Internet Draft
Data Networking Group Pankaj K. Jha
Internet Draft Cypress Semiconductor
draft-jha-optical-hdt-00.txt November, 2000
Expiration Date: April, 2001
A Hybrid Data Transport Protocol for Optical Networks
1. Status of this Memo
This document is an Internet-Draft and is in full conformance with
all provisions of Section 10 of RFC2026 [1].
Internet drafts are working documents of the Internet Engineering
Task Force (IETF), its areas, and its working groups. Note that other
groups may also distribute working documents as Internet-Drafts.
Internet drafts are draft documents valid for a maximum of six months
and may be updated, replaced, or obsoleted by other documents at any
time. It is inappropriate to use Internet-Drafts as reference
material or to cite them other than as "work in progress".
The list of current Internet-Drafts can be accessed at
http://www.ietf.org/ietf/1id-abstracts.txt.
The list of Internet-Draft Shadow Directories can be accessed at
http://www.ietf.org/shadow.html.
2. Abstract
Next-generation optical network configurations are increasingly
becoming a complex mix of SONET/SDH and DWDM-based direct data-over-
fiber links. As SONET/SDH networks are primarily geared for TDM
support, transporting IP/ATM packets along with PDH (Plesiochronous
Digital Hierarchy) channels (such as T1/T3/E1/E3) results in
inefficient utilization of provisioned bandwidth. In addition, hybrid
networks of ring and mesh configurations for short and long haul
LAN/MAN/WAN communications need a unified end-to-end protocol that
can seamlessly transport packets (native or otherwise) over any mix
of optical networks.
This draft describes a Hybrid Data Transport (HDT) protocol that
provides a unified multi-service optical transport across SONET/SDH
and direct data-over-fiber networks. In addition, it allows
transmission of any combinations of Ethernet, T1/T3, ATM, IP (or any
other protocol), NxT1/T3, fractional T1 (in increments of DS0),
lower-rate SONET/SDH or any raw data stream over SONET/SDH networks.
3. Conventions used in this document
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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].
TABLE OF CONTENTS
1. Status of this Memo ............................................1
2. Abstract .......................................................1
3. Conventions used in this document ..............................1
4. Glossary .......................................................5
5. Assumptions & Nomenclature .....................................5
6. Organization of this Draft .....................................6
7. Objectives for Multiservice Transport over Optical Networks ....6
8. Conventional Approaches for Multiservice Transport .............7
8.1 Bandwidth Allocation on SONET for Data Transport .............8
8.1.1 Virtual concatenation ....................................8
8.1.2 Inverse Multiplexing .....................................9
8.1.3 Disadvantages of VT-based Packet Transports ..............9
8.1.4 Using entire SONET SPE for Packet Data ..................11
8.1.5 Bandwidth Considerations for Data over Fiber Networks ...12
8.2 Traditional Data Transport Protocols ........................12
8.2.1 Packet-Over-SONET (POS) .................................12
8.2.2 ATM VP Multiplexing .....................................13
8.2.3 Ethernet-like Treatment of SONET ........................14
9. A Unified Data Link Layer for Optical Networks ................15
9.1 Data Link Header for Control Packets ........................17
9.2 Data Link Layer for Data Packets ............................17
10. Hybrid Data Transport .......................................18
11. Motivations for HDT .........................................21
12. Advantages of HDT ...........................................21
13. HDT Frame Structure Overview ................................22
13.1 Payload Header (PH) Structure ..............................23
13.1.1 Core Header (cHdr) ......................................23
13.1.2 Next Fragment Offset ....................................23
13.1.3 Header with MPLS labels .................................24
13.1.4 Header with OAM bytes ...................................25
13.1.5 MPLS labels followed by OAM bytes .......................25
13.1.6 Core Header HEC (cHEC) ..................................26
13.2 User Payload ...............................................26
13.2.1 Payload .................................................26
13.2.2 Payload CRC (pCRC) ......................................26
14. HDT Framing Examples ........................................27
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15. Transmission of HDT Frames ..................................27
15.1 SONET Networks .............................................27
15.1.1 Concatenated SONET ......................................28
15.1.2 Non-concatenated - Inverse Multiplexing .................28
15.1.3 Virtual Concatenation over SONET ........................28
15.2 Data-over-Fiber and WDM Networks ...........................28
16. Protocol Implementation Considerations ......................29
17. Preserving Payload CRC for Robust Transmission ..............30
17.1 Payload Error Suppression with MPLS Shim Headers ...........30
17.2 Fault Detection and Isolation with an External MPLS stack ..31
18. Data Transport over Optical Networks using HDT ..............32
18.1 Protocol-independent operation for MPLS ....................32
18.2 Transport without MPLS .....................................32
18.3 Transport using MPLS .......................................33
18.3.1 MPLS as a Shim Header within Layer 2 Frames .............33
18.3.2 MPLS in Payload Header for True Multiservice Transport ..33
18.3.3 Interconnection of MPLS Networks over Public Networks ...34
19. Single MPLS Control Plane for Multiservice Transport ........35
20. Minimization of Number of LSPs ..............................35
21. Multiservice Switching over WDM Links .......................36
22. Frame Delineation Methods ...................................37
22.1 HDLC .......................................................37
22.2 SDL (Simple Data Link, rfc2823) ............................38
22.2.1 Length (LHdr) ...........................................39
22.2.2 Length HEC (LHEC) .......................................40
22.2.3 Payload CRC (pCRC) ......................................40
23. DC-balancing ................................................40
24. Scrambling ..................................................40
25. Special SDL Frames ..........................................40
25.1 Null/Idle Frame ............................................41
25.2 Scrambler State ............................................41
25.3 A/B Messages ...............................................41
25.4 Single ATM Cell Transport ..................................41
26. HDT Payload Header (PH) Structure Details ...................42
26.1 Core Header (cHdr) .........................................42
26.1.1 Payload Identifier (PI) .................................43
26.1.2 Header Extension (HEX) ..................................44
26.1.3 Bandwidth Allocation (BA) ...............................45
26.1.4 Multi-Frame Rate Channel (MFRC) .........................46
26.1.5 Fragment Indication (FI) ................................46
26.1.6 Payload CRC .............................................47
26.1.7 Tail-end Padding (TEP) ..................................48
26.1.8 Reserved bits ...........................................48
26.1.9 Time-to-Live (TTL) ......................................48
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26.1.10Header Length (HLEN) ....................................48
27. Data Transport Operations ...................................49
27.1 Transmit Operation .........................................50
27.2 Receive Operation ..........................................51
28. End-to-end OAM Support ......................................51
29. ATM cell transport ..........................................52
29.1 Single Cell ................................................52
29.2 Multiple ATM Cells .........................................52
29.3 ATM over Frame Relay .......................................53
30. Instant Bandwidth Allocation with Statistical Multiplexing ..54
30.1 Dynamic Bandwidth Region (DBR) Allocation at Nodes .........56
30.2 Example of a Multiservice Transport Network ................57
30.3 Data Transmission at a Sending Node ........................59
30.4 Processing at an Intermediate Node .........................60
30.5 Processing at a Destination Node ...........................60
31. Segmented Dynamic Bandwidth Allocation ......................60
32. Fragmentation of Packets ....................................61
33. Tail-end Padding ............................................63
34. Multi-Frame Rate Channels ...................................63
35. Bandwidth Reuse on SONET ....................................64
36. Fault-resilient Packet Networks with Recovery and Restoration65
37. Security Considerations .....................................68
38. Acknowledgments .............................................68
39. Intellectual Property Considerations ........................68
40. Author's Address ............................................68
41. Full Copyright Statement ....................................68
42. References ..................................................69
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4. Glossary
DBR Dynamic Bandwidth Region. A set of bytes allocated to a
SONET node in which the node can send fixed-bandwidth
data.
DoF Direct Data-over-Fiber networks, e.g., over WDM or dark
fiber. Data is sent directly over fiber with no SONET/SDH
synchronous framing. Packets are delineated using
standard frame delineation such as HDLC, SDL, or ATM HEC.
Frame A frame in this draft refers to a user packet that has
been given frame delineation either using HDLC (0x7E) or
SDL (length/CRC construct) before transmission on SONET
or WDM.
HDT Hybrid Data Transport protocol
LSP Label Switched Path
LSR Label Switch Router
NBMA Non-Broadcast Multiple Access network
O-E-O Optical-Electrical-Optical conversion at an intermediate
node.
Packet A packet in this document refers to a user payload or a
user payload encapsulated with HDT header and/or MPLS
labels
POS Packet-over-SONET
PDH Plesiochronous Digital Hierarchy (such as T1/T3/E1/E3)
SDL Simple Data Link (rfc2823). A frame delineation technique
that uses length of the frame and CRC value on the length
value to form a 32-bit construct. This 32-
bit construct precedes every packet.
SPE Synchronous Payload Envelope (for SONET)
VT Virtual Tributary
5. Assumptions & Nomenclature
Throughout this document SONET is used to refer to SONET/SDH, with
similar implications for SDH. Protocol architecture and operation are
same for both SONET and SDH transport mechanisms.
All references to T1/T3 have similar implications for E1/E3.
Similarly, IP has been used to refer to any generic variable-length
packet-oriented data.
Fixed-bandwidth channels have been referred to as TDM channels,
although all fixed-bandwidth channels are not necessarily used in TDM
fashion. All discussions relating to PDH or T1/T3 apply to E1/E3 as
well.
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Since packet structure for Hybrid Data Transport protocol does not
change across SONET/SDH and direct data-over-fiber networks, all
packet descriptions for SONET also apply to data-over-fiber networks,
unless stated otherwise.
A detailed discussion of SDL (Simple Data Link) is not provided here.
Please refer to reference readings [6] for details on this protocol.
HDT works in a unified manner over any NBMA network configuration
such as optical networks (both SONET and DoF) and DSL. Since the
framing is consistent across these media, an HDT frame could travel
from an LSR at CPE end to go over DSL lines to an access multiplexer
to optical networks, providing an end-to-end MPLS-based protocols
transport.
This draft uses optical networks for all protocol discussions.
6. Organization of this Draft
This draft first presents a brief overview of current methods and
issues in multiservice transport over SONET networks.
This is followed by a detailed description of protocol framing
structure and operational examples for different networking
configurations.
Due to a greater complexity for multiprotocol transport in SONET
networks this draft initially uses SONET to illustrate protocol
functionality. Protocol operation and packet formats, however, do not
change over SONET and direct Data over Fiber (DoF) networks. Hence
all discussions apply equally for both types of networks.
7. Objectives for Multiservice Transport over Optical Networks
As more and more packet data is being sent over SONET and direct
data-over-fiber (DoF) optical networks a need has emerged for a
unified way of sending all types of traffic over any mix of short and
long haul optical networks.
Desired features of such a protocol are, but not limited to:
o Unified transport over any optical network configuration mix for
any type of data.
o Ability to transport multiple data types over a fiber (or a
wavelength).
o Support for native packet transport over any mix of optical
networks
o Use of a single control plane for link setup and transport of
different types of data
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o Sharing of a single MPLS LSP by multiple data types.
o Consistent protocol routing as a packet travels across any mix of
SONET and non-SONET networks.
o Instant bandwidth reservation for any type of data on a packet-
by-packet basis at any node with a low granularity (preferably
64kbps).
o Data-independent support for MPLS based switching so intermediate
nodes can switch and add/drop packets with only MPLS label-
switching logic and minimal additional support.
o Ability to use MPLS (or native protocol) based protection
switching and fault-restoration for all types of data.
o Add/drop operation for any type of packet at any node in an
optical network.
o Robust frame delineation over optical networks for any data type
and packet size.
8. Conventional Approaches for Multiservice Transport
Constraints in optical networking for packet data transport have made
development of packet data transport protocols quite challenging.
Until recently, SONET has been a primary form of optical networking,
due to prevalence of TDM-style transport that was required for PDH
(Plesiochronous Digital Hierarchy) channels such as T1/T3. With more
packet (and ATM) data being sent over these networks new
architectures needed to be developed.
One of the primary considerations when sending packets over SONET is
to be able to provide continued support for TDM-style channels such
as PDH (T1/T3). Despite growing popularity of packet transport, TDM
support must remain for the foreseeable future. This restriction has
been a driving force in many techniques for preserving TDM-style
partitioning of the SONET payload area.
Regardless of SONET line speed, each byte in the SONET payload
represents 64kbps (DS0) of bandwidth, since (irrespective of number
of bytes in a payload) each byte inside the payload repeats every 125
microseconds. To provide TDM channels, a SONET payload is divided
into many fixed-size slots called virtual tributaries (VT). Bandwidth
of a VT is NxDS0, where N is the number of bytes in each VT. Location
of each VT inside the payload is fixed, with each VT repeating every
125 microseconds.
The size of an individual VT (and consequently its bandwidth) is
significantly smaller than what is required by typical packet
transport standards (such as 10Mbps LAN or higher). Special methods
are needed to carry high-bandwidth LAN traffic over these low-
bandwidth VTs.
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Sending packet data over SONET involves two steps - allocating
bandwidth on SONET for sending high-bandwidth packet data, and
choosing an efficient transport protocol.
8.1 Bandwidth Allocation on SONET for Data Transport
Different methods of multiservice transport over SONET use techniques
that fall in one of these two broad categories:
o Use one or more VT (virtual tributary) channels of SONET for data
traffic, while remaining VTs continue to transport PDH (such as
T1/T3) channels. Special methods are often used to combine the
low-speed VTs to allocate higher bandwidth required for IP or ATM
traffic.
o Abandon support for T1/T3 altogether and use the entire SONET
payload for sending IP or ATM cells. Support for PDH is provided
through emulation techniques over IP or ATM.
+-+-+-----+-----+---+-----+-----+ +-+-+-----+-----+---+-----+-----+
| | | | | | | | | | | | | | | |
|T|P| | |<--GbE-------->| |T|P| | |<--GbE-------->|
|O|O| | | | | | |O|O| | | | | |
|H|H| STS | STS |...| STS | STS | |H|H| STS | STS |...| STS | STS |
| | | 1 | 1 | | 1 | 1 | | | | 1 | 1 | | 1 | 1 |
| | | | | | | | | | | | | | | |
| | |<---ATM--->| | | | | | |<---ATM--->| | | |
+-+-+-----+-----+---+-----+-----+ +-+-+-----+-----+---+-----+-----+
|<------ 125uSec Duration ------->|
Figure 1: Combining lower-rate channels for high bandwidth transport
These fixed-bandwidth circuits are provisioned for the entire
session. Because of the way these are provisioned scalability of
SONET networks is extremely limited, in addition to an inefficient
use of SONET bandwidth. A session stays provisioned even when there
is no data to send on the channel.
The only way to reuse the channel is to re-provision it. For
instance, if multiple STS-1s or STS-3s are combined (using inverse
multiplexing or virtual concatenation) for sending gigabit Ethernet
then those channels are dedicated for the purpose; no other data can
be transmitted on the channels.
8.1.1 Virtual concatenation
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In this method some VTs are used to transport data such as ATM and IP
while others continue to carry usual PDH traffic. Since individual
VTs have limited bandwidth (due to the small number of bytes in each
VT), additional steps must be taken to send high bandwidth packet
data.
