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Author: Qing K. Zhu
Publisher: Springer Science & Business Media
Published: 2013-03-14
Total Pages: 191
ISBN-13: 147573705X
DOWNLOAD EBOOK →High-Speed Clock Network Design is a collection of design concepts, techniques and research works from the author for clock distribution in microprocessors and high-performance chips. It is organized in 11 chapters.
Author: Eby G. Friedman
Publisher: Springer
Published: 2012-04-30
Total Pages: 172
ISBN-13: 9781468484427
DOWNLOAD EBOOK →A number of fundamental topics in the field of high performance clock distribution networks is covered in this book. High Performance Clock Distribution Networks is composed of ten contributions from authors at academic and industrial institutions. Topically, these contributions can be grouped within three primary areas. The first topic area deals with exploiting the localized nature of clock skew. The second topic area deals with the implementation of these clock distribution networks, while the third topic area considers more long-range aspects of next-generation clock distribution networks. High Performance Clock Distribution Networks presents a number of interesting strategies for designing and building high performance clock distribution networks. Many aspects of the ideas presented in these contributions are being developed and applied today in next-generation high-performance microprocessors.
Author: Masami Kihara
Publisher: Artech House
Published: 2006
Total Pages: 278
ISBN-13: 9781580537650
DOWNLOAD EBOOK →If you need an in-depth understanding of the digital clock technologies used in building today's telecommunications networks, this authoritative and practical book is a smart choice. Providing you with critical details on the PLL (phase-locked Loop) technique for clock synchronization and generation, and the DDS (direct digital synthesizer) technique for clock generation, the book helps you achieve synchronization in high-speed networks and frequency stabilization in portable equipment.
Author: James P. G. Sterbenz
Publisher: John Wiley & Sons
Published: 2002-03-14
Total Pages: 618
ISBN-13: 047104976X
DOWNLOAD EBOOK →Leading authorities deliver the commandments for designing high-speed networks There are no end of books touting the virtues of one or another high-speed networking technology, but until now, there were none offering networking professionals a framework for choosing and integrating the best ones for their organization's networking needs. Written by two world-renowned experts in the field of high-speed network design, this book outlines a total strategy for designing high-bandwidth, low-latency systems. Using real-world implementation examples to illustrate their points, the authors cover all aspects of network design, including network components, network architectures, topologies, protocols, application interactions, and more.
Author: Ayan Mandal
Publisher: Springer Science & Business Media
Published: 2013-11-19
Total Pages: 151
ISBN-13: 1461494052
DOWNLOAD EBOOK →This book describes novel methods for network-on-chip (NoC) design, using source-synchronous high-speed resonant clocks. The authors discuss NoCs from the bottom up, providing circuit level details, before providing architectural simulations. As a result, readers will get a complete picture of how a NoC can be designed and optimized. Using the methods described in this book, readers are enabled to design NoCs that are 5X better than existing approaches in terms of latency and throughput and can also sustain a significantly greater amount of traffic.
Author: Eby G. Friedman
Publisher: Springer Science & Business Media
Published: 2012-12-06
Total Pages: 163
ISBN-13: 1468484400
DOWNLOAD EBOOK →A number of fundamental topics in the field of high performance clock distribution networks is covered in this book. High Performance Clock Distribution Networks is composed of ten contributions from authors at academic and industrial institutions. Topically, these contributions can be grouped within three primary areas. The first topic area deals with exploiting the localized nature of clock skew. The second topic area deals with the implementation of these clock distribution networks, while the third topic area considers more long-range aspects of next-generation clock distribution networks. High Performance Clock Distribution Networks presents a number of interesting strategies for designing and building high performance clock distribution networks. Many aspects of the ideas presented in these contributions are being developed and applied today in next-generation high-performance microprocessors.
Author: Ayan Mandal
Publisher:
Published: 2013
Total Pages:
ISBN-13:
DOWNLOAD EBOOK →As VLSI fabrication technology scales, an increasing number of processing elements (cores) on a chip makes on-chip communication a new performance bottleneck. The Network-on-Chip (NoC) paradigm has emerged as an efficient and scalable infrastructure to handle the communication needs for such multi-core systems. In most existing NoCs, design decisions are made assuming that the NoC operates at the same or lower clock speed as the cores, which slows down the communication system. A major challenge in designing a high speed NoC is the difficulty of distributing a high speed, low power clock across the chip. In this dissertation, we first propose several techniques to address the issue of distributing a high-speed, low power, low jitter clock across the IC. We primarily focus our attention on resonant standing wave oscillators (SWOs), which have recently emerged as a promising technique for high-speed, low power clock generation. In addition, we also present a dynamic programming based approach to synthesize a low jitter, low power buffered H-tree for clock distribution. In the second part of this dissertation, we use these efficient clock distribution schemes to present a novel fast NoC design that relies on source synchronous data transfer over a ring. In our source-synchronous design, the clock and data NoC are routed in parallel yielding a fast, robust design. Architectural simulations on synthetic and real traffic show that our source-synchronous NoC designs can provide significantly lower latency while achieving the same or better bandwidth compared to a state of the art mesh, while consuming lower area. The fact that the our ring-based NoC runs significantly faster than the mesh contributes to these improvements. Moreover, since our proposed NoC designs are fully synchronous, they are very amenable to testing as well. In the last part of this dissertation, we explore an alternate scheme of achieving high-speed on-chip data transfer using sinusoidal signals of different frequencies. The key advantage of our method is the ability to superimpose such sinusoids and thereby effectively send multiple logic values along the same wire in a clock cycle. Experimental results show that for the same throughput as that of a traditional scheme, we require significantly fewer wires. The electronic version of this dissertation is accessible from http://hdl.handle.net/1969.1/149325
