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ACTA IMEKO 
December 2014, Volume 3, Number 4, 32 – 37 
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ACTA IMEKO | www.imeko.org December 2014 | Volume 3 | Number 4 | 32 

Techniques for on-board vibrational passenger comfort 
monitoring in public transport 

Ileana Bodini, Matteo Lancini, Simone Pasinetti, David Vetturi 

University of Brescia – Department of Mechanical and Industrial Engineering, via Branze 38, 25123 Brescia, Italy 

Section: RESEARCH PAPER  

Keywords: Vibrational on-board comfort, geo-referenced comfort measurement, thematic maps 

Citation: Ileana Bodini, Matteo Lancini, Simone Pasinetti, David Vetturi, Techniques for on-board vibrational passenger comfort monitoring in public 
transport, Acta IMEKO, vol. 3, no. 4, article 7, December 2014, identifier: IMEKO-ACTA-03 (2014)-04-07 

Editor: Paolo Carbone, University of Perugia  

Received October 11
th

, 2013; In final form January 14
th

, 2014; Published December 2014 

Copyright: © 2014 IMEKO. This is an open-access article distributed under the terms of the Creative Commons Attribution 3.0 License, which permits 
unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited 

Funding: (none reported) 

Corresponding author: Ileana Bodini, e-mail: Ileana.bodini@ing.unibs.it 

1. INTRODUCTION

The use and the development of collective transport systems
are encouraged by public institutions in order to improve 
mobility and accessibility in urban areas. These aspects are also 
key elements in the development of “smart cities”. Therefore, 
the increase of service quality and safety is fundamental in 
making public transport systems more attractive than private 
vehicles [1]. 

Service quality is usually evaluated in terms of accessibility to 
the transport system, timing flexibility and other properties of 
the transport network, while a comfort analysis is usually 
focused on the vehicle itself, even if its results depend also on 
roads and infrastructures. 

Developments in laws [2] and some researches [3, 4, 5] have 
put in evidence two different aspects that could seem to be in 
contrast: one is the necessity to improve road safety, by 
introducing traffic calming measures, such as roundabouts, 
speed bumps, chicanes, elevated pedestrian crossings or 

different types of pavements; the second is the attention to the 
exposure of workers and passengers to vibration also on public 
transport vehicles, and its effect on transport quality. Until now 
many authors have been studying traffic calming devices and 
public transport passengers interaction [6, 7, 8, 9]. 

The purpose of this work is to give useful information to the 
designers of both vehicles and infrastructures; in particular this 
research is aimed at defining a technique to evaluate how traffic 
calming devices affect the acceleration that road public 
transport passengers perceive and to provide a low-cost device 
to easily measure and monitor vibration level on road public 
transport. Therefore, taking as a reference the European 
regulations on rail transports [10], the researchers propose the 
definition of a vibrational comfort index that allows to 
characterize and compare different road infrastructures and that 
could also be useful to compare behaviours of vehicles related 
to road infrastructure and to monitor vehicle maintenance state.  

ABSTRACT 
Traffic calming devices on urban streets, such as elevated pedestrian crossings, speed bumps and roundabouts, are increasingly used, 
raising a real problem in relation to the on-board comfort that passengers perceive. To measure vibrational comfort related to traffic 
calming devices that passengers of the public transport perceive, an acquisition system called ASGCM (Autonomous System for Geo-
referenced Comfort Measurements) has been developed, taking as a reference the European regulations on rail transports. ASGCM 
permits to link each measurement of vibration, ground velocity and acceleration with geographical information resulting from a GPS. 
In this way a map of a comfort index, statistical surveys and correlation between on-board comfort and traffic calming, can be directly 
obtained by any Geographic Information System (GIS), able to query a centralized remote database, which was developed ad-hoc. A 
large number of experimental tests has been performed to define a vibrational comfort index and to collect a large dataset that allows 
statistically significant comparisons between different infrastructures and their characterization. The proposed technique can also be 
useful for diagnostics purposes, such as vehicle comparison and road maintenance state monitoring. 



 

ACTA IMEKO | www.imeko.org December 2014 | Volume 3 | Number 4 | 33 

To calculate a comfort index and to correlate it with a given 
location, accelerations and GPS positions are needed. In 
Section 2 an ASGCM (Autonomous System for Geo-referenced 
Comfort Measurements) measurement system, that consists of 
the measurement chain and the processing system that allow to 
collect data and make them available, is described. In Section 3 
the proposed comfort index is defined, and in Section 4 
different types of data analysis are proposed. Finally, in Section 
5, the comfort index validation is discussed. 

