Paper—Mobile Technology for Students & Adults with Autistic Spectrum Disorders (ASD)  

 

Mobile Technology for Students & Adults with 
Autistic Spectrum Disorders (ASD)  

https://doi.org/10.3991/ijim.v11i1.5922 

Jenny A. Vlachou 
National Center for Scientific Research, Athens, Greece 

jvlachou@gmail.com 

Athanasios S. Drigas 
National Center for Scientific Research, Athens, Greece 

dr@iit.demokritos.gr 

Abstract—This study evaluates the use and efficacy of mobile technology 
so as to provide assessment and treatment intervention to children and adults 
with Autistic Spectrum Disorders (ASD). Learning and behavioural data for as-
sessment can be captured and interpreted through mobile technology, but the 
complexity of this data in special education can sometimes discourage staff 
from using it. Mobile technology intervention, in conjunction with ad hoc ap-
plications for ASD individuals, can contribute to the individuals’ needs to a 
great extent. Needless to say, speech generating devices (SGDs) are very sup-
portive tools for autistic people who mostly suffer from limited speech, espe-
cially devices which are portable. The use of mobile technology to enhance ac-
ademic skills, among others, is being investigated. Although this technology is 
new, the autistic community has expressed its enthusiasm about it. If all parties 
involved, such as educators, caregivers, sufferers and families participated in 
the design and implementation of the appropriate apps, this could best suit ASD 
individuals’ needs and would provide them with a better quality of life. 

Keywords—assessment, ICT, intervention, ASD, developmental disabilities, 
Augmentative and Alternative Communication (AAC), Computer Assisted 
Learning (CAL), Computer Assisted Instruction (CAI), mobile technology, 
iPad, iPod, iPhone, tablet, smartphone, children with autism (CWA). 

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Paper—Mobile Technology for Students & Adults with Autistic Spectrum Disorders (ASD)  

 

1 Introduction 

1.1 Autism Spectrum Disorders (ASD)  

Autism is a disorder which appears early in childhood and there is no apparent rea-
son behind the cause. At present time, there is no cure for this. Despite the fact that 
the child can become an autistic adult, early diagnosis will allow for more effective 
treatment. Current statistics show that autism affects up to two children in every thou-
sand, and that it is three times more likely to affect boys than girls [1]. There are no 
‘standard’ symptoms, only those which are more common. These can include an im-
pairment of non-verbal communication, a lack of spontaneous activity and a depend-
ence on repetitive actions. As a result, the autistic person appears to be closed off in 
their own world, a world in which normal social skills are impaired. A typical autistic 
child does not attempt to get attention unless it is to fulfill a need, which would there-
fore need to be provided by another person.  

As a result, the child seems to be ignoring the world at large and is usually very re-
sistant to external interaction and communication [21]. A number of treatments have 
been put forward for the cure of autism. Among these are treatments which are effi-
ciently carried out by technology such as the ones that will be analysed in the present 
study. 

1.2 Mobile Technology 

Mobile devices have gained popularity within the special needs community. These 
mobile devices are the “cool new” gadgets, unlike the previous, complex and “I-am-
not-normal-looking” assisting devices. These mobile devices are said to serve as a 
communication device in the pocket, a learning device on the go and even a lifesaver 
for some. Its features include flexible multimedia content and storage, portability, 
mobility and affordability. The touch screen interface makes it appealing and simple 
to use, particularly for those who have weak motor skills. It offers practical communi-
cation solutions for autistic people, so that they can interact with their families and 
others in the community. The flexibility and the advanced capabilities of mobile tech-
nology are opening new opportunities for further research in the area of computer-
based intervention for children with ASD. Several anecdotal reports give an early 
indication of the immense possibilities of how these devices could play a significant 
role in enhancing the quality of life for children with ASD and their families. There is 
definitely a lack of published research studies on the use of mobile technology among 
children with ASD. Due to the growing popularity of adopting mobile devices as 
assisting devices, more in depth research is warranted [2]. 

