ERP predictors of individual performance on a prospective temporal reproduction task

In the domain of aesthetic preference, previous studies focused primarily on exploring the factors that influence aesthetic preference while neglecting to investigate whether aesthetic preference affects other psychological activities. This study sought to expand our understanding of time perception by examining whether aesthetic preference in viewing paintings influenced its perceived duration. Participants who preferred Chinese paintings ( n = 20) and participants who preferred western paintings ( n = 21) were recruited to complete a temporal reproduction task that measured their time perception of Chinese paintings and of western paintings. The results showed that participants who preferred Chinese paintings exhibited longer time perceptions for Chinese paintings than for western paintings, while the participants who preferred western paintings exhibited longer time perceptions for western paintings than for Chinese paintings. These results suggested that aesthetic preference could modulate our perceived duration of painting presentation. Specifically, individuals perceive longer painting presentation durations when exposed to the stimuli matching their aesthetic preferences.

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Effect of Acute Physical Activity on Interval Timing

Timing & Time Perception ◽

10.1163/22134468-00002098 ◽

2018 ◽

Vol 6 (1) ◽

pp. 14-31 ◽

Cited By ~ 1

Author(s):

Ceyda Sayalı ◽

Ezgi Uslu ◽

Melisa Menceloğlu ◽

Reşit Canbeyli ◽

Fuat Balcı

Keyword(s):

Physical Activity ◽

Temporal Integration ◽

Interval Timing ◽

Subjective Time ◽

Reproduction Task ◽

Movement Condition ◽

Temporal Reproduction ◽

Long Term Performance ◽

Term Performance ◽

Larger Sample

Timing is an integral part of physical activities. Walking as a routine form of physical activity might affect interval timing primarily in two different ways within the pacemaker–accumulator timing-theoretic framework: (1) by increasing the speed of the pacemaker due to its physiological effects; (2) by decreasing attention to time and consequently slowing the rate of temporal integration by serving as a secondary task. In order to elucidate the effect of movement on subjective time, in two different experiments we employed a temporal reproduction task conducted on the treadmill under four different encoding–decoding conditions: (1) encoding and reproducing (decoding) the duration while standing (rest); (2) encoding the duration at rest and reproducing it while moving: (3) both encoding and reproducing the duration while moving; and (4) encoding the duration while moving and reproducing it at rest. In the first experiment, participants were tested either in the 4 or the 8 km/h movement condition, whereas in the second experiment a larger sample was tested only in the 4 km/h movement condition. Data were de-trended to control for long-term performance drifts. In Experiment 1, overall durations encoded at rest and reproduced during motion were under-reproduced whereas durations encoded during motion and reproduced at rest were over-reproduced only in the 8 km/h condition. In Experiment 2, the same results were observed in the 4 km/h condition with a larger sample size. These effects on timing behavior provide support for the clock speed-driven effect of movement and contradicts the predictions of attention-based mediation.

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Temporal-Signal Detection and Individual Differences in Timing

Perception ◽

10.1068/p240525 ◽

1995 ◽

Vol 24 (5) ◽

pp. 525-538 ◽

Cited By ~ 18

Author(s):

Scott W Brown ◽

Damon C Newcomb ◽

Kathleen G Kahrl

Keyword(s):

Individual Differences ◽

Signal Detection ◽

High Sensitivity ◽

Target Duration ◽

Detection Task ◽

Reproduction Task ◽

Temporal Reproduction ◽

Low Sensitivity ◽

Improved Accuracy ◽

Judgment Data

Signal-detection procedures were used in three experiments to examine sensitivity and bias in time judgments and to evaluate individual differences in timing. The task required subjects to judge whether visual stimuli were presented for a certain target duration (the ‘signal’) or for a slightly longer duration. In experiment 1, subjects performed versions of the task involving both short (2 s) and long (12 s) target stimuli. Analyses of sensitivity and bias measures ( d' and β) provided evidence for consistency in timing performance within individuals. In experiment 2, subjects were tested on a detection task with 5, 10, or 15 s targets, followed by a temporal-reproduction task involving stimulus durations ranging from 3 to 17 s. Subjects with high temporal sensitivity showed less error in their reproductions than subjects with low temporal sensitivity. In experiment 3, subjects were pretested on a detection task with a 12 s target and then performed a temporal-production task where they attempted to generate a series of 12 s intervals under either control or informational feedback conditions. Feedback improved accuracy and reduced variability in temporal productions. However, the low-temporal-sensitivity subjects were more variable in their responses under both conditions than were the high-sensitivity subjects. The results point to the utility of a temporal-signal-detection task both as a means for studying individual differences in timing and as a pretesting technique for assigning subjects to high-sensitivity and low-sensitivity groups to reduce error in time-judgment data.

