modules/video_coding/jitter_estimator.cc - src - Git at Google

 /*
  *  Copyright (c) 2011 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/video_coding/jitter_estimator.h"

 #include <assert.h>
 #include <math.h>
 #include <string.h>
 #include <algorithm>
 #include <cstdint>

 #include "absl/types/optional.h"
 #include "modules/video_coding/internal_defines.h"
 #include "modules/video_coding/rtt_filter.h"
 #include "rtc_base/experiments/jitter_upper_bound_experiment.h"
 #include "rtc_base/numerics/safe_conversions.h"
 #include "system_wrappers/include/clock.h"

 namespace webrtc {
 namespace {
 static constexpr uint32_t kStartupDelaySamples = 30;
 static constexpr int64_t kFsAccuStartupSamples = 5;
 static constexpr double kMaxFramerateEstimate = 200.0;
 static constexpr int64_t kNackCountTimeoutMs = 60000;
 static constexpr double kDefaultMaxTimestampDeviationInSigmas = 3.5;
 }  // namespace

 VCMJitterEstimator::VCMJitterEstimator(Clock* clock,
                                        int32_t vcmId,
                                        int32_t receiverId)
     : _vcmId(vcmId),
       _receiverId(receiverId),
       _phi(0.97),
       _psi(0.9999),
       _alphaCountMax(400),
       _thetaLow(0.000001),
       _nackLimit(3),
       _numStdDevDelayOutlier(15),
       _numStdDevFrameSizeOutlier(3),
       _noiseStdDevs(2.33),       // ~Less than 1% chance
                                  // (look up in normal distribution table)...
       _noiseStdDevOffset(30.0),  // ...of getting 30 ms freezes
       _rttFilter(),
       fps_counter_(30),  // TODO(sprang): Use an estimator with limit based on
                          // time, rather than number of samples.
       time_deviation_upper_bound_(
           JitterUpperBoundExperiment::GetUpperBoundSigmas().value_or(
               kDefaultMaxTimestampDeviationInSigmas)),
       clock_(clock) {
   Reset();
 }

 VCMJitterEstimator::~VCMJitterEstimator() {}

 VCMJitterEstimator& VCMJitterEstimator::operator=(
     const VCMJitterEstimator& rhs) {
   if (this != &rhs) {
     memcpy(_thetaCov, rhs._thetaCov, sizeof(_thetaCov));
     memcpy(_Qcov, rhs._Qcov, sizeof(_Qcov));

     _vcmId = rhs._vcmId;
     _receiverId = rhs._receiverId;
     _avgFrameSize = rhs._avgFrameSize;
     _varFrameSize = rhs._varFrameSize;
     _maxFrameSize = rhs._maxFrameSize;
     _fsSum = rhs._fsSum;
     _fsCount = rhs._fsCount;
     _lastUpdateT = rhs._lastUpdateT;
     _prevEstimate = rhs._prevEstimate;
     _prevFrameSize = rhs._prevFrameSize;
     _avgNoise = rhs._avgNoise;
     _alphaCount = rhs._alphaCount;
     _filterJitterEstimate = rhs._filterJitterEstimate;
     _startupCount = rhs._startupCount;
     _latestNackTimestamp = rhs._latestNackTimestamp;
     _nackCount = rhs._nackCount;
     _rttFilter = rhs._rttFilter;
     clock_ = rhs.clock_;
   }
   return *this;
 }

 // Resets the JitterEstimate
 void VCMJitterEstimator::Reset() {
   _theta[0] = 1 / (512e3 / 8);
   _theta[1] = 0;
   _varNoise = 4.0;

   _thetaCov[0][0] = 1e-4;
   _thetaCov[1][1] = 1e2;
   _thetaCov[0][1] = _thetaCov[1][0] = 0;
   _Qcov[0][0] = 2.5e-10;
   _Qcov[1][1] = 1e-10;
   _Qcov[0][1] = _Qcov[1][0] = 0;
   _avgFrameSize = 500;
   _maxFrameSize = 500;
   _varFrameSize = 100;
   _lastUpdateT = -1;
   _prevEstimate = -1.0;
   _prevFrameSize = 0;
   _avgNoise = 0.0;
   _alphaCount = 1;
   _filterJitterEstimate = 0.0;
   _latestNackTimestamp = 0;
   _nackCount = 0;
   _latestNackTimestamp = 0;
   _fsSum = 0;
   _fsCount = 0;
   _startupCount = 0;
   _rttFilter.Reset();
   fps_counter_.Reset();
 }

