Stable low-rank matrix recovery from 3-designs
Abstract
We study the recovery of low-rank Hermitian matrices from rank-one measurements obtained by uniform sampling from complex projective 3-designs, using nuclear-norm minimization. This framework includes phase retrieval as a special case via the PhaseLift method. In general, complex projective t-designs provide a practical means of partially derandomizing Gaussian measurement models. While near-optimal recovery guarantees are known for 4-designs, and it is known that 2-designs do not permit recovery with a subquadratic number of measurements, the case of 3-designs has remained open. In this work, we close this gap by establishing recovery guarantees for (exact and approximate) 3-designs that parallel the best-known results for 4-designs. In particular, we derive bounds on the number of measurements sufficient for stable and robust low-rank recovery via nuclear-norm minimization. Our results are especially relevant in practice, as explicit constructions of 4-designs are significantly more challenging than those of 3-designs.
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