Network Working Group A. Morton
Request for Comments: 5481 AT&T Labs
Category: Informational B. Claise
Cisco Systems, Inc.
March 2009
Packet Delay Variation Applicability Statement
Status of This Memo
This memo provides information for the Internet community. It does
not specify an Internet standard of any kind. Distribution of this
memo is unlimited.
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Abstract
Packet delay variation metrics appear in many different standards
documents. The metric definition in RFC 3393 has considerable
flexibility, and it allows multiple formulations of delay variation
through the specification of different packet selection functions.
Although flexibility provides wide coverage and room for new ideas,
it can make comparisons of independent implementations more
difficult. Two different formulations of delay variation have come
into wide use in the context of active measurements. This memo
examines a range of circumstances for active measurements of delay
variation and their uses, and recommends which of the two forms is
best matched to particular conditions and tasks.
Table of Contents
1. Introduction ....................................................4
1.1. Requirements Language ......................................5
1.2. Background Literature in IPPM and Elsewhere ................5
1.3. Organization of the Memo ...................................6
2. Purpose and Scope ...............................................7
3. Brief Descriptions of Delay Variation Uses ......................7
3.1. Inferring Queue Occupation on a Path .......................7
3.2. Determining De-Jitter Buffer Size ..........................8
3.3. Spatial Composition .......................................10
3.4. Service-Level Comparison ..................................10
3.5. Application-Layer FEC Design ..............................10
4. Formulations of IPDV and PDV ...................................10
4.1. IPDV: Inter-Packet Delay Variation ........................11
4.2. PDV: Packet Delay Variation ...............................11
4.3. A "Point" about Measurement Points ........................12
4.4. Examples and Initial Comparisons ..........................12
5. Survey of Earlier Comparisons ..................................13
5.1. Demichelis' Comparison ....................................13
5.2. Ciavattone et al. .........................................15
5.3. IPPM List Discussion from 2000 ............................16
5.4. Y.1540 Appendix II ........................................18
5.5. Clark's ITU-T SG 12 Contribution ..........................18
6. Additional Properties and Comparisons ..........................18
6.1. Packet Loss ...............................................18
6.2. Path Changes ..............................................19
6.2.1. Lossless Path Change ...............................20
6.2.2. Path Change with Loss ..............................21
6.3. Clock Stability and Error .................................22
6.4. Spatial Composition .......................................24
6.5. Reporting a Single Number (SLA) ...........................24
6.6. Jitter in RTCP Reports ....................................25
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6.7. MAPDV2 ....................................................25
6.8. Load Balancing ............................................26
7. Applicability of the Delay Variation Forms and
Recommendations ................................................27
7.1. Uses ......................................................27
7.1.1. Inferring Queue Occupancy ..........................27
7.1.2. Determining De-Jitter Buffer Size (and FEC
Design) ............................................27
7.1.3. Spatial Composition ................................28
7.1.4. Service-Level Specification: Reporting a
Single Number ......................................28
7.2. Challenging Circumstances .................................28
7.2.1. Clock and Storage Issues ...........................28
7.2.2. Frequent Path Changes ..............................29
7.2.3. Frequent Loss ......................................29
7.2.4. Load Balancing .....................................29
7.3. Summary ...................................................30
8. Measurement Considerations .....................................31
8.1. Measurement Stream Characteristics ........................31
8.2. Measurement Devices .......................................32
8.3. Units of Measurement ......................................33
8.4. Test Duration .............................................33
8.5. Clock Sync Options ........................................33
8.6. Distinguishing Long Delay from Loss .......................34
8.7. Accounting for Packet Reordering ..........................34
8.8. Results Representation and Reporting ......................35
9. Security Considerations ........................................35
10. Acknowledgments ...............................................35
11. Appendix on Calculating the D(min) in PDV .....................35
12. References ....................................................36
12.1. Normative References .....................................36
12.2. Informative References ...................................37
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1. Introduction
There are many ways to formulate packet delay variation metrics for
the Internet and other packet-based networks. The IETF itself has
several specifications for delay variation [RFC3393], sometimes
called jitter [RFC3550] or even inter-arrival jitter [RFC3550], and
these have achieved wide adoption. The International
Telecommunication Union - Telecommunication Standardization Sector
(ITU-T) has also recommended several delay variation metrics (called
parameters in their terminology) [Y.1540] [G.1020], and some of these
are widely cited and used. Most of the standards above specify more
than one way to quantify delay variation, so one can conclude that
standardization efforts have tended to be inclusive rather than
selective.
This memo uses the term "delay variation" for metrics that quantify a
path's ability to transfer packets with consistent delay. [RFC3393]
and [Y.1540] both prefer this term. Some refer to this phenomenon as
"jitter" (and the buffers that attempt to smooth the variations as
de-jitter buffers). Applications of the term "jitter" are much
broader than packet transfer performance, with "unwanted signal
variation" as a general definition. "Jitter" has been used to
describe frequency or phase variations, such as data stream rate
variations or carrier signal phase noise. The phrase "delay
variation" is almost self-defining and more precise, so it is
preferred in this memo.
Most (if not all) delay variation metrics are derived metrics, in
that their definitions rely on another fundamental metric. In this
case, the fundamental metric is one-way delay, and variation is
assessed by computing the difference between two individual one-way-
delay measurements, or a pair of singletons. One of the delay
singletons is taken as a reference, and the result is the variation
with respect to the reference. The variation is usually summarized
for all packets in a stream using statistics.
The industry has predominantly implemented two specific formulations
of delay variation (for one survey of the situation, see
[Krzanowski]):
1. Inter-Packet Delay Variation, IPDV, where the reference is the
previous packet in the stream (according to sending sequence),
and the reference changes for each packet in the stream.
Properties of variation are coupled with packet sequence in this
formulation. This form was called Instantaneous Packet Delay
Variation in early IETF contributions, and is similar to the
packet spacing difference metric used for interarrival jitter
calculations in [RFC3550].
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2. Packet Delay Variation, PDV, where a single reference is chosen
from the stream based on specific criteria. The most common
criterion for the reference is the packet with the minimum delay
in the sample. This term derives its name from a similar
definition for Cell Delay Variation, an ATM performance metric
[I.356].
It is important to note that the authors of relevant standards for
delay variation recognized there are many different users with
varying needs, and allowed sufficient flexibility to formulate
several metrics with different properties. Therefore, the comparison
is not so much between standards bodies or their specifications as it
is between specific formulations of delay variation. Both Inter-
Packet Delay Variation and Packet Delay Variation are compliant with
[RFC3393], because different packet selection functions will produce
either form.
1.1. Requirements Language
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in RFC 2119 [RFC2119].
1.2. Background Literature in IPPM and Elsewhere
With more people joining the measurement community every day, it is
possible this memo is the first from the IP Performance Metrics
(IPPM) Working Group that the reader has consulted. This section
provides a brief road map and background on the IPPM literature, and
the published specifications of other relevant standards
organizations.
The IPPM framework [RFC2330] provides a background for this memo and
other IPPM RFCs. Key terms such as singleton, sample, and statistic
are defined there, along with methods of collecting samples (Poisson
streams), time-related issues, and the "packet of Type-P" convention.
There are two fundamental and related metrics that can be applied to
every packet transfer attempt: one-way loss [RFC2680] and one-way
delay [RFC2679]. The metrics use a waiting time threshold to
distinguish between lost and delayed packets. Packets that arrive at
the measurement destination within their waiting time have finite
delay and are not lost. Otherwise, packets are designated lost and
their delay is undefined. Guidance on setting the waiting time
threshold may be found in [RFC2680] and [IPPM-Reporting].
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Another fundamental metric is packet reordering as specified in
[RFC4737]. The reordering metric was defined to be "orthogonal" to
packet loss. In other words, the gap in a packet sequence caused by
loss does not result in reordered packets, but a rearrangement of
packet arrivals from their sending order constitutes reordering.
Derived metrics are based on the fundamental metrics. The metric of
primary interest here is delay variation [RFC3393], a metric that is
derived from one-way delay [RFC2680]. Another derived metric is the
loss patterns metric [RFC3357], which is derived from loss.
