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In the problem of adaptive compressed sensing, one wants to estimate an approximately $k$-sparse vector $xinmathbb{R}^n$ from $m$ linear measurements $A_1 x, A_2 x,ldots, A_m x$, where $A_i$ can be chosen based on the outcomes $A_1 x,ldots, A_{i-1} x$ of previous measurements. The goal is to output a vector $hat{x}$ for which $$|x-hat{x}|_p le C cdot min_{ktext{-sparse } x} |x-x|_q,$$ with probability at least $2/3$, where $C > 0$ is an approximation factor. Indyk, Price and Woodruff (FOCS11) gave an algorithm for $p=q=2$ for $C = 1+epsilon$ with $Oh((k/epsilon) loglog (n/k))$ measurements and $Oh(log^*(k) loglog (n))$ rounds of adaptivity. We first improve their bounds, obtaining a scheme with $Oh(k cdot loglog (n/k) +(k/epsilon) cdot loglog(1/epsilon))$ measurements and $Oh(log^*(k) loglog (n))$ rounds, as well as a scheme with $Oh((k/epsilon) cdot loglog (nlog (n/k)))$ measurements and an optimal $Oh(loglog (n))$ rounds. We then provide novel adaptive compressed sensing schemes with improved bounds for $(p,p)$ for every $0 < p < 2$. We show that the improvement from $O(k log(n/k))$ measurements to $O(k log log (n/k))$ measurements in the adaptive setting can persist with a better $epsilon$-dependence for other values of $p$ and $q$. For example, when $(p,q) = (1,1)$, we obtain $O(frac{k}{sqrt{epsilon}} cdot log log n log^3 (frac{1}{epsilon}))$ measurements.
We introduce a recursive algorithm for performing compressed sensing on streaming data. The approach consists of a) recursive encoding, where we sample the input stream via overlapping windowing and make use of the previous measurement in obtaining t
The 1-bit compressed sensing framework enables the recovery of a sparse vector x from the sign information of each entry of its linear transformation. Discarding the amplitude information can significantly reduce the amount of data, which is highly b
We characterize the measurement complexity of compressed sensing of signals drawn from a known prior distribution, even when the support of the prior is the entire space (rather than, say, sparse vectors). We show for Gaussian measurements and emph{a
In the compressive phase retrieval problem, or phaseless compressed sensing, or compressed sensing from intensity only measurements, the goal is to reconstruct a sparse or approximately $k$-sparse vector $x in mathbb{R}^n$ given access to $y= |Phi x|
Long-range correlated errors can severely impact the performance of NISQ (noisy intermediate-scale quantum) devices, and fault-tolerant quantum computation. Characterizing these errors is important for improving the performance of these devices, via