Attention of Driver during Simulated Drive
Roman Mou
ˇ
cek and Vojt
ˇ
ech Ko
ˇ
sa
ˇ
r
Department of Computer Science and Engineering, New Technologies for the Information Society,
Faculty of Applied Sciences, University of West Bohemia, Univerzitn
´
ı 8, 306 14 Plze
ˇ
n, Czech Republic
Keywords:
Neuroinformatics, Electroencephalography, Event Related Potentials, Driver’S Attention, Simulated Drive,
Car Simulator, P3 Component, Daytime, Sleep Deprivation, Peak Latency, Fractional 50% Peak Latency,
Fractional 50% Peak Area.
Abstract:
Attention of drivers is a key factor of road safety. Since inattentive drivers cause a considerable number of
accidents, it is worth to examine the causes and course of driver’s attention even in laboratory conditions during
a simulated drive. This paper deals with the experiment in which the methods of electroencephalography and
event related potentials are used under various conditions to investigate driver’s attention. Eleven participants,
university students, were stimulated with audio signals during monotonous drive in four experimental sessions.
The hypothesis is that the peak latency of the P3 component increases in time as the driver is more tired from
monotonous drive, daytime and sleep deprivation. The background of the used methods, experimental design,
participants, data processing, results and final discussion are presented in this paper.
1 INTRODUCTION
Attention of drivers is a key factor of road safety.
Inattentive drivers are dangerous to their surroundings
and cause a considerable number of accidents. How-
ever, decline of attention, especially during long rides,
is natural.
In this paper we focus on influence of monotonous
drive on driver’s attention during simulated drive.
Moreover, attention of driver can be also influenced
by daytime and sleep deprivation. This is not inves-
tigated by using common behavioral techniques; the
methods of electroencephalography (EEG) and event
related potentials (ERP) are used. An ERP auditory
experiment is performed during a drive (a car simula-
tor is used) and the subsequent analysis of the changes
in the peak latency of the P3 component is investi-
gated. The hypothesis is that the peak latency of the
P3 component (peak latency represents the level of
driver’s attention) increases in time as the driver is
more tired from monotonous drive, daytime and/or
sleep deprivation. University students as tested sub-
jects participated in the EPR experiment; their results
were analyzed and partially interpreted. However,
a deep analysis that includes e.g. statistical evalua-
tion of the results is still in progress and thus it is
not described in this paper. The paper builds on the
already published experiments and results (Moucek
and Rondik, 2012) and (Moucek and Rericha, 2012)
provided by the authors research group. These exper-
iments are based on the same hypothesis but their de-
sign differs and evolves in time according to previous
experience and knowledge.
The paper is organized as follows. Section 2 gives
a short overview of basic principles of the ERP tech-
nique and assumptions related to P3 amplitude and
P3 latency. It provides readers with essential ideas
that are important for the design of experiments de-
scribed further. Then the experiments dealing with at-
tention of drivers are summarized and extended with
respect to the papers (Moucek and Rondik, 2012)
and (Moucek and Rericha, 2012). The objectives of
the designed experiment are given in Section 3. The
description of experimental design, hardware equip-
ment, software tools, participants, course of experi-
ment, environment and obtained data and metadata is
given in Section 4. Data preprocessing is presented in
Section 5; experimental results extended by the final
discussion are provided in Section 6.
2 STATE OF THE ART
This section provides a short description of the ERP
technique, the P3 component and especially the re-
lation of P3 amplitude and P3 latency to attention.
Then a short overview of EEG/ERP experiments deal-
543
Mou
ˇ
cek R. and Koša
ˇ
r V..
Attention of Driver during Simulated Drive.
DOI: 10.5220/0004934905430550
In Proceedings of the International Conference on Health Informatics (HEALTHINF-2014), pages 543-550
ISBN: 978-989-758-010-9
Copyright
c
2014 SCITEPRESS (Science and Technology Publications, Lda.)
ing with driver’s attention is presented.