Virtual concatenation [8] combines several VT channels into a larger
virtual pipe to carry higher bandwidth traffic. This technique allows
creation of multiple, independent pipes that can carry different
types of traffic with different bandwidth requirements.
However, virtual concatenation allocates a fixed-bandwidth for packet
traffic, and it cannot dynamically adjust bandwidth usage on a
packet-by-packet basis. While it is possible to change the
concatenated bandwidth through software in a reasonably short time,
the bandwidth utilization is poor because bandwidth requirement of
network changes on a packet-to-packet basis.
Another problem with virtual concatenation is that while one virtual
pipe may be overloaded with traffic, others may be underutilized; and
virtual concatenation cannot dynamically adjust network loads on
different channels.
8.1.2 Inverse Multiplexing
In this method, data from a high bandwidth data source (such as a
10Mbps Ethernet LAN) is sent over multiple low bandwidth tributaries
(such as VT1.5) using inverse multiplexing protocols. At the
receiving end the high bandwidth data is later recovered by
recombining packets from the low bandwidth streams.
8.1.3 Disadvantages of VT-based Packet Transports
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ATM
^
|
+-+-+
+------>| S |------+
| +-----| 6 |<---+ |
| | +---+ | |
| v | v
+---+ +---+
Gigabit Ethernet ----+ S | | S +--> ATM
OC-12----+ 1 | | 5 +--> T1
+---+ +---+
^ | SONET ^ |
| v | v
+---+ OC-192 +---+
T1 ----+ S | | S +--> OC-12
Frame Relay ----+ 2 | | 4 +--> Gigabit Ethernet
+---+ +---+
^ | +---+ | |
| +---->| S |----+ |
+-------| 3 |<-----+
+-+-+
|
|
v
Frame Relay
Figure 2: Multiservice Transport Network
Consider a SONET network in Figure 2 providing a multiservice packet
transport along with TDM channels. In addition to terminating an OC-
12 traffic, this OC-192 ring connects gigabit Ethernet, frame relay,
T1, and ATM networks.
To achieve this type of multiservice transport traditional approaches
allocate permanently (or semi-permanently - with configurable
bandwidth under software control) separate circuits for carrying OC-
12, gigabit Ethernet, T1, and ATM traffic. Higher bandwidth transport
capacity is achieved by inverse multiplexing high bandwidth data over
many STS-1 channels, or by virtually concatenating various STS-1
channels [8].
Virtual tributaries are of a fixed-bandwidth, and their use as a
single entity or as a group creates fixed-bandwidth (higher)
channels.
Packet-based traffic such as LAN is bursty in nature, and bandwidth
usage changes drastically on a packet-by-packet basis. Average
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bandwidth usage is typically quite low; resulting in significant
waste when used over a fixed-bandwidth pipe. Whenever fixed-bandwidth
channels are provisioned for transporting data packets the fiber
capacity is poorly utilized. Statistically it has been observed that
average use on a 10Mbps Ethernet link, for example, is only about 20%
[9].
With inverse multiplexing or virtual concatenation, when 7 VT1.5
virtual tributaries (each VT1.5 is 1.5Mbps) are used to create a
high-bandwidth pipe to carry 10Mbps traffic, only about 20% of this
capacity is used on an average, and the remaining capacity of this
pipe is unused most of the time.
When virtual concatenation or inverse multiplexing is not used an
entire STS-1 (51.84Mbps) channel needs to be allocated for
transporting 10Mbps traffic. When an entire STS-1 is used the
bandwidth efficiency goes down to about 4%, with the remaining 96% of
the STS-1 channel capacity remaining largely unused for anything
else.
This problem of inefficiency was not of much concern when only PDH
was transported since these PDH channels were used for leased lines
and telephony applications. In this case, network capacity was
increased as leased lines and telephony circuits increased. Because
the number of these leased lines and telephony circuits wouldn't
usually go down with time, network capacity would be always fully
utilized.
As more packet data is being transported on these SONET links more
T1/T3 channels are being replaced. Because packet data bandwidth
usage is low, a large portion of fiber capacity is inefficiently
utilized.
It is important to devise a protocol to take advantage of the bursty
nature of packet data traffic and use the remaining fiber bandwidth
for other applications or to add extra packet data traffic so the
fiber is completely utilized.
8.1.4 Using entire SONET SPE for Packet Data
Another way to use SONET for packet transport removes support of PDH
(T1/T3) and uses the entire SONET payload for transporting data
packets. No virtual tributaries (VT) are configured and the entire
SPE (Synchronous Payload Envelope) is used for sending data such as
IP and ATM.
When ATM cells are sent, PDH (such as T1) support can be provided by
ATM CES (Circuit Emulation Service) protocol. Techniques to support
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PDH using IP are still evolving; these methods are tricky because IP
packets vary in size from packet to packet and timing consistencies
are hard to meet.
Identification of the type of data sent inside the SONET SPE is done
in following ways:
o A parameter inside the Path Over-Head (POH) bytes (contained in
byte C2) called the Path Signal Label (PSL) has a byte-wide value
to denote the type of data being transported (such as POS or
ATM).
o With numerous new protocols for SONET evolving it is not possible
to outline values in the PSL byte. An administrative
configuration is used between nodes to establish the type of data
being sent in the path section.
Bandwidth usage limitations using this method are same as that of the
VT approach for bandwidth allocation. Use of a fixed-bandwidth,
either through VTs or the entire SONET SPE, always results in very
low average bandwidth utilization when used for bursty packet data
transport.
8.1.5 Bandwidth Considerations for Data over Fiber Networks
For direct Data-over-Fiber (DoF) networks packets are sent using
individual frame delineation without an encapsulating synchronous
frame (such as that provided by SONET). With no timing or framing
restrictions, each data packet (whether IP packet, ATM cells, or any
other data type) is transmitted on its own with its own delineation.
There are no bandwidth management requirements per se, allowing the
fiber (or a wavelength) to be used to the capacity and limits of
transmitting and receiving nodes.
8.2 Traditional Data Transport Protocols
Once bandwidth has been allocated in the SONET SPE, different types
of data can be sent on the different bandwidth channels. When virtual
tributaries are configured (with or without virtual concatenation)
individual VT channels can be used for sending different types of
data. While one or more VTs are transmitting PDH, others could be
sending ATM cells, while the remaining could be sending IP traffic,
and so on.
8.2.1 Packet-Over-SONET (POS)
Packet data such as IP packets (or other protocol types) is
encapsulated using Packet-over-SONET (POS) protocol (rfc2615) [3] and
delimited by HDLC framing. Many packets can be put inside a single
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SONET SPE. Packet transport using POS only supports packet protocols
such as IP and cannot support T1/T3 or ATM cells.
Network connectivity and operation for POS is provided by PPP (Point-
to-Point Protocol). On SONET networks, connections between end points
are provisioned and administratively established for a point-to-point
interface. All traffic originating from station A on a provisioned
link will terminate on station B at the other end of the link.
Inherent limitations of PPP make link and bandwidth management on
SONET and DoF networks impossible. PPP cannot adjust link usage based
on bandwidth requirements and actual traffic patterns. Consequently,
while one VT may be overloaded with traffic others may be
underutilized.
With POS, a SONET network looks like a group of point-to-point links
that are permanently configured with each link no relationship to
another for traffic sharing and bandwidth management.
8.2.2 ATM VP Multiplexing
Another way to fully utilize SONET bandwidth is to fill the payload
area with ATM cells using a technique known as ATM VP (Virtual Path)
multiplexing [9]. All types of data are encoded in ATM cells and then
put inside the SONET SPE. Protocol characteristics of ATM are used
for providing different types of services. For example, T1 is
provisioned using ATM Circuit Emulation Service (CES). Similarly, IP
and other protocols are transmitted using multiprotocol encapsulation
over ATM [4]. Frame relay is transported using FR-ATM interworking
protocols, and so on.
Small fixed-size ATM cells also work efficiently with cross-connect
or add/drop multiplexer devices to switch traffic to different
destinations. Using ATM cells is an ideal way to route any type of
service to any network. This is possible because once protocols are
converted to ATM, all cells are of the same size and structure, and
optical nodes can easily route them based on their VPI/VCI without
having to look at the payload.
However, there are many limitations in using ATM based multiplexing
for multiservice transport over optical networks. Some of these are
as follows:
o Methods for OAM (Operations, Administration, and Maintenance) of
ATM networks are different from that of SONET networks, and
management of the two becomes quite cumbersome.
o ATM network routing and switch-to-switch signaling data paths
differ from IP network routes, resulting in significant
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additional network operational complexity.
o It has been found [1] that a good percentage of network traffic
consists of IP packets with small packet sizes of around 40-44
bytes. With IP over ATM (rfc2684 - Multiprotocol Encapsulation
over ATM AAL5), payload size slightly exceeds what can fit inside
a single ATM cell. These result in transmission of two ATM cells,
with the second cell that has mostly ATM overhead and stuffing
bytes. This, with other ATM overhead, means having to allocate
extra SONET bandwidth for data transport.
o Using ATM for different services requires implementation of ATM
interworking for all related protocols (such as IP-over-ATM,
Frame Relay-ATM interworking, circuit emulation, etc.)
8.2.3 Ethernet-like Treatment of SONET
To improve on limitations of POS (such as fixed-bandwidth
provisioning, poor link management, etc.) many new protocols have
been proposed that treat a SONET network as a big shared Ethernet-
type network. Most of these protocols address nodes sharing the
network as Ethernet end-points by using MAC addresses for identifying
each other.
In traditional SONET networks a frame originating from a node must
travel completely around the ring until the sending node removes it,
resulting in a waste of bandwidth.
Ethernet-based approaches (an example of such a protocol is Spatial
Reuse Protocol (SRP) [7]) avoid bandwidth waste by allowing the
destination node to strip the packet based on a destination MAC
address match, thereby allowing other downstream nodes to reuse the
bandwidth freed up by the removed packet.
This transport of Ethernet-like data, however, only work with packet-
oriented protocols, and leave issues such as guaranteed bandwidth and
QoS to the network layer protocols such as IP. Also, as with POS, a
ring carrying these protocols cannot support PDH, real-time ATM
traffic, frame relay, PPP, etc.
SONET rings usually span a large area, and it would be greatly
inefficient if these rings can only connect Ethernet networks at end
points.
These protocols do away with TDM-style operations of SONET to support
requirements for newer packet-oriented data transport applications.
Nodes are addressed using MAC addresses, with Ethernet-like framing.
Packet transport achieves better bandwidth utilization because it
benefits from statistical multiplexing of bursty nature of packet
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data. In addition, destination nodes strip a packet from the ring,
allowing bandwidth reuse on downstream link.
In Ethernet-centric models, both control and data planes use
Ethernet-like framing and IP-based operations are commonly used for
sending all types of data. In addition to forcing IP for non-IP
protocols, it requires complex hardware and software for MAC address
lookup (for both slow and high-speed data paths), IP routing
protocols, and other IP-based operations that were developed for
traditional Ethernet networks.
Numerous limitations of this approach make it a poor choice for an
efficient, general-purpose data link layer for optical networks:
o Use of Ethernet-like framing imposes specific layer 2 technology
for all types of applications, resulting in complexity for non-
Ethernet traffic such as ATM, frame relay, PPP, and raw byte
streams.
o An IP-centric model (common with Ethernet-style framing) does not
blend well with transport of ATM, T1/T3, raw byte stream, lower
rate SONET, and other data streams. These technologies require
additional transport mechanisms over IP, and these services may
not be possible to support if the complexity involved in the IP-
based transport is high.
o End-to-end resource allocation and signaling, performed by IP,
does not work well with other protocols such as ATM or PDH. For
instance, ATM networks require PNNI for signaling, and network
routes and bandwidth allocations done by IP routing protocols and
RSVP may not match the network configuration demanded by ATM
networks.
o In a similar way, routing of TDM-style traffic may not be
possible by using IP techniques since providers of these services
would like to use their specific routes for provisioning.
o Development of MPLS does not help in multiservice transport using
this approach since MPLS is carried inside Ethernet-type L2
frames. Different types of services must still be carried inside
Ethernet-type frames. Even though an LSP is set up for
transporting a certain type of traffic, each node must first look
for an Ethernet MAC address match before looking for an MPLS
label match.
Over a long-haul optical network mix, transporting data from one end-
node to another requires an all-IP network operation. Multiservice
transport would require conversion at every network boundary and a
lot of interworking operations is required.
9. A Unified Data Link Layer for Optical Networks
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Data link layer-networking requirements for optical networks are
different from those of legacy networks such as Ethernet. In
Ethernet, a packet originating from a source node goes on a link
where many stations receive the packet at the same time. On Ethernet
networks, nodes use hardware with MAC-address lookup capability so
only those packets that are meant for the node are processed and
received. Other nodes get the packet at the same time but ignore it
once they look up the initial few bytes to check for MAC-address
match.
+===+
+---+ _+ W |
+------>| S |-----+ /-+ 3 |
----+ | +-----| 4 |<---+| / +=+=+
| Tx| | +---+ || / |
----+ +---+ | | Rx || / |
| | |==+ Rx +---+ +---+ Rx +===+ +=+=+
----+ | A |W +=====+ S | | S +=====+ W |---+ W |
+--+ +1 +=====+ 1 | SONET/SDH | 3 +=====+ 2 | | 4 |
LAN | | |==+ Tx +---+ +---+ Tx +===+ +=+=+
----+ +---+ ^ |Tx +---+ || \ |
| Rx| +---->| S |----+| \ |
----+ +-------| 2 |<----+ \ +=+=+
+ --+ \--+ W |
+ 5 |
+===+
Figure 3: Data Link Operation for Optical Networks and LANs
On an Ethernet network, therefore, it is essential to have a
consistent data link layer mechanism based on MAC addresses. The
purpose of a MAC address is to have one particular node out of many
that get the packet on the network.
The situation is quite different in the case of optical networks. An
optical link terminates at a single node, and the node examines the
packets to determine their destination(s). Unlike OXC (Optical Cross-
Connects) nodes, where an entire optical link is switched without
looking inside the packets, normal optical switching nodes perform an
O-E-O operation for switching packets onto optical links.
Packets are delivered to a node through an optical link. These are
converted into electrical signals and analyzed (after appropriate
frame extraction, such as for SONET networks) and are then switched
to the appropriate output port where the packets are converted back
to optics. In Figure 2, for example, all packets coming from SONET to
W2 must be examined electrically before deciding which of the
downstream nodes (W3, W4, or W5) is the recipient. The same is true
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of all the optical nodes in this network. On the LAN side, the
situation is different, where all nodes receive packets at the same
time.
This node-to-node data transport is true also for SONET rings where
packets are delivered to the receive port of a node and then are sent
out on the appropriate transmit port.
Since packets travel from node-to-node and not to many nodes at one
time, data link requirements can be simplified for the case of
optical networks.
With these characteristics in mind it is possible to design a unified
data link layer for optical networks. With a small core header for
parameters necessary for NBMA networks it is possible to use existing
data link layer and protocol technologies and provide a true
multiservice transport for all types of optical networks.
Being able to support all legacy protocols and data formats over
optical networks is quite attractive, since it preserves all native
data traffic over short and long haul optical networks.
