+==============+===================================+================+
   | Notation     | Parameter Name                    | Example Value  |
   +==============+===================================+================+
   | R_v(t)       | Target rate request at time t     |      1 Mbps    |
   +--------------+-----------------------------------+----------------+
   | R_o(t)       | Output rate at time t             |    1.2 Mbps    |
   +--------------+-----------------------------------+----------------+
   | tau_v        | Encoder reaction latency          |    0.2 s       |
   +--------------+-----------------------------------+----------------+
   | K_d          | Burst duration during transient   |      8 frames  |
   +--------------+-----------------------------------+----------------+
   | K_B          | Burst frame size during transient |   13.5 KBytes* |
   +--------------+-----------------------------------+----------------+
   | R_e(t)       | Error in output rate at time t    |    0.2 Mbps    |
   +--------------+-----------------------------------+----------------+
   | SIGMA_t      | standard deviation of normalized  |                |
   |              | frame interval   (t/t0)           |   0.25         |
   +--------------+-----------------------------------+----------------+
   | SIGMA_B      | standard deviation of normalized  |    0.1         |
   |              | frame size  (B/B0)		          |                | 
   +--------------+-----------------------------------+----------------+
   | R_min        | minimum rate supported by video   |    150 Kbps    |
   |              | encoder or content activity       |                |
   +--------------+-----------------------------------+----------------+
   | R_max        | maximum rate supported by video   |    1.5 Mbps    |
   |              | encoder or content activity       |                |
   +==============+===================================+================+

   * Example value of K_B for a video stream encoded at 720p and 30 frames
    per second, using H.264/AVC encoder.  

	

Figure 2: List of tunable parameters in a statistical video traffic source model.

5.1. Time-damped response to target rate update

While the congestion control module can update its target rate request R_v(t) at any time, our model dictates that the encoder will only react to such changes after tau_v seconds from a previous rate transition. In other words, when the encoder has reacted to a rate change request at time t, it will simply ignore all subsequent rate change requests until time t+tau_v.

5.2. Temporary burst and oscillation during transient

The output rate R_o during the period [t, t+tau_v] is considered to be in transient. Based on observations from video encoder output data, we model the transient behavior of an encoder upon reacting to a new target rate request in the form of high variation in output frame sizes. It is assumed that the overall average output rate R_o during this period matches the target rate R_v. Consequently, the occasional burst of large frames are followed by smaller-than average encoded frames.

This temporary burst is characterized by two parameters:

• burst duration K_d: number frames in the burst event; and
• burst frame size K_B: size of the initial burst frame which is typically significantly larger than average frame size at steady state.

It can be noted that these burst parameters can also be used to mimic the insertion of a large on-demand I frame in the presence of severe packet losses. The values of K_d and K_B typically depend on the type of video codec, spatial and temporal resolution of the encoded stream, as well as the video content activity level.

5.3. Output rate fluctuation at steady state

We model output rate R_o as randomly fluctuating around the target rate R_v after convergence. There exist two sources of variations in the encoder output:

• Fluctuations in frame interval: the intervals between adjacent frames have been observed to fluctuate around the reference interval of t0 = 1/FPS. They roughly follow a Gaussian distribution, and can be modelled with the parameter SIGMA_t, which denotes the standard deviation of the normalized frame interval (ratio between actual and reference frame interval).
• Fluctuations in frame size: size of the output encoded frames also tend to fluctuate around the reference frame size B0=R_v/8/FPS. They can also be modelled via a Gaussian distribution, with the SIGMA_B denoting the standard deviation of the normalized frame size (ratio between actual and reference frame size).

Both values of SIGMA_t and SIGMA_B can be obtained via parameter fitting from empirical data captured for a given video encoder.

5.4. Rate range limit imposed by video content

The output rate R_o is further clipped within the dynamic range [R_min, R_max], which in reality are dictated by scene and motion complexity of the captured video content. In our model, these parameters are specified by the application.

6. A Trace-Driven Model

We now present the second approach to model a video traffic source. This approach is based on running an actual live video encoder offline on a set of chosen raw video sequences and using the encoder's output traces for constructing a synthetic live encoder. With this approach, the recorded video traces naturally exhibit temporal fluctuations around a given target rate request R_v(t) from the congestion control module.

The following list summarizes this approach's main steps:

1) Choose one or more representative raw video sequences.

2) Using an actual live video encoder, encode the sequences at various bitrates. Keep just the sequences of frame sizes for each bitrate.

3) Construct a data structure that contains the output of the previous step. The data structure should allow for easy bitrate lookup.

4) Upon a target bitrate request R_v(t) from the controller, look up the closest bitrates among those previously stored. Use the frame size sequences stored for those bitrates to approximate the frame sizes to output.

