S.G. Kiani scite author profile

Abstract-We consider allocating the transmit powers for a wireless multi-link (N -link) system, in order to maximize the total system throughput under interference and noise impairments, and short term power constraints. Employing dynamic spectral reuse, we allow for centralized control. In the two-link case, the optimal power allocation then has a remarkably simple nature termed binary power control: Depending on the noise and channel gains, assign full power to one link and minimum to the other, or full power on both.Binary power control (BPC) has the advantage of leading towards simpler or even distributed power control algorithms. For N > 2 we propose a strategy based on checking the corners of the domain resulting from the power constraints to perform BPC. We identify scenarios in which binary power allocation can be proven optimal also for arbitrary N . Furthermore, in the general setting for N > 2, simulations demonstrate that a throughput performance with negligible loss, compared to the best non-binary scheme found by geometric programming, can be obtained by BPC. Finally, to reduce the complexity of optimal binary power allocation for large networks, we provide simple algorithms achieving 99% of the capacity promised by exhaustive binary search.

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Adaptation, Coordination, and Distributed Resource Allocation in Interference-Limited Wireless Networks

Gesbert

et al. 2007

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Optimal Power Allocation and Scheduling for Two-Cell Capacity Maximization

et al.

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Abstract-We consider the problem of optimally allocating the base station transmit power in two neighboring cells for a TDMA wireless cellular system, to maximize the total system throughput under interference and noise impairments. Employing dynamic reuse of spectral resources, we impose a peak power constraint at each base station and allow for coordination between the base stations. By an analytical derivation we find that the optimal power allocation then has a remarkably simple nature: Depending on the noise and channel gains, transmit at full power only at base station 1 or base station 2, or both.Utilizing the optimal power allocation we study optimal link adaptation, and compare to adaptive transmission without power control. Results show that allowing for power control significantly increases the overall capacity for an average user pair, in addition to considerable power savings. Furthermore, we investigate power adaptation in combination with scheduling of users in a time slotted system. Specifically, the capacity-optimal singlecell scheduler [1] is generalized to the two-cell case. Thus, both power allocation and multiuser diversity are exploited to give substantial network capacity gains.

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Optimal and Distributed Scheduling for Multicell Capacity Maximization

Kiani¹,

Gesbert²

2008

IEEE Trans. Wireless Commun.

103

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Maximizing Multicell Capacity Using Distributed Power Allocation and Scheduling

Kiani

Oien

Gesbert

2007

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Joint optimization of transmit power and scheduling in wireless data networks promises significant system-wide capacity gains. However, this problem is known to be NP-hard and thus difficult to tackle in practice. We analyze this problem for the downlink of a multicell full reuse network with the goal of maximizing the overall network capacity. We propose a distributed power allocation and scheduling algorithm which provides significant capacity gain for any finite number of users. This distributed cell coordination scheme, in effect, achieves a form of dynamic spectral reuse, whereby the amount of reuse varies as a function of the underlying channel conditions and only limited inter-cell signaling is required.

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S.G. Kiani

Binary Power Control for Sum Rate Maximization over Multiple Interfering Links

Adaptation, Coordination, and Distributed Resource Allocation in Interference-Limited Wireless Networks

Optimal Power Allocation and Scheduling for Two-Cell Capacity Maximization

Optimal and Distributed Scheduling for Multicell Capacity Maximization

Maximizing Multicell Capacity Using Distributed Power Allocation and Scheduling

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