2019
DOI: 10.1155/2019/2875136
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Adaptive Energy Efficiency Maximization for Cognitive Underwater Acoustic Network under Spectrum Sensing Errors and CSI Uncertainties

Abstract: Energy efficiency (EE) maximization problem for Cognitive Underwater Acoustic Network is investigated in this study. Available works on EE usually assume that spectrum sensing is accurate or that channel state information (CSI) is perfect, which is often impractical. Thus, an adaptive resource allocation scheme is proposed to maximize the EE, subject to the transmission power constraint of secondary user (SU) and the interference power constraint of primary user (PU). By taking the spectrum sensing errors into… Show more

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Cited by 3 publications
(4 citation statements)
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“…Additionally, decoding the acoustic signals transmitted by NCUs is challenging, due to the lack of a standardized message format. As a result, a channel should be considered as an ON–OFF process to ensure successful data transmission and avoid collisions with NCUs [ 20 , 28 ]. Hence, any channel occupied by an NCU should be deemed as “unavailable” for cognitive communication.…”
Section: System Model and Asymmetry Of Available Channelsmentioning
confidence: 99%
“…Additionally, decoding the acoustic signals transmitted by NCUs is challenging, due to the lack of a standardized message format. As a result, a channel should be considered as an ON–OFF process to ensure successful data transmission and avoid collisions with NCUs [ 20 , 28 ]. Hence, any channel occupied by an NCU should be deemed as “unavailable” for cognitive communication.…”
Section: System Model and Asymmetry Of Available Channelsmentioning
confidence: 99%
“…In this study, the joint relay and power selection problem is solved by considering the limited feedback of quantized CSI information to obtain the maximum sum rate; In [ 30 ], another joint relay selection and power allocation method was proposed for a UCAN, which considers a trust parameter to overcome imperfect spectrum sensing. In this study, selecting a relay CU and allocating power are determined to maximize the network throughput, and this optimization problem is reduced to the proposed sub-optimal approach; In [ 31 ], the joint parameter optimization of cooperative spectrum sensing time, channel allocation, and power for a UCAN was proposed in order to maximize spectral efficiency and energy efficiency at the same time. The optimal solutions are obtained by alternating direction optimization and Dinkelbach’s optimization; In [ 32 ], a QoS-driven power allocation method for a UCAN was proposed, which helps to allocate a CU into an optimal power by considering the statistical QoS constraints (i.e., delay bounds).…”
Section: Previous Work On Spectrum Sharing For a Ucanmentioning
confidence: 99%
“…In [ 31 ], the joint parameter optimization of cooperative spectrum sensing time, channel allocation, and power for a UCAN was proposed in order to maximize spectral efficiency and energy efficiency at the same time. The optimal solutions are obtained by alternating direction optimization and Dinkelbach’s optimization;…”
Section: Previous Work On Spectrum Sharing For a Ucanmentioning
confidence: 99%
“…In the literature, UCAN technologies primarily focus on the efficient allocation of resources such as frequency (or channel), power, or data rate heuristically or optimally [15][16][17][18][19]. However, research on resource allocation or channel access for CUs in a distributed topology has been limited.…”
Section: Introductionmentioning
confidence: 99%