2. MEASUREMENT AND PROCESSING SYSTEM 

To assess the on-board comfort that bus passengers perceive 
due to traffic calming devices, an ad-hoc measurement system, 
called ASGCM (Autonomous System for Geo-referenced 
Comfort Measurements) has been developed. This is 
autonomous for long periods of time and acquires, processes, 
and records data without requiring specialized staff [11]. 

To monitor on-board comfort, two quantities are needed: 
comfort level and geographical location. The measurement 
chain consists of a capacitive triaxial accelerometer mounted 
along the three principal orthogonal axes, a NI Compact-RIO, 
an analogue input module, supply and connection cables, a 
commercial GPS antenna, and an USB Flash memory. Both the 
accelerometer and the NI Compact-RIO are battery-powered. 

The comfort level has been calculated taking into account 
both infrastructural effects, involving low frequencies, and 
vibration effects. These have been measured using a triaxial 
accelerometer, with an acquisition rate of 1000 Hz and a buffer 
of 1000 samples. In one second of acquisition the buffer is 
filled up and data are processed using a band-pass filter, from 
0.5 Hz to 300 Hz, designed according to the human response to 
vibration filters [10, 12]: acceleration magnitude is computed as 
a vector sum of the three accelerations acquired in orthogonal 
directions (the x-axis corresponds to the road direction, the y-
axis is in the road plane and orthogonal to the x-axis, and the z-
axis is perpendicular to the road plane) and an RMS 
acceleration value is calculated, considering a period of 5 
seconds. This period of time represents a compromise between 
the acquisition of low frequency vibrations and a statistically 
relevant number of samples. 

The time needed to fill the buffer is adequate to query the 
GPS: each second a standard NMEA (National Marine 
Electronics Association) RMC (Recommended Minimum 

sentence C) string is recorded [13]. This string contains 
information of position, velocity and time. Due to this 
procedure, illustrated in Figure 1, information of vibration, 
position and velocity related to the same second, are associated 
with a single geographical point. 

3. INDEX CHOICE 

The European regulation on rail transport [10] defines 
different types of comfort index; the one for standing 
passengers is called NVD. This has been adapted for road 
transport and has been calculated following equation (1), 

wy
a

wz
a

wy
a

wx
aNVD  5

22
4

2
163  (1) 

where 
wx

a is the RMS (Root Mean Square) weighed 

longitudinal acceleration, 
wy

a is the RMS weighed lateral 

acceleration and 
wz

a is the RMS weighed vertical acceleration. 

Weighing is performed following European regulations and 
considering the human response to vibration frequency filters 
[10, 12]. The higher the NVD value the greater the on-board 
discomfort. 
As stated before, each second, this comfort index is linked to 
vehicle velocity and GPS coordinates and the results are 
updated to a remote database which could then be queried, in 
order to obtain thematic maps and statistical analyses. 

4. ANALYSIS RESULTS 

4.1. Analysis of manoeuvres and infrastructures 

Querying the developed database, kinematic parameters, 
such as speed and accelerations, related to vehicle vibrational 
comfort, can be analyzed. As a first result these parameters can 
be plotted as a function of time and position, as shown in 
Figure 2. 

This type of analysis gives detailed information strictly 
related to every single passage of a chosen vehicle through a 
considered infrastructure, which can therefore be very 
accurately studied. However this kind of analysis is not very 
appropriate to monitor a complete public transport network or 
to evaluate an infrastructure design, because many external 
parameters such as driver, weather, bus crowding and traffic 
conditions can affect the measurement. These are important 

 

Figure 1. Flow chart of the automated acquisition procedure of ASGCM. 

http://www.nmea.org/
http://www.nmea.org/


 

ACTA IMEKO | www.imeko.org December 2014 | Volume 3 | Number 4 | 34 

factors that can be considered, for example, when discomfort 
causes have to be investigated. 

4.2. Geographical analysis 

To obtain less detailed but more significant information, the 
acquired data have to be aggregated. A first approach consists 
in a geographically-based aggregation obtained by dividing the 
urban map in a grid of a chosen step (for example 1 m), and 
then associating to each cell the mean value of the parameter 
under study, in particular the NVD index. To take into account 
the geographical distribution of the data, the generic parameter 
is weighed using the inverse of the squared distance between 
the centre of the cell and the recorded position of each sample, 
following the widely accepted Inverse Distance Weighing 

method. In this way a mean value of the chosen parameter has 
been calculated, taking into account both geographical 
distribution of the data and different runs of the vehicle, in 
different conditions, in the same geographical position. 

