• Refine Query
  • Source
  • Publication year
  • to
  • Language
  • 62
  • 39
  • 3
  • 2
  • 2
  • Tagged with
  • 138
  • 138
  • 69
  • 57
  • 57
  • 25
  • 24
  • 24
  • 23
  • 20
  • 20
  • 20
  • 19
  • 18
  • 18
  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
71

Analysis of Field Programmable Gate Array-Based Kalman Filter Architectures

Sudarsanam, Arvind 01 December 2010 (has links)
A Field Programmable Gate Array (FPGA)-based Polymorphic Faddeev Systolic Array (PolyFSA) architecture is proposed to accelerate an Extended Kalman Filter (EKF) algorithm. A system architecture comprising a software processor as the host processor, a hardware controller, a cache-based memory sub-system, and the proposed PolyFSA as co-processor, is presented. PolyFSA-based system architecture is implemented on a Xilinx Virtex 4 family of FPGAs. Results indicate significant speed-ups for the proposed architecture when compared against a space-based software processor. This dissertation proposes a comprehensive architecture analysis that is comprised of (i) error analysis, (ii) performance analysis, and (iii) area analysis. Results are presented in the form of 2-D pareto plots (area versus error, area versus time) and a 3-D plot (area versus time versus error). These plots indicate area savings obtained by varying any design constraints for the PolyFSA architecture. The proposed performance model can be reused to estimate the execution time of EKF on other conventional hardware architectures. In this dissertation, the performance of the proposed PolyFSA is compared against the performance of two conventional hardware architectures. The proposed architecture outperforms the other two in most test cases.
72

A Memory-Array Centric Reconfigurable Hardware Accelerator for Security Applications

Babecki, Christopher 03 June 2015 (has links)
No description available.
73

iPACE-V1: A PORTAABLE ADAPTIVE COMPUTING ENGINE

KHAN, JAWAD BASIT 11 October 2002 (has links)
No description available.
74

ONLINE PLACEMENT AND SCHEDULING ALGORITHMS AND METHODOLOGIES FOR RECONFIGURABLE COMPUTING SYSTEMS

HANDA, MANISH January 2004 (has links)
No description available.
75

FPGA Implementation of the FDTD Algorithm Using Local Sram

Wu, Shuguang January 2005 (has links)
No description available.
76

ENERGY MANAGEMENT FOR BATTERY-POWERED RECONFIGURABLE COMPUTING PLATFORMS AND NETWORKS

KHAN, JAWAD B. January 2005 (has links)
No description available.
77

PERFORMANCE IMPROVEMENT OF AN FPGA-BASED FDTD SOLVER FOR RECONFIGURABLE HIGH PERFORMANCE COMPUTING

DESAI, ASHISH R. 03 April 2006 (has links)
No description available.
78

Energy-efficientSpatio-temporalComputing Framework

Qian, Wenchao 31 May 2016 (has links)
No description available.
79

A High-end Reconfigurable Computation Platform for Particle Physics Experiments

Liu, Ming January 2008 (has links)
Modern nuclear and particle physics experiments run at a very high reaction rate and are able to deliver a data rate of up to hundred GBytes/s.  This data rate is far beyond the storage and on-line analysis capability. Fortunately physicists have only interest in a very small proportion among the huge amounts of data. Therefore in order to select the interesting data and reject the background by sophisticated pattern recognition processing, it is essential to realize an efficient data acquisition and trigger system which results in a reduced data rate by several orders of magnitude. Motivated by the requirements from multiple experiment applications, we are developing a high-end reconfigurable computation platform for data acquisition and triggering. The system consists of a scalable number of compute nodes, which are fully interconnected by high-speed communication channels. Each compute node features 5 Xilinx Virtex-4 FX60 FPGAs and up to 10 GBytesDDR2 memory. A hardware/software co-design approach is proposed to develop custom applications on the platform, partitioning performance-critical calculation to the FPGA hardware fabric while leaving flexible and slow controls to the embedded CPU plus the operating system. The system is expected to be high-performance and general-purpose for various applications especially in the physics experiment domain. As a case study, the particle track reconstruction algorithm for HADES has been developed and implemented on the computation platform in the format of processing engines. The Tracking Processing Unit (TPU) recognizes peak bins on the projection plane and reconstructs particle tracks in realtime. Implementation results demonstrate its acceptable resource utilization and the feasibility to implement the module together with the sys-tem design on the FPGA. Experimental results show that the online track reconstruction computation achieves 10.8 - 24.3 times performance acceleration per TPU module when compared to the software solution on a Xeon2.4 GHz commodity server. / QC 20101118
80

Design and Implementation of a Soft Radio Architecture for Reconfigurable Platforms

Srikanteswara, Srikathyayani 31 July 2001 (has links)
Software radios have evolved as multimode, programmable digital radios that perform radio functions using digital signal processing algorithms. They have been designed as software programmable radios using a combination of various hardware elements and structures. In this dissertation a {em{soft radio}} refers to a completely configurable radio that can be programmed through software, to change the radio behavior including the hardware functionality. Conventional software radios achieve flexibility through software with the use of static hardware. While these radios have the flexibility to operate in multiple modes, the hardware is not used efficiently. This inefficient utilization of hardware frequently limits the flexibility of software radios and the number of modes the radio can support. Soft radios however, attempt to gain flexibility through the use of reconfigurable hardware. The same piece of hardware can be configured to perform different functions based on the mode the radio is operating in. While many soft/software radio architectures have been suggested and implemented, there remains a lack of a formal design methodology that can be used to design and implement reconfigurable soft radios. Most designs are based on ad hoc approaches which are appropriate only for the problem at hand. After examining the design issues of a soft radio an architecture, called the {em{Layered Radio Architecture}}, is developed with the use of stream based processing and run-time reconfigurable hardware. These choices aid in maximizing performance with minimum hardware while keeping the architecture robust, simple, and scalable. The reconfigurable platform enables {em hardware paging} through reusability hardware. The stream-based approach gives a uniform modular structure to the processing modules and defines the protocol for interaction between various modules. The architecture describes a formal yet open design methodology and makes it possible to incorporate all of the features of a software radio while minimizing complexity issues. The layered architecture also defines the methodology for incorporating changes and updates into the system. The layered radio architecture assumes run-time reconfigurability of the hardware. This feature is not supported by existing commercial reconfigurable hardware, like FPGAs. An Custom Computing Machine (CCM), called Stallion that supports fast run time reconfiguration, has been developed at Virginia Tech. This dissertation describes the deficiencies of existing commercial reconfigurable hardware and shows how the Stallion is capable of supporting the layered radio architecture. The dissertation presents algorithms and procedures that can be used to implement the layered radio architecture using existing hardware. The architecture is validated with the implementation of two receivers: A single user CDMA receiver based on complex adaptive filtering and a W-CDMA downlink rake receiver with channel estimation. Performance analysis of these receivers show that it is important to keep the paging ratio high while maximizing utilization of the processing elements. The layered radio architecture with the use of Stallion can support existing high data rate systems. / Ph. D.

Page generated in 0.1042 seconds