Issue
Acta Acust.
Volume 10, 2026
Topical Issue - Development of European Acoustics in 20th Century
Article Number 41
Number of page(s) 9
DOI https://doi.org/10.1051/aacus/2026044
Published online 12 June 2026
  1. I. Malecki: Building Acoustics. Warszawa, 1949. (in Polish) [Google Scholar]
  2. J. Sadowski, L. Wodziński: Room Acoustics. Wydawnictwa Komunikacyjne, Warszawa, 1960. (in Polish) [Google Scholar]
  3. J. Sadowski: Acoustics: Sound Protection of Buildings. Biuro Studiów i Projektów Typowych Budownictwa Przemysłowego, Warszawa, 1965. (in Polish) [Google Scholar]
  4. R. Rogiński, J. Sadowski: Noise Control in Transportation and Industry Warszawa, Wydawnictwa Komunikacji i Laczności, 1965. (in Polish) [Google Scholar]
  5. J. Sadowski: Acoustics in Urban Planning, Architecture and Construction. Warszawa, Arkady, 1971. (in Polish) [Google Scholar]
  6. J. Sadowski: Basics of Urban Acoustics. Warszawa, Arkady, 1982. (in Polish) [Google Scholar]
  7. M. Stawicka-Wałkowska: The Acoustic Factor in Urban Design. Instytut Techniki Budowlanej, Warszawa, 1988. (in Polish) [Google Scholar]
  8. M. Stawicka-Wałkowska, B. Rudno-Rudzińska: Shaping Urban Interiors as a form of Protection Against External Noise. Prace naukowe ITB. Wydawnictwo ITB Warszawa, 2000. (in Polish) [Google Scholar]
  9. J. Sadowski: Problémes d’isolation acoustique dans la construction industrialisée d’habitations. Building Science 1, 3 (1966) 203–235. [Google Scholar]
  10. J. Sadowski: Influence de la structure du bâtiment sur les qualités acoustiques des parois séparatrices entre lodgements. Building Science 4, 3 (1969) 159–171. [Google Scholar]
  11. J. Sadowski, K. Czyżewski, P. Tomczyk: Database 2000 containing information on acoustic properties of the materials, goods and structures designed to protect from noise and vibration, in: Noise Control’01: 12th International Conference Proceedings, Kielce, 2001, pp. 277–284. [Google Scholar]
  12. A. Izewska, K. Czyzewski: Uncertainty of measurement of sound absorption coefficient in reveberation room. Prace Instytutu Techniki Budowlanej 157, 1 (2011) 3–13. [Google Scholar]
  13. E. Nowicka, E. Szewczak: Indoor sound pressure level from service equipment in buildings: influence of testing methods on measurement results. Archives of Acoustics 46, 3 (2021) 547–559. [Google Scholar]
  14. M. Niemas: New measurement stations in the accredited Acoustic Laboratory of the ITB Research Laboratories Complex. Prace Instytutu Techniki Budowlanej 32, 3 (2003) 43–57. (in Polish) [Google Scholar]
  15. P. Tomczyk: Measuring station for testing the dynamic stiffness of elastic materials used in floating floors. Prace Instytutu Techniki Budowlanej 31, 1 (2002) 29–38. (in Polish) [Google Scholar]
  16. P. Tomczyk, M. Niemas: A new test stand for determining the resistance of air flow through porous materials used for insulation and acoustic adaptation. Prace Instytutu Techniki Budowlanej 31, 1 (2002) 13–27. (in Polish) [Google Scholar]
  17. J. Sadowski: Progress in research in the field of urban acoustics on the example of Warsaw. Archiwum Akustyki 5, 1, (1970) 21–52. (in Polish) [Google Scholar]
  18. B. Szudrowicz, A. Izewska: Simplified evaluation of flanking transmission based on the mean mass and mean area of flanking elements, in: Meeting of CIB W-51 Committee Acoustics: Proc. Warsaw, 1994, pp. 140–155. [Google Scholar]
  19. B. Szudrowicz, A. Izewska, J. Sadowski: Flankinng transmission in building with multilayer partitions, in: INTER-NOISE and NOISE-CON Congress and Conference Proceedings. Vol. 1994. Institute of Noise Control Engineering, 1994, pp. 1575–1578. [Google Scholar]
  20. B. Szudrowicz, A. Izewska: Simplified evaluation of flanking transmission based on the mean mass and mean area of flanking elements. Applied Acoustics 46, 3 (1995) 307–319. [Google Scholar]
  21. J. Nurzynski: The vision of building industry transformation outlined within ManuBuild integrated Project. Prace Instytutu Techniki Budowlanej 40, 2 (2011) 27–38. [Google Scholar]