 void VCMJitterEstimator::ResetNackCount() {
   _nackCount = 0;
 }

 // Updates the estimates with the new measurements
 void VCMJitterEstimator::UpdateEstimate(int64_t frameDelayMS,
                                         uint32_t frameSizeBytes,
                                         bool incompleteFrame /* = false */) {
   if (frameSizeBytes == 0) {
     return;
   }
   int deltaFS = frameSizeBytes - _prevFrameSize;
   if (_fsCount < kFsAccuStartupSamples) {
     _fsSum += frameSizeBytes;
     _fsCount++;
   } else if (_fsCount == kFsAccuStartupSamples) {
     // Give the frame size filter
     _avgFrameSize = static_cast<double>(_fsSum) / static_cast<double>(_fsCount);
     _fsCount++;
   }
   if (!incompleteFrame || frameSizeBytes > _avgFrameSize) {
     double avgFrameSize = _phi * _avgFrameSize + (1 - _phi) * frameSizeBytes;
     if (frameSizeBytes < _avgFrameSize + 2 * sqrt(_varFrameSize)) {
       // Only update the average frame size if this sample wasn't a
       // key frame
       _avgFrameSize = avgFrameSize;
     }
     // Update the variance anyway since we want to capture cases where we only
     // get
     // key frames.
     _varFrameSize = VCM_MAX(
         _phi * _varFrameSize + (1 - _phi) * (frameSizeBytes - avgFrameSize) *
                                    (frameSizeBytes - avgFrameSize),
         1.0);
   }

   // Update max frameSize estimate
   _maxFrameSize =
       VCM_MAX(_psi * _maxFrameSize, static_cast<double>(frameSizeBytes));

   if (_prevFrameSize == 0) {
     _prevFrameSize = frameSizeBytes;
     return;
   }
   _prevFrameSize = frameSizeBytes;

   // Cap frameDelayMS based on the current time deviation noise.
   int64_t max_time_deviation_ms =
       static_cast<int64_t>(time_deviation_upper_bound_ * sqrt(_varNoise) + 0.5);
   frameDelayMS = std::max(std::min(frameDelayMS, max_time_deviation_ms),
                           -max_time_deviation_ms);

   // Only update the Kalman filter if the sample is not considered
   // an extreme outlier. Even if it is an extreme outlier from a
   // delay point of view, if the frame size also is large the
   // deviation is probably due to an incorrect line slope.
   double deviation = DeviationFromExpectedDelay(frameDelayMS, deltaFS);

   if (fabs(deviation) < _numStdDevDelayOutlier * sqrt(_varNoise) ||
       frameSizeBytes >
           _avgFrameSize + _numStdDevFrameSizeOutlier * sqrt(_varFrameSize)) {
     // Update the variance of the deviation from the
     // line given by the Kalman filter
     EstimateRandomJitter(deviation, incompleteFrame);
     // Prevent updating with frames which have been congested by a large
     // frame, and therefore arrives almost at the same time as that frame.
     // This can occur when we receive a large frame (key frame) which
     // has been delayed. The next frame is of normal size (delta frame),
     // and thus deltaFS will be << 0. This removes all frame samples
     // which arrives after a key frame.
     if ((!incompleteFrame || deviation >= 0.0) &&
         static_cast<double>(deltaFS) > -0.25 * _maxFrameSize) {
       // Update the Kalman filter with the new data
       KalmanEstimateChannel(frameDelayMS, deltaFS);
     }
   } else {
     int nStdDev =
         (deviation >= 0) ? _numStdDevDelayOutlier : -_numStdDevDelayOutlier;
     EstimateRandomJitter(nStdDev * sqrt(_varNoise), incompleteFrame);
   }
   // Post process the total estimated jitter
   if (_startupCount >= kStartupDelaySamples) {
     PostProcessEstimate();
   } else {
     _startupCount++;
   }
 }

 // Updates the nack/packet ratio
 void VCMJitterEstimator::FrameNacked() {
   if (_nackCount < _nackLimit) {
     _nackCount++;
   }
   _latestNackTimestamp = clock_->TimeInMicroseconds();
 }

 // Updates Kalman estimate of the channel
 // The caller is expected to sanity check the inputs.
 void VCMJitterEstimator::KalmanEstimateChannel(int64_t frameDelayMS,
                                                int32_t deltaFSBytes) {
   double Mh[2];
   double hMh_sigma;
   double kalmanGain[2];
   double measureRes;
   double t00, t01;

