PALS YJ. Stein
Internet-Draft RAD Data Communications
Intended status: Informational D. Black
Expires: March 4, 2016 EMC Corporation
B. Briscoe
BT
September 1, 2015
Pseudowire Congestion Considerations
draft-ietf-pals-congcons-00
Abstract
Pseudowires (PWs) have become a common mechanism for tunneling
traffic, and may be found in unmanaged scenarios competing for
network resources both with other PWs and with non-PW traffic, such
as TCP/IP flows. It is thus worthwhile specifying under what
conditions such competition is acceptable, i.e., the PW traffic does
not significantly harm other traffic or contribute more than it
should to congestion. We conclude that PWs transporting responsive
traffic behave as desired without the need for additional mechanisms.
For inelastic PWs (such as TDM PWs) we derive a bound under which
such PWs consume no more network capacity than a TCP flow. We also
propose employing a transport circuit breaker that shuts down a TDM
PW that persistently fails to comply with acceptable TDM service
criteria.
Status of This Memo
This Internet-Draft is submitted in full conformance with the
provisions of BCP 78 and BCP 79.
Internet-Drafts are working documents of the Internet Engineering
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This Internet-Draft will expire on March 4, 2016.
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Copyright Notice
Copyright (c) 2015 IETF Trust and the persons identified as the
document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal
Provisions Relating to IETF Documents
(http://trustee.ietf.org/license-info) in effect on the date of
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the Trust Legal Provisions and are provided without warranty as
described in the Simplified BSD License.
Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 2
2. Terminology . . . . . . . . . . . . . . . . . . . . . . . . . 4
3. PWs Comprising Elastic Flows . . . . . . . . . . . . . . . . 4
4. PWs Comprising Inelastic Flows . . . . . . . . . . . . . . . 5
5. Security Considerations . . . . . . . . . . . . . . . . . . . 17
6. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 17
7. Informative References . . . . . . . . . . . . . . . . . . . 18
Appendix A. Loss Probabilities for TDM PWs . . . . . . . . . . . 19
Appendix B. Effect of Packet Loss on Voice Quality for TDM PWs . 21
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 23
1. Introduction
A pseudowire (PW) (see [RFC3985]) is a construct for tunneling a
native service, such as Ethernet or TDM, over a Packet Switched
Network (PSN), such as IPv4, IPv6, or MPLS. The PW packet
encapsulates a unit of native service information by prepending the
headers required for transport in the particular PSN (which must
include a demultiplexer field to distinguish the different PWs) and
preferably the 4 byte Pseudowire Emulation Edge to Edge (PWE3)
control word.
PWs have no bandwidth reservation or control mechanisms, meaning that
when multiple PWs are transported in parallel, and/or in parallel
with other flows, there is no defined means for allocating resources
for any particular PW, or for preventing negative impact of a
particular PW on neighboring flows. The case where the service
provider network provisions a PW with sufficient capacity is well
understood and will not be discussed further here. Concerns arise
when PWs share network capacity with elastic or congestion-responsive
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traffic, whether that capacity sharing was planned by a service
provider or results from PW deployment by an end-user.
While PWs are most often placed in MPLS tunnels, there are several
mechanisms that enable transporting of PWs over an IP infrastructure.
These include:
o UDP/IP encapsulations defined for TDM PWs
([RFC4553][RFC5086][RFC5087]),
o L2 tunnelling protocol (L2TPv3) based PWs,
o MPLS PWs directly over IP according to RFC 4023 [RFC4023],
o MPLS PWs over Generic Routing Encapsulation (GRE) over IP
according to RFC 4023 [RFC4023].
Whenever PWs are transported over IP, they may compete for network
resources with neighboring congestion-responsive flows (e.g., TCP
flows). In this document we study the effect of PWs on such
neighboring flows, and discover that the negative impact of PW
traffic is generally no worse than that of congestion-responsive
flows ([RFC2914],[RFC5033]}.
At first glance one may consider a PW transported over IP to be
considered as a single flow, on a par with a single TCP flow. Were
we to accept this tenet, we would require a PW to back off under
congestion to consume no more bandwidth than a single TCP flow under
such conditions (see [RFC5348]). However, since PWs may carry
traffic from many users, it makes more sense to consider each PW to
be equivalent to multiple TCP flows.
