Estimating Driver Unawareness of Pedestrian based on Visual
Behaviors and Driving Behaviors
Minh Tien Phan, Indira Thouvenin,Vincent Fremont and Véronique Cherfaoui
Heudiasyc Laboratory, University of Technology of Compiègne, Compiègne, France
1 STAGE OF THE RESEARCH
Every year, more than 1.24 million people die in
traffic accidents around the world, half of which are
among pedestrians and cyclists, and 22 percent of
which are children (WHO, 2013). Thus, preventing
pedestrians from motor accidents is an important
problem in achieving a safe and secure society. A lot
of research in the advanced driver assistance is able
to detect the pedestrian with the in-vehicle sensors
and inform the driver of their presence. However,
most of these alert systems do not adapt to the
driver, they become distracting, annoying the driver
and will be often ignored or deactivated. Therefore,
taking into account the driver’s state and
understanding fully the situation are the challenges
for these systems.
This study is the first step of a project named
MINARDA (Mobile and Interactive Augmented
Reality for Driving Assistance). This system is
strongly connected to the user. It aims to use a
suitable visualization metaphor in augmented reality
that allows the driver to avoid dangerous situations.
Particularly, we focus on the situation in which the
pedestrian is in danger.
This paper will be structured as follows. In
sections 2 and 3, we underline our objectives of
research and define the problem. In section 4, we
review some related works. In Section 5, we
describe the proposed methodology to treat this
problem. Section 6 describes our expected outcome,
conclusion and perspectives.
2 OUTLINE OF OBJECTIVES
As mentioned above, the MINARDA system needs
to fully understand the situation to be able to provide
the appropriate cues to the user. In the context of
pedestrian safety, our first objective is to find out
what the features that characterize the driver’s
awareness or unawareness of pedestrian are. Once
we can identify these features, our second objective
is to build a model of the awareness and
unawareness a driver has of pedestrians appearing
on the road ahead. At last, we will envisage
estimating the different levels of danger to
pedestrian. The more precisely the danger levels are
classified, the more suitably the assistance cues can
adapt to the driver.
3 RESEARCH PROBLEM
In a previous work, Engel and Curio (2011, 2012),
Wakayama, (2012) proposed to estimate how easy it
is for the driver to see and notice pedestrians. The
studies included the estimate of driver’s visual
attention and pedestrian detectability in an image. In
this study, we aim to provide a new and more direct
approach. It can be assumed that the driver’s
awareness or unawareness of pedestrian could be
estimated by observing his visual behaviors and
driving behaviors. More precisely, our hypothesis is
whenever the driver is aware of a pedestrian ahead,
he has to direct his gaze to pedestrian and does some
reactions on vehicle, (brake, deceleration, wheel
angle change, etc.) what is not in the case of
unawareness.
This preliminary suggestion leads to two related
questions:
1. Is there any difference in visual behaviors and
driving behaviors between two states driver’s
awareness of and unawareness of something on road
(pedestrian in this case)?
2. Is it possible to extract and use those patterns
to help identify or learn information about the
danger to pedestrian?
In order to answer these questions, we have to
envisage different experiments and consider
different methods to measure visual behaviors and
driving behaviors. Because of their reliability and
flexibility, in this work, we use a vision-based
method to observe the visual behaviors and various
in-vehicle sensors to measure the driving behaviors.
35
Tien Phan M., Thouvenin I., Fremont V. and Cherfaoui V..
Estimating Driver Unawareness of Pedestrian based on Visual Behaviors and Driving Behaviors.
Copyright
c
2014 SCITEPRESS (Science and Technology Publications, Lda.)
4 STATE OF THE ART
In the state of the art includes the related research
that helps to understand the danger to pedestrian,
particularly those are related to the driver. Thus, we
talk about the problem of pedestrian detectability,
we review in detail the studies of driver inattention
detection, and the studies which are directly related
to the driver’s awareness of the pedestrian. We will
then identify the strength and weakness of each
method that should be considered in our works.
4.1 Pedestrian Detectability
The studies on the detectability of the pedestrian aim
to estimate how easy it is for the driver to see and
notice pedestrians. In the work of Engel and Curio
(2011), the authors did the experiments to measure
the time to recognizing the pedestrian on image.