The measured values of all metrics (both fundamental and derived)
depend to great extent on the stream characteristics used to collect
them. Both Poisson streams [RFC3393] and Periodic streams [RFC3432]
have been used with the IPDV and PDV metrics. The choice of stream
specification for active measurement will depend on the purpose of
the characterization and the constraints of the testing environment.
Periodic streams are frequently chosen for use with IPDV and PDV,
because the application streams that are most sensitive to delay
variation exhibit periodicity. Additional details that are method-
specific are discussed in Section 8 on "Measurement Considerations".
In the ITU-T, the framework, fundamental metrics, and derived metrics
for IP performance are specified in Recommendation Y.1540 [Y.1540].
[G.1020] defines additional delay variation metrics, analyzes the
operation of fixed and adaptive de-jitter buffers, and describes an
example adaptive de-jitter buffer emulator. Appendix II of [G.1050]
describes the models for network impairments (including delay
variation) that are part of standardized IP network emulator that may
be useful when evaluating measurement techniques.
1.3. Organization of the Memo
The Purpose and Scope follows in Section 2. We then give a summary
of the main tasks for delay variation metrics in Section 3.
Section 4 defines the two primary forms of delay variation, and
Section 5 presents summaries of four earlier comparisons. Section 6
adds new comparisons to the analysis, and Section 7 reviews the
applicability and recommendations for each form of delay variation.
Section 8 then looks at many important delay variation measurement
considerations. Following the Security Considerations, there is an
appendix on the calculation of the minimum delay for the PDV form.
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2. Purpose and Scope
The IPDV and PDV formulations have certain features that make them
more suitable for one circumstance and less so for another. The
purpose of this memo is to compare two forms of delay variation, so
that it will be evident which of the two is better suited for each of
many possible uses and their related circumstances.
The scope of this memo is limited to the two forms of delay variation
briefly described above (Inter-Packet Delay Variation and Packet
Delay Variation), circumstances related to active measurement, and
uses that are deemed relevant and worthy of inclusion here through
IPPM Working Group consensus.
It is entirely possible that the analysis and conclusions drawn here
are applicable beyond the intended scope, but the reader is cautioned
to fully appreciate the circumstances of active measurement on IP
networks before doing so.
The scope excludes assessment of delay variation for packets with
undefined delay. This is accomplished by conditioning the delay
distribution on arrival within a reasonable waiting time based on an
understanding of the path under test and packet lifetimes. The
waiting time is sometimes called the loss threshold [RFC2680]: if a
packet arrives beyond this threshold, it may as well have been lost
because it is no longer useful. This is consistent with [RFC3393],
where the Type-P-One-way-ipdv is undefined when the destination fails
to receive one or both packets in the selected pair. Furthermore, it
is consistent with application performance analysis to consider only
arriving packets, because a finite waiting time-out is a feature of
many protocols.
3. Brief Descriptions of Delay Variation Uses
This section presents a set of tasks that call for delay variation
measurements. Here, the memo provides several answers to the
question, "How will the results be used?" for the delay variation
metric.
3.1. Inferring Queue Occupation on a Path
As packets travel along the path from source to destination, they
pass through many network elements, including a series of router
queues. Some types of the delay sources along the path are constant,
such as links between two locations. But the latency encountered in
each queue varies, depending on the number of packets in the queue
when a particular packet arrives. If one assumes that at least one
of the packets in a test stream encounters virtually empty queues all
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along the path (and the path is stable), then the additional delay
observed on other packets can be attributed to the time spent in one
or more queues. Otherwise, the delay variation observed is the
variation in queue time experienced by the test stream.
It is worth noting that delay variation can occur beyond IP router
queues, in other communication components. Examples include media
contention: DOCSIS, IEEE 802.11, and some mobile radio technologies.
However, delay variation from all sources at the IP layer and below
will be quantified using the two formulations discussed here.
3.2. Determining De-Jitter Buffer Size
Note -- while this memo and other IPPM literature prefer the term
"delay variation", the terms "jitter buffer" and the more accurate
"de-jitter buffer" are widely adopted names for a component of packet
communication systems, and they will be used here to designate that
system component.
Most isochronous applications (a.k.a. real-time applications) employ
a buffer to smooth out delay variation encountered on the path from
source to destination. The buffer must be big enough to accommodate
the expected variation of delay, or packet loss will result.
However, if the buffer is too large, then some of the desired
spontaneity of communication will be lost and conversational dynamics
will be affected. Therefore, application designers need to know the
range of delay variation they must accommodate, whether they are
designing fixed or adaptive buffer systems.
Network service providers also attempt to constrain delay variation
to ensure the quality of real-time applications, and monitor this
metric (possibly to compare with a numerical objective or Service
Level Agreement).
De-jitter buffer size can be expressed in units of octets of storage
space for the packet stream, or in units of time that the packets are
stored. It is relatively simple to convert between octets and time
when the buffer read rate (in octets per second) is constant:
read_rate * storage_time = storage_octets
Units of time are used in the discussion below.
The objective of a de-jitter buffer is to compensate for all prior
sources of delay variation and produce a packet stream with constant
delay. Thus, a packet experiencing the minimum transit delay from
source to destination, D_min, should spend the maximum time in a
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de-jitter buffer, B_max. The sum of D_min and B_max should equal the
sum of the maximum transit delay (D_max) and the minimum buffer time
(B_min). We have
Constant = D_min + B_max = D_max + B_min,
after rearranging terms,
B_max - B_min = D_max - D_min = range(B) = range(D)
where range(B) is the range of packet buffering times, and range(D)
is the range of packet transit delays from source to destination.
Packets with transit delay between the max and min spend a
complementary time in the buffer and also see the constant delay.
In practice, the minimum buffer time, B_min, may not be zero, and the
maximum transit delay, D_max, may be a high percentile (99.9th
percentile) instead of the maximum.
Note that B_max - B_min = range(B) is the range of buffering times
needed to compensate for delay variation. The actual size of the
buffer may be larger (where B_min > 0) or smaller than range(B).
There must be a process to align the de-jitter buffer time with
packet transit delay. This is a process to identify the packets with
minimum delay and schedule their play-out time so that they spend the
maximum time in the buffer. The error in the alignment process can
be accounted for by a variable, A. In the equation below, the range
of buffering times *available* to the packet stream, range(b),
depends on buffer alignment with the actual arrival times of D_min
and D_max.
range(b) = b_max - b_min = D_max - D_min + A
where variable b represents the *available* buffer in a system with a
specific alignment, A, and b_max and b_min represent the limits of
the available buffer.
When A is positive, the de-jitter buffer applies more delay than
necessary (where Constant = D_max + b_min + A represents one possible
alignment). When A is negative, there is insufficient buffer time
available to compensate for range(D) because of misalignment.
Packets with D_min may be arriving too early and encountering a full
buffer, or packets with D_max may be arriving too late, and in either
case, the packets would be discarded.
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In summary, the range of transit delay variation is a critical factor
in the determination of de-jitter buffer size.
3.3. Spatial Composition
In Spatial Composition, the tasks are similar to those described
above, but with the additional complexity of a multiple network path
where several sub-paths are measured separately and no source-to-
destination measurements are available. In this case, the source-to-
destination performance must be estimated, using Composed Metrics as
described in [IPPM-Framework] and [Y.1541]. Note that determining
the composite delay variation is not trivial: simply summing the sub-
path variations is not accurate.
3.4. Service-Level Comparison
IP performance measurements are often used as the basis for
agreements (or contracts) between service providers and their
customers. The measurement results must compare favorably with the
performance levels specified in the agreement.
Packet delay variation is usually one of the metrics specified in
these agreements. In principle, any formulation could be specified
in the Service Level Agreement (SLA). However, the SLA is most
useful when the measured quantities can be related to ways in which
the communication service will be utilized by the customer, and this
can usually be derived from one of the tasks described above.
