[1] V. Nedic, D. Despotovic, S. Cvetanovic, M. Despotovic, S. Babic, Comparison of classical statistical methods and artificial neural network in traffic noise prediction, Environmental Impact Assessment Review, 49 (2014) 24-30.
[2] H. Wang, Y. Ding, G. Liao, C. Ai, Modeling and optimization of acoustic absorption for porous asphalt concrete, Journal of Engineering Mechanics, 142(4) (2016) 04016002.
[3] R. Kleizienė, O. Šernas, A. Vaitkus, R. Simanavičienė, Asphalt pavement acoustic performance model, Sustainability, 11(10) (2019) 2938.
[4] P.R. Donavan, B. Rymer, Assessment of highway pavements for tire/road noise generation, SAE transactions, (2003) 1829-1838.
[5] M. Harrison, Vehicle refinement: controlling noise and vibration in road vehicles, Elsevier, (2004).
[6] D. Wang, P. Liu, Z. Leng, C. Leng, G. Lu, M. Buch, M. Oeser, Suitability of PoroElastic Road Surface (PERS) for urban roads in cold regions: Mechanical and functional performance assessment, Journal of cleaner production, 165 (2017) 1340-1350.
[7] S. Han, Y. Dong, H. Chen, D. Zhang, X. Lu, Y. Shi, Noise Reduction Performance of Exposed Aggregate Cement concrete Pavement, Journal of Traffic and Transportation Engineering, 5(2) (2005) 32.
[8] S. Ullrich, Drum Measurements Of Tyre Noise As A Function Of Roadway Temperature And Circumferential Forces, In: Inter-Noise 93: People Versus Noise, 1993.
[9] I.O.f. Standardization, Acoustics: Measurement of the Influence of Road Surfaces on Traffic Noise. Part 1: Statistical Pass-By Method. Partie 1: Méthode Statistique Au Passage, International Organization for Standardization, 1997.
[10] V. Khan, K.P. Biligiri, Evolution of tyre/road noise research in India: Investigations using statistical pass-by method and noise trailer, International Journal of Pavement Research and Technology, 11(3) (2018) 253-264.
[11] G. de León, L.G. Del Pizzo, L. Teti, A. Moro, F. Bianco, L. Fredianelli, G. Licitra, Evaluation of tyre/road noise and texture interaction on rubberised and conventional pavements using CPX and profiling measurements, Road Materials and Pavement Design, 21(sup1) (2020) S91-S102.
[12] R.M. Knabben, G. Triches, E.F. Vergara, S.N. Gerges, W. van Keulen, Characterization of tire-road noise from Brazilian roads using the CPX trailer method, Applied Acoustics, 151 (2019) 206-214.
[13] S. Ling, F. Yu, D. Sun, G. Sun, L. Xu, A comprehensive review of tire-pavement noise: Generation mechanism, measurement methods, and quiet asphalt pavement, Journal of Cleaner Production, 287 (2021) 125056.
[14] T. Li, A state-of-the-art review of measurement techniques on tire–pavement interaction noise, Measurement, 128 (2018) 325-351.
[15] S. Paje, M. Bueno, F. Terán, U. Viñuela, J. Luong, Assessment of asphalt concrete acoustic performance in urban streets, The Journal of the Acoustical Society of America, 123(3) (2008) 1439-1445.
[16] P. Mikhailenko, Z. Piao, M.R. Kakar, M. Bueno, S. Athari, R. Pieren, K. Heutschi, L. Poulikakos, Low-Noise pavement technologies and evaluation techniques: a literature review, International Journal of Pavement Engineering, 23(6) (2022) 1911-1934.
[17] R. Bernhard, R.L. Wayson, J. Haddock, N. Neithalath, A. El-Aassar, J. Olek, T. Pellinen, W.J. Weiss, An introduction to tire/pavement noise of asphalt pavement, Institute of Safe, Quiet and Durable Highways, Purdue University, (2005) 26.
[18] A. Terminology, American national standard, ANSI S1, (2006) 1-1994.
[19] A.C. Sparavigna, The science of al-Biruni, arXiv preprint arXiv:1312.7288, (2013).
[20] G. Elert, The Nature of Sound, in:The Physics Hypertextbook. physics info Retrieved. (2016) 06-20.
[21] B. Jakovljevic, K. Paunovic, G. Belojevic, Road-traffic noise and factors influencing noise annoyance in an urban population, Environment international, 35(3) (2009) 552-556.
