AnArU, a virtual reality framework for physical human interactions

Virtual Reality has become, once again, a popular and interesting topic, both as a research and commercial field. This trend has its origin in the use of mobile devices as computational core and displays for Virtual Reality. Android is one of the most used platform in this context and Unity3d is a suitable graphic engine for such platform. In order to improve the immersive experience, some electronic devices, Arduino especially, are used to gather information, such as the movement of the user's arms or legs. Although these three elements are often used in Virtual Reality, few studies use all of them in combination. Those who do, do not develop a reusable framework for their implementations. In this work we present AnArU, a framework for physical human interaction in Virtual Reality. The goal of AnArU is to allow an easy, efficient and extensible communication between electronic devices and the Virtual Reality system.XIII Workshop Computación Gráfica, Imágenes y Visualización (WCGIV)Red de Universidades con Carreras en Informática (RedUNCI

AnArU, a virtual reality framework for physical human interactions

Virtual Reality has become, once again, a popular and interesting topic, both as a research and commercial field. This trend has its origin in the use of mobile devices as computational core and displays for Virtual Reality. Android is one of the most used platform in this context and Unity3d is a suitable graphic engine for such platform. In order to improve the immersive experience, some electronic devices, Arduino especially, are used to gather information, such as the movement of the user's arms or legs. Although these three elements are often used in Virtual Reality, few studies use all of them in combination. Those who do, do not develop a reusable framework for their implementations. In this work we present AnArU, a framework for physical human interaction in Virtual Reality. The goal of AnArU is to allow an easy, efficient and extensible communication between electronic devices and the Virtual Reality system.XIII Workshop Computación Gráfica, Imágenes y Visualización (WCGIV)Red de Universidades con Carreras en Informática (RedUNCI

AnArU, a virtual reality framework for physical human interactions

Virtual Reality has become, once again, a popular and interesting topic, both as a research and commercial field. This trend has its origin in the use of mobile devices as computational core and displays for Virtual Reality. Android is one of the most used platform in this context and Unity3d is a suitable game engine for such platform. In order to improve the immersive experience, some electronic devices, Arduino especially, are used to gather information, such as the movement of the user’s arms or legs. Although Android, Arduino and Unity3d are often used independently in Virtual Reality investigations, few studies use all of them together. Furthermore, each time these technologies are used in a new project, the developers have to think about a new way of communication between them. In this work we present AnArU, a framework for physical human interaction in Virtual Reality. The goal of AnArU is to allow an easy, efficient and extensible communication between the hardware and software involved in the Virtual Reality System.Facultad de Informátic

AnArU, a virtual reality framework for physical human interactions

Virtual Reality has become, once again, a popular and interesting topic, both as a research and commercial field. This trend has its origin in the use of mobile devices as computational core and displays for Virtual Reality. Android is one of the most used platform in this context and Unity3d is a suitable game engine for such platform. In order to improve the immersive experience, some electronic devices, Arduino especially, are used to gather information, such as the movement of the user’s arms or legs. Although Android, Arduino and Unity3d are often used independently in Virtual Reality investigations, few studies use all of them together. Furthermore, each time these technologies are used in a new project, the developers have to think about a new way of communication between them. In this work we present AnArU, a framework for physical human interaction in Virtual Reality. The goal of AnArU is to allow an easy, efficient and extensible communication between the hardware and software involved in the Virtual Reality System.Facultad de Informátic

AnArU, a virtual reality framework for physical human interactions

Virtual Reality has become, once again, a popular and interesting topic, both as a research and commercial field. This trend has its origin in the use of mobile devices as computational core and displays for Virtual Reality. Android is one of the most used platform in this context and Unity3d is a suitable graphic engine for such platform. In order to improve the immersive experience, some electronic devices, Arduino especially, are used to gather information, such as the movement of the user's arms or legs. Although these three elements are often used in Virtual Reality, few studies use all of them in combination. Those who do, do not develop a reusable framework for their implementations. In this work we present AnArU, a framework for physical human interaction in Virtual Reality. The goal of AnArU is to allow an easy, efficient and extensible communication between electronic devices and the Virtual Reality system.XIII Workshop Computación Gráfica, Imágenes y Visualización (WCGIV)Red de Universidades con Carreras en Informática (RedUNCI