3.5. Application-Layer FEC Design
The design of application-layer Forward Error Correction (FEC)
components is closely related to the design of a de-jitter buffer in
several ways. The FEC designer must choose a protection interval
(time to send/receive a block of packets in a constant packet rate
system) consistent with the packet-loss characteristics, but also
mindful of the extent of delay variation expected. Further, the
system designer must decide how long to wait for "late" packets to
arrive. Again, the range of delay variation is the relevant
expression delay variation for these tasks.
4. Formulations of IPDV and PDV
This section presents the formulations of IPDV and PDV, and provides
some illustrative examples. We use the basic singleton definition in
[RFC3393] (which itself is based on [RFC2679]):
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"Type-P-One-way-ipdv is defined for two packets from Src to Dst
selected by the selection function F, as the difference between the
value of the Type-P-One-way-delay from Src to Dst at T2 and the value
of the Type-P-One-Way-Delay from Src to Dst at T1".
4.1. IPDV: Inter-Packet Delay Variation
If we have packets in a stream consecutively numbered i = 1,2,3,...
falling within the test interval, then IPDV(i) = D(i)-D(i-1) where
D(i) denotes the one-way delay of the ith packet of a stream.
One-way delays are the difference between timestamps applied at the
ends of the path, or the receiver time minus the transmission time.
So D(2) = R2-T2. With this timestamp notation, it can be shown that
IPDV also represents the change in inter-packet spacing between
transmission and reception:
IPDV(2) = D(2) - D(1) = (R2-T2) - (R1-T1) = (R2-R1) - (T2-T1)
An example selection function given in [RFC3393] is "Consecutive
Type-P packets within the specified interval". This is exactly the
function needed for IPDV. The reference packet in the pair is the
previous packet in the sending sequence.
Note that IPDV can take on positive and negative values (and zero).
One way to analyze the IPDV results is to concentrate on the positive
excursions. However, this approach has limitations that are
discussed in more detail below (see Section 5.3).
The mean of all IPDV(i) for a stream is usually zero. However, a
slow delay change over the life of the stream, or a frequency error
between the measurement system clocks, can result in a non-zero mean.
4.2. PDV: Packet Delay Variation
The name Packet Delay Variation is used in [Y.1540] and its
predecessors, and refers to a performance parameter equivalent to the
metric described below.
The Selection Function for PDV requires two specific roles for the
packets in the pair. The first packet is any Type-P packet within
the specified interval. The second, or reference packet is the
Type-P packet within the specified interval with the minimum one-way
delay.
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Therefore, PDV(i) = D(i)-D(min) (using the nomenclature introduced in
the IPDV section). D(min) is the delay of the packet with the lowest
value for delay (minimum) over the current test interval. Values of
PDV may be zero or positive, and quantiles of the PDV distribution
are direct indications of delay variation.
PDV is a version of the one-way-delay distribution, shifted to the
origin by normalizing to the minimum delay.
4.3. A "Point" about Measurement Points
Both IPDV and PDV are derived from the one-way-delay metric. One-way
delay requires knowledge of time at two points, e.g., the source and
destination of an IP network path in end-to-end measurement.
Therefore, both IPDV and PDV can be categorized as 2-point metrics
because they are derived from one-way delay. Specific methods of
measurement may make assumptions or have a priori knowledge about one
of the measurement points, but the metric definitions themselves are
based on information collected at two measurement points.
4.4. Examples and Initial Comparisons
Note: This material originally presented in Slides 2 and 3 of
[Morton06].
The Figure below gives a sample of packet delays, calculates IPDV and
PDV values, and depicts a histogram for each one.
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Packet # 1 2 3 4 5
-------------------------------
Delay, ms 20 10 20 25 20
IPDV U -10 10 5 -5
PDV 10 0 10 15 10
| |
4| 4|
| |
3| 3| H
| | H
2| 2| H
| | H
H H 1| H H 1|H H H
H H | H H |H H H
---------+-------- +---------------
-10 -5 0 5 10 0 5 10 15
IPDV Histogram PDV Histogram
Figure 1: IPDV and PDV Comparison
The sample of packets contains three packets with "typical" delays of
20 ms, one packet with a low delay of 10 ms (the minimum of the
sample) and one packet with 25 ms delay.
As noted above, this example illustrates that IPDV may take on
positive and negative values, while the PDV values are greater than
or equal to zero. The histograms of IPDV and PDV are quite different
in general shape, and the ranges are different, too (IPDV range =
20ms, PDV range = 15 ms). Note that the IPDV histogram will change
if the sequence of delays is modified, but the PDV histogram will
stay the same. PDV normalizes the one-way-delay distribution to the
minimum delay and emphasizes the variation independent from the
sequence of delays.
5. Survey of Earlier Comparisons
This section summarizes previous work to compare these two forms of
delay variation.
5.1. Demichelis' Comparison
In [Demichelis], Demichelis compared the early versions of two forms
of delay variation. Although the IPDV form would eventually see
widespread use, the ITU-T work-in-progress he cited did not utilize
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the same reference packets as PDV. Demichelis compared IPDV with the
alternatives of using the delay of the first packet in the stream and
the mean delay of the stream as the PDV reference packet. Neither of
these alternative references were used in practice, and they are now
deprecated in favor of the minimum delay of the stream [Y.1540].
Active measurements of a transcontinental path (Torino to Tokyo)
provided the data for the comparison. The Poisson test stream had
0.764 second average inter-packet interval, with more than 58
thousand packets over 13.5 hours. Among Demichelis' observations
about IPDV are the following:
1. IPDV is a measure of the network's ability to preserve the
spacing between packets.
2. The distribution of IPDV is usually symmetrical about the origin,
having a balance of negative and positive values (for the most
part). The mean is usually zero, unless some long-term delay
trend is present.
3. IPDV singletons distinguish quick-delay variations (short-term,
on the order of the interval between packets) from longer-term
variations.
4. IPDV places reduced demands on the stability and skew of
measurement clocks.
He also notes these features of PDV:
1. The PDV distribution does not distinguish short-term variation
from variation over the complete test interval. (Comment: PDV
can be determined over any sub-intervals when the singletons are
stored.)
2. The location of the distribution is very sensitive to the delay
of the first packet, IF this packet is used as the reference.
This would be a new formulation that differs from the PDV
definition in this memo (PDV references the packet with minimum
delay, so it does not have this drawback).
3. The shape of the PDV distribution is identical to the delay
distribution, but shifted by the reference delay.
4. Use of a common reference over measurement intervals that are
longer than a typical session length may indicate more PDV than
would be experienced by streams that support such sessions.
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(Ideally, the measurement interval should be aligned with the
session length of interest, and this influences determination of
the reference delay, D(min).)
5. The PDV distribution characterizes the range of queue occupancies
along the measurement path (assuming the path is fixed), but the
range says nothing about how the variation took place.
The summary metrics used in this comparison were the number of values
exceeding a +/-50ms range around the mean, the Inverse Percentiles,
and the Inter-Quartile Range.
5.2. Ciavattone et al.
In [Cia03], the authors compared IPDV and PDV (referred to as delta)
using a periodic packet stream conforming to [RFC3432] with inter-
packet interval of 20 ms.
One of the comparisons between IPDV and PDV involves a laboratory
setup where a queue was temporarily congested by a competing packet
burst. The additional queuing delay was 85 ms to 95 ms, much larger
than the inter-packet interval. The first packet in the stream that
follows the competing burst spends the longest time queued, and
others experience less and less queuing time until the queue is
drained.
The authors observed that PDV reflects the additional queuing time of
the packets affected by the burst, with values of 85, 65, 45, 25, and
5 ms. Also, it is easy to determine (by looking at the PDV range)
that a de-jitter buffer of >85 ms would have been sufficient to
accommodate the delay variation. Again, the measurement interval is
a key factor in the validity of such observations (it should have
similar length to the session interval of interest).
The IPDV values in the congested queue example are very different:
85, -20, -20, -20, -20, -5 ms. Only the positive excursion of IPDV
gives an indication of the de-jitter buffer size needed. Although
the variation exceeds the inter-packet interval, the extent of
negative IPDV values is limited by that sending interval. This
preference for information from the positive IPDV values has prompted
some to ignore the negative values, or to take the absolute value of
each IPDV measurement (sacrificing key properties of IPDV in the
process, such as its ability to distinguish delay trends).
