English

Robust Interference Management for SISO Systems with Multiple Over-the-Air Computations

Information Theory 2020-04-22 v1 Information Retrieval Machine Learning math.IT

Abstract

In this paper, we consider the over-the-air computation of sums. Specifically, we wish to compute M2M\geq 2 sums sm=kDmxks_m=\sum_{k\in\mathcal{D}m}x_k over a shared complex-valued MAC at once with minimal mean-squared error (MSE\mathsf{MSE}). Finding appropriate Tx-Rx scaling factors balance between a low error in the computation of sns_n and the interference induced by it in the computation of other sums sms_m, mnm\neq n. In this paper, we are interested in designing an optimal Tx-Rx scaling policy that minimizes the mean-squared error maxm[1:M]MSEm\max_{m\in[1:M]}\mathsf{MSE}_m subject to a Tx power constraint with maximum power PP. We show that an optimal design of the Tx-Rx scaling policy (aˉ,bˉ)\left(\bar{\mathbf{a}},\bar{\mathbf{b}}\right) involves optimizing (a) their phases and (b) their absolute values in order to (i) decompose the computation of MM sums into, respectively, MRM_R and MIM_I (M=MR+MIM=M_R+M_I) calculations over real and imaginary part of the Rx signal and (ii) to minimize the computation over each part -- real and imaginary -- individually. The primary focus of this paper is on (b). We derive conditions (i) on the feasibility of the optimization problem and (ii) on the Tx-Rx scaling policy of a local minimum for Mw=2M_w=2 computations over the real (w=Rw=R) or the imaginary (w=Iw=I) part. Extensive simulations over a single Rx chain for Mw=2M_w=2 show that the level of interference in terms of ΔD=D2D1\Delta D=|\mathcal{D}_2|-|\mathcal{D}_1| plays an important role on the ergodic worst-case MSE\mathsf{MSE}. At very high SNR\mathsf{SNR}, typically only the sensor with the weakest channel transmits with full power while all remaining sensors transmit with less to limit the interference. Interestingly, we observe that due to residual interference, the ergodic worst-case MSE\mathsf{MSE} is not vanishing; rather, it converges to D1D2K\frac{|\mathcal{D}_1||\mathcal{D}_2|}{K} as SNR\mathsf{SNR}\rightarrow\infty.

Cite

@article{arxiv.2004.09906,
  title  = {Robust Interference Management for SISO Systems with Multiple Over-the-Air Computations},
  author = {Jaber Kakar and Aydin Sezgin},
  journal= {arXiv preprint arXiv:2004.09906},
  year   = {2020}
}
R2 v1 2026-06-23T14:59:35.570Z