modules/audio_processing/vad/pitch_based_vad.cc - src/ - Git at Google

 /*
  *  Copyright (c) 2012 The WebRTC project authors. All Rights Reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 #include "modules/audio_processing/vad/pitch_based_vad.h"

 #include <string.h>

 #include "modules/audio_processing/vad/common.h"
 #include "modules/audio_processing/vad/noise_gmm_tables.h"
 #include "modules/audio_processing/vad/vad_circular_buffer.h"
 #include "modules/audio_processing/vad/voice_gmm_tables.h"

 namespace webrtc {

 static_assert(kNoiseGmmDim == kVoiceGmmDim,
               "noise and voice gmm dimension not equal");

 // These values should match MATLAB counterparts for unit-tests to pass.
 static const int kPosteriorHistorySize = 500;  // 5 sec of 10 ms frames.
 static const double kInitialPriorProbability = 0.3;
 static const int kTransientWidthThreshold = 7;
 static const double kLowProbabilityThreshold = 0.2;

 static double LimitProbability(double p) {
   const double kLimHigh = 0.99;
   const double kLimLow = 0.01;

   if (p > kLimHigh)
     p = kLimHigh;
   else if (p < kLimLow)
     p = kLimLow;
   return p;
 }

 PitchBasedVad::PitchBasedVad()
     : p_prior_(kInitialPriorProbability),
       circular_buffer_(VadCircularBuffer::Create(kPosteriorHistorySize)) {
   // Setup noise GMM.
   noise_gmm_.dimension = kNoiseGmmDim;
   noise_gmm_.num_mixtures = kNoiseGmmNumMixtures;
   noise_gmm_.weight = kNoiseGmmWeights;
   noise_gmm_.mean = &kNoiseGmmMean[0][0];
   noise_gmm_.covar_inverse = &kNoiseGmmCovarInverse[0][0][0];

   // Setup voice GMM.
   voice_gmm_.dimension = kVoiceGmmDim;
   voice_gmm_.num_mixtures = kVoiceGmmNumMixtures;
   voice_gmm_.weight = kVoiceGmmWeights;
   voice_gmm_.mean = &kVoiceGmmMean[0][0];
   voice_gmm_.covar_inverse = &kVoiceGmmCovarInverse[0][0][0];
 }

 PitchBasedVad::~PitchBasedVad() {}

 int PitchBasedVad::VoicingProbability(const AudioFeatures& features,
                                       double* p_combined) {
   double p;
   double gmm_features[3];
   double pdf_features_given_voice;
   double pdf_features_given_noise;
   // These limits are the same in matlab implementation 'VoicingProbGMM().'
   const double kLimLowLogPitchGain = -2.0;
   const double kLimHighLogPitchGain = -0.9;
   const double kLimLowSpectralPeak = 200;
   const double kLimHighSpectralPeak = 2000;
   const double kEps = 1e-12;
   for (size_t n = 0; n < features.num_frames; n++) {
     gmm_features[0] = features.log_pitch_gain[n];
     gmm_features[1] = features.spectral_peak[n];
     gmm_features[2] = features.pitch_lag_hz[n];

     pdf_features_given_voice = EvaluateGmm(gmm_features, voice_gmm_);
     pdf_features_given_noise = EvaluateGmm(gmm_features, noise_gmm_);

     if (features.spectral_peak[n] < kLimLowSpectralPeak ||
         features.spectral_peak[n] > kLimHighSpectralPeak ||
         features.log_pitch_gain[n] < kLimLowLogPitchGain) {
       pdf_features_given_voice = kEps * pdf_features_given_noise;
     } else if (features.log_pitch_gain[n] > kLimHighLogPitchGain) {
       pdf_features_given_noise = kEps * pdf_features_given_voice;
     }

     p = p_prior_ * pdf_features_given_voice /
         (pdf_features_given_voice * p_prior_ +
          pdf_features_given_noise * (1 - p_prior_));

     p = LimitProbability(p);

     // Combine pitch-based probability with standalone probability, before
     // updating prior probabilities.
     double prod_active = p * p_combined[n];
     double prod_inactive = (1 - p) * (1 - p_combined[n]);
     p_combined[n] = prod_active / (prod_active + prod_inactive);

     if (UpdatePrior(p_combined[n]) < 0)
       return -1;
     // Limit prior probability. With a zero prior probability the posterior
     // probability is always zero.
     p_prior_ = LimitProbability(p_prior_);
   }
   return 0;
 }

 int PitchBasedVad::UpdatePrior(double p) {
   circular_buffer_->Insert(p);
   if (circular_buffer_->RemoveTransient(kTransientWidthThreshold,
                                         kLowProbabilityThreshold) < 0)
     return -1;
   p_prior_ = circular_buffer_->Mean();
   return 0;
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2012 The WebRTC project authors. All Rights Reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	#include "modules/audio_processing/vad/pitch_based_vad.h"