9.1 Data Link Header for Control Packets
MAC addresses are used for sending control packets and for node
addressing. This is to allow use of IP-based control protocols for
node adjacency discovery, route selections, MPLS label assignment and
distribution, and any other signaling operations. MAC addresses are
also present in initial packets for a session.
Since control packets are infrequent there is no need for extensive
hardware for MAC address lookups. One can process the control packets
and initial packets with simple hardware and software solutions.
9.2 Data Link Layer for Data Packets
Once an LSP has been set up and labels have been assigned for a flow,
there isn't a need for using MAC addresses for sending data packets
on optical networks.
On optical networks, once MPLS label(s) have been set up for an LSP,
the MPLS labels themselves can serve as data link layer addresses, as
labels have per-interface uniqueness between two nodes.
For normal data (with no MPLS set up as yet), usual data link
addressing would work just fine. All that is needed is a consistent
way of transporting MPLS labels as data link header so receiving
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nodes can tell whether they should process MPLS labels or the native
packet data link header for processing.
Once this is done, MPLS labels becomes addressing mechanism for high-
speed data switching (regardless of payload), and a lot of operations
can be easily done on networks:
o Optical network links can be treated as label switched paths
regardless of type of data
o Multiple data types can be sent on an LSP
o Segments of network can be LSPs, and protection mechanisms using
MPLS can easily be applied for all types of data
o Existing nodes with native packets can all participate in the
networking, without being forced to adapt to Ethernet-style
framing as some protocols would require them to do
o Fault recovery and restoration can be done for all data types
o Backup links can be used as alternative LSPs, and these backup
links can be used for data traffic to maximize network resources.
10. Hybrid Data Transport
The draft proposes a data transport method, called Hybrid Data
Transport (HDT) protocol, which provides a unified multiservice data-
transport mechanism for optical networks. Using HDT, an optical
network can be used to its full capacity with dynamic bandwidth
management on a packet-by-packet basis.
HDT supports end-to-end native data transmission of any type (such as
Ethernet, IP, ATM, PDH, raw data, etc.), spatial reuse of bandwidth,
instant bandwidth allocation (with 64kbps granularity), and seamless
operation over point-to-point and ring networks with any mix of SONET
or direct data-over-fiber (DoF) networks.
Multiple types of data (such as IP, Ethernet, PPP, frame relay, ATM,
even raw byte stream can be sent over a single fiber link (such as
using WDM) or inside a SONET SPE.
In Figure 4 below, multiple networks are connected using a SONET
ring. Nodes on the ring can terminate packets and cells using data
link information contained in layer 2. A gigabit Ethernet packet
entering at S-1 is received at S-4 when a destination MAC address
match is found.
Intermediate nodes S-2 and S-3 need not have any interfaces with
gigabit Ethernet support. These nodes detect an Ethernet frame and
pass the frame on. Before forwarding the packet, these and other
intermediate nodes decrement a TTL (Time-to-Live) value in the frame
header.
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ATM (VPI/VCI)
^
|
+-+-+
+------>| S |-----+
|+------| 6 |<---+|
|| +--++ ||
|| | ||
(MPLS or MAC) +---+ VPI/VCI +---+
Gigabit Ethernet ----+ S |\/-----+----| S +--> ATM (VPI/VCI)
(VPI/VCI) ATM ----+ 1 |/\ -------| 5 +--> T1 (MPLS)
+---+ \ / +---+
|| \ ||
|| / \MAC ||
+---+ / \ +---+
(MPLS) T1 ----+ S |/ \ | S +--> ATM (VPI/VCI)
Frame Relay ----+ 2 |\ DLCI \----| 4 +--> Gb Ethernet
(DLCI) +---+ \---\ +---+ (MAC or MPLS)
^| +-\-+ ||
|+----->| S |----+|
+-------| 3 |<----+
+-+-+
|(DLCI)
|
v
Frame Relay
Figure 4: Multiple Native Data Link Layer Support on a Fiber
When the frame reaches S-4, the node detects that the frame contains
an Ethernet packet. Destination MAC address is compared for a match
and the frame is taken off the ring.
At the same time that a gigabit Ethernet frame is traveling inside a
SONET SPE - ATM cells, frame relay, T1/T3, lower-rate SONET, or any
other data stream could also travel within the same SPE and reach
their destination node.
In a ring configuration, packets can be destination-stripped to
achieve bandwidth reuse. The packet stripping at a destination node
can be done on the basis of data link layer information contained
within the native packet, if available. Examples of such link layer
parameters are - Ethernet MAC address, ATM VPI/VCI, frame relay DLCI,
an MPLS label stack as a shim header, etc.
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If no nodes receive the frame, the TTL counter inside the frame
eventually expires and the frame is taken off the ring (or a point-
to-point fiber).
On ring networks frames can be source-stripped instead of waiting for
a TTL count expiration for frames that contain packets in which
sending node address can be identified (such as for Ethernet). The
sending node gets the frame back when no other node has received and
taken the frame off the ring. It then compares source MAC address to
its own address, and if a match is found it takes the frame off the
ring.
Multiservice operation on data-over-fiber networks is similar to that
of a SONET ring. Multiple frames containing different types of
packets can travel on the same fiber (or wavelength) to maximize
available bandwidth on the link. Intermediate nodes can switch these
frames based on the protocol(s) supported.
With the OPTIONAL support for MPLS within the data transport frame
structure (external to the native data packet), it is possible to
provide multiservice transport with a unified MPLS switching.
This OPTIONAL support for MPLS works independently of and/or in
conjunction with traditional MPLS shim headers.
+-+-+
| | +----------+
/----+ C + | Ethernet |
/ | | +----------+
+---------+ +-----------+ 2 / +---+
| Ethernet| | ATM cells | /
+---------+ +-----------+ /
+--++ +-+-+ / +-+-+
------->| | 1 | | / 3 | | +------------+
------->| A +--------+ B +------------+ D + |Frame Relay |
------->| | | | \ | | +------------+
+---+ +---+ \ +---+
MPLS \ 4
+------------+ Switching \
|Frame Relay | \
+------------+ \ +-+-+
\ | | +-----------+
\- -+ E + | ATM cells |
| | +-----------+
+---+
Figure 5: Multiservice Transport with Unified MPLS switching
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This MPLS support is payload-independent in frame structure and data
transport characteristics. This results in a unified architecture for
all payload types for fault resilience, bandwidth sharing, and
control and data plane support for optical networks.
For a payload that does not have any specific data link layer - such
as TDM, raw byte stream, SONET/SDH, MPLS can be used for routing the
data across optical networks.
Subsequent sections in this draft document the framing structure,
types of WAN configurations that can support this transport protocol,
and a detailed functional description of each feature.
11. Motivations for HDT
o HDT is being proposed as a common payload transport mechanism for
all types of optical networks that work with or without MPLS
support.
o One motivation for this protocol is to design general-purpose
MPLS-based optical switches and wavelength switching devices that
work on MPLS label alone, without having to worry about all the
legacy end-node protocols such as Ethernet, frame relay, ATM,
PPP, AppleTalk, SONET/SDH, and even raw data stream.
o Continued support for SONET/SDH and PDH for all networks. Many
newer protocols are gravitating towards Ethernet-based models and
they would no longer support any other type of data. HDT is
designed to work with all types of packets.
o Instant bandwidth allocations anywhere in a SONET network with
smallest possible granularity of 64kbps (DS0).
o A consistent and unified control plane for setting up light paths
with traffic engineering parameters for sending all types of
data.
o Support for alternative LSP setups that can carry all types of
critical data on backup links, instead of individual LSPs for
different protocols.
o Common LSPs for traffic-engineered links for different protocols
leading to fewer refreshes in RSVP-TE at each node.
12. Advantages of HDT
o A unified transport with the same size and structure regardless
of the type of data inside the payload area.
o All existing data link layer technologies can be used without any
modifications.
o Frame structure is unchanged as the frame travels from a point-
to-point network to a ring network, across any mix of SONET and
non-SONET framing.
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o A single fiber link can be used for sending different kinds of
traffic to the full capacity of the link.
o There is no need to set up VT or sub-VT channels in advance. ATM
cells, IP (and other protocols) packets, PPP, frame relay, NxDS0,
T1/T3 and others can be mixed inside the SPE on a packet-by-
packet basis.
o PDH channels such as T1/E1 can be dynamically allocated anywhere
inside the SONET payload in 64kbps bandwidth increments.
Bandwidth can be reserved with 64Kbps granularity for any data
type on a packet-by-packet basis.
o All types of network protocols can use a SONET SPE or a WDM link.
HDT can take many packets of one or different data types and put
them inside a single SONET SPE or data-over-fiber frame while
preserving the time dependency of data packets such as PDH on a
dynamic basis.
o It is not necessary to terminate the whole payload capacity at
each node.
o Any type of packet can be dropped at a node and a similar or a
different type of traffic can be added to the SONET payload. For
instance, an IP packet can be dropped at a node and the node can
reuse the packet area for inserting ATM cells, frame relay, PDH
traffic, or even a raw bit stream. The new packet can use the
packet area instantaneously for a fixed-bandwidth allocation
(bandwidth equal to NxDS0, where N is the number of bytes in the
payload space) regardless of the type of packet.
o Direct data-over-fiber networks can be easily supported without
HDT frame structure changes, with full link monitoring and fault
management.
o Protocol-independent support for MPLS labels. Optical nodes can
switch and add/drop packets with only MPLS label-switching logic
and some extra hardware for initial packets. The nodes do not
need to implement high-speed protocol parsers just to get to the
MPLS labels.
o Any node (or set of nodes) on the SONET network can use variable
portions of SONET payload for creating fixed-bandwidth channels
for any type of data. Other nodes on the network beyond this set
of nodes can use same sections of the SONET payload for other
packets with best-effort packet data delivery.
13. HDT Frame Structure Overview
A payload is encapsulated with a header that provides identification
of the packet and OPTIONALLY may contain MPLS labels and/or OAM
bytes.
A detailed view of the frame structure is shown below. Detailed bit
descriptions are given later in this draft in [26].
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+===============+-----------------------------------------+ (bytes)
| | Core Header (cHdr) (32 bits) | 4
| +-----------------------------------------+
| |(Optional) Next Fragment offset (32 bits)| 4
| Payload +-----------------------------------------+
| Header (PH) |(Optional) MPLS/OAM bytes (N x 32 bits) | N
| +-----------------------------------------+
| | Core Header CRC cHEC (CRC-16) | 2
+===============+-----------------------------------------+
| | |
| User Payload ~~~ ~~~
| Data | Payload data |
| ~~~ ~~~
| | |
| +-----------------------------------------+
| |(Optional) Payload CRC (CRC-32 bits) | 4
+===============+-----------------------------------------+
Figure 6: HDT Frame Structure with Native Payload Transport
The frame structure shown in Figure 6 is uniform for all types of
payload data.
Core encapsulation consists of a 32-bit header (cHdr) and a 16-bit
CRC-16 (cHEC) on the cHdr bytes. The header structure is uniform
across all packet types and optical networks (both SONET and DoF).
13.1 Payload Header (PH) Structure
13.1.1 Core Header (cHdr)
+=====+------+-----------------+------+
|cHdr | cHEC | ....Payload.... | pCRC |
+=====+------+-----------------+------+
4 2 4 (bytes)
The core header precedes every packet (with the OPTIONAL exception of
single ATM cell transport when using SDL frame delineation; described
later) and carries all information required for payload
identification, bandwidth management, and switching of packets across
any mix of optical networks.
The minimum length of a core header is 6 bytes.
13.1.2 Next Fragment Offset
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It is possible to instantly provision bandwidth for any data type at
any point in a SONET ring using HDT. As described later in this
draft, when a packet occupies a fixed location within a SONET SPE,
another newly added packet may need to be fragmented to go around the
fixed packet(s) to use any free space in provisioned area in the SPE.
When this fragmentation happens, HDT header contains a 32-bit offset
to mark the beginning of next fragment.
+-----+=================+----------+------+-----------+------+
|cHdr | Fragment offset | ..MPLS.. | cHEC |..Payload..| pCRC |
+-----+=================+----------+------+-----------+------+
4 4 Nx4 2 4 (bytes)
(OPTIONAL) (OPTIONAL)
This offset is taken from the start of current packet (or packet
fragment). A 32-bit offset is required to be able to locate fragments
that could be farther than 65,536 bytes apart in a SONET SPE (for OC-
192 and above).
13.1.3 Header with MPLS labels
+-----+==========+------+-----------------+------+
|cHdr | ..MPLS.. | cHEC | ....Payload.... | pCRC |
+-----+==========+------+-----------------+------+
4 Nx4 2 4 (bytes)
(OPTIONAL)
Bits inside cHdr indicate presence of MPLS labels and any other
optional parameters.
While native payload data such as Ethernet, ATM, PPP, and frame relay
can continue to carry MPLS as a shim header, MPLS labels MAY be
independently and simultaneously stacked between cHdr and cHEC
fields. These labels can be the same ones that would otherwise have
been put inside the shim header, or these labels could belong to an
intervening VPN or a service provider network.
Instead of building specialized data link layer logic and then
applying MPLS labels for switching packets, intermediate nodes can
switch packets in high-speed data path by just using MPLS labels.
Once MPLS labels have been configured for a path using RSVP-TE, CR-
LDP, or generalized MPLS signaling [9], multiple packet types can be
sent using same the MPLS label, if so desired for bandwidth sharing.
Because MPLS label switching is done _outside_ the payload (rather
than by inserting the MPLS label stack between the data link and the
network layer), traditional data link layer limitations do not apply
(and need not apply, as described later) to optical nodes.
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From an ATM network, ATM cells (as one cell or a collection of cells)
can be switched and sent over non-ATM networks over traffic-
engineered MPLS links to another ATM network.
Similarly, native Ethernet packets from one local area network can be
MPLS-switched across any mix of optical networks to another local
area network without any modification to the original packet.
Because MPLS labels can be used for packet switching regardless of
the type of packet, efficient and economical optical fiber protection
schemes based on MPLS [5] can be utilized for efficient protection
switching. Since there is no dependence of these labels on the type
of packet, all data can be switched on the protection fiber. Traffic
from some sources (containing any type of packet such as ATM,
Ethernet, multimedia stream, PDH, etc.) can be prioritized by putting
these on labels that are switched on high speed links while other
flows are switched on low speed links.
13.1.4 Header with OAM bytes
+-----+========+------+-----------------+------+
|cHdr | ..OAM..| cHEC | ....Payload.... | pCRC |
+-----+========+------+-----------------+------+
4 M 2 4 (bytes)
(OPTIONAL)
On data-over-fiber networks (such as WDM) OAM bytes can be sent in-
band with payload data. These bytes MAY be sent between the cHdr and
cHEC fields. The OAM bytes need not accompany every payload but are
inserted only when required. The frequency of inclusion of these
network OAM bytes for administration and health monitoring is
typically quite low compared to packet transfer rate, especially at
high data rates.
13.1.5 MPLS labels followed by OAM bytes
+-----+==========+==========+------+-----------------+------+
|cHdr | ..MPLS.. | ..OAM.. | cHEC | ....Payload.... | pCRC |
+-----+==========+==========+------+-----------------+------+
4 Nx4 M 2 4 (bytes)
(OPTIONAL)
It is also possible to provide for transport of MPLS labels followed
by OAM bytes. Using this method, in-band OAM information can be sent
on a specific LSP. In addition to normal in-band OAM operations, out-
of-band OAM can be performed using a route involving a different
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fiber (or a wavelength) or a low bandwidth LSP while high-speed data
travels on high-bandwidth links.