Then, they determined the features of pedestrians
that correlated with this time. Thus, the detectability
of pedestrian was modeled. The features of
pedestrian on image could be for example, the
position of pedestrian, size, color, light, etc. This
study was also extended to the dynamic scene
concept. Actually, instead of analyzing the
pedestrian’s detectability on images, it is possible to
do the experiments on the sequence video (Engel
and Curio, 2012). Another extension was proposed
by Wakayama (2012) who considered the motion of
pedestrian to be one of the features that characterize
the pedestrian detectability. However, as before,
because the fact that the pedestrians can be seen
easily does not mean that the driver is cognitively
aware of them (Fukagawa, Yamada, 2013).
4.2 Driver Inattention Detection
The lack of attention by drivers is the biggest single
cause of serious road accidents. A great amount of
work have been done on the inattention state of the
driver. However, the inattention of the driver was
defined in different ways. In this part (4.2), the
inattention means the abnormal states of the driver
such as fatigue, drowsiness or distraction, etc.
Otherwise, in the rest of our research, driver’s
unawareness of pedestrian is considered to be a kind
of inattention based on this definition: “Driver
Inattention means insufficient or no attention to
activities critical for safe driving” (Regan et al,
2011). According to this, unawareness of the
pedestrian means insufficient or no attention to this
pedestrian for safe driving.
The driver’s behaviors and his inattention state
are analyzed and detected under different
techniques, the majority of which are as follows.
4.2.1 Physiological Measures Observation
The physiological signals such as heart rate,
respiration or EEG and are considered to be the most
reliable signals to analyze the driver behaviors and
to detect inattentiveness.
Heart rate is easily determined through
Electrocardiogram (ECG) signal. The mental stress
while driving for example, increases blood pressure,
heart rate and activate the sympathetic nervous
system. (Moriguchi et al., 1992). There are
significance impacts in the heart rate when a driver
is in a state of cognitive inattention (thinking while
driving for example) (Akin et al, 2008).
Moreover, the EEG (Electroencephalogram)
signal has various frequency bands which can
signify different states of the driver. For example,
there is evidence that the increase of the alpha band
(8-13Hz) corresponds to relaxation. Increase of the
delta band (0.5-4Hz) and the theta band (4-8Hz)
correspond to sleep activity and drowsiness which
signify a potential failure of attention and behaviors.
(Östlund, 2004), (Santana, 2002). In another
experiment, twelve types of energy parameters
computed from three bands alpha, beta, and delta
were chosen as the evaluation index of driver fatigue
(Li, 2012)
However, these techniques are obtrusive, since it
is necessary to attach some electrodes on the drivers,
causing annoyance to them. Consequently, it is
difficult to be implemented in the real-life
applications.
4.2.2 Visual Behaviors Observation
Driver behaviors could be somehow observed from
the changes in their facial features like eyes, head
and face. In this context, several methods have been
proposed. This measurement has the advantage of
being unobtrusive, since they could be collected
with remote eye-head trackers. Moreover, they are
quite reliable.
Measurements related to head movement such as
nodding frequency and those related to the eye
region such as eyelid distance changes, eye close
duration, blinking frequency, and the recently
developed parameter PERCLOS (percentage of time
in a minute that the eye is 80% closed) (Lin,2012)
were widely used in research. After extracting these
features, Bergasa (2008) and Mohamad-Hoseyn
Sigari (2013) built a fuzzy model or finite state
VISIGRAPP2014-DoctoralConsortium
36
machine to estimate the inattentive, distracted or
fatigue state of driver.
Another cue is the size of the pupils. The pupils
is the part of the iris that allows light to enter the
retina. Besides light, the pupil dilates when mental
or cognitive effort is given. It was observed that the
pupil was dilated and the diameter of average pupil
size increased by 15% when the driver was
cognitively distracted (Akin et al, 2008), (Benedetto,
2011).
Gaze behaviors are another cues that can be used
as a metric to find if the concentration of the driver
was on driving or not. It was noticed that, when the
driver was cognitively distracted, glancing at
instruments and mirrors decreased significantly
(Harbluk, 2007). A simple method to detect the
driver’s attention was proposed by Fletcher and
Zelinsky (2009.). They used driver’s gaze vector and
road scene event correlation to estimate if the driver
has seen the event or not. Due to the “looking but
not seeing” problem, this work was not able to
reliably determine if a certain road event (pedestrian
for example) is perceived by the driver. However it
could identify if the driver has not perceived a road
event.
