A Methodology for the Definition of the Acoustic Capacity of a Road Infrastructure
Abstract
:1. Introduction
- Limit value of noise emissions: it is the maximum value of the sound pressure level (expressed in dBA), emitted only by the given source, measured at a receiver point. The Italian standards are not precise as they report that the receiver point is located on the side of the road. However, the European laws (Recommendation of the European Commission of 6 August 2003 [15]) specify that the emission values must be measured, as suggested by the French Guide du Bruit of 1980 [16], at 7.5 m of distance from the source; see Recommendation [15], Section 3.1.1, page L212/58. This last approach was taken into account in this paper.
- Limit value of noise immission: it is the maximum value of the sound pressure level (expressed in dBA) measured at a given receiver point, immitted by all noise sources. The standards about traffic noise define a limit value of sound pressure level, to be measured close to the most sensible receiver, in the “range of acoustic pertinence” whose width is defined for each type of road. However, the standards also define some limit values in each zone into which the urban area is divided according to the intended use. Moreover, these limit values can be a constraint for the acoustic capacity of a road section. For example, hypothesizing that the range of acoustic pertinence of a road section is 30 m, there could be a hospital at 50 m from the side of the road which is the strongest constraint to the value of acoustic capacity of the road. Indeed, a hospital is considered a “particularly protected zone” by the laws on acoustic pollution, as shown in Section 2 of this paper.
- modeling of noise emissions: assessment of the noise emitted in the environment by the road traffic;
- modeling of road traffic noise propagation in the environment: assessment of the noise immission measured at a given receiver point.
2. Literature Review
3. Materials and Methods
- modeling of noise emissions by road traffic; and
- modeling of noise propagation in the surrounding of the investigated area.
3.1. The Harmonoise Emission Model
3.1.1. Some Fundamental Definitions for the Calculation of Noise Emissions
3.1.2. The Harmonoise Vehicular Model
- LW,h,m,i is the sound power level LW of the sub-source h, emitted by the vehicle of the m category, at frequency i [dB];
- LWRN,h,m,i is the sound power level, caused by rolling (RN means “rolling noise”), of the sub-source h, emitted by the vehicle of the m category, at frequency i [dB];
- LWTN,h,m,i is the sound power level, caused by traction (TN means “traction noise”), at the sub-source h, emitted by the vehicle of the m category, at frequency i [dB].
- ⊕ stands for logarithmic sum.
3.1.3. The Harmonoise Traffic Model
- = explained above (Watt/m)
- LW,h,m,i = explained above (Watt)
- = traffic flow, related to the vehicle category m, taken as constant (veh/h)
- = average speed of vehicles of category m (km/h)
3.1.4. Calculation of the Equivalent Sound Pressure Level
3.2. The Harmonoise Propagation Model
- instantaneous sound pressure level, introduced at a given receiver point, generated by the sub-source h, from the source line segment j, at the frequency i;
- sound power level (in dB), generated by the sub-source h, from the source line segment j, at the frequency i. This value is computed by the Equation (10) reported in the following;
- attenuation term due to geometrical divergence;
- attenuation term due to sound absorption through the atmosphere;
- attenuation term due to ground reflection;
- attenuation term due to the sound energy loss into reflection;
- attenuation term due to the sound dispersion caused by the surrounding vegetation (trees, bushes, hedges etc).
- L′W,h,j,i = output of the emission model, calculated from Equation (3), i.e.: the sound power level emitted by each sub-source h, on a source line segment j (which represents a road section) 1 meter long, at a sound frequency i (dB/m).
- l = length of the source line segment taken into account in the propagation model (m).
3.2.1. Attenuation Due to Geometrical Divergence
3.2.2. Attenuation Due to Atmospheric Absorption
- αatm,i = coefficient of atmospheric attenuation, in (dB/m). It is calculated according to Nota et al. [29], p. 38. αatm,i is a function of temperature (K), relative humidity (%), atmospheric pressure (kPa), and wind speed (km/h).
- r = distance from the source to the receiver (m).
3.2.3. Excess Attenuation Due to the Diffraction and to the Ground Reflection
3.2.4. Attenuation Due to Reflection
- ρε = reflection coefficient which is a function of the reflecting surface;
- Srefl,i = projection of the reflection surface over the Fresnel zone;
- SFz,i = total area of Fresnel zone.
