Abstract—The paper presents two approaches in parallel modeling of vascular system development in internal organs. In the first approach, new parts of tissue are distributed among processors and each processor is responsible for perfusing its assigned parts of tissue to all vascular trees. Communication between processors is accomplished by passing messages and therefore this algorithm is perfectly suited for distributed memory architectures. The second approach is designed for shared memory machines. It parallelizes the perfusion process during which individual processing units perform calculations concerning different vascular trees. The experimental results, performed on a computing cluster and multi-core machines, show that both algorit...
Abstract—The authors ’ main interest was to develop vascular solid tumour growth model, implement ef...
Biological systems are characterised by a large number of interacting entities whose dynamics is des...
1. Full-scale simulations of the virtual physiological human (VPH) will require significant advances...
Abstract—This paper presents two approaches in parallel modeling of vascular system development in i...
International audienceThis paper presents two approaches in parallel modeling of vascular system dev...
Abstract. In this paper, an improved parallel algorithm of vascular network modeling is presented. T...
International audienceIn this paper, an improved parallel algorithm of vascular network modeling is ...
Abstract. The paper presents modeling of the vascular system in a parallel environment. The aim of t...
Abstract. This paper presents a two-level parallel algorithm of vascu-lar network development. At th...
Modeling of fluid mechanics for the vascular system is of great value as a source of knowledge about...
AbstractModeling of fluid mechanics for the vascular system is of great value as a source of knowled...
In this study, parallel computation of blood flow in a 1-D model of human arterial network has been ...
The human body contains approximately 20 billion blood vessels, which transport nutrients, oxygen, i...
Fast algorithms for simulating mathematical models of coupled blood-tissue transport and metabolism ...
The main objective of this study is to visualize the brain tumors’ growth in three-dimensional and...
Abstract—The authors ’ main interest was to develop vascular solid tumour growth model, implement ef...
Biological systems are characterised by a large number of interacting entities whose dynamics is des...
1. Full-scale simulations of the virtual physiological human (VPH) will require significant advances...
Abstract—This paper presents two approaches in parallel modeling of vascular system development in i...
International audienceThis paper presents two approaches in parallel modeling of vascular system dev...
Abstract. In this paper, an improved parallel algorithm of vascular network modeling is presented. T...
International audienceIn this paper, an improved parallel algorithm of vascular network modeling is ...
Abstract. The paper presents modeling of the vascular system in a parallel environment. The aim of t...
Abstract. This paper presents a two-level parallel algorithm of vascu-lar network development. At th...
Modeling of fluid mechanics for the vascular system is of great value as a source of knowledge about...
AbstractModeling of fluid mechanics for the vascular system is of great value as a source of knowled...
In this study, parallel computation of blood flow in a 1-D model of human arterial network has been ...
The human body contains approximately 20 billion blood vessels, which transport nutrients, oxygen, i...
Fast algorithms for simulating mathematical models of coupled blood-tissue transport and metabolism ...
The main objective of this study is to visualize the brain tumors’ growth in three-dimensional and...
Abstract—The authors ’ main interest was to develop vascular solid tumour growth model, implement ef...
Biological systems are characterised by a large number of interacting entities whose dynamics is des...
1. Full-scale simulations of the virtual physiological human (VPH) will require significant advances...