[22] T.H. Oiamo, G.M. Aasvang, Noise and Health, International Encyclopedia of Human Geography (Second Edition), Elsevier, (2020) 409-413.
[23] C. Hurtley, Night noise guidelines for Europe, WHO Regional Office Europe, (2009).
[24] A. Vaitkus, V. Vorobjovas, A. Jagniatinskis, T. Andriejauskas, B. Fiks, Peculiarity of low noise pavement design under Lithuanian conditions, The Baltic Journal of Road and Bridge Engineering, 9(3) (2014) 155-163.
[25] E. Zofka, A. Zofka, T. Mechowski, Pavement noise measurements in Poland, in: IOP Conference Series: Materials Science and Engineering, IOP Publishing, (2017), pp. 012103.
[26] T. Li, Literature review of tire-pavement interaction noise and reduction approaches, Journal of Vibroengineering, 20(6) (2018) 2424-2452.
[27] A. Vaitkus, T. Andriejauskas, V. Vorobjovas, A. Jagniatinskis, B. Fiks, E. Zofka, Asphalt wearing course optimization for road traffic noise reduction, Construction and Building Materials, 152 (2017) 345-356.
[28] U. Sandberg, J. Ejsmont, Tyre/road noise. Reference book, (2002).
[29] M.R. Ganji, A. Golroo, H. Sheikhzadeh, A. Ghelmani, M.A. Bidgoli, Dense-graded asphalt pavement macrotexture measurement using tire/road noise monitoring, Automation in Construction, 106 (2019) 102887.
[30] R.O. Rasmussen, R.J. Bernhard, U. Sandberg, E. Mun, The little book of quieter pavements, United States. Federal Highway Administration. Office of Pavement Technology, 2007.
[31] P.R. Donavan, Comparative measurements of tire/pavement noise in Europe and the United States, Noise News International, 13(2) (2005) 46-53.
[32] T. Bennert, D. Hanson, A. Maher, N. Vitillo, Influence of pavement surface type on tire/pavement generated noise, ASTM International, 2005.
[33] A. Syamkumar, K. Aditya, V. Chowdary, Development of mode-wise noise prediction models for the noise generated due to tyre-pavement surface interaction, Advanced Materials Research, 723 (2013) 50-57.
[34] T. Fujikawa, H. Koike, Y. Oshino, H. Tachibana, Definition of road roughness parameters for tire vibration noise control, Applied acoustics, 66(5) (2005) 501-512.
[35] J. Winroth, W. Kropp, C. Hoever, T. Beckenbauer, M. Männel, Investigating generation mechanisms of tyre/road noise by speed exponent analysis, Applied Acoustics, 115 (2017) 101-108.
[36] T. Dare, R. McDaniel, A. Shah, Modeling Tire-Pavement Noise Using MnROAD Data, (2015).
[37] Z. Zhang, B. Luan, X. Liu, M. Zhang, Effects of surface texture on tire-pavement noise and skid resistance in long freeway tunnels: From field investigation to technical practice, Applied Acoustics, 160 (2020) 107120.
[38] P.W.R. Association, Report of the committee on surface characteristics, in: Proceeding of XVIII World Road Congress, (1987), pp. 13-19.
[39] R. Pelloli, Road surface characteristics and hydroplaning, Transportation Research Record, 624 (1977) 27-32.
[40] T. Li, Influencing parameters on tire–pavement interaction noise: Review, experiments, and design considerations. Designs, 2(4) (2018): 38.
[41] B.M. Luccioni, M. Luege, Concrete pavement slab under blast loads, International journal of impact engineering, 32(8) (2006) 1248-1266.
[42] U. Sandberg, Road surface influence on tire/road noise-Part I Descornet, G., Sandberg, U: Road surface influence on tire/road noise-Part II VTI preprint, 56 (1980).
[43] M. Sakhaeifar, A. Banihashemrad, G. Liao, B. Waller, Tyre–pavement interaction noise levels related to pavement surface characteristics, Road Materials and Pavement Design, 19(5) (2018) 1044-1056.
[44] F. Anfosso-Lédée, M.-T. Do, Geometric descriptors of road surface texture in relation to tire-road noise, Transportation research record, 1806(1) (2002) 160-167.
[45] K. Gee, Surface texture for asphalt and concrete pavements, FHWA Technical Advisory TA, 5040 (2005).
[46] P.R. Donavan, Effect of porous pavement on wayside traffic noise levels, Transportation Research Record, 2403(1) (2014) 28-36.