   // Kalman filtering

   // Prediction
   // M = M + Q
   _thetaCov[0][0] += _Qcov[0][0];
   _thetaCov[0][1] += _Qcov[0][1];
   _thetaCov[1][0] += _Qcov[1][0];
   _thetaCov[1][1] += _Qcov[1][1];

   // Kalman gain
   // K = M*h'/(sigma2n + h*M*h') = M*h'/(1 + h*M*h')
   // h = [dFS 1]
   // Mh = M*h'
   // hMh_sigma = h*M*h' + R
   Mh[0] = _thetaCov[0][0] * deltaFSBytes + _thetaCov[0][1];
   Mh[1] = _thetaCov[1][0] * deltaFSBytes + _thetaCov[1][1];
   // sigma weights measurements with a small deltaFS as noisy and
   // measurements with large deltaFS as good
   if (_maxFrameSize < 1.0) {
     return;
   }
   double sigma = (300.0 * exp(-fabs(static_cast<double>(deltaFSBytes)) /
                               (1e0 * _maxFrameSize)) +
                   1) *
                  sqrt(_varNoise);
   if (sigma < 1.0) {
     sigma = 1.0;
   }
   hMh_sigma = deltaFSBytes * Mh[0] + Mh[1] + sigma;
   if ((hMh_sigma < 1e-9 && hMh_sigma >= 0) ||
       (hMh_sigma > -1e-9 && hMh_sigma <= 0)) {
     assert(false);
     return;
   }
   kalmanGain[0] = Mh[0] / hMh_sigma;
   kalmanGain[1] = Mh[1] / hMh_sigma;

   // Correction
   // theta = theta + K*(dT - h*theta)
   measureRes = frameDelayMS - (deltaFSBytes * _theta[0] + _theta[1]);
   _theta[0] += kalmanGain[0] * measureRes;
   _theta[1] += kalmanGain[1] * measureRes;

   if (_theta[0] < _thetaLow) {
     _theta[0] = _thetaLow;
   }

   // M = (I - K*h)*M
   t00 = _thetaCov[0][0];
   t01 = _thetaCov[0][1];
   _thetaCov[0][0] = (1 - kalmanGain[0] * deltaFSBytes) * t00 -
                     kalmanGain[0] * _thetaCov[1][0];
   _thetaCov[0][1] = (1 - kalmanGain[0] * deltaFSBytes) * t01 -
                     kalmanGain[0] * _thetaCov[1][1];
   _thetaCov[1][0] = _thetaCov[1][0] * (1 - kalmanGain[1]) -
                     kalmanGain[1] * deltaFSBytes * t00;
   _thetaCov[1][1] = _thetaCov[1][1] * (1 - kalmanGain[1]) -
                     kalmanGain[1] * deltaFSBytes * t01;

   // Covariance matrix, must be positive semi-definite
   assert(_thetaCov[0][0] + _thetaCov[1][1] >= 0 &&
          _thetaCov[0][0] * _thetaCov[1][1] -
                  _thetaCov[0][1] * _thetaCov[1][0] >=
              0 &&
          _thetaCov[0][0] >= 0);
 }

 // Calculate difference in delay between a sample and the
 // expected delay estimated by the Kalman filter
 double VCMJitterEstimator::DeviationFromExpectedDelay(
     int64_t frameDelayMS,
     int32_t deltaFSBytes) const {
   return frameDelayMS - (_theta[0] * deltaFSBytes + _theta[1]);
 }

 // Estimates the random jitter by calculating the variance of the
 // sample distance from the line given by theta.
 void VCMJitterEstimator::EstimateRandomJitter(double d_dT,
                                               bool incompleteFrame) {
   uint64_t now = clock_->TimeInMicroseconds();
   if (_lastUpdateT != -1) {
     fps_counter_.AddSample(now - _lastUpdateT);
   }
   _lastUpdateT = now;

   if (_alphaCount == 0) {
     assert(false);
     return;
   }
   double alpha =
       static_cast<double>(_alphaCount - 1) / static_cast<double>(_alphaCount);
   _alphaCount++;
   if (_alphaCount > _alphaCountMax)
     _alphaCount = _alphaCountMax;