Deeper in this context, Doshi and Trivedi (2009)
provided a result on the observation of the dynamic
of overt visual attentions shifts. They found that
there are various interactions between head and eye
movements that are useful in detecting the driver
distractions, as well as the driver intent. Indeed, their
results validated the differences existing between
goal-oriented and stimulus-oriented gaze shift.
Moreover, this feature could be observed in
dynamics of eye and head movements. They also
investigated the problem of detecting the intent of
the driver in changing lane which was considered to
be a goal-oriented attention shift. (Doshi and
Trivedi, 2012). This result showed that the driver
attentiveness or awareness of something should be
observed through the dynamic of many parameters.
4.2.3 Driving Behaviors Observation
Another method on the driver’s inattention research
is to detect it indirectly through driving behaviors
such as vehicle speed, steering wheel movement,
lateral position, and break or acceleration pedal
states. (Imamura et al, 2008), (Ueno et al, 1994).
The projects conducted by HASTE (Human
Machine and the Safety of Traffic in Europe)
demonstrated that the steering measures were
significantly affected by the visual task, when a
subject had to perform the visual task, the steering
effort was higher than in the baseline condition.
(Östlund et al., 2004).
The IVDRs (In-vehicle Data Recorder) offer
valuable information on a driver’s behavior through
the analysis of automobile-operating information.
Jensen and Wagner (2011) also proposed a
combination of three analysis methods to evaluate
the driver performance: data threshold violations,
phase plane analysis with limits and a recurrence
plot with outlier limits. These methods were based
on the measures of vehicle speed, engine speed,
vehicle latitude and longitude coordinates, and
lateral accelerations.
Although these techniques are not obtrusive, they
are subject to several limitations such as vehicle
type, driver experience, geometric characteristics,
state of road, etc. (Bergasa, 2008 ).
4.3 Driver Unawareness of Pedestrian
To the best of our knowledge, there are no studies
that are directly related to the estimation of the
driver unawareness of pedestrian or other traffic
events. The most closely related works are those of
(Fukagawa, Yamada, 2013) who proposed a
hypothesis that is likely linked to our work. Their
study was based on the driver’s operational data
such as pressure on the accelerator pedal, pressure
on the brake pedal (called acceleration reaction),
steering angle and vehicle behavior data such as
vehicle speed to estimate the driver’s awareness of
pedestrian.
Their hypothesis was that whenever a pedestrian
appears on the road, if the driver noticed it, he had to
do the acceleration reaction somehow. They used the
driving behavior data collected by Research Institute
of Human Engineering for Quality of Life
(Akamatsu et al., 2003). From that, they proposed to
calculate the probability of acceleration reaction
being observed at a distance given that response to
driver’s aware of the pedestrian. This probability
was assumed to be a log-normal distribution. They
also proposed to calculate the probability of
acceleration reaction being observed at a distance
given that not in response to driver’s aware of the
pedestrian and this probability was considered to be
a uniform distribution. Hence, using Bayes theorem,
they calculated the probability that one acceleration
reaction was caused in response to driver’s
awareness of pedestrian.
However, there is a couple of weaknesses in this
study. Firstly, in the data collected in real and actual
road condition, it was supposed that whenever a
pedestrian appeared on road, the driver had to notice
EstimatingDriverUnawarenessofPedestrianbasedonVisualBehaviorsandDrivingBehaviors
37
them, this is hard to verify. Secondly, the driver
could totally accelerate if he had been aware of the
pedestrians and identify that they were not in danger.
On the other hand, this probability model is not
reliable because of the use of a specific distribution
law. Finally, this study can’t determine if the driver
has not noticed the pedestrian or has been unaware
of them.
5 METHODOLOGY
In this work, we have defined the driver’s
unawareness and awareness of pedestrian. We use
the camera-based system to observe his visual
behavior and the in-vehicle sensors to measure the
driving behaviors. Moreover, in the experiment, we
have discussed two most important issues as follow.
