modules/video_coding/timing/frame_delay_variation_kalman_filter.h - src - Git at Google

 /*
  *  Copyright (c) 2022 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.
  */

 #ifndef MODULES_VIDEO_CODING_TIMING_FRAME_DELAY_VARIATION_KALMAN_FILTER_H_
 #define MODULES_VIDEO_CODING_TIMING_FRAME_DELAY_VARIATION_KALMAN_FILTER_H_

 #include "api/units/data_size.h"
 #include "api/units/time_delta.h"

 namespace webrtc {

 // This class uses a linear Kalman filter (see
 // https://en.wikipedia.org/wiki/Kalman_filter) to estimate the frame delay
 // variation (i.e., the difference in transmission time between a frame and the
 // prior frame) for a frame, given its size variation in bytes (i.e., the
 // difference in size between a frame and the prior frame). The idea is that,
 // given a fixed link bandwidth, a larger frame (in bytes) would take
 // proportionally longer to arrive than a correspondingly smaller frame. Using
 // the variations of frame delay and frame size, the underlying bandwidth and
 // queuing delay variation of the network link can be estimated.
 //
 // The filter takes as input the frame delay variation, the difference between
 // the actual inter-frame arrival time and the expected inter-frame arrival time
 // (based on RTP timestamp), and frame size variation, the inter-frame size
 // delta for a single frame. The frame delay variation is seen as the
 // measurement and the frame size variation is used in the observation model.
 // The hidden state of the filter is the link bandwidth and queuing delay
 // buildup. The estimated state can be used to get the expected frame delay
 // variation for a frame, given its frame size variation. This information can
 // then be used to estimate the frame delay variation coming from network
 // jitter.
 //
 // Mathematical details:
 //  * The state (`x` in Wikipedia notation) is a 2x1 vector comprising the
 //    reciprocal of link bandwidth [1 / bytes per ms] and the
 //    link queuing delay buildup [ms].
 //  * The state transition matrix (`F`) is the 2x2 identity matrix, meaning that
 //    link bandwidth and link queuing delay buildup are modeled as independent.
 //  * The measurement (`z`) is the (scalar) frame delay variation [ms].
 //  * The observation matrix (`H`) is a 1x2 vector set as
 //    `{frame_size_variation [bytes], 1.0}`.
 //  * The state estimate covariance (`P`) is a symmetric 2x2 matrix.
 //  * The process noise covariance (`Q`) is a constant 2x2 diagonal matrix
 //    [(1 / bytes per ms)^2, ms^2].
 //  * The observation noise covariance (`r`) is a scalar [ms^2] that is
 //    determined externally to this class.
 class FrameDelayVariationKalmanFilter {
  public:
   FrameDelayVariationKalmanFilter();
   ~FrameDelayVariationKalmanFilter() = default;

   // Predicts and updates the filter, given a new pair of frame delay variation
   // and frame size variation.
   //
   // Inputs:
   // `frame_delay_variation_ms`:
   //    Frame delay variation as calculated by the `InterFrameDelay` estimator.
   //
   // `frame_size_variation_bytes`:
   //    Frame size variation, i.e., the current frame size minus the previous
   //    frame size (in bytes). Note that this quantity may be negative.
   //
   // `max_frame_size_bytes`:
   //    Filtered largest frame size received since the last reset.
   //
   // `var_noise`:
   //    Variance of the estimated random jitter.
   //
   // TODO(bugs.webrtc.org/14381): For now use doubles as input parameters as
   // units defined in api/units have insufficient underlying precision for
   // jitter estimation.
   void PredictAndUpdate(double frame_delay_variation_ms,
                         double frame_size_variation_bytes,
                         double max_frame_size_bytes,
                         double var_noise);

   // Given a frame size variation, returns the estimated frame delay variation
   // explained by the link bandwidth alone.
   double GetFrameDelayVariationEstimateSizeBased(
       double frame_size_variation_bytes) const;

   // Given a frame size variation, returns the estimated frame delay variation
   // explained by both link bandwidth and link queuing delay buildup.
   double GetFrameDelayVariationEstimateTotal(
       double frame_size_variation_bytes) const;

  private:
   // State estimate (bandwidth [1 / bytes per ms], queue buildup [ms]).
   double estimate_[2];
   double estimate_cov_[2][2];  // Estimate covariance.