[47] R.S. McDaniel, K.J. Kowalski, A. Shah, J. Olek, R.J. Bernhard, Long term performance of a porous friction course, (2010).
[48] H. Bendtsen, Q. Lu, E. Kohler, Acoustic aging of asphalt pavements: A Californian/Danish comparison, (2010).
[49] M. Gustafsson, C.M. Berglund, B. Forsberg, I. Forsberg, S. Forward, S. Grudemo, U. Hammerström, M. Hjort, T. Jacobson, C. Johansson, Effects of winter tyres: state of the art, VTI Rapport, (543) (2006).
[50] J.S. Yang, T.F. Fwa, G.P. Ong, C.H. Chew, Finite-element analysis of effect of wide-base tire on tire-pavement noise, Advanced Materials Research, 723 (2013) 105-112.
[51] U. Sandberg, J. Ejsmont, Influence of tyre tread rubber hardness on tyre/road noise emission, Inter-Noise, Istanbul, Turkey, (2007).
[52] D. Rochoux, F. Biesse, Tire/road noise, the tire vibration as the main noise source from road texture, in: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, Institute of Noise Control Engineering, 2010, pp. 7199-7208.
[53] J. Walker, Noise from the Tyre-Road Interface with Heavy Commercial Vehicles, Transport Engineer, (68) (1975).
[54] W. Flanagan, Recent studies give unified picture of tire noise, Automotive Engineering, 80(4) (1972).
[55] R.K. Hillquist, P.C. Carpenter, A basic study of automobile tire noise, The Journal of the Acoustical Society of America, 54(1_Supplement) (1973) 331-331.
[56] W.A. Leasure Jr, E.K. Bender, Tire–road interaction noise, The Journal of the Acoustical Society of America, 58(1) (1975) 39-50.
[57] M. Bueno, J. Luong, U. Viñuela, F. Terán, S. Paje, Pavement temperature influence on close proximity tire/road noise, Applied Acoustics, 72(11) (2011) 829-835.
[58] U. Sandberg, Semi-generic temperature corrections for tyre/road noise, in: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, Institute of Noise Control Engineering, 2004, pp. 3302-3309.
[59] S. Konishi, T. Fujino, N. Tomita, M. Sakamoto, Temperature effect on tire/road noise, JSAE Review, 1(16) (1995) 113.
[60] G. Liao, M. Heitzman, R. West, S. Wang, C. Ai, Temperature effects on the correlations between tire-pavement noises and pavement surface characteristics, in: New Frontiers in Road and Airport Engineering, 2015, pp. 219-232.
[61] R. McDaniel, A. Shah, T. Dare, R. Bernhard, Hot mix asphalt surface characteristics related to ride, texture, friction, noise and durability, Institute for Safe, Quiet, and Durable Highways North Central Superpave Center Purdue University, 7 (2014).
[62] T. Li, J. Feng, R. Burdisso, C. Sandu, Effects of speed on tire–pavement interaction noise (Tread-pattern–related noise and non–tread-pattern–related noise), Tire Science and Technology, 46(2) (2018) 54-77.
[63] T. Dare, R. Bernhard, Accelerometer measurements of tire tread vibrations and implications to wheel-slap noise, Tire Science and Technology, 41(2) (2013) 109-126.
[64] J. Ejsmont, S. Taryma, Halas Opon Samochodow Osobowych Poruszajacych Sie Posuchych Nawierzchniach asfaltowych I Betonowych, Technical University of Gdansk, Gdansk, Poland, (1982).
[65] G. Tong, Q. Wang, K. Yang, X.C. Wang, An experiment investigation to the radial tire noise, Advanced Materials Research, 694 (2013) 361-365.
[66] U. Sandberg, J.A. Ejsmont, Three basic methods for measurement of tire/road noise, in, Statens Väg-och Trafikinstitut., VTI särtryck 99, 1984.
[67] S. Kocak, M.E. Kutay, Relationship between material characteristics of asphalt mixtures and highway noise, Transportation research record, 2295(1) (2012) 35-43.
[68] G. Tong, Q. Wang, K. Yang, L. Wang, Simulation on the radial tire wear noise, Applied Mechanics and Materials, 488 (2014) 1121-1124.
[69] K. Glaeser, Road surface characteristics and type road noise, Federal Highway Research Institute BAST, (2007).
[70] R.J. Bernhard, R.S. McDaniel, Basics of noise generation for pavement engineers, Transportation research record, 1941(1) (2005) 161-166.
