TICTOC S. Rodrigues
Internet-Draft IDT
Intended status: Informational P. Meyer
Expires: September 5, 2011 Zarlink
K. Lindqvist
Netnod
March 4, 2011
TICTOC Requirement
draft-ietf-tictoc-requirements-01.txt
Abstract
Distribution of high precision time and frequency over the Internet
and special purpose IP networks is becoming more and more needed as
IP networks replace legacy networks and as new applications with need
for frequency and time are developed on the Internet. The IETF
formed the TICTOC working group to address the problem and perform an
analysis on existing solutions and the needs. This document
summarizes application needs, as described and agreed on at an TICTOC
interim meeting held in Paris from June 16 to 18, 2008.
Status of this Memo
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This Internet-Draft will expire on September 5, 2011.
Copyright Notice
Copyright (c) 2011 IETF Trust and the persons identified as the
document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal
Provisions Relating to IETF Documents
(http://trustee.ietf.org/license-info) in effect on the date of
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 3
2. Terminology . . . . . . . . . . . . . . . . . . . . . . . . . 3
3. Applications Requirements . . . . . . . . . . . . . . . . . . 3
3.1. Cellular Backhauling . . . . . . . . . . . . . . . . . . . 3
3.1.1. Cellular Backhauling . . . . . . . . . . . . . . . . . 4
3.1.2. Cellular Backhaul Requirements Summary . . . . . . . . 10
3.2. Circuit Emulation . . . . . . . . . . . . . . . . . . . . 11
3.2.1. Circuit Emulation Requirements . . . . . . . . . . . . 11
3.2.2. Circuit Emulation Requirements Summary . . . . . . . . 12
3.3. Test and Measurement . . . . . . . . . . . . . . . . . . . 12
3.3.1. Test and Measurement Requirements . . . . . . . . . . 14
3.4. Industrial Automation . . . . . . . . . . . . . . . . . . 16
3.4.1. Industrial Automation Requirements . . . . . . . . . . 16
3.5. ToD/ Internet . . . . . . . . . . . . . . . . . . . . . . 17
3.5.1. ToD/Internet Requirements . . . . . . . . . . . . . . 17
3.6. Networking . . . . . . . . . . . . . . . . . . . . . . . . 18
3.6.1. Networking SLA Requirements . . . . . . . . . . . . . 18
3.6.2. Networking CDR Requirements . . . . . . . . . . . . . 19
3.7. Legal Uses of Time . . . . . . . . . . . . . . . . . . . . 20
3.7.1. Legal Uses of Time Requirements . . . . . . . . . . . 20
3.8. Metrology . . . . . . . . . . . . . . . . . . . . . . . . 21
3.8.1. Metrology Requirements . . . . . . . . . . . . . . . . 21
3.9. Sensor Networks . . . . . . . . . . . . . . . . . . . . . 22
3.9.1. Sensors Networks Requirements . . . . . . . . . . . . 23
4. Network Dependencies . . . . . . . . . . . . . . . . . . . . . 23
5. Network Topology . . . . . . . . . . . . . . . . . . . . . . . 24
6. Security Considerations . . . . . . . . . . . . . . . . . . . 24
7. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 25
8. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . 25
9. Informative References . . . . . . . . . . . . . . . . . . . . 25
Appendix A. Existing Time and Frequency Transfer Mechanisms . . . 26
A.1. Radio-based Timing Transfer Methods . . . . . . . . . . . 27
A.2. Dedicated Wire-based Timing Transfer Methods . . . . . . . 27
A.3. Transfer Using Packet Networks . . . . . . . . . . . . . . 28
A.3.1. NTP summary description . . . . . . . . . . . . . . . 29
A.3.2. IEEE1588 summary description . . . . . . . . . . . . . 29
Appendix B. Other Forums Working in this Problem Space . . . . . 30
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . . 31
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1. Introduction
There is an emerging need to distribute highly accurate time and
frequency information over IP and over MPLS packet switched networks
(PSNs). In this draft, the requirements for transporting accurate
time and/or frequency are addressed.
2. Terminology
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 [RFC2119]
3. Applications Requirements
There are many applications that need synchronization. Some
applications only need frequency; for others a combination of
frequency and time of day or phase may be required. At the TICTOC
interim meeting, it was agreed that these applications be grouped
based on what was believed to be common requirements, and where the
requirements where distinct from each other. This section describes
these applications (or groups of applications) that was agreed on at
the TICTOC interim meeting.