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Paper—Mobile Technology for Students & Adults with Autistic Spectrum Disorders (ASD)  

 

2 Mobile Technology Tools 

2.1 Mobile Tools for Assessment 

The effectiveness of receiving informative feedback for the purpose of updating the 
assessment and diagnosis of children with autism (CWA), as well as the therapeutic 
interventions, are presented by Gillian R. Hayes et al. (2014) in their review paper. 
The study took place at  the Emory Autism Research Center located at the Walden 
School. This center provides services for CWA. This study included the development 
of three prototype capture and access  applications: (1) The Walden Monitor, a weara-
ble prototype for recording observable data, with a head-mounted bullet camera based 
on a Tablet PC  for the research assistant to capture the child’s data. (2) Abaris, an 
Environmental Prototype for Recording Discrete Trial Data where therapists use a 
tablet application to customize the child’s daily therapy and to record data. (3) Care-
Log, a distributable prototype for recording semi-structured data that consists of a 
mobile system using the configuration of capture and access devices designed to col-
lect this information. The findings were that predetermined capture and access appli-
cations are not flexible enough to support the cyclical activities involved in caring for 
CWA, unless end users are able to iterate on the capture and access applications. 
Thus, it is critical that end users be involved in the process of developing capture and 
access applications, services and data integration processes in future applications [3]. 
The reasons why paper persists in the workplace of special education instead of tech-
nology for collection and use of student data is discussed in the paper of Gabriela 
Marcu et al. (2013). The staff itself, is positive towards trying new technologies pro-
vided that it supports their work practices and that they see evidence of success. The 
authors attempt to enumerate various technological devices and software such as the 
Abaris system for autism therapy, the AMA tablet application for data analysis and 
five mobile applications for iPads, such as: ABC DATA Pro, Autism Tracker Pro, 
Behavior Journal, Behavior Tracker Pro and Catalyst HD. However, the problem lies 
with the fact that special education does not have standardised or well established 
work practices, due to the individualised needs of each student and the unpredictable 
nature of the special education environment. In more detail, six factors affected the 
result of data collection in special education. Three of these factors explained why 
paper substitutes technology use and these are: 

1. Data needs are complex and not standardised 
2. Immediate demands of the job interfere with thorough in situ data collection 
3. Existing technology for data collection is inadequate 

The other three factors explain why technology could improve sharing and use of 
data: 

1. Data sheets are idiosyncratic and not useful without human mediation 
2. Improved communication with parents could benefit children’s development 
3. Staff are willing and even eager to incorporate technology 

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Paper—Mobile Technology for Students & Adults with Autistic Spectrum Disorders (ASD)  

 

Technology benefits can be augmented in the future, especially if data is collected 
in situ which is critical in autism education [4]. 

2.2 Mobile Tools for Intervention 

Using mobile technology, for people with special education needs (SEN) in all 
domains of life seems very promising lately. 

Debora M. Kagohara et al. (2013) conducted a review of studies that involved 
iPods, iPads and related devices in teaching programs for individuals with develop-
mental disabilities. The examination of 15 studies reported results for 47 individuals 
aged from 4 to 27 years old with autism spectrum disorder (ASD) and/or intellectual 
disabilities. It focused on five domains: (a) academic, (b) communication, (c) em-
ployment, (d) leisure and (e) transition across school settings. 

The main objectives of the review were to: (a) describe the skills that have been 
successfully taught to individuals with developmental disabilities using iPod/iPad-
based instruction, (b) describe the software applications that have been used  with 
these iPod/iPad-based instructional programs and (c) gain an overall view of the ef-
fectiveness of iPod/iPad-based instruction for this population. These devices and 
associated software applications have been used to either (i) deliver instructional 
prompts via the iPod Touch or iPad or (ii) teach the person to operate an iPod Touch 
or iPad to access preferred stimuli or as a speech-generating device (SGD) to request 
preferred stimuli. The results of these 15 studies were very encouraging suggesting 
that iPods, iPod Touch, iPads and related devices are viable technological aids for 
individuals with developmental disabilities. An important direction for future research 
is to use such devices for other communicative purposes such as greetings, conversa-
tions and comments [5]. 
The three major domains of intervening mobile tools will be thoroughly analysed 
next. 

