IEEE 1900 1 SERIES-2008 en Definitions and Concepts for Dynamic Spectrum Access Terminology Relating to Emerging Wireless Networks System Functionality and Spec.pdf

1、IEEE Std 1900.1-2008 IEEE Standard Definitions and Concepts for Dynamic Spectrum Access: Terminology Relating to Emerging Wireless Networks, System Functionality, and Spectrum Management IEEE 3 Park Avenue New York, NY 10016-5997, USA 26 September 2008 IEEE Communications Society Sponsored by the IE

2、EE Standards Coordinating Committee 41 on Dynamic Spectrum Access Networks 1900.1 TM IEEE Std 1900.1 TM -2008 IEEE Standard Definitions and Concepts for Dynamic Spectrum Access: Terminology Relating to Emerging Wireless Networks, System Functionality, and Spectrum Management Sponsor IEEE Communicati

3、ons Society and IEEE Standards Coordinating Committee 41 on Dynamic Spectrum Access Networks Approved 12 June 2008 IEEE-SA Standards Board Abstract: This standard provides definitions and explanations of key concepts in the fields of spectrum management, cognitive radio, policy-defined radio, adapti

4、ve radio, software-defined radio, and related technologies. The document goes beyond simple, short definitions by providing amplifying text that explains these terms in the context of the technologies that use them. The document also describes how these technologies interrelate and create new capabi

5、lities while at the same time providing mechanisms supportive of new spectrum management paradigms such as dynamic spectrum access. Keywords: cognitive radio, cognitive radio networks, dynamic spectrum access, policy-based radio, software-controlled radio, software-defined radio, spectrum management

6、 The Institute of Electrical and Electronics Engineers, Inc. 3 Park Avenue, New York, NY 10016-5997, USA Copyright 2008 by the Institute of Electrical and Electronics Engineers, Inc. All rights reserved. Published 26 September 2008. Printed in the United States of America. IEEE and 802 are registere

7、d trademarks in the U.S. Patent +1 978 750 8400. Permission to photocopy portions of any individual standard for educational classroom use can also be obtained through the Copyright Clearance Center. iv Copyright 2008 IEEE. All rights reserved. Introduction This introduction is not part of IEEE Std

8、1900.1-2008, IEEE Standard Definitions and Concepts for Dynamic Spectrum Access: Terminology Relating to Emerging Wireless Networks, System Functionality, and Spectrum Management. This standard establishes common terminology for describing emerging networks and nodes employing radio devices characte

9、rized by cognition, adaptation, environment awareness, and policy-based adaptive techniques. Specifically, the definitions provided in this document stem predominantly from a spectrum management point of view. It is anticipated that these definitions will ultimately mature and ideally achieve widesp

10、read acceptance among researchers, manufacturers, service providers, regulators, and operators. The intent of this document is to promote a common understanding of systems technology and spectrum management terms so that technologists in a variety of fields such as radio science, including digital c

11、ommunications, computer science, and artificial intelligence, and regulators have a common understanding of the terminology. It is the intent of this document to provide concise definitions of key terms in advanced radio system technologies and in advanced spectrum management techniques. The focus o

12、f this standard is on terms and concepts relating to emerging wireless networks, radio, technology, system functionality, and spectrum management. It was agreed that in some cases, multiple definitions for a specific term were appropriate. Development of this standard required: a) The creation of so

13、me new terms (e.g., cognitive radio) and the development of definitions for these new terms. b) The development of alternative definitions for existing terms (e.g., dynamic frequency selection) that have been defined by other standards development organizations; these alternative definitions were re

14、quired for next-generation radio and spectrum management because these terms have new meanings when used in the context of discussing advanced radio systems. It is deemed to be outside the focus of this standard to include all of the terms relevant to wireless communications systems and spectrum man

15、agement (e.g., radio frequency and radio signal). However, when deemed appropriate, existing terms from the ITU-R and other IEEE documents are included for the convenience of the reader even though the term and definition is unchanged for next-generation radio and spectrum management. These terms ar

16、e clearly identified in the text. This document provides normative terms and definitions to support the research and deployment of dynamic spectrum management (DSM) and dynamic spectrum access (DSA). Many factors are creating a need for DSM and DSA. Among the forces creating this need for change are

17、 as follows: The increasing use of wireless services and their need for spectrum. The increasing data load being transmitted wirelessly, requiring increasing spectrum bandwidth. The emergence of multimode products such as mobile, broadcast, and radiolocation into single devices. Increasing pressure

18、to guarantee spectrum access for priority services such as public safety while allowing other uses for that same spectrum when not in use by those priority services. v Copyright 2008 IEEE. All rights reserved. Overview of New Technologies Terminology used to describe equipment, systems, and networks

19、 employing advanced radio functionality are contained within this standard that will provide researchers, manufacturers, service providers, regulators, operators, and users with the means of describing advanced radio devices and spectrum management techniques. Some of the general features of these e

20、merging radio and wireless networking systems are as follows: Flexibility Dynamic and adaptive behavior Awareness (e.g., location and radio environment), cognition, and intelligence Networking for group collaboration and interaction (e.g., sensing the spectrum usage environment) These features creat

21、e many new avenues for improving use and access to the radio spectrum. Specifically, they provide additional degrees of freedom that allow a device to choose the best method of spectrum access for a particular situation and to alter the method of access to respond to changing conditions. For example

