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Autonomous Distributed Power Control for Cognitive Radio Networks

Autonomous Distributed Power Control for Cognitive Radio Networks. Sooyeol Im ; Jeon , H.; Hyuckjae Lee ; IEEE Vehicular Technology Conference, 2008. VTC 2008-Fall. Outline. Introduction System Model Related Works Autonomous Distributed Power Control for Cognitive Radio Networks

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Autonomous Distributed Power Control for Cognitive Radio Networks

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  1. Autonomous Distributed Power Control for Cognitive Radio Networks SooyeolIm; Jeon, H.; Hyuckjae Lee; IEEE Vehicular Technology Conference, 2008. VTC 2008-Fall

  2. Outline • Introduction • System Model • Related Works • Autonomous Distributed Power Control for Cognitive Radio Networks • Simulations • Conclusions • Comments

  3. Introduction • In 2004, FCC proposed that unlicensed devices flexibly utilize the TV spectrum with no harmful interference [2][3]. • The cognitive radio allows the secondary user (SU) to opportunistically access the spectrum licensed to the primary user (PU) without interfering with the PU. • Power control of CR networks is more complex than cellular networks • The quality of service requirements of the secondary user. • The protection of the primary users’ communication. • Secondary users should always check the estimated interference at the primary receiver after determining their transmission power. [2] FCC, “Notice of Proposed Rule Making,” ET Docket No. 04-113, May 2004. [3] M. J. Marcus, “Unlicensed Cognitive Sharing of TV Spectrum: The Controversy at the Federal Communications Commission,” IEEE Commun. Mag., vol. 43, no. 5, pp. 24-25, May 2005.

  4. Introduction (cont’d) • Centralized Power Control • A central manager controls the transmission power of all users within its coverage. • Fuzzy Logic System (built-in fuzzy power controller) [5] • Dynamically adjust its transmission power in response to the changes of the interference level caused by the SU to PU. • In [6], the optimal power control problem was modeled as a concave minimization problem. • Drawback • all information required for managing the network should be known to the central entity • very heavy signaling is inevitable [5] J. T. Le and Q. Liang, “An Efficient Power Control Scheme for Cognitive Radios,” in IEEE Wireless Communications and Networking Conference, 2007 [6] W. Wang, T. Peng, and W. Wang, “Optimal Power Control under Interference Temperature Constraint in Cognitive Radio Network,” in IEEE Wireless Communications and Networking Conference, 2007,

  5. Introduction (cont’d) • Distributed Power Control • Each user controls its transmission power by itself using only local information. • An additional process to satisfy QoS for the PU • Let the SUs recognize the interference temperature at the primary receiver. • In [7], a joint coordination and power control algorithm was proposed. • Coordination phase and power control phase • In [8], a genie-aided distributed power control algorithm was proposed. •  They are not fully autonomous distributed power control algorithm. [7] Y. Xing and R. Chandramouli, “QoS Constrained Secondary Spectrum Sharing,” in IEEE Dynamic Spectrum Access Networks, 2005 [8] L. Qian, X. Li, J. Attia, and Z. Gajic, “Power Control for Cognitive Radio Ad Hoc Networks,” in IEEE Local and Metropolitan Area Networks, 2007

  6. Introduction (cont’d) • In this paper, • Fully autonomous distributed power control scheme without an additional process for CR networks • The constraint for the sum of the interference of PU induced by all SUs in the network is replaced by new one which limits the individual transmission power. • The individual transmission power constraint and the proposed scheme are numerically derived. • The simulation results demonstrate that the proposed scheme never exceed the interference temperature limit (ITL) of the PU

  7. System Model • Network Architecture • One Primary transmitter • N secondary users • PTV: TX power of TV STA • Pi: TX power of SU • α1, α2: the path loss factor of the TV and the SU. α1<α2 h Primary users Secondary users

