Type of Document Dissertation Author Bittner, Ray A. Jr. URN etd-38419290973280 Title Wormhole Run-Time Reconfiguration: Conceptualization and VLSI Design of a High Performance Computing System Degree PhD Department Electrical and Computer Engineering Advisory Committee
Advisor Name Title Peter M. Athanas Committee Chair A. Lynn Abbott none Calvin J. Ribbens none Nathaniel J. Davis none Scott F. Midkiff none Keywords
- VLSI
- data flow
- DSP
- wormhole run-time reconfiguration
- FPGA
Date of Defense 1997-01-23 Availability unrestricted Abstract In the past, various approaches to the high
performance numerical computing problem have
been explored. Recently, researchers have
begun to explore the possibilities of using Field
Programmable Gate Arrays (FPGAs) to solve
numerically intensive problems. FPGAs offer the
possibility of customization to any given
application, while not sacrificing applicability to
a wide problem domain. Further, the
implementation of data flow graphs directly in
silicon makes FPGAs very attractive for these
types of problems. Unfortunately, current
FPGAs suffer from a number of inadequacies
with respect to the task. They have lower
transistor densities than ASIC solutions, and
hence less potential computational power per
unit area. Routing overhead generally makes an
FPGA solution slower than an ASIC design.
Bit-oriented computational units make them
unnecessarily inefficient for implementing tasks
that are generally word-oriented. And finally, in
large volumes, FPGAs tend to be more
expensive per unit due to their lower transistor
density.
To combat these problems, researchers are
now exploiting the unique advantage that
FPGAs exhibit over ASICs: reconfigurability.
By customizing the FPGA to the task at hand,
as the application executes, it is hoped that the
cost-performance product of an FPGA system
can be shown to be a better solution than a
system implemented by a collection of custom
ASICs. Such a system is called a Configurable
Computing Machine (CCM). Many aspects of
the design of the FPGAs available today hinder
the exploration of this field.
This thesis addresses many of these problems
and presents the embodiment of those solutions
in the Colt CCM. By offering word grain
reconfiguration and the ability to partially
reconfigure at computational element resolution,
the Colt can offer higher effective utilization over
traditional FPGAs. Further, the majority of the
pins of the Colt can be used for both normal I/O
and for chip reconfiguration. This provides
higher reconfiguration bandwidth contrasted
with the low percentage of pins used for
reconfiguration of FPGAs. Finally, Colt uses a
distributed reconfiguration mechanism called
Wormhole Run-Time Reconfiguration (RTR)
that allows multiple data ports to simultaneously
program different sections of the chip
independently. Used as the primary example of
Wormhole RTR in the patent application, Colt is
the first system to employ this computing
paradigm.
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