PWE3 Working Group Andrew G. Malis
Internet Draft Ken Hsu
Expiration Date: March 2002 Vivace Networks, Inc.
Tom Johnson Jeremy Brayley
Marlene Drost Steve Vogelsang
Ed Hallman John Shirron
Litchfield Communications, Inc. Laurel Networks, Inc.
Jim Boyle Luca Martini
Protocol Driven Networks, Inc. Craig White
Level 3 Communications, LLC.
Ron Cohen
Lycium Networks David Zelig
Corrigent Systems, LTD.
Prayson Pate
Overture Networks, Inc.
September 2001
SONET/SDH Circuit Emulation over Packet (CEP)
draft-malis-pwe3-sonet-00.txt
Status of this Memo
This document is an Internet-Draft and is in full conformance with
all provisions of section 10 of RFC 2026 [1].
Internet-Drafts are working documents of the Internet Engineering
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Internet-Drafts are draft documents valid for a maximum of six
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Abstract
Generic requirements for Pseudo Wire Emulation Edge-to-Edge (PWE3) have
been described in [3]. This draft lists SONET specific requirements
and provides encapsulation formats and semantics for connecting SONET
edge networks through a core packet network using IP, L2TP or MPLS.
This basic application of SONET interworking will allow SONET service
providers to take advantage of new technologies in the core in order to
provide SONET services.
Table of Contents
1 Conventions used in this document...........................2
2 Introduction................................................2
3 Scope.......................................................3
4 CEP Encapsulation Format....................................4
5 CEP Operation...............................................9
6 SONET/SDH Maintenance Signals..............................12
7 SONET/SDH Transport Timing.................................16
8 SONET/SDH Pointer Management...............................17
9 CEP Performance Monitors...................................18
10 Open Issues................................................20
11 Security Considerations....................................20
12 Intellectual Property Disclaimer...........................20
13 References.................................................22
14 Acknowledgments............................................23
15 AuthorÆs Addresses.........................................23
1 Conventions used in this document
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 [2].
2 Introduction
This document describes a protocol that performs SONET Emulation
over a variety of Packet-Switched Networks (PSNs) as part of the
PWE3 Working Group. The document assumes that the reader is
familiar with the PWE3 terminology and concepts described in PWE3
requirements and framework documents [3] and [4]. The protocol is
titled ôCircuit Emulation over Packetö (CEP).
The transmission system for circuit-oriented TDM signals is the
Synchronous Optical Network (SONET) [5], [9] / Synchronous Digital
Hierarchy (SDH) [6]. To support TDM traffic (which includes voice,
data, and private leased line services) PSNs must emulate the
circuit characteristics of SONET/SDH payloads. A circuit identifer
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and a CEP header are used to encapsulate the SONET/SDH TDM signals
for transmission over an arbitrary PSN.
This document also describes an optional extension to CEP called
Dynamic Bandwidth Allocation (DBA). This is a method for
dynamically reducing the bandwidth utilized by emulated SONET/SDH
circuits in the packet network. This bandwidth reduction is
accomplished by not sending the SONET/SDH payload through the packet
network under certain conditions such as AIS-P or STS SPE
Unequipped.
This document is based on a previous document describing a method
for encapsulating SONET signals for carriage over MPLS networks
(CEM) [7]. This document is closely related to [8] which describes
a MIB for controlling and observing CEP services.
3 Scope
This document describes how to provide CEP for the following digital
signals:
1. SONET STS-1 synchronous payload envelope (SPE)/SDH VC-3
2. STS-Nc SPE (N = 3, 12, 48, or 192)/SDH VC-4, VC-4-4c, VC-4-16c,
or VC-4-64c
For the remainder of this document, these constructs will be
referred to as SONET/SDH channels.
Although this document currently covers up to OC-192c/VC-4-64c,
future revision MAY address higher rates.
Other SONET/SDH signals, such as virtual tributary (VT) structured
sub-rate mapping, are not explicitly discussed in this document;
however, it can be extended in the future to support VT and lower
speed non-SONET/SDH services.
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4 CEP Encapsulation Format
In order to transport SONET/SDH SPEs through a packet-oriented
network, the SPE is broken into fragments. A Circuit ID Word and
CEP Header are pre-pended to each fragment. The basic CEP packet
appears in Figure 1.
+-----------------------------------+
| Circuit ID Word |
+-----------------------------------+
| CEP Header |
+-----------------------------------+
| |
| |
| SONET/SDH SPE Fragment |
| |
| |
+-----------------------------------+
Figure 1. Basic CEP Packet
The Circuit ID Word is a 32-bit field that contains an arbitrary
value that is used to map CEP packets to specific SONET/SDH
channels. The circuit ID word is intentionally designed to match
the format of an MPLS shim.
0 1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Circuit ID | Exp |S| TTL |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 2. CEP Circuit ID Word
Circuit ID: Matches the Label Position in an MPLS shim. It SHOULD
be used to map individual packet streams to SONET channels.