The following two sections consider PWs of two types.
Elastic Flows: Section 3 concludes that the response to congestion
of a PW carrying elastic (e.g., TCP) flows is no different
from the combined behaviours of the set of the same elastic
flows were they not encapsulated within a PW.
Inelastic Flows: Section 4 considers the case of inelastic constant
bit-rate (CBR) TDM PWs ([RFC4553][RFC5086] [RFC5087])
competing with TCP flows. Such PWs require a preset amount
of bandwidth, that may be lower or higher than that consumed
by an otherwise unconstrained TCP flow under the same network
conditions. In any case, such a PW is unable to respond to
congestion in a TCP-like manner; although admittedly the
total bandwidth it consumes remains constant and does not
increase to consume additional bandwidth as TCP rates back
off. For TDM pseudowires, a transport circuit breaker
[I-D.ietf-tsvwg-circuit-breaker] may be employed to shut down
a TDM pseudowire that persistently fails to comply with
acceptable TDM service criteria. We will show that such TDM
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service quality degradation generally occurs before the TDM
PW becomes TCP-unfriendly.
Thus, in both cases, pseudowires will not inflict significant harm on
neighboring TCP flows, as in one case they respond adequately to
congestion, and in the other they would be shut down due to being
unable to emulate the native service before harming neighboring
flows.
2. Terminology
The following acronyms used in this document :
AIS Alarm Indication Signal (see G.775)
BER Bit Error Rate [G826]
BW bandwidth
CBR Constant Bit Rate
ES Errored Second [G826]
ESR Errored Second Rate [G826]
GRE Generic Routing Encapsulation (see RFC 2890)
L2TPv3 Layer 2 Tunneling Protocol Version 3 (see RFC 3931)
MOS Mean Opinion Score (see ITU-T P.800)
MPLS Multiprotocol Label Switching (see RFC 3031)
NSP Native Service Processing (see RFC 3985)
PLR Packet Loss Ratio
PSN Packet Switched Network [RFC3985]
PW pseudowire [RFC3985]
SAToP Structure Agnostic TDM over Packet [RFC4553]
SES Severely Errored Seconds [G826]
SESR Severely Errored Seconds Ratio [G826]
TCP Transmission Control Protocol
TDM Time Division Multiplexing (see G.703)
UDP User Datagram Protocol
3. PWs Comprising Elastic Flows
In this section we consider Ethernet PWs that primarily carry
congestion-responsive traffic. We expand on the remark in
Section 6.5 (Congestion Considerations) of [RFC4553], and show that
the desired congestion avoidance behavior is automatically obtained
and additional mechanisms are not needed.
Let us assume that an Ethernet PW aggregating several TCP flows is
flowing alongside several TCP/IP flows. Each Ethernet PW packet
carries a single Ethernet frame that carries a single IP packet that
carries a single TCP segment. Thus, if congestion is signaled by an
intermediate router dropping a packet, a single end-user TCP/IP
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packet is dropped, whether or not that packet is encapsulated in the
PW.
The result is that the individual TCP flows inside the PW experience
the same drop probability as the non-PW TCP flows. Thus the behavior
of a TCP sender (retransmitting the packet and appropriately reducing
its sending rate) is the same for flows directly over IP and for
flows inside the PW. In other words, individual TCP flows are
neither rewarded nor penalized for being carried over the PW. An
elastic PW does not behave as a single TCP flow, as it will consume
the aggregated bandwidth of its component flows; yet if its component
TCP flows backs off by some percentage, the bandwidth of the PW as a
whole will be reduced by the very same percentage, purely due to the
combined effect of its component flows.
This is, of course, precisely the desired behavior. Were individual
TCP flows rewarded for being carried over a PW, this would create an
incentive to create PWs for no operational reason. Were individual
flows penalized, there would be a deterrence that could impede
pseudowire deployment.
There have been proposals to add additional TCP-friendly mechanisms
to PWs, for example by carrying PWs over DCCP. In light of the above
arguments, it is clear that this would force the PW down to the
bandwidth of a single flow, rather than N flows, and penalize the
constituent TCP flows. In addition, the individual TCP flows would
still back off due to their end points being oblivious to the fact
that they are carried over a PW. This would further degrade the
flow's throughput as compared to a non-PW-encapsulated flow, in
contradiction to desirable behavior.