2.1 Event Related Potentials and P3
Component
ERPs were first used as an alternative to measure-
ments of the speed and accuracy of motor responses in
paradigms with discrete stimuli and responses. They
have two advantages compared to behavioral meth-
ods: they are useful for determining which stage or
stages of processing are influenced by a given exper-
imental manipulation (a detailed set of examples is
in (Luck et al., 2000)) and they provide an online mea-
sure of the processing of stimuli even when there is no
behavioral response (Luck, 2005).
The P3 component depends entirely on the task
performed by the subject and is not directly influ-
enced by the physical properties of the stimulus. It
is sensitive to a variety of global factors, such as time
since the last meal, weather, body temperature, and
even day time or the time of year (Luck, 2005). Al-
though thousands of experiments related to the P3
component have been published, we still do not know
exactly what the P3 component really means. The
proposal that the P3 component is related to a process
called context updating seems to be approximately
correct (Luck, 2005).
On the other hand, there are known the factors
which influence the amplitude and the latency of the
P3 component that is sensitive to the probability of
the target stimulus. Ideas and assumptions related to
the latency of the P3 component are associated with
stimulus categorization. If stimulus categorization is
postponed (it also includes increasing the time re-
quired for low-level sensory processing), P3 latency
is increased. While P3 latency depends on the time
required to stimulus categorization, it does not de-
pend on consequent processes (e.g. response selec-
tion). Thus P3 latency can be used to determine if
a performed experiment influences the processes of
stimulus categorization or processes related to a re-
sponse (Luck, 2005).
In our case we suppose that stimulus categoriza-
tion is influenced by driver fatigue and the time re-
quired for low-level sensory processing of incoming
stimuli increases with the level of fatigue.
2.2 Experiments on Driver’s Attention
Omitting behavioral studies not many experiments
dealing with driver’s attention during simulated drive
were performed using the techniques of electroen-
cephalography and event related potentials.
Suitability of EEG-based techniques is described
in (Schier, 2000); drivers’ activity during a driving
simulation task was recorded. As the result, an in-
crease in alpha activity was interpreted as less atten-
tional activity and a decrease as more attentional ac-
tivity.
EEG data as an effective indicator to evaluate
driver fatigue are presented in (Li et al., 2012). The
evaluation model for driver fatigue was established
with the regression equation based on the EEG data
from two significant electrodes Fp1 and O1. The ac-
curacy of the model was about 92.3%.
The impact of a surrogate Forward Collision
Warning System and its reliability according to the
driver’s attentional state by recording both behav-
ioral and electrophysiological data was presented
in (Bueno et al., 2012). These results showed that
electrophysiological data could be a valuable tool to
complement behavioral data and to have a better un-
derstanding of how these systems impact the driver.
The effect of a normal night’s sleep vs. prior
sleep restricted to five hours, in a counterbalanced de-
sign, on prolonged (two hours) afternoon simulated
driving in 20 younger and 19 older healthy men was
studied in (Filtness et al., 2012). After sleep re-
striction younger drivers showed significantly more
sleepiness-related deviations and greater 4 to 11 Hz
EEG power, indicative of sleepiness.
The ERP technique was used in (Wester et al.,
2008) where the impact of secondary task perfor-
mance (an auditory oddball task) on a primary driv-
ing task (lane keeping) was investigated. The study
showed that when performing a simple secondary task
during driving, performance of the driving task and
this secondary task are both unaffected (Wester et al.,
2008).
3 OBJECTIVES OF
EXPERIMENT
The assumptions described in Section 2 have been
taken into account during designing the experiment.
Then the objectives of the experiment are:
• To construct a monotonous track where a substan-
tial decrease of attention is supposed.
• To design and implement a simple auditory ERP
experiment.
