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IEEE SCC41 PARs Date: 2009-08-22 Authors: Notice:This document has been prepared to assist IEEE 802.19. It is offered as a basis for discussion and is not binding on the contributing individual(s) or organization(s). The material in this document is subject to change in form and content after further study. The contributor(s) reserve(s) the right to add, amend or withdraw material contained herein. Rashid Saeed, TMRND
SCC41 Standards Project Acceptance Criteria • 1. Broad market application • Each SCC41 (P1900 series) standard shall address a well defined problem or need, be commercially relevant, have applicability to multiple market segments if possible, and cater to an open market where many produces and consumers can benefit. • 2. Consistency • Each SCC41 (P1900 series) standard shall be consistent with other SCC41 (P1900 series) standards in the series. • 3. Distinct Identity • Each SCC41 (P1900 series) standard shall have a distinct identity and does not substantially overlap or duplicate the work in other existing industry standards. • 4. Achievable Scope • Each SCC41 (P1900 series) project shall have the potential to produce a mature draft within 18 months of PAR approval. • 5. Balanced and committed participation • To uphold the IEEE-SA principle of open, balanced, consensus-based, inclusive participation, a project requesting approval shall be scrutinized for balance in the participants. This means that a diversity of stakeholders should be represented. Also, to ensure successful and timely completion of the standard, the project team shall demonstrate commitment to get the standard completed. 2 Rashid Saeed, TMRND
IEEE 1900.1 WG on Terminology and Concepts for Next Generation Radio Systems and Spectrum Management Purpose New concepts and technologies are rapidly emerging in the fields of DySPAN and many of the terms do not have precise definitions or have multiple definitions. spectrum management, policy defined radio, adaptive radio, software defined radio, reconfigurable radio and networks and related technologies. The IEEE 1900.1 Working Group will develop a standard to clarify these terminologies and how these technologies relate to each other. 3 Rashid Saeed, TMRND
IEEE 1900.1 Scope The standard will go beyond simple, short definitions by providing amplifying text that explains these technologies from different perspectives. The document will also describe how these technologies interrelate and can be use in a wide variety of communication service environments to achieve new capabilities while at the same time providing mechanisms supportive of new spectrum management paradigms and spectrum access. Current Status PAR is approved in March 2005; IEEE Draft Standard P1900.1 is in the balloting and recirculation stages. 4 Rashid Saeed, TMRND
IEEE 1900.1 Project Authorization Request (Full PAR) 5 Rashid Saeed, TMRND
IEEE 1900.2 WG on Recommended Practice for Interference and Coexistence Analysis Purpose The primary goal of DySPAN is to improve spectral efficiency. This standard will provide guidance for the analysis of coexistence and interference between various radio services. Scope This standard will provide technical guidelines for analyzing the potential for coexistence or in contrast interference between radio systems operating in the same frequency band or between different frequency bands. Current Status PAR approved March 2005; IEEE Draft Standard P1900.2 is in the balloting and recirculation stages. 6 Rashid Saeed, TMRND
IEEE 1900.2 Project Authorization Request (Full PAR) 7 Rashid Saeed, TMRND
IEEE 1900.3 WG on Recommended Practice for Conformance Evaluation of SDR Software Modules Purpose to provide recommended practices that will help assure compliance with requirements for spectrum use by using formal mathematical concepts and methods. The methods developed in this document will provide an initial evaluation to be used before hardware testing and will support the evaluation being developed in 1900.2. To provide guidance for validity analysis of proposed SDR terminal software prior to programming and activation of an SDR terminal or SDR components. To provide guidance on how to estimate the conformance with relevant specifications of software intended for deployment into a SDR terminal. To support quality control and testing. To assure that SDR software can be deployed with high confidence that it will operate within prescribed regulatory and operational limits. 8 Rashid Saeed, TMRND
IEEE 1900.3 Scope This recommended practice will provide technical guidelines for analyzing SDR software modules to ensure compliance with regulatory and operational requirements. Current Status Old PAR was approved on May 2005 New PAR was approved by the groups and SCC41 in July 2007. 9 Rashid Saeed, TMRND
IEEE 1900.3 Project Authorization Request (Full PAR) 10 Rashid Saeed, TMRND
IEEE 1900.4 Coexistence support for reconfigurable, heterogeneous air interfaces Purpose To improve overall composite capacity and QoS of wireless systems in a multiple Radio Access Technologies (RATs) environment, by defining an appropriate system architecture and protocols which will facilitate the optimization of radio resource usage, in particular, by exploiting information exchanged between network and mobile Terminals, whether or not they support multiple simultaneous links and dynamic spectrum access. 11 Rashid Saeed, TMRND
IEEE 1900.4 Scope The standard defines the building blocks for enabling coordinated network-device distributed decision making which comprising: network resource managers, device resource managers, the information to be exchanged between the building blocks, will aid in the optimization of radio resource usage, including spectrum access control, in heterogeneous wireless access networks. The standard is limited to the architectural and functional definitions at a first stage. The corresponding protocols definition related to the information exchange will be addressed at a later stage. 12 Rashid Saeed, TMRND
IEEE 1900.4 Need for the Project Multimode reconfigurable devices are increasingly being adopted within the wireless industry. The choice among various supported air interfaces on a single wireless device is already a reality today, with devices offering, for example, 2nd, 3rd generation cellular radio access technologies and 802 wireless standards. Last but not least, devices and networks with DSA capabilities allowing the use of spectrum resource simultaneously among different systems are emerging and will be part of the radio eco-space. 13 Rashid Saeed, TMRND
IEEE 1900.4.1 Standard for Interfaces and Protocols Enabling Distributed Decision Making for Optimized Radio Resource Usage in Heterogeneous Wireless Networks (Full PAR) Rashid Saeed, TMRND
P1900.4a: Amendment: Architecture and Interfaces for Dynamic Spectrum Access Networks in White Space Frequency Bands (Full PAR) Rashid Saeed, TMRND
IEEE 1900.5 WG on Policy Language and Policy Architectures for Managing CR for DSA Applications Purpose The purpose is to define a policy language (or a set of policy languages or dialects) to specify interoperable, vendor-independent control of CR functionality and behavior for DSA resources and services. Scope The initial work will concentrate on standardizing the features necessary for a policy language to be bound to one or more policy architectures Future additional tasks will build on this foundation to standardize how this is done in greater detail, paying special attention to interoperability concerns. Current Status Study Group approved March 2006. Study group A is changed to WG 5 on December 2007 SCC41 plenary 16 Rashid Saeed, TMRND
IEEE 1900.6: Standard For Spectrum Sensing Interfaces And Data Structures For Dynamic Spectrum Access And Other Advanced Radio Communication Systems • Purpose: • To make the development and evolution of trusted spectrum sensing capabilities. • Scope: • Define the sensing technology, client design , and data link between the sensors and clients. 17 Rashid Saeed, TMRND
IEEE 1900.6 (PAR Draft) Rashid Saeed, TMRND
Thank you Rashid Saeed, TMRND