End of MPLS labels (and beginning of OAM bytes) is determined by end-
of-stack bit in the bottom label.
13.1.6 Core Header HEC (cHEC)
+-----+----------+----------+======+-----------------+------+
|cHdr | ..MPLS.. | ..OAM.. | cHEC | ....Payload.... | pCRC |
+-----+----------+----------+======+-----------------+------+
4 Nx4 M 2 4 (bytes)
(OPTIONAL)
Core Header HEC is a CRC-16 (2 bytes) computed over all 4 bytes of
cHdr, and any MPLS and OAM bytes.
13.2 User Payload
User payload area immediately follows the cHEC field in HDT payload
header (PH).
13.2.1 Payload
The payload can contain any data type from end-nodes or core
networks.
The user payload data MAY be followed by payload CRC. Indication of
whether a CRC field is present after payload is contained in the cHdr
fields.
A few sample types are as follows:
o Ethernet & IEEE802.3, with or without MPLS shim header
o ATM cell(s)
o PPP, Frame Relay, with or without MPLS shim header
o MAN networking and newer data transport protocols over SONET such
as SRP [7] and other variants
o SONET/SDH
o T1/T3
o Raw byte stream
13.2.2 Payload CRC (pCRC)
If a CRC field is present it MUST be based on standard ITU-T CRC-32.
Presence or absence of pCRC is indicated in a cHdr field parameter.
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14. HDT Framing Examples
Frame structure for some common data types are as follows:
Native packet data:
+=====+======+-----------------------------+------+
|cHdr | cHEC | Ethernet/IP/PPP/Frame Relay | pFCS |
+=====+======+-----------------------------+------+
4 2 4
ATM Cells:
+=====+======+-----+-----+-----+-----+-----+-----+
|cHdr | cHEC | ATM | ATM | ATM | ATM | ATM | ATM |
+=====+======+-----+-----+-----+-----+-----+-----+
4 2 53 53 53 53 53 53
ATM Cells with external MPLS:
+=====+==========+======+-----+-----+-----+-----+
|cHdr | ..MPLS.. | cHEC | ATM | ATM | ATM | ATM |
+=====+==========+======+-----+-----+-----+-----+
4 N 2 53 53 53 53
Packet Data with external MPLS & OAM:
+=====+======+======+=====+--------------------------------+------+
|cHdr | MPLS |.OAM. |cHEC | Ethernet/Frame Relay/PPP, etc. | pFCS |
+=====+======+======+=====+--------------------------------+------+
4 N M 2 4
Ethernet with MPLS shim header, OAM, and external MPLS stack:
+=====+======+======+=====+----+-----------------+----------+------+
|cHdr | MPLS |.OAM. |cHEC | L2 |MPLS Shim Header | IP, etc. | pFCS |
+=====+======+======+=====+----+-----------------+----------+------+
4 N M 2 <--- Ethernet Frame with MPLS ----> 4
o ATM cells are transported in their entirety.
o Ethernet packets are sent natively, with or without MPLS shim
headers.
o The HDT MPLS stack is external to the actual payload for all
cases, and its use is OPTIONAL.
15. Transmission of HDT Frames
15.1 SONET Networks
HDT frames are transmitted in the payload area. Consequently, these
frames can be sent over an entire SPE in a concatenated mode, or over
virtual tributaries (with or without virtual concatenation). Each
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frame consists of a header and a payload (with the exception of a
single ATM cell, when used with SDL delineation).
15.1.1 Concatenated SONET
+---+---+------------------------------------------------+
| | | ++--------++-----------++----------++-------+ |
| T | P | || T1 || IP ||ATM cells || NxDS0 | |
| O | O | ++--------++-----------++++--------++-------+--+
| H | H | ||PPP ||IP (Fixed BW)|| Raw Data Stream |
| | | ++--------++--++---------++-----------++-------+
| | | || Ethernet || Low rate SONET/SDH || PPP |
| | | ++------------++-++-----------++------++-------+
| | | ||Frame Relay || Ethernet || ATM cells |
+---+---+-++---------------++-----------++---------------+
Figure 7: Multiple Data Types in a single SONET SPE
Frames are sent inside the SONET payload area, as shown above. Each
frame has a header as described earlier. Frames are allowed to cross
over SPE boundaries.
15.1.2 Non-concatenated - Inverse Multiplexing
With non-concatenated SONET, HDT frames can be sent over one or more
Virtual Tributaries (VT) or lower-rate SONET channels. While one or
more VTs (or channels) carry HDT frames, others can continue to carry
PDH, ATM, or POS (Packet-over-SONET) data as usual. End nodes as well
as intermediate SONET ADMs can add/drop channels without any changes.
To create higher data rates, frames can be sent over multiple
channels by using inverse multiplexing over the channels.
15.1.3 Virtual Concatenation over SONET
To create higher data rates, one or more lower-rate SONET channels
may be combined using virtual concatenation to create a high-
bandwidth pipe. This pipe can then be used for sending HDT frames,
while other channels continue to send other data. Virtual
concatenation only requires modification in SONET hardware at the two
end nodes, with full transparency to intermediate nodes.
15.2 Data-over-Fiber and WDM Networks
On Data-over-Fiber (DoF) links, HDT frames are transmitted just the
same way as they are done over SONET, except that there is no
encapsulating envelope for housing the frames.
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HDT frames can travel across a mix of SONET and DoF without any frame
modifications.
SDL framing mechanism uses length/CRC pair as a header and a frame
delimiter. Its robust CRC and frame locator technique makes it a good
candidate for direct data-over-fiber networks without SONET framing.
It is possible that over time, use of OAM packets will obviate the
need for complex SONET framing and link management overheads. In the
case of direct data-over-fiber networks the HDT protocol structure
will run unmodified over fiber.
Because HDT packet framing is the same for both SONET and non-SONET
networks, design of optical nodes in a long-haul network with a
hybrid of WDM point-to-point networks without SONET framing and a
complex interconnection of SONET rings.
16. Protocol Implementation Considerations
+--------------------+ +-----------------+
Legacy | | | | Legacy
System | ATM IP PPP T1 | | ATM IP PPP T1 | System
| \ | | / | | \ | | / |
+--------------------+ +-----------------+
\ | | / \ | | /
+----------+ +-----------+
| MPLS | | MPLS |
(Optional) | Switching| | Switching | (Optional)
+------+---+ +-----+-----+
| |
| |
+-------+------+ +-------+------+
| HDT Encaps | | HDT Encaps |
| (HDLC/SDL | | (HDLC/SDL |
| Framing) | | Framing) |
+-------+------+ +-------+------+
| |
+-+-+ \ / +-+-+
| | \/ | |
| A +===~~~~~~=====+ B |
| | /\ | |
+---+ / \ +---+
(Mix of SONET & DoF)
Figure 8: Multiservice Transport Network using HDT
A typical system network configuration is shown in Figure 8.
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Implementing HDT transport in systems require just one additional
logic added at their input and output ports for HDT encapsulation.
Since HDT allows MPLS label transport that is independent of layer-2
protocol, a generic MPLS switching logic can be used for switching
all types of data.
Use of SDL requires a hardware implementation for SDL delineation and
frame synchronization.
If HDLC is used for frame delineation existing hardware can be used
for generating and processing HDT packets.
Once a packet has been de-encapsulated, normal hardware and software
operations can be performed for processing native packets such as
Ethernet, ATM, frame relay, PPP, PDH, and any other byte stream.
17. Preserving Payload CRC for Robust Transmission
Using packets with traditional MPLS shim header structure to short
and long haul optical networks has serious implications in line error
detection and fault location.
When a MPLS shim header is used (between layer 2 and layer 3 fields),
the payload CRC (for the entire packet) needs to be re-computed at
every node where MPLS label add/drop/swap operation takes place.
Any data corruption problems (due to memory problems or any other
device failure) within the node before the packet is sent on output
port are permanently hidden as the packet travels downstream. Even if
a data corruption problem is detected, it is almost impossible to
find out which node caused the error.
As payload sizes are becoming larger (such as for jumbo frames, and
multiprotocol over frame relay and ATM where the payload size can be
about 9K), probability of errors due to node hardware errors while
bytes are being stored and sent out on the transmit port becomes
higher.
17.1 Payload Error Suppression with MPLS Shim Headers
Let us consider a case of MPLS shim header operation over an optical
network.
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+---+ +-+-+ +-+-+ +-+-+
| | 1 | | 2 | | 3 | |
------>| A +------+ B +---------+ C +----------+ D +---->
| | | | | | | |
+---+ +---+ +---+ +---+
+----+------------------+----------+------+
| L2 | MPLS Shim Header | IP, etc. | pFCS |
+----+------------------+----------+------+
<--- Ethernet Frame with MPLS --> 4
At node A:
o Payload enters A.
o Payload CRC is verified for correct frame.
o After MPLS label lookup, label add/drop/swap done
o Internal memory or device error causes packet data corruption
within A
o As node A sends the packet out (with new MPLS label), payload CRC
is re-computed after the last payload byte is sent.
At node B:
o Payload enters B.
o Payload CRC is verified for correct frame.
o The payload in error is received as a correct frame.
o MPLS label operations done
o Packet sent out with a re-computed CRC
o Errors are hidden for the node and all downstream nodes.
At downstream Nodes:
o C & D may never find out if there was an error, especially if the
byte errors happen within the payload data area and not the
network headers.
o Even if C, D, or other downstream nodes find out the error, they
cannot isolate the faulty node. This is because no node ever
found an error.
o If payload error occurs infrequently it may be even harder to
isolate the faulty node.
17.2 Fault Detection and Isolation with an External MPLS stack
An ideal solution is to check the CRC at input, but not to re-compute
the CRC on packet output. An efficient way to do this is to separate
header CRC from payload CRC. This way, header CRC is re-computed
easily and quickly at intermediate nodes while the payload CRC is
preserved end-to-end.
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+=====+======+======+=====+----+-------------------------+------+
|cHdr | .. MPLS .. |cHEC | L2 | IP, etc. | pFCS |
+=====+======+======+=====+----+----------+--------------+------+
4 N M 2 <-- Ethernet Frame with pFCS --------->
In HDT, MPLS labels are carried inside the payload header and the
payload header bytes have their own CRC for error checks.
As packets go from node to node, only the cHEC value changes when
MPLS labels are modified, leaving payload CRC (pFCS) value unchanged.
Whenever a node causes byte corruption in payload data, the
downstream node will immediately find the error and discard the
packet.
18. Data Transport over Optical Networks using HDT
18.1 Protocol-independent operation for MPLS
In current MPLS stack encoding methods [11] MPLS labels are carried
inside a packet, their existence known either by a unique protocol
identifier. For multiservice transport over optical nodes, however,
having to go deeper into the frame at intermediate nodes to get MPLS
tags requires that all nodes be protocol-aware for all types of
protocols. For instance, to learn of Ethernet MPLS shim headers, PPP
MPLS, etc., the node must know the packet protocol to find out
whether MPLS labels are present and how they are encoded inside.
While physical medium-dependent link layer protocols such as Ethernet
must have an Ethernet-style framing with embedded MPLS labels,
optical transport and switching nodes need not do so. Because MPLS
labels are used for switching packets at nodes and are not part of
the payload, having pure MPLS fields outside the payload simplifies
node design significantly. Using this technique it is possible to
design high-speed switching logic at nodes without having to
incorporate protocol-specific knowledge for packets. Notice that HDT
is part of an optical framing, just as POS (Packet-Over-SONET) is for
data packets. MPLS labels can be looked at and processed by optical
nodes outside the actual payload. If optical nodes are MPLS capable,
for instance, packets can be carried from network-to-network without
performing an inter-working function (IWF) at the network boundaries.
18.2 Transport without MPLS
With its support for per-packet payload identification and robust
frame delineation, HDT is able to send multiple types of packet over
any mix of SONET and data-over-fiber networks.
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+---+ +---+
ATM ----+ | | +---- ATM
Ethernet ----+ | | +---- Ethernet
| | Any mix of | |
Raw Data ----+ A +================+ B +---- Raw Data
| +================+ |
PPP ----+ |SONET and/or DoF| +---- PPP
Frame Relay --+ | | +---- Frame Relay
+---+ +---+
Figure 9: Data Mixing over same Fiber
Since each data type is clearly identified through a uniform header,
all types of packets can be mixed over the same fiber (or wavelength)
with or without SONET support.
18.3 Transport using MPLS
The use of MPLS in HDT header is OPTIONAL.
HDT supports current MPLS label stack encoding schemes in addition
to, or in lieu of, an external MPLS label stack for data transport
over optical networks.
18.3.1 MPLS as a Shim Header within Layer 2 Frames
In this case, while HDT provides payload header for payload
identification, bandwidth allocation, and other parameters, MPLS
stack is carried in a shim header over native protocols such as
Ethernet, ATM, Frame Relay, or PPP.
With this method, networks can transmit multiple native protocol
packets over the same fiber (or wavelength) and use MPLS switching
with native data packets.
18.3.2 MPLS in Payload Header for True Multiservice Transport
True multiservice transport with traffic engineering can be achieved
with the use of MPLS in HDT header fields. De-linking MPLS from layer
2 dependencies over optical networks allows the use of MPLS without
constraints of traditional data link layer technologies. Any type of
payload including PDH, SONET/SDH, IP, ATM, and raw byte stream can be
switched using MPLS.
MPLS labels are carried in an outside header that contains payload
identification, among other parameters.
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+---+ +---+
ATM --------+ | | +-------- ATM
Ethernet --------+ | | +-------- Ethernet
| +------------+ |
Raw Data --------+ A | LSP | B +-------- Raw Data
| +------------+ |
PPP --------+ | | +-------- PPP
Frame Relay ------+ | | +-------- Frame Relay
+---+ +---+
Figure 10: Statistical Multiplexing of Services over the same LSP
Because HDT provides per-packet payload identification, the same MPLS
labels (belonging to an LSP) can be used for sending different
LAN/WAN data types, including raw data stream.
A bounded set of LSPs, limited only by provisioned link capacity, can
be created with different bandwidth allocations, with each LSP
carrying multiservice traffic.
18.3.3 Interconnection of MPLS Networks over Public Networks
/--------------------\
/ \
/ +---+ \
/ +------>| S |------+ \
----+ / |+------| 4 |<----+| \ +----
| / Tx|| +---+ || \ |
----+ / ||Rx || \ +----
| +===+ Rx +---+ Pt-to-Pt +---+ Rx\ +===+ |
----+ | R |=====| S | & | S |=====| R |---+----
+-----+ 1 |=====| 1 | Ring Network| 3 |=====| 2 | |
LAN | +===+ Tx +---+ +---+ Tx/ +===+ |LAN
----+ \ ^|Tx +---+ || / +----
| \ Rx|+----->| S |-----+| / |
----+ \ +-------| 2 |<-----+ / +----
\ + --+ /
MPLS Shim \ PUBLIC NETWORK / MPLS Shim
Header \---------------------/ Header
External MPLS Stack
LSPs for carrying
(ENTERPRISE NETWORK) Different Data Flows (ENTERPRISE NETWORK)
Figure 11: Interconnection of MPLS domains
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By using external MPLS labels with HDT header, two private enterprise
internal MPLS-based networks (working on legacy protocols with MPLS
shim header) can be connected over a public network. In this case,
LSRs on the two private networks shown in Figure 11 use MPLS stack
spanning the two networks in a transparent fashion.