Intervening Mobile Tools for Augmentative or Alternative Communication 
(AAC) In 2014, Sue Fletcher-Watson conducted a review on Computer-Assisted 
Learning (CAL) for people with autism spectrum disorder. New technologies are 
helping to break down some of the objections to computer assisted learning (CAL). 
Some people argue that CAL can only be delivered effectively in schools with lots of 
computers and that there is a lower ability limit on who can benefit. However CAL is 
being overtaken by technologically-enhanced approached similar to mobile devices. 
Even though a device such as an iPad carries a considerable price tag, once purchased 
the user has access to hundreds of low-priced apps marketed at people with autism 
and thousands more which may also be appealing. Communication apps such as 
Proloquo2Go or Speak4Yourself  come with the promise of giving a non-verbal per-
son with autism a voice. The rise of mobile devices such as Smartphones and the now 
wide-spread use of touchscreen technology invites new ways of thinking about educa-
tion and support for people with autism spectrum disorders. In an early example of his 
work, Bishop (2003) reports on the use of a mobile phone application called PARLE 
(Portable Affect Reference Learning Environment) which can be used to translate 
confusing language such as metaphors into simpler versions. Case studies indicate 

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Paper—Mobile Technology for Students & Adults with Autistic Spectrum Disorders (ASD)  

 

that PixTalk software can be incorporated into an on-going therapy. Mechling and his 
colleagues have successfully trialed the use of a personal digital assistant to support 
both abstract and real world skills by using step-by-step prompts [6],[7].  

Lizbeth Escobedo et al. (2012) study the Mobile Social Compass titled 
“MOSOCO”, a mobile assisting application that uses augmented reality and the visual 
supports of a validated curriculum, the Social Compass, to help children with autism 
practise social skills in real-life situations. They present the results of a seven-week 
deployment study of MOSOCO in a public school in Southern California with both 
autistic students and neurotypical (NT) students.   

MOSOCO provides autistic children with interactive features to encourage them to 
make eye contact, maintain appropriate spatial boundaries, reply on conversational 
initiators, share interests with partners, disengage appropriately at the end of an inter-
action and identify potential communication partners. MOSOCO runs on an Android 
smartphone which is wirelessly connected to a server. It uses the smartphone’s cam-
era to augment a real-life social situation with visual support mimicking the Social 
Compass curriculum which augments social stories using paper-based visual supports. 

The results of the study demonstrate that MOSOCO facilitates practicing and learn-
ing social skills, increases both quantity and quality of social interactions, reduces 
social and behavioural mistakes, and enables the integration of children with autism in 
social groups of neurotypical children [8]. 

Doris Adams Hill and Margaret M. Flores (2014) compared the Picture Exchange 
Communication System and the iPad™ for the Communication of students with Au-
tism Spectrum Disorder and Developmental Delay. 

The Picture Exchange Communication System (PECS™), a picture-based, low-
tech augmentative and alternative communication strategy developed by Frost and 
Bondy (2002), utilises preference for visual processing as well as the principles of 
Applied Behavior Analysis (ABA) to teach functional communication skills to indi-
viduals without that ability. PECS™ training occurs in six phases. It begins with 
teaching how to communicate (Phase I) and moves through five other phases which 
include increasing distance from the communicative partner (Phase II), picture dis-
crimination (Phase III), sentence structure (Phase IV), responding to “What do you 
want?”(Phase V) and commenting (Phase VI). 

There are iPad™ applications designed to facilitate its use as a communication sys-
tem. One such application is Proloquo2Go™ which provides augmentative and alter-
native communication (AAC) for people who have difficulty in speaking. It provides 
text-to-speech voices, colour picture symbols and a vocabulary of over 7000 items 
(Apple, 2011; Assistiveware, 2011). Utilising the iPad™ with the Proloquo2go appli-
cation as AAC can be used by individuals of all ages, is inexpensive compared to 
some devices and also portable. 

