0000000001001246

AUTHOR

Michael U. Gutmann

showing 2 related works from this author

Spatio-Chromatic Adaptation via Higher-Order Canonical Correlation Analysis of Natural Images

2014

Independent component and canonical correlation analysis are two general-purpose statistical methods with wide applicability. In neuroscience, independent component analysis of chromatic natural images explains the spatio-chromatic structure of primary cortical receptive fields in terms of properties of the visual environment. Canonical correlation analysis explains similarly chromatic adaptation to different illuminations. But, as we show in this paper, neither of the two methods generalizes well to explain both spatio-chromatic processing and adaptation at the same time. We propose a statistical method which combines the desirable properties of independent component and canonical correlat…

LightVisual SystemRECEPTIVE-FIELD PROPERTIESlcsh:MedicineSocial and Behavioral SciencesBioinformaticsSTRIATE CORTEXCOLOR APPEARANCEImage Processing Computer-AssistedPsychophysicsPsychologylcsh:ScienceVisual CortexMathematicsCoding MechanismsMultidisciplinarySPECTRAL DESCRIPTIONSStatisticsSensory SystemsPRIMARY VISUAL-CORTEXDATA SETSPrincipal component analysisSensory PerceptionSPATIAL STRUCTURECanonical correlationAlgorithmsColor PerceptionResearch ArticleeducationColorCHROMATIC MECHANISMS114 Physical sciencesArtificial IntelligenceComponent (UML)PsychophysicsHumansComputer SimulationChromatic scaleStatistical MethodsBiologyProbabilityComputational NeuroscienceModels StatisticalINDEPENDENT COMPONENT ANALYSISbusiness.industrylcsh:RNeurosciencesComputational BiologyPattern recognitionIndependent component analysisData set2-STAGE LINEAR RECOVERYChromatic adaptationlcsh:QArtificial intelligencebusinessPhotic StimulationMathematicsNeurosciencePLoS ONE
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Complex-Valued Independent Component Analysis of Natural Images

2011

Linear independent component analysis (ICA) learns simple cell receptive fields fromnatural images. Here,we showthat linear complex-valued ICA learns complex cell properties from Fourier-transformed natural images, i.e. two Gabor-like filters with quadrature-phase relationship. Conventional methods for complex-valued ICA assume that the phases of the output signals have uniform distribution. We show here that for natural images the phase distributions are, however, often far from uniform. We thus relax the uniformity assumption and model also the phase of the sources in complex-valued ICA. Compared to the original complex ICA model, the new model provides a better fit to the data, and leads…

Uniform distribution (continuous)business.industryPhase (waves)Pattern recognitionSimple cellComplex cellIndependent component analysismedicine.anatomical_structureComponent analysisComputer Science::SoundReceptive fieldmedicineArtificial intelligenceLinear independencebusinessMathematics
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