• To perform the auditory ERP experiment on the
group of participants in the following way: each
participant undergoes four drives in a car simula-
tor, these drives are held in two days, one drive
in the morning (between 9 and 12 AM) and one
HEALTHINF2014-InternationalConferenceonHealthInformatics
544
drive in the afternoon (between 1 and 4 PM). The
participant completes first two drives after a usual
night’s sleep, while the other two drives are com-
pleted after a sleep restricted to a maximum of
four hours.
• To divide each drive into time intervals of the
same length.
• To compare the latency of the averaged P3 com-
ponents depending on daytime and sleep depriva-
tion and to evaluate results to confirm/reject the
hypothesis given in Section 1.
4 DESIGN OF EXPERIMENT
A simple auditory ERP protocol was designed. All
participants were elicited by the following three audi-
tory stimuli:
• non-target stimulus S1 is a harmonious tone at
a frequency of 560 Hz, duration time 500 ms with
probability of occurrence p = 0.86,
• target stimulus S2 is a harmonious tone at a fre-
quency of 880 Hz, duration time 500 ms with
probability of occurrence p = 0.11,
• rare stimulus S3 is a continuous change of a har-
monious tone at a frequency of 200 Hz to a har-
monious tone at a frequency of 1000 Hz and back,
duration time 1000 ms, probability of occurrence
p = 0.03.
The stimulus onset asynchrony (SOA) was set to
1500 ms. Two target stimuli cannot be sequential.
The stimuli were played from the speakers inside the
car simulator.
Each drive was 20 minutes long and consisted of
four sub-sessions. Each sub-session was five minutes
long, participants were stimulated in the second and
fourth sub-session. The first and third sub-sessions
served both for relaxation of the participant and for
preventing the participant from familiarity with the
presented stimuli. During all stimulation sessions the
participants drove the car simulator on a monotonous
track. The participant responded to the target stimulus
by changing lanes.
4.1 Hardware Equipment
All experiments were performed in the neuroinfor-
matics laboratory at Department of Computer Sci-
ence and Engineering, University of West Bohemia,
equipped with all necessary hardware devices for
EEG/ERPs recording. The experimental car simula-
tor was equipped with the Logitech G27 wheel, ac-
celerator, and brake. Four computers were used: the
first one for presentation of stimuli, the second one for
storing recorded data, the third one for the presenta-
tion of the track, and the fourth one for storing video
recordings of drivers from the cab of the car simula-
tor. The track was projected on the wall in front of the
car simulator. V-Amp was used as an EEG amplifier.
4.2 Software Tools
The stimulation protocol was implemented in the Pre-
sentation software tool produced by Neurobehavioral
Systems, Inc (Neuro Behavioral Systems, 2013). The
protocol itself was five minute long. The sequence
of stimuli was generated randomly, but it always con-
tained the same number of target, non-target, and rare
stimuli. The harmonious tones were generated in the
Audacity software tool. The track was prepared us-
ing the World Racing 2 game produced by the Sy-
netic Company (SYNETIC GmbH, 2013). There was
used the same track as in (Moucek and Rericha,
2012). The BrainVision Recorder (Brain Products,
2013b) was used for recording and storing EEG/ERP
data and the BrainVision Analyzer (Brain Products,
2013a) was used for processing raw EEG/ERP data.
4.3 Recording System
Common EEG caps (the 10-20 system defining the
location of scalp electrodes) were used depending on
the size of the participants’ heads. The reference elec-
trode was placed above the nose and the ground elec-
trodes were placed on ears.
4.4 Participants
A group of 11 volunteers, university students (eight
men, three women), aged 19-23, participated in the
experiment. Table 1 summarizes detailed information
about the participants obtained from completed ques-
tionnaires.
4.5 Course of Experiment
All participants got all necessary information about
the experiment in a written form in advance. Then
informed consent was obtained from all participants.
Before starting each experiment the participant was
familiarized with basic behavioral rules during an
EEG/ERP experiment. Then the participant was fa-
miliarized with the car simulator controls and with
the track, subsequently they were allowed to drive
around.