3.1. Cellular Backhauling
Within Cellular backhauling, there are several applications that need
to be considered. Some of these applications only require frequency
information, others require time-of-day, and others require phase.
The cellular backhauling applications to be considered are:
o GSM
o Mobile Wimax
o LTE
o UMTS FDD
o UMTS TDD
o CDMA2000
o TD-SCDMA
Conventionally GSM and UMTS FDD base stations obtain this reference
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frequency by locking on to the E1/T1 that links them to the base
station controller. With the replacement of TDM links with Packet
Switched Networks (PSNs) such as Ethernet, IP or MPLS, this simple
method of providing a frequency reference is lost, and frequency
information must be made available in some other way.
The synchronization requirement is derived from the need for the
radio frequencies to be accurate. Radio spectrum is a limited and
valuable commodity that needs to be used as efficiently as possible.
In GSM, transmission frequencies are allocated to a given cellular
base station and its neighbours in such fashion as to ensure that
they do not interfere with each other. If the radio network designer
cannot rely on the accuracy of these frequencies, the spacing between
the frequencies used by neighbouring sites must be increased, with
significant economic consequences.
There is an additional requirement derived from the need for smooth
handover when a mobile station crosses from one cell to another. If
the radio system designer can not guarantee that the preparations
required for handover occur in a few milliseconds, then they must
allow the mobile station to consume frequency resources
simultaneously in both cells in order to avoid service disruption.
The preparations required involve agreement between the mobile and
base stations on the new frequencies and time offsets; these
agreements can be accomplished quickly when the two base stations'
frequency references are the same to a high degree of accuracy.
3.1.1. Cellular Backhauling
The requirements for the "Cellular Backhauling" are depicted in the
following sections.
3.1.1.1. GSM/UMTS FDD
The requirements for the GSM/UMTS FDD are as follows:
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Synchronization Type (e.g. time, frequency or phase): frequency
Frequency stability: 50-250 ppb (1)
Frequency accuracy : 50-250 ppb (1)
Uncalibrated time/time stability:
Uncalibrated time/time accuracy: NA
Stabilization Time : As soon as possible
Jitter on recovered timing signal: Depends on the oscillator stability
Wander on recovered timing signal: Depends on the oscillator stability
What expected network characteristics
(WAN, LAN, MAN, private, public, etc)?:
Does the application require security? (if so, which one:
authentication, encryption, traceability, others): No (2)
Reliability requirements (e.g. fault tolerance):
Traceability to a specific clock, clock quality, path, time:
Holdover requirement:
Cost (consumer, enterprise, carrier):
Auto-configuration (plug and play): No
Manageability (how much effort the operator needs to put in to manage
this application?) - In-band or out-of-band of protocol (MIBs?):
Scale and scalability:
Note (1) This is requirement in the air interface. In practice more
accurate frequency is required at the input. For example OBSAI RP1
defines 16 ppb
Note (2) assumes a private network
3.1.1.2. UMTS TDD
The requirements for the UMTS TDD are as follows:
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Synchronization Type (e.g. time, frequency or phase): phase alignment
Frequency stability: 50-250 ppb (1)
Frequency accuracy : 50-250 ppb (1)
Uncalibrated time/time stability:
Uncalibrated time/time accuracy: The phase alignment of neighbouring
base stations shall be within 2.5us
Stabilization Time : As soon as possible
Jitter on recovered timing signal: Depends on the oscillator stability
Wander on recovered timing signal: Depends on the oscillator stability
What expected network characteristics (WAN, LAN, MAN, private, public,
etc)?:
Does the application require security? (if so, which one:
authentication, encryption, traceability, others): No (2)
Reliability requirements (e.g. fault tolerance):
Traceability to a specific clock, clock quality, path, time:
Holdover requirement:
Cost (consumer, enterprise, carrier):
Auto-configuration (plug and play): No
Manageability (how much effort the operator needs to put in to manage
this application?) - In-band or out-of-band of protocol (MIBs?):
Scale and scalability:
Note (1) This is requirement in the air interface. In practice more
accurate frequency is required at the input. For example OBSAI RP1
defines 16 ppb
Note (2) assumes a private network
3.1.1.3. Mobile Wimax
The requirements for the Mobile Wimax (1) are as follows:
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Synchronization Type (e.g. time, frequency or phase): phase alignment
