Distributed power control in quasi-synchronous multi-carrier CDMA systems

This paper addresses the power assignment problem in multicarrier code-division multiple-access (MC-CDMA) systems. The problem is formulated as finding the correct transmission power to achieve a desired quality of service (QoS), described by an objective signal-to-interference and noise ratio (SINR). First, the model of the MC-CDMA is described, and by considering a matched filter at the receiver, the SINR after data estimation is explicitly characterized. Due to the diversity in MC-CDMA systems, the power assignment problem is approached with a minimum norm perspective restricted to achieve a pre-defined objective SINR per user. Centralized and distributed solutions are presented in the paper. The distributed power allocation strategy is further extended to consider general controllers, and measurement and processing delays. Necessary conditions for closed-loop stability and convergence to the optimal minimum norm solution are derived by using the small-gain theorem. One advantage of the proposed methodology is that it can use power control strategies previously suggested for CDMA systems, as the Foschini-Miljanic scheme and LQ-control. © 2012 AACC American Automatic Control Council).

MC-CDMA; Power control; quality of service Combinatorial optimization; Matched filters; Multicarrier modulation; Power control; Quality control; Quality of service; Signal interference; Signal to noise ratio; Turbo codes; Distributed power control; Distributed Power-Allocation; MC-CDMA; Minimum norm solutions; Multi carrier code-division multiple-access systems; Multi-carrier CDMA systems; Power control strategies; Signal-to-interference and noise ratios; Code division multiple access

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