Structural optimization of 3D masonry buildings
ACM Transactions on Graphics (TOG), 2012•dl.acm.org
In the design of buildings, structural analysis is traditionally performed after the aesthetic
design has been determined and has little influence on the overall form. In contrast, this
paper presents an approach to guide the form towards a shape that is more structurally
sound. Our work is centered on the study of how variations of the geometry might improve
structural stability. We define a new measure of structural soundness for masonry buildings
as well as cables, and derive its closed-form derivative with respect to the displacement of …
design has been determined and has little influence on the overall form. In contrast, this
paper presents an approach to guide the form towards a shape that is more structurally
sound. Our work is centered on the study of how variations of the geometry might improve
structural stability. We define a new measure of structural soundness for masonry buildings
as well as cables, and derive its closed-form derivative with respect to the displacement of …
In the design of buildings, structural analysis is traditionally performed after the aesthetic design has been determined and has little influence on the overall form. In contrast, this paper presents an approach to guide the form towards a shape that is more structurally sound. Our work is centered on the study of how variations of the geometry might improve structural stability. We define a new measure of structural soundness for masonry buildings as well as cables, and derive its closed-form derivative with respect to the displacement of all the vertices describing the geometry. We start with a gradient descent tool which displaces each vertex along the gradient. We then introduce displacement operators, imposing constraints such as the preservation of orientation or thickness; or setting additional objectives such as volume minimization.
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