Editors' introduction: Fractional differencing and long memory processes

In this paper we present results of a simulation study to assess and compare the accuracy of forecasting techniques for long-memory processes in small sample sizes. We analyse dierences between adaptive ARMA(1,1) L-step forecasts, where the parameters are estimated by minimizing the sum of squares o

Field equations with time and coordinate derivatives of noninteger order are derived from a stationary action principle for the cases of power-law memory function and long-range interaction in systems. The method is applied to obtain a fractional generalization of the Ginzburg-Landau and nonlinear S

CCC 0270-731 41951050573-I 2 'The robustness to conditional heteroskedastic effects and variance shifts is crucial, since, as pointed out by Milonas et al. (1 985), results of futures price dynamics may be biased by variance nonstationarity.

This paper addresses the issues of maximum likelihood estimation and forecasting of a long-memory time series with missing values. A state-space representation of the underlying long-memory process is proposed. By incorporating this representation with the Kalman ®lter, the proposed method allows no

The long-memory Gaussian processes presented as the integrals Vt = t 0 h(t -s)'(s) dWs and Bt = t 0 (s) dVs are considered. The fractional Brownian motion is a particular case when '; ; h are the power functions. The integrals Vt are transformed into Gaussian martingales. The Girsanov theorem for Bt