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Dopaminergic Modulation of Motor Timing in Healthy Volunteers Differs as a Function of Baseline DA Precursor Availability

Timing & Time Perception ◽

10.1163/22134468-00002005 ◽

2013 ◽

Vol 1 (1) ◽

pp. 77-98 ◽

Cited By ~ 6

Author(s):

Jennifer T. Coull ◽

Hye J. Hwang ◽

Marco Leyton ◽

Alain Dagher

Keyword(s):

Healthy Volunteers ◽

Time Interval ◽

Motor Timing ◽

Reproduction Task ◽

Migration Effect ◽

Temporal Reproduction ◽

Testing Block ◽

Paradoxical Effects ◽

Tyrosine Depletion ◽

Baseline Levels

Although numerous experiments in patients and animals implicate the dopamine (DA) system in timing, there are relatively few studies examining this effect in healthy volunteers. Moreover, the majority of these studies employed tasks of perceptual timing. We therefore investigated the DA modulation of motor timing in healthy volunteers using Acute Phenylalanine/Tyrosine Depletion (APTD), an amino-acid drink that reduces concentrations of the DA precursors tyrosine and phenylalanine. We also examined how APTD’s effects on timing might differ as a function of underlying DA function, as indexed by baseline levels of DA precursors. 18 healthy volunteers performed a Mixed Temporal Reproduction task, in which reproduction of five different sample durations (500 ms–1500 ms) were tested within a single testing block. Reproduction times conformed to Vierordt’s Law, such that the shortest durations were overestimated and the longest ones underestimated. Yet contrary to reported effects in Parkinson’s disease, we found no DA modulation of this ‘migration’ effect in our healthy volunteers. Instead, APTD produced systematic shifts in reproduction time across all durations. However, the direction of the shift differed according to individual differences in baseline levels of DA precursor availability. Specifically, APTD slowed reproduction times in participants with low baseline DA precursor levels whereas it speeded them in participants with high baseline levels. These apparently paradoxical effects can be reconciled in terms of the inverted U-shaped relationship between DA function and cognition. Finally, APTD had no effect on a test of temporal production in which participants were asked to provide spontaneous estimates of a one-second time interval. The differential effect of APTD on the reproduction versus production tasks suggests DA modulates the magnitude of the duration initially encoded into working memory, rather than clock-speed.

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Abstracting time in memory

10.31234/osf.io/478cx ◽

2021 ◽

Author(s):

Sophie K Herbst ◽

Izem Mangione ◽

Tadeusz Kononowicz ◽

Virginie van Wassenhove

Keyword(s):

Working Memory ◽

Delay Period ◽

Abstract Representation ◽

Time Intervals ◽

Reproduction Task ◽

Elapsed Time ◽

Temporal Reproduction ◽

The Future ◽

Empty Time

Planning the future relies on the ability to remember how long events last, yet, how durations are stored in memory is unknown. Here, we developed a novel n-item delayed duration reproduction task to assess whether elapsed time is stored as a continuous feature or as an abstract item in memory. In three experiments (N = 58), participants listened to non-rhythmic sequences composed of empty time intervals (durations), which they had to reproduce as precisely as possible following a delay period. We manipulated the number of time intervals (n-item) and the overall sequence duration to separate their effects on recall precision. The precision of temporal reproduction systematically decreased with an increasing number of items. Our results suggest that the number of time intervals, not their duration, determines recall precision. We interpret this as evidence towards an abstract representation of duration in working memory.

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Visual reproduction test in normal elderly: Influence of schooling and visual task complexity

Dementia & Neuropsychologia ◽

10.1590/s1980-57642012dn06020005 ◽

2012 ◽

Vol 6 (2) ◽

pp. 91-96 ◽

Cited By ~ 2

Author(s):

Paulo Roberto de Brito-Marques ◽

José Eulálio Cabral-Filho ◽

Rafael Moura Miranda

Keyword(s):