3.2.5. Attenuation Due to Sound Dispersion Caused by Vegetation Ascat
- average diameter of trees;
- length of the sound path across the wooden areas;
- average height of trees;
- noise frequency.
3.2.6. Synthesis of the Harmonoise Sound Propagation Model
3.3. The Concept of “Acoustic Capacity” and Capacity Constraints
3.3.1. Synthesis on the Calculation of the Acoustic Emissions Using the Harmonoise Emission Model
- the vehicle flow by vehicle category on each road section;
- the average speed and the average acceleration for each vehicle category flow. The average acceleration, when using SUMO, is automatically calculated by the software. In the practice of use, in particular in the LIST Port project, three categories of vehicles were considered: cars, motorcycles, and heavy vehicles.
- the sound power level L′W,h,m,i emitted, for each sub-source h, by a stream of vehicles, of category m and at a noise frequency i, per meter;
- the sound pressure level Lp (in dBA) at a receiver point, placed at a distance of r meters (normally 7.5 meters) from the trajectory of the vehicle flow (Equation (7)).
- The equivalent sound pressure level over a period T, at a receptor point (Equation (8)), due to the vehicle flow. Normally, in traffic applications, T is considered equal to one hour. This pressure level must be compared with the limit values established by regulations.
3.3.2. Synthesis of the Calculation of the Acoustic Immissions Using the Harmonoise Propagation Model
- The Harmonoise propagation model receives as input: the sound power level emitted by a vehicular flow per meter of source line, calculated using the emission model: L′W,h,m,i.
- The Harmonoise propagation model provides as output: the sound pressure level detected by a given receiver at a receptor point. This sound pressure level is compared to the limit values given by regulations (law 447/95, DPCM 14 November 1997 and DPR 142/2004 in Italy).
3.3.3. Verification of Capacity Constraints
- Emission limit value: i.e., the sound pressure level detected by a receiver placed near the sound source/road (for example: blue dot in Figure 4). The height of the receiver point is 1.5 m (1.2 according to the European Commission Recommendation of 2003 [15]). However, the Italian standards are imprecise as to the receiver’s horizontal position, and report generically “on the side of the road”, while European standards report, more precisely, that the receiver must be placed at 7.5 m horizontally from the vehicle trajectory (point “RE” in Figure 5). In particular, the receiver is placed at 7.5 m from the road centerline if the road is composed of two lanes, and from the center of the lane if the road is composed by only one lane; see: [33,34,35].
- Immission limit value: i.e., the sound pressure level detected at a sensible receiver point. The Presidential Decree no. 142 of 30 March 2004 establishes limit values for noise immissions at a point, as for example the green dot in Figure 4, in the acoustic pertinence range of the road infrastructure (green line in Figure 4). In this case, the noise immissions are measured at 1 m from the most exposed façade, of the most sensitive building/receiver, and at a height of 4 m above the ground (point “RI” in Figure 5). In any case, also outside the pertinence range, road traffic contributes, together with other kind of noise sources, to the immission value detected at a sensible receiver in any point of the municipal territory (Law no. 447/95 and the DPCM 14 November 1997), and in particular at a receiver point, again located 4 m above the ground and 1 m from the most exposed façade: for example, the red dot in Figure 4.
4. Results
4.1. First Application Example
- Aexcess,i = attenuation term due to ground reflection and diffraction: neglected as there are no obstacles from the source to the receiver and the ground is flat;
- Arefl,i = attenuation term due to the sound energy loss in reflection: neglected as there are no obstacles from the source to the receiver and the ground is flat;
- Ascat,i = attenuation term due to the sound dispersion caused by the surrounding vegetation (trees, bushes, hedges, etc.): neglected as there is no vegetation between the source and the receiver.
- d = average distance among the vehicles (m) (a single type of vehicle was considered);
- k = density (veh/m), that is, the number of vehicles present in the road link under study, in the given time instant;
- Q = traffic flow (veh/h);
- = average speed (km/h);
- Lw,1 veic = equivalent sound power level emitted by a single vehicle (dB(A));
- L′w = equivalent sound power level per meter, emitted by the linear noise source (dB(A)/m).
- Lp = equivalent sound pressure level, measured at the receiver (dB(A));
- L′w = explained above (dB(A)/m);
- r = distance between the noise source and the receiver (m). For the calculation of noise emissions, a receiver located at 7.5 m from the middle of the carriageway was taken into account. For the calculation of noise immissions, the most sensible receiver was taken into account.
