1 / 37

Issues in Motor Control

Issues in Motor Control. Degrees of Freedom Problem Perceptual-Motor Integration Problem Serial Order and Timing Problem Learning Problem. (Rosenbaum, 2002). Earlier Ideas Used Response Chaining: Closed (feedback)-Loop Control:. No, because delays too long between movements

emile
Download Presentation

Issues in Motor Control

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. Issues in Motor Control • Degrees of Freedom Problem • Perceptual-Motor Integration Problem • Serial Order and Timing Problem • Learning Problem (Rosenbaum, 2002)

  2. Earlier Ideas Used Response Chaining: Closed (feedback)-Loop Control: • No, because • delays too long between movements • disrupting feedback does not necessarily impeded movement • Systematic mistakes in speech, typing, etc “He hissed all my mystery lessons” rather than “he missed all my history lessons”

  3. Closed-Loop Control: Still Occurs • Can you think of an example? • Muscle spindle (20-30 ms) • Long-loop reflexes

  4. Open-(feedforward) Loop Control • Anticipatory Control • Predictive Control • Prospective Control

  5. Closed-Loop Control: Still Occurs http://www2.fhs.usyd.edu.au/ess/odwyer/Human%20Motor%20Learning%20and%20Control/Lectures/Week%206/Using_Information_FF_vs_FB_Control.pdf

  6. Need for Closed and Open-Loop Systems http://www2.fhs.usyd.edu.au/ess/odwyer/Human%20Motor%20Learning%20and%20Control/Lectures/Week%206/Using_Information_FF_vs_FB_Control.pdf

  7. What must be specified in advance for open-loop control to be accomplished? • Willingham (1999) • Donders (1868)

  8. Strategic Allocentric Conscious P-M Integration Egocentric Un/Conscious Sequencing Egocentric Un/Conscious Dynamic Egocentric Unconscious

  9. Information Processing

  10. Solving motor control problems using Open-Loop Control: Plans or Programs • Evidence for planning movements in advance • Reaction Time approach RT is larger as task is more complex – Presumably this occurs because more demanding mental operations http://www2.fhs.usyd.edu.au/ess/odwyer/Human%20Motor%20Learning%20and%20Control/Lectures/Week%206/Using_Information_FF_vs_FB_Control.pdf

  11. RT: Input-?-Output Movement Initiation GO Response Programming = Reaction Time

  12. Perceptual-Motor Integration Sequencing or Serial Order

  13. Parallel Processing Cascade Processing

  14. Influences on RT RT is a volatile measure which is sensitive to many factors: • stimulus factors: • modality of presentation (visual, auditory, tactile, kinaesthetic) • intensity (loudness, brightness) • temporal predictability • number of response choices • stimulus-response compatibility • response complexity SRT CRT SRT

  15. stimulus factors impacting SRT: • modality of presentation (visual, auditory, tactile, kinaesthetic) • intensity (loudness, brightness) • temporal predictability RT (ms) -- ++ Signal Intensity

  16. Event Uncertainty and CRT • Number of response choices • Probability Effects • Precues • Sequential Effects

  17. Hick’s Law CRT = a + b (log2 N) # Decisions CRT = SRT + DT (# Decision)

  18. Precues What is being precued? Where is the impact? CRT = SRT + DT (# Decision)

  19. Reducing Event Uncertainty: Probability Effects

  20. Decision Time CRT = SRT + DT (# Decision) Stimulus-Response Compatibility • Degree of correspondence between the stimulus array and the response

  21. CRT = SRT + DT (# Decision)

  22. Perceptual-Motor Integration

  23. Response Programming: What movement parameters must be planned?

  24. Henry and Roger (1960) MT (ms) 0 95 465 208 Keep in mind that the RT for the finger lift is being measured here not MT: What movement parameter(s) were responsible for increase in RT

  25. Using Henry & Rogers data: What are the key movement parameters that need to be planned? • Movement Duration • Number of Elements (sequence length effects) • Changes in Direction • Force/velocity requirements • Directions requirements

  26. INT Complexity 150 ms 450 ms Simple SEQ Complexity 150-450-450-150 450-150-150-450 Complex Simple Complex Mono vs Multi-syllabic /ba/

  27. Start Fixation Point Stimulus Display Study Time Ready ? Yes 100 % 15 % 0 % ‘ ’ GO Signal Reaction Time Speech Duration Analyze Interval Yes Error ? No Model Replay Rectified & Waveform Filtered End Self-select paradigm and speech Duration of programmed unit Number of programmed units

  28. Defining complexity of the utterance INT Complexity CV ta CC(C)V stra Simple SEQ Complexity CV repeat ta-ta-ta-ta CC(C)V repeat stra-stra-stra-stra CC(C)V change ta-stra-ru-ta Complex Simple Complex

  29. Apraxia of Speech (AOS): Is it a planning or programming problem? • Motor Planning • Van der Merwe (1997) • Motor Programming • Levelt (1989) • phonetic encoding leading to “phonetic plan” • Van Lieshout et al., (1996) • motor plan assembly and muscle command preparation

  30. Closed vs. Open Loop Plans or Motor Programs Quantifying the plan: Reaction Time The plan (or RT) involves: Perception-Response Selection-Programming Verifying this model by finding factors impacting Perception-Response Selection-Programming (c)Rt = SRT + DT(# of Decisions)

  31. (C)RT = SRT + DT(# of Decisions) Movement Duration Number of Elements (sequence length effects) Changes in Direction Force/velocity requirements Directions requirements • Modality of presentation • intensity (loudness, brightness) • temporal predictability Perceptual Process Motor Programming • Compatibility of S and R • Practice • Number of Alternative • Precues • Sequential dependencies Decision Making (response selection)

More Related