Correlation techniques offer a good possibility for contactless measurement of the velocity of solid surfaces. The system presented consists of an optical sensor unit, which transforms the stochastic roughness of the object into two signals with a delay time /spl tau/*, and of a correlation unit, which extracts the delay time from the signals and calculates the velocity of the surface. The main algorithm of that digital correlator, representing an identification problem of the delay time /spl tau/*, is realized by a closed-loop with the advantage of estimating only one point of the correlation function. The dynamic response is mainly dependent on the bandwidth of the sensor signals and the sampling frequency of the correlator, but not on its arithmetic speed. The mathematical description of the correlator is discussed both in the time domain and the, z-domain. Based on a linearized system, this allows one to determine the dynamic response and the stability of the closed-loop correlator. Two different applications are presented: the measurement of the velocity of paper webs and the measurement of the length of textile yarns during a winding process.