We have limited our treatment to the case of TCP traffic carried by
Ethernet PWs, but it is not overly difficult to show that our result
is equally valid for other PW types, such as ATM or frame relay
pseudowires.
4. PWs Comprising Inelastic Flows
Inelastic PWs, such as TDM PWs ([RFC4553][RFC5086][RFC5087]), are
potentially more problematic than the elastic PWs of the previous
section. As mentioned in Section 8 (Congestion Control) of
[RFC4553], being constant bit-rate (CBR), TDM PWs can not respond to
congestion. On the other hand, being CBR, they at least do not
attempt to capture additional bandwidth when neighboring TCP flows
back off.
Since a TDM PW continuously consumes a constant amount of bandwidth,
if the bandwidth occupied by a TDM PW endangers the network as a
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whole, the only recourse is to shut it down, denying service to all
customers of the TDM native service. We can accomplish this by
employing a transport circuit breaker, by which we mean an automatic
mechanism for terminating a flow to prevent negative impact on other
flows and on the network as a whole [I-D.ietf-tsvwg-circuit-breaker].
Note that a transport circuit breaker is intended as a protection
mechanism of last resort, just as an electrical circuit breaker is
only triggered when absolutely necessary. We should mention in
passing that under certain conditions it may be possible to reduce
the bandwidth consumption of a TDM PW. A prevalent case is that of a
TDM native service that carries voice channels that may not all be
active. Using the AAL2 mode of [RFC5087] (perhaps along with
connection admission control) can enable bandwidth adaptation, at the
expense of more sophisticated native service processing (NSP).
In the following we will show that for many cases of interest a TDM
PW, even when treated as a single flow, will behave in a reasonable
manner without any additional mechanisms. We will focus on
structure-agnostic TDM PWs [RFC4553] although our analysis can be
readily applied to structure-aware PWs (see Appendix A).
In order to quantitatively compare TDM PWs to TCP flows, we will
compare the effect of TDM PW traffic with that of TCP traffic having
the same packet size and delay. This is potentially an overly
pessimistic comparison, as TDM PW packets are frequently configured
to be short in order to minimize latency, while TCP packets are free
to be much larger.
There are two network parameters relevant to our discussion, namely
the one-way delay (D) and the packet loss ratio (PLR). The one-way
delay of a native TDM service consists of the physical time-of-flight
plus 125 microseconds for each TDM switch traversed; and is thus very
small as compared to typical PSN network-crossing latencies. Due to
native TDM services being designed with this low latency in mind,
emulated TDM services are usually required to have similarly low end-
to-end delay. In our comparisons we will only consider one-way
delays of a few milliseconds.
Regarding packet loss, the relevant RFCs specify actions to be
carried out upon detecting a lost packet. Structure-agnostic
transport has no alternative to outputting an "all-ones" Alarm
Indication Signal (AIS) pattern towards the TDM circuit, which, when
long enough in duration, is recognized by the receiving TDM device as
a fault indication (see Appendix A). TDM standards (such as [G826])
place stringent limits on the number of such faults tolerated.
Calculations presented in the appendix show that only loss
probabilities in the realm of fractions of a percent are relevant for
structure-agnostic transport (see Appendix A). Structure-aware
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transport regenerates frame alignment signals thus avoiding AIS
indications resulting from infrequent packet loss. Furthermore, for
TDM circuits carrying voice channels the use of packet loss
concealment algorithms is possible (such algorithms have been
previously described for TDM PWs). However, even structure-aware
transport ceases to provide a useful service at about 2 percent loss
probability. Hence, in our comparisons we will only consider PLRs of
1 or 2 percent.
RFC 5348 on TCP Friendly Rate Control (TFRC) [RFC5348] provides a
simplified formula for TCP throughput as a function of round-trip
delay and packet loss ratio.
S
X = ------------------------------------------------
R ( sqrt(2p/3) + 12 sqrt(3p/8) p (1+32p^2) )
where
X is average sending rate in Bytes per second,
S is the segment (packet payload) size in Bytes,
R is the round-trip time in seconds,
p is the packet loss probability (i.e., PLR/100).