Exp: Experimental Use, 3 bits. SHOULD conform to use of Exp bits
within an MPLS shim.
S: Bottom of Stack, 1 bit. SHOULD be set to 1 to indicate the
bottom of an MPLS label stack.
TTL: Time to Live, 8 bits. SHOULD be utilized in a manner
consistent with the TTL field of an MPLS Shim.
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The CEP Header supports a basic and extended mode. The Basic CEP
Header provides the minimum functionality necessary to accurately
emulate a TDM SONET over a PSN. Bit 0 of the first 32-bit CEP
header indicates whether or not the extended header is present.
When this bit is 0, then no extended header is present. When this
bit is 1, then an extended header is present. At this time, the
contents of the extended header are for future study. However, it
is expected that this field will provide support for payload
compression, header protection, enhanced performance monitoring,
and/or other extensions to the base protocol.
The Basic CEP header has the following format:
0 1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|0|R|D|N|P| Structure Pointer[0:12] | Sequence Number[0:13] |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 3. Basic CEP Header Format
The Extended CEP header appears below:
0 1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|1|R|D|N|P| Structure Pointer[0:12] | Sequence Number[0:13] |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Reserved |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 4. Extended CEP Header Format
The above fields are defined as follows:
R bit: CEP-RDI. This bit is set to one to signal to the remote CEP
function that a loss of packet synchronization has occurred. See
section 5.4 for details.
D bit: Signals DBA Mode. MUST be set to zero for Normal Operation.
MUST be set to one if CEP is currently in DBA mode. DBA is an
optional mode during which trivial SPEs are not transmitted into the
packet network. See Table 1 and section 5 for further details.
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The N and P bits: MAY be used to explicitly relay negative and
positive pointer adjustment events across the PSN. They are also
used to relay SONET/SDH maintenance signals such as AIS-P. See
Table 1 and sections 6 and 8 for more details.
+---+---+---+----------------------------------------------+
| D | N | P | Interpretation |
+---+---+---+----------------------------------------------+
| 0 | 0 | 0 | Normal Mode û No Ptr Adjustment |
| 0 | 0 | 1 | Normal Mode û Positive Ptr Adjustment |
| 0 | 1 | 0 | Normal Mode û Negative Ptr Adjustment |
| 0 | 1 | 1 | Normal Mode û AIS-P |
| | | | |
| 1 | 0 | 0 | DBA Mode û STS SPE Unequipped |
| 1 | 0 | 1 | DBA Mode û STS SPE Unequipped Pos Ptr Adj |
| 1 | 1 | 0 | DBA Mode û STS SPE Unequipped Neg Ptr Adj |
| 1 | 1 | 1 | DBA Mode û AIS-P |
+---+---+---+----------------------------------------------+
Table 1. Interpretation of D, N, and P bits
Sequence Number[0:13]: This is a packet sequence number, which MUST
continuously cycle from 0 to 0x3FFF. It SHOULD begin at zero when a
CEP channel is created.
Structure Pointer[0:12]: The Structure Pointer MUST contain the
offset of the J1 byte within the CEP SPE Fragment. The value is
from 0 to 0x1FFE, where 0 means the first byte after the CEP header.
The Structure Pointer MUST be set to 0x1FFF if a packet does not
carry the J1 byte. See [5], [6] and [9] for more information on the
J1 byte and the SONET/SDH payload pointer. Implementations MUST
support SPE Fragments of up to 1023 bytes and MAY support SPE
fragments of up to 8191 bytes.
Note: CEP packets are fixed in length for all of the packets of a
particular emulated TDM stream. This length is statically
provisioned for each TDM stream. Therefore, the length of each CEP
packet does not need to be carried in the CEP header.
4.1 PSN Encapsulation
In principle, CEP packets can be carried over any packet-oriented
network. The following sections describe specifically how CEP
packets MUST be encapsulated for carriage over MPLS or IP networks.
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4.1.1 MPLS Encapsulation
To transport a CEP packet over an MPLS network, an MPLS label-stack
MUST be pushed on top of the CEP packet.
+-----------------------------------+
| MPLS Label Stack |
+-----------------------------------+
| Circuit ID Word |
+-----------------------------------+
| CEP Header |
+-----------------------------------+
| |
| |
| SONET/SDH SPE Fragment |
| |
| |
+-----------------------------------+
Figure 5. Typical MPLS Transport Encapsulation
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4.1.2 IP Encapsulation
It is highly desirable to define a single encapsulation format that
will work for both IP and MPLS. Furthermore, it is desirable that
the encapsulation mechanism be as efficient as possible.
One way to achieve these goals is to map CEP directly onto IP.
Because the Circuit ID Word is essentially an MPLS Shim, the CEP
packet may be treated as an MPLS packet. A mechanism for carrying
MPLS over IP is described in [10].
Using this encapsulation scheme would result in the packet format
illustrated in figure 6.
