Global ETD Search

61	Concurrency in multi-core processor design Clancy, Patrick January 1900 (has links) Thesis (B.A.)--Haverford College, [Dept. of Computer Science, 2007]. / Includes bibliographical references.
62	The implementation and evaluation of parallel algorithms on C.mmp / Oleinick, Peter N. January 1978 (has links) Thesis (Ph. D.)--Carnegie-Mellon University. / "CMU-CS-78-151." "Supported by the Defense Advanced Research Projects Agency (Contract: F44620-73-C-0074, monitored by the Air Force Office of Scientific Research), and in part by the Office of Naval Research (Contract: N00014-77-C-0500." Includes bibliographical references (leaves [96]-97).
63	Scalable parallel algorithms and software for large scale proteomics Kulkarni, Gaurav Ramesh. January 2010 (has links) (PDF) Thesis (M.S. in computer science)--Washington State University, May 2010. / Title from PDF title page (viewed on June 2, 2010). "School of Electrical Engineering and Computer Science." Includes bibliographical references (p. 64-66).
64	Systolic arrays for the matrix iterative methods Haider, Shahid Abbas January 1993 (has links) The systolic array research was pioneered by H. T. Kung and C. E. Leiserson. Systolic arrays are special purpose synchronous architectures consisting of simple, regular and modular processors which are regularly interconnected to form an array. Systolic arrays are well suited for computational bound problems in Linear Algebra. In this thesis, the numerical problems, especially iterative algorithms are chosen and implemented on the linear systolic array. same. 005
65	Parallel conic recognition by bus automata / Breene, Leila Anne January 1982 (has links) No description available. Computer Science Parallel processing Androids
66	Real-Time Processing and Visualization of 3D Time-Variant Datasets Elshahali, Mai Hassan Ahmed Ali 14 September 2015 (has links) Scientific visualization is primarily concerned with the visual presentation of three-dimensional phenomena in domains like medicine, meteorology, astrophysics, etc. The emphasis in scientific visualization research has been on the efficient rendering of measured or simulated data points, surfaces, volumes, and a time component to convey the dynamic nature of the studied phenomena. With the explosive growth in the size of the data, interactive visualization of scientific data becomes a real challenge. In recent years, the graphics community has witnessed tremendous improvements in the performance capabilities of graphics processing units (GPUs), and advances in GPU-accelerated rendering have enabled data exploration at interactive rates. Nevertheless, the majority of techniques rely on the assumption that a true three-dimensional geometric model capturing physical phenomena of interest, is available and ready for visualization. Unfortunately, this assumption does not hold true in many scientific domains, in which measurements are obtained from a given scanning modality at sparsely located intervals in both space and time. This calls for the fusion of data collected from multiple sources in order to fill the gaps and tell the story behind the data. For years, data fusion has relied on machine learning techniques to combine data from multiple modalities, reconstruct missing information, and track features of interest through time. However, these techniques fall short in solving the problem for datasets with large spatio-temporal gaps. This realization has led researchers in the data fusion domain to acknowledge the importance of human-in-the-loop methods where human expertise plays a major role in data reconstruction. This PhD research focuses on developing visualization and interaction techniques aimed at addressing some of the challenges that experts are faced with when analyzing the spatio-temporal behavior of physical phenomena. Given a number of datasets obtained from different measurement modalities and from simulation, we propose a generalized framework that can guide research in the field of multi-sensor data fusion and visualization. We advocate the use of GPU parallelism in our developed techniques in order to emphasize interaction as a key component in the successful exploration and analysis of multi-sourced data sets. The goal is to allow the user to create a mental model that captures their understanding of the spatio-temporal behavior of features of interest; one which they can test against real data measurements to verify their model. This model creation and verification is an iterative process in which the user interacts with the visualization, explores and builds an understanding of what occurred in the data, then tests this understanding against real-world measurements and improves it. We developed a system as a reference implementation of the proposed framework. Reconstructed data is rendered in a way that completes the users' cognitive model, which encodes their understanding of the phenomena in question with a high degree of accuracy. We tested the usability of the system and evaluated its support for this cognitive model construction process. Once an acceptable model is constructed, it is fed back to the system in the form of a reference dataset, which our framework uses to guide the real-time tracking of measurement data. Our results show that interactive exploration tasks enable the construction of this cognitive model and reference set, and that real-time interaction is achievable during the exploration, reconstruction, and enhancement of multi-modal time-variant three-dimensional data, by designing and implementing advanced GPU-based visualization techniques. / Ph. D. Visualization User Interaction Parallel Processing
67	PDDS : a parallel deductive database system Cao, Hua January 1995 (has links) No description available. 005
68	New data synchronization & mapping strategies for PACE - VLSI processor architecture Xu, Yifan January 1995 (has links) No description available. 005 Parallel processing; Real-time control
69	A rigorous examination of sequentially expressed algorithms to reveal their concurrency hierarchies Jones, Christopher Michael January 1977 (has links) The methods of Scott-Strachey semantics are applied to the problem of writing programs for parallel computers, using serial languages such as are in common use, with compilers which attempt to discover and exploit potential parallelism in independent sections of program. A mathematical model of a parallel computer is first developed in detail, and in chapters 1 and 2 three basic conditions are derived which together ensure determinacy of operation in a parallel machine, first in purely semantic terms, then in a form more related to the syntactic structure of a language. The remaining chapters apply these basic conditions to three actual languages, showing how the conditions can be reduced to purely syntactic (hence compiler evaluable) tests. Chapter 3 uses a very simple language to introduce the techniques required. Chapter 4 adds procedures, with all the complexity they involve. Chapter 5 considers the rather more fruitful area of arrays and loops. The result, in all but the most trivial cases, is a rather complicated set of conditions which, while they produce the desired effect, suggest that today's commonly used languages are not the most suitable method of exploiting parallel computers. 518
70	Parallel execution of logic programs. January 1988 (has links) Ho-Fung Leung. / Thesis (M.Ph.)--Chinese University of Hong Kong, 1988. / Bibliography: leaves [2-6], 3rd group. Logic programming

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