- the equivalent sound power level emitted by each vehicle; and
- the position of each vehicle: that is, the link where the vehicle is, and the position of the vehicle in the link.
- Lw,1 veic, of Equation (14), as the average (“logarithmic average”, Equation (17)) of the sound power levels emitted by all vehicles present in the link under study in each simulation time instant (which is not provided directly by SUMO);
- the density k, calculated as the number of vehicles present in the link in each time instant, divided by the link length in m. From the density, d = 1/k was calculated, that is the average space among vehicles in meters.
- Departing from a given value of traffic demand, SUMO automatically calculates traffic flows on each link of the test network, and noise emissions of each vehicle in each simulation time instant.
- For the road section circled in blue in Figure 6, and for each simulation time instant, we calculated: the value of vehicle density k, and the average noise emissions of all vehicles present in the link at the given time instant, that is Lw,1 veic.
- Applying Equation (14), for each simulation time instant, we calculated the “instantaneous” L′w value.
- We calculated the equivalent sound power level L′w over 1 h of simulation.
- We calculated the equivalent sound pressure level Lp from L′w by means of Equation (16) considering a distance of 7.5 m from the road centerline.
4.2. Second Application Example
- road section circled in light blue: 1050 veh/h in both directions;
- road section circled in orange: 1065 veh/h in exit from the intersection and 850 veh/h towards the intersection;
- road section circled in green: 215 veh/h, only one way, towards the intersection.
- the equivalent sound power level emitted by each vehicle;
- the link where each vehicle is located, and the position of the vehicle in the link.
- the average (“logarithmic average”, Equation (17)) of the sound power levels emitted by all vehicles present in the link in each simulation time instant: that is, Lw,1 veic of Equation (14) (which is not provided directly by SUMO);
- the density k, described in the previous Section 4.2. (which is not provided directly by SUMO).
- road section circled in light blue: 62.2 dB(A)/m
- road section circled in orange: 60.8 dB(A)/m
- road section circled in green: 47.5 dB(A)/m
- road section circled in light blue: 47.45 dB(A);
- road section circled in orange: 46.05 dB(A).
- Cth = through-movement capacity (veh/h) of rank 1 movements,
- Nth = number of through lanes (shared or exclusive). In this example, it is always equal to 1, for both road sections circled in light blue and in orange, because they have only one lane per direction (see Figure 9).
- p*0,j = probability that there will be no queue in the inside through lane.The probability p*0,j is equal to 1.0 if no left turn (having to give way to vehicles coming from the opposite direction) is allowed from the major street.In this example, p*0,j is equal to 1.0 because vehicles coming from link 1 are obliged to turn right to link 4; vehicles coming from link 3 and turning left to link 2 do not have to give way.
5. Discussion
6. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References and Notes
- Transportation Research Board. Highway Capacity Manual 2000; Transportation Research Board, National Research Council: Washington, DC, USA, 2000. [Google Scholar]
- Ferrari, P. Road pricing and network equilibrium. Transp. Res. Part B 1995, 29, 357–372. [Google Scholar] [CrossRef]
- Buchanan, C. Traffic in Towns; H.M.S.O.: London, UK, 1963. [Google Scholar]
- Sharpe, C.P.; Maxman, R.J.; Voorhees, A.M. A Methodology for the Compilation of the Environmental Capacity of Roadway Networks. Highway Research Record; Highway Research Board: Washington, DC, USA, 1972; pp. 33–40. Available online: https://onlinepubs.trb.org/Onlinepubs/hrr/1972/394/394-004.pdf (accessed on 23 October 2021).
- Holdsworth, J.; Singleton, D. Environmental capacity of roads. In Proceedings of the 5th Australian Transport Research Forum, Canberra, Australia, 18–20 April 1979; pp. 219–238. [Google Scholar]
- Ferrari, P. Fondamenti di Pianificazione dei Trasporti; Pitagora Editrice: Bologna, Italy, 2001. [Google Scholar]
- Zachariadis, T.; Samaras, Z. An Integrated Modeling System for the Estimation of Motor Vehicle Emissions. J. Air Waste Manag. Assoc. 1999, 49, 1010–1026. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Emisia, S.A. COPERT—Computer Programme to Calculate Emissions from Road Transport. 2018. Available online: http://emisia.com/ (accessed on 23 October 2021).
