FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W1998572781> ?p ?o ?g. }

• W1998572781 endingPage "288" @default.
• W1998572781 startingPage "281" @default.
• W1998572781 abstract "Abstract In Discrete Element Method (DEM) simulations, the most costly operation performed by the program in terms of CPU time is often the process of identifying which pairs of particles are potentially in contact. Program performance can especially be degraded when the relative size difference between the smallest and largest discrete elements is greater than a factor of 2 to 5. Recently, particle-based searches with a hierarchy of cell spaces were proposed to eliminate the size-dependence problem (Peters et al. (2009) [1] ), He et al. (2007) [2] . Both methods allowed the cell size to be based on the diameter of the smallest particles, and the methods were found to be effective. In this paper, the authors evaluate the performance of a related but simpler algorithm dubbed the ‘bounding box search method’. The bounding box method entails identifying all cells which any part of a target particle may occupy, listing the target particle as present in those cells, and searching for potential contacts over the same set of cells (the ‘bounding box’). Where the hierarchy methods improve performance by creating multiple cell spaces based on particle sizes, the bounding box method uses only a single cell space, but allows the cell size to be based on the smallest particles, rather than the largest. To evaluate the performance of the bounding box algorithm, timed simulations were performed on systems with varying numbers of particles and particle size distributions, and runtimes were compared to identical systems simulated using a so-called ‘basic’ search algorithm, which places a target particle in a single cell and searches over all neighboring cells. Results presented herein show the bounding box approach to yield improved performance relative to the simple search method for most systems, especially those with the largest numbers of particles and least uniform size distributions. The effect of selected cell size is also examined, and it is shown that cell sizes between one and two times the smallest particle diameter yielded the best performance." @default.
• W1998572781 created "2016-06-24" @default.
• W1998572781 creator A5013636663 @default.
• W1998572781 creator A5021523332 @default.
• W1998572781 date "2011-02-01" @default.
• W1998572781 modified "2023-10-14" @default.
• W1998572781 title "A bounding box search algorithm for DEM simulation" @default.
• W1998572781 cites W1996087839 @default.
• W1998572781 cites W2001045671 @default.
• W1998572781 cites W2015013584 @default.
• W1998572781 cites W2026516771 @default.
• W1998572781 cites W2036916709 @default.
• W1998572781 cites W2065769087 @default.
• W1998572781 cites W2082392251 @default.
• W1998572781 cites W2086378364 @default.
• W1998572781 cites W2165558283 @default.
• W1998572781 cites W2397641815 @default.
• W1998572781 doi "https://doi.org/10.1016/j.cpc.2010.09.008" @default.
• W1998572781 hasPublicationYear "2011" @default.
• W1998572781 type Work @default.
• W1998572781 sameAs 1998572781 @default.
• W1998572781 citedByCount "14" @default.
• W1998572781 countsByYear W19985727812012 @default.
• W1998572781 countsByYear W19985727812014 @default.
• W1998572781 countsByYear W19985727812015 @default.
• W1998572781 countsByYear W19985727812016 @default.
• W1998572781 countsByYear W19985727812017 @default.
• W1998572781 countsByYear W19985727812019 @default.
• W1998572781 countsByYear W19985727812020 @default.
• W1998572781 countsByYear W19985727812022 @default.
• W1998572781 countsByYear W19985727812023 @default.
• W1998572781 crossrefType "journal-article" @default.
• W1998572781 hasAuthorship W1998572781A5013636663 @default.
• W1998572781 hasAuthorship W1998572781A5021523332 @default.
• W1998572781 hasConcept C11413529 @default.
• W1998572781 hasConcept C115961682 @default.
• W1998572781 hasConcept C147037132 @default.
• W1998572781 hasConcept C154945302 @default.
• W1998572781 hasConcept C41008148 @default.
• W1998572781 hasConcept C63584917 @default.
• W1998572781 hasConceptScore W1998572781C11413529 @default.
• W1998572781 hasConceptScore W1998572781C115961682 @default.
• W1998572781 hasConceptScore W1998572781C147037132 @default.
• W1998572781 hasConceptScore W1998572781C154945302 @default.
• W1998572781 hasConceptScore W1998572781C41008148 @default.
• W1998572781 hasConceptScore W1998572781C63584917 @default.
• W1998572781 hasIssue "2" @default.
• W1998572781 hasLocation W19985727811 @default.
• W1998572781 hasOpenAccess W1998572781 @default.
• W1998572781 hasPrimaryLocation W19985727811 @default.
• W1998572781 hasRelatedWork W2387360586 @default.
• W1998572781 hasRelatedWork W2883297582 @default.
• W1998572781 hasRelatedWork W2952736415 @default.
• W1998572781 hasRelatedWork W2962677013 @default.
• W1998572781 hasRelatedWork W3036286480 @default.
• W1998572781 hasRelatedWork W3192357901 @default.
• W1998572781 hasRelatedWork W3205398323 @default.
• W1998572781 hasRelatedWork W3209723314 @default.
• W1998572781 hasRelatedWork W4237171675 @default.
• W1998572781 hasRelatedWork W4287027631 @default.
• W1998572781 hasVolume "182" @default.
• W1998572781 isParatext "false" @default.
• W1998572781 isRetracted "false" @default.
• W1998572781 magId "1998572781" @default.
• W1998572781 workType "article" @default.