   // In order to avoid a low frame rate stream to react slower to changes,
   // scale the alpha weight relative a 30 fps stream.
   double fps = GetFrameRate();
   if (fps > 0.0) {
     double rate_scale = 30.0 / fps;
     // At startup, there can be a lot of noise in the fps estimate.
     // Interpolate rate_scale linearly, from 1.0 at sample #1, to 30.0 / fps
     // at sample #kStartupDelaySamples.
     if (_alphaCount < kStartupDelaySamples) {
       rate_scale =
           (_alphaCount * rate_scale + (kStartupDelaySamples - _alphaCount)) /
           kStartupDelaySamples;
     }
     alpha = pow(alpha, rate_scale);
   }

   double avgNoise = alpha * _avgNoise + (1 - alpha) * d_dT;
   double varNoise =
       alpha * _varNoise + (1 - alpha) * (d_dT - _avgNoise) * (d_dT - _avgNoise);
   if (!incompleteFrame || varNoise > _varNoise) {
     _avgNoise = avgNoise;
     _varNoise = varNoise;
   }
   if (_varNoise < 1.0) {
     // The variance should never be zero, since we might get
     // stuck and consider all samples as outliers.
     _varNoise = 1.0;
   }
 }

 double VCMJitterEstimator::NoiseThreshold() const {
   double noiseThreshold = _noiseStdDevs * sqrt(_varNoise) - _noiseStdDevOffset;
   if (noiseThreshold < 1.0) {
     noiseThreshold = 1.0;
   }
   return noiseThreshold;
 }

 // Calculates the current jitter estimate from the filtered estimates
 double VCMJitterEstimator::CalculateEstimate() {
   double ret = _theta[0] * (_maxFrameSize - _avgFrameSize) + NoiseThreshold();

   // A very low estimate (or negative) is neglected
   if (ret < 1.0) {
     if (_prevEstimate <= 0.01) {
       ret = 1.0;
     } else {
       ret = _prevEstimate;
     }
   }
   if (ret > 10000.0) {  // Sanity
     ret = 10000.0;
   }
   _prevEstimate = ret;
   return ret;
 }

 void VCMJitterEstimator::PostProcessEstimate() {
   _filterJitterEstimate = CalculateEstimate();
 }

 void VCMJitterEstimator::UpdateRtt(int64_t rttMs) {
   _rttFilter.Update(rttMs);
 }

 void VCMJitterEstimator::UpdateMaxFrameSize(uint32_t frameSizeBytes) {
   if (_maxFrameSize < frameSizeBytes) {
     _maxFrameSize = frameSizeBytes;
   }
 }

 // Returns the current filtered estimate if available,
 // otherwise tries to calculate an estimate.
 int VCMJitterEstimator::GetJitterEstimate(double rttMultiplier) {
   double jitterMS = CalculateEstimate() + OPERATING_SYSTEM_JITTER;
   uint64_t now = clock_->TimeInMicroseconds();

   if (now - _latestNackTimestamp > kNackCountTimeoutMs * 1000)
     _nackCount = 0;

   if (_filterJitterEstimate > jitterMS)
     jitterMS = _filterJitterEstimate;
   if (_nackCount >= _nackLimit)
     jitterMS += _rttFilter.RttMs() * rttMultiplier;

   static const double kJitterScaleLowThreshold = 5.0;
   static const double kJitterScaleHighThreshold = 10.0;
   double fps = GetFrameRate();
   // Ignore jitter for very low fps streams.
   if (fps < kJitterScaleLowThreshold) {
     if (fps == 0.0) {
       return rtc::checked_cast<int>(std::max(0.0, jitterMS) + 0.5);
     }
     return 0;
   }

   // Semi-low frame rate; scale by factor linearly interpolated from 0.0 at
   // kJitterScaleLowThreshold to 1.0 at kJitterScaleHighThreshold.
   if (fps < kJitterScaleHighThreshold) {
     jitterMS = (1.0 / (kJitterScaleHighThreshold - kJitterScaleLowThreshold)) *
                (fps - kJitterScaleLowThreshold) * jitterMS;
   }

   return rtc::checked_cast<int>(std::max(0.0, jitterMS) + 0.5);
 }

 double VCMJitterEstimator::GetFrameRate() const {
   if (fps_counter_.ComputeMean() == 0.0)
     return 0;

   double fps = 1000000.0 / fps_counter_.ComputeMean();
   // Sanity check.
   assert(fps >= 0.0);
   if (fps > kMaxFramerateEstimate) {
     fps = kMaxFramerateEstimate;
   }
   return fps;
 }
 }  // namespace webrtc
	/*
	* Copyright (c) 2011 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/video_coding/jitter_estimator.h"

