Using a Cognitive Model of Web-Navigation to Generate Support for 3D Virtual Navigation

AbstractThough the cognitive processes controlling user navigation in virtual environments as well as in websites are similar, cognitive models of web-navigation have never been used for generating support in virtual environment navigation. We created a simulated 3D building of a hospital and presented users various navigation tasks under two conditions: a control condition and a model-generated support condition. Participants with model-generated support participants took significantly less time to reach their destination and were significantly less disoriented. The impact of model-generated support on disorientation was especially higher for users with low spatial ability

An empirical study of virtual reality menu interaction and design

This study focused on three different menu designs each with their own unique interactions and organizational structures to determine which design features would perform the best. Fifty-four participants completed 27 tasks using each of the three designs. The menus were analyzed based on task performance, accuracy, usability, intuitiveness, and user preference. Also, an analysis was conducted between two different menu organization styles: top-down menu organization (Method-TD) and bottom-up organization (Method-BU). There was no evidence that demographic factors had any effect on the overall results. By and large, the Stacked menu design received very positive results and feedback from all the participants. The Spatial design received average feedback with some participants preferring it while others struggled to use it and felt that it was too physically demanding. The worst performer was the Radial design that consistently ranked last and failed to pass usability and accuracy tests. A NGOMSL study was conducted to determine any differences in performance between a top-down menu organizational approach and a bottom-up approach or differences between the predicted task completion times and the reported times. The results of this study predicted that the Spatial design should have taken the least amount of time to perform, however, the experimental results showed that the Stacked design in fact out-performed the Spatial design’s task completion times. A potential explanation as to why the Stacked outperformed the Spatial is the increased physical demand of the Spatial design not anticipated with the NGOMSL analysis because of a design feature which caused a high level of cumbersomeness with the interactions. Overall, there were no statistical differences found between Method-TD and Method-BU, but a large difference found between the predicted times and observed times for Stacked, Radial, and Spatial. Participants overwhelmingly performed better than the predicted completion times for the Stacked design, but then did not complete the tasks by the predicted times for the Radial and Spatial. This study recommends the Stacked menu for VR environments and proposes further research into a Stacked-Spatial hybrid design to allow for the participant’s preferred design aspects of both designs to be used in a VR environment

Designing engaging experiences with location-based augmented reality games for urban tourism environments.

Gameplay has recently unfolded as playfulness in various cultural forms using mobile technologies. The rapid affordability paired with the latest technology improvements enabled the diffusion of mobile devices among tourists, who are among the most avid users of mobile technologies. The advent of mobile devices has initiated a significant change in the way we perceive and connect with our environment and paved the way for location-based, mobile augmented reality (AR) games that provide new forms of experiences for travel and tourism. With the recent developments like Pokémon Go and a prediction of 420 million downloads per year by 2019, the mobile game market is one of the fastest growing fields in the sector. Location-based AR games for mobile devices make use of players‟ physical location via the GPS sensor, accelerometer and compass to project virtual 2D and 3D objects with the build-in camera in real time onto the mobile game user interface (GUI) in order to facilitate gameplay activities. Players interact with the virtual and physical game world and overcome artificial challenges while moving around in the real environment. Where current mobile games withdraw players from reality, location-based AR games aim to engage players with the physical world by combining virtual and physical game mechanics in an enhanced way that increases the level of interactive educative and entertaining engagement. Despite some recent research on location-based AR games, game designers do not know much about how to address tourism requirements and the development of mediated playful experiences for urban tourism environments. This study explores the use of location-based AR games to create engaging and meaningful experiences with the tourism urban environment by combining interdisciplinary research of social sciences, (mobile) game design and mobile game user research (mGUR) to contribute to experience design in the context of travel and tourism. Objectives of the study are to identify the influence of key game elements and contextual gameplay parameters on the individual game experience (GX). To achieve the aim, the study has taken a pragmatic interpretivist approach to understand the player‟s individual GX in an evolving gameplay process in order to inform location-based game design. The project explores the interaction between the player, the game and the tourism context, which is assessed by a sequential triangulation of qualitative mixed methods. Two games were identified to be relevant for the tourism application that fulfilled the attributes of a location-based AR game. The first game is a role-playing adventure game, set in the time and place of the Cold War, called Berlin Wall 1989. The second game, Ingress, is a fictive, large area, massively multiplayer role-playing game that uses the real world as the battleground between two game fractions. A conceptual framework has been developed that presents the player engagement process with location-based AR games in urban tourism environments. The findings of the study indicate that gameplay is a moment-by-moment experience that is influenced by multiple aspects. The creation of engaging experiences between players, the game and the tourism context is related to six identified engagement characteristics; emotional engagement, ludic engagement, narrative engagement, spatial engagement, social engagement and mixed reality engagement. The study identified that the main motivations of playing a location-based AR game are the exploration of and learning about the visited destination, curiosity about the new playful activity and socialising with other players. Emotions underlie the creation of engagement stimulated by the alteration of playful interactions. The findings revealed that storytelling and simple game mechanics such as walking, feedback and goal orientation are essential elements in the creation of engaging experiences. Augmented reality, as a feature to connect the real with the virtual world, needs to create real added value for the gameplay in order to be perceived as engaging for players. The study proposes serious location-based AR games as an alternative form for tourism interpretation and has showed opportunities to enhance the tourist experience through self-directed, physical and mental interaction between players, the environment and the location-based AR game. The findings of the research illustrate the complexity of designing location-based game experiences. The developed conceptual framework can be used to inform future location-based AR game design for travel and tourism