We can now compare the bandwidth consumed by TDM pseudowires with
that of a TCP flow for given packet loss ratio and one-way end-to-end
delay (taken to be half the round-trip delay R). The results are
depicted in the accompanying figures (available only in the PDF
version of this document). In Figures 1 and 2 we see the
conventional rate vs. packet loss plot for low-rate TDM (both T1 and
E1) traffic, as well as TCP traffic with the same payload size (64 or
256 Bytes respectively). Since the TDM rates are constant (T1 and E1
having payload throughputs of 1.544 Mbps and 2.048 Mbps
respectively), and Structure-Agnostic TDM over packet (SAToP) can
only faithful emulate a TDM service up to a PLR of about half a
percent, the T1 and E1 pseudowires occupy line segments on the graph.
On the other hand, the TCP rate equation produces rate curves
dependent on both one-way delay and packet loss.
For large packet sizes, short one-way delays, and low packet loss
ratios, the TDM pseudowires typically consume much less bandwidth
than TCP would under identical conditions. Only for small packets,
long one-way delays, and high packet loss ratios, do TDM PWs
potentially consume more bandwidth, and even then only marginally.
Further, our "apples to apples" comparison forced the TCP traffic to
use packets much smaller than would be typical.
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Similarly, in Figures 3 and 4 we repeat the exercise for higher rate
E3 and T3 (rates 34.368 and 44.736 Mbps respectively) pseudowires,
allowing delays and PLRs suitable for these signals. We see that the
TDM pseudowires consume much less bandwidth than TCP, for all
reasonable parameter combinations.
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Figure 1 E1/T1 PWs vs. TCP for segment size 64B
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Figure 2 E1/T1 PWs vs. TCP for segment size 256B
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Figure 3 T3/E3 PWs vs. TCP for segment size 536B
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Figure 4 T3/E3 PWs vs. TCP for segment size 1024B
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We can use the TCP rate equation to determine precise conditions
under which a TDM PW consumes no more bandwidth than a TCP flow
between the same endpoints would consume under identical conditions.
Replacing the round-trip delay with twice the one-way delay D,
setting the bandwidth to that of the TDM service BW, and the segment
size to be the TDM fragment (taking into account the PWE3 control
word), we obtain the following condition for a TDM PW.
4 S
D < -----------
BW f(p)
where
D is the one-way delay,
S is the TDM segment size (packet excluding overhead) in Bytes,
BW is TDM service bandwidth in bits per second,
f(p) = sqrt(2p/3) + 12 sqrt(3p/8) p (1+32p^2).
One may view this condition as defining a 'friendly' operating
envelope for a TDM PW, as a TDM PW that occupies no more bandwidth
than a TCP flow causes no more congestion than that TCP flow. Under
this condition it is acceptable to place the TDM PW alongside
congestion-responsive traffic such as TCP. On the other hand, were
the TDM PW to consume significantly more bandwidth a TCP flow, it
could contribute disproportionately to congestion, and its mixture
with congestion-responsive traffic might be inappropriate. Note that
we are sidestepping any debate over the validity of the TCP-
friendliness concept, and merely saying that there can be no question
that a TDM PW is acceptable if it causes no more congestion than a
single TCP flow.
We derived this condition assuming steady-state conditions, and thus
two caveats are in order. First, the condition does not specify how
to treat a TDM PW that initially satisfies the condition, but is then
faced with a deteriorating network environment. In such cases one
additionally needs to analyze the reaction times of the responsive
flows to congestion events. Second, the derivation assumed that the
TDM PW was competing with long-lived TCP flows, because under this
assumption it was straightforward to obtain a quantitative comparison
with something widely considered to offer a safe response to
congestion. Short-lived TCP flows may find themselves disadvantaged
as compared to a long-lived TDM PW satisfying the above condition.
We see in Figures 5 and 6 that TDM pseudowires carrying T1 or E1
native services satisfy the condition for all parameters of interest
for large packet sizes (e.g., S=512 Bytes of TDM data). For the
SAToP default of 256 Bytes, as long as the one-way delay is less than
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10 milliseconds, the loss probability can exceed 0.3 or 0.6 percent.