[71] D. Wang, A. Schacht, Z. Leng, C. Leng, J. Kollmann, M. Oeser, Effects of material composition on mechanical and acoustic performance of poroelastic road surface (PERS), Construction and Building Materials, 135 (2017) 352-360.
[72] C. Leng, G. Lu, J. Gao, P. Liu, X. Xie, D. Wang, Sustainable green pavement using bio-based polyurethane binder in tunnel, Materials, 12(12) (2019) 1990.
[73] S. Alber, W. Ressel, P. Liu, D. Wang, M. Oeser, Influence of soiling phenomena on air-void microstructure and acoustic performance of porous asphalt pavement, Construction and Building Materials, 158 (2018) 938-948.
[74] L. Chu, T. Fwa, K. Tan, Evaluation of wearing course mix designs on sound absorption improvement of porous asphalt pavement, Construction and Building Materials, 141 (2017) 402-409.
[75] R.M. Knabben, G. Trichês, S.N. Gerges, E.F. Vergara, Evaluation of sound absorption capacity of asphalt mixtures, Applied Acoustics, 114 (2016) 266-274.
[76] M. Möser, Technische Akustik, Springer, 2005.
[77] M. Wolkesson, Evaluation of impedance tube methods-A two microphone in-situ method for road surfaces and the three microphone transfer function method for porous materials, (2012).
[78] M. Haider, M. Conter, Austrian experience with the backing board method for statistical pass-by measurements, in: Proc. of acoustics, 2008.
[79] D.M. Gonzalez, J.M.B. Morillas, G.R. Gozalo, Acoustic behaviour of plates made of different materials for measurements with the microphone flush mounted, Applied Acoustics, 132 (2018) 135-141.
[80] G.H. Wang, R. Shores, J. Botts, R. Hibbett, On-board sound intensity tire-pavement noise study in North Carolina, North Carolina. Dept. of Transportation. Research and Analysis Group, 2011.
[81] C. Vuye, A. Bergiers, B. Vanhooreweder, The acoustical durability of thin noise reducing asphalt layers, Coatings, 6(2) (2016) 21.
[82] M. Bueno, J. Luong, F. Terán, U. Viñuela, S. Paje, Macrotexture influence on vibrational mechanisms of the tyre–road noise of an asphalt rubber pavement, International Journal of Pavement Engineering, 15(7) (2014) 606-613.
[83] T. AASHTO, 76-12. Standard method of test for measurement of tire/pavement noise using the on-board sound intensity (OBSI) method, USA: American Association of State and Highway Transportation Officials, (2010).
[84] R. Rasmussen, R. Sohaney, P. Wiegand, Measuring and reporting tire-pavement noise using on-board sound intensity (OBSI), National Concrete Pavement Technology Center, Iowa State University, Ames, Iowa. (2011).
[85] T. Park, M. Kim, C. Jang, T. Choung, K.-A. Sim, D. Seo, S.I. Chang, The public health impact of road-traffic noise in a highly-populated city, Republic of Korea: Annoyance and sleep disturbance, Sustainability, 10(8) (2018) 2947.
[86] R. Kim, Burden of disease from environmental noise, in: WHO International Workshop on Combined Environmental Exposure: Noise, Air Pollutants and Chemicals. Ispra, 2007.
[87] F.G. Praticò, F. Anfosso-Lédée, Trends and issues in mitigating traffic noise through quiet pavements, Procedia-Social and Behavioral Sciences, 53 (2012) 203-212.
[88] D.E. Mogrovejo, G.W. Flintsch, E.D. de León Izeppi, K.K. McGhee, R.A. Burdisso, Short-Term effect of pavement surface aging on tire–pavement noise measured with Onboard sound Intensity Methodology, Transportation Research Record, 2403(1) (2014) 17-27.
[89] E. Saemann, G. Dimitri, P. Kindt, Tire requirements for pavement surface characteristics, in: 7th symposium on pavement surface characteristics: SURF, 2012, pp. 1-33.
[90] M. Haider, M. Conter, R. Wehr, U. Sandberg, F. Anfosso-Lédée, Project ROSANNE: rolling resistance, skid resistance, and noise emission measurement standards for road surfaces, in: Internoise 2014, 2014, pp. 6p.
[91] M. Liu, X. Huang, G. Xue, Effects of double layer porous asphalt pavement of urban streets on noise reduction, International Journal of Sustainable Built Environment, 5(1) (2016) 183-196.
[92] B. Yu, L. Jiao, F. Ni, J. Yang, Long-term field performance of porous asphalt pavement in China, Road Materials and Pavement Design, 16(1) (2015) 214-226.