Frequency stability: 15 ppb
Frequency accuracy : 15 ppb
Uncalibrated time/time stability:
Uncalibrated time/time accuracy: The phase alignment of neighbouring
base stations shall be within 1us
Stabilization Time : As soon as possible
Jitter on recovered timing signal:
Wander on recovered timing signal:
What expected network characteristics (WAN, LAN, MAN, private, public,
etc)?:
Does the application require security? (if so, which one:
authentication, encryption, traceability, others): No (2)
Reliability requirements (e.g. fault tolerance):
Traceability to a specific clock, clock quality, path, time:
Holdover requirement:
Cost (consumer, enterprise, carrier):
Auto-configuration (plug and play): No
Manageability (how much effort the operator needs to put in to manage
this application?) - In-band or out-of-band of protocol (MIBs?):
Scale and scalability:
Note (1) 1024 OFDM carriers, BW 10 MHz, Cyclic prefix ratio 1:8, RF
carrier 3.5 GHz
Note (2) assumes a private network
3.1.1.4. LTE
The requirements for the LTE are as follows:
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Synchronization Type (e.g. time, frequency or phase): phase alignment
Frequency stability: 50-250 ppb (1)
Frequency accuracy : 50-250 ppb (1)
Uncalibrated time/time stability:
Uncalibrated time/time accuracy: From 1us to 50us (2, 3)
Stabilization Time : As soon as possible
Jitter on recovered timing signal: Depends on the oscillator stability
Wander on recovered timing signal: Depends on the oscillator stability
What expected network characteristics (WAN, LAN, MAN, private, public,
etc)?:
Does the application require security? (if so, which one:
authentication, encryption, traceability, others): No (4)
Reliability requirements (e.g. fault tolerance):
Traceability to a specific clock, clock quality, path, time:
Holdover requirement:
Cost (consumer, enterprise, carrier):
Auto-configuration (plug and play): No
Manageability (how much effort the operator needs to put in to manage
this application?) - In-band or out-of-band of protocol (MIBs?):
Scale and scalability:
Note (1) This is requirement in the air interface. In practice more
accurate frequency is required at the input. For example OBSAI RP1
defines 16 ppb
Note (2) : no precise phase accuracy requirements defined in
standard. The actual requirement will depend on implementation and
network scenario.
Note (3) : In general LTE TDD systems may be defined to operate with
10-50 microseconds phase accuracy by making some limitations on the
deployment (e.g. cell range), and radio frame configuration, however
further investigations are required. When no assumption possible,
microsecond or sub-microsecond requirement would apply.
Note (4) assumes a private network
3.1.1.5. CDMA2000
The requirements for the CDMA2000 are as follows:
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Synchronization Type (e.g. time, frequency or phase): phase alignment
Frequency stability: 50-250 ppb (1)
Frequency accuracy : 50-250 ppb (1)
Uncalibrated time/time stability:
Uncalibrated time/time accuracy: The pilot time alignment error should
be less than 3us and shall be less than 10us(compared to system
time)
Stabilization Time : As soon as possible
Jitter on recovered timing signal: Depends on the oscillator stability
Wander on recovered timing signal: Depends on the oscillator stability
What expected network characteristics (WAN, LAN, MAN, private, public,
etc)?:
Does the application require security? (if so, which one:
authentication, encryption, traceability, others): No (2)
Reliability requirements (e.g. fault tolerance):
Traceability to a specific clock, clock quality, path, time: System Time,
synchronous to UTC time (except for leap seconds) and uses the same
time origin as GPS time. (3)
Holdover requirement:
Cost (consumer, enterprise, carrier):
Auto-configuration (plug and play): No
Manageability (how much effort the operator needs to put in to manage
this application?) - In-band or out-of-band of protocol (MIBs?):
Scale and scalability:
Note (1) This is requirement in the air interface. In practice more
accurate frequency is required at the input. For example OBSAI RP1
defines 16 ppb
Note (2) assumes a private network
Note (3) 3GPP2, C.S0010-B version 2.0, 2004
3.1.1.6. TD-SCDMA
The requirements for the TD-SCDMA are as follows:
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Synchronization Type (e.g. time, frequency or phase): phase alignment
Frequency stability: 50-250 ppb (1)
Frequency accuracy : 50-250 ppb (1)
Uncalibrated time/time stability:
Uncalibrated time/time accuracy: The phase alignment of neighbouring
base stations shall be within 3us
Stabilization Time : As soon as possible
Jitter on recovered timing signal: Depends on the oscillator stability
Wander on recovered timing signal: Depends on the oscillator stability