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Note that this example illustrates a case where the IPDV distribution
is asymmetrical, because the delay variation range (85 ms) exceeds
the inter-packet spacing (20 ms). We see that the IPDV values 85,
-20, -20, -20, -20, -5 ms have zero mean, but the left side of the
distribution is truncated at -20 ms.
Elsewhere in the article, the authors considered the range as a
summary statistic for IPDV, and the 99.9th percentile minus the
minimum delay as a summary statistic for delay variation, or PDV.
5.3. IPPM List Discussion from 2000
Mike Pierce made many comments in the context of a working version of
[RFC3393]. One of his main points was that a delay histogram is a
useful approach to quantifying variation. Another point was that the
time duration of evaluation is a critical aspect.
Carlo Demichelis then mailed his comparison paper [Demichelis] to the
IPPM list, as discussed in more detail above.
Ruediger Geib observed that both IPDV and the delay histogram (PDV)
are useful, and suggested that they might be applied to different
variation time scales. He pointed out that loss has a significant
effect on IPDV, and encouraged that the loss information be retained
in the arrival sequence.
Several example delay variation scenarios were discussed, including:
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Packet # 1 2 3 4 5 6 7 8 9 10 11
-------------------------------------------------------
Ex. A
Lost
Delay, ms 100 110 120 130 140 150 140 130 120 110 100
IPDV U 10 10 10 10 10 -10 -10 -10 -10 -10
PDV 0 10 20 30 40 50 40 30 20 10 0
-------------------------------------------------------
Ex. B
Lost L
Delay, ms 100 110 150 U 120 100 110 150 130 120 100
IPDV U 10 40 U U -10 10 40 -20 -10 -20
PDV 0 10 50 U 20 0 10 50 30 20 0
Figure 2: Delay Examples
Clearly, the range of PDV values is 50 ms in both cases above, and
this is the statistic that determines the size of a de-jitter buffer.
The IPDV range is minimal in response to the smooth variation in
Example A (20 ms). However, IPDV responds to the faster variations
in Example B (60 ms range from 40 to -20). Here the IPDV range is
larger than the PDV range, and overestimates the buffer size
requirements.
A heuristic method to estimate buffer size using IPDV is to sum the
consecutive positive or zero values as an estimate of PDV range.
However, this is more complicated to assess than the PDV range, and
has strong dependence on the actual sequence of IPDV values (any
negative IPDV value stops the summation, and again causes an
underestimate).
IPDV values can be viewed as the adjustments that an adaptive de-
jitter buffer would make, if it could make adjustments on a packet-
by-packet basis. However, adaptive de-jitter buffers don't make
adjustments this frequently, so the value of this information is
unknown. The short-term variations may be useful to know in some
other cases.
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5.4. Y.1540 Appendix II
Appendix II of [Y.1540] describes a secondary terminology for delay
variation. It compares IPDV, PDV (referred to as 2-point PDV), and
1-point packet delay variation (which assumes a periodic stream and
assesses variation against an ideal arrival schedule constructed at a
single measurement point). This early comparison discusses some of
the same considerations raised in Section 6 below.
5.5. Clark's ITU-T SG 12 Contribution
Alan Clark's contribution to ITU-T Study Group 12 in January 2003
provided an analysis of the root causes of delay variation and
investigated different techniques for measurement and modeling of
"jitter" [COM12.D98]. Clark compared a metric closely related to
IPDV, Mean Packet-to-Packet Delay Variation, MPPDV = mean(abs(D(i)-
D(i-1))) to the newly proposed Mean Absolute Packet Delay Variation
(MAPDV2, see [G.1020]). One of the tasks for this study was to
estimate the number of packet discards in a de-jitter buffer. Clark
concluded that MPPDV did not track the ramp delay variation he
associated access link congestion (similar to Figure 2, Example A
above), but MAPDV2 did.
Clark also briefly looked at PDV (as described in the 2002 version of
[Y.1541]). He concluded that if PDV was applied to a series of very
short measurement intervals (e.g., 200 ms), it could be used to
determine the fraction of intervals with high packet discard rates.
6. Additional Properties and Comparisons
This section treats some of the earlier comparison areas in more
detail and introduces new areas for comparison.
6.1. Packet Loss
The measurement of packet loss is of great influence for the delay
variation results, as displayed in the Figures 3 and 4 (L means Lost
and U means Undefined). Figure 3 shows that in the extreme case of
every other packet loss, the IPDV metric doesn't produce any results,
while the PDV produces results for all arriving packets.
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Packet # 1 2 3 4 5 6 7 8 9 10
Lost L L L L L
---------------------------------------
Delay, ms 3 U 5 U 4 U 3 U 4 U
IPDV U U U U U U U U U U
PDV 0 U 2 U 1 U 0 U 1 U
Figure 3: Path Loss Every Other Packet
In case of a burst of packet loss, as displayed in Figure 4, both the
IPDV and PDV metrics produce some results. Note that PDV still
produces more values than IPDV.
Packet # 1 2 3 4 5 6 7 8 9 10
Lost L L L L L
---------------------------------------
Delay, ms 3 4 U U U U U 5 4 3
IPDV U 1 U U U U U U -1 -1
PDV 0 1 U U U U U 2 1 0
Figure 4: Burst of Packet Loss
In conclusion, the PDV results are affected by the packet-loss ratio.
The IPDV results are affected by both the packet-loss ratio and the
packet-loss distribution. In the extreme case of loss of every other
packet, IPDV doesn't provide any results.
6.2. Path Changes
When there is little or no stability in the network under test, then
the devices that attempt to characterize the network are equally
stressed, especially if the results displayed are used to make
inferences that may not be valid.
Sometimes the path characteristics change during a measurement
interval. The change may be due to link or router failure,
administrative changes prior to maintenance (e.g., link-cost change),
or re-optimization of routing using new information. All these
causes are usually infrequent, and network providers take appropriate
measures to ensure this. Automatic restoration to a back-up path is
seen as a desirable feature of IP networks.
Frequent path changes and prolonged congestion with substantial
packet loss clearly make delay variation measurements challenging.
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Path changes are usually accompanied by a sudden, persistent increase
or decrease in one-way delay. [Cia03] gives one such example. We
assume that a restoration path either accepts a stream of packets or
is not used for that particular stream (e.g., no multi-path for
flows).
In any case, a change in the Time to Live (TTL) (or Hop Limit) of the
received packets indicates that the path is no longer the same.
Transient packet reordering may also be observed with path changes,
due to use of non-optimal routing while updates propagate through the
network (see [Casner] and [Cia03] )
Many, if not all, packet streams experience packet loss in
conjunction with a path change. However, it is certainly possible
that the active measurement stream does not experience loss. This
may be due to use of a long inter-packet sending interval with
respect to the restoration time, and it becomes more likely as "fast
restoration" techniques see wider deployment (e.g., [RFC4090]).
Thus, there are two main cases to consider, path changes accompanied
by loss, and those that are lossless from the point of view of the
active measurement stream. The subsections below examine each of
these cases.
6.2.1. Lossless Path Change
In the lossless case, a path change will typically affect only one
IPDV singleton. For example, the delay sequence in the Figure below
always produces IPDV=0 except in the one case where the value is 5
(U, 0, 0, 0, 5, 0, 0, 0, 0).
Packet # 1 2 3 4 5 6 7 8 9
Lost
------------------------------------
Delay, ms 4 4 4 4 9 9 9 9 9
IPDV U 0 0 0 5 0 0 0 0
PDV 0 0 0 0 5 5 5 5 5
Figure 5: Lossless Path Change
However, if the change in delay is negative and larger than the
inter-packet sending interval, then more than one IPDV singleton may
be affected because packet reordering is also likely to occur.
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The use of the new path and its delay variation can be quantified by
treating the PDV distribution as bi-modal, and characterizing each
mode separately. This would involve declaring a new path within the
sample, and using a new local minimum delay as the PDV reference
delay for the sub-sample (or time interval) where the new path is
present.