Each student was scheduled to experience eight sessions using PECS™ (Bondy & 
Frost,1994) and seven sessions using the iPad™ . 

The results of this study were mixed, with students responding differently to each 
communication intervention. This lack of difference is significant for the field be-
cause it shows that limited technological intervention can be as or more effective than 
more advanced technology. An intervention such as PECS might be preferable during 

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Paper—Mobile Technology for Students & Adults with Autistic Spectrum Disorders (ASD)  

 

the early stages of communication development. It would also make sense that the 
iPad™ be preferable once the student has developed a communication repertoire. 

It is important that early intervention strategies involving empirically-based inter-
ventions be used to influence a positive outcome for students with autism and devel-
opmental delay (DD) (National Autism Center, 2009). This study focused on compar-
ing the use of PECS™ and the iPad™ for the purpose of requesting. As a result, it is 
recommended that initial functional communication training begin with PECS™ and 
then with a transition from PECS™ (after mastery of phases I-III) to the iPad™. This 
could be a viable teaching progression of functional communication skills for some 
students with ASD or DD. The authors contend that this is worthy of additional re-
search [9]. 

Maggie Ward et al. (2013) evaluated an iPad application titled “Go Talk Now 
Free” as a functional communication tool for a five-year-old boy with ASD, through 
their study. This application is similarly formatted to the traditional Picture Exchange 
Communication System (PECS) request board, making all the choices visibly availa-
ble for the child to select on a single touch screen page on the application. The study 
that took place in the participant’s special education classroom required: (1) children 
to bring whichever activity they chose into the classroom (“the choose time”) during 
the baseline strategy, (2) researchers to successfully teach the participant how to make 
requests and test the use of the model, lead, test intervention strategy which was the 
purpose of this study and (3) researchers to provide no further verbal or physical 
prompting apart from the question “What do you want?” when presenting the iPad 
choose board to the participant during the independent strategy. The use of the iPad 
app “Go Talk Now Free” as functional communication proved to be successful for the 
participant, and a contributor to his success could have been his familiarity with using 
the iPad. Based on the success shown in this study, the researcher hopes that the par-
ticipant will generalise his knowledge of making independent requests by simply 
“choosing time” to “requesting” throughout the entire school day [10]. 

In 2013, David Mc Naughton and Janice Light point out in their paper that the iPad 
and other mobile technologies provide powerful new tools to potentially enhance 
communication for individuals with developmental disabilities, acquired neurogenic 
disorders and degenerative neurological conditions. These mobile technologies offer a 
number of potential benefits including: (a) increased awareness and social acceptance 
of augmentative and alternative communication (AAC), (b) greater consumer empow-
erment in accessing AAC solutions, (c) increased adoption of AAC technologies, (d) 
greater functionality and interconnectivity and (e) greater diffusion of AAC research 
and development. However, there are a number of significant challenges remaining 
that must be addressed if these benefits are to be fully realized: (a) to ensure the focus 
is on communication, not just technology, (b) to develop innovative models of AAC 
service delivery to ensure successful outcomes, (c) to ensure ease of access for all 
individuals who require AAC and (d) to maximize AAC solutions to support a wide 
variety of communication functions. Finally, research should consider the effects of 
iPads and other mobile technologies on the ASD’s facilitators: family members, 
teachers, etc., as well as making sure that the most complex communication needs are 
satisfied [11].  

