Eye-tracking Dataset to Support the Research on Autism Spectrum
Disorder
Federica Cilia
1
, Romuald Carette
2
, Mahmoud Elbattah
3,4
, Jean-Luc Guérin
3
and Gilles Dequen
3
1
Laboratoire CRP-CPO, Université de Picardie Jules Verne, Amiens, France
2
Evolucare Technologies, Villers-Bretonneux, France
3
Laboratoire MIS, Université de Picardie Jules Verne, Amiens, France
4
Faculty of Environment and Technology, University of the West of England, Bristol, U.K.
Keywords: Autism Spectrum Disorder, ASD, Eye-tracking, Machine Learning.
Abstract: The availability of data is a key enabler for researchers across different disciplines. However, domains, such
as healthcare, are still fundamentally challenged by the paucity and imbalance of datasets. Health data could
be inaccessible due to a variety of hurdles such as privacy concerns, or lack of sharing incentives. In this
regard, this study aims to publish an eye-tracking dataset developed for the purpose of autism diagnosis. Eye-
tracking methods are used intensively in that context, whereas abnormalities of the eye gaze are largely
recognised as the hallmark of autism. As such, it is believed that the dataset can allow for developing useful
applications or discovering interesting insights. As well, Machine Learning is a potential application for
developing diagnostic models that can help detect autism at an early stage of development.
1 INTRODUCTION
Autism Spectrum Disorder (ASD) is a neuro-
developmental disorder, which is characterized by
various impairments, mainly social communication
and interaction issues, and repetitive behaviour
(American Psychiatric Association, 2013). ASD-
diagnosed individuals usually suffer from troubles in
interaction and communication in multiple forms.
The most remarkable symptom is the poor
development of non-verbal skills such as the lack or
absence of eye contact. With such troubling deficits,
a considerable strain can unfortunately be placed on
the well-being of autistic individuals and their
families as well. From an economic standpoint, it was
estimated that autism costs the UK, for example,
more than heart disease, cancer, and stroke combined
(Buescher et al., 2014).
The detection of autism at an early stage of
development is highly favourable to realise common
benefits for children and their families. Multiple
studies (e.g., Smith et al., 2000; Dawson et al., 2010)
reported improved outcomes of treatment such as
intellectual capacity, communication, adaptive
behaviour, and educational support. However, the
diagnosis of autism has been considered as a
challenging task. The diagnosis process includes a
variety of cognitive tests that typically require hours
of intensive clinical examinations. Furthermore,
standardised tests require a considerable amount of
time and effort to be conducted, and the diversity of
symptoms increase the complexity of identifying an
accurate classification.
In this regard, a large body of the psychological
research endeavoured to develop assistive
instruments based on observational measures or
diagnostic interviews. Examples include Childhood
Autism Rating Scale (Schopler et al., 1980), Autism
Diagnostic Observation Schedule (ADOS) (Lord et
al., 1989), and Autism Diagnostic Interview (ADI-R)
(Lord, Rutter, and Le Couteur, 1994). More recently,
a range of technologies have been embraced for
aiding the process of screening and diagnosis. In
particular, the eye-tracking technology has received
an extensive research interest in the ASD context.
Abnormalities of the eye gaze have been largely
recognised as the hallmark of autism (Guillon et al.,
2014), which makes eye-tracking methods suitable
for a variety of diagnostic tasks.
This study seeks to contribute to the research
community of ASD by providing an eye-tracking
dataset. On the one hand, part of our earlier work
(Carette et al., 2018) has published an image dataset,
which represented the visual patterns of eye-tracking
Cilia, F., Carette, R., Elbattah, M., Guérin, J. and Dequen, G.
Eye-tracking Dataset to Support the Research on Autism Spectrum Disorder.
DOI: 10.5220/0011540900003523
In Proceedings of the 1st Workshop on Scarce Data in Artificial Intelligence for Healthcare (SDAIH 2022), pages 59-64
ISBN: 978-989-758-629-3
Copyright
c
2023 by SCITEPRESS – Science and Technology Publications, Lda. Under CC license (CC BY-NC-ND 4.0)
59
scanpaths. On the other hand, the present work aims
to publish the raw eye-tracking output, which should
allow for extended opportunities for studying and
analysing the gaze behaviour of ASD. This study has
been generally initiated in the frame of an
interdisciplinary research of Psychology and AI. The
collaboration has brought together psychologists
from the CRP-CPO lab along with AI researchers
from the MIS lab, based at the University of Picardie
Jules Verne in France.
2 BACKGROUND AND RELATED
WORK
This section aims to provide a review of the literature
as follows. Initially, a brief history is given on the
origins of eye-tracking. Further, we review selective
studies that employed eye-tracking to analyse the
gaze behaviour among ASD-diagnosed individuals.
2.1 Brief History of Eye-tracking
Eye-tracking refers to the process of capturing and
measuring eye movements and the absolute point of
gaze (POG) (Majaranta, and Bulling, 2014). The
POG represents the focal point of the eye gaze in the
visual scene. Modern eye-trackers largely fall into
three categories including screen-based eye-trackers,
eye-tracking glasses, and Virtual Reality (VR)
headsets as well.