The process of detecting a bi-modal delay distribution is made
difficult if the typical delay variation is larger than the delay
change associated with the new path. However, information on a TTL
(or Hop Limit) change or the presence of transient reordering can
assist in an automated decision.
The effect of path changes may also be reduced by making PDV
measurements over short intervals (minutes, as opposed to hours).
This way, a path change will affect one sample and its PDV values.
Assuming that the mean or median one-way delay changes appreciably on
the new path, then subsequent measurements can confirm a path change
and trigger special processing on the interval to revise the PDV
result.
Alternatively, if the path change is detected, by monitoring the test
packets TTL or Hop Limit, or monitoring the change in the IGP link-
state database, the results of measurement before and after the path
change could be kept separated, presenting two different
distributions. This avoids the difficult task of determining the
different modes of a multi-modal distribution.
6.2.2. Path Change with Loss
If the path change is accompanied by loss, such that there are no
consecutive packet pairs that span the change, then no IPDV
singletons will reflect the change. This may or may not be
desirable, depending on the ultimate use of the delay variation
measurement. Figure 6, in which L means Lost and U means Undefined,
illustrates this case.
Packet # 1 2 3 4 5 6 7 8 9
Lost L L
------------------------------------
Delay, ms 3 4 3 3 U U 8 9 8
IPDV U 1 -1 0 U U U 1 -1
PDV 0 1 0 0 U U 5 6 5
Figure 6: Path Change with Loss
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PDV will again produce a bi-modal distribution. But here, the
decision process to define sub-intervals associated with each path is
further assisted by the presence of loss, in addition to TTL,
reordering information, and use of short measurement intervals
consistent with the duration of user sessions. It is reasonable to
assume that at least loss and delay will be measured simultaneously
with PDV and/or IPDV.
IPDV does not help to detect path changes when accompanied by loss,
and this is a disadvantage for those who rely solely on IPDV
measurements.
6.3. Clock Stability and Error
Low cost or low complexity measurement systems may be embedded in
communication devices that do not have access to high stability
clocks, and time errors will almost certainly be present. However,
larger time-related errors (~1 ms) may offer an acceptable trade-off
for monitoring performance over a large population (the accuracy
needed to detect problems may be much less than required for a
scientific study, ~0.01 ms for example).
Maintaining time accuracy <<1 ms has typically required access to
dedicated time receivers at all measurement points. Global
positioning system (GPS) receivers have often been installed to
support measurements. The GPS installation conditions are fairly
restrictive, and many prospective measurement efforts have found the
deployment complexity and system maintenance too difficult.
As mentioned above, [Demichelis] observed that PDV places greater
demands on clock synchronization than for IPDV. This observation
deserves more discussion. Synchronization errors have two
components: time-of-day errors and clock-frequency errors (resulting
in skew).
Both IPDV and PDV are sensitive to time-of-day errors when attempting
to align measurement intervals at the source and destination. Gross
misalignment of the measurement intervals can lead to lost packets,
for example, if the receiver is not ready when the first test packet
arrives. However, both IPDV and PDV assess delay differences, so the
error present in any two one-way-delay singletons will cancel as long
as the error is constant. So, the demand for NTP or GPS
synchronization comes primarily from one-way-delay measurement time-
of-day accuracy requirements. Delay variation and measurement
interval alignment are relatively less demanding.
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Skew is a measure of the change in clock time over an interval with
respect to a reference clock. Both IPDV and PDV are affected by
skew, but the error sensitivity in IPDV singletons is less because
the intervals between consecutive packets are rather small,
especially when compared to the overall measurement interval. Since
PDV computes the difference between a single reference delay (the
sample minimum) and all other delays in the measurement interval, the
constraint on skew error is greater to attain the same accuracy as
IPDV. Again, use of short PDV measurement intervals (on the order of
minutes, not hours) provides some relief from the effects of skew
error. Thus, the additional accuracy demand of PDV can be expressed
as a ratio of the measurement interval to the inter-packet spacing.
A practical example is a measurement between two hosts, one with a
synchronized clock and the other with a free-running clock having 50
parts per million (ppm) long term accuracy.
o If IPDV measurements are made on packets with a 1 second spacing,
the maximum singleton error will be 1 x 5 x 10^-5 seconds, or 0.05
ms.
o If PDV measurements are made on the same packets over a 60 second
measurement interval, then the delay variation due to the max
free-running clock error will be 60 x 5 x 10-5 seconds, or 3 ms
delay variation error from the first packet to the last.
Therefore, the additional accuracy required for equivalent PDV error
under these conditions is a factor of 60 more than for IPDV. This is
a rather extreme scenario, because time-of-day error of 1 second
would accumulate in ~5.5 hours, potentially causing the measurement
interval alignment issue described above.
If skew is present in a sample of one-way delays, its symptom is
typically a nearly linear growth or decline over all the one-way-
delay values. As a practical matter, if the same slope appears
consistently in the measurements, then it may be possible to fit the
slope and compensate for the skew in the one-way-delay measurements,
thereby avoiding the issue in the PDV calculations that follow. See
[RFC3393] for additional information on compensating for skew.
Values for IPDV may have non-zero mean over a sample when clock skew
is present. This tends to complicate IPDV analysis when using the
assumptions of a zero mean and a symmetric distribution.
There is a third factor related to clock error and stability: this is
the presence of a clock-synchronization protocol (e.g., NTP) and the
time-adjustment operations that result. When a time error is
detected (typically on the order of a few milliseconds), the host
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clock frequency is continuously adjusted to reduce the time error.
If these adjustments take place during a measurement interval, they
may appear as delay variation when none was present, and therefore
are a source of error (regardless of the form of delay variation
considered).
6.4. Spatial Composition
ITU-T Recommendation [Y.1541] gives a provisional method to compose a
PDV metric using PDV measurement results from two or more sub-paths.
Additional methods are considered in [IPPM-Spatial].
PDV has a clear advantage at this time, since there is no validated
method to compose an IPDV metric. In addition, IPDV results depend
greatly on the exact sequence of packets and may not lend themselves
easily to the composition problem, where segments must be assumed to
have independent delay distributions.
6.5. Reporting a Single Number (SLA)
Despite the risk of over-summarization, measurements must often be
displayed for easy consumption. If the right summary report is
prepared, then the "dashboard" view correctly indicates whether there
is something different and worth investigating further, or that the
status has not changed. The dashboard model restricts every
instrument display to a single number. The packet network dashboard
could have different instruments for loss, delay, delay variation,
reordering, etc., and each must be summarized as a single number for
each measurement interval. The single number summary statistic is a
key component of SLAs, where a threshold on that number must be met
x% of the time.
The simplicity of the PDV distribution lends itself to this
summarization process (including use of the percentiles, median or
mean). An SLA of the form "no more than x% of packets in a
measurement interval shall have PDV >= y ms, for no less than z% of
time" is relatively straightforward to specify and implement.
[Y.1541] introduced the notion of a pseudo-range when setting an
objective for the 99.9th percentile of PDV. The conventional range
(max-min) was avoided for several reasons, including stability of the
maximum delay. The 99.9th percentile of PDV is helpful to
performance planners (seeking to meet some user-to-user objective for
delay) and in design of de-jitter buffer sizes, even those with
adaptive capabilities.
IPDV does not lend itself to summarization so easily. The mean IPDV
is typically zero. As the IPDV distribution will have two tails
(positive and negative), the range or pseudo-range would not match
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the needed de-jitter buffer size. Additional complexity may be
introduced when the variation exceeds the inter-packet sending
interval, as discussed above (in Sections 5.2 and 6.2.1). Should the
Inter-Quartile Range be used? Should the singletons beyond some
threshold be counted (e.g., mean +/- 50 ms)? A strong rationale for
one of these summary statistics has yet to emerge.
When summarizing IPDV, some prefer the simplicity of the single-sided
distribution created by taking the absolute value of each singleton
result, abs(D(i)-D(i-1)). This approach sacrifices the two-sided
inter-arrival spread information in the distribution. It also makes
the evaluation using percentiles more confusing, because a single
late packet that exceeds the variation threshold will cause two pairs
of singletons to fail the criteria (one positive, the other negative
converted to positive). The single-sided PDV distribution is an
advantage in this category.