During the experiment the examiner controlled
data recording, video recording and activated/deacti-
AttentionofDriverduringSimulatedDrive
545
Table 1: Data about participants (Vision - number of diopters, Hours of sleep - usual sleep/sleep before experiment/sleep
deprivation before experiment).
Participant Gender Laterality Vision Hearing Driving license Active driver Hours of Sleep
1 M R - - Y Y 7 / 6 / 4
2 M R 1.75 - Y Y 7 / 8 / 0
3 W R - - Y Y 7 / 7 / 0
4 M R 5 - Y Y 8 / 5 / 2
5 W R - - N N 8 / 8 / 2
6 M R - - Y Y 7 / 7 / 0
7 M R - - Y Y 7 / 7 / 4
8 M L - - Y Y 7 / 10 / 4
9 M L - - Y Y 8 / 8 / 3
10 W R - - Y N 6 / 10 / 2
11 M R 2 - Y Y 7 / 7 / 4
vated the stimulation program. The experiment was
ended after 20 minutes. The participant left the car
stimulator and the examiner asked him/her to fill in
the questionnaire containing the questions related to
his/her feeling of fatigue during/after the ride.
4.6 Environment
All experiments were performed during February 14
and April 12, 2013 (late winter and spring in the
Czech Republic).
4.7 Data and Metadata
EEG/ERP data were recorded with the sampling fre-
quency 1 kHz; no filters were used during data record-
ing. The resulting signal was stored into three files:
.eeg file containing raw data; .vhdr file containing
metadata that describe raw data in .eeg file, and
.avg file containing the averaged signal around the
used stimuli. All recorded data, collected metadata,
and questionnaires were stored in the EEG/ERP por-
tal (EEG/ERP Portal, 2013). The data are publicly
available for registered users.
5 DATA PROCESSING
The recorded EEG/ERP data were further processed
using the following workflow:
• Data Filtering: IIR filter was applied to data from
the Fz, Cz and Pz electrodes. These three elec-
trodes were also selected for further processing.
• Data Segmentation: The epochs were extracted
from datasets, data corresponding to each tar-
get stimulus were selected in the time interval (-
100ms, 900ms) in the area of occurrence of the
target stimulus.
• Rejection of Corrupted Data: The segmented data
containing artifacts were manually rejected.
• Baseline Correction: The baseline was corrected
using the interval (-100ms, 0ms) before occur-
rence of each target stimulus.
• Data Averaging: The epochs selected from each
twenty minutes long experiment of each partic-
ipant were averaged and stored Then the grand
averages for each of four experimental sessions
(morning + usual sleep, afternoon + usual sleep,
morning + sleep deprivation, afternoon + sleep
deprivation) and for some of their combinations
were computed.
The latency of the P3 component was determined us-
ing the following techniques:
• Peak Latency: The simplest way to determine the
latency of the P3 component is to find its max-
imum amplitude in the time interval of possible
occurrence of the P3 component. This maximum
value is referred to as peak latency. However,
this measure of peak latency has several short-
comings and is more suitable for the components
with a clearly identifiable maximum value. There-
fore, two other techniques of latency determina-
tion were used in this study (Luck, 2005), (Kiesel
et al., 2008).
• Fractional 50% Peak Latency: This technique
simply marks the time point, when 50% percent-
age of the maximum amplitude (this maximum
amplitude is not necessarily the true peak ampli-
tude) was reached in the backward direction.
• Fractional 50% Area Latency: This technique
works by computing the area under the compo-
nent over a given latency range and finding the
time point that divides that area into halves.
HEALTHINF2014-InternationalConferenceonHealthInformatics
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−100 0 100 200 300 400
500 600
700 800 900
−15
−10
−5
0
5
10
15
Time [ms]
Voltage [µV]
morning + usual sleep
afternoon + usual sleep
morning + sleep deprivation
afternoon + sleep deprivation
Figure 1: Grand average on the electrode Fz - experimental sessions differ in the daytime and duration of sleep.
