Plausible layout generation using machine learning, evolutionary optimisation and parametric methods

Marcinkeviciute, Daiva and Jabi, Wassim ORCID: https://orcid.org/0000-0002-2594-9568 2023. Plausible layout generation using machine learning, evolutionary optimisation and parametric methods. Presented at: 6th International Symposium on Formal Methods in Architecture (6FMA), 24-28 May 2022. Published in: Mora, Plácido Lizancos, Viana, David Leite, Morais, Franklim and Vaz, Jorge Vieira eds. Formal Methods in Architecture. FMA 2022. Digital Innovations in Architecture, Engineering and Construction. Singapore: Springer, pp. 251-268. 10.1007/978-981-99-2217-8_14 Item availability restricted.

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Abstract

Testing the preliminary design of a building is usually carried out to ensure that the requirements for its programme, space sizes, adjacencies, travel distances and access to daylight are satisfactorily met. Increasingly, this task is being implemented through automated plan layout generation tools. However, these tools struggle to create realistic and functional floor plans. In this paper, our aim is to generate plausible floor plans with fully functional circulation systems by combining Machine Learning (ML), evolutionary optimisation and parametric methods. We focused on generating buildings with functioning circulation, consisting of primary circulation with building entrances, horizontal and vertical connections and secondary circulation that connects all the rooms. We started by analysing school buildings, as a test case scenario, which showed that their zoning, circulation and topological relationships consistently follow design patterns. This enabled us to specify algorithmic rules for room placement. The floor plans also allowed us to generate the dataset needed to train a neural network and a decision tree. To achieve this, we traced the overall zones (functional and circulation spaces) of the ground floor layout and encoded it with its main features such as its area-to-perimeter ratio and the shape of its convex hull. We also varied the geometry of the layout without modifying its topology to add more training test cases for the neural network. Once the neural network and decision tree have been trained, our implementation proceeded in three main phases. First, the user inputs the approximate building shape using a simple closed curve. Selecting either the trained neural network or the decision tree, the user is presented with a matching building layout from a gallery which is geometrically transformed to closely fit the user’s sketch. Second, the spatial program is packed into the overall layout parametrically, using an algorithm based on the aforementioned set of rules. Finally, three fitness criteria (adjacencies, travel distances and daylight) are measured and optimised using an evolutionary solver. The result is a novel and optimised plausible floor plan with a functional circulation system. While the current workflow is designed to generate only the ground floor, we plan to expand it to generate multi-storey buildings. Our analysis has found that extracting design patterns, matching sketches using ML and optimising the result using an evolutionary solver is significantly more efficient than manual processes. The paper concludes with a discussion of the potential of integrating artificial intelligence in the early phases of design and the need to share standardised and richer building data beyond architectural projection drawings.

Item Type:	Conference or Workshop Item (Paper)
Date Type:	Published Online
Status:	Published
Schools:	Architecture
Publisher:	Springer
ISBN:	9789819922161
Date of First Compliant Deposit:	9 August 2023
Last Modified:	14 Aug 2023 14:15
URI:	https://orca.cardiff.ac.uk/id/eprint/161527

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