For packets containing 128 or 64 Bytes the constraints are more
troublesome, but there are still parameter ranges where the TDM PW
consumes less than a TCP flow under similar conditions. Similarly,
Figures 7 and 8 demonstrate that E3 and T3 native services with the
SAToP default of 1024 Bytes of TDM per packet satisfy the condition
for a broad spectrum of delays and PLRs.
Note that violating the condition for a short amount of time is not
sufficient justification for shutting down the TDM PW. While TCP
flows react within a round trip time, PW commissioning and
decommissioning are time consuming processes that should only be
undertaken when it becomes clear that the congestion is not
transient.
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Figure 5 TCP Compatibility areas for T1 SAToP
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Figure 6 TCP Compatibility areas for E1 SAToP
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Figure 7 TCP Compatibility areas for E3 SAToP
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Figure 8 TCP Compatibility areas for T3 SAToP
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5. Security Considerations
This document does not introduce any new congestion-specific
mechanisms and thus does not introduce any new security
considerations above those present for PWs in general.
6. IANA Considerations
This document requires no IANA actions.
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7. Informative References
[RFC2914] Floyd, S., "Congestion Control Principles", BCP 41,
RFC 2914, DOI 10.17487/RFC2914, September 2000,
<http://www.rfc-editor.org/info/rfc2914>.
[RFC3985] Bryant, S., Ed. and P. Pate, Ed., "Pseudo Wire Emulation
Edge-to-Edge (PWE3) Architecture", RFC 3985,
DOI 10.17487/RFC3985, March 2005,
<http://www.rfc-editor.org/info/rfc3985>.
[RFC4023] Worster, T., Rekhter, Y., and E. Rosen, Ed.,
"Encapsulating MPLS in IP or Generic Routing Encapsulation
(GRE)", RFC 4023, DOI 10.17487/RFC4023, March 2005,
<http://www.rfc-editor.org/info/rfc4023>.
[RFC4553] Vainshtein, A., Ed. and YJ. Stein, Ed., "Structure-
Agnostic Time Division Multiplexing (TDM) over Packet
(SAToP)", RFC 4553, DOI 10.17487/RFC4553, June 2006,
<http://www.rfc-editor.org/info/rfc4553>.
[RFC5033] Floyd, S. and M. Allman, "Specifying New Congestion
Control Algorithms", BCP 133, RFC 5033,
DOI 10.17487/RFC5033, August 2007,
<http://www.rfc-editor.org/info/rfc5033>.
[RFC5086] Vainshtein, A., Ed., Sasson, I., Metz, E., Frost, T., and
P. Pate, "Structure-Aware Time Division Multiplexed (TDM)
Circuit Emulation Service over Packet Switched Network
(CESoPSN)", RFC 5086, DOI 10.17487/RFC5086, December 2007,
<http://www.rfc-editor.org/info/rfc5086>.
[RFC5087] Stein, Y(J)., Shashoua, R., Insler, R., and M. Anavi,
"Time Division Multiplexing over IP (TDMoIP)", RFC 5087,
DOI 10.17487/RFC5087, December 2007,
<http://www.rfc-editor.org/info/rfc5087>.
[RFC5348] Floyd, S., Handley, M., Padhye, J., and J. Widmer, "TCP
Friendly Rate Control (TFRC): Protocol Specification",
RFC 5348, DOI 10.17487/RFC5348, September 2008,
<http://www.rfc-editor.org/info/rfc5348>.
[G775] International Telecommunications Union, "Loss of Signal
(LOS), Alarm Indication Signal (AIS) and Remote Defect
Indication (RDI) defect detection and clearance criteria
for PDH signals", ITU Recommendation G.775, October 1998.
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[G826] International Telecommunications Union, "Error Performance
Parameters and Objectives for International Constant Bit
Rate Digital Paths at or above Primary Rate",
ITU Recommendation G.826, December 2002.
[P862] International Telecommunications Union, "Perceptual
evaluation of speech quality (PESQ): An objective method
for end-to-end speech quality assessment of narrow-band
telephone networks and speech codecs", ITU Recommendation
G.826, February 2001.
[I-D.stein-pwe3-tdm-packetloss]
Stein, Y(J). and I. Druker, "The Effect of Packet Loss on
Voice Quality for TDM over Pseudowires", October 2003.