Hence, the methodology of research is determined
5.1 Driving Simulation Vs. Naturalistic
Driving Data Collection
In our work, both driving simulations and real
conditions driving are expected out. Firstly, a
driving simulation is used to collect all information
from different sensors. From that, the feature vectors
representing the driver’s awareness and unawareness
of pedestrian will be extracted. The simulation
environment is useful because we can control the
situation and can propose different scenario that fit
well to our research problem. For example, we can
propose two scenarios. First, a scenario where the
driver is asked to recognize the gender of a
pedestrian while driving. On the other hand, a
scenario of driver’s unawareness in which the driver
is demanded to do a second visual task while
driving.
Naturalistic driving data help to verify the
hypothesis in real conditions. Many experiments
have been conducted in simulated environment and
the results have been discussed. However, in real
driving conditions the result might be drastically
lower as a moving vehicle presents new challenges
like variable lighting, changing background and
vibration, etc. (Arun et al, 2012). The data collected
in real conditions will be extracted and annotated
whenever a pedestrian appears on road. Then, we
will compare the driver visual reaction and
acceleration reaction with the ones that have been
extracted in simulation driving.
We use the help of MINARDA system
embedded on CARMEN platform to collect the
information.
Figure 1: MINARDA system and CARMEN car- Ready
for simulation driving as well as naturalistic driving data
collection.
5.2 Hybrid Measures
Each previously mentioned method get their own
advantages and limitations. Nevertheless, in the
advanced driving assistance systems, the
environment, the vehicle and the driver have to be
considered to be an overall driving system (Trivedi
et al. 2007). Proposed study is to consolidate various
measures which could lead to a good detection
system. Indeed, beside the pedestrian detection
system that provides all properties of pedestrian on
road (position, distance, time to collision, etc.), we
propose to use the visual behaviors, specially the
looking vector which is provided by SMI Glass and
head motion which is provided by the Facelab
System. In the other hand, the driving behaviors
such as the driver acceleration reaction are measured
by the IVDR. These cues will be collected in high
frequency to analyze the driver’s awareness or
unawareness of pedestrian.
Our hypothesis is that, this kind of driver
inattention should be observed through the change of
the looking reaction with respect to a pedestrian or
the change in his driving acceleration. Or it may be
characterized by the interaction of these both
reactions, for example, by a reaction of looking first
and followed by an acceleration reaction. This
hypothesis may be complete the study of Yuuki
Fukugawa (2013) since we are able to observe the
case when the driver is aware of pedestrian and does
no reaction acceleration and the case when the driver
does the acceleration reaction but he is unawareness
of a pedestrian.
6 EXPECTED OUTCOME
At the end of this study, the reliable patterns that
characterize the driver’s states of unawareness and
awareness of pedestrian are expected to be extracted
out. Then, we intend to develop a new learning
algorithm based on these patterns in order to model
this driver’s behavior and the danger level to
VISIGRAPP2014-DoctoralConsortium
38
pedestrian. The whole algorithm will be
implemented on the MINARDA system.
In this paper, we talked about the danger to
pedestrian. We provided a review on the methods
that help to analyze the driver behaviors and to
detect his inattention state. We propose a novel
approach directly related to pedestrian safety, the
driver’s awareness and unawareness of pedestrian.
This study could be extended to other type of road
events such as traffic light or other vehicles
detection and help us to understand better the
driving context.
REFERENCES
Akamatsu, M.; Sakaguchi, Y. and Okuwa, M. 2003.
“Modeling of Driving Behavior When Approaching an
Intersection Based on Measured Behavioral Data on
An Actual Road”. Proceedings of the Human Factors
and Ergonomics Society Annual Meeting, 47, 1895-
1899.
Akin, M.; Kurt, M.; Sezgin, N. and Bayram, M.
2008.”Estimating vigilance level by using EEG and
EMG signals”. Neural Computing and Applications,
Springer-Verlag, 17, 227-236.
Arun, S.; Sundaraj, K. & Murugappan, M.2012
“Driver inattention detection methods: A review”
Sustainable Utilization and Development in
Engineering and Technology (STUDENT), 2012 IEEE
Conference on, 1-6
Benedetto, S.; Pedrotti, M.; Minin, L.; Baccino, T.; Re, A.
and Montanari, R. 2011. “Driver workload and eye
blink duration”.Transportation Research Part F:
Traffic Psychology and Behaviour , 14, 199 – 208.
Bergasa, L.; Nuevo, M.; Barea, R. and Lopez, E.
Prokhorov, D. (Ed.). 2008. “Visual Monitoring of
Driver Inattention”. Computational Intelligence in
Automotive Applications, Springer Berlin Heidelberg,
132, 19-37.
