9. Evacuation simulation using Hybrid Space Discretisation and Application to Large Underground Rail Tunnel Station
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N Chooramun
Abstract
In all evacuation simulation tools, the space through which agents navigate and interact is represented by one the following methods, namely Coarse regions, Fine nodes and Continuous regions. Each of the spatial representation methods has its benefits and limitations. For instance, the Coarse approach allows simulations to be processed very rapidly, but is unable to represent the interactions of the agents from an individual perspective; the Continuous approach provides a detailed representation of agent movement and interaction but suffers from relatively poor computational performance. The Fine nodal approach presents a compromise between the Continuous and Coarse approaches such that it allows agent interaction to be modelled while providing good computational performance. Our approach for representing space in an evacuation simulation tool differs such that it allows evacuation simulations to be run using a combination of Coarse regions, Fine nodes and Continuous regions. This approach, which we call Hybrid Spatial Discretisation (HSD), is implemented within the buildingEXODUS evacuation simulation software. The HSD incorporates the benefits of each of the spatial representation methods whilst providing an optimal environment for representing agent movement and interaction. In this work, we demonstrate the effectiveness of the HSD through its application to a moderately large case comprising of an underground rail tunnel station with a population of 2,000 agents.
Abstract
In all evacuation simulation tools, the space through which agents navigate and interact is represented by one the following methods, namely Coarse regions, Fine nodes and Continuous regions. Each of the spatial representation methods has its benefits and limitations. For instance, the Coarse approach allows simulations to be processed very rapidly, but is unable to represent the interactions of the agents from an individual perspective; the Continuous approach provides a detailed representation of agent movement and interaction but suffers from relatively poor computational performance. The Fine nodal approach presents a compromise between the Continuous and Coarse approaches such that it allows agent interaction to be modelled while providing good computational performance. Our approach for representing space in an evacuation simulation tool differs such that it allows evacuation simulations to be run using a combination of Coarse regions, Fine nodes and Continuous regions. This approach, which we call Hybrid Spatial Discretisation (HSD), is implemented within the buildingEXODUS evacuation simulation software. The HSD incorporates the benefits of each of the spatial representation methods whilst providing an optimal environment for representing agent movement and interaction. In this work, we demonstrate the effectiveness of the HSD through its application to a moderately large case comprising of an underground rail tunnel station with a population of 2,000 agents.
Kapitel in diesem Buch
- Frontmatter i
- Preface of the Book of Proceedings of the Virtual Conference on Computational Science (VCCS-2016) v
- Contents vii
- List of contributing authors xi
- 1. Addressing the challenges of standalone multi-core simulations in molecular dynamics 1
- 2. Optical and magnetic properties of free-standing silicene, germanene and T-graphene system 23
- 3. Theoretical study of the electronic states of newly detected dications. Case of MgS2+ AND SiN2+ 71
- 4. Analytical Solution of Pantograph Equation with Incommensurate Delay 93
- 5. Computational chemistry applied to vibrational spectroscopy: A tool for characterization of nucleic acid bases and some of their 5-substituted derivatives 117
- 6. Mechanism of nucleophilic substitution reactions of 4-(4’-nitro)phenylnitrobenzofurazan ether with aniline in acetonitrile 153
- 7. Computational methods in preformulation study for pharmaceutical solid dosage forms of therapeutic proteins 163
- 8. Computational Investigation of Cationic, Anionic and Neutral Ag2AuN (N = 1–7) Nanoalloy Clusters 173
- 9. Evacuation simulation using Hybrid Space Discretisation and Application to Large Underground Rail Tunnel Station 191
- 10. DFT study of anthocyanidin and anthocyanin pigments for Dye-Sensitized Solar Cells: Electron injecting from the excited states and adsorption onto TiO2 (anatase) surface 205
- 11. Elemental Two-Dimensional Materials Beyond Graphene 219
- Index 229
Kapitel in diesem Buch
- Frontmatter i
- Preface of the Book of Proceedings of the Virtual Conference on Computational Science (VCCS-2016) v
- Contents vii
- List of contributing authors xi
- 1. Addressing the challenges of standalone multi-core simulations in molecular dynamics 1
- 2. Optical and magnetic properties of free-standing silicene, germanene and T-graphene system 23
- 3. Theoretical study of the electronic states of newly detected dications. Case of MgS2+ AND SiN2+ 71
- 4. Analytical Solution of Pantograph Equation with Incommensurate Delay 93
- 5. Computational chemistry applied to vibrational spectroscopy: A tool for characterization of nucleic acid bases and some of their 5-substituted derivatives 117
- 6. Mechanism of nucleophilic substitution reactions of 4-(4’-nitro)phenylnitrobenzofurazan ether with aniline in acetonitrile 153
- 7. Computational methods in preformulation study for pharmaceutical solid dosage forms of therapeutic proteins 163
- 8. Computational Investigation of Cationic, Anionic and Neutral Ag2AuN (N = 1–7) Nanoalloy Clusters 173
- 9. Evacuation simulation using Hybrid Space Discretisation and Application to Large Underground Rail Tunnel Station 191
- 10. DFT study of anthocyanidin and anthocyanin pigments for Dye-Sensitized Solar Cells: Electron injecting from the excited states and adsorption onto TiO2 (anatase) surface 205
- 11. Elemental Two-Dimensional Materials Beyond Graphene 219
- Index 229