[I-D.ietf-tsvwg-circuit-breaker]
Fairhurst, G., "Network Transport Circuit Breakers",
draft-ietf-tsvwg-circuit-breaker-02 (work in progress),
July 2015.
Appendix A. Loss Probabilities for TDM PWs
ITU-T Recommendation G.826 [G826] specifies limits on the Errored
Second Ratio (ESR) and the Severely Errored Second Ratio (SESR). For
our purposes, we will simplify the definitions and understand an
Errored Second (ES) to be a second of time during which a TDM bit
error occurred or a defect indication was detected. A Severely
Errored Second (SES) is an ES second during which the Bit Error Rate
(BER) exceeded one in one thousand (10^-3). Note that if the error
condition AIS was detected according to the criteria of ITU-T
Recommendation G.775 [G775] a SES was considered to have occurred.
The respective ratios are the fraction of ES or SES to the total
number of seconds in the measurement interval.
All TDM signals run at 8000 frames per second (higher rate TDM
signals have longer frames). So, assuming an integer number of TDM
frames per TDM PW packet, the number of packets per second is given
by packets per second = 8000 / (frames per packet). Prevalent cases
are 1, 2, 4 and 8 frames per packet, translating to 8000, 4000, 2000,
and 1000 packets per second, respectively.
For both E1 and T1 TDM circuits, G.826 allows ESR of 4% (0.04), and
SESR of 0.2% (0.002). For E3 and T3 the ESR must be no more than
7.5% (0.075), while the SESR is unchanged. Focusing on E1 circuits,
the ESR of 4% translates, assuming the worst case of isolated exactly
periodic packet loss, to a packet loss event no more than every 25
seconds. However, once a packet is lost, another packet lost in the
same second doesn't change the ESR, although it may contribute to the
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ES becoming a SES. Thus for 1, 2, 4, and 8 frames per packet, the
maximum allowed packet loss probability is 0.0005%, 0.001%, 0.002%,
and 0.004% respectively.
These extremely low allowed packet loss probabilities are only for
the worst case scenario. With tail-drop buffers, when packet loss is
above 0.001%, it is likely that loss bursts will occur. If the lost
packets are sufficiently close together (we ignore the precise
details here) then the permitted packet loss ratio increases by the
appropriate factor, without G.826 being cognizant of any change.
Hence the worst-case analysis is expected to be extremely pessimistic
for real networks. Next we will consider the opposite extreme and
assume that all packet loss events are in periodic loss bursts. In
order to minimize the ESR we will assume that the burst lasts no more
than one second, and so we can afford to lose in each burst no more
than the number of packets transmitted in one second. As long as
such one-second bursts do not exceed four percent of the time, we
still maintain the allowable ESR. Hence the maximum permissible
packet loss ratio is 4%. Of course, this estimate is extremely
optimistic, and furthermore does not take into consideration the SESR
criteria.
As previously explained, a SES is declared whenever AIS is detected.
There is a major difference between structure-aware and structure-
agnostic transport in this regards. When a packet is lost SAToP
outputs an "all-ones" pattern to the TDM circuit, which is
interpreted as AIS according to G.775 [G775]. For E1 circuits, G.775
specifies that AIS is detected when four consecutive TDM frames have
no more than 2 alternations. This means that if a PW packet or
consecutive packets containing at least four frames are lost, and
four or more frames of "all-ones" output to the TDM circuit, a SES
will be declared. Thus burst packet loss, or packets containing a
large number of TDM frames, lead SAToP to cause high SESR, which is
20 times more restricted than ESR. On the other hand, since
structure-aware transport regenerates the correct frame alignment
pattern, even when the corresponding packet has been lost, packet
loss will not cause declaration of SES. This is the main reason that
SAToP is much more vulnerable to packet loss than the structure-aware
methods.
For realistic networks, the maximum allowed packet loss for SAToP
will be intermediate between the extremely pessimistic estimates and
the extremely optimistic ones. In order to numerically gauge the
situation, we have modeled the network as a four-state Markov model,
(corresponding to a successfully received packet, a packet received
within a loss burst, a packet lost within a burst, and a packet lost
when not within a burst). This model is an extension of the widely
used Gilbert model. We set the transition probabilities in order to
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roughly correspond to anecdotal evidence, namely low background
isolated packet loss, and infrequent bursts wherein most packets are
lost. Such simulation shows that up to 0.5% average packet loss may
occur and the recovered TDM still conforms to the G.826 ESR and SESR
criteria.
