Donald P. Brutzman: a biography

Design and implement large-scale networked underwater virtual worlds using Web-accessible 3D graphics and network streams. Integrate sensors, models and datasets for real-time interactive use by scientists, underwater robots, ships and students of all ages

Enabling collaboration in virtual reality navigators

In this paper we characterize a feature superset for Collaborative Virtual Reality Environments (CVRE), and derive a component framework to transform stand-alone VR navigators into full-fledged multithreaded collaborative environments. The contributions of our approach rely on a cost-effective and extensible technique for loading software components into separate POSIX threads for rendering, user interaction and network communications, and adding a top layer for managing session collaboration. The framework recasts a VR navigator under a distributed peer-to-peer topology for scene and object sharing, using callback hooks for broadcasting remote events and multicamera perspective sharing with avatar interaction. We validate the framework by applying it to our own ALICE VR Navigator. Experimental results show that our approach has good performance in the collaborative inspection of complex models.Postprint (published version

Integrating realistic human group behaviors into a networked 3D virtual environment

Distributed Interactive Simulation DIS-Java-VRML Working Group. Includes supplementary material provided from the contents of a CD-Rom issued containing the work of all three Working Group members and all supplementary material, in compressed format.Virtual humans operating inside large-scale virtual environments (VE) are typically controlled as single entities. Coordination of group activity and movement is usually the responsibility of their real world human controllers. Georeferencing coordinate systems, single-precision versus double-precision number representation and network delay requirements make group operations difficult. Mounting multiple humans inside shared or single vehicles, (i.e. air-assault operations, mechanized infantry operations, or small boat/riverine operations) with high fidelity is often impossible. The approach taken in this thesis is to reengineer the DIS-Java-VRML Capture the Flag game geolocated at Fort Irwin, California to allow the inclusion of human entities. Human operators are given the capability of aggregating or mounting nonhuman entities for coordinated actions. Additionally, rapid content creation of human entities is addressed through the development of a native tag set for the Humanoid Animation (H-Anim) 1.1 Specification in Extensible 3D (X3D). Conventions are demonstrated for integrating the DIS-Java-VRML and H-Anim draft standards using either VRML97 or X3D encodings. The result of this work is an interface to aggregate and control articulated humans using an existing model with a standardized motion library in a networked virtual environment. Virtual human avatars can be mounted and unmounted from aggregation entities. Simple demonstration examples show coordinated tactical maneuver among multiple humans with and without vehicles. Live 3D visualization of animated humanoids on realistic terrain is then portrayed inside freely available web browsers.Approved for public release; distribution is unlimited

A Scalable Network Architecture for Closely Coupled Collaboration

This article describes the architecture and the network communication of a large-scale, networked virtual environment, which is designed to specifically support closely-coupled collaboration in highly interactive scenarios. Its main goals are the maintenance of low latency during user interaction and fast multicasting of messages in order to fulfill consistency requirements. This is achieved by sophisticated message distribution techniques, peer-to-peer connections between interacting clients and a global hierarchical communication topology. Scalability is realised through partitioning the virtual world

Analysis domain model for shared virtual environments

The field of shared virtual environments, which also encompasses online games and social 3D environments, has a system landscape consisting of multiple solutions that share great functional overlap. However, there is little system interoperability between the different solutions. A shared virtual environment has an associated problem domain that is highly complex raising difficult challenges to the development process, starting with the architectural design of the underlying system. This paper has two main contributions. The first contribution is a broad domain analysis of shared virtual environments, which enables developers to have a better understanding of the whole rather than the part(s). The second contribution is a reference domain model for discussing and describing solutions - the Analysis Domain Model

A case for 3D streaming on peer-to-peer networks

One of the most serious issues holding back the widespread of 3D contents on Internet has been their inaccessibility due to large data volume. Many compression and progressive transmission tech-niques, as well as format standards, have been proposed in recent years to make 3D streaming increasingly viable for the efficient and accessible delivery of 3D contents. However, existing propos-als have yet to seriously address one of the most important issues in practical adoption – a system’s scalability in terms of the number of concurrent users. We argue that due to 3D contents ’ large data vol-ume and interactive nature, client-server architecture, with its inher-ently fixed resource availability and high cost, will not be suitable to support popular Internet-scale 3D streaming. On the other hand, peer-to-peer (P2P) architectures hold the promise of both scalabil-ity and affordability. In this position paper, we describe the po-tential promises and challenges in adapting 3D streaming to P2P networks, using multi-user networked virtual environment (NVE) as an example. We also propose Flowing LoD (FLoD), a scalable, distributed and fault-tolerant P2P 3D streaming mechanism, that is based on Voronoi-based Overlay Network (VON), a P2P overlay specifically designed for NVE applications

VR-LAB: A Distributed Multi-User Environment for Educational Purposes and Presentations