- Wang, F.; Xie, Z.; Liang, J.; Fang, B.; Piao, Y.; Hao, M.; Wan, Z. Tourmaline-Modified FeMnTiOx Catalysts for Improved Low-Temperature NH3-SCR Performance. Environ. Sci. Technol. 2019, 53, 6989–6996. [Google Scholar] [CrossRef] [PubMed]
- Ouyang, J.; Zhao, Z.; Yang, H.; Zhang, Y.; Tang, A. Large-scale synthesis of sub-micro sized halloysite-composed CZA with enhanced catalysis performances. Appl. Clay Sci. 2018, 152, 221–229. [Google Scholar] [CrossRef]
- Wang, X.; Fu, H.; Lu, J.; Han, S. Study on road section environmental traffic capacity model and algorithm under double constraints. Transp. Res. Part D 2016, 48, 14–19. [Google Scholar] [CrossRef]
- Koorey, G.; Chesterman, R. Assessing the environmental capacity of local residential streets. In Proceedings of the 12th World Conference on Transport Research, Lisbon, Portugal, 11–15 July 2010. [Google Scholar]
- Distefano, N.; Leonardi, S. La Capacità Ambientale come Indicatore di Qualità delle Infrastrutture Stradali; Working Paper of Stradelandia; University of Catania: Catania, Italy, 2005. [Google Scholar]
- Official Gazette of the Italian Republic, Decree of the President of the Council of Ministers (DPCM) of 14 November 1997.
- Official Journal of the European Union, European Commission Recommendation no. 2003/613/EC, of 6 August 2003.
- Ministére de l’environnement et du cadre de vie et Ministére des Transports. Guide du Bruit des Transports Terrestres: Prévision des Niveaux Sonores; CERTU: Lyon, France, 1980. [Google Scholar]
- Salomons, E.; Van Maercke, D.; Defrance, J. The Harmonoise sound propagation model. Acta Acust. United Acust. 2011, 97, 62–74. [Google Scholar] [CrossRef]
- LIST Port Project. Available online: http://interreg-maritime.eu/web/listport/progetto (accessed on 23 October 2021).
- Official Gazette of the Italian Republic, Decree of the President of the Council of Ministers (DPCM) of 1 March 1991.
- Official Gazette of the Italian Republic, Law no. 447 of 26 October 1995.
- CERTU; SETRA; LCPC; CSTB. NMPB-Routes-96. In Bruit des Infrastructures Routières, Méthod de Calcul Incluant les Effets Météorologiques; CERTU: Lyon, France, 1997. [Google Scholar]
- Official Gazette of the Italian Republic, Decree of the Ministry of the Environment of 16 March 1998.
- Official Journal of the European Union, Directive no. 2002/49/CE of the European Parliament and of the Council, of 25 June 2002.
- Official Gazette of the Italian Republic, Decree of the President of the Council of Ministers (DPCM) of 30 March 2004, no. 142.
- Official Gazette of the Italian Republic, Legislative Decree (D.Lgs.) no. 194 of 19 August 2005.
- UNI. Metodo per la Stima dell’Impatto e del Clima Acustico per Tipologia di Sorgenti—Parte 2. In Rumore Stradale; Standard No. 11143 of 2005; UNI: Cedar Falls, IA, USA, 2005. [Google Scholar]
- Official Journal of the European Union, Directive (EU) no. 2015/996 of the European Commission, of 19 May 2015.
- Official Gazette of the Italian Republic, Legislative Decree (D.Lgs.) no. 42 of 17 February 2017.
- Nota, R.; Barelds, R.; Van Maercke, D. Harmonoise WP 3 Engineering Method for Road Traffic and Railway Noise after Validation and Fine-Tuning; Technical Report HAR32TR-040922-DGMR20; Harmonoise Project: Brussels, Belgium, 2005. [Google Scholar]
- Farina, A. Acustica ambientale—La propagazione del suono in campo libero e gli effetti dell’ambiente, del rumore e delle sue sorgenti. In Proceedings of the RCF Audio Academy, Reggio Emilia, Italy, 10 January 2016. [Google Scholar]
- De Vos, P.; Beuving, M.; Verheijen, E. Harmonised Accurate and Reliable Methods for the EU Directive on the Assessment and Management of Environmental Noise; Final Technical Report; Harmonoise Project, 2005; Available online: https://cordis.europa.eu/project/id/IST-2000-28419 (accessed on 23 October 2021).