  22. E. Nowicka: Nanomaterials and nanotechnology as a new solution for lightweight façade elements, in: VII FORUM ACUSTICUM, Kraków, joined with 61st Open Seminar on Acoustics, 2014. [Google Scholar]
  23. B. Pietruszka, E. Nowicka: The new concept of building components based on eco-innovative materials, in: VII FORUM ACUSTICUM, Kraków, joined with 61st Open Seminar on Acoustics, 2014. [Google Scholar]
  24. B. Szudrowicz: Application of the model method to test the acoustic properties of building partitions. Biuletyn Informacja / Centralny Ośrodek Informacji Budownictwa 11, 2 (1973) 13–19. (in Polish) [Google Scholar]
  25. B. Szudrowicz: Acoustic properties of massive reinforced concrete ceilings. Inżynieria i Budownictwo 42, 7, 8 (1985) 242–247. (in Polish) [Google Scholar]
  26. B. Szudrowicz: Assessment of acoustic properties of walls made of hollow ceramic elements. Prace Instytutu Techniki Budowlanej 29, 4 (2000) 21–30. (in Polish) [Google Scholar]
  27. I. Zuchowicz-Wodnikowska: The comparision of the reverberation time measured in halls with the use of natural and artificial sound sources. Archiwum Akustyki 3, 2 (1968) 201–206. [Google Scholar]
  28. M. Mirowska, I. Zuchowicz: Domestic sound-absorbing materials, products and systems. Centralny Ośrodek Badawczo-Rozwojowy Przemysłu Izolacji Budowlanej, Katowice, 1974. (in Polish) [Google Scholar]
  29. M. Mirowska, J. Szczecinska, I. Zuchowicz: Technical and Acoustic Parameters of Sound-absorbing Materials, Products and Systems Manufactured in Poland. Instytut Techniki Budowlanej, Warszawa, 1981. [Google Scholar]
  30. B. Szudrowicz, Some issues of window acoustic insulation. Przeglad Budowlany 41, 12 (1969) 625–632. (in Polish) [Google Scholar]
  31. J. Sadowski, B. Szudrowicz: The influence of materials and structures on the acoustic climate of apartments and its impact on the health of residents. Informacja o Budownictwie Naukowa-Techniczna-Ekonomiczna 5 (1975) 1–2. (in Polish) [Google Scholar]
  32. B. Szudrowicz: Acoustic problems associated with the use of air vents in rooms. Informacja INSTAL 4 (1995) 11–12. (in Polish) [Google Scholar]
  33. J. Nurzynski: The acoustic performance of circular openings and wall-mounted vents. Applied Acoustics 162 (2020) 107200. [Google Scholar]
  34. J. Nurzynski: Empirical study on the sound insulation of simple slot ventilators. Building Acoustics 13, 3 (2006) 223–241. [Google Scholar]
  35. A. Izewska, Sound insulation of seals has influence on acoustic quality of doorsets. Materialy Budowlane 8 (2012) 27–29. [Google Scholar]
  36. L. Nowotny, J. Nurzynski: Proposal of an assessment method of the impact sound insulation of lightweight floors. Buildings 10, 1 (2020) 13. [Google Scholar]
  37. J. Nurzynski, L. Nowotny: Acoustic performance of floors made of composite panels. Materials 16, 5 (2023) 2128. [Google Scholar]
  38. J. Nurzynski: Sound insulation of bulkhead panels. Applied Acoustics 179 (2021) 108061. [Google Scholar]
  39. B. Szudrowicz: Acoustics of external wall insulation. Kalejdoskop Budowlany 3, 12 (1999) 46–49. (in Polish) [Google Scholar]
  40. M. Mirowska, K. Czyzewski: Influence of thickness and structural parameters on sound absorption coefficients of porous materials, in: International Congress on Acoustics, Madrid, 2007. [Google Scholar]
  41. M. Mirowska: Sound-absorbing Properties of Products for Acoustic Adaptation of Rooms and Noise Protection. Instytut Techniki Budowlanej, Warszawa, 2010. (in Polish) [Google Scholar]
  42. J. Nurzyński: Sound insulation of lightweight external frame walls and the acoustic effect of additional thermal insulation. Applied Acoustics 190 (2022) 108645. [Google Scholar]
  43. L. Nowotny, J. Nurzynski: The influence of insulating layers on the acoustic performance of lightweight frame floors intended for use in residential buildings. Energies 13, 5 (2020) 1217. [Google Scholar]
  44. B. Szudrowicz, E. Nowicka: New standard PN-B-02151-4:2015-06 Part 4: Requirements for reverberation conditions and speech intelligibility in rooms and guidelines for conducting tests. Materiały Budowlane 8 (2015) 2–4. [Google Scholar]