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Amie M. King et al. (2013) conducted a study to describe how children and young 
adults with autism spectrum disorder (ASD) are currently using iPads® and applica-
tions. The purpose was to explore application use  and the role of educational profes-
sionals on  the iPad® as well as determining potential research needs regarding iPad® 
use in people with ASD. Six individuals (ages 6;6 to 20;8) with ASD were observed 
while they were using iPads® and apps in their classroom. The apps were categorized 
into: (1) augmentative and alternative communication (AAC) apps which represented 
51% of the app time spent, (2) academic apps, with 36% and (3) game apps with only 
13% of the app time spent. The observation included video data and the recording 
sessions occurred randomly so as to capture different behaviours throughout all activi-
ties. There were five phases in which the data were coded: (i) In the 1st phase,  all of 
the video data were reviewed repeatedly by the first and third authors. (ii) In the 2nd , 
the video data were filtered to exclude behaviours that provided irrelevant information 
to the study. (iii) The 3rd phase involved coding time spent in the different iPad® 
environments. (iv) The fourth phase of data coding consisted of indicating the pres-
ence or absence of an educational professional and the last one (v) involved further 
analysis on how the 28 apps were used by the participants. If the app was used in a 
way that was inconsistent with its intended function, it was characterized as a viola-
tion of the app which was a unique finding of this study. The final outcome of the 
study was that iPads being used at schools support ASD individuals. As long as there 
is an educational professional present, violation of apps is less likely to occur [12]. 

Sally Bereznak et al. (2012) conducted research in the field of video self-prompting 
and mobile technology to find out if these increase the capability of day-to-day living 
and vocational independence for students with autism spectrum disorders. Video 
instruction can include video modelling (VM) and/or video prompting (VP). In the 
current investigation, they essentially provided a prosthetic device (iPhone) and train-
ing to help the participants become more independent. In doing so, they  linked a 
number of elements of self-determined, self-efficacy and independence. 

The current study addressed two research questions related to video prompting in 
order to teach individuals with ASD. These questions focused on whether students 
would be able to learn how to use an iPhone as a self-prompting video tool to teach 
themselves vocational and independent living tasks and if they would be able to inde-
pendently complete them when using video prompting. The study furthered the evalu-
ation of handheld commercially-designed devices as an effective teaching tool for 
individuals with ASD as long as motor difficulties were not involved. The percentage 
of success when using the iPhone for completing the tasks was much higher than the 
one which guided them only through the baseline sessions.  

Further research is needed to describe effective techniques which can benefit indi-
viduals with ASD for potential employment opportunities so that they can efficiently 
and effectively follow through with various tasks without the assistance of others. 
(Mechling et al. 2009a, 2009b) [13]. 

Debora M. Kagohara et al. (2010) suggest an alternative solution for individuals 
with autism and limited speech. These individuals are prime candidates for speech 
generating devices (SGDs) yet face problems with these devices. SGDs are typically 
computer-based devices with a visual display and either have a digitised or synthe-

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sized speech output. Up till now, it was common for people who could not use these 
devices to be prescribed a different SGD or otherwise adapt to this existing device, 
both of which were quite costly. An other option was to give up using this type of 
technology. However, this was not a good solution either since SGDs provide one of 
the most complete forms of communication among all AACs, due to their assisting 
speech features. In Steven’s case, an autistic 17-year-old adolescent who used an i-
Pod SGD and had difficulty activating the speech output feature, a behavioural inter-
vention with differential reinforcement and delayed prompting was suggested. Specif-
ically, he used the i-Pod touch with Proloquo2Go software that he was prescribed 
with. He encountered difficulty in enabling the speech so alternatively a person was 
there to assist him in order to determinate if the problem was due to lack of motor 
control or if he was in need of behavioural intervention. The results showed that he 
corresponded positively to behavioural intervention and finally managed to complete 
the task of enabling the speech feature on his own by the required time [14]. 

Intervening Mobile Tools for Academic: Larah van der Meer et al. (2015) men-
tion in their paper that iPads have been successfully used as speech-generating devic-
es (SGDs) for children with ASD and limited speech. However, little research has 
investigated the use of iPads to enhance academic skills such as picture/word match-
ing. In the present study, a student with ASD received assistance in being taught pic-
ture and word matching by using an iPad-based SGD as a response mode. A multiple 
baseline across matching tasks design was used to evaluate the effects of a graduated 
guidance, prompting procedural and differential reinforcement on correct matching 
across four matching tasks (i.e. picture to picture, word to picture, picture to word and 
word to word). Targeting both picture and word matching is relevant to a range of  
academic/literacy skills. This technology may enable such students to participate in 
such academic/literacy skill tasks that they may otherwise be excluded from. 

