1 / 23

The Phase Correction Response in Sensorimotor Synchronization

The Phase Correction Response in Sensorimotor Synchronization. Bruno H. Repp Haskins Laboratories, New Haven, CT (now retired). Preliminaries. Apologies for focusing on my own research! The data I will show are for musicians as participants (“master tappers”).

jane
Download Presentation

The Phase Correction Response in Sensorimotor Synchronization

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. The Phase Correction Response in SensorimotorSynchronization Bruno H. Repp Haskins Laboratories, New Haven, CT (now retired)

  2. Preliminaries • Apologies for focusing on my own research! • The data I will show are for musicians as participants (“master tappers”). • References can be found in Repp (2005) and Repp & Su (2013), two large review papers in Psychonomic Bulletin & Review.

  3. Definitions Sensorimotor synchronization is the temporal coordination of a rhythmic movement with an external rhythm. Such coordination requires sensorimotorcoupling, which gives rise to phase correction: temporal adjustments of the movement that improve and maintain synchronization. When both rhythms consist of discrete events (e.g., metronome ticks accompanied by finger taps), each external event elicits an adjustment of the subsequent movement event: a phase correction response (PCR). Coupling strength can be estimated from discrete time series with statistical methods. One convenient method, however, is to introduce perturbations in the external rhythm and to observe the PCRs elicited by them.

  4. The Phase Shift Paradigm IOI = inter-onset interval PS = phase shift PCR = phase correction response (includes noise!) Calculation of the PCR: PCRi = ai - ai-1 = (ti - mi) - (ti-1 - mi-1) = (ti - ti-1) - (mi - mi-1) = Ti - Mi a = asynchrony; t = time of tap; m = time of (metronome) tone T = inter-tap interval; M = metronome IOI

  5. The PCR Function • The PCR function is strongly linear for PSs within ~ ±10% of the IOI. • Thus, PCR = α * PS • The slope α is an estimate of sensorimotor coupling strength. • The perceptual threshold for detecting a PS (~ ±5% of the IOI) seems irrelevant. (Schematic data for illustration)

  6. The Complete PCR Function • For PSs between ±50% of the IOI, the PCR function is nonlinear (sigmoid-shaped). • There is also an asymmetry: Large negative PSs elicit smaller PCRs than do large positive PSs. IOI = 500 ms Phase Shift (ms) (Repp, 2002, Human Movement Science)

  7. Intentional Suppression of the PCR The Event Onset Shift (EOS) Paradigm PCRi = ai - ai-1 - PS IOI = 500 ms • PCRs to EOSs larger than ±10% of the IOI can be suppressed, but a small residual PCR remains. • It is immaterial whether the perturbation is an EOS or a PS. • The steep linear slope of the PCR function within ±10% of the IOI is unaffected (?) by intentional suppression. EOS or PS (ms) (Repp, 2002, Human Movement Science)

  8. Does the Slope of the PCR Function Change at a Fixed Absolute or Relative Magnitude of the PS? • No clear answer Absolute (ms) Relative (% of IOI) (Repp, 2011, Journal of Motor Behavior)

  9. Alpha as a Function of IOI PSs within ±10% of IOI PSs within ±25 ms PSs within ±10% of IOI • Alpha increases linearlywith IOI up to at least 1200 ms • Overcorrection (α > 1) occurs at IOIs > ~ 1 second • Perceptual detection threshold appears irrelevant (once again) • Alpha increases less steeply at IOIs greater than ~ 1 second (nonlinearity?) (Repp, 2008, Journal of Motor Behavior) (Repp, 2011, Journal of Motor Behavior)

  10. Enhancement of Alpha During the PCR • Alpha is increased substantiallyimmediately after a phase shift (i.e., during the PCR) • Alpha is reduced when phase is modulated throughout the external rhythm • Alpha in rhythms with phase shifts is uncorrelated with alpha in other rhythms (Repp, Keller, & Jacoby, 2012, ActaPsychologica)

  11. What Triggers the PCR? Is it the preceding asynchrony? • Perhaps, when an asynchrony is perceived. • But can subliminal perception really trigger a PCR? • Moreover, an asynchrony is not needed for a PCR! • Indeed, the PCR tends to be larger in the absence of an asynchrony! (Repp, 2001, Journal of Experimental Psychology: Human Perception and Performance)

