Unveiling the relationship between pavement surface texture and roughness and the energy loss of a tire: The rolling resistance in a battery electric vehicle
Restricted accessResearch articleFirst published online 2026
Unveiling the relationship between pavement surface texture and roughness and the energy loss of a tire: The rolling resistance in a battery electric vehicle
A significant portion of the energy used to propel a vehicle is dissipated as rolling resistance (RR) in the tire-road interaction. Largely due to the hysteretic losses resulting from the cyclical deformations of the tire's viscoelastic material as the tread engages with asperities of different wavelengths, RR depends on the tire and pavement surface characteristics. However, factors related to vehicle and ambient conditions also play a role. In particular, specifics of battery electric vehicles (BEVs) like the increased tire load and different torque performance compared to equivalent-sized internal combustion engine vehicles are expected to increase the RR and induced energy consumption. This paper investigates the relationship between the pavement surface characteristics and the RR in a passenger BEV. To this end, experimental measurements of the RR were performed in conditions close to real driving. They involved an instrumented BEV equipped with two dynamometric wheels acting as tribometers, driven on a test track featuring several asphalt pavement sections of diverse texture and roughness levels, and differing in age and wearing course. Standardized descriptors of these surface properties were then correlated with the corresponding measured RR coefficients. Different segmentation strategies were applied to derive the values of the metrics. The results (1) validate correlations previously observed in drum- and trailer-based measurements and (2) reveal how local variations in pavement surface characteristics influence RR. These findings may support road pavement managers in the design of pavement management strategies that potentialize the environmental benefits offered by passenger BEVs.
VezaIAsy’ariMZIdrisM, et al.Electric vehicle (EV) and driving towards sustainability: comparison between EV, HEV, PHEV, and ICE vehicles to achieve net zero emissions by 2050 from EV. Alexandria Eng J2023; 82: 459–467.
PamidimukkalaAKermanshachiSRosenbergerJM, et al.Barriers and motivators to the adoption of electric vehicles: a global review. Green Energy and Intelligent Transportation2024; 3: 100153.
SchuringDJ. The rolling loss of pneumatic tires. Rubber Chem Technol1980; 53: 600–727.
6.
LaClairTJ. Rolling resistance. In: The pneumatic tire. Washington, DC: National Highway Traffic Safety Administration, U. S. Department of Transportation, 2006, pp.475–532.
7.
SohaneyR. Pavement texture evaluation and relationships to rolling resistance at MnRoad. Minneapolis, MN: Minnesota Department of Transportation, 2013.
8.
GuFWestRPowellB. Influence of asphalt pavement characteristics on vehicular rolling resistance. Auburn, AL: National Center for Asphalt Technology, 2020.
9.
SandbergUHammarströmUHaiderM, et al. Rolling resistance: Basic information and state-of- the-art on measurement methods. MIRIAM Project, 2011.
10.
EjsmontJSjögrenLŚwieczko-ŻurekB, et al.Influence of road wetness on tire-pavement rolling resistance. Journal of Civil Engineering and Architecture2015; 9: 1302–1310.
11.
EjsmontJTarymaSRonowskiG, et al.Influence of load and inflation pressure on the tyre rolling resistance. International Journal of Automotive Technology2016; 17: 237–244.
12.
YdreforsLHjortMKharraziS, et al.Rolling resistance and its relation to operating conditions: a literature review. Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering2021; 235: 2931–2948.
13.
CerezoVSantosJBouteldjaM, et al. Relationship between driving conditions, pavement surface characteristics and rolling resistance. IN: Roads and airports pavement surface characteristics. London, UK: CRC Press (Taylor & Francis Group), 2023, pp.600–608.
14.
AratMBolarinwaEO. Rolling resistance effect of tire road contact in electric vehicle systems. Detroit, MI: SAE 2015 World Congress & Exhibition, 2015.
15.
MattinzioliTButtAAHarveyJ. Literature review on pavements and electric vehicle interaction: a research roadmap. Transp Res D-Transp Environ2023; 122: 103886.
HolmbergKErdemirA. The impact of tribology on energy use and CO2 emission globally and in combustion engine and electric cars. Tribol Int2019; 135: 389–396.