6.6. Jitter in RTCP Reports
Section 6.4.1 of [RFC3550] gives the calculation of the "inter-
arrival jitter" field for the RTP Control Protocol (RTCP) report,
with a sample implementation in an Appendix.
The RTCP "interarrival jitter" value can be calculated using IPDV
singletons. If there is packet reordering, as defined in [RFC4737],
then estimates of Jitter based on IPDV may vary slightly, because
[RFC3550] specifies the use of receive-packet order.
Just as there is no simple way to convert PDV singletons to IPDV
singletons without returning to the original sample of delay
singletons, there is no clear relationship between PDV and [RFC3550]
"interarrival jitter".
6.7. MAPDV2
MAPDV2 stands for Mean Absolute Packet Delay Variation (version) 2,
and is specified in [G.1020]. The MAPDV2 algorithm computes a
smoothed running estimate of the mean delay using the one-way delays
of 16 previous packets. It compares the current one-way delay to the
estimated mean, separately computes the means of positive and
negative deviations, and sums these deviation means to produce
MAPVDV2. In effect, there is a MAPDV2 singleton for every arriving
packet, so further summarization is usually warranted.
Neither IPDV or PDV forms assist in the computation of MAPDV2.
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6.8. Load Balancing
Network traffic load balancing is a process to divide packet traffic
in order to provide a more even distribution over two or more equally
viable paths. The paths chosen are based on the IGP cost metrics,
while the delay depends on the path's physical layout. Usually, the
balancing process is performed on a per-flow basis to avoid delay
variation experienced when packets traverse different physical paths.
If the sample includes test packets with different characteristics
such as IP addresses/ports, there could be multi-modal delay
distributions present. The PDV form makes the identification of
multiple modes possible. IPDV may also reveal that multiple paths
are in use with a mixed-flow sample, but the different delay modes
are not easily divided and analyzed separately.
Should the delay singletons using multiple addresses/ports be
combined in the same sample? Should we characterize each mode
separately? (This question also applies to the Path Change case.)
It depends on the task to be addressed by the measurement.
For the task of de-jitter buffer sizing or assessing queue
occupation, the modes should be characterized separately because
flows will experience only one mode on a stable path. Use of a
single flow description (address/port combination) in each sample
simplifies this analysis. Multiple modes may be identified by
collecting samples with different flow attributes, and
characterization of multiple paths can proceed with comparison of the
delay distributions from each sample.
For the task of capacity planning and routing optimization,
characterizing the modes separately could offer an advantage.
Network-wide capacity planning (as opposed to link capacity planning)
takes as input the core traffic matrix, which corresponds to a matrix
of traffic transferred from every source to every destination in the
network. Applying the core traffic matrix along with the routing
information (typically the link state database of a routing protocol)
in a capacity planning tool offers the possibility to visualize the
paths where the traffic flows and to optimize the routing based on
the link utilization. In the case where equal cost multiple paths
(ECMPs) are used, the traffic will be load balanced onto multiple
paths. If each mode of the IP delay multi-modal distribution can be
associated with a specific path, the delay performance offers an
extra optimization parameter, i.e., the routing optimization based on
the IP delay variation metric. As an example, the load balancing
across ECMPs could be suppressed so that the Voice over IP (VoIP)
calls would only be routed via the path with the lower IP delay
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variation. Clearly, any modifications can result in new delay
performance measurements, so there must be a verification step to
ensure the desired outcome.
7. Applicability of the Delay Variation Forms and Recommendations
Based on the comparisons of IPDV and PDV presented above, this
section matches the attributes of each form with the tasks described
earlier. We discuss the more general circumstances first.
7.1. Uses
7.1.1. Inferring Queue Occupancy
The PDV distribution is anchored at the minimum delay observed in the
measurement interval. When the sample minimum coincides with the
true minimum delay of the path, then the PDV distribution is
equivalent to the queuing time distribution experienced by the test
stream. If the minimum delay is not the true minimum, then the PDV
distribution captures the variation in queuing time and some
additional amount of queuing time is experienced, but unknown. One
can summarize the PDV distribution with the mean, median, and other
statistics.
IPDV can capture the difference in queuing time from one packet to
the next, but this is a different distribution from the queue
occupancy revealed by PDV.
7.1.2. Determining De-Jitter Buffer Size (and FEC Design)
This task is complimentary to the problem of inferring queue
occupancy through measurement. Again, use of the sample minimum as
the reference delay for PDV yields a distribution that is very
relevant to de-jitter buffer size. This is because the minimum delay
is an alignment point for the smoothing operation of de-jitter
buffers. A de-jitter buffer that is ideally aligned with the delay
variation adds zero buffer time to packets with the longest
accommodated network delay (any packets with longer delays are
discarded). Thus, a packet experiencing minimum network delay should
be aligned to wait the maximum length of the de-jitter buffer. With
this alignment, the stream is smoothed with no unnecessary delay
added. Figure 5 of [G.1020] illustrates the ideal relationship
between network delay variation and buffer time.
The PDV distribution is also useful for this task, but different
statistics are preferred. The range (max-min) or the 99.9th
percentile of PDV (pseudo-range) are closely related to the buffer
size needed to accommodate the observed network delay variation.
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The PDV distribution directly addresses the FEC waiting time
question. When the PDV distribution has a 99th percentile of 10 ms,
then waiting 10 ms longer than the FEC protection interval will allow
99% of late packets to arrive and be used in the FEC block.
In some cases, the positive excursions (or series of positive
excursions) of IPDV may help to approximate the de-jitter buffer
size, but there is no guarantee that a good buffer estimate will
emerge, especially when the delay varies as a positive trend over
several test packets.
7.1.3. Spatial Composition
PDV has a clear advantage at this time, since there is no validated
method to compose an IPDV metric.
7.1.4. Service-Level Specification: Reporting a Single Number
The one-sided PDV distribution can be constrained with a single
statistic, such as an upper percentile, so it is preferred. The IPDV
distribution is two-sided, usually has zero mean, and no universal
summary statistic that relates to a physical quantity has emerged in
years of experience.
7.2. Challenging Circumstances
Note that measurement of delay variation may not be the primary
concern under unstable and unreliable circumstances.
7.2.1. Clock and Storage Issues
When appreciable skew is present between measurement system clocks,
IPDV has an advantage because PDV would require processing over the
entire sample to remove the skew error. However, significant skew
can invalidate IPDV analysis assumptions, such as the zero-mean and
symmetric-distribution characteristics. Small skew may well be
within the error tolerance, and both PDV and IPDV results will be
usable. There may be a portion of the skew, measurement interval,
and required accuracy 3-D space where IPDV has an advantage,
depending on the specific measurement specifications.
Neither form of delay variation is more suited than the other to
on-the-fly summarization without memory, and this may be one of the
reasons that [RFC3550] RTCP Jitter and MAPDV2 in [G.1020] have
attained deployment in low-cost systems.
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7.2.2. Frequent Path Changes
If the network under test exhibits frequent path changes, on the
order of several new routes per minute, then IPDV appears to isolate
the delay variation on each path from the transient effect of path
change (especially if there is packet loss at the time of path
change). However, if one intends to use IPDV to indicate path
changes, it cannot do this when the change is accompanied by loss.
It is possible to make meaningful PDV measurements when paths are
unstable, but great importance would be placed on the algorithms that
infer path change and attempt to divide the sample on path change
boundaries.
When path changes are frequent and cause packet loss, delay variation
is probably less important than the loss episodes and attention
should be turned to the loss metric instead.
7.2.3. Frequent Loss
If the network under test exhibits frequent loss, then PDV may
produce a larger set of singletons for the sample than IPDV. This is
due to IPDV requiring consecutive packet arrivals to assess delay
variation, compared to PDV where any packet arrival is useful. The
worst case is when no consecutive packets arrive and the entire IPDV
sample would be undefined, yet PDV would successfully produce a
sample based on the arriving packets.
7.2.4. Load Balancing
PDV distributions offer the most straightforward way to identify that
a sample of packets have traversed multiple paths. The tasks of
de-jitter buffer sizing or assessing queue occupation with PDV should
be use a sample with a single flow because flows will experience only
one mode on a stable path, and it simplifies the analysis.
