Spherical tangible user interfaces in mixed reality

The popularity of virtual reality (VR) and augmented reality (AR) has grown rapidly in recent years, both in academia and commercial applications. This is rooted in technological advances and affordable head-mounted displays (HMDs). Whether in games or professional applications, HMDs allow for immersive audio-visual experiences that transport users to compelling digital worlds or convincingly augment the real world. However, as true to life as these experiences have become in a visual and auditory sense, the question remains how we can model interaction with these virtual environments in an equally natural way. Solutions providing intuitive tangible interaction would bear the potential to fundamentally make the mixed reality (MR) spectrum more accessible, especially for novice users. Research on tangible user interfaces (TUIs) has pursued this goal by coupling virtual to real-world objects. Tangible interaction has been shown to provide significant advantages for numerous use cases. Spherical tangible user interfaces (STUIs) present a special case of these devices, mainly due to their ability to fully embody any spherical virtual content. In general, spherical devices increasingly transition from mere technology demonstrators to usable multi-modal interfaces. For this dissertation, we explore the application of STUIs in MR environments primarily by comparing them to state-of-the-art input techniques in four different contexts. Thus, investigating the questions of embodiment, overall user performance, and the ability of STUIs relying on their shape alone to support complex interaction techniques. First, we examine how spherical devices can embody immersive visualizations. In an initial study, we test the practicality of a tracked sphere embodying three kinds of visualizations. We examine simulated multi-touch interaction on a spherical surface and compare two different sphere sizes to VR controllers. Results confirmed our prototype's viability and indicate improved pattern recognition and advantages for the smaller sphere. Second, to further substantiate VR as a prototyping technology, we demonstrate how a large tangible spherical display can be simulated in VR. We show how VR can fundamentally extend the capabilities of real spherical displays by adding physical rotation to a simulated multi-touch surface. After a first study evaluating the general viability of simulating such a display in VR, our second study revealed the superiority of a rotating spherical display. Third, we present a concept for a spherical input device for tangible AR (TAR). We show how such a device can provide basic object manipulation capabilities utilizing two different modes and compare it to controller techniques with increasing hardware complexity. Our results show that our button-less sphere-based technique is only outperformed by a mode-less controller variant that uses physical buttons and a touchpad. Fourth, to study the intrinsic problem of VR locomotion, we explore two opposing approaches: a continuous and a discrete technique. For the first, we demonstrate a spherical locomotion device supporting two different locomotion paradigms that propel a user's first-person avatar accordingly. We found that a position control paradigm applied to a sphere performed mostly superior in comparison to button-supported controller interaction. For discrete locomotion, we evaluate the concept of a spherical world in miniature (SWIM) used for avatar teleportation in a large virtual environment. Results showed that users subjectively preferred the sphere-based technique over regular controllers and on average, achieved lower task times and higher accuracy. To conclude the thesis, we discuss our findings, insights, and subsequent contribution to our central research questions to derive recommendations for designing techniques based on spherical input devices and an outlook on the future development of spherical devices in the mixed reality spectrum.Die Popularität von Virtual Reality (VR) und Augmented Reality (AR) hat in den letzten Jahren rasant zugenommen, sowohl im akademischen Bereich als auch bei kommerziellen Anwendungen. Dies ist in erster Linie auf technologische Fortschritte und erschwingliche Head-Mounted Displays (HMDs) zurückzuführen. Ob in Spielen oder professionellen Anwendungen, HMDs ermöglichen immersive audiovisuelle Erfahrungen, die uns in fesselnde digitale Welten versetzen oder die reale Welt überzeugend