Open AccessParameterized Estimation of Long-Range Correlation and Variance Components in Human Serial Interval Production
Author(s) -
Ana Diniz,
João Barreiros,
Nuno Crato
Publication year - 2010
Publication title -
motor control
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.514
H-Index - 46
eISSN - 1543-2696
pISSN - 1087-1640
DOI - 10.1123/mcj.14.1.26
Subject(s) - autocorrelation , estimator , component (thermodynamics) , range (aeronautics) , parameterized complexity , finger tapping , mathematics , parametric statistics , white noise , function (biology) , computer science , maximization , noise (video) , tapping , interval (graph theory) , algorithm , statistics , artificial intelligence , mathematical optimization , acoustics , engineering , medicine , physics , evolutionary biology , biology , audiology , image (mathematics) , thermodynamics , combinatorics , aerospace engineering
Repetitive movements lead to isochronous serial interval production which exhibit inherent variability. The Wing-Kristofferson model offers a decomposition of the interresponse intervals in tapping tasks based on a cognitive component and on a motor component. We suggest a new theoretical and fully parametric approach to this model in which the cognitive component is modeled as a long-memory process and the motor component is treated as a white noise process, mutually independent. Under these assumptions, we obtained the autocorrelation function and the spectral density function. Furthermore, we propose an estimator based on the maximization of the frequency-domain representation of the likelihood function. Finally, we conducted a simulation study to assess the properties of this estimator and performed an experimental study involving tapping tasks with two target frequencies (1.250 Hz and 0.625 Hz).
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