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1. Musical expertise generalizes to superior temporal scaling in a Morse code tapping task

Author

Indre V. Viskontas, Matthew A. Slayton, Katrina Shore, Dean V. Buonomano, and Juan L. Romero-Sosa

Subjects

Male, InformationSystems_INFORMATIONINTERFACESANDPRESENTATION(e.g.,HCI), Computer science, Computer Vision, Speech recognition, Social Sciences, Musical, law.invention, Mathematical and Statistical Techniques, Learning and Memory, 0302 clinical medicine, law, Feature (machine learning), Psychology, Recurrent Neural Networks, 0303 health sciences, Sequence, Multidisciplinary, Physics, Statistics, Brain, Contrast (statistics), Physical Sciences, Auditory Perception, Medicine, Educational Status, Regression Analysis, Tapping, Female, Research Article, Adult, Computer and Information Sciences, Neural Networks, Science, Linear Regression Analysis, Research and Analysis Methods, Morse code, 03 medical and health sciences, Learning, Humans, Statistical Methods, Scaling, 030304 developmental biology, Music Cognition, Cognitive Psychology, Biology and Life Sciences, Acoustics, Target Detection, Task (computing), Acoustic Stimulation, People and Places, Animal Studies, Linear Models, Cognitive Science, Population Groupings, Bioacoustics, Undergraduates, Mathematics, Music, Psychomotor Performance, 030217 neurology & neurosurgery, Neuroscience

Abstract

A key feature of the brain's ability to tell time and generate complex temporal patterns is its capacity to produce similar temporal patterns at different speeds. For example, humans can tie a shoe, type, or play an instrument at different speeds or tempi-a phenomenon referred to as temporal scaling. While it is well established that training improves timing precision and accuracy, it is not known whether expertise improves temporal scaling, and if so, whether it generalizes across skill domains. We quantified temporal scaling and timing precision in musicians and non-musicians as they learned to tap a Morse code sequence. We found that non-musicians improved significantly over the course of days of training at the standard speed. In contrast, musicians exhibited a high level of temporal precision on the first day, which did not improve significantly with training. Although there was no significant difference in performance at the end of training at the standard speed, musicians were significantly better at temporal scaling-i.e., at reproducing the learned Morse code pattern at faster and slower speeds. Interestingly, both musicians and non-musicians exhibited a Weber-speed effect, where temporal precision at the same absolute time was higher when producing patterns at the faster speed. These results are the first to establish that the ability to generate the same motor patterns at different speeds improves with extensive training and generalizes to non-musical domains.

Published

2019