Litcius/Paper detail

Euclidean Contractivity of Neural Networks With Symmetric Weights

Veronica Centorrino, Anand Gokhale, A. S. Davydov, Giovanni Russo, Francesco Bullo

2023IEEE Control Systems Letters10 citationsDOI

Abstract

This paper investigates stability conditions of continuous-time Hopfield and firing-rate neural networks by leveraging contraction theory. First, we present a number of useful general algebraic results on matrix polytopes and products of symmetric matrices. Then, we give sufficient conditions for strong and weak Euclidean contractivity, i.e., contractivity with respect to the ℓ2 norm, of both models with symmetric weights and (possibly) non-smooth activation functions. Our contraction analysis leads to contraction rates which are log-optimal in almost all symmetric synaptic matrices. Finally, we use our results to propose a firing-rate neural network model to solve a quadratic optimization problem with box constraints.

Topics & Concepts

PolytopeEuclidean geometryArtificial neural networkContraction (grammar)Euclidean distanceMathematicsQuadratic equationAlgebraic numberMatrix normSymmetric matrixMatrix (chemical analysis)Norm (philosophy)Pure mathematicsComputer scienceCombinatoricsMathematical analysisGeometryPhysicsArtificial intelligenceEigenvalues and eigenvectorsLawMaterials scienceComposite materialQuantum mechanicsMedicineInternal medicinePolitical scienceControl and Stability of Dynamical SystemsAdvanced Memory and Neural ComputingModel Reduction and Neural Networks