Doshi, A. and Trivedi, M. 2009.”Head and gaze dynamics
in visual attention and context learning” Computer
Vision and Pattern Recognition Workshops, 2009.
CVPR Workshops 2009. IEEE Computer Society
Conference on, 77-84.
Doshi, A. and Trivedi, M. 2012. “Head and eye gaze
dynamics during visual attention shifts in complex
environments” Journal of Vision, 12
Engel, D. and Curio, C. 2011. “Predicting human perception
performance with machine vision”. Intelligent Vehicles
Symposium (IV), 2011 IEEE, 429-435.
Engel, D. and Curio, C. 2012. “Detectability prediction in
dynamic scenes for enhanced environment perception”
Intelligent Vehicles Symposium (IV), 2012 IEEE, 178-
183.
Fletcher, L. and Zelinsky, A. 2009. “Driver Inattention
Detection based on Eye Gaze-Road Event
Correlation”. Int. J. Rob. Res., Sage Publications, Inc.,
28, 774-801.
Fukagawa, Y. and Yamada, K. 2013. “Estimating Driver
Awareness of Pedestrians from Driving Behavior
based on a Probabilistic Model”. Intelligent Vehicles
Symposium (IV).
Harbluk, J. L.; Noy, Y. I.; Trbovich, P. L. and Eizenman,
M. 2007. “An on-road assessment of cognitive
distraction: Impacts on driver’s visual behavior and
braking performance”. Accident Analysis &
Prevention, 39, 372 – 379.
Imamura, T.; Yamashita, H.; bin Othman, R.; Zhang, Z.
and Miyake, T. 2008. “Driving behavior classification
river sensing based on vehicle steering wheel
operations”.
SICE Annual Conference, 2008, 2714-2718.
Jensen, M. and Wagner, J. 2011. “Analysis of In-Vehicle
Driver Behaviour Data for Improved Safety”.
International Journal of Vehicle Safety. 197-212.
Li, W.; chang He, Q.; min Fan, X. and min Fei, Z.2012.
“Evaluation of driver fatigue on two channels of EEG
data”. Neuroscience Letters, 506, 235 – 239.
Lin, S. T.; Tan, Y. Y.; Chua, P. Y.; Tey, L. K. & Ang, C. H.
2012 “PERCLOS Threshold for Drowsiness Detection
during Real Driving” Journal of Vision, 12, 546.
Mohamad-Hoseyn Sigari, Mahmood Fathy and Soryani,
M. 2013. “A Driver Face Monitoring System for
Fatigue and Distraction Detection”. International
Journal of Vehicular Technology, 11.
Östlund, J; and al. 2004. “Delivrable 2- HMI and safety
related driver performance”. Human Machine
Interface and the Safety of Traffic in Europe (HASTE)
project.
Regan, M. A.; Hallett, C. and Gordon, C. P. 2011. “Driver
distraction and driver inattention: Definition,
relationship and taxonomy”. Accident Analysis &
Prevention, 43, 1771 -1781.
Santana Diaz, A.; Jammes, B.; Esteve, D. and Gonzalez
Mendoza, M. 2002. “Driver hypovigilance diagnosis
using wavelets and statistical analysis”. 2002.
Intelligent Transportation Systems. Proceedings. The
IEEE 5th International Conference on, 162-167
Trivedi, M. M.; G, T. and Mccall, J. 2007. “Looking-in
and looking-out of a vehicle: Computer-vision-based
enhanced vehicle safety”. IEEE Trans. Intell. Transp.
Syst, 8, 108-120.
Ueno, H.; Kaneda, M. and Tsukino, M. 1994.
“Development of drowsiness detection system”.
Vehicle Navigation and Information Systems
Conference, 1994. Proceedings. 1994, 15-20.
Wakayama, M.; Deguchi, D.; Doman, K.; Ide, I.; Murase,
H. and Tamatsu, Y.2012. ”Estimation of the human
performance for pedestrian detectability based on
visual search and motion features”.Pattern
Recognition (ICPR), 2012 21st International
Conference on, 1940-1943.
WHO, World Health Organization, 2013. “Global Status
Report on Road Safety Supporting a decade of action”.
EstimatingDriverUnawarenessofPedestrianbasedonVisualBehaviorsandDrivingBehaviors
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