- Noise, Predictor-LimA. Available online: https://dgmrsoftware.com/products/predictor/ (accessed on 23 October 2021).
- Farina, A. Modelli numerici per il rumore da traffico stradale e ferroviario in aree urbane. In Proceedings of the Conference “Rumore? Ci Stiamo Muovendo—Secondo Seminario sull’Inquinamento Acustico” (Noise? We Are Moving—Second Seminar on the Acoustic Pollution), Rome, Italy, 26–27 October 1998. [Google Scholar]
- Calejo Rodrigues, R. Traffic noise and energy. In Proceedings of the 6th International Conference on Energy and Environment Research, Aveiro, Portugal, July 22–25 2019; pp. 177–183. [Google Scholar]
- De Leon, G.; Fidecaro, F.; Cerchiai, M.; Reggiani, M.; Ascari, E.; Licitra, G. Implementation of CNOSSOS-EU method for road noise in Italy. In Proceedings of the 23rd International Congress on Acoustics, Aachen, Germany, 9–13 September 2019. [Google Scholar]
- Transportation Research Board. Highway Capacity Manual 2016; Transportation Research Board, National Research Council: Washington, DC, USA, 2016. [Google Scholar]
- Gazzetta Ufficiale della Repubblica Italiana, Ministry Decree no. 6792 of 5 November 2001, Norme funzionali e geometriche per la costruzione delle strade.
- Transportation Research Board. Highway Capacity Manual 2010; Transportation Research Board, National Research Council: Washington, DC, USA, 2010. [Google Scholar]
Standard/Law | Topic | Description |
---|---|---|
French/European standard: Guide du Bruit of 1980 [16]. | Receiver position. Calculation methods of acoustic descriptors. | Detailed methodology for the measurement of noise emissions and immissions (*). Position of the receiver to measure noise emissions, also in the case of road intersections (*). Early simple methods for calculating noise emissions and immissions (a). |
Italian law: DPCM of 1 March 1991 [19]. | Earliest thresholds for noise emissions and immissions. | Earliest limit values for sound pressure immissions; it introduced the acoustic zoning of the territory and the so-called “recovery plans” (b). |
Italian law: law no. 447 of 1995 [20]. | Main general concepts. | Concepts of noise emission and immission limit values, attention values, and quality values (*). Definition of the types of noise sources (*). |
French standard: NMPB-Routes of 1996 [21] | Calculation methods of acoustic descriptors. | Methodology to calculate noise emissions and immissions (a). |
Italian law: DPCM no. 413 of 14/11/1997 [14]. | Thresholds for noise emissions and immissions. | Classification of the municipal land into six classes according to the vulnerability of receivers (*). Definition of the noise emission and immission limit values for each of the six classes (*). |
Italian law: Ministerial Decree of 16/3/1998 [22]. | Receiver position. | Definition of the periods of measure of the acoustic pollution (*). Positions of the receiver for the measurement of noise immissions: at a horizontal distance of 1 m from the most exposed building façade and at a height of 4 m from the road surface (*). |
European law: EU Directive no. 2002/49/CE of 2002 [23]. | General concepts. Calculation methods of acoustic descriptors. | Introduction to the acoustic descriptors Lden, Lday, Levening, and Lnight. Methodology to calculate descriptors: NMPB-Routes of 1996 (“old” French method) (a). |
European law: European Commission Recommendation of 6/8/2003 [15]. | Receiver position. | Position of the receiver to measure noise emissions and immissions. The receiver for noise emissions must be placed at 7.5 m horizontal distance from the vehicle trajectory and at 1.2 m height. To assess noise immissions, the receiver must be placed at a height of 4 ± 0.2 m from the ground (*) |
Italian law: DPR no. 142 of 30/3/2004 [24]. | Thresholds for noise immissions. | Concept of acoustic pertinence range of a road infrastructure. Definition of the width of the pertinence range and of noise immission limit values in the pertinence range (*). |