Visual Memory ◽

Task Complexity ◽

Individual Performance ◽

Visual Task ◽

Reproduction Task ◽

Clinical Evaluations ◽

Significant Difference ◽

Reproduction Test ◽

High Degree ◽

Years Of Schooling

ABSTRACT Tests of visual reproduction are used to assess visual memory. However, when the test is based on geometrical elements results could be influenced by schooling. Objective: To evaluate the influence of different schooling levels on performance of a visual reproduction task. Methods: A sample of 253 individuals (66 male and 187 female), aged 60 to 92 years were evaluated on a visual reproduction task comprising three geometric pictures of increasing complexity. Each individual was shown a picture for 8 to10 seconds and a drawing of it was then immediately elicited. Four groups were defined according to the following schooling levels: illiterate, 1 to 4 years, 5 to 8 years and over 8 years. Individual performance was measured by summing the items correctly reproduced for the three pictures. Results: A significant difference for age was found between the illiterate and other three schooling groups. The reproduction of picture one was better reproduced than pictures 2 and 3 for all schooling levels (p<0.001). Pictures 2 and 3 did not differ among the schooling levels. Picture reproduction among the schooling levels showed that the group with over 8 years of schooling performed better on pictures 1 and 2 (p<0.001) but not on picture 3. Conclusion: Individuals aged 60 years or older, with 8 years' schooling or less, showed a reduced capacity to reproduce geometric pictures of a high degree of complexity. Clinical evaluations that use geometrical tests could be misinterpreted when not controlled for schooling level.

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Different Brain Circuits Underlie Motor and Perceptual Representations of Temporal Intervals

Journal of Cognitive Neuroscience ◽

10.1162/jocn.2008.20017 ◽

2008 ◽

Vol 20 (2) ◽

pp. 204-214 ◽

Cited By ~ 89

Author(s):

Domenica Bueti ◽

Vincent Walsh ◽

Chris Frith ◽

Geraint Rees

Keyword(s):

Parietal Cortex ◽

Brain Activity ◽

Premotor Cortex ◽

Temporal Information ◽

Extrastriate Cortex ◽

Reproduction Task ◽

Temporal Reproduction ◽

Temporal Intervals ◽

Temporal Estimation ◽

The Right

In everyday life, temporal information is used for both perception and action, but whether these two functions reflect the operation of similar or different neural circuits is unclear. We used functional magnetic resonance imaging to investigate the neural correlates of processing temporal information when either a motor or a perceptual representation is used. Participants viewed two identical sequences of visual stimuli and used the information differently to perform either a temporal reproduction or a temporal estimation task. By comparing brain activity evoked by these tasks and control conditions, we explored commonalities and differences in brain areas involved in reproduction and estimation of temporal intervals. The basal ganglia and the cerebellum were commonly active in both temporal tasks, consistent with suggestions that perception and production of time are subserved by the same mechanisms. However, only in the reproduction task was activity observed in a wider cortical network including the right pre-SMA, left middle frontal gyrus, left premotor cortex, with a more reliable activity in the right inferior parietal cortex, left fusiform gyrus, and the right extrastriate visual area V5/MT. Our findings point to a role for the parietal cortex as an interface between sensory and motor processes and suggest that it may be a key node in translation of temporal information into action. Furthermore, we discuss the potential importance of the extrastriate cortex in processing visual time in the context of recent findings.

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Subjective time compression induced by continuous action

Scientific Reports ◽

10.1038/s41598-021-92946-x ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

Sayako Ueda ◽

Shingo Shimoda

Keyword(s):

Voluntary Action ◽

Subjective Time ◽

Reproduction Task ◽

Continuous Action ◽

Time Compression ◽

Time Experience ◽

Temporal Reproduction ◽

Daily Events ◽

Different Types ◽

Underlying Mechanisms

AbstractIncreasing evidence indicates that voluntary actions can modulate the subjective time experience of its outcomes to optimize dynamic interaction with the external environment. In the present study, using a temporal reproduction task where participants reproduced the duration of an auditory stimulus to which they were previously exposed by performing different types of voluntary action, we examined how the subjective time experience of action outcomes changed with voluntary action types. Two experiments revealed that the subjective time experience of action outcomes was compressed, compared with physical time, if the action was performed continuously (Experiment 1), possibly enhancing the experience of controlling the action outcome, or if the action was added an extra task-unrelated continuous action (Experiment 2), possibly reflecting different underlying mechanisms from subjective time compression induced by the task-related continuous action. The majority of prior studies have focused on the subjective time experience of action outcomes when actions were performed voluntarily or not, and no previous study has examined the effects of differences in voluntary action types on the subjective time experience of action outcomes. These findings may be useful in situations in which people wish to intentionally compress their own time experience of daily events through their voluntary actions.

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