We give a deterministic, nearly logarithmic-space algorithm for mild spectral sparsification of undirected graphs. Given a weighted, undirected graph $G$ on $n$ vertices described by a binary string of length $N$, an integer $kleq log n$, and an error parameter $epsilon > 0$, our algorithm runs in space $tilde{O}(klog (Ncdot w_{mathrm{max}}/w_{mathrm{min}}))$ where $w_{mathrm{max}}$ and $w_{mathrm{min}}$ are the maximum and minimum edge weights in $G$, and produces a weighted graph $H$ with $tilde{O}(n^{1+2/k}/epsilon^2)$ edges that spectrally approximates $G$, in the sense of Spielmen and Teng [ST04], up to an error of $epsilon$. Our algorithm is based on a new bounded-independence analysis of Spielman and Srivastavas effective resistance based edge sampling algorithm [SS08] and uses results from recent work on space-bounded Laplacian solvers [MRSV17]. In particular, we demonstrate an inherent tradeoff (via upper and lower bounds) between the amount of (bounded) independence used in the edge sampling algorithm, denoted by $k$ above, and the resulting sparsity that can be achieved.
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