	#include <assert.h>
	#include <math.h>
	#include <string.h>
	#include <algorithm>
	#include <cstdint>

	#include "absl/types/optional.h"
	#include "modules/video_coding/internal_defines.h"
	#include "modules/video_coding/rtt_filter.h"
	#include "rtc_base/experiments/jitter_upper_bound_experiment.h"
	#include "rtc_base/numerics/safe_conversions.h"
	#include "system_wrappers/include/clock.h"

	namespace webrtc {
	namespace {
	static constexpr uint32_t kStartupDelaySamples = 30;
	static constexpr int64_t kFsAccuStartupSamples = 5;
	static constexpr double kMaxFramerateEstimate = 200.0;
	static constexpr int64_t kNackCountTimeoutMs = 60000;
	static constexpr double kDefaultMaxTimestampDeviationInSigmas = 3.5;
	} // namespace

	VCMJitterEstimator::VCMJitterEstimator(Clock* clock,
	int32_t vcmId,
	int32_t receiverId)
	: _vcmId(vcmId),
	_receiverId(receiverId),
	_phi(0.97),
	_psi(0.9999),
	_alphaCountMax(400),
	_thetaLow(0.000001),
	_nackLimit(3),
	_numStdDevDelayOutlier(15),
	_numStdDevFrameSizeOutlier(3),
	_noiseStdDevs(2.33), // ~Less than 1% chance
	// (look up in normal distribution table)...
	_noiseStdDevOffset(30.0), // ...of getting 30 ms freezes
	_rttFilter(),
	fps_counter_(30), // TODO(sprang): Use an estimator with limit based on
	// time, rather than number of samples.
	time_deviation_upper_bound_(
	JitterUpperBoundExperiment::GetUpperBoundSigmas().value_or(
	kDefaultMaxTimestampDeviationInSigmas)),
	clock_(clock) {
	Reset();
	}

	VCMJitterEstimator::~VCMJitterEstimator() {}

	VCMJitterEstimator& VCMJitterEstimator::operator=(
	const VCMJitterEstimator& rhs) {
	if (this != &rhs) {
	memcpy(_thetaCov, rhs._thetaCov, sizeof(_thetaCov));
	memcpy(_Qcov, rhs._Qcov, sizeof(_Qcov));

	_vcmId = rhs._vcmId;
	_receiverId = rhs._receiverId;
	_avgFrameSize = rhs._avgFrameSize;
	_varFrameSize = rhs._varFrameSize;
	_maxFrameSize = rhs._maxFrameSize;
	_fsSum = rhs._fsSum;
	_fsCount = rhs._fsCount;
	_lastUpdateT = rhs._lastUpdateT;
	_prevEstimate = rhs._prevEstimate;
	_prevFrameSize = rhs._prevFrameSize;
	_avgNoise = rhs._avgNoise;
	_alphaCount = rhs._alphaCount;
	_filterJitterEstimate = rhs._filterJitterEstimate;
	_startupCount = rhs._startupCount;
	_latestNackTimestamp = rhs._latestNackTimestamp;
	_nackCount = rhs._nackCount;
	_rttFilter = rhs._rttFilter;
	clock_ = rhs.clock_;
	}
	return *this;
	}

	// Resets the JitterEstimate
	void VCMJitterEstimator::Reset() {
	_theta[0] = 1 / (512e3 / 8);
	_theta[1] = 0;
	_varNoise = 4.0;

	_thetaCov[0][0] = 1e-4;
	_thetaCov[1][1] = 1e2;
	_thetaCov[0][1] = _thetaCov[1][0] = 0;
	_Qcov[0][0] = 2.5e-10;
	_Qcov[1][1] = 1e-10;
	_Qcov[0][1] = _Qcov[1][0] = 0;
	_avgFrameSize = 500;
	_maxFrameSize = 500;
	_varFrameSize = 100;
	_lastUpdateT = -1;
	_prevEstimate = -1.0;
	_prevFrameSize = 0;
	_avgNoise = 0.0;
	_alphaCount = 1;
	_filterJitterEstimate = 0.0;
	_latestNackTimestamp = 0;
	_nackCount = 0;
	_latestNackTimestamp = 0;
	_fsSum = 0;
	_fsCount = 0;
	_startupCount = 0;
	_rttFilter.Reset();
	fps_counter_.Reset();
	}