Results indicate that the participant successfully learned picture and word matching 
with an iPad-based SGD as the response mode. Furthermore, the teaching procedures 
appeared to be effective in reducing repetitive responding and keeping the mind clear 
when the order in which pictures were presented was randomised. Future research is 
needed, though, to investigate the long-term effects that iPods/iPads may have on 
learning [15]. 

Leslie Neely et al. (2013) discuss the effects of using an iPad for instructional pur-
poses with regards to challenging behaviour and academic engagement. In recent 
years, the Apple iPad has emerged as a popular educational form of technology for 
individuals on the autism spectrum. This study compared the behaviour of two stu-
dents with ASD and escape-maintained challenging behaviour, when academic in-
struction was delivered via an iPad and when delivered through traditional materials. 
A reversal A–B–A–B design was implemented to deliver instruction using traditional 
materials in the first phase and instruction via the iPad in the second phase. Both chil-
dren showed lower levels of challenging behaviour and higher levels of academic 
engagement during the iPad situation whereas in the traditional materials situation, 
they showed higher levels of challenging behaviour with lower levels of academic 
engagement. As a result, there is an advantage of using the iPad because it seems to 
reduce escape-maintained behaviour in ASD children. Future research is warranted, 

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though, to investigate the duration of  the iPad’s effects as this form of technology is 
fairly new [16]. 

In 2014, Therese M. Cumming et al. did a research project on the introduction of  
iPads as instructional tools in order to enhance learning opportunities for students 
with developmental disabilities at a private school in Sydney. The core questions that 
teachers were addressing through this action research were: (a) How mobile devices 
such as iPads can assist and enhance learning opportunities among students. 

(b) What the perception of students with developmental disabilities and their teach-
ers is in regard to using the iPad as an instructional tool. Both questions were well-
aligned with the UDL model. 

The results related to the first question were well received by both teachers and 
students. What was obvious from the data analysis was that iPads have enhanced 
learning opportunities for students. The iPad was beneficial to students in the general 
areas of access, learning, independence and engagement. They worked independently 
on all their subjects through the use of iPad apps and most importantly through com-
munication which was assisted by the Proloquo2 app in a certain case. With regard to 
the second one, students found the technology effective in terms of reading instruc-
tion, vocabulary development and communication, as well as being fun and motivat-
ing. To fully test the effectiveness of the iPads, the addition of more stringent, qualita-
tive and quantitative data collection and analysis on student achievement is warranted 
for the future. In addition, research on tablet integration should be conducted across 
other settings and types of schools such as ones with no prior familiarisation with 
certain technology within the home [17]. 

In their study, Cathi Draper Rodríguez et al. (2013) show that implementing and 
using iPads in the special education classroom is very effective. Based on literature, 
suggestions on the planning and implementation of iPad technologies are as follows: 
(1) Planning for mobile technology in the classroom. Logistical preplanning must 
occur to ensure that the instructional time is used effectively, such as when students 
will use the devices, how many students will use the device at one time and  what the 
rules are for use and how they will be taught.  (2) Rubrics for choosing apps. Due to 
the large variety of educational apps in the market, it would be helpful for educators 
to access educational and behavioural app review sites or to use an evaluation rubric 
to determine the best applications for individual student needs. (3) Bulk buying for 
apps. Charging and syncing multiple devices can be a challenge for teachers purchas-
ing apps. IPad and iPod devices can be purchased through Apple’s volume purchase 
program. Apps for Android tablets can be purchased in bulk through Chrome App 
Packs. (4) Professional development. Self-efficacy among teachers with regard to 
using mobile devices as educational or assisting technology is an integral component 
of successful implementation (Messinger-Willma & Marino, 2010).  Professional 
development through mobile learning is offered to groups, face-to-face and online or 
by showing interest in research projects within this field at a low cost. (5) School–
home communication/collaboration. This is important for the families of students 
with disabilities. According to their needs, students are able to personalize their fea-
tures on their tablet. Therefore, parents will be able to take part in the required tasks 
along with their children. Parent training, as well as the teacher’s assistance, can en-

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courage involvement among all parties in order to support the student both at school 
and at home. (6) Transition between environments. The transition between school and 
the community can greatly benefit students with disabilities when using mobile devic-
es as an assisting tool. With the tips mentioned above, teachers can increase the effec-
tiveness of using technology with the hope of increasing the engagement and satisfac-
tion in their classrooms [18]. 

