel-driven. A ray-driven version and a corresponding high performance forward projector can be easily designed. Thus, our findings can be used to speed up any type of image reconstruction algorithm (approximate or exact analytical algorithms and iterative algorithms) and therefore yield a versatile and valuable component of future image reconstruction pipelines.

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Algorithm for hyperfast cone-beam spiral backprojection

Steckmann

Knaup

Kachelrieí

2010

Computer Methods and Programs in Biomedicine

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GPU-based parallel-beam and cone-beam forward- and backprojection using CUDA

Knaup

Steckmann

Kachelrieß

2008

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CT image reconstruction using hexagonal grids

Knaup

Steckmann

Bockenbach³

et al. 2007

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Blooming artifact reduction for cardiac CT

Steckmann

Kachelries

2010

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Sven Steckmann

High performance cone-beam spiral backprojection with voxel-specific weighting

Algorithm for hyperfast cone-beam spiral backprojection

GPU-based parallel-beam and cone-beam forward- and backprojection using CUDA

CT image reconstruction using hexagonal grids

Blooming artifact reduction for cardiac CT

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