5) The output of the synthetic encoder contains "encoded" frames with zeros as contents but with realistic sizes.

Section 6.1 explains steps 1), 2), and 3), Section 6.2 elaborates on steps 4) and 5). Finally, Section 6.3 briefly discusses the possibility to extend the model for supporting variable frame rate and/or variable frame resolution.

6.1. Choosing the video sequence and generating the traces

The first step we need to perform is a careful choice of a set of video sequences that are representative of the use cases we want to model. Our use case here is video conferencing, so we must choose a low-motion sequence that resembles a "talking head", for instance a news broadcast or a video capture of an actual conference call.

The length of the chosen video sequence is a tradeoff. If it is too long, it will be difficult to manage the data structures containing the traces. If it is too short, there will be an obvious periodic pattern in the output frame sizes, leading to biased results when evaluating congestion controller performance. In our experience, a one-minute-long sequence is a fair tradeoff.

Once we have chosen the raw video sequence, denoted S, we use a live encoder, e.g. [H264] or [HEVC] to produce a set of encoded sequences. As discussed in Section 3, a live encoder's output bitrate can be tuned by varying three input parameters, namely, quantization step size, frame rate, and picture resolution. In order to simplify the choice of these parameters for a given target rate, we assume a fixed frame rate (e.g. 25 fps) and a fixed resolution (e.g., 480p). See section 6.3 for a discussion on how to relax these assumptions.

Following these simplifications, we run the chosen encoder by setting a constant target bitrate at the beginning, then letting the encoder vary the quantization step size internally while encoding the input video sequence. Besides, we assume that the first frame is encoded as an I-frame and the rest are P-frames. We further assume that the encoder algorithm does not use knowledge of frames in the future so as to encode a given frame.

We define R_min and R_max as the minimum and maximum bitrate at which the synthetic codec is to operate. We divide the bitrate range between R_min and R_max in n_s + 1 bitrate steps of length l = (R_max - R_min) / n_s. We then use the following simple algorithm to encode the raw video sequence.

    r = R_min
    while r <= R_max do
        Traces[r] = encode_sequence(S, r, e)
        r = r + l
    

where function encode_sequence takes as parameters, respectively, a raw video sequence, a constant target rate, and an encoder algorithm; it returns a vector with the sizes of frames in the order they were encoded. The output vector is stored in a map structure called Traces, whose keys are bitrates and values are frame size vectors.

The choice of a value for n_s is important, as it determines the number of frame size vectors stored in map Traces. The minimum value one can choose for n_s is 1, and its maximum value depends on the amount of memory available for holding the map Traces. A reasonable value for n_s is one that makes the steps' length l = 200 kbps. We will further discuss step length l in the next section.

6.2. Using the traces in the syntethic codec

The main idea behind the trace-driven synthetic codec is that it mimics a real live codec's rate adaptation when the congestion controller updates the target rate R_v(t). It does so by switching to a different frame size vector stored in the map Traces when needed.

6.2.1. Main algorithm

We maintain two variables r_current and t_current:

* r_current points to one of the keys of the map Traces. Upon a change in the value of R_v(t), typically because the congestion controller detects that the network conditions have changed, r_current is updated to the greatest key in Traces that is less than or equal to the new value of R_v(t). For the moment, we assume the value of R_v(t) to be clipped in the range [R_min, R_max].

        r_current = r
        such that
           ( r in keys(Traces)  and
           r <= R_v(t)  and
       	(not(exists) r' in keys(Traces) such that r < r' <= R_v(t)) )
        
	

* t_current is an index to the frame size vector stored in Traces[r_current]. It is updated every time a new frame is due. We assume all vectors stored in Traces to have the same size, denoted size_traces. The following equation governs the update of t_current:

	  
          if t_current < SkipFrames then
              t_current = t_current + 1
    	  else
              t_current = ((t_current+1-SkipFrames) % (size_traces- SkipFrames))
            	          + SkipFrames
    	

where operator % denotes modulo, and SkipFrames is a predefined constant that denotes the number of frames to be skipped at the beginning of frame size vectors after t_current has wrapped around. The point of constant SkipFrames is avoiding the effect of periodically sending a (big) I-frame followed by several smaller- than-normal P-frames. We typically set SkipFrames to 20, although it could be set to 0 if we are interested in studying the effect of sending I-frames periodically.

We initialize r_current to R_min, and t_current to 0.