	#include <string.h>

	#include "modules/audio_processing/vad/common.h"
	#include "modules/audio_processing/vad/noise_gmm_tables.h"
	#include "modules/audio_processing/vad/vad_circular_buffer.h"
	#include "modules/audio_processing/vad/voice_gmm_tables.h"

	namespace webrtc {

	static_assert(kNoiseGmmDim == kVoiceGmmDim,
	"noise and voice gmm dimension not equal");

	// These values should match MATLAB counterparts for unit-tests to pass.
	static const int kPosteriorHistorySize = 500; // 5 sec of 10 ms frames.
	static const double kInitialPriorProbability = 0.3;
	static const int kTransientWidthThreshold = 7;
	static const double kLowProbabilityThreshold = 0.2;

	static double LimitProbability(double p) {
	const double kLimHigh = 0.99;
	const double kLimLow = 0.01;

	if (p > kLimHigh)
	p = kLimHigh;
	else if (p < kLimLow)
	p = kLimLow;
	return p;
	}

	PitchBasedVad::PitchBasedVad()
	: p_prior_(kInitialPriorProbability),
	circular_buffer_(VadCircularBuffer::Create(kPosteriorHistorySize)) {
	// Setup noise GMM.
	noise_gmm_.dimension = kNoiseGmmDim;
	noise_gmm_.num_mixtures = kNoiseGmmNumMixtures;
	noise_gmm_.weight = kNoiseGmmWeights;
	noise_gmm_.mean = &kNoiseGmmMean[0][0];
	noise_gmm_.covar_inverse = &kNoiseGmmCovarInverse[0][0][0];

	// Setup voice GMM.
	voice_gmm_.dimension = kVoiceGmmDim;
	voice_gmm_.num_mixtures = kVoiceGmmNumMixtures;
	voice_gmm_.weight = kVoiceGmmWeights;
	voice_gmm_.mean = &kVoiceGmmMean[0][0];
	voice_gmm_.covar_inverse = &kVoiceGmmCovarInverse[0][0][0];
	}

	PitchBasedVad::~PitchBasedVad() {}

	int PitchBasedVad::VoicingProbability(const AudioFeatures& features,
	double* p_combined) {
	double p;
	double gmm_features[3];
	double pdf_features_given_voice;
	double pdf_features_given_noise;
	// These limits are the same in matlab implementation 'VoicingProbGMM().'
	const double kLimLowLogPitchGain = -2.0;
	const double kLimHighLogPitchGain = -0.9;
	const double kLimLowSpectralPeak = 200;
	const double kLimHighSpectralPeak = 2000;
	const double kEps = 1e-12;
	for (size_t n = 0; n < features.num_frames; n++) {
	gmm_features[0] = features.log_pitch_gain[n];
	gmm_features[1] = features.spectral_peak[n];
	gmm_features[2] = features.pitch_lag_hz[n];

	pdf_features_given_voice = EvaluateGmm(gmm_features, voice_gmm_);
	pdf_features_given_noise = EvaluateGmm(gmm_features, noise_gmm_);

	if (features.spectral_peak[n] < kLimLowSpectralPeak \|\|
	features.spectral_peak[n] > kLimHighSpectralPeak \|\|
	features.log_pitch_gain[n] < kLimLowLogPitchGain) {
	pdf_features_given_voice = kEps * pdf_features_given_noise;
	} else if (features.log_pitch_gain[n] > kLimHighLogPitchGain) {
	pdf_features_given_noise = kEps * pdf_features_given_voice;
	}

	p = p_prior_ * pdf_features_given_voice /
	(pdf_features_given_voice * p_prior_ +
	pdf_features_given_noise * (1 - p_prior_));

	p = LimitProbability(p);

	// Combine pitch-based probability with standalone probability, before
	// updating prior probabilities.
	double prod_active = p * p_combined[n];
	double prod_inactive = (1 - p) * (1 - p_combined[n]);
	p_combined[n] = prod_active / (prod_active + prod_inactive);

	if (UpdatePrior(p_combined[n]) < 0)
	return -1;
	// Limit prior probability. With a zero prior probability the posterior
	// probability is always zero.
	p_prior_ = LimitProbability(p_prior_);
	}
	return 0;
	}

	int PitchBasedVad::UpdatePrior(double p) {
	circular_buffer_->Insert(p);
	if (circular_buffer_->RemoveTransient(kTransientWidthThreshold,
	kLowProbabilityThreshold) < 0)
	return -1;
	p_prior_ = circular_buffer_->Mean();
	return 0;
	}

	} // namespace webrtc