Multivariate inhomogeneous diffusion models with covariates and mixed effects

Abstract

Modeling of longitudinal data often requires diffusion models that incorporate overall time-dependent, nonlinear dynamics of multiple components and provide sufficient flexibility for subject-specific modeling. This complexity challenges parameter inference and approximations are inevitable. We propose a method for approximate maximum-likelihood parameter estimation in multivariate time-inhomogeneous diffusions, where subject-specific flexibility is accounted for by incorporation of multidimensional mixed effects and covariates. We consider N multidimensional independent diffusions Xi = (Xit)0≤ t≤ Ti, 1≤ i≤ N, with common overall model structure and unknown fixed-effects parameter μ. Their dynamics differ by the subject-specific random effect φi in the drift and possibly by (known) covariate information, different initial conditions and observation times and duration. The distribution of φi is parametrized by an unknown and θ = (μ, ) is the target of statistical inference. Its maximum likelihood estimator is derived from the continuous-time likelihood. We prove consistency and asymptotic normality of θN when the number N of subjects goes to infinity using standard techniques and consider the more general concept of local asymptotic normality for less regular models. The bias induced by time-discretization of sufficient statistics is investigated. We discuss verification of conditions and investigate parameter estimation and hypothesis testing in simulations.