+-----------------------------------+
| |
| IPv6/v4 Header [10] |
| |
+-----------------------------------+
| Circuit ID Word |
+-----------------------------------+
| CEP Header |
+-----------------------------------+
| |
| |
| SONET/SDH SPE Fragment |
| |
| |
+-----------------------------------+
Figure 6. MPLS Transport Encapsulation
4.1.3 L2TP Encapsulation
Encapsulation for L2TP PSNs is for future study.
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5 CEP Operation
The following sections describe CEP operation.
5.1 Introduction and Terminology
CEP MUST support a normal mode of operation and MAY support an
optional extension called Dynamic Bandwidth Allocation (DBA).
During normal operation, SONET/SDH payloads are fragmented, pre-
pended with the CEP Header, the Circuit ID Word, and the PSN header,
and then transmitted into the packet network. During DBA mode, only
the CEP header, the Circuit ID Word, and PSN header are transmitted.
This is done to conserve bandwidth when meaningful user data is not
present in the SPE, such as during AIS-P or STS SPE Unequipped.
5.1.1 CEP Packetizer and De-Packetizer
As with all adaptation functions, CEP has two distinct components:
adapting TDM SONET/SDH into a CEP packet stream, and converting the
CEP packet stream back into a TDM SONET/SDH. The first function
will be referred to as CEP Packetizer and the second as CEP De-
Packetizer. This terminology is illustrated in figure 7.
+------------+ +---------------+
| | | |
SONET --> | CEP | --> PSN --> | CEP | --> SONET
SDH | Packetizer | | De-Packetizer | SDH
| | | |
+------------+ +---------------+
Figure 7. CEP Terminology
Note: the CEP de-packetizer requires a buffering mechanism to
account for delay variation in the CEP packet stream. This
buffering mechanism will be generically referred to as the CEP
jitter buffer.
5.1.2 CEP DBA
DBA is an optional mode of operation that only transmits the CEP
Header, the Circuit ID Word, and PSN Header into the packet network
under certain circumstances such as AIS-P or STS Unequipped.
If DBA is supported by a CEP implementation, the user SHOULD be able
to configure if DBA will be triggered by AIS-P, STS Unequipped,
both, or neither on a per channel basis.
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If DBA is supported, the determination of AIS-P and STS Unequipped
MUST be based on the state of SONET/SDH Section, Line, and Path
Overhead bytes.
During AIS-P, there is no valid payload pointer, so pointer
adjustments cannot occur. During STS Unequipped, the SONET/SDH
payload pointer is valid, and therefore pointer adjustments MUST be
supported even during DBA. See Table 1 for details.
5.2 Description of Normal CEP Operation
During normal operation, the CEP packetizer will receive a fixed
rate byte stream from a SONET/SDH interface. When a packets worth
of data has been received from a SONET/SDH channel, the CEP Header,
the Circuit ID Word, and PSN Header are pre-pended to the SPE
fragment and the resulting CEP packet is transmitted into the packet
network. Because all CEP packets associated with a specific
SONET/SDH channel will have the same length, the transmission of CEP
packets for that channel SHOULD occur at regular intervals.
At the far end of the packet network, the CEP de-packetizer will
receive packets into a jitter buffer and then play out the received
byte stream at a fixed rate onto the corresponding SONET/SDH
channel. The jitter buffer SHOULD be adjustable in length to
account for varying network delay behavior. The receive packet rate
from the packet network should be exactly balanced by the
transmission rate onto the SONET/SDH channel, on average. The time
over which this average is taken corresponds to the depth of the
jitter buffer for a specific CEP channel.
The CEP sequence numbers provide a mechanism to detect lost and/or
mis-ordered packets. The CEP de-packetizer MUST detect lost or mis-
ordered packets. The CEP de-packetizer SHOULD play out an all ones
pattern (AIS) in place of any dropped packets. The CEP de-
packetizer MAY re-order packets received out of order. If the CEP
de-packetizer does not support re-ordering, it must drop mis-ordered
packets.
5.3 Description of CEP Operation during DBA
There are several issues that should be addressed by a workable CEP
DBA mechanism. First, when DBA is invoked, there should be a
substantial savings in bandwidth utilization in the packet network.
The second issue is that the transition in and out of DBA should be
tightly coordinated between the local CEP packetizer and CEP de-
packetizer at the far side of the packet network. A third is that
the transition in and out of DBA should be accomplished with minimal
disruption to the adapted data stream.
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Another goal is that the reduction of CEP traffic due to DBA should
not be mistaken for a fault in the packet network or vice-versa.
Finally, the implementation of DBA should require minimal
modifications beyond what is necessary for the nominal CEP case.
The mechanism described below is a reasonable balance of these
goals.