	void VCMJitterEstimator::ResetNackCount() {
	_nackCount = 0;
	}

	// Updates the estimates with the new measurements
	void VCMJitterEstimator::UpdateEstimate(int64_t frameDelayMS,
	uint32_t frameSizeBytes,
	bool incompleteFrame /* = false */) {
	if (frameSizeBytes == 0) {
	return;
	}
	int deltaFS = frameSizeBytes - _prevFrameSize;
	if (_fsCount < kFsAccuStartupSamples) {
	_fsSum += frameSizeBytes;
	_fsCount++;
	} else if (_fsCount == kFsAccuStartupSamples) {
	// Give the frame size filter
	_avgFrameSize = static_cast<double>(_fsSum) / static_cast<double>(_fsCount);
	_fsCount++;
	}
	if (!incompleteFrame \|\| frameSizeBytes > _avgFrameSize) {
	double avgFrameSize = _phi * _avgFrameSize + (1 - _phi) * frameSizeBytes;
	if (frameSizeBytes < _avgFrameSize + 2 * sqrt(_varFrameSize)) {
	// Only update the average frame size if this sample wasn't a
	// key frame
	_avgFrameSize = avgFrameSize;
	}
	// Update the variance anyway since we want to capture cases where we only
	// get
	// key frames.
	_varFrameSize = VCM_MAX(
	_phi * _varFrameSize + (1 - _phi) * (frameSizeBytes - avgFrameSize) *
	(frameSizeBytes - avgFrameSize),
	1.0);
	}

	// Update max frameSize estimate
	_maxFrameSize =
	VCM_MAX(_psi * _maxFrameSize, static_cast<double>(frameSizeBytes));

	if (_prevFrameSize == 0) {
	_prevFrameSize = frameSizeBytes;
	return;
	}
	_prevFrameSize = frameSizeBytes;

	// Cap frameDelayMS based on the current time deviation noise.
	int64_t max_time_deviation_ms =
	static_cast<int64_t>(time_deviation_upper_bound_ * sqrt(_varNoise) + 0.5);
	frameDelayMS = std::max(std::min(frameDelayMS, max_time_deviation_ms),
	-max_time_deviation_ms);

	// Only update the Kalman filter if the sample is not considered
	// an extreme outlier. Even if it is an extreme outlier from a
	// delay point of view, if the frame size also is large the
	// deviation is probably due to an incorrect line slope.
	double deviation = DeviationFromExpectedDelay(frameDelayMS, deltaFS);

	if (fabs(deviation) < _numStdDevDelayOutlier * sqrt(_varNoise) \|\|
	frameSizeBytes >
	_avgFrameSize + _numStdDevFrameSizeOutlier * sqrt(_varFrameSize)) {
	// Update the variance of the deviation from the
	// line given by the Kalman filter
	EstimateRandomJitter(deviation, incompleteFrame);
	// Prevent updating with frames which have been congested by a large
	// frame, and therefore arrives almost at the same time as that frame.
	// This can occur when we receive a large frame (key frame) which
	// has been delayed. The next frame is of normal size (delta frame),
	// and thus deltaFS will be << 0. This removes all frame samples
	// which arrives after a key frame.
	if ((!incompleteFrame \|\| deviation >= 0.0) &&
	static_cast<double>(deltaFS) > -0.25 * _maxFrameSize) {
	// Update the Kalman filter with the new data
	KalmanEstimateChannel(frameDelayMS, deltaFS);
	}
	} else {
	int nStdDev =
	(deviation >= 0) ? _numStdDevDelayOutlier : -_numStdDevDelayOutlier;
	EstimateRandomJitter(nStdDev * sqrt(_varNoise), incompleteFrame);
	}
	// Post process the total estimated jitter
	if (_startupCount >= kStartupDelaySamples) {
	PostProcessEstimate();
	} else {
	_startupCount++;
	}
	}

	// Updates the nack/packet ratio
	void VCMJitterEstimator::FrameNacked() {
	if (_nackCount < _nackLimit) {
	_nackCount++;
	}
	_latestNackTimestamp = clock_->TimeInMicroseconds();
	}

	// Updates Kalman estimate of the channel
	// The caller is expected to sanity check the inputs.
	void VCMJitterEstimator::KalmanEstimateChannel(int64_t frameDelayMS,
	int32_t deltaFSBytes) {
	double Mh[2];
	double hMh_sigma;
	double kalmanGain[2];
	double measureRes;
	double t00, t01;