   // Process noise covariance. This is a diagonal matrix, so we only store the
   // diagonal entries.
   double process_noise_cov_diag_[2];
 };

 }  // namespace webrtc

 #endif  // MODULES_VIDEO_CODING_TIMING_FRAME_DELAY_VARIATION_KALMAN_FILTER_H_
	/*
	* Copyright (c) 2022 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.
	*/

	#ifndef MODULES_VIDEO_CODING_TIMING_FRAME_DELAY_VARIATION_KALMAN_FILTER_H_
	#define MODULES_VIDEO_CODING_TIMING_FRAME_DELAY_VARIATION_KALMAN_FILTER_H_

	#include "api/units/data_size.h"
	#include "api/units/time_delta.h"

	namespace webrtc {

	// This class uses a linear Kalman filter (see
	// https://en.wikipedia.org/wiki/Kalman_filter) to estimate the frame delay
	// variation (i.e., the difference in transmission time between a frame and the
	// prior frame) for a frame, given its size variation in bytes (i.e., the
	// difference in size between a frame and the prior frame). The idea is that,
	// given a fixed link bandwidth, a larger frame (in bytes) would take
	// proportionally longer to arrive than a correspondingly smaller frame. Using
	// the variations of frame delay and frame size, the underlying bandwidth and
	// queuing delay variation of the network link can be estimated.
	//
	// The filter takes as input the frame delay variation, the difference between
	// the actual inter-frame arrival time and the expected inter-frame arrival time
	// (based on RTP timestamp), and frame size variation, the inter-frame size
	// delta for a single frame. The frame delay variation is seen as the
	// measurement and the frame size variation is used in the observation model.
	// The hidden state of the filter is the link bandwidth and queuing delay
	// buildup. The estimated state can be used to get the expected frame delay
	// variation for a frame, given its frame size variation. This information can
	// then be used to estimate the frame delay variation coming from network
	// jitter.
	//
	// Mathematical details:
	// * The state (`x` in Wikipedia notation) is a 2x1 vector comprising the
	// reciprocal of link bandwidth [1 / bytes per ms] and the
	// link queuing delay buildup [ms].
	// * The state transition matrix (`F`) is the 2x2 identity matrix, meaning that
	// link bandwidth and link queuing delay buildup are modeled as independent.
	// * The measurement (`z`) is the (scalar) frame delay variation [ms].
	// * The observation matrix (`H`) is a 1x2 vector set as
	// `{frame_size_variation [bytes], 1.0}`.
	// * The state estimate covariance (`P`) is a symmetric 2x2 matrix.
	// * The process noise covariance (`Q`) is a constant 2x2 diagonal matrix
	// [(1 / bytes per ms)^2, ms^2].
	// * The observation noise covariance (`r`) is a scalar [ms^2] that is
	// determined externally to this class.
	class FrameDelayVariationKalmanFilter {
	public:
	FrameDelayVariationKalmanFilter();
	~FrameDelayVariationKalmanFilter() = default;

	// Predicts and updates the filter, given a new pair of frame delay variation
	// and frame size variation.
	//
	// Inputs:
	// `frame_delay_variation_ms`:
	// Frame delay variation as calculated by the `InterFrameDelay` estimator.
	//
	// `frame_size_variation_bytes`:
	// Frame size variation, i.e., the current frame size minus the previous
	// frame size (in bytes). Note that this quantity may be negative.
	//
	// `max_frame_size_bytes`:
	// Filtered largest frame size received since the last reset.
	//
	// `var_noise`:
	// Variance of the estimated random jitter.
	//
	// TODO(bugs.webrtc.org/14381): For now use doubles as input parameters as
	// units defined in api/units have insufficient underlying precision for
	// jitter estimation.
	void PredictAndUpdate(double frame_delay_variation_ms,
	double frame_size_variation_bytes,
	double max_frame_size_bytes,
	double var_noise);

	// Given a frame size variation, returns the estimated frame delay variation
	// explained by the link bandwidth alone.
	double GetFrameDelayVariationEstimateSizeBased(
	double frame_size_variation_bytes) const;

	// Given a frame size variation, returns the estimated frame delay variation
	// explained by both link bandwidth and link queuing delay buildup.
	double GetFrameDelayVariationEstimateTotal(
	double frame_size_variation_bytes) const;

	private:
	// State estimate (bandwidth [1 / bytes per ms], queue buildup [ms]).
	double estimate_[2];
	double estimate_cov_[2][2]; // Estimate covariance.

	// Process noise covariance. This is a diagonal matrix, so we only store the
	// diagonal entries.
	double process_noise_cov_diag_[2];
	};

	} // namespace webrtc

	#endif // MODULES_VIDEO_CODING_TIMING_FRAME_DELAY_VARIATION_KALMAN_FILTER_H_