Recent research has shown that ceiling geometry can greatly affect the illuminance levels and daylighting uniformity in indoor spaces. Usually, modeling and evaluating the daylighting performance of flat ceilings and light shelves can be done easily. However, with the increase of sophisticated and complex parametric forms of suspended ceilings, architects have been struggling to adequately assess their daylight performance. This is mainly due to the time and effort required to examine all parameters within the ceiling form. Additionally, most available architectural tools for examining parametric ceilings are based on the use of Genetic Algorithm (GA), which proves to be an efficient way to search for an optimal solution but lacks the ability of providing the designer with multiple sets of alternatives for better decision making. In response, this paper examines a workflow based on the use of the Pareto principle that has been developed in order to assess the ceiling parameters and variables. It then ranks them according to their performance in search for optimized configurations that allow architects and designers a trade-off in the early design stage. Then, the paper will introduce a parameters elimination method to decrease the time required for daylighting simulations when new parameters are added to a ceiling that has been analyzed.
ADVANCES IN BUILDING ENERGY RESEARCH
- Pareto Principle
- Performance-based Design
- Genetic Algorithm