When the packet enters a public network, LSRs R1 and R2 running HDT
use another label stack 'outside' the native packet from private
networks, as shown below.
+=====+======+======+----+-----------------+----------+------+
|cHdr | cHEC |.MPLS.| L2 |MPLS Shim Header | Payload | pFCS |
+=====+======+======+----+-----------------+----------+------+
4 2 N <--- Ethernet Frame with MPLS ----> 4
(PUBLIC) (ENTERPRISE)
Figure 12: MPLS label stacks for interconnection of domains
Packets coming from private networks do not, however, need to have
MPLS stack _ native packets can be transported along with packets
with shim headers since MPLS switches within the public network
wouldn't look at the payload.
Since HDT allows multiservice transport, many different types of data
can be put in an LSP in the public network. The public network may
set up different LSPs with various traffic engineering and QoS
parameters and put different types of packets from the private
network to be carried over the public network.
19. Single MPLS Control Plane for Multiservice Transport
Since a single LSP can carry multiple protocols with a uniform frame
structure for carrying all types of traffic, a single optical control
plane can be used for provisioning a path (or wavelength) using a
consistent traffic management scheme such as RSVP-TE or CR-LDP. This
path can then be used for sending all types of traffic to fully
utilize the provisioned link.
Thus, a single IP based control plane can be used for all types of
data to be transported using MPLS. Since data is transported opaquely
a single control plane is needed for multiservice transport.
20. Minimization of Number of LSPs
Since a single LSP can send multiple types of data, fewer LSPs are
required for creating traffic-engineered links. A consistent and
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unified control plane for setting up light paths with traffic
engineering parameters for sending all types of data.
For non-SONET style fault resilience and recovery, a minimum number
of alternative LSPs can be set up to carry all types of critical data
on backup links. There is no need to set up individual LSPs for
different protocols.
Fewer LSPs for carrying all the different protocols lead to lower
management overhead and fewer refreshes in RSVP-TE at each node.
Different LSPs can be created with different traffic engineering and
QoS parameters and then different types of data can be sent on them
depending on the requirements of data traffic.
For instance, a high-bandwidth LSP can be provisioned to transport a
mix of some IP flows, ATM traffic, raw byte stream, and some frame
relay traffic. Other IP flows, some other ATM traffic and other frame
relay flows can be given to another LSP with a differently
provisioned bandwidth.
21. Multiservice Switching over WDM Links
Many topologies are under development for switching of WDM links
based on MPLS labels.
One of the premises of HDT is that with more research into MPLS and
deployment of MPLS in optical networks for data switching, traffic
engineering, route aggregation, and fault protection, MPLS would
become a common switching mechanism for all types of data flows.
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+-+---------+ +-+---------+ +-+----------+
|M| Ethernet| |M| Ethernet| |M| Raw Data |
+-+---------+ +-+---------+ +-+----------+
+-+-----------+ ================================
|M| ATM cells | 2/
+-+-----------+ / +-+------------++-+---------+
+---+ +---+ / |M|Frame Relay ||M| Ethernet|
| | 1 | | / 3 +-+------------++-+---------+
------>| A +======+ B +=====================================
| | | | \
+---+ +---+ \ 4
+-+------------+ MPLS-based \ +-+-----------+ +-+---------+
|M| Frame Relay| WDM \ |M| ATM cells | |M| Ethernet|
+-+------------+ Switching \ +-+-----------+ +-+---------+
==============================
Figure 13: Multiservice transport over each WDM link
For optical networks MPLS will become the dominant mechanism for
switching packet data, wavelengths, optical TDM, and anything else
that requires switching data over a traffic-engineered path.
MPLS labels as a common header facilitate uniform processing for all
types of payload without regard to payload content.
MPLS labels are established using common signaling methods; and once
the labels are assigned traffic can be sent on the labels with MPLS
being the only data link layer, for switching purposes.
In the figure above, different types of data arrive on switch at node
B. The switching logic at node B looks at labels and switches frames
to appropriate output links (after label modification).
22. Frame Delineation Methods
HDT frames can be delineated over optical networks using any robust
frame delineation mechanism, such as HDLC (0x7E) or SDL (Simple Data
Link, rfc2823).
22.1 HDLC
HDLC-based delineation and scrambling are done as per Packet-over-
SONET (POS) protocol as defined in rfc2615 [3], without the PPP
protocol encapsulation requirements.
+====+-----+------+-----------------+------+====+
| 7E |cHdr | cHEC | ....Payload.... | pCRC | 7E |
+====+-----+------+-----------------+------+====+
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1 4 2 4 1 (bytes)
Figure 14: HDLC Delineation
Unlike POS, there is no PPP HDLC header (such as FF 03) encapsulation
in HDT, as PPP is one of the many types of payload that can be
carried inside HDT.
In a system, HDT encapsulation is always processed before getting to
the payload. Therefore, it is not possible to transport a non-HDT
HDLC frame (containing PPP, for example).
Using delineation based on HDLC has many limitations when working
with large frames and higher speeds of operation for optical
networks:
o Every outgoing byte needs to be monitored, and stuffing needs to
be performed to prevent flag emulation by data bytes. And the
receiver also needs to monitor every incoming byte to perform the
de-stuffing. Processing every byte at speeds of OC-48/192/768
requires hardware running at high speeds.
o Malicious long packets (killer packets) can defeat scrambling,
causing loss of synchronization. This is more likely now with
increasingly large packet sizes with newer protocols such as
multiprotocol over frame relay and jumbo Ethernet frames.
o No advance knowledge of length prevents efficient use of
variable-size queues for handling packets on incoming ports.
Length of HDLC frame can only be determined when terminating 0x7E
is encountered. Since nodes have no knowledge of frame length a
priori, they must allocate buffer with the highest size for every
incoming frame.
o Loss of synchronization can become a hopeless situation because
only one value (0x7E) acts both as a start marker and an end
marker for a packet.
o HDLC implicitly is bandwidth inefficient as byte stuffing causes
the number of bytes transmitted to be much larger than the actual
number of bytes in the packet.
22.2 SDL (Simple Data Link, rfc2823)
SDL framing (rfc2823, [6]) prefixes a packet with a 32-bit word.
First 16 bits of this word (LHdr) hold the length of the entire
payload and the other 16 bits (LHEC) contain CRC-16 (Cyclic
Redundancy Check) calculated on the 16-bit length field, as shown
below.
<----SDL --->|<------------ Packet --------------->|
+=====+======+-----+------+-----------------+------+
|LHdr | LHEC |cHdr | cHEC | ....Payload.... | pCRC |
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+=====+======+-----+------+-----------------+------+
2 2 4 2 N 4 (bytes)
Figure 15: SDL Delineation
SDL provides a robust CRC-16 based framed boundary delineation
mechanism that solves all current POS issues like robustness in bad
BER conditions, variable packet size expansion, and malicious long
packet scrambler manipulation.
Packets are located by hunting for a length/CRC match, much the same
way as ATM cells are located by HEC synchronization. The next packet
within a SONET payload or on a DoF link is located by jumping length
bytes in the frame and again looking for a length/CRC match.
In case of data corruption at the location of a length CRC field, the
hardware begins a byte-by-byte hunting for the length/CRC construct
until a match is found.
22.2.1 Length (LHdr)
The field is 16 bits and it contains length (in bytes) for all the
bytes following LHEC field. This includes cHdr, cHEC, payload, and
pCRC fields.
The SDL draft (rfc2823) specifies the length field to include all
bytes following the LHEC (length CRC) field up to the end of payload
but not including pCRC. It mandates an advance negotiation or
provisioning for presence or absence of pCRC in all frames. This
scheme for pCRC is sufficient for sending a single type of packet.
In a multiservice transport, however, some data types may not have an
explicit CRC field present at the end of the payload. Examples of
such data types are _ ATM cell(s), SONET/SDH frame(s), T1/T3/NxDS0
frames, etc. In addition, in systems frame delineation logic is
always separate from CRC computation/verification logic.
To accommodate this variation, and to de-couple frame HEC delineation
from payload CRC dependence, this draft specifies that the LHdr
length value MUST include length of pCRC field (4 bytes), if present.
With this scheme, frame delineation mechanism is simpler - to get to
the next frame, the delineation logic simply crosses over an offset
given by LHdr value.
Length field values can range from 0 to FFFF, allowing a maximum of
65536 bytes to be sent (including HDT header, payload, and pCRC).
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Minimum length of bytes following the LHEC field is 7 bytes. This is
equal to the minimum size of an HDT header (6 bytes) plus 1 byte of a
payload (with no pCRC).
Consequently, LHdr values of 0-6 (inclusive) are reserved and used
for special SDL frames (described in the next section).
22.2.2 Length HEC (LHEC)
This field is 16 bits, and it contains ITU-T CRC-16 calculated on the
16-bit LHdr field.
22.2.3 Payload CRC (pCRC)
The payload CRC is an OPTIONAL field. When present it MUST be an ITU-
T CRC-32. Presence or absence of the payload CRC is indicated in the
payload header cHdr.
23. DC-balancing
The four-octet length/CRC construct is DC balanced by exclusive-OR
(also known as "modulo 2 addition") with the hex value B6AB31E0.
This is the maximum transition, minimum sidelobe, Barker-like
sequence of length 32. No other scrambling is done on the header
itself.
24. Scrambling
By default, an independent, self-synchronous X^43 + 1 scrambler is
used on the data portion of the message including the 32 bit CRC (if
present). This is done in exactly the same manner as with the ATM
X^43 + 1 scrambler on an ATM channel. The scrambler is not clocked
when SDL header bits are transmitted.
Thus, the data scrambling MAY be implemented in an entirely
independent manner from the SDL framing, and the data stream may be
pre-scrambled before insertion of SDL framing marks.
An OPTIONAL set-reset scrambler defined for SDL is an X^48 + X^28
+X^27 + X + 1 independent scrambler initialized to all ones when the
link enters PRESYNCH state and reinitialized if the value ever
becomes all zero bits.
25. Special SDL Frames
Length values 0-3 (inclusive) for the frame are reserved for special
SDL packets. For these special frames, the length value (LHdr) does
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not reflect the actual number of bytes in the payload - it is a fixed
length depending on the packet type (determined by the LHdr value).
25.1 Null/Idle Frame
(Length = 0)
A null packet is a 4-byte length/CRC construct with the LHdr field
equal to zero.
+-----+------+
|0000 | LHEC |
+-----+------+
2 2 (bytes)
Null frames are used as fillers when there are no packets to be sent.
25.2 Scrambler State
(Length = 1)
+------+------+-----------------+--------+
| 0001 | LHEC | Scrambler State | CRC-16 |
+------+------+-----------------+--------+
2 2 6 2 (bytes)
The special value of 1 for Packet Length is reserved to transfer the
Scrambler State from the transmitter to the receiver for the optional
set-reset scrambler. In this case, the SDL header is followed by six
octets (48 bits) of Scrambler State. Neither the Scrambler State nor
the CRC are scrambled.
25.3 A/B Messages
(Length = 2, Reserved)
+-----------+------+-----------------+--------+
| 0010 | LHEC | .._ Payload _.. | CRC-16 |
+-----------+------+-----------------+--------+
2 2 6 2
In SDL specification, special values of 2 and 3 for Packet Length
were reserved for "A" and "B" messages, which are also six octets in
length followed by two octets of CRC-16. Each of these eight octets
is scrambled. These messages are reserved for use by link maintenance
protocols, in a manner analogous to ATM's OAM cells.
This draft uses code for "B" messages for sending a single ATM cell.
Code for "A" message remains reserved.
25.4 Single ATM Cell Transport
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(Length = 3)
A length value of 3 is used for sending a single ATM cell.
+--------+------+-----------------+
| 0011 | LHEC | ATM Cell |
+--------+------+-----------------+
2 2 53 (bytes)
To save on overheads, no HDT header is used for sending a single ATM
cell. Only SDL delineation is used.
The ATM cell is sent in its entirety, with no payload CRC.
26. HDT Payload Header (PH) Structure Details
+===============+-----------------------------------------+(bytes)
| | Core Header (cHdr) (32 bits) | 4
| +-----------------------------------------+
| |(Optional) Next Fragment offset (32 bits)| 4
| Payload +-----------------------------------------+
| Header |(Optional) MPLS/OAM bytes (N x 32 bits) | N
| +-----------------------------------------+
| | Core Header CRC cHEC (CRC-16) | 2
+===============+-----------------------------------------+
| User Payload ~~~ ~~~
| Data | Payload data |
| ~~~ ~~~
| +-----------------------------------------+
| |(Optional) Payload CRC (16/32 bits) | 4
+===============+-----------------------------------------+
26.1 Core Header (cHdr)
As discussed earlier, HDT header (cHdr) is a 32-bit value precedes
every payload (except for a single ATM cell when using SDL
delineation) and provides all parameters that are needed to describe
the type of data being transported and to advise nodes on how to
process the packet.
Bit(s) Description
------ -----------
D31: D24 Header Length in bytes (HLEN) - [8 bits]
D23: D16 Time-to-Live (TTL) - [8 bits]
D15: D14 Reserved for Future Use - [2 bits]
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D13: D12 Tail-end padding (TEP)- [2 bits]
00: No padding
01: 1-byte padding
10: 2-byte padding
11: 3-byte padding
D11 Payload CRC (pCRC) - [1 bit]
0: No Payload CRC (pCRC - 32 bits)at the end of payload
1: Payload CRC (pCRC) at the end of payload
D10 Fragmentation Identifier (FI) - [1 bit]
0: No fragmentation, or a complete packet
1: Packet Fragment
D9 Multi-frame Rate Channel (MF) - [1 bit]
0: No Rate channel
1: Rate channel, goes over multiple frames
D8 Bandwidth Allocation (BA) - [1 bit]
0: Do not allocate bandwidth for this packet
1: Allocate bandwidth for this packet
D7: D5 Header Extension (HEX) - [3 bits]
000: No additional header data bytes
001: MPLS Labels
010: OAM bytes
011: MPLS followed by OAM bytes
100: Reserved for future use
-
111
D4: D0 Payload Identifier (PI) - [5 bits]
Each of these parameters is described below.
26.1.1 Payload Identifier (PI)
[D4: D0]
These bits indicate the type of data in the payload. Payload
identification is provided for systems to help process packets. HDT
does not differentiate in treatment of packets.
Bits Description
---- -----------
00000 Null packet
00001 ATM Cell(s)
00010 PPP
00011 Ethernet / IEEE802.3
00100 PDH (T1/T3)
00101 Frame relay
00110 IP
00111 Raw byte stream
01000 SONET/SDH
01001- Reserved for future use
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11111
There are only two types of payload:
o Null packets: different from Null Frames of SDL (that are marked
with length LHdr = 0), these are packets that have been dropped
at a node, leaving the packet area reusable at the node or any
other downstream node.
o ATM/IP/Ethernet/Frame Relay/PPP/PDH/raw packets: standard
packet/PDH data packets.