Figure 3 shows a thematic map of the comfort index of a 
particular bus route as an average of a large number of 
acquisitions. In particular the bus route is superimposed on the 
city cartography: very uncomfortable spots (in red) as well as 
comfortable ones (in blue) are evidenced. 

In general, thematic maps can be very useful to correlate a 
physical quantity, such as vehicle speed, acceleration vector, on-
board comfort, with a given infrastructure, for example a 
roundabout, a speed bump or an elevated pedestrian crossing. 

 

Figure 2. Kinematic parameters (speed and acceleration) and NVD index on 
the same roundabout. 

 

Figure 3. Thematic map of a portion of a bus route of the NVD comfort 
index, superimposed on the city cartography. 

35302520151050

0.12

0.10

0.08

0.06

0.04

0.02

0.00

NVD

D
e

n
s
it

y

Mean 9.807

StDev 4.067

N 2125

Histogram of NVD
Normal 

35

30

25

20

15

10

5

0

N
V

D

Boxplot of NVD

 

Figure 4. NVD comfort index statistical analysis. 



 

ACTA IMEKO | www.imeko.org December 2014 | Volume 3 | Number 4 | 35 

However, using this kind of analysis, it is not possible to define 
different levels of index NVD related to real situations of 
comfort or discomfort, therefore thematic maps such as that 
shown in Figure 3 can be only used to define areas of relative 
discomfort with respect to the acquired data, without being able 
to point out which is actually the level of criticality itself. 

4.3. Statistical analysis 

A second approach to data aggregation consists in isolating 
some identified infrastructures or situations of interest, such as 
crossings, elevated pedestrian crossings, roundabouts, straight 
roads and considering the interesting physical quantities related 
to these infrastructures (such as vehicle speed, accelerations, 
on-board comfort) as stochastic variables over which a 
statistical analysis can be performed. 

This allows to point out known situations of high comfort 
levels (straight roads with good pavement conditions) and low 
comfort levels (roundabouts, raised bumps) and to statistically 
investigate the corresponding NVD levels to develop a 
quantitative scale of the index of comfort. 

The proposed method of analysis consists in selecting a path 
portion with fixed length, centred on the chosen infrastructure, 
and in assessing some important statistical parameters of the 
distribution of the variable of interest, in particular its 
Probability Distribution Function (PDF), its Cumulative 
Distribution Function (CDF), a box plot and the 95th percentile 
of the distribution. This last parameter depends less on 
impulsive NVD index variations, not relevant from a statistical 
point of view, than the maximum NVD value, therefore, it has 
been chosen to summarize the complete distribution with a 
single number. A box plot is able, in particular, to synthetically 
indicate the trend of the probability distribution through the 

identification of its quartiles. 
As an example, referring to the roundabout proposed in 

Figure 2 and considering the NDV index as a stochastic 
variable, it is possible to study some statistical parameters, that 
give brief information about comfort (or discomfort) level 
related to the chosen infrastructure. Figure 4 shows the 
histogram of the distribution and a box plot of NVD indexes 
associated with the roundabout. A further example is given in 
Figure 5, which represents the NVD index of a single run as a 
function of position along the path (inside the inspection radius 
centred on the roundabout) and puts in evidence (dotted line) 
that the 95th percentile of the NVD can be used to represent 
the worst on-board vibrational comfort condition, which occurs 
when the bus enters the selected infrastructure. 

The complete statistical population includes all runs through 
an infrastructure (or through the whole route) of the same 
vehicle in different traffic, bus crowding, weather conditions 
and for different drivers. Each one of these parameters is a 
possible analysis criterion and a possible query for the database. 

Following the described method, different statistical analyses 
have been performed; in particular, it is possible to represent 
cumulative distribution functions of the comfort index of a 
complete bus route or of a chosen type of infrastructure, such 
as roundabouts, elevated pedestrian crossings or straight roads. 
Figure 6 shows these cumulative distributions and allows to 
compare the comfort index of the whole route with that related 
to a particular type of infrastructure, giving brief information 
about on-board comfort of a specific bus route and allowing 

 

Figure 5. NVD comfort index – 95
th

 percentile. 

 

Figure 6. Comparison between cumulative distribution functions of the 
complete route for different infrastructures (straight roads, elevated 
pedestrian crossings and roundabouts). 

 

Figure 7. Comparison between box plots of different infrastructures 
(straight roads (SR), elevated pedestrian crossings (PC) and roundabouts 
(RO)) on the whole route. 

 

Figure 8. Comparison between box plots of different roundabouts. 



