Computational Design and Parametric Analysis of a Fractal-Based Folded-Smooth (F-S) Hybrid Shell Structure

Iasef Md Rian

doi:10.1007/s00004-024-00806-8

Computational Design and Parametric Analysis of a Fractal-Based Folded-Smooth (F-S) Hybrid Shell Structure

Iasef Md Rian^*

^*Corresponding author for this work

Department of Architecture

Research output: Contribution to journal › Article › peer-review

Abstract

This paper investigates the architectural and structural potential of folded-smooth (F-S) hybrid shell structures, modeled using the Takagi-Landsberg (TL) function and Iterated Function Systems (IFS) to achieve smooth transitions between folded and smooth surfaces. Using a hyperbolic paraboloid (hypar) profile, the study evaluates the distinct structural behaviors of F-S configurations. Finite element analysis shows that lateral F-S shells with folded ends at the ground achieve comparable stability to smooth hypars, while longitudinal F-S shells with unsupported ends show structural weaknesses, particularly at flying edges. Despite construction challenges, the study demonstrates that F-S shells combine structural robustness and aesthetic flexibility, advancing design possibilities in hybrid architectural forms.

Original language	English
Journal	Nexus Network Journal
DOIs	https://doi.org/10.1007/s00004-024-00806-8
Publication status	Accepted/In press - 2025

Keywords

Folded-Smooth (F-S) Shells
Hyperbolic paraboloid (hypar)
Iterated Function Systems (IFS)
Structural analysis
Takagi-Landsberg (TL) function

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10.1007/s00004-024-00806-8

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title = "Computational Design and Parametric Analysis of a Fractal-Based Folded-Smooth (F-S) Hybrid Shell Structure",

abstract = "This paper investigates the architectural and structural potential of folded-smooth (F-S) hybrid shell structures, modeled using the Takagi-Landsberg (TL) function and Iterated Function Systems (IFS) to achieve smooth transitions between folded and smooth surfaces. Using a hyperbolic paraboloid (hypar) profile, the study evaluates the distinct structural behaviors of F-S configurations. Finite element analysis shows that lateral F-S shells with folded ends at the ground achieve comparable stability to smooth hypars, while longitudinal F-S shells with unsupported ends show structural weaknesses, particularly at flying edges. Despite construction challenges, the study demonstrates that F-S shells combine structural robustness and aesthetic flexibility, advancing design possibilities in hybrid architectural forms.",

keywords = "Folded-Smooth (F-S) Shells, Hyperbolic paraboloid (hypar), Iterated Function Systems (IFS), Structural analysis, Takagi-Landsberg (TL) function",

author = "Rian, {Iasef Md}",

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AU - Rian, Iasef Md

N1 - Publisher Copyright: © The Author(s), under exclusive licence to Springer Nature Switzerland AG 2024.

PY - 2025

Y1 - 2025

N2 - This paper investigates the architectural and structural potential of folded-smooth (F-S) hybrid shell structures, modeled using the Takagi-Landsberg (TL) function and Iterated Function Systems (IFS) to achieve smooth transitions between folded and smooth surfaces. Using a hyperbolic paraboloid (hypar) profile, the study evaluates the distinct structural behaviors of F-S configurations. Finite element analysis shows that lateral F-S shells with folded ends at the ground achieve comparable stability to smooth hypars, while longitudinal F-S shells with unsupported ends show structural weaknesses, particularly at flying edges. Despite construction challenges, the study demonstrates that F-S shells combine structural robustness and aesthetic flexibility, advancing design possibilities in hybrid architectural forms.

AB - This paper investigates the architectural and structural potential of folded-smooth (F-S) hybrid shell structures, modeled using the Takagi-Landsberg (TL) function and Iterated Function Systems (IFS) to achieve smooth transitions between folded and smooth surfaces. Using a hyperbolic paraboloid (hypar) profile, the study evaluates the distinct structural behaviors of F-S configurations. Finite element analysis shows that lateral F-S shells with folded ends at the ground achieve comparable stability to smooth hypars, while longitudinal F-S shells with unsupported ends show structural weaknesses, particularly at flying edges. Despite construction challenges, the study demonstrates that F-S shells combine structural robustness and aesthetic flexibility, advancing design possibilities in hybrid architectural forms.

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KW - Hyperbolic paraboloid (hypar)

KW - Iterated Function Systems (IFS)

KW - Structural analysis

KW - Takagi-Landsberg (TL) function

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JO - Nexus Network Journal

JF - Nexus Network Journal

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Computational Design and Parametric Analysis of a Fractal-Based Folded-Smooth (F-S) Hybrid Shell Structure

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