We consider abstractly defined time series arrays y
t(T), 1 \le t\le T, requiring only that
their sample lagged second moments converge and that their end values
y1+j(T) and
yT-j(T) be of order less than
T½ for each j \ge 0. We show that,under quite
general assumptions, various types of arrays that arise naturally in time
series analysis have these properties,including regression residuals from a
time series regression, seasonal adjustments and infinite variance processes
rescaled by their sample standard deviation. We establish a useful uniform
convergence result,namely that these properties are preserved in a uniform way
when relatively compact sets of absolutely summable filters are applied to the
arrays. This result serves as the foundation for the proof, in a companion
paper by Findley, Pötscher and Wei, of the consistency of parameter
estimates specified to minimize the sample mean squared multistep-ahead
forecast error when invertible short-memory models are fit to (short- or
long-memory)time series or time series arrays.
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