Timing at peak force may be the hidden target controlled in continuation and synchronization tapping
Timing at peak force may be the hidden target controlled in continuation and synchronization tapping
Timing control, such as producing movements at a given rate or synchronizing movements to an external event, has been studied through a finger-tapping task where timing is measured at the initial contact between finger and tapping surface or the point when a key is pressed. However, the point of peak force is after the time registered at the tapping surface and thus is a less obvious but still important event during finger tapping. Here, we compared the time at initial contact with the time at peak force as participants tapped their finger on a force sensor at a given rate after the metronome was turned off (continuation task) or in synchrony with the metronome (sensorimotor synchronization task). We found that, in the continuation task, timing was comparably accurate between initial contact and peak force. These two timing events also exhibited similar trial-by-trial statistical dependence (i.e., lag-one autocorrelation). However, the central clock variability was lower at the peak force than the initial contact. In the synchronization task, timing control at peak force appeared to be less variable and more accurate than that at initial contact. In addition to lower central clock variability, the mean SE magnitude at peak force (SEP) was around zero while SE at initial contact (SEC) was negative. Although SEC and SEP demonstrated the same trial-by-trial statistical dependence, we found that participants adjusted the time of tapping to correct SEP, but not SEC, toward zero. These results suggest that timing at peak force is a meaningful target of timing control, particularly in synchronization tapping. This result may explain the fact that SE at initial contact is typically negative as widely observed in the preexisting literature.
continuation tapping, sensorimotor synchronization, timing at peak force, timing at initial contact, negative synchronization error, timing variability
Du, Yue
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Clark, Jane E.
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Whitall, Jill
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Du, Yue
2a5c8dca-a1b1-4a63-94cc-9cd211f0fcea
Clark, Jane E.
d5c0297c-431e-4880-b61c-b87d7611f3cb
Whitall, Jill
9761aefb-be80-4270-bc1f-0e726399376e
Du, Yue, Clark, Jane E. and Whitall, Jill
(2017)
Timing at peak force may be the hidden target controlled in continuation and synchronization tapping.
Experimental Brain Research.
(doi:10.1007/s00221-017-4918-3).
Abstract
Timing control, such as producing movements at a given rate or synchronizing movements to an external event, has been studied through a finger-tapping task where timing is measured at the initial contact between finger and tapping surface or the point when a key is pressed. However, the point of peak force is after the time registered at the tapping surface and thus is a less obvious but still important event during finger tapping. Here, we compared the time at initial contact with the time at peak force as participants tapped their finger on a force sensor at a given rate after the metronome was turned off (continuation task) or in synchrony with the metronome (sensorimotor synchronization task). We found that, in the continuation task, timing was comparably accurate between initial contact and peak force. These two timing events also exhibited similar trial-by-trial statistical dependence (i.e., lag-one autocorrelation). However, the central clock variability was lower at the peak force than the initial contact. In the synchronization task, timing control at peak force appeared to be less variable and more accurate than that at initial contact. In addition to lower central clock variability, the mean SE magnitude at peak force (SEP) was around zero while SE at initial contact (SEC) was negative. Although SEC and SEP demonstrated the same trial-by-trial statistical dependence, we found that participants adjusted the time of tapping to correct SEP, but not SEC, toward zero. These results suggest that timing at peak force is a meaningful target of timing control, particularly in synchronization tapping. This result may explain the fact that SE at initial contact is typically negative as widely observed in the preexisting literature.
Text
Timing at peak force may be the hidden target controlled in continuation and synchronization tapping
- Accepted Manuscript
More information
Accepted/In Press date: 14 February 2017
e-pub ahead of print date: 2 March 2017
Keywords:
continuation tapping, sensorimotor synchronization, timing at peak force, timing at initial contact, negative synchronization error, timing variability
Organisations:
Researcher Development
Identifiers
Local EPrints ID: 406236
URI: http://eprints.soton.ac.uk/id/eprint/406236
ISSN: 0014-4819
PURE UUID: b7f6152e-7f3b-4e29-891e-eb947abc3b17
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Date deposited: 10 Mar 2017 10:43
Last modified: 16 Mar 2024 05:05
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Contributors
Author:
Yue Du
Author:
Jane E. Clark
Author:
Jill Whitall
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