However, the use of eye-tracking interestingly has
a long history that dates back to the 19th century. The
early development of eye-tracking is credited to the
French ophthalmologist Louis Javal from the
Sorbonne University. In seminal research that
commenced in 1878, Javal had produced the novel
observations of fixations and saccades based on the
gaze behaviour during the reading process (Javal
1878; Javal 1879). A fixation describes the brief
moments while the eye gaze is paused on a particular
object, which allow the brain to perform the
perception process. The average duration of fixation
was estimated to be around 330ms (Henderson,
2003). While saccades include a constant scanning
with very rapid and short eye movements. Saccades
consist of quick ballistic jumps of 2
o
or longer, which
continue for about 30–120ms (Jacob, 1995).
Afterwards, Edmund Huey built a primitive eye-
tracking tool for analysing eye movements while
reading (Huey, 1908). More advanced
implementations of eye-tracking instruments were
developed by (Buswell 1922; Buswell 1935).
Photographic films were utilised to record the eye
movements while looking at a collection of paintings.
The eye-tracking records included both of the
direction and duration of movements. Eye trackers
are currently utilised in a plethora of applications. To
name a few, applications of marketing (Boerman, and
Müller, 2022), psychology (Åsberg Johnels et al.,
2022), product design (Jeon, Cho, and Oh, 2021), and
many others.
2.2 Eye-tracking Research in Autism
Making an accurate diagnosis of autism has been
considered as a challenging task, which usually
requires an intensive clinical assessment and
experience. With contemporary advances in
technology, new approaches have come into
prominence to assist the procedures of diagnosis and
assessment. Examples includes a variety of
technologies such as Electroencephalography (EEG)
(Abdulhay et al., 2020), Magnetic Resonance
Imaging (MRI) (Dekhil et al., 2019), and eye-tracking
(Cilia et al., 2021) in particular.
In this context, the literature contains abundant
contributions that endeavoured to apply eye-tracking
methods for analysing and understanding the
characteristics of autism. Various interesting
physiological elements were reported based on
findings output from eye-tracking experiments. For
instance, eye movements in face-to-face interactions
were observed to be different for individuals who had
different levels of the autism severity (Vabalas, and
Freeth, 2016). Specifically, highly autistic individuals
were noticed to experience saccades of shorter
duration and less frequency as well. In another
application of eye-tracking, ASD toddlers could be
identified based on the frequency of saccades and
fixations (Pierce et al., 2011). The results showed that
the ASD-diagnosed group spent significant longer
periods of fixations on dynamic geometric images.
Other studies sought to integrate eye-tracking
with contemporary AI approaches to advance the
diagnostic applications of autism. For example, a
Deep Learning model was implemented to detect
autism using eye-tracking tasks of free-image
viewing (Jiang, and Zhao, 2017). Deep Learning was
utilised to extract features automatically from a
collection of discriminative images. Likewise, CNN-
based architecture was applied for the detection of
eye contact during social interactions (Chong et al.,
2017). Their results reported a precision and recall of
76% and 80%, respectively. Another Deep Learning-
based framework was developed for ASD screening
using photo-taking tasks (Chen, and Zhao, 2019).
SDAIH 2022 - Scarce Data in Artificial Intelligence for Healthcare
60
They applied LSTM models for encoding the
temporal information of eye movements.
The present study endeavours to contribute with
an eye-tracking dataset to the research community of
autism. The dataset is based on a set of eye-tracking
experiments. Our earlier work (Carette et al., 2018)
published an image dataset of the eye-tracking output.
The images illustrated the dynamics of eye
movements in visualisations of the eye-tracking
scanpaths. The dataset was used in numerous
publications such as (Ahmed, and Jadhav, 2020),
(Akter et al., 2021), (Gaspar et al., 2022), and
(Elbattah et al., 2022). It is hoped that the present
dataset will also deem useful to develop further
applications for the ASD diagnosis.
3 DATA DESCRIPTION
3.1 Brief History of Eye-tracking
The participants included a set of 59 children
recruited from a few schools in the region of Hauts-
de-France. The age of participants ranged from 3 to
12 years old. It was highly desirable for the
participants to be at an early stage of development. A
parental permission was obtained for every child
before taking part in our experiments. Further, the
parents were acquainted with the study objectives
through orientation sessions.
Initially, the participants were organised based on
a basic binary grouping as: i) Typically developing
(TD), and ii) ASD-diagnosed. In addition, the CARS
score (Schopler et al., 1980) was employed to classify
the severity of autism more precisely. The CARS
method has been widely applied in the Psychology
practice for describing the severity of ASD symptoms
(Jones, and Klin, 2013). The scale includes various
ratings on different behavioural aspects (e.g., verbal
communication, activity level). Table 1 gives a
summary of the characteristics of participants.
3.2 Experimental Protocol
The eye-tracking experiments included a set of photos
and video scenarios, which were particularly
designed to stimulate the eye gaze across different
parts of the screen. The participants were seated at
approximately 60cm distance away from the monitor.
