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Radio Resource Management of Coexisting Multi-Radio Systems

Radio Resource Management of Coexisting Multi-Radio Systems. Date: 2008-7-14. Authors:.

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Radio Resource Management of Coexisting Multi-Radio Systems

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  1. Radio Resource Management of Coexisting Multi-Radio Systems Date: 2008-7-14 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. KC Chen, National Taiwan University

  2. Abstract We introduce the fundamental benefits of cooperative relay by organizing cognitive radio nodes, and primary methodologies to facilitate radio resource management so that cooperation among co-existing wireless networks can support future wireless communications, in terms of tremendous number of nodes, high-bandwidth requirement, and smooth migration from legacy systems and devices. KC Chen, National Taiwan University

  3. Three Technology Directions for Co-Existing Multi-Radio Systems • Cognitive and cooperative relay • Relying on terminal capability with software radio at physical layer to support multiple-radio systems and re-configurable networking capability • Inter-system handover • Realizing terminal access selection and mobility management among candidate systems and personal networks • Joint radio resource allocation • Joint optimization among systems • All OFDMA • OFDMA, CDMA, and others KC Chen, National Taiwan University

  4. Illustration of a generalized cooperative relay from source to destination KC Chen, National Taiwan University

  5. Self-organized Cognitive Radio Terminal Device Architecture KC Chen, National Taiwan University

  6. Cognitive and Cooperative Relay Following network coding study to develop the algorithms, cognitive and cooperative relay can increase 130% more throughput per bandwidth with 92% useful, in randomly generated network topology. KC Chen, National Taiwan University

  7. Inter-System Handover • A gateway (GW) entity can be introduced as an anchor point for inter-system communication and that provides the interface (IG) to the Internet and communicates with external routing functional entities. • GWs connect different RANs and the RANs will be considered as the elements of the whole communication networks. • A base station (BS) would perform almost all radio related functions for the active terminals (i.e., terminals sending data) and would be responsible for governing radio transmission to and reception from the terminal and relay nodes (RNs) in one or more cells. The BS is in control of relays (if used) and determines routes, forwards packets to the respective relay and takes care of flow control for the relays to ensure that they can forward the data to their associated terminals. KC Chen, National Taiwan University

  8. Scenario for inter-system mobility management including a 4G system BS is in control of relays (if used) and determines routes, forwards packets to the respective relay KC Chen, National Taiwan University

  9. Realization of inter-system inter-working in a 4G scenario Specific RRM (SRRM) is the entity in charge of adapting the RANs to the cooperation. KC Chen, National Taiwan University

  10. GW pools for support of mobility management in a 4G scenario The pool of GWs decouples the physical relation between a unique GW and a number of BS associated. KC Chen, National Taiwan University

  11. Cooperative Joint radio resource allocation • An even more aggressive scenario is to have a fully “integrated” system network architecture • to allow joint radio resource allocation among different systems • to approach ultimate radio resource utilization • in terms of frequency/sub-carrier, time, code, spatial/antenna in MIMO • Execution in 3 steps via mathematical optimization • Spectrum re-farming • allocating a pre-determined frequency band B among those N cells to maximize total network capacity according to demands • Spectrum (and power) allocation in each cell • Cross-layer resource allocation among co-existing systems KC Chen, National Taiwan University

  12. Numerical Result of Capacity Improvement by Cross-Layer Resource Allocation KC Chen, National Taiwan University

  13. Concluding Remarks • We suggest 3 technical directions toward co-existence of multi-radio systems • Cognitive radio terminal • Inter-system handover • Joint radio resource allocation • Easy to upgrade from legacy devices and systems • International standardization efforts would be helpful to facilitate ideas of enhancing spectrum efficiency KC Chen, National Taiwan University

  14. References • K.C. Chen, L.H. Kung, David Shiung, R. Prasad, S. Chen, “Self-Organizing Terminal Architecture for Cognitive Radio Networks”, Wireless Personal Multimedia Communications Conference, Jaipur, India, Dec. 3-6, 2007. • K.C. Chen, Y.J. Peng, N. Prasad, Sumei Sun, Y.C. Liang, “Cognitive Radio Network Architecture: Part I – General Structure”, Proceeding of ACM International Conference on Ubiquitous Information Management and Communication, Seoul, 2008. • Chu-Hsiang Huang, Yen-Chieh Lai, Kwang-Cheng Chen, “Network Capacity of Cognitive Radio Relay Network”, to appear in PhyCom, 2008. • E. Tragos, A. Mihovska, E. Mino-Diaz, P. Karamolegkos, “Access Selection and Mobility Management in a Beyond 3G RAN: The WINNER Approach”, ACM MobiWac, 2007. • Feng Seng Chu, Kwang-Cheng Chen, “Radio Resource Allocation for Mobile MIMO-OFDMA,” IEEE Vehicular Technology Conference - Spring, Singapore, 2008. Acknowledgement: This research is supported in part by the European research projects WINNER II and MAGNET Beyond, and by the research projects sponsored by National Science Council and Ministry of Economic Affairs, Taiwan ROC. KC Chen, National Taiwan University

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