void DynamicLoudnessCH2012::configureModelParameters(const string& setName) { //common to all setRate(1000); setOuterEarType(OME::ANSIS342007_FREEFIELD); setSpectrumSampledUniformly(true); setHoppingGoertzelDFTUsed(false); setExcitationPatternInterpolated(false); setInterpolationCubic(true); setSpecificLoudnessOutput(true); setBinauralInhibitionUsed(true); setPresentationDiotic(true); setFirstSampleAtWindowCentre(true); setFilterSpacingInCams(0.1); setCompressionCriterionInCams(0.0); attackTimeSTL_ = 0.016; releaseTimeSTL_ = 0.032; attackTimeLTL_ = 0.1; releaseTimeLTL_ = 2.0; if (setName == "Faster") { setFilterSpacingInCams(0.5); setCompressionCriterionInCams(0.3); LOUDNESS_DEBUG(name_ << ": using a filter spacing of 0.5 Cams" << " with 0.3 Cam spectral compression criterion."); } else if (setName != "CH2012") { configureModelParameters("CH2012"); LOUDNESS_DEBUG(name_ << "Using Settings from Chen and Hu 2012 paper."); } }
StationaryLoudnessCHGM2011::StationaryLoudnessCHGM2011() : Model("StationaryLoudnessCHGM2011", false) { //Default parameters setOuterEarFilter (OME::Filter::ANSIS342007_FREEFIELD); setFilterSpacingInCams (0.1); setPresentationDiotic (true); setBinauralInhibitionUsed (true); setSpecificLoudnessOutput (true); setPartialLoudnessUsed (true); }
void DynamicLoudnessGM2002::configureModelParameters(const string& setName) { //common to all setRate(1000); setOuterEarFilter(OME::ANSIS342007_FREEFIELD); setMiddleEarFilter(OME::ANSIS342007_MIDDLE_EAR_HPF); setSpectrumSampledUniformly(true); setHoppingGoertzelDFTUsed(false); setSpectralResolutionDoubled(false); setExcitationPatternInterpolated(false); setInterpolationCubic(true); setFilterSpacingInCams(0.25); setCompressionCriterionInCams(0.0); setRoexBankFast(false); setSpecificLoudnessANSIS342007(false); setFirstSampleAtWindowCentre(true); setPresentationDiotic(true); setBinauralInhibitionUsed(true); setPartialLoudnessUsed(true); configureSmoothingTimes("GM2002"); if (setName != "GM2002") { if (setName == "Faster") { setRoexBankFast(true); setExcitationPatternInterpolated(true); setFilterSpacingInCams(0.5); setCompressionCriterionInCams(0.2); LOUDNESS_DEBUG(name_ << ": Using faster params for Glasberg and Moore's 2002 model."); } else if (setName == "Recent") { configureSmoothingTimes("MGS2003"); setSpecificLoudnessANSIS342007(true); LOUDNESS_DEBUG(name_ << ": Using updated " << "time-constants from 2003 paper and high-level specific " << "loudness equation (ANSI S3.4 2007)."); } else if (setName == "FasterAndRecent") { configureSmoothingTimes("MGS2003"); setSpecificLoudnessANSIS342007(true); setRoexBankFast(true); setExcitationPatternInterpolated(true); setFilterSpacingInCams(0.5); setCompressionCriterionInCams(0.2); LOUDNESS_DEBUG(name_ << ": Using faster params and " << "updated time-constants from 2003 paper and " << "high-level specific loudness equation (ANSI S3.4 2007)."); } else if (setName == "WEAR2015") { setSpecificLoudnessANSIS342007(true); setRoexBankFast(true); setExcitationPatternInterpolated(false); setFilterSpacingInCams(1.25); setCompressionCriterionInCams(0.7); LOUDNESS_DEBUG(name_ << ": Using faster params as per Ward et al. (2015) and " << "high-level specific loudness equation (ANSI S3.4 2007)."); } else { LOUDNESS_DEBUG(name_ << ": Using original params from Glasberg and Moore 2002."); } } }