Cami E. Burton et al. (2013) conducted a study on Video Self-Modelling (VSM) 
with an iPad to teach functional mathematical skills to adolescents with Autism and 
Intellectual Disability. 

Functional mathematics focuses on teaching practical mathematics within real-life 
situations such as telling the time, using money and completing tasks related to meas-
urement. Four adolescent male students viewed videos of themselves on an iPad solv-
ing mathematical problems in order to estimate the amount of money used to pay for a 
given item and the amount needed to receive in change. A multiple-baseline-across-
participants design to investigate the effects of  VSM on the mathematical skill acqui-
sition of adolescents with autism was used. The design included baseline, intervention 
and post-intervention phases. The outcome was that VSM intervention allowed stu-
dents with disabilities to increase their access to the core curriculum without teacher 
assistance. Additional  research is needed to examine the use of VSM via an iPad to 
teach students with autism and intellectual disabilities a variety of  academic subjects 
such as science, reading and writing [19]. 

Heather Duncan, Joo Tan (2012) describe a project idea in their paper to design 
and implement a mobile web application on iPad2 that would allow adults with au-
tism to complete their work with minimal supervision. Supervision is often an obsta-
cle for employment since employers are not fond of providing job coaches or super-
vising their autistic employees themselves. This application would aim to reduce the 
amount of supervision as it would act as a visual task manager or as a supervisor. One 
important feature of the application would be the ability to split each task into small 
“inner steps” that would signify its completion. Another one would be to include a 
communication system that would allow both image-based and text-to-speech com-
munication. Having a number of customization options, providing Wireless Internet 
functionality and offering the ability to create video, animation or photo slideshows 
would enhance the ability of the schedule to convey the inner steps of a task to the 
autistic individual. The ongoing research would be divided into two major phases. 
Phase one would focus on functionality that is related to the end user (the autistic 
individual) interface. Phase two (future) of this research would involve supervisor 
functions such as creating/updating the tasks, including storage capability and adding 
security features [20]. 

Intervening Mobile Tools for Entertainment: In their paper, Iain Werry et al. 
(1999) discuss how mobile robotics are able to aid disabled, handicapped or autistic 
people. Through the AuRoRA (Autonomous Robotic platform as a Remedial tool for 
children with Autism) research project, Mobile Robotic Technology can be useful in a 
scientifically challenging application area named the rehabilitation of children with 
autism. It has the potential to advance our understanding of human-robot interface 
design, as well as aid in the rehabilitation of the autistic people. This is attempted 

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through the TEACCH philosophy method which guides the robotic platform to pro-
vide the necessary stimulation to re-enforce the child’s responses. Additionally, what 
is needed the most in the autistic world is: 

• a stable environment through repetitive actions 
• keeping away the fear of the unpredictable  
• keeping the child’s attention by stretching its interactive and communicative abili-

ties, 

all of which can be provided by the robot.  
The initial robot, a Labo-1 mobile platform, has sensors for input information and 

two buttons for behavioural selection. However, future developments are expected to 
have more sensors, a camera, an optional speech device and advanced machine-
learning capabilities so as to adapt continually and provide enjoyable life-like experi-
ences [21]. 

Through their research, Juan Pablo Hourcade et al. (2013) evaluate weather tablet 
apps can encourage social interaction in children with autism spectrum disorders. The 
set of apps - Drawing, Music, Untagle and Photogoo – which are all from Open Au-
tism Software aim to help children with ASD associate social face-to-face interaction 
with playing. It is true that positive feelings came out of the children when they initi-
ated with tablets because they were not anxious over the presence of an unpredictable 
person. The apps have very simple user interfaces with little or no use of words to 
better appeal. There is also no right or wrong way of doing things with the apps. Chil-
dren are able to explore the apps, express themselves freely and also reduce anxiety. 