  12. What Triggers the PCR? Is it mixed phase resetting? Perception Asynchrony Phase correction (1) ti - mi No threshold? Ci - α * (ti - mi) (sensorimotor) Phase resetting (sensory) Phase correction mi + Ci α mi (2) References Ci - α * (ti - mi) ti + Ci 1 - α ti Persistence (motor) (inhibitory) t = time of tap; m = time of (metronome) tone; C = internal timekeeper interval

  13. What Triggers the PCR? (continued) • The mixed phase resetting model bypasses the issue of subliminal perception. • It readily accounts for the increased PCR in the absence of an asynchrony. • It can explain the nonlinear PCR function and the increase of alpha with IOI. • However, it cannot explain overcorrection at long IOIs. • Also, it cannot explain why alpha is enhanced during the PCR. Is it the preceding perceptual asynchrony? Asynchrony Phase correction Neural dynamics (3) ei- mi ? Ci – f(ei- mi) (perceptual) e = expectation (of sound) (cf. Large & Jones, 1999, Psychological Review) • This model allows for a nonlinear dynamic process that could lead to overcorrection or alpha enhancement. A dynamic approach avoids the issue of subliminal perception.

  14. Perceptual Monitoring of Subdivisions (Baseline condition) • Presence of a subdivision following the EOS reduces the PCR (relative to baseline). • A shifted subdivision elicits a PCR (smaller than baseline). • Insertion of a single “shifted” subdivision elicits a small PCR! • All these effects become larger when the IOI is increased. (Repp, 2008, Psychological Research)

  15. Temporal Evolution of the PCR Condition A • The PCR takes 250-300 ms to evolve, regardless of IOI duration. • Conditions B and C yield results similar to those of condition A. (Repp, 2011, Experimental Brain Research)

  16. Does the PCR Increase with the Immediately Preceding IOI (> 300 ms)? • Sometimes it does (see Figure A on left), but more often it doesn’t. • In two-interval rhythms, the PCR also does not increase systematically with cycle (IOI) duration (see figure below). (Repp, London, & Keller, 2008, Music Perception) (Repp, London, & Keller, 2011, Psychological Research)

  17. The PCR Is a Response to Violation of Temporal Expectations • The PCR depends on the direction of change and may run counter to long-term changes in relative phase caused by subdivision timing. (Repp & Jendoubi, 2009, Advances in Cognitive Psychology)

  18. Using the PCR to Investigate Auditory Streaming IOI = 450 ms IOI = 600 ms • The PCR seemed to be insensitive to auditory streaming! (Repp, 2009a, Quarterly Journal of Experimental Psychology)

  19. Using the PCR to Investigate Auditory Streaming (continued) IOI = 450 ms IOI = 600 ms • Here the PCR was again insensitive to streaming at the slower tempo, but at the faster tempo a streaming effect was evident. • Overall, the results suggest that perceptually segregated streams are often still integrated into a composite rhythm. (Repp, 2009b, Quarterly Journal of Experimental Psychology)

  20. Anticipatory Phase Correction (APC) • Phase correction can be consciously controlled. • Up to 1 s was needed for optimal use of cues. • APC was generally conservative (< 80%). • PCR to residual PS was like PCR without APC. IOI (ms) (Repp & Moseley, 2012, Human Movement Science)

  21. Kinematic Implementation of Phase Correction • Phase correction occurs during the upward movementin tapping but evolves continuously (and is less vigorous) during the oscillation cycle (Torre & Balasubramaniam, 2009, Experimental Brain Research) (Repp & Steinman, 2010, Human Movement Science)

  22. Summary • The PCR elicited by perturbations is a manifestation of sensorimotor coupling. • It is usually automatic but can be consciously controlled for purposes of intentional decoupling or anticipation (based on advance information). • It does not require awareness of perturbations or asynchronies, not are sensorimotor asynchronies required to trigger it. • It increases nonlinearly with perturbation magnitude but is a highly linear function of perturbation magnitude within a narrow range. • Itincreases with metronome IOI duration, but not necessarily with preceding IOI duration or cycle duration in non-isochronous rhythms.* • At long IOI durations (> 1 s), overcorrection occurs, for still unknown reasons.* • Sensorimotor coupling (alpha) is increased immediately after a perturbation (i.e., during the PCR). • Phase correction in rhythms containing perturbations seems to be distinct from phase correction in isochronous or continuously modulated rhythms.* • The PCR may represent a neural system response to asynchronies between temporal predictions and the actual times of occurrence of rhythmic events.* • *Further research is required!

  23. Thank you for your attention! This research was supported by grants from the National Institute of Health and the National Science Foundation.

More Related