What expected network characteristics (WAN, LAN, MAN, private, public,
etc)?:
Does the application require security? (if so, which one:
authentication, encryption, traceability, others): No (2)
Reliability requirements (e.g. fault tolerance):
Traceability to a specific clock, clock quality, path, time:
Holdover requirement:
Cost (consumer, enterprise, carrier):
Auto-configuration (plug and play): No
Manageability (how much effort the operator needs to put in to manage
this application?) - In-band or out-of-band of protocol (MIBs?):
Scale and scalability:
Note (1) This is requirement in the air interface. In practice more
accurate frequency is required at the input. For example OBSAI RP1
defines 16 ppb
Note (2) assumes a private network
3.1.2. Cellular Backhaul Requirements Summary
Based on the sections above, the following can be summarized for the
cellular backhaul applications. Two families of technologies can be
identified:
o Those only requiring the recovery of an accurate and stable
frequency synchronization signal as a reference for the radio
signal (e.g. GSM, UMTS FDD, LTE FDD). In this case the
requirement ranges between 15 ppb (Wimax) and 250 ppb (UMTS Home
Base Stations). This requirement is applicable on the air
interface. In practice more accurate frequency on the long term
is required at the input of the Base Stations (e.g. 16 ppb might
be required for applications operating with 50 ppb)
o Mobile technologies that in addition to frequency synchronization,
also need phase synchronization. This is the case for the TDD
technologies such as UMTS TDD. The requirement in this case
ranges between 2.5 microseconds (phase error between Base
Stations) to several tens of microseconds that could be sufficient
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for some LTE TDD configurations. There is also a case (CDMA2000)
that in addition to phase synchronization also requires the
distribution of accurate time of day (3 microseconds max error
during normal operation).
3.2. Circuit Emulation
The PWE3 WG has produced three techniques for emulating traditional
low-rate (E1, T1, E3, T3) TDM services over PSNs, namely SAToP
[RFC4553], CESoPSN [RFC5086], and TDMoIP [RFC5087]. The Network
Synchronization reference model and deployment scenarios for
emulation of TDM services have been described in [RFC4197], Section
4.3. The major technical challenge for TDM pseudowires is the
accuracy of its clock recovery.
TDM network standards for timing accuracy and stability are extremely
demanding. These requirements are not capriciously dictated by
standards bodies, rather they are critical to the proper functioning
of a high-speed TDM network. Consider a TDM receiver utilizing its
own clock when converting the physical signal back into a bit-stream.
If the receive clock runs at precisely the same rate as the source
clock, then the receiver need only determine the optimal sampling
phase. However, with any mismatch of clock rates, no matter how
small, bit slips will eventually occur. For example, if the receive
clock is slower than the source clock by one part per million (ppm),
then the receiver will output 999,999 bits for every 1,000,000 bits
sent, thus deleting one bit. Similarly, if the receive clock is
faster than the source clock by one part per billion (ppb), the
receiver will insert a spurious bit every billion bits. One bit slip
every million bits may seem acceptable at first glance, but
translates to a catastrophic two errors per second for a 2 Mb/s E1
signal. ITU-T recommendations permit a few bit slips per day for a
low-rate 64 kb/s channel, but strive to prohibit bit slips entirely
for higher-rate TDM signals.
3.2.1. Circuit Emulation Requirements
The requirements for the Circuit Emulation are as follows:
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Synchronization Type (e.g. time, frequency or phase): frequency
Frequency stability: NA
Frequency accuracy : NA
Uncalibrated time/time stability: NA
Uncalibrated time/time accuracy: NA
Stabilization Time :
Jitter on recovered timing signal: G.8261/G.823/G.824
Wander on recovered timing signal: G.8261/G.823/G.824
What expected network characteristics (WAN, LAN, MAN, private, public,
etc)?:
Does the application require security? (if so, which one:
authentication, encryption, traceability, others): No
Reliability requirements (e.g. fault tolerance): NA
Traceability to a specific clock, clock quality, path, time:
Holdover requirement: Yes
Cost (consumer, enterprise, carrier):
Auto-configuration (plug and play): No
Manageability (how much effort the operator needs to put in to manage
this application?) - In-band or out-of-band of protocol (MIBs?):
Scale and scalability:
3.2.2. Circuit Emulation Requirements Summary
The Circuit Emulation application requires the receiver to recover
the same long term frequency accuracy as the original TDM signal.