During DBA, packets MUST be emitted at exactly the same rate as they
would be during normal operation. This SHOULD be accomplished by
transmitting each DBA packet after a complete packet of data has
been received from the SONET/SDH channel. The only change from
normal operation is that the CEP packets during DBA MUST only carry
the CEP header, the Circuit ID Word, and the PSN Header. Because
some links have a minimum supported packet size, the CEP packetizer
MAY append a configurable number of bytes immediately after the CEP
header to pad out the CEP packet to reach the mimumum supported
packet size. The D-bit MUST be set to one, to indicate that DBA is
active.
The CEP de-packetizer MUST assume that each packet received with the
D-bit set represents a normal-sized packet containing an AIS-P or
SPE Unequipped payload as noted by N and P. See Table 1. The CEP
de-packetizer MUST accept DBA packets with or without padding.
This allows the CEP packetization and de-packetization logic during
DBA to be similar to the nominal case. It ensures that the correct
SONET/SDH indication is reliably transmitted between CEP adaptation
points. It minimizes the risk of under or over running the jitter
buffer during the transition in and out of DBA, since packets are
continuously transmitted during DBA. And, it guarantees that faults
in the packet network are recognized as distinctly different from
line conditioning on the SONET/SDH interfaces.
5.4 Packet Synchronization
A key component in declaring the state of a CEP service is whether
or not the CEP de-packetizer is in or out of packet synchronization.
The following paragraphs describe how that determination is made.
As discussed in section 5, a CEP de-packetizer MAY or MAY NOT
support re-ordering of mis-ordered packets.
As packets are received from the PSN, they are placed into a jitter
buffer prior to play out on the SONET interface. If a CEP de-
packetizer supports re-ordering, any packet received before itÆs
play out time will still be considered valid.
If a CEP de-packetizer does not support re-ordering, a number of
approaches may be used to minimize the impact of mis-ordered or lost
packets on the final re-assembled SONET stream. For example, AAL1
[11] uses a simple state-machine to re-order packets in a sub-set of
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possible cases. The algorithm for these state-machines is outside
of the scope of CEP.
However, the final determination as to whether or not to declare
acquisition or loss of packet synchronization MUST be based on the
same criteria regardless of whether an implementation supports or
does not support re-ordering.
Therefore, the determination of acquisition or loss of packet
synchronization is always made at SONET play-out time. During SONET
play-out, the CEP de-packetizer will play received CEP packets onto
the SONET interface. However, if the jitter buffer is empty or the
packet to be played out has not been received, the CEP de-packetizer
will have to play out an empty packet onto the SONET interface in
place of the unavailable packet.
The acquisition of packet synch is based on the number of sequential
CEP packets that are played onto the SONET interface. While, loss
of packet synch is based on the number of sequential æemptyÆ packets
that are played onto the SONET interface. Specific details of these
two cases is described below.
5.4.1 Acquisition of Packet Synchronization
At startup, a CEP de-packetizer will be out of packet
synchronization by default. To declare packet synchronization at
startup or after a loss of packet synchronization, the CEP de-
packetizer must play-out a configurable number of CEP packets with
sequential sequence numbers towards the SONET interface.
5.4.2 Loss of Packet Synchronization
Once a CEP de-packetizer is in packet sync, it may encounter a set
of events that will cause it to lose packet synchronization.
If the CEP de-packetizer encounters more than a configurable number
of sequentialempty packets, the CEP de-packetizer MUST declare loss
of packet synchronization.
6 SONET/SDH Maintenance Signals
There are several issues that must be considered in the mapping of
maintenance signals between SONET/SDH and a PSN. A description of
how these signals and conditions are mapped between the two domains
is described below.
For clarity, the mappings are split into two groups: SONET/SDH to
PSN, and PSN to SONET/SDH.
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6.1 SONET/SDH to PSN
The following sections describe how SONET/SDH Maintenance Signals
and Alarm conditions are mapped into a Packet Switched Network.
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6.1.1 AIS-P Indication
In a SONET/SDH network, SONET Path outages are signaled using
maintenance alarms such as Path AIS (AIS-P). In particular, AIS-P
indicates that the SONET/SDH Path is not currently transmitting
valid end-user data, and the SPE contains all ones.
It should be noted that nearly every type of service-effecting
section or line defect will result in an AIS-P condition.
The SONET/SDH hierarchy is illustrated below.
+----------+
| PATH |
+----------+
^
|
AIS-P
|
|
+----------+
| LINE |
+ ---------+
^ ^
| |
AIS-L +------ LOP
|
|
+----------+
| SECTION |
+----------+
^ ^
| |
| |
LOS LOF
Figure 8. SONET/SDH Fault Hierarchy.
Should the Section Layer detect a Loss of Signal (LOS) or Loss of
Frame (LOF) condition, it sends AIS-L up to the Line Layer. If the
Line Layer detects AIS-L or Loss of Path (LOP), it sends AIS-P to
the Path Layer.
In normal mode during AIS-P, CEP packets are generated as usual.
