TY - JOUR
T1 - Methodological Advances for Detecting Physiological Synchrony During Dyadic Interactions
AU - McAssey, M.P.
AU - Helm, J.
AU - Hsieh, F.
AU - Sbarra, D.
AU - Ferrer, E.
PY - 2011
Y1 - 2011
N2 - A defining feature of many physiological systems is their synchrony and reciprocal influence. An important challenge, however, is how to measure such features. This paper presents two new approaches for identifying synchrony between the physiological signals of individuals in dyads. The approaches are adaptations of two recently-developed techniques, depending on the nature of the physiological time series. For respiration and thoracic impedance, signals that are measured continuously, we use Empirical Mode Decomposition to extract the lowfrequency components of a nonstationary signal, which carry the signal's trend. We then compute the maximum cross-correlation between the trends of two signals within consecutive overlapping time windows of fixed width throughout each of a number of experimental tasks, and identify the proportion of large values of this measure occurring during each task. For heart rate, which is output discretely, we use a structural linear model that takes into account heteroscedastic measurement error on both series. The results of this study indicate that these methods are effective in detecting synchrony between physiological measures and can be used to examine emotional coherence in dyadic interactions. © 2012 Hogrefe Publishing.
AB - A defining feature of many physiological systems is their synchrony and reciprocal influence. An important challenge, however, is how to measure such features. This paper presents two new approaches for identifying synchrony between the physiological signals of individuals in dyads. The approaches are adaptations of two recently-developed techniques, depending on the nature of the physiological time series. For respiration and thoracic impedance, signals that are measured continuously, we use Empirical Mode Decomposition to extract the lowfrequency components of a nonstationary signal, which carry the signal's trend. We then compute the maximum cross-correlation between the trends of two signals within consecutive overlapping time windows of fixed width throughout each of a number of experimental tasks, and identify the proportion of large values of this measure occurring during each task. For heart rate, which is output discretely, we use a structural linear model that takes into account heteroscedastic measurement error on both series. The results of this study indicate that these methods are effective in detecting synchrony between physiological measures and can be used to examine emotional coherence in dyadic interactions. © 2012 Hogrefe Publishing.
U2 - 10.1027/1614-2241/a000053
DO - 10.1027/1614-2241/a000053
M3 - Article
SN - 1614-1881
SP - 1
EP - 13
JO - Methodology: European Journal of Research Methods for the Behavioral and Social Sciences
JF - Methodology: European Journal of Research Methods for the Behavioral and Social Sciences
ER -