Appendix B. Effect of Packet Loss on Voice Quality for TDM PWs
Packet loss in voice traffic cause audio artifacts such as choppy,
annoying or even unintelligible speech. The precise effect of packet
loss on voice quality has been the subject of detailed study in the
VoIP community, but VoIP results are not directly applicable to TDM
PWs. This is because VoIP packets typically contain over 10
milliseconds of the speech signal, while multichannel TDM packets may
contain only a single sample, or perhaps a very small number of
samples.
The effect of packet loss on TDM PWs has been previously reported
[I-D.stein-pwe3-tdm-packetloss]. In that study it was assumed that
each packet carried a single sample of each TDM timeslot (although
the extension to multiple samples is relatively straightforward and
does not drastically change the results). Four sample replacement
algorithms were compared, differing in the value used to replace the
lost sample:
1. replacing every lost sample by a preselected constant (e.g., zero
or "AIS" insertion),
2. replacing a lost sample by the previous sample,
3. replacing a lost sample by linear interpolation between the
previous and following samples,
4. replacing the lost sample by STatistically Enhanced INterpolation
(STEIN).
Only the first method is applicable to SAToP transport, as structure
awareness is required in order to identify the individual voice
channels. For structure aware transport, the loss of a packet is
typically identified by the receipt of the following packet, and thus
the following sample is usually available. The last algorithm posits
the LPC speech generation model and derives lost samples based on
available samples both before and after each lost sample.
The four algorithms were compared in a controlled experiment in which
speech data was selected from English and American English subsets of
the ITU-T P.50 Appendix 1 corpus [P.50App1] and consisted of 16
speakers, eight male and eight female. Each speaker spoke either
three or four sentences, for a total of between seven and 15 seconds.
The selected files were filtered to telephony quality using modified
IRS filtering and down-sampled to 8 KHz. Packet loss of 0, 0.25,
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0.5, 0.75, 1, 2, 3, 4 and 5 percent were simulated using a uniform
random number generator (bursty packet loss was also simulated but is
not reported here). For each file the four methods of lost sample
replacement were applied and the Mean Opinion Score (MOS) was
estimated using PESQ [P862]. Figure 9 depicts the PESQ-derived MOS
for each of the four replacement methods for packet drop
probabilities up to 5%.
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Figure 9 PESQ derived MOS as a function of packet drop probability
For all cases the MOS resulting from the use of zero insertion is
less than that obtained by replacing with the previous sample, which
in turn is less than that of linear interpolation, which is slightly
less than that obtained by statistical interpolation.
Unlike the artifacts speech compression methods may produce when
subject to buffer loss, packet loss here effectively produces
additive white impulse noise. The subjective impression is that of
static noise on AM radio stations or crackling on old phonograph
records. For a given PESQ-derived MOS, this type of degradation is
more acceptable to listeners than choppiness or tones common in VoIP.
If MOS>4 (full toll quality) is required, then the following packet
drop probabilities are allowable:
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zero insertion - 0.05 %
previous sample - 0.25 %
linear interpolation - 0.75 %
STEIN - 2 %
If MOS>3.75 (barely perceptible quality degradation) is acceptable,
then the following packet drop probabilities are allowable:
zero insertion - 0.1 %
previous sample - 0.75 %
linear interpolation - 3 %
STEIN - 6.5 %
If MOS>3.5 (cell-phone quality) is tolerable, then the following
packet drop probabilities are allowable:
zero insertion - 0.4 %
previous sample - 2 %
linear interpolation - 8 %
STEIN - 14 %
Authors' Addresses
Yaakov (Jonathan) Stein
RAD Data Communications
24 Raoul Wallenberg St., Bldg C
Tel Aviv 69719
ISRAEL
Phone: +972 (0)3 645-5389
Email: yaakov_s@rad.com
David L. Black
EMC Corporation
176 South St.
Hopkinton, MA 69719
USA
Phone: +1 (508) 293-7953
Email: david.black@emc.com
Bob Briscoe
BT
Email: ietf@bobbriscoe.net
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