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7.3. Summary
+---------------+----------------------+----------------------------+
| Comparison | PDV = D(i)-D(min) | IPDV = D(i)-D(i-1) |
| Area | | |
+---------------+----------------------+----------------------------+
| Challenging | Less sensitive to | Preferred when path |
| Circumstances | packet loss, and | changes are frequent or |
| | simplifies analysis | when measurement clocks |
| | when load balancing | exhibit some skew |
| | or multiple paths | |
| | are present | |
|---------------|----------------------|----------------------------|
| Spatial | All validated | Has sensitivity to |
| Composition | methods use this | sequence and spacing |
| of DV metric | form | changes, which tends to |
| | | break the requirement for |
| | | independent distributions |
| | | between path segments |
|---------------|----------------------|----------------------------|
| Determine | "Pseudo-range" | No reliable relationship, |
| De-Jitter | reveals this | but some heuristics |
| Buffer Size | property by | |
| Required | anchoring the | |
| | distribution at the | |
| | minimum delay | |
|---------------|----------------------|----------------------------|
| Estimate of | Distribution has | No reliable relationship |
| Queuing Time | one-to-one | |
| and Variation | relationship on a | |
| | stable path, | |
| | especially when | |
| | sample min = true | |
| | min | |
|---------------|----------------------|----------------------------|
| Specification | One constraint | Distribution is two-sided, |
| Simplicity: | needed for | usually has zero mean, and |
| Single Number | single-sided | no universal summary |
| SLA | distribution, and | statistic that relates to |
| | easily related to | a physical quantity |
| | quantities above | |
+---------------+----------------------+----------------------------+
Summary of Comparisons
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8. Measurement Considerations
This section discusses the practical aspects of delay variation
measurement, with special attention to the two formulations compared
in this memo.
8.1. Measurement Stream Characteristics
As stated in Section 1.2, there is a strong dependency between the
active measurement stream characteristics and the results. The IPPM
literature includes two primary methods for collecting samples:
Poisson sampling described in [RFC2330], and Periodic sampling in
[RFC3432]. The Poisson method was intended to collect an unbiased
sample of performance, while the Periodic method addresses a "known
bias of interest". Periodic streams are required to have random
start times and limited stream duration, in order to avoid unwanted
synchronization with some other periodic process, or cause
congestion-aware senders to synchronize with the stream and produce
atypical results. The random start time should be different for each
new stream.
It is worth noting that [RFC3393] was developed in parallel with
[RFC3432]. As a result, all the stream metrics defined in [RFC3393]
specify the Poisson sampling method.
Periodic sampling is frequently used in measurements of delay
variation. Several factors foster this choice:
1. Many application streams that are sensitive to delay variation
also exhibit periodicity, and so exemplify the bias of interest.
If the application has a constant packet spacing, this constant
spacing can be the inter-packet gap for the test stream. VoIP
streams often use 20 ms spacing, so this is an obvious choice for
an Active stream. This applies to both IPDV and PDV forms.
2. The spacing between packets in the stream will influence whether
the stream experiences short-range dependency, or only long-range
dependency, as investigated in [Li.Mills]. The packet spacing
also influences the IPDV distribution and the stream's
sensitivity to reordering. For example, with a 20 ms spacing the
IPDV distribution cannot go below -20 ms without packet
reordering.
3. The measurement process may make several simplifying assumptions
when the send spacing and send rate are constant. For example,
the inter-arrival times at the destination can be compared with
an ideal sending schedule, and allowing a one-point measurement
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of delay variation (described in [Y.1540]) that approximates the
IPDV form. Simplified methods that approximate PDV are possible
as well (some are discussed in Appendix II of [Y.1541]).
4. Analysis of truncated, or non-symmetrical IPDV distributions is
simplified. Delay variations in excess of the periodic sending
interval can cause multiple singleton values at the negative
limit of the packet spacing (see Section 5.2 and [Cia03]). Only
packet reordering can cause the negative spacing limit to be
exceeded.
Despite the emphasis on inter-packet delay differences with IPDV,
both Poisson [Demichelis] and Periodic [Li.Mills] streams have been
used, and these references illustrate the different analyses that are
possible.
The advantages of using a Poisson distribution are discussed in
[RFC2330]. The main properties are to avoid predicting the sample
times, avoid synchronization with periodic events that are present in
networks, and avoid inducing synchronization with congestion-aware
senders. When a Poisson stream is used with IPDV, the distribution
will reflect inter-packet delay variation on many different time
scales (or packet spacings). The unbiased Poisson sampling brings a
new layer of complexity in the analysis of IPDV distributions.
8.2. Measurement Devices
One key aspect of measurement devices is their ability to store
singletons (or individual measurements). This feature usually is
closely related to local calculation capabilities. For example, an
embedded measurement device with limited storage will like provide
only a few statistics on the delay variation distribution, while
dedicated measurement systems store all the singletons and allow
detailed analysis (later calculation of either form of delay
variation is possible with the original singletons).
Therefore, systems with limited storage must choose their metrics and
summary statistics in advance. If both IPDV and PDV statistics are
desired, the supporting information must be collected as packets
arrive. For example, the PDV range and high percentiles can be
determined later if the minimum and several of the largest delays are
stored while the measurement is in-progress.
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8.3. Units of Measurement
Both IPDV and PDV can be summarized as a range in milliseconds.
With IPDV, it is interesting to report on a positive percentile, and
an inter-quantile range is appropriate to reflect both positive and
negative tails (e.g., 5% to 95%). If the IPDV distribution is
symmetric around a mean of zero, then it is sufficient to report on
the positive side of the distribution.
With PDV, it is sufficient to specify the upper percentile (e.g.,
99.9%).
8.4. Test Duration
At several points in this memo, we have recommended use of test
intervals on the order of minutes. In their paper examining the
stability of Internet path properties [Zhang.Duff], Zhang et al.
concluded that consistency was present on the order of minutes for
the performance metrics considered (loss, delay, and throughput) for
the paths they measured.
The topic of temporal aggregation of performance measured in small
intervals to estimate some larger interval is described in the Metric
Composition Framework [IPPM-Framework].
The primary recommendation here is to test using durations that are
similar in length to the session time of interest. This applies to
both IPDV and PDV, but is possibly more relevant for PDV since the
duration determines how often the D_min will be determined, and the
size of the associated sample.
8.5. Clock Sync Options
As with one-way-delay measurements, local clock synchronization is an
important matter for delay variation measurements.
There are several options available:
1. Global Positioning System receivers
2. In some parts of the world, Cellular Code Division Multiple
Access (CDMA) systems distribute timing signals that are derived
from GPS and traceable to UTC.
3. Network Time Protocol [RFC1305] is a convenient choice in many
cases, but usually offers lower accuracy than the options above.
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When clock synchronization is inconvenient or subject to appreciable
errors, then round-trip measurements may give a cumulative indication
of the delay variation present on both directions of the path.
However, delay distributions are rarely symmetrical, so it is
difficult to infer much about the one-way-delay variation from round-
trip measurements. Also, measurements on asymmetrical paths add
complications for the one-way-delay metric.
8.6. Distinguishing Long Delay from Loss
Lost and delayed packets are separated by a waiting time threshold.
Packets that arrive at the measurement destination within their
waiting time have finite delay and are not lost. Otherwise, packets
are designated lost and their delay is undefined. Guidance on
setting the waiting time threshold may be found in [RFC2680] and
[IPPM-Reporting].
In essence, [IPPM-Reporting] suggests to use a long waiting time to
serve network characterization and revise results for specific
application delay thresholds as needed.
8.7. Accounting for Packet Reordering
Packet reordering, defined in [RFC4737], is essentially an extreme
form of delay variation where the packet stream arrival order differs
from the sending order.
PDV results are not sensitive to packet arrival order, and are not
affected by reordering other than to reflect the more extreme
variation.