The phase noise (jitter and wander) of the recovered signal has to be
limited according to the relevant ITU-T recommendation (e.g. G.823).
There are no requirements on phase or time synchronization in this
case.
3.3. Test and Measurement
Note: The application information and the requirements for this
section was provided by the LXI Consortium Technical Committee.
In the test and measurement sector there is a desire to move from
special purpose communications infrastructure with calibrated wiring
run back to a centralize controller, to a distributed system, in
which instructions are distributed in advance to be executed at a
predetermined time, and in which measurements are taken remotely and
communicated back to a common point for later correlation and
analysis.
Test and Measurement (T&M) is a very diverse industry and as would be
expected, requirements vary widely with the application. However the
vast majority of the newer instruments and systems make use of LAN
technology and many have a connection to the local enterprise network
for data transfer, or monitoring and control.
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Because of the increasingly heavy use of LAN technology in T&M
instruments and systems, we are dependent on the availability of
network infrastructure, e.g. bridges, and low level silicon, e.g.
PHYs and PHY/MAC, that supports not only T&M connectivity (data
transport) but increasingly timing and frequency transfer support as
well.
Furthermore T&M is going to require this support not only for the
existing 10/100/1000 BaseT technology but on the newer high
throughput LAN technology under development. While most instruments
produce data at modest rates, many can source or sink data at rates
well in excess of 40Gsamples/s. In addition, the time and phase
coherence requirements on the data transport, e.g. LAN, typically
are tighter on the high data rate instruments.
The other major headache in the use of LAN in T&M is latency and
jitter because it compromises the determinism needed for some
applications. One of the promises of LAN-based precise time is that
in many circumstances precise time can be used to overcome latency
issues. For example, for many data acquisition applications the
ability to precisely and accurately timestamp data at the collection
point makes LAN latency and jitter a non-issue.
Many T&M applications are localized, often to a bench or rack of
equipment. The LAN will be local and private although there is often
a connection to the local enterprise network. It is not uncommon in
such applications to include a rubidium oscillator to provide a
phase-coherent stable frequency source to critical instrumentation
such as counters, scopes, signal generators and analyzers. In many
cases the LAN, in principle, could fill the frequency distribution
role if the LAN technology supported it. In these systems time
transfer is becoming important first for timestamping data to
facilitate data management and post acquisition processing, and in
some cases as part of the control structure. The precise time
specifications vary from milliseconds for general applications to
nanoseconds for the most critical.
There is an important class of applications where time, and sometimes
frequency traceable to international standards is required, generally
due to regulatory issues, e.g. testing of medical, safety critical or
military devices. The ability to deliver traceable time and
frequency over the network to the enterprise would be a big help in
these applications.
There are also T&M applications that are widely distributed due to
the nature of the device or system being measured. Environmental
measurement systems, surveillance, SCADA systems, and the
telecommunication system itself are examples. Timestamping data is
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an essential requirement to overcome the communication latency and
jitter issues. The specific timing requirements clearly cover a wide
range. Environmental and SCADA is typically a ms. However to really
instrument a telecom system will require timing at least on the order
of a packet length or better. Even more extreme are timing for RF
test ranges (which can cover several miles), long-baseline
interferometry, and RF surveillance where the time accuracy must be
on the order of ns. In some cases public networks will be used if
the time distribution is adequate.
3.3.1. Test and Measurement Requirements
The requirements for the Test and Measurement are summarized in this
section. Where appropriate both the low and high end of the
requirements spectrum are given to illustrate the breadth of
requirements for the application areas discussed. Note that
typically the applications with the most demanding requirements are
also the high dollar value applications and in many cases the most
critical in terms of the cost of failure, e.g. failure of a
surveillance system, monitoring of telecommunications, military test
systems where either the operational cost of downtime or the cost of
the device being tested is high.
The requirements for the Test and Measurement are as follows:
Synchronization Type (e.g. time, frequency or phase): Time: ms to ns -
high value applications will open up as this spec improves.
Frequency: part in 10^9 minimum, 10^11 desirable and with the
lowest phase noise obtainable for critical applications.
Frequency stability: When applicable (high end RF) the lowest phase
noise possible in the short term, long term consistent with
accuracy and calibration intervals- better than 1
ppm/year desirable.
Frequency accuracy : Generally consistency across the system is
more important than absolute accuracy. For calibration
applications at least 1ppm.
Uncalibrated time/time stability: Short term from fractional
ms to ns or better. Long term comparable to GPS
distributed time .