In the last three years our research was focused on a new distributed multi-user environment. Finally, all components were integrated in a system called the VR-Lab, which will be described on the following pages. The VR-Lab provides Hard- and Software for a distributed presentation system. Elements which are often used in environments called Computer Supported Cooperative Work (CSCW). In contrast to other projects the VR-Lab integrates a distributed system in a common environment of a lecture room and does not generate a virtual conference room in a computer system. Thus, allowing inexperienced persons to use the VR-LAB and benefit from the multimedia tools in their common environment. To build the VR-LAB we developed a lot of hard- and software and integrated it into a lecture room to perform distributed presentations, conferences or teaching. Additionally other software components were developed to be connected to the VR-LAB, control its components, or distribute content between VR-LAB installations. Beside standard software for video and audio transmission, we developed and integrated a distributed 3D-VRML-Browser to present three dimensional content to a distributed audience. One of the interesting features of this browser is the object oriented distributed scene graph. By coupling a high-speed rendering system with a database we could distribute objects to other participants. So the semantic properties of any geometrical or control object can be kept and used by the remote participant. Because of the high compression achieved by the transport of objects instead of triangles a lot of bandwidth could be saved. Also each participant could select a display quality appropriate to its hardware.Diese Arbeit beschreibt ein integriertes Virtual-Reality System, das VR Lab. Das System besteht aus verschiedenen Hard- und Softwarekomponenten die eine verteiltevirtuelle Multi-User Umgebung darstellen die vor allem im Bereich verteilter Präsentationen verwendet werden kann. Im Gegensatz zu anderen Systemen dieser Art, die oft im Bereich des Computer Supported Cooperative Work (CSCW) eingesetzt werden dient unser System nicht dazu eine Präsentationsumgebung im Computer nachzubilden sondern eine reele Umgebung zu schaffen in der verteilte Präsentationen durchgeführt werden können. Dies soll vor allem ungeübten Personen die Arbeit mit verteilten Umgebungen erleichtern. Dazu wurden verschiedene Hard- und Softwarekomponenten entwickelt. Darunter der verteilte 3D Browser MRT-VR, der es ermöglicht 3D Daten an verschiedenen Stellen gleichzeitig zu visualisieren. MRT-VR zeichnet sich insbesondere dadurch aus, daß die 3D Objekte nicht als Polygondaten transportiert werden, sonderen als Objekte und so deren Objekteigenschaften beibehalten werden. Dies spart nicht nur sehr viel Bandbreite bei der Übertragung sondern ermöglicht auch Darstellungen in unterschiedlichen Qualitätsstufen auf den unterschiedlichen Zielrechnern der Teilnehmer. Ein weiterer Teil der Arbeit beschreibt die Entwicklung einer preiswerten imersiven 3D Umgebung um die 3D Daten in ansprechender Qualität zu visualisieren. Alle Komponenten wurden in einer gemeinsamen Umgebung, dem VR-Lab, integriert und mt Steuerungskomponenten versehen

On extending collaboration in virtual reality environments

We characterize the feature superset of Collaborative Virtual Reality Environments (CVREs) out of existing implementations, and derive a novel component framework for transforming standalone VR tools into full-fledged multithreaded collaborative environments. The contributions of our approach rely on cost-effective techniques for loading graphics rendering, user interaction and network communications software components into separate threads, with a top thread for session collaboration. The framework recasts VR tools under a scalable peer-to-peer topology for scene sharing, callback hooks for event broadcasting and multicamera perspectives of avatar interaction. We validate the framework by applying it to our own Alice VR navigator. Experimental results show good performance of our approach in the collaborative inspection of complex models.Postprint (published version

DIVE on the internet

This dissertation reports research and development of a platform for Collaborative Virtual Environments (CVEs). It has particularly focused on two major challenges: supporting the rapid development of scalable applications and easing their deployment on the Internet. This work employs a research method based on prototyping and refinement and promotes the use of this method for application development. A number of the solutions herein are in line with other CVE systems. One of the strengths of this work consists in a global approach to the issues raised by CVEs and the recognition that such complex problems are best tackled using a multi-disciplinary approach that understands both user and system requirements. CVE application deployment is aided by an overlay network that is able to complement any IP multicast infrastructure in place. Apart from complementing a weakly deployed worldwide multicast, this infrastructure provides for a certain degree of introspection, remote controlling and visualisation. As such, it forms an important aid in assessing the scalability of running applications. This scalability is further facilitated by specialised object distribution algorithms and an open framework for the implementation of novel partitioning techniques. CVE application development is eased by a scripting language, which enables rapid development and favours experimentation. This scripting language interfaces many aspects of the system and enables the prototyping of distribution-related components as well as user interfaces. It is the key construct of a distributed environment to which components, written in different languages, connect and onto which they operate in a network abstracted manner. The solutions proposed are exemplified and strengthened by three collaborative applications. The Dive room system is a virtual environment modelled after the room metaphor and supporting asynchronous and synchronous cooperative work. WebPath is a companion application to a Web browser that seeks to make the current history of page visits more visible and usable. Finally, the London travel demonstrator supports travellers by providing an environment where they can explore the city, utilise group collaboration facilities, rehearse particular journeys and access tourist information data

Ein leistungsfähiges System zur Online-Präsentation von Sequenzen komplexer virtueller 3D-Szenen

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