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Target-Rate Least-Squares Power Allocation over Parallel Channels

Information Theory 2026-03-10 v1 math.IT

Abstract

We study power allocation over NN parallel Gaussian channels, such as OFDM subcarriers, when each channel has a desired target spectral efficiency. Given channel gain-to-noise coefficients ai>0a_i>0 and per-channel targets Ti0T_i\ge 0, we minimize the total squared rate deviation i=1N(log2(1+aiPi)Ti)2\sum_{i=1}^{N}(\log_2(1+a_iP_i)-T_i)^2 subject to a sum-power constraint iPiPtot\sum_i P_i \le P_{\mathrm{tot}} and nonnegativity Pi0P_i \ge 0. We prove that the optimal allocation never overshoots any target and may leave power unused when all targets are jointly feasible, a structure fundamentally different from classical waterfilling. Using the KKT conditions, we derive a per-channel closed-form solution in terms of the Lambert~W function on the active set and reduce the remaining computation to a one-dimensional monotone bisection for the dual variable. The resulting algorithm runs in O(Nlog(1/ε))O(N\log(1/\varepsilon)) time and achieves up to 1{,}890×\times speedup over general-purpose numerical solvers at N=1024N=1024 channels. Numerical experiments over Rayleigh fading channels confirm that the closed-form solution matches numerical optimization to machine precision and demonstrate superior target-tracking performance compared to waterfilling, uniform allocation, and proportional fairness across a range of operating conditions.

Keywords

Cite

@article{arxiv.2603.06893,
  title  = {Target-Rate Least-Squares Power Allocation over Parallel Channels},
  author = {Bhaskar Krishnamachari},
  journal= {arXiv preprint arXiv:2603.06893},
  year   = {2026}
}

Comments

20 pages, 9 figures

R2 v1 2026-07-01T11:08:01.432Z