Uncalibrated time/time accuracy: Usually self-consistency
requirements are tighter: ms to ns system wide.
Absolute accuracy (traceable) is probably ms to 100 ns.
Stabilization Time : Not usually important. Many times critical
instruments themselves need minutes to hours to stabilize.
However stabilization times greater than a few minutes will
reduce the number of practical wide-area applications.
Jitter on recovered timing signal: In the most critical applications,
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the lowest phase noise achievable, in terms of TIE less than
the stability requirement.
Wander on recovered timing signal: Modest for most measurements.
For surveillance, long baseline, and similar less than the
required stability over the duration of the test.
What expected network characteristics (WAN, LAN, MAN, private, public,
etc)?: Most are private or enterprise LAN. Large scale
applications will benefit from using the public
telecommunications networks.
Does the application require security? (if so, which one:
authentication, encryption, traceability, others): To date
timing security requirements have been rare with the possible
exception of measurement systems with legal requirements.
Data security is more important when the public networks
are involved.
Reliability requirements (e.g. fault tolerance): Has not been an
issue to date in most systems.
Traceability to a specific clock, clock quality, path, time:
Traceability to a path means that if there is on-path support
we want to trace the path. Can also help to avoid time loops.
Traceability is needed to establish NIST traceability. T&M will
expect that public networks solve the timing loop problem. T&M
end systems are typically strictly hierarchical networks without
multiple paths.
Holdover requirement: Has not been an issue to date- but as T&M
increasingly is integrated into operational systems it will
become more important. Telecom requirements are probably
sufficient.
Cost (consumer, enterprise, carrier): In most T&M systems component
cost is very important. In many, operational cost is important.
Auto-configuration (plug and play): Very important. T&M customers to
date would prefer to avoid any network related configuration.
Manageability (how much effort the operator needs to put in to manage
this application?) - In-band or out-of-band of protocol
(MIBs?): As little as possible operator interaction. However
visibility into system performance, including timing, is
very important both operationally and during debug and
commissioning.
Scale and scalability: T&M systems range from small systems with
perhaps 2 or 3 instruments to large scale data acquisition
with thousands of end devices. The physical scale of T&M
systems varies widely from a few instruments on a
bench to a few instruments separated by miles, and from
several thousand instruments and sensors concentrated
on a local device such as a jet engine to several thousand
spread over many miles in environmental monitoring, or
monitoring the telecommunications system. In all cases
it is very common for these systems to grow as
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additional test requirements are imposed so scalability is
important.
3.4. Industrial Automation
In the industrial sector there is a desire to move from special
purpose communications infrastructure with calibrated wiring run back
to a centralize controller, to a distributed system. One example of
this tendency is described below.
In the printing industry there is a need to control operations in
multi-stand printing machines. The paper travels through these
machines at a speed of nearly 100 km/h. At these speeds, co-
ordination error of 1 microsecond between operations taking place at
different positions in the machine produces a 0.03mm color offset,
which is visible to the naked eye and results in an unacceptable
degradation in quality.
3.4.1. Industrial Automation Requirements
The requirements for the Industrial Automation are summarized as
follows.
Synchronization Type (e.g. time, frequency or phase):
Frequency stability:
Frequency accuracy :
Uncalibrated time/time stability:
Uncalibrated time/time accuracy:
Stabilization Time :
Jitter on recovered timing signal:
Wander on recovered timing signal:
What expected network characteristics (WAN, LAN, MAN, private, public,
etc)?:
Does the application require security? (if so, which one:
authentication, encryption, traceability, others):
Reliability requirements (e.g. fault tolerance):
Traceability to a specific clock, clock quality, path, time:
Holdover requirement:
Cost (consumer, enterprise, carrier):
Auto-configuration (plug and play):
Manageability (how much effort the operator needs to put in to manage
this application?) - In-band or out-of-band of protocol (MIBs?):
Scale and scalability:
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3.5. ToD/ Internet
General time distribution over the Internet or IP networks, is often
called Time of Day or Wall-clock. Most existing use cases are using
NTP over the Internet with low precision requirements. However, new
applications are arising that require higher precision rates than
what is currently available.
Internet TOD is important to the maintenance of IT infrastructure in
an organization. Generally the larger an organization becomes, the
more important time synchronization is. Time synchronization is
critical for the following: 1. Server and router log file entry time
tags 2. "Date modified" attributes for files 3. