In this research, I have integrated genetic optimization to recommend sustainable building solutions based on lifecycle cost ($) and
carbon impact (kgCO2eq). Compared to exhaustive sampling, this workflow locates optimal solutions more efficiently and intelligently, with
design diversity quantified as the third objective to optimize.

Genetic Optimization; Building Lifecycle Analysis; Design Diversity

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[4] Tseranidis, S., Brown, N. C., & Mueller, C. T. (2016). Data-driven approximation algorithms for rapid performance evaluation and optimization of civil structures. Automation in Construction, 72(April 2017), 279293. https://doi.org/10.1016/j.autcon.2016.02.002

[5] Hester, J., Gregory, J., & Kirchain, R. (2017). Sequential early-design guidance for residential single-family buildings using a probabilistic metamodel of energy consumption. Energy and Buildings, 134, 202211.

[6] Hester, J., Gregory, J., Ulm, F. J., & Kirchain, R. (2018). Building design-space exploration through quasi-optimization of life cycle impacts and costs. Building and Environment, 144(July), 3444. https://doi.org/10.1016/j.buildenv.2018.08.003

[7] Lobaccaro, G., Wiberg, A. H., Ceci, G., Manni, M., Lolli, N., & Berardi, U. (2018). Parametric design to minimize the embodied GHG

emissions in a ZEB. Energy and Buildings, 167, 106123.