  8. System Model (cont’d) • Two QoS requirements • Interference temperature for primary user • PU should be able to communicate whenever it wants. • The total amount of interference at the primary receiver caused by all SU’s opportunistic communications should be less than the ITL (Interference Temperature Limit). GTV,i: the link gain from SU transmitter i to the TV receiver Pi: the tx power of SU transmitter ξTV: the interference at PU

  9. System Model (cont’d) • Received SINR of Secondary User (receiver i) • For reliable communication, Receiver capture threshold Interference Let Gi,j be the link gain from the secondary transmitter j to the secondary receiver i, Gi,TV be the link gain from the secondary transmitter j to the secondary receiver I, PTV be the transmission power of the TV transmitter, N0 be the receiver noise power.

  10. Related Work – DCPC • Distributed Constrained Power Control [10] • Goal: keep the transmission power of the users in the network at the minimum level required to achieve the SINR for reliable communication. N x 1 Vector U N x N Matrix H [10] S. A. Grandhi, J. Zander, and R. Yates, “Constrained Power Control,” Wireless Pers. Commun., vol. 1,Dec. 1994.

  11. Related Work – DCPC (cont’d) • The equation can be rewritten as, • The matrix notation of the linear inequality • Pis the transmission power vector P = (P1,P2,…,PN)T • If the maximum eigenvalue of the matrix H isless than one, there exists a non-negative power vector P which satisfies the above equation.

  12. Related Work – DCPC (cont’d) • The Pareto optimal power vector is, • To solve the equation distributively, a general iterative method was introduced in [9].

  13. Related Work – GDCPC (cont’d) • The drawback of DCPC is that • the transmission power of the user reaches the maximum transmission power even if the user cannot achieve the minimum required SINR • Generalized DCPC (GDCPC) [11] • Motivation: to complement the drawback of DCPC • When the user cannot achieve the required SINR, it reduces the power to arbitrary level instead of necessarily using the maximum transmission power [11] F. Berggren, R. Jantti, and S. Kim, “A Generalized Algorithm for Constrained Power Control With Capability of Temporary Removal,” IEEE Trans. Veh. Commun., vol. 50, Nov. 2001.

  14. Related Work – GDCPC (cont’d) • GDCPC can be represented as, • The Power value is chosen arbitrarily within the range of

  15. Autonomous Distributed Power Control for Cognitive Radio Networks • Since DCPC and GDPC don’t consider the QoS requirement for the PU • the resulting transmission power of them may exceed the ITL of the primary receiver • By translating the interference constraint by the sum of all SUs’ transmission power to the individual constraint for each SU • the QoS requirement for the PU can be easily guaranteed

  16. Autonomous Distributed Power Control for Cognitive Radio Networks(cont’d) • Assumptions • Each secondary user can know the number of secondary users N by using ad-hoc routing protocol. • The primary receiver transmits the beacon including the information about the beacon power and the ITL of itself. • The SUs can know the link gain from itself to the TV receiver and the ITL of the TV receiver

  17. Autonomous Distributed Power Control for Cognitive Radio Networks(cont’d) • Autonomous DCPC • Autonomous GDCPC Upper bound power value

  18. Simulations

  19. Simulations (cont’d) d Comparison of the interference temperature at the TV receiver

  20. Simulations (cont’d) Comparison of the number of the supported users

  21. Simulations (cont’d) • The secondary transmitter nearest to the TV receiver is the worst interferer with the TV receiver • The secondary transmitter satisfies Eq.(18), all secondary transmitters in the network satisfy that. • The distance d satisfies the inequality(19), the proposed schemes are always equal to the conventional schemes.

  22. Conclusions • Consider that the distributed power control problem in the CR network which shares the primary user’s channel • The transmission power constraint of each secondary user to protect the primary user is numerically derived. • Future work • The convergence rate of he proposed scheme using iterative method

  23. Comments • Make an improvement of others related work such as DCPC and GDCPC. • Problem Definition  Model Formulation  Scenario Related method  Improvement  Simulation & Comparison.

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