The N and P bits MUST be set to 11 binary to signal AIS-P explicitly
through the packet network. The D-bit MUST be set to zero to
indicate that the SPE is being carried through the packet network.
Normal CEP packets with the SPE fragment, CEP Header, the Circuit ID
Word, and PSN Header MUST be transmitted into the packet network.
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However, to conserve network bandwidth during AIS-P, DBA MAY be
employed. If DBA has been enabled for AIS-P and AIS-P is currently
occurring, the N and P bits MUST be set to 11 binary to signal AIS,
and the D-bit MUST be set to one to indicate that the SPE is not
being carried through the packet network. Only the CEP header, the
Circuit ID Word, and the PSN Header MUST be transmitted into the
packet network.
6.1.2 STS SPE Unequipped Indication
The declaration of STS SPE unequipped MUST conform to [9]. Quoted
below:
ôR6-135 [481] STS PTE shall detect an STS Path Unequipped (UNEQ-P)
defect within 10 ms of the onset of at least five consecutive
samples (which may or may not be consecutive frames) of unequipped
STS Signal Labels (C2 byte), as specified in Table 6-2ö
The termination of STS SPE unequipped MUST also conform to [9].
ôR6-137 [485v2] STS PTE shall terminate an UNEQ-P defect within 10
ms of the onset of at least five consecutive samples (which may or
may not be consecutive frames) of STS Signal Labels that are not
unequipped or all-ons, as specified in Table 6-2ö
For normal operation during SPE Unequipped, the N and P bits MUST be
interpreted as usual. The SPE MUST be transmitted into the packet
network along with the CEP Header, the Circuit ID Word, and PSN
Header, and the D-Bit MUST be set to zero.
If DBA has been enabled for STS SPE Unequipped and the Unequipped is
occurring on the SONET/SDH channel, the D-bit MUST be set to one to
indicate DBA is active. Only the CEP Header, the Circuit ID Word,
and PSN Header MUST be transmitted into the packet network. The N
and P bits MAY be used to signal pointer adjustments as normal. See
Table 1 and section 5 for details.
6.1.3 CEP-RDI
The CEP function MUST send CEP-RDI towards the packet network during
loss of packet synchronization. This MUST be accomplished by
setting the R bit to one in the CEP header.
6.2 PSN to SONET/SDH
The following sections discuss how the various conditions on the
packet network are converted into SONET/SDH indications.
6.2.1 AIS-P Indication
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There are several conditions in the packet network that will cause
the CEP de-packetization function to play out an AIS-P indication
towards a SONET/SDH channel.
The first of these is the receipt of CEP packets with the N and P
bits set to one, and the D-bit set to zero. This is an explicit
indication of AIS-P being received at the far-end of the packet
network, with DBA disabled for AIS-P. The CEP de-packetizer MUST
play out the received SPE fragment (which will incidentally be
carrying all ones), and MUST configure the SONET/SDH Overhead to
signal AIS-P as defined in [5], [6], and [9].
The second case is the receipt of CEP packets with the N and P bits
set to one, and the D-bit set to one. This indicates that AIS-P is
being received at the far-end of the packet network, with DBA
enabled for AIS-P. The CEP de-packetizer MUST play out one packetÆs
worth of all ones for each packet received, and MUST configure the
SONET/SDH Overhead to signal AIS-P as defined in [5], [6], and [9].
A third case that will cause a CEP de-packetization function to play
out an AIS-P indication onto a SONET/SDH channel is during loss of
packet synchronization. The CEP de-packetizer MUST configure the
SONET/SDH Overhead to signal AIS-P as defined in [5], [6], and [9].
6.2.2 STS SPE Unequipped Indication
There are three conditions in the packet network that will cause the
CEP function to transmit STS SPE Unequipped indications onto the
SONET/SDH channel.
The first, which is transparent to CEP, is the receipt of regular
CEP packets that happen to be carrying an SPE that contains the
appropriate Path overhead to signal STS SPE unequipped. This case
does not require any special processing on the part of the CEP de-
packetizer.
The second case is the receipt of CEP packets that have the D-bit
set to one to indicate DBA active and the N and P bits set to 00
binary, 01 binary, or 10 binary to indicate SPE Unequipped with or
without pointer adjustments. The CEP de-packetizer MUST use this
information to transmit a packet of all zeros onto the SONET/SDH
interface, and adjust the payload pointer as necessary.
The third case when a CEP de-packetizer MUST play out an STS SPE
Unequipped Indication towards the SONET interface is when the VC-
label has been withdrawn due to de-provisioning of the circuit.
7 SONET/SDH Transport Timing
It is assumed that the distribution of SONET/SDH Transport timing
information is addressed through external mechanisms such as
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Building Integrated Timing System (BITS), Global Positioning System
(GPS) or other such methods and is therefore outside of the scope of
this specification.