Italian law: Legislative Decree no. 194 of 19/8/2005 [25]. | General concepts. | Adoption of EU Directive no. 2002/49/CE in Italy: introduction of the acoustic descriptors Lden, Lday, Levening, and Lnight (*). Methodology to calculate descriptors: NMPB-Routes of 1996 (“old” French method) (a). |
European standard: UNI no. 11,143 of 2005 [26]. | Receiver position. | Position of the receiver for measuring noise emissions (recognized only in Italy) (*). |
European law: European Union Directive no. 2015/996/EU of 2015 [27]. | Calculation methods of acoustic descriptors. | New methodology for the calculation of noise emission and propagation in the case of road, railway, industrial, and aircraft noise. This methodology is called CNOSSOS-EU and is essentially a simplified Harmonoise model (*). |
Italian law: Legislative Decree no. 42 of 17/2/2017 [28]. | Calculation methods of acoustic descriptors. | Adoption in Italy of the European Union Directive no. 2015/996/EU and of the CNOSSOS-EU methodology for calculating noise emissions and propagation (*). |
Main Type | m | Example of Vehicle Types | Notes |
---|---|---|---|
Light vehicles | 1a | Cars (incl. MPVs up to 7 seats) | 2 axles, max 4 wheels |
1b | Vans, SUV, pickup trucks, RV, car + trailer or car + caravan, MPVs with 8–9 seats | 2–4 axles, max 2 wheels per axle | |
1c | Electric vehicles | ||
1d | Hybrid vehicles | ||
Medium heavy vehicles | 2a | Buses | 2 axles (6 wheels) |
2b | Light trucks and heavy vans | 2 axles (6 wheels) | |
2c | Medium heavy trucks | 2 axles (6 wheels) | |
2d | Trolley buses | 2 axles (6 wheels) | |
2e | Low noise design | 2 axles (6 wheels) | |
Heavy vehicles | 3a | Buses | 3–4 axles |
3b | Heavy trucks | 3 axles | |
3c | Heavy trucks | 4–5 axles | |
3d | Heavy trucks | ≥6 axles | |
3e | Low noise design | ≥3 axles | |
Other heavy vehicles | 4a | Construction trucks (partly off-road use) | |
4b | Agr. tractors, machines, dumper trucks, tanks | ||
Two-wheelers | 5a | Mopeds, scooters | Include also 3-wheel motorcycles |
5b | Motorcycles |
Land Use Destination Class | Reference Times | |
---|---|---|
Daytime (6:00–22:00) | Night (22:00–6:00) | |
I—particularly protected areas | 45 | 35 |
II—mainly residential areas | 50 | 40 |
III—mixed type areas | 55 | 45 |
IV—area of intense human activity | 60 | 50 |
V—mainly industrial areas | 65 | 55 |
VI—exclusively industrial areas | 65 | 65 |
Road Type | Road Sub-Type | Pertinence Range Width [m] | Schools and Hospitals | Other Receivers | ||
---|---|---|---|---|---|---|
Daytime dB(A) | Night dB(A) | Daytime dB(A) | Night dB(A) | |||
D—arterials | Da (separate carriageways) | 100 | 50 | 40 | 70 | 60 |
Db (other arterials) | 100 | 50 | 40 | 65 | 55 | |
E—urban collectors | 30 | Defined by Municipalities, according to the acoustical zoning of the urban area. | ||||
F—locals | 30 |
Acoustic Capacity | Physical Capacity |
---|---|
1300 veh/h per direction | 1900 veh/h per direction |
Link | Acoustic Capacity (veh/h) | Physical Capacity (veh/h) |
---|---|---|
Link 1 (section in light blue) | 1050 | 1500 |
Link 2 (section in light blue) | 1050 | 1900 |
Link 3 (section in orange) | 850 | 1700 |
Link 4 (section in orange) | 1065 | 1900 |
Link 5 (section in green) | - | 224 |
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. |
© 2021 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
Share and Cite
Lupi, M.; Pratelli, C.; Farina, A. A Methodology for the Definition of the Acoustic Capacity of a Road Infrastructure. Sustainability 2021, 13, 11920. https://doi.org/10.3390/su132111920
Lupi M, Pratelli C, Farina A. A Methodology for the Definition of the Acoustic Capacity of a Road Infrastructure. Sustainability. 2021; 13(21):11920. https://doi.org/10.3390/su132111920
Chicago/Turabian StyleLupi, Marino, Chiara Pratelli, and Alessandro Farina. 2021. "A Methodology for the Definition of the Acoustic Capacity of a Road Infrastructure" Sustainability 13, no. 21: 11920. https://doi.org/10.3390/su132111920
APA StyleLupi, M., Pratelli, C., & Farina, A. (2021). A Methodology for the Definition of the Acoustic Capacity of a Road Infrastructure. Sustainability, 13(21), 11920. https://doi.org/10.3390/su132111920