An intelligent physical layer for cognitive radio networks

Subscribe (Full Service)


	Search: The ACM Digital Library The Guide

	Feedback

An intelligent physical layer for cognitive radio networks

Full text

Pdf (442 KB)

Source

ACM International Conference Proceeding Series archive
Proceedings of the 4th Annual International Conference on Wireless Internet table of contents

Maui, Hawaii

SESSION: Cognitive radio networks table of contents

Article No. 12

Year of Publication: 2008

ISBN:978-963-9799-36-3

Authors

Aveek Dutta	University of Colorado, Boulder, CO
Jeffrey Fifield	University of Colorado, Boulder, CO
Graham Schelle	University of Colorado, Boulder, CO
Dirk Grunwald	University of Colorado, Boulder, CO
Douglas Sicker	University of Colorado, Boulder, CO

Sponsors

: ICST
: Intel
: XIRRUS

Publisher

ICST (Institute for Computer Sciences, Social-Informatics and Telecommunications Engineering) ICST, Brussels, Belgium, Belgium

Bibliometrics

Downloads (6 Weeks): 14, Downloads (12 Months): 46, Citation Count: 1

Additional Information:

abstract references cited by index terms collaborative colleagues

Tools and Actions:	Review this Article Save this Article to a Binder Display Formats: BibTeX EndNote ACM Ref

ABSTRACT

In this paper, we present an intelligent physical layer for cognitive mesh networks. It is well recognized that wireless mesh networks suffer from the inherent property of per hop delay attributed to store and forward routing and channel contention. We show that an intelligent physical layer coupled with efficient traffic engineering and channel allocation mechanism will reduce latency. In this paper, we discuss the evolution of an OFDM receiver, with sufficient software control to aid reconfigurability, capable of receiving and decoding information on different set of subcarriers, and also capable of switching the incoming signals to a different part of the available spectrum on the fly. Equipped with this enhanced receiver we propose a mechanism for wireless worm-hole routing, which employs frequency domain switching between subchannels where each subchannel is defined by a set of subcarriers. The OFDM receiver handles three primitives: transmit, receive and relay rather than just transmit or receive. Instead of a contention based, store and forward routing, a relay oriented physical layer has been proposed to reduce latency. The processing pipeline at an intermediate node no longer involves higher layer processing, and the hardware relays the incoming signal on-the-fly to a different part of the spectrum allowing for a full duplex transmission as the transmitter can relay signals while it is receiving on a different subchannel.

REFERENCES

Note: OCR errors may be found in this Reference List extracted from the full text article. ACM has opted to expose the complete List rather than only correct and linked references.

	1	Ram Ramanathan, Challenges: a radically new architecture for next generation mobile ad hoc networks, Proceedings of the 11th annual international conference on Mobile computing and networking, August 28-September 02, 2005, Cologne, Germany [doi>10.1145/1080829.1080843]
	2	J. Fifield, P. Kasemir, D. Grunwald, and D. Sicker, "Experiences with a platform for frequency agile techniques", in DYSPAN, 2007.
	3	C. Dick and F. Harris, "FPGA implementation of an OFDM PHY", in Signals, Systems and Computers, 2003. Conference Record of the Thirty-Seventh Asilomar Conference on, vol. 1, 9--12 Nov. 2003, pp. 905--909 Vol. 1.
	4	M. Speth, S. Fechtel, G. Fock, and H. Meyr, "Optimum receiver design for wireless broad-band systems using OFDM - I", in Communications, IEEE Transactions on, vol. 47, Nov 1999, pp. 1668--1677.
	5	M. Speth, S. Fechtel, G. Fock, and H. Meyr, "Optimum receiver design for OFDM-based broadband transmission - II. A case study", in Communications, IEEE Transactions on, vol. 49, Apr 2001, pp. 571--578.
	6	A. Troya, K. Maharatna, M. Krstic, E. Grass, and R. Kraemer, "OFDM synchronizer implementation for an IEEE 802.11(a) compliant modem", in IASTED International Conference on Wireless and Optical Communication, 2002. IASTED, 2002, pp. 152--157.
	7	"Rice university. WARP - wireless open-access research platform." {Online}. Available: http://warp.rice.edu
	8	"IEEE." {Online}. Available: http://standards.ieee.org/
	9	M. Wouters, G. Vanwijnsberghe, P. Van Wesemael, T. Huybrechts, and S. Thoen, "Real time implementation on fpga of an ofdm based wireless lan modem extended with adaptive loading", in Solid-State Circuits Conference, 2002. ESSCIRC 2002. Proceedings of the 28th European, 24--26 Sept. 2002, pp. 531--534.
	10	J. D. Guffey, A. M. Wyglinski, and G. J. Minden, "Agile radio implementation of ofdm physical layer for dynamic spectrum access research", in Global Telecommunications Conference, 2007. GLOBECOM '07. IEEE, 26--30 Nov. 2007, pp. 4051--4055.
	11	J. Zhu, B. Bing, Y. G. Li, and J. Xu, "An adaptive subchannel allocation algorithm for ofdm-based wireless home networks", in Consumer Communications and Networking Conference, 2004. CCNC 2004. First IEEE, 5--8 Jan. 2004, pp. 352--356.
	12	T. Schmidl and D. Cox, "Low-overhead, low-complexity {burst} synchronization for ofdm", in Communications, 1996. ICC 96, Conference Record, Converging Technologies for Tomorrow's Applications. 1996 IEEE International Conference on, vol. 3, 23--27 Jun 1996, pp. 1301--1306 vol. 3.
	13	"Xilinx System Generator for DSP." {Online}. Available: http://www.xilinx.com/
	14	S. Coleri, M. Ergen, A. Puri, and A. Bahai, "Channel estimation techniques based on pilot arrangement in ofdm systems", in Broadcasting, IEEE Transactions on, vol. 48, Sep 2002, pp. 223--229.
	15	Moises Serra , Pere Marti , Jordi Carrabina, Implementation of a Channel Equalizer for OFDM Wireless LANs, Proceedings of the 15th IEEE International Workshop on Rapid System Prototyping, p.232-238, June 28-30, 2004 [doi>10.1109/RSP.2004.25]
	16	"Perl script for viterbi decoder -." {Online}. Available: http://viterbi-gen.sourceforge.net/
	17	R. McTasney, D. Grunwald, and D. Sicker, "Low-Latency Multichannel Wireless Mesh Networks", in Proceedings of the 16th International Conference on Computer Communications and Networks 2007 ICCCN 2007. New York, NY, USA: IEEE, 2007, pp. 1082--1087.