8 SONET/SDH Pointer Management
A pointer management system is defined as part of the definition of
SONET/SDH. Details on SONET/SDH pointer management can be found in
[5], [6], and [9]. If there is a frequency offset between the frame
rate of the transport overhead and that of the SONET/SDH SPE, then
the alignment of the SPE shall periodically slip back or advance in
time through positive or negative stuffing.
The emulation of this aspect of SONET networks may be accomplished
using a variety of techniques including (but not limited to)
explicit pointer adjustment relay (EPAR) and adaptive pointer
management (APM).
In any case, the handling of the SPE data by the CEP packetizer is
the same.
During a negative pointer adjustment event, the CEP packetizer MUST
incorporate the H3 byte from the SONET/SDH stream into the CEP
packet payload in order with the rest of the SPE. During a positive
pointer adjustment event, the CEP de-packetizer MUST strip the stuff
byte from the CEP packet payload.
When playing out a negative pointer adjustment event, the
appropriate byte of the CEP payload MUST be placed into the H3 byte
of the SONET/SDH stream. When playing out a positive pointer
adjustment, the CEP de-packetizer MUST insert a stuff-byte into the
appropriate position within the SONET/SDH stream.
The details regarding the use of the H3 byte and stuff byte during
positive and negative pointer adjustments can be found in [5], [6],
and [9].
8.1 Explicit Pointer Adjustment Relay (EPAR)
CEP provides an OPTIONAL mechanism to explicitly relay pointer
adjustment events from one side of the PSN to the other. This
technique will be referred to as Explicit Pointer Adjustment Relay
(EPAR). The mechanics of EPAR are described below.
The following text only applies to implementations that choose to
implement EPAR. Any CEP implementation that does not support EPAR
MUST either set the N and P bits to zero or utilize them to relay
AIS-P and STS Unequipped as shown in table 1.
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If EPAR is being used, the pointer adjustment event MUST be
transmitted in three consecutive packets by the packetizer. The de-
packetizer MUST play out the pointer adjustment event when any one
packet with N/P bit set is received.
References [5],[6],and [9] specify that pointer adjustment events
MUST be separated by three SONET/SDH frames without a pointer
adjustment event. In order to explicitly relay all legal pointer
adjustment events, the packet size for a specific circuit SHOULD be
no larger than (783 * 4 * N)/3, where N is the STS-Nc multiplier.
In addition, it is possible for pointer adjustments to occur in back
to back SONET/SDH frames. In order to support this possibility,
EPAR implementations SHOULD set the packet size for a particular
circuit to be no larger than (783*N)/3. Where N is the STS-Nc
multiplier.
Since the minimum value of N is one, EPAR implementations SHOULD
support a minimum payload length of 783/3 or 261 bytes.
For EPAR implementations, the CEP de-packetizer MUST utilize the CEP
sequence numbers to insure that SONET/SDH pointer adjustment events
are not played any more frequently than once per every three CEP
packets transmitted by the remote CEP packetizer.
If both bits are set, then an AIS-P event has occurred (this is
further discussed in section 6).
When DBA is invoked (i.e. the D-bit = 1), N and P have additional
meanings. See Table 1 and section 5.
8.2 Adaptive Pointer Management (APM)
Another OPTIONAL method that may be used to emulate SONET pointer
management is Adaptive Pointer Management (APM). In basic terms,
APM uses information about the depth of the CEP jitter buffers to
introduce pointer adjustments in the reassembled SONET SPE.
Details about specific APM algorithms is for future study.
9 CEP Performance Monitors
SONET/SDH as defined in [5], [6], and [9], includes the definition
of several counters that may be used to monitor the performance of
SONET/SDH services. These counters are referred to as Performance
Monitors.
In order for CEP to be utilized by traditional SONET/SDH network
operators, CEP SHOULD provide similar functionality. To this end,
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the following sections describe a number of counters that will
collectively be referred to as CEP Performance Monitors.
9.1 Near-End Performance Monitors
These performance monitors are maintained by the CEP De-Packetizer
during reassembly of the SONET stream.
The performance monitors are based on two types of defects.
Type 1 defect is defined as: missing or dropped packet.
Type 2 defect is defined as: buffer under run, buffer over-run,
LOPS.
Each second that contain at least one type 1 defect SHALL be
declared as ES-CEP.
Each second that contain type 2 defect, or missing packets above
pre-defined, configurable threshold of missing/dropped packets SHALL
be declared both SES-CEP and ES-CEP. Default value for missing
packet to SES is 3.
UAS-CES shall be declared after X consecutives SES-CEP, cleared
after X consecutive seconds without SES-CEP. Default value of X is
10 seconds.
Once unavailability is declared, ES and SES counts shall be
inhibited up to the point where the unavailability was started. Once
unavailability is removed, ES that occurred along the X seconds
clearing period shall be added to the ES counts. An update is
required even for closed intervals if necessary.
LOPS failure is declared after 2.5 +/- 0.5 seconds of LOPS defect,
and cleared after 10 seconds free of LOPS defect state. The VC is
considered down as long as LOPS failure is declared.