A quiet room at the university campus was used for
running our experiments. In addition, physical
barriers were applied around the screen to avoid
visual distractions.
Table 1: Summary of participants.
Count of Participants (TD, ASD) 59 (30, 29)
Gender (Female, Male) 21 (≈ 36%), 38
(
≈ 64%
)
Age (Mean, Median) 7.88, 8.1 years
CARS Score (Mean, Median) 32.97, 34.50
Figure 1: A screenshot from one of the videos used in the
eye-tracking experiments.
We used a SMI Red-M eye tracker with 60 Hz
sampling rate, which is a screen-based eye-tracker.
The eye-tracker was operated along with a 17-inch
monitor in our experiments. The screen resolution
was 1280x1024.
The content and length of videos varied to allow
for analysing the ocular activity from different
aspects and levels. The content of photos and videos
was generally aimed to include visual items (e.g.,
colourful balloons, cartoons), which could be
attractive to children in particular. The position of
items can change over the experiment timeline. In
addition, other videos included human presenters.
The presenter usually attempted to turn the
participant’s attention to elements, which could be
visible or invisible around the display area. The
French language was the working language in all
videos and conversations, as the mother tongue of
participants. Figure 1 presents a sample screenshot
captured from one of the videos.
We used other stimuli provided by the SMI
Experiment Center Software. The Stimuli included a
variety of types, which are used in the eye-tracking
research. For instance, static and dynamic naturalistic
scenes with and without receptive language, static
face or objects and cartoons stimuli, and other joint
attention stimuli. Eye-tracking experiments usually
took about 5 minutes. The participants were inspected
with respect to the quality of eye contact with the
presenter, and the level of focus on other elements. A
five-point scheme of calibration was applied. A set of
verification procedures followed the calibration
scheme.
Eye-tracking Dataset to Support the Research on Autism Spectrum Disorder
61
Table 2: Summary of participants.
Timestamp [ms]
Eye Movement
Category
Point-Regard X
[px]
Point-Regard Y
[px]
Pupil Diameter-
Right [mm]
Pupil Diameter-
Left [mm]
8005654.069 Fixation 1033.9115 834.0902 4.3785 4.5431
8005673.953 Fixation 1030.3754 826.0894 4.4050 4.5283
8005693.85 Saccade 1027.337 826.3127 4.4273 4.6036
8005713.7 Saccade 1015.0085 849.2188 4.3514 4.5827
8005733.589 Saccade 613.7673 418.1735 4.3538 4.5399
The eye-tracking device captured three categories
of eye movements including fixations, saccades, and
blinks. Additionally, the POG coordinates were
captured by the eye tracker. Table 2 gives a simplified
view of the eye-tracking records. As an example, the
table lists five eye-tracking records that represent a
sequence of two fixations and three saccades. The
records also give the POG coordinates for the right
and left eye over time. Due to limited space, many
variables had to be excluded from the table below (e.g.
pupil position, pupil diameter, pupil size).
3.3 Dataset
The dataset is distributed over 25 CSV-formatted files.
Each file represents the output of an eye-tracking
experiment. However, a single experiment usually
included multiple participants. The participant ID is
clearly provided at each record at the ‘Participant’
column, which can be used to identify the class of
participant (i.e., TD or ASD).
Furthermore, a set of metadata files is included.
The main metadata file, Participants.csv, is used to
describe the key characteristics of participants (e.g.
gender, age, CARS). Every participant was also
assigned a unique ID. Table 2 presents a couple of
metadata examples. Table 3 provides some examples
in this regard.
Table 3: Summary of participants.
ID Gender Age CARS Class
27 F 5.6 40 ASD
51 F 10.7 NA TD
3.4 Ethical Approval
The study received the ethical approval by the ethics
committee of Rouen University (Reference: 2016-02-
B). The CNIL (Commission nationale de
l'informatique et des libertés) declaration number of
research conformity is 2208663v0.
The study fulfils the principles and terms of the
1964 Helsinki declaration. Before starting the study,
the approval was obtained from the heads of the
regional and district education authorities, as well as
the head and teachers of the participating schools. The
parents of participants had also given their written
informed consent.
3.5 Usage Notes
The dataset is shared publicly on the Figsahre
repository. The files along with metadata can be
downloaded directly from the URL below.
https://doi.org/10.6084/m9.figshare.20113592
4 LIMITATIONS AND
CONCLUSIONS
There are some limitations that should be considered
as follows. First, the relatively small number of
participants is one limitation of the dataset. Second,
the duration of eye-tracking experiments was also
relatively short (≈ 5 min). Longer scenarios could
have allowed for a more exhaustive representation of
the gaze behaviour.
Despite limitations, it is conceived that the dataset
can be effectively utilised in the ASD research in
many ways. We believe that further studies can avail
of the dataset by applying data analysis or Machine
Learning. For instance, predictive models could be
developed to assist the diagnosis process.
ACKNOWLEDGEMENT
We acknowledge the financial support provided by
Fonds European de Development Régional (FEDER)
and Hauts-de-France.
SDAIH 2022 - Scarce Data in Artificial Intelligence for Healthcare
62
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