18.
AkbarianMMoeini-ArdakaniSSUlmF-J, et al.Mechanistic approach to pavement–vehicle interaction and its impact on life-cycle assessment. Transp Res Rec: J Transp Res Board2012; 2306: 171–179.
19.
HoeverCKroppW. A model for investigating the influence of road surface texture and tyre tread pattern on rolling resistance. J Sound Vib2015; 351: 161–176.
20.
RajaeiSChattiK. Mechanistic modeling of macro-texture’s effect on rolling resistance. In: Advances in materials and pavement performance prediction II. London, UK: CRC Press (Taylor & Francis Group), 2020, pp.228–231.
21.
DingYWangHQianJ, et al.Evaluation of tire rolling resistance from tire-deformable pavement interaction modeling. Journal of Transportation Engineering, Part B: Pavements2021; 147: 04021041.
22.
Anfosso-LédéeFCerezoVKarlssonR. Experimental validation of the rolling resistance measurement method including updated draft standard. ROSANNE Project, 2016.
23.
EjsmontJARonowskiGŚwieczko-ŻurekB, et al.Road texture influence on tyre rolling resistance. Road Materials and Pavement Design2017; 18: 181–198.
24.
VieiraT. Rolling resistance evaluation of winter tyres on in-service road surfaces. Tire Science and Technology2021; 49: 78–103.
25.
GuiggianiM. The science of vehicle dynamics: handling, braking, and ride of road and race cars. Cham, Switzerland: Springer, 2018.
26.
ISO 13473-1:2019, Characterization of pavement texture by use of surface profiles – Part 1: determination of mean profile depth.
27.
ASTM E1926-08:2021, Standard practice for computing international roughness index of roads from longitudinal profile measurements.
28.
EN 13036-5:2019, Road and airfield surface characteristics – test methods – part 5: determination of longitudinal unevenness indices.
29.
BergiersAGoubertLAnfosso-LédéeF, et al.Comparison of Rolling Resistance Measuring Equipment - Pilot Study. MIRIAM Project, 2011. https://miriam-project.eu/publications
30.
EjsmontJRonowskiGYdreforsL, et al.Comparison of tire rolling resistance measuring methods for different surfaces. International Journal of Automotive Technology2024; 25: 965–976.
31.
CenekPD. Rolling resistance characteristics of New Zealand road surfaces. In: Vehicle-road interaction. West Conshohocken, PA: ASTM International, 1994, pp.248–262.
FontarasGDilaraPBernerM, et al.An experimental methodology for measuring of aerodynamic resistances of heavy duty vehicles in the framework of European CO2 emissions monitoring scheme. SAE International Journal of Commercial Vehicles2014; 07: 102–110.
34.
KomnosDBroekaertSZacharofN, et al.A method for quantifying the resistances of light and heavy-duty vehicles under in-use conditions. Energy Convers Manage2024; 299: 117810.
35.
PassmoreMAJenkinsEG. A comparison of the coastdown and steady state torque methods of estimating vehicle drag forces. Detroit, MI: SAE International Congress and Exposition, 1988.
36.
ISO 28580:2018, Passenger car, truck and bus tyre rolling resistance measurement method: single point test and correlation of measurement results.
37.
EjsmontJTarymaSRonowskiG, et al.Influence of temperature on the tyre rolling resistance. International Journal of Automotive Technology2018; 19: 45–54.
38.
ChenSLiuXLuoH, et al.A state-of-the-art review of asphalt pavement surface texture and its measurement techniques. Journal of Road Engineering2022; 2: 156–180.
39.
EjsmontJSommerS. Selected aspects of pavement texture influence on tire rolling resistance. Coatings2021; 11: 76.
40.
HammarströmUErikssonJKarlssonR, et al. Rolling resistance model, fuel consumption model and the traffic energy saving potential from changed road surface conditions. Linköping, Sweden: Statens väg- och transportforskningsinstitut, 2012.
41.
RajaeiSChattiK. Mechanistic modeling of the effect of pavement surface profile on rolling resistance. Okemos, MI: Center for Highway Pavement Preservation, 2020.