FC-CEP is the number of time type 1 or type 2 defect states were
declared. The NE shall have thresholding on ES-CEP, SES-CEP and
UAS-CEP (thresholding mean activate a notification if more than pre-
defined # of seconds are declared as ES, etc. in 15 minutes
interval).
9.2 Far-End Performance Monitors
These performance monitors provide insight into the CEM De-
packetizer at the far-end of the PSN.
Far end statistics are based on the RDI-CEP bit. Limited
functionality is supported compared to [GR-253] for simplicity and
because it is assumed that all relevant statistics are available
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from the end point of the PW. CEP-FE defect is declared when CEP-RDI
is set in the incoming CEP packets.
CEP-FE failure declared after 2.5 +/- 0.5 seconds of CEP-FE defect,
and cleared after 10 seconds free of CES-FE defect state. Sending
notification to the OS for CEP-FE failure is local policy.
This draft does not attempt to define SES-CEPFE, UAS-CEPFE and FC-
CEPFE, but they can be added if to fully emulate GR-253 far end PM
(thresholding is required too here except for FC-CEPFE). (Note that
ES-CEPFE is not relevant since CEP does not report back missing
packets - only LOPS which is SES).
The definition of additional performance monitors is for future
study.
10 Open Issues
This version of the draft does not address payload compression
within the emulated SONET. Payload compression is expected to be
supported by future versions of this draft by utilizing the extended
CEP header.
This version of the draft does not tie into PWE3 maintenance
mechanisms for the setup and tear down of services. That short-
coming will be addressed in future revisions of this document.
Underlying MPLS QoS requirements are not covered by this revision of
the draft. Future revisions may discuss underlying QoS
requirements.
Support for VT and lower speed non-SONET/SDH services are not
covered in this revision of the draft. Future revisions may address
VT and non-SONET/SDH TDM services.
An alternate version of DBA has been suggested that would suppress
transmission of the entire CEP packet stream under certain
circumstances. Future versions of this draft may define such a
mechanism.
11 Security Considerations
This document does not address or modify security issues within the
relevant PSNs.
12 Intellectual Property Disclaimer
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This document is being submitted for use in IETF standards
discussions. Vivace Networks, Inc. has filed one or more patent
applications relating to the CEP technology outlined in this
document. Vivace Networks, Inc. will grant free unlimited licenses
for use of this technology.
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13 References
[1] Bradner, S., "The Internet Standards Process -- Revision 3",
BCP 9, RFC 2026, October 1996.
[2] Bradner, S., "Key words for use in RFCs to Indicate Requirement
Levels", BCP 14, RFC 2119, March 1997
[3] Xiao et al, " Requirements for Pseudo-Wire Emulation Edge-to-
Edge (PWE3)", draft-ietf-pwe3-requirements-01.txt, work in
progress, July 2001
[4] Pate et al, ôFramework for Pseudo Wire Emulation Edge-to-Edge
(PWE3)ö, draft-pate-pwe3-framework-01.txt, work in progress,
July 13, 2001
[5] American National Standards Institute, "Synchronous Optical
Network (SONET) - Basic Description including Multiplex
Structure, Rates and Formats," ANSI T1.105-1995.
[6] ITU Recommendation G.707, "Network Node Interface For The
Synchronous Digital Hierarchy", 1996.
[7] Malis et al, ôSONET/SDH Circuit Emulation Service Over MPLS
(CEM) Encapsulationö, draft-malis-sonet-ces-mpls-05.txt, work
in progress, July 2001.
[8] Danenberg et al, "SONET/SDH Circuit Emulation Service Over PSN
(CEP) Management Information Base Using SMIv2", draft-
danenberg-pw-cem-mib-01.txt, work in progress, July 2001.
[9] Telcordia Technologies, ôSynchronous Optical Network (SONET)
Transport Systems: Common Generic Criteriaö, GR-253-CORE, Issue
3, September 2000.
[10] Worster, ôMPLS Label Stack Encapsulation in IPö, draft-
worster-mpls-in-ip-05, work in progress, July 2001.
[11] ITU-T, ôRecommendation I.363.1, B-ISDN Adaptation Layer
Specification: Type AAL1ö, Appendix III, August 1996.
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14 Acknowledgments
The authors would like to thank all the members of the PWE3 WG who
have contributed to this effort.
15 AuthorÆs Addresses
Andrew G. Malis
Vivace Networks, Inc.
2730 Orchard Parkway
San Jose, CA 95134
Email: Andy.Malis@vivacenetworks.com
Ken Hsu
Vivace Networks, Inc.
2730 Orchard Parkway
San Jose, CA 95134
Email: Ken.Hsu@vivacenetworks.com
Jeremy Brayley
Laurel Networks, Inc.
2706 Nicholson Rd.
Sewickley, PA 15143
Email: jbrayley@laurelnetworks.com
Steve Vogelsang
Laurel Networks, Inc.
