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Tanic, M., Stankovic, D., Kostic, I., Nikolic, V., Petrovic, M., Kondic, S. (2016). Pedagogical Implications of the Concepts of the Classroom in Europe: The Key Historical Layers, Tendencies and Influential Lines. Journal of Asian Architecture and Building Engineering, 15(1), 1–8.10.3130/jaabe.15.1Search in Google Scholar
Ito, K., Murakami, S. (2010). Cost-effectiveness Analysis of Improved Indoor Temperature and Ventilation Conditions in School Buildings. Journal of Asian Architecture and Building Engineering, 9(2), 523–529.10.3130/jaabe.9.523Search in Google Scholar
Kielb, C., Lin, S., Muscatiello, N., Hord, W., Rogers- Harrington, J., Healy, J. (2014). Building-related health symptoms and classroom indoor air quality: a survey of school teachers in New York State. Indoor Air, 25(4), 371–380.10.1111/ina.12154Search in Google Scholar
Agarwal, N., Shiva Nagendra, S.M. (2016). Modelling of particulate matters distribution inside the multilevel urban classrooms in tropical climate for exposure assessment. Build. Environ., 102, 73–82.10.1016/j.buildenv.2016.03.015Search in Google Scholar
Krüger, E.L., Zannin, P.H.T. (2004). Acoustic, thermal and luminous comfort in classrooms. Build. Environ., 39(9), 1055–1063.10.1016/j.buildenv.2004.01.030Search in Google Scholar
Nowoświat, A., Olechowska, M. (2016). Investigation Studies on the Application of Reverberation Time. Arch. Acoust., 41(1), 15–26.10.1515/aoa-2016-0002Search in Google Scholar
Houtgast, T., Steeneken, H.J.M. (1973). The Modulation Transfer Function in room acoustics as a predictor of speech intelligibility. Acoustica, 28, 66–73.10.1121/1.1913632Search in Google Scholar
Olechowska, M., Ślusarek, J. (2016). Analysis of selected methods used for the reverberation time estimation. Architecture Civil Engineering Environment 9(4), 79–87.10.21307/acee-2016-054Search in Google Scholar
Nowoświat, A., Olechowska, M. (2016). Fast estimation of speech transmission index using the reverberation time. Appl. Acoust., 102, 55–61.10.1016/j.apacoust.2015.09.001Search in Google Scholar
Weinzierl, S., Vorländer, M. (2015). Room acoustical parameters as predictors of room acoustical impression: What do we know and what would we like to know? Acoust. Aust., 43(1), 41–48.10.1007/s40857-015-0007-6Search in Google Scholar
Hodgson, M. (1999). Experimental investigation of the acoustical characteristics of University classrooms. J. Acoust. Soc. Am. 106(4), 1810–1819.10.1121/1.427931Search in Google Scholar
Bistafa, S.R., Bradley, J.S. (2000). Predicting reverberation times in a simulated classroom. J. Acoust. Soc. Am., 108, 1721–1731.10.1121/1.1310191Search in Google Scholar
Mikulski, W., Radosz, J. (2011). Acoustics of Classrooms in Primary Schools – Results of the Reverberation Time and Speech Transmission Index Assessments in Selected Buildings. Arch. Acoust., 36(4), 777–793.10.2478/v10168-011-0052-6Search in Google Scholar
Nowoświat, A., Bochen, J., Dulak, L., Żuchowski, R. (2016). Investigation studies involving sound absorbing parameters of roadside screen panels subjected to aging in simulated conditions. Appl. Acoust. 111, 8–15.10.1016/j.apacoust.2016.04.001Search in Google Scholar
Tomiku, R., Otsuru, T., Takahashi, Y. (2002). Finite Element Sound Field Analysis of Diffuseness in Reverberation Rooms. Journal of Asian Architecture and Building Engineering, 1(2), 33–39.10.3130/jaabe.1.2_33Search in Google Scholar
Nowoświat, A., Olechowska, M., Ślusarek, J. (2016). Prediction of reverberation time using the residual minimization method. Appl. Acoust., 106, 42–50.10.1016/j.apacoust.2015.12.024Search in Google Scholar
