An exploration of the potential of Automatic Speech Recognition to assist and enable receptive communication in higher education

The potential use of Automatic Speech Recognition to assist receptive communication is explored. The opportunities and challenges that this technology presents students and staff to provide captioning of speech online or in classrooms for deaf or hard of hearing students and assist blind, visually impaired or dyslexic learners to read and search learning material more readily by augmenting synthetic speech with natural recorded real speech is also discussed and evaluated. The automatic provision of online lecture notes, synchronised with speech, enables staff and students to focus on learning and teaching issues, while also benefiting learners unable to attend the lecture or who find it difficult or impossible to take notes at the same time as listening, watching and thinking

3D assistive technologies and advantageous themes for collaboration and blended learning of users with disabilities

The significance of newly emergent 3D virtual worlds to different genres of users is currently a controversial subject in deliberation. Users range from education pursuers, business contenders, and social seekers to technology enhancers and many more who comprise both users with normal abilities in physical life and those with different disabilities. This study aims to derive and critically analyze, using grounded theory, advantageous and disadvantageous themes and their sub concepts of providing elearning through 3D Virtual Learning Environments (VLEs), like Second Life, to disabled users; hence providing evidence that 3DVLEs not only support traditional physical learning, but also offer e-learning opportunities unavailable through 2D VLEs (like moodle, blackboard), and offer learning opportunities unavailable through traditional physical education. Furthermore, to achieve full potential from the above mentioned derived concepts, architectural and accessibility design requirements of 3D educational facilities proposed by different categories of disabled students to accommodate for their needs, are demonstrated

Challenges in Inclusiveness for People with Disabilities within STEM Learning and Working Environments

This report is a reflection on the necessity for the inclusion of people with disabilities in the field of STEM and the different methods and processes that need to be revised or implemented to achieve this goal. It will delve into further detail about the challenges facing PWDs in STEM through interview anecdotes and survey results. Each solution offered will be accompanied by thorough research and support. Policymakers, teachers and students may use these recommendations to break down barriers to STEM careers and build a more inclusive future

The VIVID model : accessible IT e-learning environments for the vision impaired

Sighted learners and vision impaired learners experience different problems when accessing e-learning environments. Web designers use complex visual images and interactive features which learners with vision impairment are unable to access. Learners with vision impairment must rely on assistive technologies to acquire the information they are seeking. Vision impaired learners must have conversion facilities to translate the contents of these displays into readable and accessible formats.This research identifies problems faced by learners with vision impairment and demonstrates how e-learning environments must be modified to ensure success. The most significant problems are the lack of accessibility to teaching materials and an inability to participate in the learning experience to the same extent as sighted learners. Learning materials designed for sighted learners are often unsuited to those with vision impairment. Frequently, text provided is too small and unable to be altered; colour graphics are of little value unless accompanied by text or audio description and interactive Web sites present numerous challenges in navigation. Most courses are designed for sighted learners and learners with vision impairment struggle to maintain the required timeframe because of difficulties in reading texts and documents, completing assignments and sourcing reference materials due to their inaccessible formats and presentation.These problems result in lower academic achievement for vision impaired learners, which in turn lead to a lack of choices in employment opportunities. Learning environments for people with vision impairment need specific consideration in design and implementation. This ensures that the learning materials meet their needs and allow maximum accessibility so that the learners can achieve the same outcomes as their sighted peers.There is a small number of existing models to assist the design of e-learning sites for people with a disability. Kelley’s holistic model (2005) and Seale’s contextualised model (2006) are designed for people with disabilities in general and not specifically for those with vision impairment. Lazar’s Web accessibility integration model (2004) does not take into account the importance of social elements. Prougestaporn’s WAVIP model, (2010) whilst it has generic guidelines, the model is limited in its scope.Venable’s Design Science Research method was chosen to investigate the specific problems faced by vision impaired learners enrolled in IT e-learning courses. The characteristics of approximately one hundred adult vision impaired learners were investigated using two case study environments. The data were collected by observation and semi-structured interviews. Additionally, data were collected from these same learners to identify their specific needs in a Web-based learning situation. Accessibility needs were also identified and analysed. These activities involved the Problem Diagnosis stage in the Design Science Research model. Accessibility guidelines and legal and statutory requirements from several sources were also investigated. The components needed to deliver an effective, fully accessible IT curriculum in two Web-based e-learning environments for the vision impaired was then identified.Information was compiled from studying two learning environments for the vision impaired. Data instruments used in this phase were observations and semi-structured interviews with vision impaired learners and teachers. These activities involved the Problem Diagnosis and Theory Building stages of the Venable model. The relationships between the characteristics and needs of the learner, and the components of the learning environment for an Information and Communications and Technology (ICT) curriculum were analysed and then synthesised to build a conceptual model of an effective Web-based e-learning environment for the vision impaired.A new theoretical model, the Vision Impaired using Virtual IT Discovery (VIVID) was then developed. This holistic framework takes into account the specific needs of vision impaired learners. It also includes a social element which vision impaired learners identified as being extremely important to the success of their learning. This activity involved both the Technology Design/Invention state and the Theory Building stage in the Venable model.An evaluation was carried out by a focus group of eight experts in the field of accessible and e-learning course design and the model was then modified to incorporate their suggestions.The resulting model is a high level, comprehensive conceptual model that can be applied in differing pedagogical environments relating to IT education for adult learners with vision disabilities. It provides a framework to guide education managers, instructional designers and developers who are creating accessible IT e-learning environments for the vision impaired.Whilst this model relates only to the IT area, further research could extend its use to other curriculum areas and to those learners with multiple disabilities

