QUICK PROTOCOL FOR INTEGRATING THE ATTRIBUTE INFORMATION OF UNSTRUCTURED POINT CLOUD DATA INTO A SOLAR ENVELOPE SIMULATION

IF 0.7 4区艺术学 0 ARCHITECTURE

Journal of Green Building Pub Date : 2023-12-01 DOI:10.3992/jgb.18.4.3

M. Alkadri, Francesco De Luca, M. Turrin, Muhammad Rafif Cahyadi Agung

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引用次数: 0

Abstract

This study proposes a novel method of solar geometry by considering the potential application of point cloud data combined with the simulation of solar radiation. With the support of geometric and radiometric information stored in the point cloud such as position information (XYZ) color information (RGB), and reflection intensity (I), architects may compensate for missing information on the existing context during the simulation, especially due to the limited capacity of current 3D modelling sites. However, the dataset often comes in the format of unstructured point cloud data retrieved from merged data scans and as a result, the radiometric information is difficult to occupy due to multiple reference points. Through a 3D subtractive procedure, this study not only examines volumetric samples of the three-dimensional matrix that fulfills the criteria of solar envelopes but also finds the optimal values of the merged data scan for input of solar radiation. In this regard, simulation of solar radiation contributes to identifying the most and the least exposed areas to the sun in existing contexts. This provides information related to visible sun hours that can be used to perform ray tracing analysis between the proposed 3D plot and surrounding contexts. Our proposed method ultimately helps architects not only generate solar geometry based on real contextual settings but also to understand comprehensively the microclimate conditions of the design context.

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将非结构化点云数据的属性信息纳入太阳包层模拟的快速协议

考虑到点云数据与太阳辐射模拟相结合的潜在应用，提出了一种新的太阳几何方法。在点云中存储的几何和辐射信息(如位置信息(XYZ)、颜色信息(RGB)和反射强度(I))的支持下，建筑师可以在模拟过程中补偿现有环境中缺失的信息，特别是由于当前3D建模站点的容量有限。然而，数据集通常以合并数据扫描检索的非结构化点云数据的格式出现，由于存在多个参考点，因此难以占用辐射测量信息。通过三维减法程序，本研究不仅检查了满足太阳包层标准的三维矩阵的体积样本，而且还找到了太阳辐射输入的合并数据扫描的最佳值。在这方面，太阳辐射的模拟有助于确定在现有情况下太阳照射最多和最少的地区。这提供了与可见太阳时数相关的信息，可用于在拟议的3D图和周围环境之间执行光线追踪分析。我们提出的方法最终不仅可以帮助建筑师根据真实的环境设置生成太阳几何形状，还可以全面了解设计环境的小气候条件。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Green Building ARCHITECTURE-

CiteScore

2.30

自引率

7.10%

发文量

期刊介绍： The purpose of the Journal of Green Building is to present the very best peer-reviewed research in green building design, construction, engineering, technological innovation, facilities management, building information modeling, and community and urban planning. The Research section of the Journal of Green Building publishes peer-reviewed articles in the fields of engineering, architecture, construction, construction management, building science, facilities management, landscape architecture, interior design, urban and community planning, and all disciplines related to the built environment. In addition, the Journal of Green Building offers the following sections: Industry Corner that offers applied articles of successfully completed sustainable buildings and landscapes; New Directions in Teaching and Research that offers guidance from teachers and researchers on incorporating innovative sustainable learning into the curriculum or the likely directions of future research; and Campus Sustainability that offers articles from programs dedicated to greening the university campus.