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Bayesian integration of visual and auditory signals for spatial localization

Authors: Peter W. Battaglia, Robert A. Jacobs, and Richard N. Aslin. Bayesian integration of visual and auditory signals for spatial localization. COGS 272, Spring 2010 Instructor: Prof. Angela Yu Presenter: Vikram Gupta. Outline. Introduction Background Methods Procedure Results

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Bayesian integration of visual and auditory signals for spatial localization

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  1. Authors: Peter W. Battaglia, Robert A. Jacobs, and Richard N. Aslin Bayesian integration of visual and auditory signals for spatial localization COGS 272, Spring 2010 Instructor: Prof. Angela Yu Presenter: Vikram Gupta

  2. Outline • Introduction • Background • Methods • Procedure • Results • Discussion

  3. IntroductionSpatial Localization is Complex • Integration of multiple sensory and motor signals • Sensory: binaural time, phase, intensity difference • Motor: orientation of the head

  4. Introduction∫ Inconsistent Spatial Cues • Typically, we receive consistent spatial cues • What if this is not true? • Ex: Movie theater, television • Visual capture • Vision dominates over conflicting auditory cue. • Ex: recalibration in juvenile owl • Optimal?

  5. BackgroundModels for inconsistent cue integration • Winner Take All (ex. vision capture) • Dominant signal exclusively decides • Blend information from sensory sources • Is blending statistically optimal? • Example: Maximum Likelihood Estimate • Assumption independent sensory signals, normal dist.

  6. BackgroundMLE Example Impact of reliability on MLE estimate

  7. MLE Model • Is Normal distribution a good estimate of neural coding of sensory input? • Does this integration always occur? Or are there qualifying conditions? • Does it make sense to integrate if • Lv* and La* are far apart? • v and a are temporally separated?

  8. Schematic of MLE Integration • Ernst, 2006 (MLE integration for haptic and visual input

  9. Experiment • Vision capture or MLE match empirical data? • Method summary: • Noise is produced at 1 of 7 locations 1.50 apart • Visual stimulus has noise at 5 levels • 10%, 23%, 36%, 49%, 62% • Single sensory modality trial (Audio / noisy Visual )  MLE parameters  predict performance for Audio + noisy Visual  compare with Empirical data

  10. Experiment S C • Single-modality • Standard stimuli followed by comparison • Is C Left / Right of S? • Bimodal • Standard stimuli has Audio and Visual apart from center • Audio and visual Comparison stimuli are co-located. • Only 1 subject aware of spatial discrepancy in S

  11. Results (1 subject) • Cumulative normal distribution fits to data • Mean and variance are used for MLE model • Wv receives high value when visual noise is low • Wa receives high value when visual noise is high

  12. Results (MLE Estimate of sensory input) • rt = 1 comparison to the right of standard • pt = , probability of rt, given mean and variance • R = set of responses to the independent trials • Assuming normal distribution, MLE estimate of mean and variance parameters • µml = 1/T * (∑ rt) σ2ml = 1/T * (rt - µml) 2

  13. L* based on MLE estimates • Mean is calculated according to above weighted average • Variance is smaller than either P(L|v) or P(L|a)

  14. L* based on MLE estimates • MLE estimate for wv and wa are found by maximizing RHS of (3) and using (6) • tau is scale parameter or slope

  15. Results (bi-modal, same subject, all subjects) • Standard stimulus • Visual -1.50 • Audio 1.50 • Point of Subjective Equality • -1.10 for low visual noise • 0.10 for high noise • Visual input dominates at low noise • Equal weight at high noise

  16. Empirical vs. MLE • MLE estimates for visual weight are significantly lower than the empirical results. • A Bayesian model with a prior that reduces variance in visual-only trials provides a good regression fit for the data.

  17. Bayesian (MAP) Cue Integration • For visual only trials, instead of using MLE for mean and variance, we multiply the RHS above with the probability of the occurrence of the normal distribution • mean is assumed to have a uniform distribution. • variance is assumed to have inverse gamma distribution with parameters biased for small variance.

  18. Discussion • Bayesian approach is a hybrid of MLE and visual capture models. • How are variances encoded? • How are priors encoded? • How does temporal separation in cues impact sensory integration? • Biological basis for Bayesian cue integration?

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