Author_Institution :
Dept. of Electr. & Comput. Eng., California Univ., San Diego, La Jolla, CA, USA
Abstract :
Let (Y,X)={Y(t),X(t),-∞<t<∞} be real-valued continuous-time jointly stationary processes and let (tj) be a renewal point processes on (0,∞), with a finite mean rate, independent of (Y,X). We consider the estimation of regression function r(x0, x1,...,xm-1; τ1,...,τm) of ψ(Y(τm)) given (X(0)=x0, X(τ1)=x1,...,X(τm-1)=x-1 ) for arbitrary lags 0<τ1<...< τm on the basis of the discrete-time observations {Y(tj),X(tj),tj)j=1n . We estimate the regression function and all its partial derivatives up to a total order p⩾1 using high-order local polynomial fitting. We establish the weak consistency of such estimates along with rates of convergence. We also establish the joint asymptotic normality of the estimates for the regression function and all its partial derivatives up to a total order p⩾1 and provide explicit expressions for the bias and covariance matrix (of the asymptotically normal distribution)
Keywords :
convergence of numerical methods; covariance matrices; functional analysis; normal distribution; parameter estimation; polynomials; signal sampling; statistical analysis; asymptotically normal distribution; bias; convergence rates; covariance matrix; data analysis; discrete-time observations; explicit expressions; finite mean rate; high-order local polynomial fitting; joint asymptotic normality; local polynomial fitting approach; multivariate regression estimation; partial derivatives; real-valued continuous-time stationary processes; regression function estimation; renewal point processes; sampled data; weak consistency; Communication system control; Control systems; Convergence; Covariance matrix; Data analysis; Filtering; Gaussian distribution; Multivariate regression; Polynomials; Sampling methods;