erweitern. Doch so lebensecht diese Erfahrungen in visueller und auditiver Hinsicht geworden sind, so bleibt doch die Frage, wie die Interaktion mit diesen virtuellen Umgebungen auf ebenso natürliche Weise gestaltet werden kann. Lösungen, die eine intuitive, greifbare Interaktion ermöglichen, hätten das Potenzial, das Spektrum der Mixed Reality (MR) fundamental zugänglicher zu machen, insbesondere für Unerfahrene. Die Forschung an Tangible User Interfaces (TUIs) hat dieses Ziel durch das Koppeln virtueller und realer Objekte verfolgt und so hat sich gezeigt, dass greifbare Interaktion für zahlreiche Anwendungsfälle signifikante Vorteile bietet. Spherical Tangible User Interfaces (STUIs) stellen einen Spezialfall von greifbaren Interfaces dar, insbesondere aufgrund ihrer Fähigkeit, beliebige sphärische virtuelle Inhalte vollständig verkörpern zu können. Generell entwickeln sich sphärische Geräte zunehmend von reinen Technologiedemonstratoren zu nutzbaren multimodalen Instrumenten, die auf eine breite Palette von Interaktionstechniken zurückgreifen können. Diese Dissertation untersucht primär die Anwendung von STUIs in MR-Umgebungen durch einen Vergleich mit State-of-the-Art-Eingabetechniken in vier verschiedenen Kontexten. Dies ermöglicht die Erforschung der Bedeutung der Verkörperung virtueller Objekte, der Benutzerleistung im Allgemeinen und der Fähigkeit von STUIs, die sich lediglich auf ihre Form verlassen, komplexe Interaktionstechniken zu unterstützen. Zunächst erforschen wir, wie sphärische Geräte immersive Visualisierungen verkörpern können. Eine erste Studie ergründet die Praxistauglichkeit einer einfach konstruierten, getrackten Kugel, die drei Arten von Visualisierungen verkörpert. Wir testen simulierte Multi-Touch-Interaktion auf einer sphärischen Oberfläche und vergleichen zwei Kugelgrößen mit VR-Controllern. Die Ergebnisse bestätigten die Praxistauglichkeit des Prototyps und deuten auf verbesserte Mustererkennung sowie Vorteile für die kleinere Kugel hin. Zweitens, um die Validität von VR als Prototyping-Technologie zu bekräftigen, demonstrieren wir, wie ein großes, anfassbares sphärisches Display in VR simuliert werden kann. Es zeigt sich, wie VR die Möglichkeiten realer sphärischer Displays substantiell erweitern kann, indem eine simulierte Multi-Touch-Oberfläche um die Fähigkeit der physischen Rotation ergänzt wird. Nach einer ersten Studie, die die generelle Machbarkeit der Simulation eines solchen Displays in VR evaluiert, zeigte eine zweite Studie die Überlegenheit des drehbaren sphärischen Displays. Drittens präsentiert diese Arbeit ein Konzept für ein sphärisches Eingabegerät für Tangible AR (TAR). Wir zeigen, wie ein solches Werkzeug grundlegende Fähigkeiten zur Objektmanipulation unter Verwendung von zwei verschiedenen Modi bereitstellen kann und vergleichen es mit Eingabetechniken deren Hardwarekomplexität zunehmend steigt. Unsere Ergebnisse zeigen, dass die kugelbasierte Technik, die ohne Knöpfe auskommt, nur von einer Controller-Variante übertroffen wird, die physische Knöpfe und ein Touchpad verwendet und somit nicht auf unterschiedliche Modi angewiesen ist. Viertens, um das intrinsische Problem der Fortbewegung in VR zu erforschen, untersuchen wir zwei gegensätzliche Ansätze: eine kontinuierliche und eine diskrete Technik. Für die erste präsentieren wir ein sphärisches Eingabegerät zur Fortbewegung, das zwei verschiedene Paradigmen unterstützt, die einen First-Person-Avatar entsprechend bewegen. Es zeigte sich, dass das Paradigma der direkten Positionssteuerung, angewandt auf einen Kugel-Controller, im Vergleich zu regulärer Controller-Interaktion, die zusätzlich auf physische Knöpfe zurückgreifen kann, meist besser abschneidet. Im Bereich der diskreten Fortbewegung evaluieren wir das Konzept einer kugelförmingen Miniaturwelt (Spherical World in Miniature, SWIM), die für die Avatar-Teleportation in einer großen virtuellen Umgebung verwendet werden kann. Die Ergebnisse zeigten eine subjektive Bevorzugung der kugelbasierten Technik im Vergleich zu regulären Controllern und im Durchschnitt eine schnellere Lösung der Aufgaben sowie eine höhere Genauigkeit. Zum Abschluss der Arbeit diskutieren wir unsere Ergebnisse, Erkenntnisse und die daraus resultierenden Beiträge zu unseren zentralen Forschungsfragen, um daraus Empfehlungen für die Gestaltung von Techniken auf Basis kugelförmiger Eingabegeräte und einen Ausblick auf die mögliche zukünftige Entwicklung sphärischer Eingabegräte im Mixed-Reality-Bereich abzuleiten