2706 Nicholson Rd.
Sewickley, PA 15143
Email: sjv@laurelnetworks.com
John Shirron
Laurel Networks, Inc.
2607 Nicholson Rd.
Sewickley, PA 15143
Email: jshirron@laurelnetworks.com
Luca Martini
Level 3 Communications, LLC.
1025 Eldorado Blvd.
Broomfield, CO 80021
Email: luca@level3.net
Tom Johnson
Litchfield Communications, Inc.
76 Westbury Park Rd.
Watertown, CT 06795
Email: tom_johnson@litchfieldcomm.com
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Ed Hallman
Litchfield Communications, Inc.
76 Westbury Park Rd.
Watertown, CT 06795
Email: ed_hallman@litchfieldcomm.com
Marlene Drost
Litchfield Communications, Inc.
76 Westbury Park Rd.
Watertown, CT 06795
Email: marlene_drost@litchfieldcomm.com
Jim Boyle
Protocol Driven Networks, Inc.
1381 Kildaire Farm #288
Cary, NC 27511
Email: jboyle@pdnets.com
David Zelig
Corrigent Systems LTD.
126, Yigal Alon st.
Tel Aviv, ISRAEL
Email: davidz@corrigent.com
Ron Cohen
Lycium Networks
Hamanofim 9, POB 12256
Herzeliya, Israel 46733
Email: ronc@lyciumnetworks.com
Prayson Pate
Overture Networks
P. O. Box 14864
RTP, NC, USA 27709
Email: prayson.pate@overturenetworks.com
Craig White
Level3 Communications, LLC.
1025 Eldorado Blvd,
Broomfield CO 80021
Email: Craig.White@Level3.com
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Appendix A. SONET/SDH Rates and Formats
For simplicity, the discussion in this section uses SONET
terminology, but it applies equally to SDH as well. SDH-equivalent
terminology is shown in the tables.
The basic SONET modular signal is the synchronous transport signal-
level 1 (STS-1). A number of STS-1s may be multiplexed into higher-
level signals denoted as STS-N, with N synchronous payload envelopes
(SPEs). The optical counterpart of the STS-N is the Optical Carrier-
level N, or OC-N. Table 2 lists standard SONET line rates discussed
in this document.
OC Level OC-1 OC-3 OC-12 OC-48 OC-192
SDH Term - STM-1 STM-4 STM-16 STM-64
Line Rate(Mb/s) 51.840 155.520 622.080 2,488.320 9,953.280
Table 2. Standard SONET Line Rates
Each SONET frame is 125 ´s and consists of nine rows. An STS-N frame
has nine rows and N*90 columns. Of the N*90 columns, the first N*3
columns are transport overhead and the other N*87 columns are SPEs.
A number of STS-1s may also be linked together to form a super-rate
signal with only one SPE. The optical super-rate signal is denoted
as OC-Nc, which has a higher payload capacity than OC-N.
The first 9-byte column of each SPE is the path overhead (POH) and
the remaining columns form the payload capacity with fixed stuff
(STS-Nc only). The fixed stuff, which is purely overhead, is N/3-1
columns for STS-Nc. Thus, STS-1 and STS-3c do not have any fixed
stuff, STS-12c has three columns of fixed stuff, and so on.
The POH of an STS-1 or STS-Nc is always nine bytes in nine rows. The
payload capacity of an STS-1 is 86 columns (774 bytes) per frame.
The payload capacity of an STS-Nc is (N*87)-(N/3) columns per frame.
Thus, the payload capacity of an STS-3c is (3*87 - 1)*9 = 2,340
bytes per frame. As another example, the payload capacity of an STS-
192c is 149,760 bytes, which is exactly 64 times larger than the
STS-3c.
There are 8,000 SONET frames per second. Therefore, the SPE size,
(POH plus payload capacity) of an STS-1 is 783*8*8,000 = 50.112
Mb/s. The SPE size of a concatenated STS-3c is 2,349 bytes per frame
or 150.336 Mb/s. The payload capacity of an STS-192c is 149,760
bytes per frame, which is equivalent to 9,584.640 Mb/s. Table 2
lists the SPE and payload rates supported.
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SONET STS Level STS-1 STS-3c STS-12c STS-48c STS-192c
SDH VC Level - VC-4 VC-4-4c VC-4-16c VC-4-64c
Payload Size(Bytes) 774 2,340 9,360 37,440 149,760
Payload Rate(Mb/s) 49.536 149.760 599.040 2,396.160 9,584.640
SPE Size(Bytes) 783 2,349 9,396 37,584 150,336
SPE Rate(Mb/s) 50.112 150.336 601.344 2,405.376 9,621.504
Table 2. Payload Size and Rate
To support circuit emulation, the entire SPE of a SONET STS or SDH
VC level is encapsulated into packets, using the encapsulation
defined in section 4, for carriage across packet-switched networks.
Full Copyright Statement
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