Tomas E. Matthews scite author profile

The pleasurable desire to move to music, also known as groove, is modulated by rhythmic complexity. How the sensation of groove is influenced by other musical features, such as the harmonic complexity of individual chords, is less clear. To address this, we asked people with a range of musical experience to rate stimuli that varied in both rhythmic and harmonic complexity. Rhythm showed an inverted U-shaped relationship with ratings of pleasure and wanting to move, whereas medium and low complexity chords were rated similarly. Pleasure mediated the effect of harmony on wanting to move and high complexity chords attenuated the effect of rhythm on pleasure. We suggest that while rhythmic complexity is the primary driver, harmony, by altering emotional valence, modulates the attentional and temporal prediction processes that underlie rhythm perception. Investigation of the effects of musical training with both regression and group comparison showed that training increased the inverted U effect for harmony and rhythm, respectively. Taken together, this work provides important new information about how the prediction and entrainment processes involved in rhythm perception interact with musical pleasure.

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The sensation of groove engages motor and reward networks

Matthews

et al. 2020

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The Impact of Instrument-Specific Musical Training on Rhythm Perception and Production

et al. 2016

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Studies comparing musicians and non-musicians have shown that musical training can improve rhythmic perception and production. These findings tell us that training can result in rhythm processing advantages, but they do not tell us whether practicing a particular instrument could lead to specific effects on rhythm perception or production. The current study used a battery of four rhythm perception and production tasks that were designed to test both higher- and lower-level aspects of rhythm processing. Four groups of musicians (drummers, singers, pianists, string players) and a control group of non-musicians were tested. Within-task differences in performance showed that factors such as meter, metrical complexity, tempo, and beat phase significantly affected the ability to perceive and synchronize taps to a rhythm or beat. Musicians showed better performance on all rhythm tasks compared to non-musicians. Interestingly, our results revealed no significant differences between musician groups for the vast majority of task measures. This was despite the fact that all musicians were selected to have the majority of their training on the target instrument, had on average more than 10 years of experience on their instrument, and were currently practicing. These results suggest that general musical experience is more important than specialized musical experience with regards to perception and production of rhythms.

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The sensation of groove is affected by the interaction of rhythmic and harmonic complexity

Matthews

Witek

Heggli

et al. 2018

Preprint

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48Groove is defined as the pleasurable desire to move to music. Research has shown that 49 rhythmic complexity modulates the sensation of groove but how other musical features, such as 50 harmony, influence groove is less clear. To address this, we asked people with a range of musical 51 experience to rate stimuli that varied in both rhythmic and harmonic complexity. Rhythm 52 showed an inverted U-shaped relationship with ratings of pleasure and wanting to move, whereas 53 medium and low complexity chords were rated similarly. Pleasure mediated the effect of 54 harmony on wanting to move and high complexity chords attenuated the effect of rhythm. While 55 rhythmic complexity is the primary driver, harmony both modulates the effect of rhythm and 56 makes a unique contribution via its effect on pleasure. These results may be accounted for by 57 predictive processes based on rhythmic and harmonic expectancies that are known to contribute 58 to musical pleasure or reward.When listening to music we often find ourselves tapping or moving along to the beat. 93 This has led to the study of groove, which is the pleasurable desire to move to music [1][2][3]. 94 Certain types of music are more likely to induce the sensation of groove than others. However, 95 which specific aspects of music contribute to this sensation is less clear. Research on groove has 96 focused on rhythmic complexity, and syncopation in particular, showing an inverted U-shaped 97 relationship between degree of syncopation and ratings of pleasure and wanting to move [3]. 98 That is, medium levels of syncopation are rated higher than low or high levels. This research has 99 largely examined rhythm in isolation, but other musical properties likely contribute to the 100 sensation of groove. Harmony in particular may be a strong contributor because it modulates 101 affective responses [4]. However, the extent to which harmony affects groove has not been 102 investigated. Furthermore, few studies have examined the impact of musical training on the 103 sensation of groove. Therefore, in the current study we developed a set of rhythmic stimuli that 104 varied in both their degree of rhythmic and harmonic complexity. We asked people with a broad 105 range of musical training to listen to and rate how much the stimuli made them want to move and 106 how much pleasure they experienced. Our goals were to investigate whether harmonic 107 complexity and its interaction with rhythm affects the sensation of groove. In addition, we 108 investigated the effects of rhythmic complexity and musical training on groove. 109

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The sweet spot between predictability and surprise: musical groove in brain, body, and social interactions

et al. 2022

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Groove—defined as the pleasurable urge to move to a rhythm—depends on a fine-tuned interplay between predictability arising from repetitive rhythmic patterns, and surprise arising from rhythmic deviations, for example in the form of syncopation. The perfect balance between predictability and surprise is commonly found in rhythmic patterns with a moderate level of rhythmic complexity and represents the sweet spot of the groove experience. In contrast, rhythms with low or high complexity are usually associated with a weaker experience of groove because they are too boring to be engaging or too complex to be interpreted, respectively. Consequently, the relationship between rhythmic complexity and groove experience can be described by an inverted U-shaped function. We interpret this inverted U shape in light of the theory of predictive processing and provide perspectives on how rhythmic complexity and groove can help us to understand the underlying neural mechanisms linking temporal predictions, movement, and reward. A better understanding of these mechanisms can guide future approaches to improve treatments for patients with motor impairments, such as Parkinson’s disease, and to investigate prosocial aspects of interpersonal interactions that feature music, such as dancing. Finally, we present some open questions and ideas for future research.

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Tomas E. Matthews

The sensation of groove is affected by the interaction of rhythmic and harmonic complexity

The sensation of groove engages motor and reward networks

The Impact of Instrument-Specific Musical Training on Rhythm Perception and Production

The sensation of groove is affected by the interaction of rhythmic and harmonic complexity

The sweet spot between predictability and surprise: musical groove in brain, body, and social interactions

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