	// Kalman filtering

	// Prediction
	// M = M + Q
	_thetaCov[0][0] += _Qcov[0][0];
	_thetaCov[0][1] += _Qcov[0][1];
	_thetaCov[1][0] += _Qcov[1][0];
	_thetaCov[1][1] += _Qcov[1][1];

	// Kalman gain
	// K = Mh'/(sigma2n + hMh') = Mh'/(1 + hMh')
	// h = [dFS 1]
	// Mh = M*h'
	// hMh_sigma = hMh' + R
	Mh[0] = _thetaCov[0][0] * deltaFSBytes + _thetaCov[0][1];
	Mh[1] = _thetaCov[1][0] * deltaFSBytes + _thetaCov[1][1];
	// sigma weights measurements with a small deltaFS as noisy and
	// measurements with large deltaFS as good
	if (_maxFrameSize < 1.0) {
	return;
	}
	double sigma = (300.0 * exp(-fabs(static_cast<double>(deltaFSBytes)) /
	(1e0 * _maxFrameSize)) +
	1) *
	sqrt(_varNoise);
	if (sigma < 1.0) {
	sigma = 1.0;
	}
	hMh_sigma = deltaFSBytes * Mh[0] + Mh[1] + sigma;
	if ((hMh_sigma < 1e-9 && hMh_sigma >= 0) \|\|
	(hMh_sigma > -1e-9 && hMh_sigma <= 0)) {
	assert(false);
	return;
	}
	kalmanGain[0] = Mh[0] / hMh_sigma;
	kalmanGain[1] = Mh[1] / hMh_sigma;

	// Correction
	// theta = theta + K(dT - htheta)
	measureRes = frameDelayMS - (deltaFSBytes * _theta[0] + _theta[1]);
	_theta[0] += kalmanGain[0] * measureRes;
	_theta[1] += kalmanGain[1] * measureRes;

	if (_theta[0] < _thetaLow) {
	_theta[0] = _thetaLow;
	}

	// M = (I - Kh)M
	t00 = _thetaCov[0][0];
	t01 = _thetaCov[0][1];
	_thetaCov[0][0] = (1 - kalmanGain[0] * deltaFSBytes) * t00 -
	kalmanGain[0] * _thetaCov[1][0];
	_thetaCov[0][1] = (1 - kalmanGain[0] * deltaFSBytes) * t01 -
	kalmanGain[0] * _thetaCov[1][1];
	_thetaCov[1][0] = _thetaCov[1][0] * (1 - kalmanGain[1]) -
	kalmanGain[1] * deltaFSBytes * t00;
	_thetaCov[1][1] = _thetaCov[1][1] * (1 - kalmanGain[1]) -
	kalmanGain[1] * deltaFSBytes * t01;

	// Covariance matrix, must be positive semi-definite
	assert(_thetaCov[0][0] + _thetaCov[1][1] >= 0 &&
	_thetaCov[0][0] * _thetaCov[1][1] -
	_thetaCov[0][1] * _thetaCov[1][0] >=
	0 &&
	_thetaCov[0][0] >= 0);
	}

	// Calculate difference in delay between a sample and the
	// expected delay estimated by the Kalman filter
	double VCMJitterEstimator::DeviationFromExpectedDelay(
	int64_t frameDelayMS,
	int32_t deltaFSBytes) const {
	return frameDelayMS - (_theta[0] * deltaFSBytes + _theta[1]);
	}

	// Estimates the random jitter by calculating the variance of the
	// sample distance from the line given by theta.
	void VCMJitterEstimator::EstimateRandomJitter(double d_dT,
	bool incompleteFrame) {
	uint64_t now = clock_->TimeInMicroseconds();
	if (_lastUpdateT != -1) {
	fps_counter_.AddSample(now - _lastUpdateT);
	}
	_lastUpdateT = now;

	if (_alphaCount == 0) {
	assert(false);
	return;
	}
	double alpha =
	static_cast<double>(_alphaCount - 1) / static_cast<double>(_alphaCount);
	_alphaCount++;
	if (_alphaCount > _alphaCountMax)
	_alphaCount = _alphaCountMax;

