Randomness Efficient Fast-Johnson-Lindenstrauss Transform with Applications in Differential Privacy and Compressed Sensing

Abstract

The Johnson-Lindenstrauss property ( JLP) of random matrices has immense application in computer science ranging from compressed sensing, learning theory, numerical linear algebra, to privacy. This paper explores the properties and applications of a distribution of random matrices. Our distribution satisfies JLP with desirable properties like fast matrix-vector multiplication, sparsity, and optimal subspace embedding. We can sample a random matrix from this distribution using exactly 2n+n n random bits. We show that a random matrix picked from this distribution preserves differential privacy under the condition that the input private matrix satisfies certain spectral property. This improves the run-time of various differentially private mechanisms like Blocki et al. (FOCS 2012) and Upadhyay (ASIACRYPT 13). Our final construction has a bounded column sparsity. Therefore, this answers an open problem stated in Blocki et al. (FOCS 2012). Using the results of Baranuik et al. (Constructive Approximation: 28(3)), our result implies a randomness efficient matrices that satisfies the Restricted-Isometry Property of optimal order for small sparsity with exactly linear random bits. We also show that other known distributions of sparse random matrices with the JLP does not preserves differential privacy; thereby, answering one of the open problem posed by Blocki et al. (FOCS 2012). Extending on the works of Kane and Nelson (JACM: 61(1)), we also give unified analysis of some of the known Johnson-Lindenstrauss transform. We also present a self-contained simplified proof of an inequality on quadratic form of Gaussian variables that we use in all our proofs.