It was also investigated as to whether activities with multi-touch tablet apps pro-
moted better social behaviour over activities without tablets. This appeared to be a 
fact, where video recordings attributed to the results through capturing the children’s 
faces and body gestures. 

More specifically, the types of events they coded, among others, were: verbal in-
teractions, supportive comments between kids and physical interactions. These three 
made a positive difference when students socialised through tablets rather than doing 
the activities without them [22]. 

The present study by Debora M. Kagohara (2010) examines whether students with 
developmental disabilities can learn to self-operate an iPod Touch in order to watch 
entertaining videos with video modelling (VM) and response prompting. Three stu-
dents were selected for this study. They all attended the same classroom in a special-
ised school for adolescents and young adults with a range of disabilities. A question-
naire was created to give the participants as stakeholders an opportunity to consent to 
their involvement in the study and to identify preferred stimuli for use in the study. 
The questionnaire seemed to have a positive influence since the participants felt their 
opinion mattered. All participants indicated that they were interested in learning how 
to use the iPod and provided a list of what they liked to watch. They also indicated 
that watching a video was one of their preferred methods for learning. The aim of the 
study was to motivate students to participate and to teach them how to operate the 
iPod in order to watch their preferred entertainment videos. Future research could  

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Paper—Mobile Technology for Students & Adults with Autistic Spectrum Disorders (ASD)  

 

determine whether participants might be differentially sensitive to other iPod-based 
leisure skills such as playing video games or listening to music [23]. 

3 Conclusion 

In conclusion, mobile technology is very appealing to all children, especially to 
those with ASD, who lack communication skills but are eager to play with a portable 
device. Predicted responses from a mobile device do not cause any anxiety to these 
children, thus have a gamesome attitude and feel more secure.  

Mobile technology assessment tools are very important, not only for the initial di-
agnosis of autism, but for updating the sequent assessments throughout a patient’s 
therapeutic intervention. It is found that a continual observation of the patient’s be-
haviour will end up receiving the correct diagnosis and can only be achieved by a 
mobile device that records constantly. 

Despite the fact that capturing data for assessment can sometimes be a tedious task 
with ongoing mobile technologies, due to the data’s complexity, the assessment per-
sonnel is optimistic and receptive to new approaches.  

Mobile technology tools for intervention are quite promising, too at present and 
progress has already been made in ASD individuals as shown by the statistics. There 
is always enough space for further development, though, and better applications for 
the ASDs especially if these are implemented by all parties, such as family members, 
educators and therapists who are involved in the rehabilitation of the autistic people. 

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5 Authors 

Athanasios Drigas is a Research Director at IIT-N.C.S.R. Demokritos. He is the 
Coordinator of Telecoms Lab and founder of Net Media Lab since 1996. From 1990 
to 1999 he was the Operational manager of the Greek Academic network. He has 
been the Coordinator of Several International Projects, in the fields of ICTs, and e-
services (e-learning, e-psychology, e-government, e-inclusion, e-culture etc). He has 
published more than 270 articles, 7 books, 25 educational CD-ROMs and several 
patents. He has been a member of several International committees for the design and 
coordination of Network and ICT activities and of international conferences and jour-
nals. (e-mail: dr@iit.demokritos.gr). 

Jenny Vlachou (MA in Teaching Methodology of Computer Science) is a Special 
Education ICT Teaching Professional, and scientific collaborator of Net Media Lab, 
NCSR Demokritos. (e-mail: jvlachou@gmail.com). 

Submitted 08 June 2016. Published as resubmitted by the authors 23 September 2016. 

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	iJIM – Vol. 11, No. 1, 2017
	Mobile Technology for Students & Adults with Autistic Spectrum Disorders (ASD)