  45. E. Nowicka: Directions of the amendment to the national standards for permissible levels of noise in rooms (2016) 34–35. DOI: https://doi.org/10.15199/33.2016.08.09. [Google Scholar]
  46. E. Nowicka, B. Szudrowicz: The requirements for the protection of dwellings against the external noise adopted in PN-B-02151-3:2015-10. Materiały Budowlane 8 (2016). DOI: https://doi.org/10.15199/33.2016.08.12. [Google Scholar]
  47. E. Nowicka, B. Szudrowicz: The requirements for the protection of dwellings against the internal noise adopted in PN-B-02151-3:2015-10. Materiały Budowlane 8 (2016) 43–46. [Google Scholar]
  48. M. Mirowska: Results of measurements and limits proposal for low frequency noise in the living environment. Journal of Low Frequency Noise and Vibration 14, 3 (1995) 135–141. [Google Scholar]
  49. M. Mirowska: Proposal of low frequency noise limits in the dwellings. Acta Acustica 82, 1 (1996) S114. [Google Scholar]
  50. M. Mirowska: Problems of measurement and evaluation of low-frequency noise in residential buildings in the light of recommendations and the new European standards. Journal of Low Frequency Noise Vibration and Active Control 22, 4 (2003) 203–208. [Google Scholar]
  51. M. Mirowska: Low-frequency Noise in Residential Building: Loise Sources, Effects on Inhabitants and Methods of Nuisance Assessment. Instytut Techniki Budowlanej, Warszawa, 2013. (in Polish) [Google Scholar]
  52. A. Izewska: Global index of acoustic quality of building project. Acustica 82 (1996) 112. [Google Scholar]
  53. H.M. Koprowska: Assessment of acoustic insulation of partitions in buildings exposed to music and noise from entertainment activities. FORUM ACUSTICUM, Krakow (2014) 1–4. [Google Scholar]
  54. H.M. Turkowska: Analysis of the nuisance of domestic noise from selected sources in residential buildings, in: International Conference Noise Control, Lidzbark Warminski, 2022, pp. 1–16. [Google Scholar]
  55. E. Nowicka: Initial acoustic assessment of long underground enclosures for designers. Tunnelling and Underground Space Technology 105 (2020) 103577. [Google Scholar]
  56. E. Nowicka: The acoustical assessment of the commercial spaces and buildings. Applied Acoustics 169 (2020) 107491. [Google Scholar]
  57. E. Nowicka: Improving engineering design using smart evaluation of indoor acoustical climate of dining places. Applied Sciences-Basel 15, 5 (2025) 2700. [Google Scholar]
  58. J. Sadowski, J. Nurzynski: Architectural and environmental acoustics as an aspect of sustainable development. Archives of Acoustics 32, 4 (2007) 971–982. [Google Scholar]
  59. J. Nurzynski: Sustainable Building and the Protection Against Noise. Building Research Institute, Warszawa, 2013, p.224. [Google Scholar]
  60. J. Nurzynski: Acoustic quality of dwellings, a concept of uniform classification scheme, in: CESB 10 Prague: Central Europe towards Sustainable Building: From Theory to Practice. Conference, Prague, Czech Republic, 30 June-2 July 2010. Grada Publishing, Prague, 2010, pp. 493–496. [Google Scholar]
  61. B. Szudrowicz, M. Niemas: Acoustic classification of residential buildings: general issues, requirements. Materiały Budowlane 8 (2011) 2–7. (in Polish) [Google Scholar]
  62. E. Nowicka: Proposal to introduce acoustic classification for public buildings, in: Materiały 52 Szkoły Zimowej Akustyki Środowiska i Wibroakustyki, Szczyrk, 2025. (in Polish) [Google Scholar]
  63. J. Nurzyński: How to exploit effectively noise maps, a proposal for acoustical categorisation of residential areas, in: 22nd International Congress on Sound and Vibration. Florence, Italy. International Institute of Acoustics and Vibration, Acoustical Society of Italy, Florence, 2015, pp. 1–6. [Google Scholar]
  64. I. Zuchowicz-Wodnikowska, Emission and Propagation of Industrial Noise in the Outdoor Environment. Instytut Techniki Budowlanej, Warszawa, 2009. (in Polish) [Google Scholar]

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