−100 0 100 200 300 400
500 600
700 800 900
−15
−10
−5
0
5
10
15
Time [ms]
Voltage [µV]
usual sleep
sleep deprivation
Figure 2: Grand average on the electrode Fz after usual sleep and sleep deprivation.
6 RESULTS AND DISCUSSION
The results from performed experiments are summa-
rized in the figures and tables presented further. The
following description is then valid for each figure and
table:
AttentionofDriverduringSimulatedDrive
547
Table 2: Latency of the P3 component on the electrode Fz; the peak latency technique applied.
Participant Experimental
session 1 [ms]
Experimental
session 2 [ms]
Experimental
session 3 [ms]
Experimental
session 4 [ms]
1 299 271 276 291
2 300 319 316 320
3 296 298 296 289
4 288 278 280 281
5 286 292 290 284
6 294 301 303 303
7 291 284 300 301
8 284 294 304 298
9 291 299 323 315
10 280 281 279 273
11 291 288 289 296
Grand average GA1 GA2 GA3 GA4
293 295 304 299
Grand average GA12 GA34 GA13 GA24
293 298 293 298
Table 3: Latency of the P3 component on the electrode Fz; the fractional 50% peak latency technique applied.
Participant Experimental
session 1 [ms]
Experimental
session 2 [ms]
Experimental
session 3 [ms]
Experimental
session 4 [ms]
1 333 270 310 323
2 290 283 312 314
3 278 278 272 280
4 270 271 278 263
5 325 291 268 323
6 291 284 289 284
7 269 266 273 269
8 283 265 280 283
9 300 337 320 332
10 269 271 277 268
11 312 314 316 309
Grand average GA1 GA2 GA3 GA4
286 277 284 282
Grand average GA12 GA34 GA13 GA24
281 283 284 279
Table 4: Latency of the P3 component on the electrode Fz; the fractional 50% area latency technique applied.
Participant Experimental
session 1 [ms]
Experimental
session 2 [ms]
Experimental
session 3 [ms]
Experimental
session 4 [ms]
1 378 363 359 375
2 342 343 361 360
3 336 342 346 353
4 329 324 345 320
5 352 351 321 338
6 341 340 345 351
7 319 318 320 317
8 402 390 339 398
9 328 343 354 361
10 337 330 338 334
11 350 337 347 346
Grand average GA1 GA2 GA3 GA4
336 333 344 346
Grand average GA12 GA34 GA13 GA24
335 345 339 339
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• Experimental Session 1 - a set of experiments per-
formed in the morning after usual sleep
• Experimental Session 2 - a set of experiments per-
formed in the afternoon after usual sleep
• Experimental Session 3 - a set of experiments per-
formed in the morning after sleep deprivation
• Experimental Session 4 - a set of experiments per-
formed in the afternoon after sleep deprivation
• GAX - the grand average computed by averaging
together the averaged waveforms of the partici-
pants of the experimental session X
• GAXY - the grand average computed by averag-
ing together the averaged waveforms of the par-
ticipants of the experimental sessions X and Y
Figure 1 shows the grand averages on the elec-
trode Fz for all experimental sessions and Figure 2
shows the grand averages on the electrode Fz for ses-
sions after usual sleep and sleep deprivation.
Table 2 presents the latency of the P3 component
on the electrode Fz using the technique of peak la-
tency. The resulting data were determined manually
using Brain Vision Analyzer software. Table 3 and
Table 4 show the latency of the P3 component af-
ter application of the fractional 50% peak latency and
fractional 50% area latency. These latencies were de-
termined by using a custom software application.
It is not possible to mutually compare the laten-
cies obtained by using different techniques. The im-
portance of latency is not in its absolute value but in
the difference between the values measured for the
experimental sessions described above.