Raw packets are any streams of data bytes, not necessarily having any
protocol structure. These bytes are usually switched using MPLS
labels.
26.1.2 Header Extension (HEX)
[D7: D5]
These bits indicate presence of any additional bytes in the HDT
header between cHdr and cHEC fields. Currently, values are defined
for MPLS and OAM fields; other values can be added in future.
Bits Description
---- -----------
000 Header contains no additional data bytes.
001 MPLS labels.
010 OAM bytes.
The OAM bytes can be sent in-band with a packet, allowing a
packet to carry OAM bytes to a destination node/network.
Instead of using a repetitive frame or a special packet type
to hold OAM bytes, any packet can be used to send OAM
information.
Consequently, every packet does not need to carry OAM bytes;
the OAM bytes can be sent only when needed at the required
intervals for link management and monitoring. At other times
only packet data is sent with no OAM overheads.
A packet MAY not be present in payload area when OAM bytes are
sent in the header. In other words, OAM bytes can be sent
using MPLS labels to the destination node.
011 MPLS labels followed by OAM bytes.
In this case MPLS labels precede OAM bytes, allowing MPLS to
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traverse the routes for sending both OAM and packet payload
over a network.
End of MPLS labels (and beginning of OAM bytes) is determined
by end-of-stack bit in the bottom label. When the last label
has been popped at a node, the node changes the bit value from
011 (MPLS+OAM) to 010 (OAM only).
100-111 Reserved for future use. These can be used for sending any
other types of control and signaling information that would
otherwise have required complex modifications and layer 2 shim
header creations to native packets.
26.1.3 Bandwidth Allocation (BA)
[D8]
The Bandwidth Allocation/Reuse (BA) bit allows any packet inside a
SONET frame to instantly reserve a guaranteed bandwidth on a packet-
by-packet basis. Use of this bit allows a node to instantly provision
and secure a position within a SONET SPE for a packet. This is
similar to a virtual tributary, except that now any packet can become
like a virtual tributary, the length of which is the same as the
length of the packet.
In traditional SONET architectures fixed size and location of virtual
tributaries were defined. Bandwidth provided by a virtual tributary
is equal to NxDS0, where N is the number of bytes in the tributary.
Higher-bandwidth LAN/WAN traffic was sent over these low-bandwidth
tributaries by complex mechanisms such as inverse multiplexing and
virtual concatenation.
Provisioning these circuit-switched virtual tributaries takes a long
time, and sending packet-switched data over these circuit-switched
tributaries leads to network complexity, both in configuration and
maintenance.
With the BA bit a sending node can send an entire packet inside a
SONET SPE and mark it for bandwidth allocation. Subsequent nodes
preserve location of this packet inside SONET, creating a virtual
tributary on the fly. The size of this tributary is determined by the
size of packet (and HDT overhead bytes). When the packet is received
at the destination node and stripped off the ring (or, in case of
multicast packets the sending node takes the packet off the ring),
the area occupied by this packet is free for reuse for any other type
of data.
Bit Description
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--- -----------
0 No bandwidth allocation. The starting location occupied by
packet inside a SONET frame is not guaranteed as it goes down
the network. Downstream nodes can readjust location of packets
in the SONET SPE as packets are removed and added at nodes.
Depending on packet priority vis-a-vis other packets pending
transmission, the packet may even miss the current SONET frame
and get delayed until the next frame cycle.
1 A sending node (or any downstream node along the path) sets
this bit to reserve packet location in the SONET SPE. Bandwidth
reserved on the link for this packet is equal to NxDS0, where N
is the number of bytes in this packet.
With this bit set to 1, downstream nodes will not change the
starting location of the packet within the SONET frame, giving
a packet repetition rate of exactly 125 uS. Higher bandwidth
packet stream is sent with multiple (different) packets in the
same SPE.
26.1.4 Multi-Frame Rate Channel (MFRC)
[D9]
This bit, in conjunction with the BA bit (bit D8) set to a 1,
provides a multi-frame rate channel for low-bandwidth requirements
such as DS0, 2xDS0, etc. These are typically used for providing data
communication channels, HDLC facility data links, and other
applications. Details on multi-frame rate channels are given in
section [34].
This bit set to a 1 indicates that the payload does not contain a
complete packet, instead the payload contains byte(s) from a packet
(such as an HDLC frame). These multi-frame rate channels appear in
every SONET SPE at the same location.
No payload CRC field follows the payload bytes. The CRC values, if
present, contained in the data bytes that go through the rate
channel. The pCRC bit (D11) is set to 0.
Multi-frame rate channels are also created when HLEN value is in the
range of 1-5. When HLEN value is in 1-5 range, there is no cHdr
field. Instead, all bytes following HLEN contain user data that go
through the rate channel.
26.1.5 Fragment Indication (FI)
[D10]
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On a direct data-over-fiber link, or when there are no fixed-
bandwidth packets in a SONET SPE, packet data can be filled in as
they come from system or incoming network side. All bytes belonging
to a packet are sent continuously, with packets sent one after
another.
However, on SONET when some packets are fixed in location within the
SPE, another packet that is dropped at an intermediate node leaves a
space that may either be smaller or larger than the size of a new
packet to be added.
If the empty space is larger than the size of the new packet, the new
packet is added and the remaining area is filled with idle packet(s)
and/or another packet that can fit there.
If the space is smaller, then the new packet to be added is
arithmetically fragmented (no network level fragmentation and
duplication of network headers), with fragments continued in other
areas in the SPE.
When fragmentation takes place, payload headers of first and
subsequent fragments indicate presence of any following fragments.
A 0 in FI field means that the payload area contains either a
complete packet or last fragment in a fragmentation sequence. A 1 in
FI field indicates the packet is a packet fragment.
A 0 in FI field of a fragment marks end a fragment sequence.
When FI is 1, a 4-byte Next Fragment Offset parameter follows the
cHdr field.
The FI bits are unused and set to 0 if none of the packets in an SPE
requires a fixed-bandwidth allocation.
26.1.6 Payload CRC
[D11]
This bit indicates if there is a payload CRC (CRC-32) present at the
end of payload.
A 0 indicates there is no CRC-32 payload CRC present at the end of
user payload data.
A 1 indicates a CRC-32 for the payload bytes is present at the end of
payload.
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26.1.7 Tail-end Padding (TEP)
[D13: D12]
On SONET, sometimes there may be less than 4 bytes left between
consecutive packets, making it impossible to place a SDL null packet.
This can happen when the subsequent packet has a fixed-bandwidth
allocation (more on this is discussed later) and cannot be moved
within the SPE. In this case, these bytes (1, 2, or 3) are padded at
the end of These bytes are then shown as tail-end padding for the
preceding packet.
When all packets to be sent inside a SONET SPE are normal data
packets (IP, ATM, or any other type) with no fixed-bandwidth
requirements, the TEP bits are unused and set to 00.
26.1.8 Reserved bits
[D15: D14]
Reserved for future use.
26.1.9 Time-to-Live (TTL)
[D23: D16]
Sending node sets this 8-bit field to a value that MUST be at least
equal to the number of nodes on the network. To preserve consistency
of operation across a hybrid nature of modern optical network types,
nodes on both ring and linear networks set and process the TTL field.
When a packet passes through a node, the node decrements TTL field by
one. If the TTL count reaches zero, the packet is taken off the
network.
26.1.10 Header Length (HLEN)
[D31: D24]
The header length includes the remaining 3 bytes of Payload Header
cHdr (cHdr is 4 bytes long, and HLEN is the first byte), any
additional payload header data bytes such as any MPLS/OAM bytes, and
the 16-bit cHEC.
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+------------------------------------+
| Bytes covered by HLEN |
v v
+======+=======+==========+==========+======+-----------+------+
|HLEN |D23: D0| ..MPLS.. | ..OAM.. | cHEC |..Payload..| pCRC |
+======+=======+==========+==========+======+-----------+------+
1 3 Nx4 M 2 4 (bytes)
(OPTIONAL)
<--- cHdr ---->
Figure 16: Header Length HLEN Field in HDT Header
As smallest size of a core header is 6 bytes (4 bytes cHdr + 2 bytes
cHEC), the smallest value HLEN field can have is 6. Value of HLEN is
between 6 and 255 (inclusive), giving a maximum header size of 256
bytes (including 1 byte of HLEN field).
Values 1-5 are reserved for creating rate channels (starting at DS0
for value 1 and going up by DS0 value for each increment).
27. Data Transport Operations
A device supporting Hybrid Data Transport protocol works much the
same way as any other transport protocol over optical networks. Since
packets can be natively and transparently transported over HDT,
operations for processing Ethernet, ATM, POS (Packet-over-SONET),
PDH, and any other packet types are the same.
The only change in implementation is addition of an HDT header to
packets to allow multiservice transport within a SONET SPE or over a
single fiber (or wavelength) for data-over-fiber networks.
There are two cases to consider for data transport using HDT:
o There are no PDH channels (such as T1/T3) or lower-order
SONET/SDH channels to be sent along with packets. All packets are
statistically multiplexed over SONET with no specific timing
relationships between successive packets. Payload consists
typically of Ethernet (10M/100M/1G), ATM, Frame Relay, PPP, any
other protocols, and raw data streams.
o In the second case, in addition to data types described in the
first case above, there are packets or data types (such as PDH,
SONET/SDH, etc.) that need guaranteed bandwidth on a dynamic
basis while other data types are statistically multiplexed and
transmitted in remaining areas of SONET SPE.
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The first of these two cases is quite straightforward, and is
described here. The second case is described in the following
section.
Let us consider a typical system where many legacy protocols from a
Host system (either from a physical port, such as an Ethernet port,
or through internal LAN/WAN protocol translation such as PPP/Frame
Relay/ATM) need to go to optical network.
+----------+ +------+
ATM ----+ | | |
Ethernet ----+ | | |
| Host | | Line |
Raw Data ----+ System +=====+ Card +---- SONET/SDH or WDM
| +=====+ |
PPP ----+ | | |
Frame Relay --+ | | |
+----------+ +------+
Figure 17: Multiservice Transport System
27.1 Transmit Operation
In a transmit operation, a node takes inputs from one or more
sources, adds an HDT header to each of the packets, encapsulates with
SDL length/CRC construct (or HDLC framing) and then puts these frames
inside a SONET SPE or directly over a fiber (or wavelength).
A RECOMMENDED implementation approach is as follows:
o Receive input data packet payload. The payload can be IP,
Ethernet, PPP, frame relay, ATM (one or more cells), T1/T3,
NxDS0, SONET/SDH, or just a raw byte stream.
o Add any MPLS label stack, if needed
o Create an HDT header to it with following parameters: data type
identifier, bandwidth allocation (if needed), bit to indicate if
MPLS and/or OAM bytes are present, a bit to indicate if a payload
CRC is present, and finally a length value for the header
including MPLS/OAM bytes.
o Compute cHEC (CRC-16) for header bytes and add to the packet, or
just add a cHEC (CRC-16) placeholder so line card can compute and
fill in the CRC-16 as the packet is being transmitted.
o If HDLC framing is used, send the packet to line card for
scrambling, byte stuffing and HDLC framing.
o If SDL framing is to be used, place a length/CRC construct in
front of the packet with length (LHdr) equal to the entire packet
including any tail end CRC-32. Compute LHEC (CRC-16) for LHdr and
place it in the LHEC field, or just add a LHEC (CRC-16)
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placeholder so line card can compute and fill in the CRC-16 as
the frame is being transmitted.
o The line card computes payload CRC (if needed), computes and
places CRC values (as programmed) in placeholders, and scrambles
HDT header, payload and CRC (as programmed).
o On SONET the frame is sent in a tributary (or a lower-rate SONET)
in non-concatenated mode, or on a higher-bandwidth virtually
concatenated channel, or inside a concatenated payload. On data-
over-fiber networks, the frame is sent directly after appropriate
signal coding.
27.2 Receive Operation
+------------------------------------+
v v
+======+=======+==========+==========+======+-----------+------+
| HLEN |D23: D0| ..MPLS.. | ..OAM.. | cHEC |..Payload..| pCRC |
+======+=======+==========+==========+======+-----------+------+
1 3 Nx4 M 2 4 (bytes)
(OPTIONAL)
<--- cHdr ---->
Figure 18: HDT Receive Operation
When no fixed-bandwidth payloads are involved (BA bit = 0 in core
header cHdr), receive operation is quite straightforward:
o A receiver uses standard HDLC delineation in case of HDLC
framing, and SDL length/CRC hunting and synchronization for an
SDL framing.
o Once a frame has been located, core header HEC (cHEC) for header
bytes is examined. Should there be an error in cHEC, the entire
payload that follows MUST be discarded.
o If core header (cHdr) bits show presence of MPLS labels, the
packet is handed over to a standard MPLS switching logic. If
there are OAM bytes following MPLS labels these OAM bytes are
processed after the packet reaches its destination.
o If there are no MPLS labels, payload (containing native ATM
cells, Ethernet, IP, PPP, etc.) is passed to system with payload
identification. Once we get to payload area, the byte stream
contains native packets and these can be processed by legacy
system logic.
o If there are no MPLS labels, and the frame contains only OAM
bytes (in the header) followed by packet/cells, OAM bytes are
delivered to the node for processing. Nodes can use L2
information contained in payload packet (such as MAC address, ATM
VPI/VCI, frame relay DLCI, etc.) to process or forward OAM
28. End-to-end OAM Support
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In HDT, OAM bytes can OPTIONALLY be sent inside the header. These OAM
bytes can be sent in any of the following ways:
o With native packets - in this case the OAM bytes are delivered to
a destination node on a destination network by using layer 2/3
information contained in the packet.
o Using MPLS labels in the HDT header - OAM bytes are sent on any
LSP chosen by the MPLS labels, while payload area contains data
packets.
o Using MPLS labels in the HDT header - OAM bytes are sent on any
LSP chosen by the MPLS labels. The payload area may not contain
any data packets. This method is used for just sending OAM bytes
at periodic intervals for link monitoring and management.
This method of sending end-to-end OAM bytes has major benefits for
both SONET and data-over-fiber networks. Recall that in SONET
networks, the overhead bytes do not cross ring boundaries, making it
difficult to monitor other networks. Also, in an optical network mix
of SONET and non-SONET it is impossible to conduct OAM operations on
any network from a node.
By allowing attachment of OAM bytes with packet and a way to route
OAM bytes to any node, it is easy to monitor nodes and networks
anywhere. In an optical network mix, this can be used to detect link
failure in both ring and point-to-point networks.
Failures in LSPs can be detected by sending OAM bytes on them at
required intervals. Since any type of payload can be used, networks
running any type of traffic can be monitored using this method. For
instance, if Ethernet-based transmission is used in metropolitan
networks without any SONET framing periodic OAM bytes can be sent for
network monitoring along with Ethernet packets. On a mesh network,
these bytes can be sent using layer2/3 addressing or using MPLS to
any network.
By sending OAM bytes at only required intervals and not with every
packet, overheads are minimized for non-SONET networks.
29. ATM cell transport
29.1 Single Cell
If a single ATM cell needs to be sent, it can be sent with least
amount of overhead using special SDL framing, as described in [25.4].
