GPU Accelerated DRR Computation with Scatter

Allbwn ymchwil: Cyfraniad at gyfnodolynErthygladolygiad gan gymheiriaid

StandardStandard

GPU Accelerated DRR Computation with Scatter. / Vidal, F. P.; Folkerts, M.; Freud, N. et al.
Yn: Medical Physics, Cyfrol 38, Rhif 6, 01.07.2011, t. 3455-3456.

Allbwn ymchwil: Cyfraniad at gyfnodolynErthygladolygiad gan gymheiriaid

HarvardHarvard

Vidal, FP, Folkerts, M, Freud, N & Jiang, S 2011, 'GPU Accelerated DRR Computation with Scatter', Medical Physics, cyfrol. 38, rhif 6, tt. 3455-3456. https://doi.org/10.1118/1.3611828

APA

Vidal, F. P., Folkerts, M., Freud, N., & Jiang, S. (2011). GPU Accelerated DRR Computation with Scatter. Medical Physics, 38(6), 3455-3456. https://doi.org/10.1118/1.3611828

CBE

Vidal FP, Folkerts M, Freud N, Jiang S. 2011. GPU Accelerated DRR Computation with Scatter. Medical Physics. 38(6):3455-3456. https://doi.org/10.1118/1.3611828

MLA

VancouverVancouver

Vidal FP, Folkerts M, Freud N, Jiang S. GPU Accelerated DRR Computation with Scatter. Medical Physics. 2011 Gor 1;38(6):3455-3456. doi: 10.1118/1.3611828

Author

Vidal, F. P. ; Folkerts, M. ; Freud, N. et al. / GPU Accelerated DRR Computation with Scatter. Yn: Medical Physics. 2011 ; Cyfrol 38, Rhif 6. tt. 3455-3456.

RIS

TY - JOUR

T1 - GPU Accelerated DRR Computation with Scatter

AU - Vidal, F. P.

AU - Folkerts, M.

AU - Freud, N.

AU - Jiang, S.

PY - 2011/7/1

Y1 - 2011/7/1

N2 - Purpose: We propose a fast software library implemented on graphics processing unit (GPU) to compute digitally reconstructed radiographs (DRRs). It takes into account first order Compton scattering. Methods: The simulation is based on the evaluation of the Beer-Lambert law and of the Klein-Nishina equation. The algorithm is fully determinist and has been fully implemented on GPU to achieve clinically acceptable efficiency. A full resolution simulation is performed for primary radiation. A much lower image resolution is used for Compton scattering as it adds a low frequency pattern over the projection image. Each voxel of the CT dataset is considered as a secondary source. The number of photons that reach each voxel is evaluated. Then, for each secondary source, a projection image is computed and integrated in the final image. The photon energy between each secondary source and each pixel is also computed. An interlaced sampling mode is also proposed to further reduce the computation time without sacrificing numerical accuracy. Finally, the speed and accuracy are assessed. Results: We show that the computations can be fully implemented on the GPU with an original under-sampling method to produce clinically acceptable results. For example, a simulation can be achieved in less than 7 seconds whilst the maximum relative error remains below 5% and the average relative error below 1.4 At full resolution, a speed-up by factor ∼12X is achieved for the GPU implementation with our interlaced-mode by comparison with our multi-threaded CPU implementation using 8 threads in parallel. Conclusions: DRR calculation with scatter is computationally intensive. The use of GPU can achieve clinically acceptable efficiency. A Compton fluence map can be computed in a few seconds using under-sampling, whilst keeping numerical inaccuracies relatively low. This work can be used for CBCT reconstruction to reduce scatter artifacts.

AB - Purpose: We propose a fast software library implemented on graphics processing unit (GPU) to compute digitally reconstructed radiographs (DRRs). It takes into account first order Compton scattering. Methods: The simulation is based on the evaluation of the Beer-Lambert law and of the Klein-Nishina equation. The algorithm is fully determinist and has been fully implemented on GPU to achieve clinically acceptable efficiency. A full resolution simulation is performed for primary radiation. A much lower image resolution is used for Compton scattering as it adds a low frequency pattern over the projection image. Each voxel of the CT dataset is considered as a secondary source. The number of photons that reach each voxel is evaluated. Then, for each secondary source, a projection image is computed and integrated in the final image. The photon energy between each secondary source and each pixel is also computed. An interlaced sampling mode is also proposed to further reduce the computation time without sacrificing numerical accuracy. Finally, the speed and accuracy are assessed. Results: We show that the computations can be fully implemented on the GPU with an original under-sampling method to produce clinically acceptable results. For example, a simulation can be achieved in less than 7 seconds whilst the maximum relative error remains below 5% and the average relative error below 1.4 At full resolution, a speed-up by factor ∼12X is achieved for the GPU implementation with our interlaced-mode by comparison with our multi-threaded CPU implementation using 8 threads in parallel. Conclusions: DRR calculation with scatter is computationally intensive. The use of GPU can achieve clinically acceptable efficiency. A Compton fluence map can be computed in a few seconds using under-sampling, whilst keeping numerical inaccuracies relatively low. This work can be used for CBCT reconstruction to reduce scatter artifacts.

U2 - 10.1118/1.3611828

DO - 10.1118/1.3611828

M3 - Article

VL - 38

SP - 3455

EP - 3456

JO - Medical Physics

JF - Medical Physics

IS - 6

T2 - American Association of Physicists in Medicine 2011

Y2 - 31 July 2011 through 4 August 2011

ER -