Cabrera, D., Xun, J., Guski, M. (2016). Calculating Reverberation Time from Impulse Responses: A Comparison of Software Implementations. Acoust. Aust., 44, 369–378.10.1007/s40857-016-0055-6Search in Google Scholar
Rizzo, F., Zazzini, P. (2016). Improving the acoustical properties of an elliptical plan space with a cable net membrane roof. Acoust. Aust. 44(3), 449–456.10.1007/s40857-016-0072-5Search in Google Scholar
Batubara, M., Tanimura, H., Asikhia, M.O., Toshimori, A. (2002). An Application of the AHP to Urban Residential Upgrading in Jakarta. Journal of Asian Architecture and Building Engineering, 1(1), 253–259.10.3130/jaabe.1.253Search in Google Scholar
Liu, J., Yao, R., McCloy, R. (2012). A method to weight three categories of adaptive thermal comfort. Energy and Buildings, 47, 312–320.10.1016/j.enbuild.2011.12.007Search in Google Scholar
Chung, H.J., Kim, S., Yang, J. (2017). Extraction and Analysis of Technical Management Factors for Passive Houses in Korea. Journal of Asian Architecture and Building Engineering, 16(1), 75–82.10.3130/jaabe.16.75Search in Google Scholar
Madbouly, A.I., Noaman, A.Y., Ragab, A.H.M., Khedra, A.M., Fayoumi, A.G. (2016). Assessment model of classroom acoustics criteria for enhancing speech intelligibility and learning quality. Appl. Acoust., 114, 147–158.10.1016/j.apacoust.2016.07.018Search in Google Scholar
ISO 3382-1:2009. Acoustics – Measurement of room acoustic parameters – Part 1: Performance spaces.Search in Google Scholar
ISO 3382-2:2008. Acoustics – Measurement of room acoustic parameters – Part 2: Reverberation time in ordinary rooms.Search in Google Scholar
Plomp, R., Steeneken, H.J.M., Hotgast, T. (1980). Predicting Speech Intelligibility in Rooms from the Modulation Transfer Function II. Mirror image computer model applied rectangular rooms. Acustica, 46, 74.Search in Google Scholar
Houtgast, T., Steeneken, H.J.M. (1984). A Multi – Language Evaluation of the RASTI – Method for Estimating Speech Intelligibility in Auditoria. Acustica, 54(4), 185–199.Search in Google Scholar
Houtgast, T., Steeneken, H.J.M. (1985). A review of the MTF concept in room acoustics and its use for estimating speech intelligibility in auditoria. J. Acoust. Soc. Am., 77(3), 1069–1077.10.1121/1.392224Search in Google Scholar
Passero, C.R.M., Zannin, P.H.T. (2010). Statistical comparison of reverberation times measured by the integrated impulse response and interrupted noise methods, computationally simulated with ODEON software, and calculated by Sabine, Eyring and Arau- Puchades’ formulas. Appl. Acoust., 71, 1204–1210.10.1016/j.apacoust.2010.07.003Search in Google Scholar
Saaty, T.L. (1977). A scaling method for priorities in hierarchical structures. Mathematical Psychology, 15(3), 234–281.10.1016/0022-2496(77)90033-5Search in Google Scholar
Nowoświat, A., Leszczyńska, M. (2016). Application of hierarchical analysis method to design the structural partitions with different material and structural solutions for window glazing. Architecture Civil Engineering Environment, 9(3), 95–104.10.21307/acee-2016-038Search in Google Scholar
PN-B-02151-4. Akustyka budowlana. Ochrona przed hałasem w budynkach. Cześć 4. Wymagania dotyczące warunków pogłosowych i zrozumiałości mowy w pomieszczeniach. (ang. Building acoustics. Protection against noise in buildings. Part 4. Requirements for reverberation and speech intelligibility in rooms).Search in Google Scholar
Nowoświat A., Olechowska M. (2017). Estimation of reverberation time in classrooms, using the Residual Minimization Method. Arch. Acoust., 42(4), 609–617.10.1515/aoa-2017-0065Search in Google Scholar