The Anthropomorphic Hand Assessment Protocol (AHAP)

The progress in the development of anthropomorphic hands for robotic and prosthetic applications has not been followed by a parallel development of objective methods to evaluate their performance. The need for benchmarking in grasping research has been recognized by the robotics community as an important topic. In this study we present the Anthropomorphic Hand Assessment Protocol (AHAP) to address this need by providing a measure for quantifying the grasping ability of artificial hands and comparing hand designs. To this end, the AHAP uses 25 objects from the publicly available Yale-CMU-Berkeley Object and Model Set thereby enabling replicability. It is composed of 26 postures/tasks involving grasping with the eight most relevant human grasp types and two non-grasping postures. The AHAP allows to quantify the anthropomorphism and functionality of artificial hands through a numerical Grasping Ability Score (GAS). The AHAP was tested with different hands, the first version of the hand of the humanoid robot ARMAR-6 with three different configurations resulting from attachment of pads to fingertips and palm as well as the two versions of the KIT Prosthetic Hand. The benchmark was used to demonstrate the improvements of these hands in aspects like the grasping surface, the grasp force and the finger kinematics. The reliability, consistency and responsiveness of the benchmark have been statistically analyzed, indicating that the AHAP is a powerful tool for evaluating and comparing different artificial hand designs

Feature-based hybrid inspection planning for complex mechanical parts

Globalization and emerging new powers in the manufacturing world are among many challenges, major manufacturing enterprises are facing. This resulted in increased alternatives to satisfy customers\u27 growing needs regarding products\u27 aesthetic and functional requirements. Complexity of part design and engineering specifications to satisfy such needs often require a better use of advanced and more accurate tools to achieve good quality. Inspection is a crucial manufacturing function that should be further improved to cope with such challenges. Intelligent planning for inspection of parts with complex geometric shapes and free form surfaces using contact or non-contact devices is still a major challenge. Research in segmentation and localization techniques should also enable inspection systems to utilize modern measurement technologies capable of collecting huge number of measured points. Advanced digitization tools can be classified as contact or non-contact sensors. The purpose of this thesis is to develop a hybrid inspection planning system that benefits from the advantages of both techniques. Moreover, the minimization of deviation of measured part from the original CAD model is not the only characteristic that should be considered when implementing the localization process in order to accept or reject the part; geometric tolerances must also be considered. A segmentation technique that deals directly with the individual points is a necessary step in the developed inspection system, where the output is the actual measured points, not a tessellated model as commonly implemented by current segmentation tools. The contribution of this work is three folds. First, a knowledge-based system was developed for selecting the most suitable sensor using an inspection-specific features taxonomy in form of a 3D Matrix where each cell includes the corresponding knowledge rules and generate inspection tasks. A Travel Salesperson Problem (TSP) has been applied for sequencing these hybrid inspection tasks. A novel region-based segmentation algorithm was developed which deals directly with the measured point cloud and generates sub-point clouds, each of which represents a feature to be inspected and includes the original measured points. Finally, a new tolerance-based localization algorithm was developed to verify the functional requirements and was applied and tested using form tolerance specifications. This research enhances the existing inspection planning systems for complex mechanical parts with a hybrid inspection planning model. The main benefits of the developed segmentation and tolerance-based localization algorithms are the improvement of inspection decisions in order not to reject good parts that would have otherwise been rejected due to misleading results from currently available localization techniques. The better and more accurate inspection decisions achieved will lead to less scrap, which, in turn, will reduce the product cost and improve the company potential in the market

Making a stronger case for comparative research to investigate the behavioral and neurological bases of three-dimensional navigation

The rich diversity of avian natural history provides exciting possibilities for comparative research aimed at understanding three-dimensional navigation. We propose some hypotheses relating differences in natural history to potential behavioral and neurological adaptations possessed by contrasting bird species. This comparative approach may offer unique insights into some of the important questions raised by Jeffery et al

Making a stronger case for comparative research to investigate the behavioral and neurological bases of three-dimensional navigation

The rich diversity of avian natural history provides exciting possibilities for comparative research aimed at understanding three-dimensional navigation. We propose some hypotheses relating differences in natural history to potential behavioral and neurological adaptations possessed by contrasting bird species. This comparative approach may offer unique insights into some of the important questions raised by Jeffery et al

Effects of the Planar Galactic Tides and Stellar Mass on Comet Cloud Dynamics

We report the first results of a research program to explore the sensitivity of the orbits of Oort cloud comets to changes in the strength of the Galactic tides in the plane of the disk and also to changes in the mass of the host star. We performed 2D simulations that confirm that the effects of the tides on comet orbits are sensitive to a star's distance from the Galactic center. A comet cloud closer to the Galactic center than the Sun will have comet perihelia reduced to the region of the inner planets more effectively by the planar tides alone. Similar results are found for a star of smaller mass. We also show how this phenomenon of comet injection persists for a set of alternative Galactic potential models. These preliminary results suggest a fruitful line of research, one that aims to generalize the study of comet cloud dynamics to systems different from the Solar System. In particular, it will allow us to study the roles played by comet clouds in defining the boundaries of the Galactic Habitable Zone.Comment: Published by The Open Astronomy Journal; some slight differences from published versio