IPDV results will change if reordering is present because they are
sensitive to the sequence of delays of arriving packets. The main
example of this sensitivity is in the truncation of the negative tail
of the distribution.
o When there is no reordering, the negative tail is limited by the
sending time spacing between packets.
o If reordering occurs (and the reordered packets are not
discarded), the negative tail can take on any value (in
principal).
In general, measurement systems should have the capability to detect
when sequence has changed. If IPDV measurements are made without
regard to packet arrival order, the IPDV will be under-reported when
reordering occurs.
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8.8. Results Representation and Reporting
All of the references that discuss or define delay variation suggest
ways to represent or report the results, and interested readers
should review the various possibilities.
For example, [IPPM-Reporting] suggests reporting a pseudo-range of
delay variation based on calculating the difference between a high
percentile of delay and the minimum delay. The 99.9th percentile
minus the minimum will give a value that can be compared with
objectives in [Y.1541].
9. Security Considerations
The security considerations that apply to any active measurement of
live networks are relevant here as well. See the "Security
Considerations" sections in [RFC2330], [RFC2679], [RFC3393],
[RFC3432], and [RFC4656].
Security considerations do not contribute to the selection of PDV or
IPDV forms of delay variation, because measurements using these
metrics involve exactly the same security issues.
10. Acknowledgments
The authors would like to thank Phil Chimento for his suggestion to
employ the convention of conditional distributions of delay to deal
with packet loss, and his encouragement to "write the memo" after
hearing "the talk" on this topic at IETF 65. We also acknowledge
constructive comments from Alan Clark, Loki Jorgenson, Carsten
Schmoll, and Robert Holley.
11. Appendix on Calculating the D(min) in PDV
Practitioners have raised several questions that this section intends
to answer:
- How is this D_min calculated? Is it DV(99%) as mentioned in
[Krzanowski]?
- Do we need to keep all the values from the interval, then take the
minimum? Or do we keep the minimum from previous intervals?
The value of D_min used as the reference delay for PDV calculations
is simply the minimum delay of all packets in the current sample.
The usual single value summary of the PDV distribution is D_(99.9th
percentile) minus D_min.
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It may be appropriate to segregate sub-sets and revise the minimum
value during a sample. For example, if it can be determined with
certainty that the path has changed by monitoring the Time to Live or
Hop Count of arriving packets, this may be sufficient justification
to reset the minimum for packets on the new path. There is also a
simpler approach to solving this problem: use samples collected over
short evaluation intervals (on the order of minutes). Intervals with
path changes may be more interesting from the loss or one-way-delay
perspective (possibly failing to meet one or more SLAs), and it may
not be necessary to conduct delay variation analysis. Short
evaluation intervals are preferred for measurements that serve as a
basis for troubleshooting, since the results are available to report
soon after collection.
It is not necessary to store all delay values in a sample when
storage is a major concern. D_min can be found by comparing each new
singleton value with the current value and replacing it when
required. In a sample with 5000 packets, evaluation of the 99.9th
percentile can also be achieved with limited storage. One method
calls for storing the top 50 delay singletons and revising the top
value list each time 50 more packets arrive.
12. References
12.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC2330] Paxson, V., Almes, G., Mahdavi, J., and M. Mathis,
"Framework for IP Performance Metrics", RFC 2330,
May 1998.
[RFC2679] Almes, G., Kalidindi, S., and M. Zekauskas, "A One-
way Delay Metric for IPPM", RFC 2679,
September 1999.
[RFC2680] Almes, G., Kalidindi, S., and M. Zekauskas, "A One-
way Packet Loss Metric for IPPM", RFC 2680,
September 1999.
[RFC3393] Demichelis, C. and P. Chimento, "IP Packet Delay
Variation Metric for IP Performance Metrics
(IPPM)", RFC 3393, November 2002.
[RFC3432] Raisanen, V., Grotefeld, G., and A. Morton,
"Network performance measurement with periodic
streams", RFC 3432, November 2002.
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[RFC4090] Pan, P., Swallow, G., and A. Atlas, "Fast Reroute
Extensions to RSVP-TE for LSP Tunnels", RFC 4090,
May 2005.
[RFC4656] Shalunov, S., Teitelbaum, B., Karp, A., Boote, J.,
and M. Zekauskas, "A One-way Active Measurement
Protocol (OWAMP)", RFC 4656, September 2006.
[RFC4737] Morton, A., Ciavattone, L., Ramachandran, G.,
Shalunov, S., and J. Perser, "Packet Reordering
Metrics", RFC 4737, November 2006.
12.2. Informative References
[COM12.D98] Clark, A., "Analysis, measurement and modelling of
Jitter", ITU-T Delayed Contribution COM 12 - D98,
January 2003.
[Casner] Casner, S., Alaettinoglu, C., and C. Kuan, "A Fine-
Grained View of High Performance Networking",
NANOG 22, May 20-22, 2001,
<http://www.nanog.org/mtg-0105/agenda.html>.
[Cia03] Ciavattone, L., Morton, A., and G. Ramachandran,
"Standardized Active Measurements on a Tier 1 IP
Backbone", IEEE Communications Magazine, p. 90-97,
June 2003.
[Demichelis] Demichelis, C., "Packet Delay Variation Comparison
between ITU-T and IETF Draft Definitions",
November 2000, <http://www.advanced.org/ippm/
archive.3/att-0075/01-pap02.doc>.
[G.1020] ITU-T, "Performance parameter definitions for the
quality of speech and other voiceband applications
utilizing IP networks", ITU-T
Recommendation G.1020, 2006.
[G.1050] ITU-T, "Network model for evaluating multimedia
transmission performance over Internet Protocol",
ITU-T Recommendation G.1050, November 2005.
[I.356] ITU-T, "B-ISDN ATM Layer Cell Transfer
Performance", ITU-T Recommendation I.356,
March 2000.
[IPPM-Framework] Morton, A., "Framework for Metric Composition",
Work in Progress, October 2008.
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RFC 5481 Delay Variation AS March 2009
[IPPM-Reporting] Morton, A., Ramachandran, G., and G. Maguluri,
"Reporting Metrics: Different Points of View", Work
in Progress, January 2009.
[IPPM-Spatial] Morton, A. and E. Stephan, "Spatial Composition of
Metrics", Work in Progress, July 2008.
[Krzanowski] Presentation at IPPM, IETF-64, "Jitter Definitions:
What is What?", November 2005.
[Li.Mills] Li, Q. and D. Mills, "The Implications of Short-
Range Dependency on Delay Variation Measurement",
Second IEEE Symposium on Network Computing
and Applications, 2003.
[Morton06] Morton, A., "A Brief Jitter Metrics Comparison, and
not the last word, by any means...", slide
presentation at IETF 65, IPPM Session, March 2006.
[RFC1305] Mills, D., "Network Time Protocol (Version 3)
Specification, Implementation", RFC 1305,
March 1992.
[RFC3357] Koodli, R. and R. Ravikanth, "One-way Loss Pattern
Sample Metrics", RFC 3357, August 2002.
[RFC3550] Schulzrinne, H., Casner, S., Frederick, R., and V.
Jacobson, "RTP: A Transport Protocol for Real-Time
Applications", STD 64, RFC 3550, July 2003.
[Y.1540] ITU-T, "Internet protocol data communication
service - IP packet transfer and availability
performance parameters", ITU-T Recommendation
Y.1540, November 2007.
[Y.1541] ITU-T, "Network Performance Objectives for IP-Based
Services", ITU-T Recommendation Y.1541,
February 2006.
[Zhang.Duff] Zhang, Y., Duffield, N., Paxson, V., and S.
Shenker, "On the Constancy of Internet Path
Properties", Proceedings of ACM SIGCOMM Internet
Measurement Workshop, November 2001.
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Authors' Addresses
Al Morton
AT&T Labs
200 Laurel Avenue South
Middletown, NJ 07748
USA
Phone: +1 732 420 1571
Fax: +1 732 368 1192
EMail: acmorton@att.com
URI: http://home.comcast.net/~acmacm/
Benoit Claise
Cisco Systems, Inc.
De Kleetlaan 6a b1
Diegem, 1831
Belgium
Phone: +32 2 704 5622
EMail: bclaise@cisco.com
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