000 Informatik, Informationswissenschaft, allgemeine Werke
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This thesis deals with the first part of a larger project that follows the ultimate goal of implementing a software tool that creates a Mission Control Room in Virtual Reality. The software is to be used for the operation of spacecrafts and is specially developed for the unique real-time requirements of unmanned satellite missions. Beginning from launch, throughout the whole mission up to the recovery or disposal of the satellite, all systems need to be monitored and controlled in continuous intervals, to ensure the mission’s success. Mission Operation is an essential part of every space mission and has been undertaken for decades. Recent technological advancements in the realm of immersive technologies pave the way for innovative methods to operate spacecrafts. Virtual Reality has the capability to resolve the physical constraints set by traditional Mission Control Rooms and thereby delivers novel opportunities. The paper highlights underlying theoretical aspects of Virtual Reality, Mission Control and IP Communication. However, the focus lies upon the practical part of this thesis which revolves around the first steps of the implementation of the virtual Mission Control Room in the Unity Game Engine. Overall, this paper serves as a demonstration of Virtual Reality technology and shows its possibilities with respect to the operation of spacecrafts.
Latency is a key characteristic inherent to any computer system. Motion-to-Photon (MTP) latency describes the time between the movement of a tracked object and its corresponding movement rendered and depicted by computer-generated images on a graphical output screen. High MTP latency can cause a loss of performance in interactive graphics applications and, even worse, can provoke cybersickness in Virtual Reality (VR) applications. Here, cybersickness can degrade VR experiences or may render the experiences completely unusable. It can confound research findings of an otherwise sound experiment. Latency as a contributing factor to cybersickness needs to be properly understood. Its effects need to be analyzed, its sources need to be identified, good measurement methods need to be developed, and proper counter measures need to be developed in order to reduce potentially harmful impacts of latency on the usability and safety of VR systems. Research shows that latency can exhibit intricate timing patterns with various spiking and periodic behavior. These timing behaviors may vary, yet most are found to provoke cybersickness. Overall, latency can differ drastically between different systems interfering with generalization of measurement results. This review article describes the causes and effects of latency with regard to cybersickness. We report on different existing approaches to measure and report latency. Hence, the article provides readers with the knowledge to understand and report latency for their own applications, evaluations, and experiments. It should also help to measure, identify, and finally control and counteract latency and hence gain confidence into the soundness of empirical data collected by VR exposures. Low latency increases the usability and safety of VR systems.
Virtual reality and related media and communication technologies have a growing
impact on professional application fields and our daily life. Virtual environments
have the potential to change the way we perceive ourselves and how we interact
with others. In comparison to other technologies, virtual reality allows for the
convincing display of a virtual self-representation, an avatar, to oneself and also to
others. This is referred to as user embodiment. Avatars can be of varying realism
and abstraction in their appearance and in the behaviors they convey. Such userembodying
interfaces, in turn, can impact the perception of the self as well as
the perception of interactions. For researchers, designers, and developers it is of
particular interest to understand these perceptual impacts, to apply them to therapy,
assistive applications, social platforms, or games, for example. The present thesis
investigates and relates these impacts with regard to three areas: intrapersonal
effects, interpersonal effects, and effects of social augmentations provided by the
simulation.
With regard to intrapersonal effects, we specifically explore which simulation
properties impact the illusion of owning and controlling a virtual body, as well
as a perceived change in body schema. Our studies lead to the construction of
an instrument to measure these dimensions and our results indicate that these
dimensions are especially affected by the level of immersion, the simulation latency,
as well as the level of personalization of the avatar.
With regard to interpersonal effects we compare physical and user-embodied social
interactions, as well as different degrees of freedom in the replication of nonverbal
behavior. Our results suggest that functional levels of interaction are maintained,
whereas aspects of presence can be affected by avatar-mediated interactions, and
collaborative motor coordination can be disturbed by immersive simulations.
Social interaction is composed of many unknown symbols and harmonic patterns
that define our understanding and interpersonal rapport. For successful virtual
social interactions, a mere replication of physical world behaviors to virtual environments
may seem feasible. However, the potential of mediated social interactions
goes beyond this mere replication. In a third vein of research, we propose and
evaluate alternative concepts on how computers can be used to actively engage in
mediating social interactions, namely hybrid avatar-agent technologies. Specifically,
we investigated the possibilities to augment social behaviors by modifying and
transforming user input according to social phenomena and behavior, such as nonverbal
mimicry, directed gaze, joint attention, and grouping. Based on our results
we argue that such technologies could be beneficial for computer-mediated social
interactions such as to compensate for lacking sensory input and disturbances in
data transmission or to increase aspects of social presence by visual substitution or
amplification of social behaviors.
Based on related work and presented findings, the present thesis proposes the
perspective of considering computers as social mediators. Concluding from prototypes
and empirical studies, the potential of technology to be an active mediator of social
perception with regard to the perception of the self, as well as the perception of
social interactions may benefit our society by enabling further methods for diagnosis,
treatment, and training, as well as the inclusion of individuals with social disorders.
To this regard, we discuss implications for our society and ethical aspects. This
thesis extends previous empirical work and further presents novel instruments,
concepts, and implications to open up new perspectives for the development of
virtual reality, mixed reality, and augmented reality applications.