Teaching Visually Impaired College Students in Introductory Statistics

Instructors of postsecondary classes in statistics rely heavily on visuals in their teaching, both within the classroom and in resources like textbooks, handouts, and software, but this information is often inaccessible to students who are blind or visually impaired (BVI). The unique challenges involved in adapting both pedagogy and course materials to accommodate a BVI student may provoke anxiety among instructors teaching a BVI student for the first time, and instructors may end up feeling unprepared or “reinventing the wheel.” We discuss a wide variety of accommodations inside and outside of the classroom grounded in the empirical literature on cognition and learning and informed by our own experience teaching a blind student in an introductory statistics course

A Rule Set for the Future

This volume, Digital Young, Innovation, and the Unexpected, identifies core issues concerning how young people's use of digital media may lead to various innovations and unexpected outcomes. The essays collected here examine how youth can function as drivers for technological change while simultaneously recognizing that technologies are embedded in larger social systems, including the family, schools, commercial culture, and peer groups. A broad range of topics are taken up, including issues of access and equity; of media panics and cultural anxieties; of citizenship, consumerism, and labor; of policy, privacy, and IP; of new modes of media literacy and learning; and of shifting notions of the public/private divide. The introduction also details six maxims to guide future research and inquiry in the field of digital media and learning. These maxims are "Remember History," "Consider Context," "Make the Future (Hands-on)," "Broaden Participation," "Foster Literacies," and "Learn to Toggle." They form a kind of flexible rule set for investigations into the innovative uses and unexpected outcomes now emerging or soon anticipated from young people's engagements with digital media

Using Information Communications Technologies to Implement Universal Design for Learning

The purpose of this paper is to assist Ministries of Education, their donors and partners, Disabled Persons Organizations (DPOs), and the practitioner community funded by and working with USAID to select, pilot, and (as appropriate) scale up ICT4E solutions to facilitate the implementation of Universal Design for Learning (UDL), with a particular emphasis on supporting students with disabilities to acquire literacy and numeracy skills. The paper focuses primarily on how technology can support foundational skills acquisition for students with disabilities, while also explaining when, why, and how technologies that assist students with disabilities can, in some applications, have positive impacts on all students’ basic skills development. In 2018, USAID released the Toolkit for Universal Design for Learning to Help All Children Read, section 3.1 of which provides basic information on the role of technologies to support UDL principles and classroom learning. This paper expands upon that work and offers more extensive advice on using ICT4E1 to advance equitable access to high quality learning. Like the UDL toolkit, the audience for this guide is mainly Ministries of Education and development agencies working in the area of education, but this resource can also be helpful for DPOs and non-governmental organizations (NGOs) wishing to pilot or spearhead ICT initiatives. Content for this paper was informed by expert interviews and reviews of field reports during 2018. These included programs associated with United Nations, Zero Project, World Innovation Summit, UNESCO Mobile Learning Awards, and USAID’s All Children Reading: A Grand Challenge for Development. Relevant case studies of select education programs integrating technology to improve learning outcomes for students with disabilities were summarized for this document

E-Learning

E-learning enables students to pace their studies according to their needs, making learning accessible to (1) people who do not have enough free time for studying - they can program their lessons according to their available schedule; (2) those far from a school (geographical issues), or the ones unable to attend classes due to some physical or medical restriction. Therefore, cultural, geographical and physical obstructions can be removed, making it possible for students to select their path and time for the learning course. Students are then allowed to choose the main objectives they are suitable to fulfill. This book regards E-learning challenges, opening a way to understand and discuss questions related to long-distance and lifelong learning, E-learning for people with special needs and, lastly, presenting case study about the relationship between the quality of interaction and the quality of learning achieved in experiences of E-learning formation