22、 dynamic spectrum access systems have been suggested as a fundamental, technology-enabled method to make more effective and efficient use of scarce available spectrum. In principle, the DSA concept advocates empowering radio systems with the local authority and responsibility to manage available sp

23、ectrum. However, practical methods for designing, developing, and managing such systems remain in the early formative stages. Current spectrum management practices do not provide effective techniques for certifying these types of advanced radio devices or for managing their access to the radio spect

24、rum. This situation could create barriers to the introduction of new radio technologies if resolution of spectrum issues for each new device must be addressed on a case-by-case basis. Recent advancements in wireless communication technology have given rise to many new terms and concepts within the b

25、ody of technical literature, including reconfigurable radio, software-defined radio, software-controlled radio, policy-defined radio, adaptive radio, cognitive radio, and others. Although radios certainly play an important part in the design and construction of wireless communication systems, these

26、advanced technologies extend beyond what is commonly thought of as a “radio.” When describing these technologies, therefore, it is more useful to consider them in the context of a complete communications system or network. For example, the terms “cognitive radio” and “adaptive radio” are often used,

27、 and although it may be a convenient linguistic construct, it is unclear that the use of these terms is always both linguistically and logically correct. In wireless communication systems, radios are physical devices that transmit and receive information encoded on radio-frequency (RF) waveforms usi

28、ng antennas, transmitters, and receivers. That is, radios are designed to perform certain functions, for example, receiving and transmitting. The development of this standard was founded on the premise that wireless communication systems will evolve to the point where cognitive and adaptive function

29、ality play an important, essential role in their use of the radio spectrum, and that the industry is now approaching that point in history. Consequently, this standard provides definitions for terms describing this expanded functionality that are relevant to spectrum use by next-generation radios an

30、d networks. For example, the cognition function may not be just a radio function as radio is defined herein; some of the functionality may lie outside the radio itself. This focus is provided throughout the standard. The term “cognitive” has recently entered into the lexicon of wireless networks in

31、an attempt to describe a functionality that is inherently distributed within not only a given network but also potentially a network of networks. Consider, for example, a network of unlicensed band WiFi *access points and stations providing Internet access for the population of a metropolitan area,

32、operating alongside a public safety network, *WiFi is a mark of the Wi-Fi Alliance. including police, fire, and ambulance communications in the same band, with both networks sharing information that allows them to coexist. This new cognitive functionality provides a mechanism for peaceful coexistenc

33、e among multiple networks and the potential for equitable sharing of RF spectrum. As the term “cognitive” implies, at the heart of the new technology is knowledge, that is, information that is gathered and stored in possibly a distributed manner throughout the network of networks. The concepts of co

34、llaboration and consent are equally important; that is, some policy agreement exists that defines the objectives and constraints of the participating networks (cf. policy-based radios). Throughout this standard, that cognitive and related functionality may be shared throughout the network, network n

35、odes, and the radios in the network nodes. No attempt is made to define exactly how these functions are distributed because that is an implementation issue. Virtually all radios on the market today use some form of digital signal processing involving a microprocessor and software of some form to per

36、form even the simplest function (e.g., changing the operating frequency). Yet, the term “software-defined radio” is commonly used to distinguish a certain class of radios, and usually it is meant to convey a meaning that goes beyond merely implying the existence of some software in the device. The t

37、erm is used to describe certain functionality that is performed or managed differently because it is driven by software rather than by hardware. It is important to realize that communications nodes and networks with primitive cognitive, adaptive, and software-defined functionality exist today. The c

38、urrent IEEE 802.11a/b/g standard specifies a Carrier Sense Multiple Access/Collision Avoidance (CSMA/CA) Media Access Control (MAC) protocol that involves a “stop, look and listen watch out for the cars” cognitive functionality. It is inherently adaptive and can be instantiated in software. This rep

39、resents the early stages of an advanced and evolving communications technology with objectives including the ability to offer more robust, maximum-channel capacity usage, increased spectrum-usage efficiency, as well as fault-tolerant and ubiquitous information-conveyance capabilities for one or more

40、 users. Communication nodes and networks with cognitive functionality can potentially use contextual information to devise and implement solutions that ideally best serve the current and anticipated information transfer requirements. This contextual information can be derived from the physical (node

41、 state and device resources, spatial, environmental, network topology, and communications channel information), regulatory and policy (frequency spectrum usage rules and etiquettes, licenses, user access rights), social (individualistic or collaborative and distributed network existence), and econom

42、ic (payment mechanisms, spectrum market environment) domains. In the framework of wireless networks, whether it is a portion of the network or the entire network, network management procedures imply the management of the available transmission spectrum, which in turn impacts system performance, reso

43、urce allocation, quality-of-service, and so on. To this extent, network management is directly related to spectrum management; therefore, comprehension of network management concepts is necessary when discussing spectrum management. In this standard, some terms are related (i.e., some terms are defi

44、ned and then used in the definitions of other terms). Terms that appear in the definition of other terms are placed in bold in the definition for the higher level term (see, for example, the term software-defined radio and the term software defined). Notice to users Laws and regulations Users of the

45、se documents should consult all applicable laws and regulations. Compliance with the provisions of this standard does not imply compliance to any applicable regulatory requirements. Implementers of the standard are responsible for observing or referring to the applicable regulatory requirements. IEEE does not, by the publication of its standards, intend to urge action that is not in compliance with applicable laws, and these documents may not be construed as doing so. vi Copyright 2008 IEEE. All rights reserved.