Quantum matching pursuit: A quantum algorithm for sparse representations

Representing signals with sparse vectors has a wide spectrum of applications that ranges from image and video coding to shape representation and health monitoring. In many applications with real-time requirements or that deal with high-dimensional signals, the computational complexity of the encoder that finds the sparse representation plays an important role. Quantum computing has recently shown promising speedups in many representation learning tasks. In this work, we propose a quantum version of the well-known matching-pursuit algorithm. Assuming the availability of a fault-tolerant quantum random access memory, our quantum matching pursuit lowers the complexity of its classical counterpart by a polynomial factor, at the cost of some error in the computation of the inner products, enabling the computation of sparse representations of high-dimensional signals. Besides proving the computational complexity of our algorithm, we provide numerical experiments that show that its error is negligible in practice. This work opens the path to further research on quantum algorithms for finding sparse representations, showing suitable quantum computing applications in signal processing.