 

ACTA IMEKO | www.imeko.org December 2014 | Volume 3 | Number 4 | 36 

for a comfort-based classification of specific traffic calming 
devices or road infrastructures. A comparison between comfort 
indexes related to different types of traffic calming devices and 
road infrastructures is also shown in Figure 7, using box plots 
as the statistical method. 

Figure 8 shows that it is also possible to compare different 
traffic calming devices of the same type, such as roundabouts, 
and to study comfort index distribution of buses crossing such 
infrastructures. In particular, Figure 8 represents the 
comparison between different roundabouts of the same bus 
route and box plot are sorted according to diameter size; data 
were acquired using the same model of bus. Due to this kind of 
graph it is possible to deduce if roundabouts with different 
diameters present different levels of comfort. Another 
parameter that could be taken into account is the type of 
manoeuvre on roundabouts with the same geometry. 

5. INDEX VALIDATION 

To validate the proposed NVD Index, an analysis of 
correlation between instrumental comfort measurements and 
individual comfort perception has been performed. The 
individual perception of the comfort/discomfort level, on a 
selected bus route, has been evaluated by a test panel jury of 
more than 30 passengers who were asked repeatedly to express 
an evaluation of their perception in relation to different 
infrastructures (straight road, pedestrian crossing, roundabout, 
etc.), just few moments after their occurrence, for the whole 
duration of the chosen track. 

The evaluation is given using a score that varies from 0, 
when the situation is perceived as very comfortable, to 4, when 
the situation is very uncomfortable. This ranking system is 
explained in advance to each subject to avoid misevaluation. 

For all devices under investigation, mean value and standard 
deviation have been calculated. As an example, Figure 9 shows 
a distribution of jury responses on subjectively perceived 
comfort levels: in the graph each judgment (qualitative 
indication) is associated with a numerical value (quantitative 
indication) and the average value of judgment has also been 
reported.  

To search for a significant correlation, the NVD index 
related to each studied infrastructure was considered a 
stochastic variable and the 95th percentile of its distribution was 
chosen to synthesize the discomfort of the considered 
infrastructure. A linear regression was the result of a simple 

least square approach [13], between this indicator and the 
average of the panel responses. 

A linear relation has been found (R=96%) between the 95th 
percentile of the NVD distributions and test panel opinions, 
associating the best comfort levels found (mean evaluation 0.2 
– close to “very good” comfort) with an NVD level of 5 and 
the highest discomfort (mean evaluation 4 – “very bad”) with 
an NVD level of 25. This relationship is shown in Figure 10 
and could be used, as proposed by the authors, to define 
threshold values for comfort index. 

6. CONCLUSIONS 

A portable and autonomous measuring device for on-board 
comfort measurements on local transport buses has been set 
up, and specific software for retrieving from multiple devices, 
stocking and localizing data on the whole local transport 
network has been created. Automated tools for a geographical 
analysis of collected data with a standard GIS interface have 
also been developed and statistical analysis of the influence of 
specific traffic calming devices on on-board comfort was made 
feasible using the data collected.  

A linear correlation between the results obtained by the 
measurement system and subjective perception of discomfort 
by a panel jury has been found, validating the authors’ proposal 
of a modified NVD index for road vehicles for public 
transportation. In particular, the proposed analysis 
methodology allows, thanks to comfort thematic maps, to 
identify critical points, geographically localized, on a particular 
route, thus making  possible a fast maintenance work if needed 
or pointing out comfort problems related to traffic calming 
devices or particular traffic and infrastructure conditions. Using 
the proposed index it is possible to compare different bus 
routes, different types of infrastructures, different types of bus 
travelling on the same route, different infrastructure of the 
same type that differs from geometry or for crossing 
manoeuvres. 

Systematic acquisition of data regarding the whole transport 
network of a chosen area could allow to monitor the temporal 
evolution of vibrational comfort of the road network that is 
related to traffic conditions, road surface damages, presence of 
traffic calming devices. In this way, not only the general 
appreciation of the public transport system could be assessed, 
but also the temporal development of road conditions, as well 
as the interactions between subsequent traffic calming devices 
or road infrastructures. 

 

Figure 9. Relation between NVD index and panel evaluation. 

 

Figure 10. Linear relation between 95
th

 percentile of NVD index and panel 
evaluation. 



 

ACTA IMEKO | www.imeko.org December 2014 | Volume 3 | Number 4 | 37 

ACKNOWLEDGEMENT 

Authors would like to thank Brescia Trasporti, and its bus 
drivers, for the support received, prof. G. Maternini for 
comments and insights and prof. F. Docchio for careful reading 
and discussion. 

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