The process of external wall tile planning within BIM is time-consuming to be completed. It is due to numerous attributes that need to be created and filled. Therefore, this study creates an attributes creation system for BIM-based external wall tile planning using parametric design. First, this study established the tile database according to the Knowledge Base (KB) and transferred the KB into pattern-matching rules. Second, it developed a system for automatically input, label, and calculate wall tile layout through the connection between BIM and parametric design platform. Third, this research integrated the system with Optical Microscope Algorithm (OMA) to obtain the minimum percentage of truncated tiles. The developed system is completed through five modules, namely import tile database, create tile attributes, input wall tile data, label and calculate tile, and optimize truncated tiles percentage. Then, this study successfully tried the system in the case of an eight-story building. It decreased the truncated tiles percentage to 15.35% for fixed starting points and 15.17% for free starting points. The findings indicate that the system is applicable in external wall tile planning.

The process of external wall tile planning within BIM is time-consuming to be completed. It is due to numerous attributes that need to be created and filled. Therefore, this study creates an attributes creation system for BIM-based external wall tile planning using parametric design. First, this study established the tile database according to the Knowledge Base (KB) and transferred the KB into pattern-matching rules. Second, it developed a system for automatically input, label, and calculate wall tile layout through the connection between BIM and parametric design platform. Third, this research integrated the system with Optical Microscope Algorithm (OMA) to obtain the minimum percentage of truncated tiles. The developed system is completed through five modules, namely import tile database, create tile attributes, input wall tile data, label and calculate tile, and optimize truncated tiles percentage. Then, this study successfully tried the system in the case of an eight-story building. It decreased the truncated tiles percentage to 15.35% for fixed starting points and 15.17% for free starting points. The findings indicate that the system is applicable in external wall tile planning.

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