Propagation Issues for Cognitive Radio

Cognitive radios are expected to work in bands below about 3.5 GHz and may be used for a variety of applications, e.g., broadband fixed wireless access, mobile and nomadic access, etc. Cognitive radio system designers must have access to a wide range of channel models covering a wide span of operati...

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Veröffentlicht in:	Proceedings of the IEEE 2009-05, Vol.97 (5), p.787-804
Hauptverfasser:	Molisch, Andreas F., Greenstein, Larry J., Shafi, Mansoor
Format:	Artikel
Sprache:	eng
Schlagworte:	Angle-of-arrival Bands Bandwidth Blockage Broadband channel models Channels Chromium Cognitive radio delay spread Dispersion Dispersions Doppler Frequency domain analysis Mobile communication systems Modems multipath propagation path loss Physical properties Propagation Propagation delay Propagation losses Radio Radio systems Radiofrequency interference Radios Shadow mapping shadowing Wireless communications
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container_title	Proceedings of the IEEE
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creator	Molisch, Andreas F. Greenstein, Larry J. Shafi, Mansoor
description	Cognitive radios are expected to work in bands below about 3.5 GHz and may be used for a variety of applications, e.g., broadband fixed wireless access, mobile and nomadic access, etc. Cognitive radio system designers must have access to a wide range of channel models covering a wide span of operating frequencies, carrier bandwidths, deployment conditions, and environments. This paper provides a comprehensive overview of the propagation channel models that will be used for the design of cognitive radio systems. We start with classical models for signal loss versus distance and discuss their dependence on the physical properties of the environment and operating frequency. Here we also introduce the concept of log-normal shadowing resulting from signal blockage by man-made and natural features. Next, we discuss the time-varying nature of the wireless channel, introduced as a result of the motion of objects in the channel. This is followed by a discussion on the dispersion of the signal caused by various effects of propagation, especially in the time and frequency domains. Angular dispersion, which is discussed next, is important because cognitive radios may be based on modems that exploit the spatial domain. Lastly, we summarize channel models that have been standardized for fixed and mobile systems.
doi_str_mv	10.1109/JPROC.2009.2015704
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subjects	Angle-of-arrival Bands Bandwidth Blockage Broadband channel models Channels Chromium Cognitive radio delay spread Dispersion Dispersions Doppler Frequency domain analysis Mobile communication systems Modems multipath propagation path loss Physical properties Propagation Propagation delay Propagation losses Radio Radio systems Radiofrequency interference Radios Shadow mapping shadowing Wireless communications
title	Propagation Issues for Cognitive Radio
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