Artificial Intelligence-Based Comfort Assessment and Simulation of Architectural Sound Environments

[1] Beccali, M., Strazzeri, V., Germanà, M.L., Melluso, V., & Galatioto, A. (2017). Vernacular and bioclimatic architecture and indoor thermal comfort implications in hot-humid climates: an overview. Renewable and Sustainable Energy Reviews, 1726-1736. Search in Google Scholar

[2] Buonomano, A., Forzano, C., Kalogirou, S. A., & Palombo, A. (2018). Building-faade integrated solar thermal collectors: energy-economic performance and indoor comfort simulation model of a water based prototype for heating, cooling, and dhw production. Renewable Energy, 137(JUL.), 20-36. Search in Google Scholar

[3] Bennacer, R., & Ma, X. (2023). Anisothermal flow dynamics in ventilated open space involved with indoor comfort. International Journal of Thermal Sciences. Search in Google Scholar

[4] Ahmed, A. Q., Gao, S., & Kareem, A. K. (2017). Energy saving and indoor thermal comfort evaluation using a novel local exhaust ventilation system for office rooms. Applied Thermal Engineering, 110, 821-834. Search in Google Scholar

[5] Alshdiefat, A. S. (2022). Effect of indoor environment on occupant air comfort and productivity in office buildings: a response surface analysis approach. Sustainability, 14. Search in Google Scholar

[6] Zhang, Xu, Ba, Meihui, Kang, & Jian, et al. (2018). Effect of soundscape dimensions on acoustic comfort in urban open public spaces. Applied Acoustics. Search in Google Scholar

[7] Livia Claudi, Arnesano, M., Chiariotti, P., Battista, G., & Revel, G. M. (2019). A soft-sensing approach for the evaluation of the acoustic comfort due to building envelope protection against external noise. Measurement. Search in Google Scholar

[8] Pijls, R., Galetzka, M., Groen, B. H., & Pruyn, A. T. H. (2019). Comfortable seating: the influence of seating comfort and acoustic comfort on customers’ experience of hospitality in a self-service restaurant. Applied Ergonomics, 81, 102902. Search in Google Scholar

[9] Efstathios, Margaritis, Jian, & Kang. (2017). Relationship between green space-related morphology and noise pollution. Ecological Indicators. Search in Google Scholar

[10] Choi, E., Bhandari, T. R., & Shrestha, N. (2022). Social inequality, noise pollution, and quality of life of slum dwellers in pokhara, nepal. Archives of environmental & occupational health(2), 77. Search in Google Scholar

[11] Paul, K. C., Haan, M., Mayeda, E. R., & Ritz, B. R. (2019). Ambient air pollution, noise, and late-life cognitive decline and dementia risk. Annual Review of Public Health, 40(1), 203-220. Search in Google Scholar

[12] WSZO?EK, & Tadeusz. (2017). Cumulative industrial noise impact on the environment. Archives of Acoustics. Search in Google Scholar

[13] Albert, D. G., & Decato, S. N. (2017). Acoustic and seismic ambient noise measurements in urban and rural areas. Applied Acoustics, 119(APR.), 135-143. Search in Google Scholar

[14] Xu, W., Tang, Y., Zhang, M., Qi, W., & Wang, W. (2020). Arbitrary shaped acoustic omnidirectional absorber based on transformation theory. International Journal of Modern Physics B, 2050111. Search in Google Scholar

[15] Gramez, A., & Boubenider, F. (2017). Acoustic comfort evaluation for a conference room: a case study. Applied Acoustics, 118, 39-49. Search in Google Scholar

[16] Elayouch, A., Addouche, M., & Khelif, A. (2018). Extensive tailorability of sound absorption using acoustic metamaterials. Journal of Applied Physics, 124(15), 155103.1-155103.7. Search in Google Scholar

[17] Rocca, M., Puccio, F. D., Forte, P., & Leccese, F. (2022). Acoustic comfort requirements and classifications: buildings vs. yachts. Ocean engineering(Jul.1), 255. Search in Google Scholar

[18] Domenighini, P., Belloni, E., & Buratti, C. (2023). Experimental subjective and objective analysis of speech intelligibility and acoustic comfort conditions in an unchanged xvii century italian church. Applied acoustics. Search in Google Scholar

[19] Lympany, S. V., James, M. M., Salton, A. R., Calton, M. F., & Pedersen, K. (2019). A geospatial model of the global ambient soundscape. The Journal of the Acoustical Society of America, 146(4), 2983-2983. Search in Google Scholar

[20] Mobley, F., Davis, B., Hall, J., & Moore, T. (2018). Decontamination of acoustic measurement with critical point noise detection. Applied Acoustics, 138, 156-162. Search in Google Scholar

[21] Claudi, LiviaArnesano, MarcoChiariotti, PaoloBattista, GianmarcoRevel, Gian Marco. (2019). A soft-sensing approach for the evaluation of the acoustic comfort due to building envelope protection against external noise. Measurement, 146. Search in Google Scholar

[22] Oquendo-Di Cosola, V., Olivieri, F., & Ruiz-García, L. (2022). A systematic review of the impact of green walls on urban comfort: temperature reduction and noise attenuation. Renewable and Sustainable Energy Reviews, 162. Search in Google Scholar

[23] Nering, K., Kowalska-Koczwara, A., & Stypua, K. (2020). Annoyance based vibro-acoustic comfort evaluation of as summation of stimuli annoyance in the context of human exposure to noise and vibration in buildings. Sustainability, 12. Search in Google Scholar