	// In order to avoid a low frame rate stream to react slower to changes,
	// scale the alpha weight relative a 30 fps stream.
	double fps = GetFrameRate();
	if (fps > 0.0) {
	double rate_scale = 30.0 / fps;
	// At startup, there can be a lot of noise in the fps estimate.
	// Interpolate rate_scale linearly, from 1.0 at sample #1, to 30.0 / fps
	// at sample #kStartupDelaySamples.
	if (_alphaCount < kStartupDelaySamples) {
	rate_scale =
	(_alphaCount * rate_scale + (kStartupDelaySamples - _alphaCount)) /
	kStartupDelaySamples;
	}
	alpha = pow(alpha, rate_scale);
	}

	double avgNoise = alpha * _avgNoise + (1 - alpha) * d_dT;
	double varNoise =
	alpha * _varNoise + (1 - alpha) * (d_dT - _avgNoise) * (d_dT - _avgNoise);
	if (!incompleteFrame \|\| varNoise > _varNoise) {
	_avgNoise = avgNoise;
	_varNoise = varNoise;
	}
	if (_varNoise < 1.0) {
	// The variance should never be zero, since we might get
	// stuck and consider all samples as outliers.
	_varNoise = 1.0;
	}
	}

	double VCMJitterEstimator::NoiseThreshold() const {
	double noiseThreshold = _noiseStdDevs * sqrt(_varNoise) - _noiseStdDevOffset;
	if (noiseThreshold < 1.0) {
	noiseThreshold = 1.0;
	}
	return noiseThreshold;
	}

	// Calculates the current jitter estimate from the filtered estimates
	double VCMJitterEstimator::CalculateEstimate() {
	double ret = _theta[0] * (_maxFrameSize - _avgFrameSize) + NoiseThreshold();

	// A very low estimate (or negative) is neglected
	if (ret < 1.0) {
	if (_prevEstimate <= 0.01) {
	ret = 1.0;
	} else {
	ret = _prevEstimate;
	}
	}
	if (ret > 10000.0) { // Sanity
	ret = 10000.0;
	}
	_prevEstimate = ret;
	return ret;
	}

	void VCMJitterEstimator::PostProcessEstimate() {
	_filterJitterEstimate = CalculateEstimate();
	}

	void VCMJitterEstimator::UpdateRtt(int64_t rttMs) {
	_rttFilter.Update(rttMs);
	}

	void VCMJitterEstimator::UpdateMaxFrameSize(uint32_t frameSizeBytes) {
	if (_maxFrameSize < frameSizeBytes) {
	_maxFrameSize = frameSizeBytes;
	}
	}

	// Returns the current filtered estimate if available,
	// otherwise tries to calculate an estimate.
	int VCMJitterEstimator::GetJitterEstimate(double rttMultiplier) {
	double jitterMS = CalculateEstimate() + OPERATING_SYSTEM_JITTER;
	uint64_t now = clock_->TimeInMicroseconds();

	if (now - _latestNackTimestamp > kNackCountTimeoutMs * 1000)
	_nackCount = 0;

	if (_filterJitterEstimate > jitterMS)
	jitterMS = _filterJitterEstimate;
	if (_nackCount >= _nackLimit)
	jitterMS += _rttFilter.RttMs() * rttMultiplier;

	static const double kJitterScaleLowThreshold = 5.0;
	static const double kJitterScaleHighThreshold = 10.0;
	double fps = GetFrameRate();
	// Ignore jitter for very low fps streams.
	if (fps < kJitterScaleLowThreshold) {
	if (fps == 0.0) {
	return rtc::checked_cast<int>(std::max(0.0, jitterMS) + 0.5);
	}
	return 0;
	}

	// Semi-low frame rate; scale by factor linearly interpolated from 0.0 at
	// kJitterScaleLowThreshold to 1.0 at kJitterScaleHighThreshold.
	if (fps < kJitterScaleHighThreshold) {
	jitterMS = (1.0 / (kJitterScaleHighThreshold - kJitterScaleLowThreshold)) *
	(fps - kJitterScaleLowThreshold) * jitterMS;
	}

	return rtc::checked_cast<int>(std::max(0.0, jitterMS) + 0.5);
	}

	double VCMJitterEstimator::GetFrameRate() const {
	if (fps_counter_.ComputeMean() == 0.0)
	return 0;

	double fps = 1000000.0 / fps_counter_.ComputeMean();
	// Sanity check.
	assert(fps >= 0.0);
	if (fps > kMaxFramerateEstimate) {
	fps = kMaxFramerateEstimate;
	}
	return fps;
	}
	} // namespace webrtc