When a new frame is due, we need to calculate its size. There are three cases:

a) R_min <= R_v(t) < Rmax:

In this case we use linear interpolation of the frame sizes appearing in Traces[r_current] and Traces[r_current + l]. The interpolation is done as follows:

	size_lo = Traces[r_current][t_current]
       	size_hi = Traces[r_current + l][t_current]
       	distance_lo = ( R_v(t) - r_current ) / l
       	framesize = size_hi * distance_lo + size_lo * (1 - distance_lo)    
	

b) R_v(t) < R_min:

In this case, we scale the trace sequence with the lowest bitrate, in the following way:

	factor = R_v(t) / R_min
       	framesize = max(1, factor * Traces[R_min][t_current])
    	

c) R_v(t) >= R_max:

We also use scaling for this case. We use the trace sequence with the greatest bitrate:

	factor = R_v(t) / R_max
        framesize = factor * Traces[R_max][t_current]
    	

In case b), we set the minimum to 1 byte, since the value of factor can be arbitrarily close to 0.

6.2.2. Notes to the main algorithm

* Reacting to changes in target bitrate. Similarly to the statistical model presented in Section 5, the trace-driven synthetic codec can have a time bound, tau_v, to reacting to target bitrate changes. If the codec has reacted to an update in R_v(t) at time t, it will delay any further update to R_v(t) to time t + tau_v. Note that, in any case, the value of tau_v cannot be chosen shorter than the time between frames, i.e. the inverse of the frame rate.

* I-frames on demand. The synthetic codec could be extended to simulate the sending of I-frames on demand, e.g., as a reaction to losses. To implement this extension, the codec's API is augmented with a new function to request a new I-frame. Upon calling such function, t_current is reset to 0.

* Variable length l of steps defined between R_min and R_max. In the main algorithm's description, the step length l is fixed. However, if the range [R_min, R_max] is very wide, it is also possible to define a set of steps with a non-constant length. The idea behind this modification is that the difference between 400 kbps and 600 kbps as bitrate is much more important than the difference between 4400 kbps and 4600 kbps. For example, one could define steps of length 200 Kbps under 1 Mbps, then length 300 kbps between 1 Mbps and 2 Mbps, 400 kbps between 2 Mbps and 3 Mbps, and so on.

6.3. Varying frame rate and resolution

The trace-driven synthetic codec model explained in this section is relatively simple because we have fixed the frame rate and the frame resolution. The model could be extended to have variable frame rate, variable spatial resolution, or both.

When the encoded picture quality at a given bitrate is low, one can potentially decrease the frame rate (if the video sequence is currently in low motion) or the spatial resolution in order to improve quality-of-experince (QoE) in the overall encoded video. On the other hand, if target bitrate increases to a point where there is no longer a perceptible improvement in the picture quality of individual frames, then one might afford to increase the spatial resolution or the frame rate (useful if the video is currently in high motion).

Many techniques have been proposed to choose over time the best combination of encoder quatization step size, frame rate, and spatial resolution in order to maximize the quality of live video codecs [Ozer2011][Hu2010]. Future work may consider extending the trace-driven codec to accommodate variable frame rate and/or resolution.

From the perspective of congestion control, varying the spatial resolution typically requires a new intra-coded frame to be generated, thereby incurring a temporary burst in the output traffic pattern. The impact of frame rate change tends to be more subtle: reducing frame rate from high to low leads to sparsely spaced larger encoded packets instead of many densely spaced smaller packets. Such difference in traffic profiles may still affect the performance of congestion control, especially when outgoing packets are not paced at the transport module. We leave the investigation of varying frame rate to future work.

7. Combining The Two Models

It is worthwhile noting that the statistical and trace-driven models each has its own advantages and drawbacks. While both models are fairly simple to implement, it takes significantly greater effort to fit the parameters of a statistical model to actual encoder output data whereas it is straightforward for a trace-driven model to obtain encoded frame size data. On the other hand, once validated, the statistical model is more flexible in mimicking a wide range of encoder/content behaviors by simply varying the correponding parameters in the model. In this regard, a trace-driven model relies -- by definition -- on additional data collection efforts for accommodating new codecs or video contents.

In general, trace-driven model is more realistic for mimicking ongoing, steady-state behavior of a video traffic source whereas statistical model is more versatile for simulating transient events (e.g., when target rate changes from A to B with temporary bursts during the transition). It is also possible to combine both models into a hybrid approach, using traces during steady-state and statistical model during transients.

                                      +---------------+
                            transient | Generate next |
                              +------>| K_d transient |
            +-------------+  /        |    frames     |
     R_v(t) |   Compare   | /         +---------------+
    ------->|   against   |/  
            |   previous  | 
            | target rate |\  
            +-------------+ \         +---------------+       
                             \        | Generate next | 
                              +------>|  frame from   |
                        steady-state  |    trace      |    
                                      +---------------+