Daylighting design via Monte Carlo with a corresponding scientific visualization

Daylighting design via Monte Carlo with a corresponding scientific visualization

A brief history of Monte Carlo methods is presented, with emphasis on uses in engineering. An overview of daylighting design is then presented, exploring both quantity and quality of light. Various strategies for achieving effectively daylit enclosures are examined, with heavy emphasis upon computat...

Ausführliche Beschreibung

Gespeichert in:
Bibliographische Detailangaben
Hauptverfasser: Burns, P. J., Schweitzer, R., McHugh, J., Zeeb, C.
Format: Tagungsbericht
Sprache:eng
Schlagworte:
Ambient intelligence
Applied computing > Physical sciences and engineering > Engineering
Computer systems organization > Architectures
Computer systems organization > Architectures > Parallel architectures > Multiple instruction, multiple data
Computing methodologies > Modeling and simulation > Simulation types and techniques
Convergence
Daylighting
History
Mathematics of computing > Probability and statistics > Probabilistic reasoning algorithms > Markov-chain Monte Carlo methods
Mathematics of computing > Probability and statistics > Probabilistic reasoning algorithms > Sequential Monte Carlo methods
Mechanical engineering
Monte Carlo methods
Network address translation
Testing
Theory of computation > Randomness, geometry and discrete structures
Theory of computation > Randomness, geometry and discrete structures > Computational geometry
Visualization
Online-Zugang:Volltext bestellen
Tags: Tag hinzufügen
Keine Tags, Fügen Sie den ersten Tag hinzu!
Beschreibung
Zusammenfassung:A brief history of Monte Carlo methods is presented, with emphasis on uses in engineering. An overview of daylighting design is then presented, exploring both quantity and quality of light. Various strategies for achieving effectively daylit enclosures are examined, with heavy emphasis upon computation. Monte Carlo methods are the only ones which are sufficiently robust to handle specular surfaces and properties which vary with incident angle (such as for glass). A general purpose computer code, DAY3D, is developed and applied to the calculation of luminous intensities in general enclosures. Due to the requirement for huge computing resources, an architectural study of photon tracing on a Cray Y/MP and a CM-2 is performed, illustrating the promise of a small CM-2 architecture for this problem. Various strategies for visualizing both field results and the discrete Monte Carlo processes are explored.
ISSN:1063-9535
DOI:10.1145/169627.169721