29.2 Multiple ATM Cells
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One or more ATM cells can be sent together, framed inside an HDT
payload, as shown in [14]. The set of cells is switched as one entity
from node to node using MPLS switching. When it reaches the
destination ATM network, the cells are then taken out and delivered
to the ATM switch by a de-framer.
29.3 ATM over Frame Relay
Because ATM cells can now be sent as a group (as shown in []), the
group can be also sent across a non-ATM network as long as there is
external information in the packet to route the data.
Over pure MPLS switching networks, the group can be switched using
MPLS labels in HDT header fields.
Whenever an ATM node must interface with a node inside a frame relay
network, normal frame relay - ATM interworking function (IWF)
specification should be followed for proper translations.
However, no interworking functions need be performed when two ATM
networks must be connected through an intervening frame relay
network.
In this case, one or ATM cells are sent as a group inside payload
area of a frame relay packet. Format for this group is similar to the
format shown in [14], with the removal of a cHEC field, as shown
below:
+-----+-----+-----+-----+-----+-----+-----+
|cHdr | ATM | ATM | ATM | ATM | ATM | ATM |
+-----+-----+-----+-----+-----+-----+-----+
The HLEN field inside the cHdr gives length of the payload above
(cHdr and ATM cells).
For transmission over frame relay, frame format is similar to rfc1973
[12].
+----+--------+---------+-------+-----+-----+-----+-----+-----+----+
| 7E | Q.922 | Control | NLPID |cHdr | ATM | ... | ATM | CRC | 7E |
+----+--------+---------+-------+-----+-----+-----+-----+-----+----+
ATM cells are transmitted without any modification.
NLPID value for HDT has not been established yet.
The cHEC parameter has been removed for transmission over frame relay
because the payload bytes are protected by CRC at the end of frame
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relay payload. The cHdr header has been retained to allow ATM and
other types of packet data to be sent in the payload area with the
same NLPID value. Bits inside cHdr define the type of packet being
sent using this mechanism.
30. Instant Bandwidth Allocation with Statistical Multiplexing
In addition to providing multiservice transport (with or without
MPLS) over a single fiber (or wavelength) for data-over-fiber or over
a SONET SPE, HDT supports dynamic provisioning and tear down of TDM-
style channels along with multiservice packet data.
With this support it is possible to send NxDS0, T1/T3, lower order
SONET, and any other TDM channel along with any type of packet data
over SONET networks. Both TDM and packet data types can be
statistically multiplexed in any combination. Bandwidth can be
provisioned instantly - either for the entire ring or across a few
nodes in one direction or both directions (this is described in a
different section). At any instant, and between any two nodes,
whenever a TDM channel is not needed, the bandwidth that would have
been used for the TDM channel can be used for packet data (or any
other TDM channels, for that matter).
Bandwidth can be provisioned on a per-packet basis in smallest
possible fine granularity of DS0 (64Kbps) - same as the amount of
bandwidth taken up by a single byte on a SONET network.
As noted earlier, HDT frames can be sent either over an entire SONET
payload area or within a single tributary (or STS-1/3/12/48 channel)
or a virtually concatenated high-bandwidth channel.
Consequently, a system can continue to use traditional TDM channels
on other tributaries while using HDT on selected tributaries (or STS-
1/3/12/48 channels) or on a virtually concatenated high-bandwidth
channel. For instance, one can allocate a high-bandwidth channel for
HDT and use this channel for provisioning multiservice transport for
packet data and TDM channels - all statistically multiplexed, while
other tributaries on SONET are still used for TDM, POS (Packet-over-
SONET), or ATM transport as usual.
Bandwidth is allocated by provisioning a series of bytes inside a
SONET payload for carrying the data. Since each byte corresponds to a
64kbps (DS0) channel, N-bytes inside the SONET payload give a
bandwidth of NxDS0. Higher bandwidth operation is achieved by
allocating more bytes, providing more occurrence of packets in the
SONET payload from a source node, or a combination of both.
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ATM
^
|
+-+-+
+------>| S |------+
| +-----| 6 |<---+ |
| | +---+ | |
| v | v
+---+ +---+
Gigabit Ethernet ----+ S | | S +--> ATM
OC-12----+ 1 | | 5 +--> T1
+---+ +---+
^ | SONET ^ |
| v | v
+---+ OC-192 +---+
T1 ----+ S | | S +--> OC-12
Frame Relay ----+ 2 | | 4 +--> Gigabit Ethernet
+---+ +---+
^ | +---+ | |
| +---->| S |----+ |
+-------| 3 |<-----+
+-+-+
|
|
v
Frame Relay
Figure 19: TDM and Packet Transport over SONET
Consider the case of a gigabit Ethernet link between S-1 and S-4 over
SONET as shown above. Traditional bandwidth allocation schemes for
gigabit Ethernet, for example, allocate N bytes required for
achieving gigabit speeds by taking these bytes from different STS-1/3
channels. These channels are then combined either using inverse-
multiplexing or virtual concatenation techniques.
However, the N bytes allocated for the gigabit Ethernet transport are
not always filled completely with Ethernet packets. Ethernet traffic
is bursty in nature, packets are of different sizes, and depending on
traffic load the packets do not use all of the provisioned space
every time. Link utilization is statistically quite low, resulting in
poor use of provisioned bandwidth.
An optimal use of link bandwidth would be to statistically multiplex
and use the remaining bandwidth whenever available.
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+-+-+---------------------------+ +-+-+---------------------------+
| | +----+------------+---------+ | | +----+-------------+--------+
|T|P| T1 | Ethernet-1 | ATM | |T|P| T1 | Frame Relay | PPP |
|O|O+----+--+---------+----+----+ |O|O+----+--+----------+--------+
|H|H| PPP |Ethernet-2(BW)|Raw | |H|H| PPP |Ethernet-2(BW)|Raw |
| | +-----+-+--------------+----+ | | +-----+-+--------------+----+
| | | ATM | SONET/SDH | | | | ATM | SONET/SDH |
| | +-----+-------+-------+-----+ | | +-----+-------+-------+-----+
| | | Frame Relay | NxDS0 | ATM | | | | Ethernet-3 | NxDS0 | ATM |
+-+-+-------------+-------+-----+ +-+-+-------------+-------+-----+
|<-- 125uS (Low rate SONET/SDH) -->|
|<-- 125uS (Ethernet Fixed BW) -->|
|<---- 125uS (NxDS0) ------------>|
|<--------- 125uS (T1) ---------->|
|<------ 125uS Inter-frame --->|
Figure 20: Multiservice Packet and TDM Transport using HDT
Procedure for transmission of packets with a guaranteed bandwidth
over SONET is similar to that of sending any normal packet.
A SONET payload with typical multiservice transport is shown in
Figure 20. Note that while normal data packet location and contents
change from frame to frame, fixed-bandwidth packets always repeat at
the same location within a SONET payload, creating a 125uS repetitive
pattern.
Steps required for guaranteed bandwidth operation are as follows:
30.1 Dynamic Bandwidth Region (DBR) Allocation at Nodes
+-+-+-------+------+-----+-----+ +-+-+-------+------+-----+-----+
| | | | | | | | | | | | | |
|T|P| DBR | DBR | DBR |Free | |T|P| DBR | DBR | DBR | Free|
|O|O| | | | | |O|O| | | | |
|H|H| Node | Node | Node| | |H|H| Node | Node | Node| |
| | | 1 | 3 | N | | | | | 1 | 3 | N | |
| | | | | | | | | | | | | |
| | | | | | | | | | | | | |
+-+-+-------+------+-----+-----+ +-+-+-------+------+-----+-----+
|<---- 125uSec Inter-frame ----->|
Figure 21: Allocation of Dynamic Bandwidth Region (DBR) for Nodes
First step in providing an instant bandwidth provisioning and data
transmission between to nodes, or among a set of nodes, is allocating
permissible bandwidth limits at the sending node.
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For all fixed-bandwidth traffic, a sending node (node S-1, in this
example) is allocated a set of N bytes, called Dynamic Bandwidth
Region (DBR). A DBR of N bytes corresponds to a bandwidth of NxDS0.
Size and location of this DBR can be changed at any time at the
sending node.
The concept of a DBR is similar to a VT (virtual tributary), however,
unlike a VT a DBR is changeable both in size and location within a
SONET SPE. A DBR can be as large as the entire allowable payload area
inside the SONET SPE. In addition, unlike a VT, all nodes and all
types of traffic for _normal_, bandwidth-insensitive data can share a
DBR if the DBR is not fully utilized at any instant at any node.
A sending node MUST use the bytes within its DBR to send all data
with a fixed-bandwidth transmission requirement. The node MAY use DBR
for sending normal data traffic, if at any instant it does not have
any packets to send from a fixed-bandwidth source. At any instant,
the sending node, or any downstream node, MAY use unused area in a
DBR for sending any normal, bandwidth-insensitive traffic.
Other nodes on the SONET network MAY also be allocated non-
overlapping fixed-bandwidth sets, depending on network and traffic
requirements and admission permissions for fixed-bandwidth data
transport.
If a node does not have a need for sending any fixed-bandwidth
traffic, it MAY choose not to have any DBR allocated and yield this
bandwidth to other nodes that may need to send fixed-bandwidth
traffic.
Number of bytes in DBR for different nodes MAY be different. The only
upper limit on size of a DBR comes from size of SONET SPE. Total
bandwidth for a DBR is adjustable in increments of a byte (DS0).
Using this method, there is no need to allocate bandwidths in
increments of STS-1 or similar finite granularity. One can precisely
allocate a bandwidth for a gigabit Ethernet, a 100M Ethernet,
fractional T-1, or even one DS0 channel.
Each DBR can carry multiple HDT packets, with each HDT packet
containing same or different types of data such as SONET, T1, frame
relay, IP, Ethernet, ATM, or any raw byte stream.
Provisioning and allocation of DBR to different nodes could be done
through administrative, RSVP extensions, or other signaling means.
This is for further study.
30.2 Example of a Multiservice Transport Network
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To describe operation of a dynamic bandwidth management with
statistical multiplexing it is best to illustrate with an example of
a metropolitan or campus network over OC-48, as shown in Figure 22.
ATM
^
|
+-+-+
+------>| S |-----+
|+------| 6 |<---+|
|| +---+ ||
|| ||
+---+ +---+
Frame Relay --+ S | | S +--> 100M Ethernet
100M Ethernet --+ 1 | | 5 |
1G Ethernet ----+ | | |
ATM ----+ | | +--> T3
+---+ +---+
|| SONET ||
|| ||
+---+ OC-48 +---+
T3 ----+ S | | S +--> ATM
1G Ethernet ----+ 2 | | 4 |
+---+ +---+
^| +---+ ||
|+----->| S |----+|
+-------| 3 |<----+
+-+-+
|
|
Frame Relay
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+-+-+------+------+----+----+ +-+-+------+------+----+----+
| | | | | | | | | | | | | |
|T|P| DBR | DBR |DBR |Free| |T|P| DBR | DBR |DBR |Free|
|O|O| | | | | |O|O| | | | |
|H|H| S-1 | S-5 |S-3 | | |H|H| S-1 | S-5 |S-3 | |
| | | S-2 | S-6 | | | | | | S-2 | S-6 | | |
| | | | | | | | | | | | | |
| | | 1.2G | 150M |128K| | | | | 1.2G | 150M |128K| |
| | | | | | | | | | | | | |
+-+-+------+------+----+----+ +-+-+------+------+----+----+
Figure 22: Multiservice Transport over OC-48
In this example network, S-1 and S-2 are end-points of a gigabit
Ethernet. S-1 and S-5 connect 100M Ethernet networks, and S-1 and S-3
have a 128 Kbps frame relay link. In addition, S-2 and S-5 have a T3
circuit-switched link. Many other variations of this network
configuration are possible.
It is RECOMMENDED that nodes on a bandwidth link share the same area
in the SPE. In the configuration above, S-1 and S-2 are allocated an
aggregate bandwidth equal to the largest need for bandwidth. As a
better, fine-tuned alternative both S-1 and S-2 can share a 1G DBR
area; and S-1 and S-2 can share additional DBR areas for requirements
for 100M, T3, frame relay, and any other interface needs.
S-3 gets a DBR allocation for 128Kbps bandwidth. Recall that
bandwidth can be allocated with a fine granularity of DS0 (64 Kbps).
All of these DBR areas can be freely used by any node anywhere in the
ring for transmission of normal data packets (with BA bit = 0).
Unassigned area in the SPE is free and any node can use it for
sending any type of traffic.
30.3 Data Transmission at a Sending Node
o To send a packet a sending node prepares a core header (cHdr) for
the packet. The node specifies the type of data and presence of
any MPLS labels and/or OAM bytes in cHdr parameter bits.
o The node sets BA bit (bit D8) set to 1 to denote guaranteed
bandwidth transmission for the packet.
o The completed HDT frame is sent at an available location within
the DBR.
o The node MAY use remaining area in its own DBR or any other place
within the SONET SPE with any other normal packet to fully
utilize the provisioned bandwidth.
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30.4 Processing at an Intermediate Node
Processing at an intermediate node in Figure 19(in this figure
intermediate nodes are S-2 and S-3 for sending node S-1 and
destination node S-4) is relatively straightforward:
o A node looks at the packet data link information _ MPLS label at
the top of the stack in HDT header; or ATM VPI/VCI, Ethernet MAC,
and frame relay DLCI to determine if the node is the destination
node for this packet. If a match is found, the node is a
destination node and it processes the packet as described in the
next section.
o As SONET frames containing fixed-bandwidth packets go around the
ring, intermediate nodes detect these packets by checking the BA
bit [bit D8].
o If the BA bit is 0, the packet is treated as a normal packet, and
the node can place the packet anywhere inside an outgoing SONET
SPE.
o If the BA bit is 1, the node records the offset of this packet
and preserves it in outgoing SPE - providing a 125uS-repetition
rate for the packet.
o The intermediate node MAY add its own data (fixed or variable
bandwidth) to the SPE depending on availability of bandwidth. If
the data requires a fixed-bandwidth allocation, the node can add
it only within its own allocated DBR.
30.5 Processing at a Destination Node
o A node looks at the packet data link information _ MPLS label at
the top of the stack in HDT header; or ATM VPI/VCI, Ethernet MAC,
and frame relay DLCI to determine if the node is the destination
node for this packet.
o It clears the PI (Payload Identifier) bit (bit D4: D0) to mark
the area occupied by the packet as null and reusable.
o The packet is received by the node and taken off the ring, if
required. Multicast packets are not taken off the ring.
31. Segmented Dynamic Bandwidth Allocation
HDT also allows segmented bandwidth allocation over a section of a
SONET network. Assume an application where a server (node A)
downloads real-time multimedia video data to the client (node B).
While a guaranteed bandwidth availability is needed in the (A->B)
direction, the (B->A) direction does not need the bandwidth. The
traffic in (B->A) direction may simply consist of requests and
acknowledgments from client to server.