[93] M.-L. Zeng, L.-Q. Peng, C.-F. Wu, B.-Y. Tan, Experimental study of the performance of ultrathin asphalt friction course, Wuhan Ligong Daxue Xuebao(Journal of Wuhan University of Technology), 34(4) (2012) 27-31.
[94] J.T. Guo, R. Zhang, R. Wang, Experimental research on sound absorption performance of low-noise pavement, Advanced Materials Research, 374 (2012) 1400-1404.
[95] M. Li, W. van Keulen, H. Ceylan, G. Tang, M. van de Ven, A. Molenaar, Influence of road surface characteristics on tire–road noise for thin-layer surfacings, Journal of Transportation Engineering, 141(11) (2015) 04015024.
[96] S. Luo, Q. Lu, Z. Qian, Performance evaluation of epoxy modified open-graded porous asphalt concrete, Construction and Building Materials, 76 (2015) 97-102.
[97] J. Ejsmont, L. Goubert, G. Ronowski, B. Świeczko-Żurek, Ultra low noise poroelastic road surfaces. Coatings 6 (2): 18, in, (2016).
[98] S. Meiarashi, Porous elastic road surface as an ultimate highway noise measure, in: The XXIInd PIARC World Road CongressWorld Road Association (PIARC), (2003).
[99] U. Sandberg, L. Goubert, Persuade: a European project for exceptional noise reduction by means of poroelastic road surfaces, in: 40th International Congress and Exposition on Noise Control Engineering 2011 (INTER-NOISE 2011), Institute of Noise Control Engineering of Japan (INCE/J), Acoustical Society …, 2011, pp. 673-684.
[100] K.P. Biligiri, B. Kalman, A. Samuelsson, Understanding the fundamental material properties of low-noise poroelastic road surfaces, International Journal of Pavement Engineering, 14(1) (2013) 12-23.
[101] B. Świeczko‐Żurek, J. Ejsmont, G. Motrycz, P. Stryjek, Risks related to car fire on innovative Poroelastic Road Surfaces—PERS, Fire and Materials, 39(2) (2015) 95-108.
[102] V.F. Vázquez, F. Terán, J. Luong, S.E. Paje, Functional performance of stone mastic asphalt pavements in Spain: Acoustic assessment, Coatings, 9(2) (2019) 123.
[103] G. Greer, Stone Mastic Asphalt–A review of its noise reducing and early life skid resistance properties, in: Proceedings of ACOUSTICS, 2006, pp. 319-323.
[104] J. Chandler, S. Phillips, P. Roe, H. Viner, Quieter concrete roads: construction, texture, skid resistance and noise, TRL REPORT TRL 576, (2003).
[105] V. Vázquez, F. Terán, P. Huertas, S. Paje, Field assessment of a Cold-In place-recycled pavement: Influence on rolling noise, Journal of Cleaner Production, 197 (2018) 154-162.
[106] W. Gardziejczyk, A. Plewa, R. Pakholak, Effect of addition of rubber granulate and type of modified binder on the viscoelastic properties of stone mastic asphalt reducing tire/road noise (SMA LA), Materials, 13(16) (2020) 3446.
[107] G. Licitra, A. Moro, L. Teti, L. Del Pizzo, F. Bianco, Modelling of acoustic ageing of rubberized pavements, Applied Acoustics, 146 (2019) 237-245.
[108] F. Kehagia, S. Mavridou, Noise reduction in pavement made of rubberized bituminous top layer, Open Journal of Civil Engineering, 2014 (2014).
[109] M.J. Brennan*, A.M. Kavanagh, J.N. Sheahan, Case studies of a low-noise road surface, International Journal of Pavement Engineering, 2(2) (2001) 121-134.
[110] M. Gao, Study on Noise Reduction Characteristics of Continuous Gradation Rubber Particles Asphalt Pavement, Doctoral dissertation, Inner Mongolia Agricultural University, 2009.
[111] V. Najafi Moghaddam Gilani, M. Habibzadeh, S.M. Hosseinian, R. Salehfard, A review of railway track laboratory tests with various scales for better decision-making about more efficient apparatus using TOPSIS analysis, Advances in Civil Engineering, 2022 (2022).
[112] H. Ziari, A. Amini, A. Saadatjoo, S.M. Hosseini, V.N.M. Gilani, A prioritization model for the immunization of accident prone using multi-criteria decision methods and fuzzy hierarchy algorithm, Computational Research Progress in Applied Science & Engineering (CRPASE), 3(3) (2017).
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