Nonlocal Means (NLM) algorithm is widely considered as a state-of-the-art denoising filter in many research fields. Its high computational complexity leads researchers to the development of parallel programming approaches and the use of massively parallel architectures such as the GPUs. In the recent years, the GPU devices had led to achieving reasonable running times by filtering, slice-by-slice, and 3D datasets with a 2D NLM algorithm. In our approach we design and implement a fully 3D NonLocal Means parallel approach, adopting different algorithm mapping strategies on GPU architecture and multi-GPU framework, in order to demonstrate its high applicability and scalability. The experimental results we obtained encourage the usability of our approach in a large spectrum of applicative scenarios such as magnetic resonance imaging (MRI) or video sequence denoising
3D Data Denoising via Nonlocal Means Filter by Using Parallel GPU Strategies / Cuomo, Salvatore; Pasquale De, Michele; Piccialli, Francesco. - In: COMPUTATIONAL AND MATHEMATICAL METHODS IN MEDICINE. - ISSN 1748-670X. - 2014:(2014), pp. 1-14. [10.1155/2014/523862]
3D Data Denoising via Nonlocal Means Filter by Using Parallel GPU Strategies
CUOMO, SALVATORE;PICCIALLI, FRANCESCO
2014
Abstract
Nonlocal Means (NLM) algorithm is widely considered as a state-of-the-art denoising filter in many research fields. Its high computational complexity leads researchers to the development of parallel programming approaches and the use of massively parallel architectures such as the GPUs. In the recent years, the GPU devices had led to achieving reasonable running times by filtering, slice-by-slice, and 3D datasets with a 2D NLM algorithm. In our approach we design and implement a fully 3D NonLocal Means parallel approach, adopting different algorithm mapping strategies on GPU architecture and multi-GPU framework, in order to demonstrate its high applicability and scalability. The experimental results we obtained encourage the usability of our approach in a large spectrum of applicative scenarios such as magnetic resonance imaging (MRI) or video sequence denoisingI documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.