Computing optimal discrete readout weights in reservoir computing is NP-hard

Abstract

We show NP-hardness of a generalized quadratic programming problem, which we called Unconstrained N-ary Quadratic Programming (UNQP). This problem has recently become practically relevant in the context of novel memristor-based neuromorphic microchip designs, where solving the UNQP is a key operation for on-chip training of the neural network implemented on the chip. UNQP is the problem of finding a vector v ∈ SN which minimizes vT\,Q\,v +vT c , where S = \s1, …, sn\ ⊂ Z is a given set of eligible parameters for v, Q ∈ ZN × N is positive semi-definite, and c ∈ ZN. In memristor-based neuromorphic hardware, S is physically given by a finite (and small) number of possible memristor states. The proof of NP-hardness is by reduction from the Unconstrained Binary Quadratic Programming problem, which is a special case of UNQP where S = \0, 1\ and which is known to be NP-hard.