The results did not demonstrate that the latency of
the P3 component was influenced by daytime. The
assumption that the latency of the P3 component in-
creases with sleep deprivation can be shown on the
results from Table 2 and Table 4. However, latencies
of individual participants do not confirm this hypothe-
sis when any technique described in this paper is used.
One possible reason for this result is that the number
of the target stimuli for each participant is too small to
get rid of signal noise. This noise is more eliminated
when grand averages are computed.
7 CONCLUSIONS
This paper shortly described the experiment that had
investigated attention of drivers by using the methods
of electroencephalography and event related poten-
tials. Experimental results showed that the P3 com-
ponent had been clearly identified during all exper-
imental sessions. Despite expectations, prolongation
of peak latency in time was not clearly observed when
the grand average measure of each participant was in-
vestigated. On the other hand, this prolongation was
observable when the techniques of peak latency and
fractional 50% area latency were applied to compute
the grand average for each experimental session. The
results are currently not statistically evaluated to pro-
vide more detailed information.
In the future, it would be probably appropriate to
increase the number of target stimuli (i.e. to prolong
the drive) to get more evident results from individual
participants.
ACKNOWLEDGEMENTS
The work was supported by the UWB grant SGS-
2013-039 Methods and Applications of Bio- and
Medical Informatics and by the European Regional
Development Fund (ERDF), Project ”NTIS - New
Technologies for Information Society”, European
Centre of Excellence, CZ.1.05/1.1.00/02.0090.
REFERENCES
Brain Products (2013a). Brain vision analyzer.
Brain Products (2013b). Brain vision recorder.
Bueno, M., Fabrigoule, C., Deleurence, P., Ndiaye, D., and
Fort, A. (2012). An electrophysiological study of the
impact of a forward collision warning system in a sim-
ulator driving task. Brain Research, 1470:69–79. cited
By (since 1996)1.
EEG/ERP Portal (2008-2013). EEG/ERP Portal.
Filtness, A., Reyner, L., and Horne, J. (2012). Driver
sleepiness-comparisons between young and older men
during a monotonous afternoon simulated drive. Bio-
logical Psychology, 89(3):580–583.
Kiesel, A., Miller, J., Jolicour, P., and Brisson, B. (2008).
Measurement of erp latency differences: A compari-
son of single-participant and jackknife-based scoring
methods. Psychophysiology, 45(2):250–274.
Li, W., He, Q.-C., Fan, X.-M., and Fei, Z.-M. (2012). Eval-
uation of driver fatigue on two channels of eeg data.
Neuroscience Letters, 506(2):235–239.
Luck, S., Woodman, G., and Vogel, E. (2000). Event-related
potential studies of attention. Trends in Cognitive Sci-
ences, 4(11).
Luck, S. J. (2005). An Introduction to the Event-Related Po-
tential Technique (Cognitive Neuroscience). A Brad-
ford Book, 1 edition.
Moucek, R. and Rericha, J. (2012). Driver’s attention dur-
ing monotonous driving. 2012 5th International Con-
ference on Biomedical Engineering and Informatics,
BMEI 2012, pages 486–490.
AttentionofDriverduringSimulatedDrive
549
Moucek, R. and Rondik, T. (2012). Influence of mental
load on driver’s attention. Transaction on Transport
Sciences, 5(1):21–26.
Neuro Behavioral Systems (2013). Presentation.
Schier, M. (2000). Changes in eeg alpha power during simu-
lated driving: A demonstration. International Journal
of Psychophysiology, 37(2):155–162.
SYNETIC GmbH (2013). World racing 2.
Wester, A., Bcker, K., Volkerts, E., Verster, J., and Ken-
emans, J. (2008). Event-related potentials and sec-
ondary task performance during simulated driving.
Accident Analysis and Prevention, 40(1):1–7.
HEALTHINF2014-InternationalConferenceonHealthInformatics
550