AnArU, a virtual reality framework for physical human interactions

Virtual Reality has become, once again, a popular and interesting topic, both as a research and commercial field. This trend has its origin in the use of mobile devices as computational core and displays for Virtual Reality. Android is one of the most used platform in this context and Unity3d is a suitable game engine for such platform. In order to improve the immersive experience, some electronic devices, Arduino especially, are used to gather information, such as the movement of the user’s arms or legs. Although Android, Arduino and Unity3d are often used independently in Virtual Reality investigations, few studies use all of them together. Furthermore, each time these technologies are used in a new project, the developers have to think about a new way of communication between them. In this work we present AnArU, a framework for physical human interaction in Virtual Reality. The goal of AnArU is to allow an easy, efficient and extensible communication between the hardware and software involved in the Virtual Reality System.Facultad de Informátic

Engaging immersive video consumers: Challenges regarding 360-degree gamified video applications

360-degree videos is a new medium that has gained the attention of the research community imposing challenges for creating more interactive and engaging immersive experiences. The purpose of this study is to introduce a set of technical and design challenges for interactive, gamified 360-degree mixed reality applications that immerse and engage users. The development of gamified applications refers to the merely incorporation of game elements in the interaction design process to attract and engage the user through playful interaction with the virtual world. The study presents experiments with the incorporation of series of game elements such as time pressure challenges, badges and user levels, storytelling narrative and immediate visual feedback to the interaction design logic of a mixed reality mobile gaming application that runs in an environment composed of 360-degree video and 3D computer generated objects. In the present study, the architecture and overall process for creating such an application is being presented along with a list of design implications and constraints. The paper concludes with future directions and conclusions on improving the level of immersion and engagement of 360-degree video consumers

A Simulation Pedagogical Approach to Engaging Generalist Pre-service Teachers in Physical Education Online: The GoPro Trial 1.0

There has been a continuous increase in enrolments within teacher education programs in recent years delivered via online and external modes. Such levels of enrolment have raised discussion around the theory-practice nexus and whether pre-service teachers (PSTs) can optimally engage with practical learning components via online platforms. This paper provides insight into the potential and feasibility of using GoPro video technology as an innovation in online teacher education delivery of practical physical education (PE) classes. Upon completion of the university semester, qualitative data was collected detailing the generalist PSTs’ perceptions relating to the potential of using GoPro video footage to capture practical PE classes. Field note observations also documented implementation considerations for integrating GoPro technology into practical PE lessons. The findings from the GoPro trial provide valuable insight for teacher education providers for future planning and delivery of university practical PE classes onlin

Utilization of viewer location based projection effects on ODV video display in CAVE like environments

The thesis work provides an overview of the CAVE-like virtual environments by describing and comparing different kinds of virtual environments and the technologies behind them. It provides through information about presence, immersion and user experience of a virtual environment. It also explains the concept of omni directional videos, which are used in CAVE virtual environment. The study involves a CAVE-like virtual environment hardware setup situated at University of Tampere. The system is evaluated by conducting an experiment where the participants are viewing objects in omni directional (360-degree) videos (ODV). The participants were asked to perform certain tasks within virtual environments. The study objective is to understand how adjusting virtual camera parameters based on the user’s physical head location effects the user experience of viewing 360-degree videos in a CAVE-like environment. Three conditions are tested which are termed as scaling conditions. In each scaling condition, the virtual camera moved differently based on the user’s head movements. The results are collected through questionnaires, observations and interviews. The questionnaire data is compiled using statistical analysis. The results describe the overall user experience of CAVE-like virtual environment, the level of immersion and presence felt by the user and any possible cyber-sickness. The study conducted paves way to explore different dimensions of CAVE-based ODV viewing and how to improve it