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Bandwidth released
+------<-------<---------<-+
| +---+ |
| +------>| S |-----+ |
v |+------| 6 |<---+| |
|| +---+ || |
|| || |
+---+ +---+
| S | | S +--> 100 M Ethernet
100M Ethernet --> 1 + | 5 | (Client)
(Server) +---+ +---+ B
A || SONET ||
|| ||
| +---+ OC-48 +---+
| | S | | S | ^
| | 2 | | 4 | |
| +---+ +---+ |
| ^| +---+ || |
| |+----->| S |----+| |
| +-------| 3 |<----+ |
| +---+ |
+---->---------->----------+
Guaranteed Bandwidth
Figure 23: Bandwidth allocation on a partial link
When node A sends a packet with a guaranteed bandwidth it sets the BA
bit. When B sends a packet to A, it clears the BA bit if it does not
need a guaranteed bandwidth. The packets in (B->A) direction travel
as a normal packet, allowing other nodes to use the released
bandwidth for time-critical packets.
Note that even if B sets the BA bit to a 1, a lot of bandwidth is
released to the network. If B is a client sending acknowledgments and
requests these packets are significantly smaller than packets coming
in (A->B) direction. Since bandwidth consumed is only equal to the
NxDS0 (where N is the number of bytes occupied by a packet), the (B-
>A) link releases a lot of bandwidth to the `pool'.
32. Fragmentation of Packets
Support of PDH-type channel requires a fixed starting location for
the channel in every frame. If PDH support is not needed, packets of
any mix can be put anywhere inside the SPE and we can achieve
excellent bandwidth utilization without much any complexity.
When a data packet is sent inside an SPE that is already carrying a
mix of some fixed-bandwidth channels, it MAY happen that there are
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usable areas in the SPE between fixed-bandwidth channels that can be
utilized for sending packet data or some other fixed-bandwidth
channels.
Referring to Figure 22, when fixed-bandwidth packets are destination-
stripped at destination nodes and packets of different sizes are
added it is likely that spaces exist between two fixed-bandwidth
packets that cannot fully accommodate a new packet to be added at
this node.
+------>---------->-------->-------+
| |
+-+-+---------|----------------------------------|-----------+
| | +----+----+-------+------------+-----------+-v---------+ |
|T|P| T1 | Pkt Frag 1 | FB packet | FB packet | Pkt Frag 2| |
|O|O+----+--+--------------+----+--+----+------+-----v-+---+-+
|H|H| PPP | Pkt Last Frag|DS0 | PPP | | |PPP |
| | +-----+-+-^------------+----+-----+-+------------|-+-----+
| | | ATM | | SONET/SDH | ATM | Ethernet| |
+-+-+-----+---|-----------------+-----+--------------|-------+
+--------------------------------------+
Figure 24: Fragmentation over a fixed-bandwidth packet boundary
In this case, a part of the packet is stored in the available space,
and is continued at next available empty space in the SPE. All
fragments look like complete packets with proper SDL framing and
fragment length information with each pointing to the next by storing
the starting address of the next fragment in its Next Fragment Offset
field. Fragmentation of HDT frames allows filling the entire SPE with
different types of data to its full capacity.
If a particular space in the SPE is too small to house HDT header,
fragment offset, and some payload bytes the space is filled with idle
packets. Idle packets for SDL are length/CRC constructs with the
length value set to 0000. For HDLC-based delineation
Fragmentation of a packet is quite easy in SONET because all bytes in
an SPE are transmitted sequentially, and there isn't any problem in
recovering fragments and putting them together.
If payload has a CRC-32 at the end, it shows up only in the last
fragment. Each of the fragments, except the last one, has Fragment
Indication (FI) bit set to 1 in its HDT header. The Next Fragment
Offset 32-bit value is set to offset of the next fragment from the
beginning of current fragment.
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33. Tail-end Padding
It is possible that between two fixed-bandwidth frames there is an
unused set of bytes. This free space is usually created when a frame
occupying that space is dropped at a node.
When a new frame to be added in the free space is smaller than the
free space size, the remaining area must be filled with some valid
data.
When HDLC framing is used, this free space is simply filled with the
delimiter flag.
In case of SDL framing [refer to section 22.2], depending on the
number of bytes in the remaining area, following steps are taken:
o 1-3 bytes in the remaining area: these bytes are set to 00 and
included in the added frame as tail-end padding. The Tail-end
Padding (TEP) bit in cHdr is set to the number of bytes padded.
o 4 bytes: a Null/Idle SDL frame is inserted in the four bytes.
o 5+ bytes: an SDL frame is placed with LHdr set to (number of
bytes _ 4; 4 is the length of SDL LHdr + LHEC fields). The first
byte following these is HLEN of cHdr. The HLEN field is set to
the number of bytes that follow the first 4 bytes. Note that HLEN
values of 0-5 are not used for sending a packet, instead these
values are used to provide rate channels. A HLEN value of 0 gives
is exactly one byte of payload, giving a single DS0 channel
34. Multi-Frame Rate Channels
An easy extension of HDT support for dynamically creating fixed-
bandwidth channels is creation of smaller rate channels such as DS0,
2xDS0, etc. These are typically used for providing data communication
channels, HDLC facility data links, and other applications.
+-----+------+=====+======+------------------+
|LHdr | LHEC |cHdr | cHEC | Channel Byte(s) |
+-----+------+=====+======+------------------+
2 2 4 2 N
This bit set to a 1 indicates that the payload does not contain a
complete packet, instead the payload contains byte(s) from a packet
(such as an HDLC frame). These multi-frame rate channels appear in
every SONET SPE at the same location.
There is no CRC for the payload in the HDT frame. The CRC-32 (or CRC-
16) is a part of user HDLC packet, for instance, and it appears
within the channel bytes.
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Operation of these channels is similar to what SONET provides through
data communication channels. However, these channels are more
powerful than what is provided by SONET in following ways:
o Any number of channels can be created within an SPE
o These channels coexist with any other type of data being
transmitted in the SPE
o These rate channels can be of any size, starting from DS0 all the
way up to the full capacity of the SPE.
35. Bandwidth Reuse on SONET
For packet transport over SONET rings, it is advantageous to take a
packet off the ring once it has reached its destination. As discussed
in [8.2.3], new protocols such as Spatial Reuse Protocol (SRP [7])
use destination MAC addresses for selecting packets for destination
stripping to free occupied bandwidth.
Instead of supporting only Ethernet-style framing, HDT provides for
any type of data to be destination-stripped. As shown in Figure 25,
different types of layer 2 frames can be destination-stripped at
their respective destination nodes to free up bandwidth on a SONET
network.
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ATM (VPI/VCI)
^
|
+-+-+
+------>| S |-----+
|+------| 6 |<---+|
|| +--++ ||
|| | ||
(MPLS or MAC) +---+ VPI/VCI +---+
Gigabit Ethernet ----+ S |\/-----+----| S +--> ATM (VPI/VCI)
(VPI/VCI) ATM ----+ 1 |/\ -------| 5 +--> T1 (MPLS)
+---+ \ / +---+
|| \ ||
|| / \MAC ||
+---+ / \ +---+
(MPLS) T1 ----+ S |/ \ | S +--> ATM (VPI/VCI)
Frame Relay ----+ 2 |\ DLCI \----| 4 +--> Gb Ethernet
(DLCI) +---+ \---\ +---+ (MAC or MPLS)
^| +-\-+ ||
|+----->| S |----+|
+-------| 3 |<----+
+-+-+
| (DLCI)
| (MPLS)
v
Frame Relay
Figure 25: Bandwidth Reuse on SONET for Multiprotocol Traffic
Either layer 2 information (such as ATM VPI/VCI, frame relay DLCI, or
Ethernet MAC address) contained within the protocol frame or MPLS
label provided in HDT header can be used for destination-stripping
the packet. Raw byte streams (clear channel data) would normally use
MPLS labels for destination stripping.
When MPLS is used, instead of switching cell-by-cell multiple ATM
cells can be carried as an ensemble from one node to another node
guided by MPLS switching.
36. Fault-resilient Packet Networks with Recovery and Restoration
Due to its protocol-independent frame format and MPLS encoding, HDT
provides a homogeneous way for creating fault-resilient optical
networks for any combination of SONET and data-over-fiber networks.
With multiservice transport capability, alternative LSPs are created
with traffic engineering parameters for an aggregation of critical
traffic that needs to be protected at a segment. One can take
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different data flows (of different network protocol types) and put
these on an alternative LSP link. Different alternative LSP links
going to different destinations can be set up. These different LSPs
can take different priorities and mixes of traffic when a fault
occurs.
A network diagram with a hybrid of point-to-point (PTP) and ring
networks is shown below.
A fixed interconnection that goes through entire SONET ring forces
all traffic passing through the SONET network to go to all nodes in
case of a fault. In the diagram below, an optimal path for a packet
going from (A) to (B) could be to go from W1 to S1 to S2 to W2. If
S1-S2 link were to fail, it may not be desirable for a fiber wrap at
S1 and S2 and go through S1-S4-S3-S2 route. It may be much more
preferable to go through W1-W2 using a point-to-point WDM link for
all or part of its critical data.
Therefore, a simple fiber wrap-around on a standard SONET link may
not be optimal at all times. Many times network providers may choose
to keep cheaper point-to-point alternative routes as backup links in
case a few of their key nodes or links fail.
MPLS labels are set up for network layout, traffic engineering, and
alternative route selections. In the example above, an LSP (Label
Switched Path) is set up for W1-S1-S2-W2.
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+----+
+-------->| S |---------+
|+--------| 4 |<-------+| +---------+
|| +----+ || |+-------+|
|| \ || || RING ||
|| LSP-S4S3|| || 2 ||
+---+ +---+ SONET \.. +---+ |+---+ ||
| W | PTP | S | RING 1 | S | || S | ||
(A)----+ 1 ++--------+ 1 |------------------+ 3 +------+| 5 | ||
From | || Link +---+ LSP-S1S3 +---+ |+---+ ||
PTP +---+|LSP-W1S1 || || || ||
or | || +---+ || || +---+ ||
Ring | |+------->| S |--------+| |+-| S |-+|
\ +---------| 2 |<--------+ +--| 6 |--+
\ +---+ +-+-+
\ LSP-W1W2 +---+ +--->
\------------------------------+ W +--------+--->(B)
PTP | 2 | To other PTP
Link +---+ or
ring networks
Figure 26: Fault Recovery and Restoration
The purpose of this draft is not to describe methods for alternative
LSP setups. Fault recovery and service restoration have been
discussed in [5, 10].
HDT provides following features to achieve fault recovery and
restoration:
o HDT provides a unified way of switching different types of data
on backup LSPs.
o Because it allows sharing of an LSP for different types of
services, number of LSPs to be set up for fault recovery and
restoration is minimized.
o It allows transmission of OAM bytes (SONET or non-SONET) from any
end node to another end node on any network. While SONET has
standard methods for link failure detection, such features are
not available in non-SONET networks. In this example, OAM bytes
can be sent on W1-W2 link along with in-band MPLS labels and data
packets. Or, only OAM bytes can be sent using MPLS labels on
desired link(s) to determine link and/or node health.
o Standard OAM bytes can be used to send periodic hello messages to
confirm health of a link. These OAM bytes can be routed on the
network using native packets or MPLS labels, as described in
[section 28]. Protection and link health monitoring is thus not
limited to SONET networks - standard OAM bytes can be used for
any type of network mix.
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37. Security Considerations
The reliability of public SONET/SDH networks depends on well-behaved
traffic that does not disrupt the synchronous data recovery
mechanisms. This protocol relies on SDL and HDLC that has framing
and scrambling options that are used to ensure the distribution of
transmitted data such that SONET/SDH design assumptions are not
likely to be violated. Any further security issues are not addressed
in this document.
38. Acknowledgments
The author would like to sincerely acknowledge reviews & comments by
Enrique J. Hernandez-Valencia (Bell Labs), Bobby Cates (NASA Ames),
Dirceu Cavendish (NEC), Ben Crosby (Alcatel), Tom Moore (ADC
Telecom), Luc Roy (Alidian), Raj Sharma (Luminous), Davide Trivellin
(Overtek), and Necdet Uzun (Auroranetics); and Gary Cochran, Ed
Grivna, Nilam Ruparelia, and Paul Scott (Cypress).
39. Intellectual Property Considerations
Cypress Semiconductor Corporation may own intellectual property on
some of the technologies disclosed in this document. In the event
that Cypress obtains such patent rights, Cypress intends to license
them on reasonable and non-discriminatory terms in accordance with
the intellectual property rights procedures of the IETF standards
process.
Lucent Technologies Inc. may own intellectual property on some of the
technologies discussed and used in this document.
40. Author's Address
Pankaj K Jha
Cypress Semiconductor
3901 N First Street
San Jose, CA 95134
USA
Phone: 408 432 7091
Fax: 408 943 2949
Email: pkj@cypress.com
41. Full Copyright Statement
"Copyright (C) The Internet Society. All Rights Reserved. This
document and translations of it may be copied and furnished to
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others, and derivative works that comment on or otherwise explain it
or assist in its implementation may be prepared, copied, published
and distributed, in whole or in part, without restriction of any
kind, provided that the above copyright notice and this paragraph are
included on all such copies and derivative works. However, this
document itself may not be modified in any way, such as by removing
the copyright notice or references to the Internet Society or other
Internet organizations, except as needed for the purpose of
developing Internet standards in which case the procedures for
copyrights defined in the Internet Standards process must be
followed, or as required to translate it into._
42. References
1. Doshi, B., Dravida, S., Hernandez-Valencia, E., Matragi, W.,
Qureshi, M., Anderson, J., Manchester, J.,"A Simple Data Link
Protocol for High Speed Packet Networks", Bell Labs Technical
Journal, pp. 85-104, Vol.4 No.1, January-March 1999.
2. Anderson, J., Manchester, J., Rodriguez-Moral, A.,
Veeraraghavan, M.,"Protocols and Architectures for IP Optical
Networking", Bell Labs Technical Journal, pp. 105-124, Vol.4
No.1, January - March 1999.
3. Malis, A., Simpson, W., PPP over SONET/SDH, rfc2615, June 1999.
4. Grossman, D., Heinanen, J., Multiprotocol Encapsulation over ATM
Adaptation Layer 5, rfc2684, September 1999.
5. Haskin, D., Krishnan, R., A Method for Setting an Alternative
Label Switched Paths to Handle Fast Reroute, draft-haskin-mpls-
fast-reroute-05.txt, November 2000.
6. Carlson, J., Langner, P., Hernandez-Valencia, E.J., Manchester,
J., PPP over Simple Data Link (SDL) using SONET/SDH with ATM-
like framing, rfc2823.txt, May 2000.
7. Tsiang, D., Suwala, G., The Cisco SRP MAC Layer Protocol,
rfc2892, August 2000.
8. Jones, N., Murton, C., Extending PPP over SONET/SDH with virtual
concatenation, high order and low order payloads, draft-ietf-
pppext-posvcholo-02.txt, June 2000.
9. Wu, Tsong-Ho, Cost-effective Network Solution, IEEE
Communications Magazine, September 1993, pp. 64-73.
10. Sharma, V. et al, Framework for MPLS-based Recovery, draft-ietf-
mpls-recovery-frmwrk-00.txt, September 2000.
11. Rosen, E., MPLS Label Stack Encoding, draft-ietf-mpls-label-
encaps-08.txt, July 2000.
12. Simpson, W., PPP in Frame Relay, rfc1973, June 1996.
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