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Self-modifying Circuitry for Trillion-element Reconfigurable Devices: an Analysis of a Future Computing Paradigm for Efficient, Scalable, Defect-tolerant Processing Nicholas J. Macias
Self-modifying Circuitry for Trillion-element Reconfigurable Devices: an Analysis of a Future Computing Paradigm for Efficient, Scalable, Defect-tolerant Processing
Nicholas J. Macias
As transistors density continues to rise, it becomes increasingly difficult to scale current computing designs to utilize these high transistor counts. This work presents a scalable alternative to the traditional von Neumann architecture, in the form of a self-configurable array of programmable elements. Unlike traditional FPGAs, this architecture utilizes self-analysis and self-modification to address a number of scalability challenges, including handling mixed-granularity designs; handling of defects; and dynamic architecture tuning. Included are details of the basic architecture, examples of its application to solving real-world problems, and an analysis of its scalability. Emphasis is placed on the ability of the system's self-configuration mechanism to support efficient parallel bootstrapping of the system. This work also discusses the three-dimensional version of the Cell Matrix, and explores how this extra dimension can be used to more-efficiently solve future problems.
| Media | Books Paperback Book (Book with soft cover and glued back) |
| Released | December 7, 2011 |
| ISBN13 | 9783846593387 |
| Publishers | LAP LAMBERT Academic Publishing |
| Pages | 172 |
| Dimensions | 150 × 10 × 226 mm · 274 g |
| Language | German |
See all of Nicholas J. Macias ( e.g. Paperback Book )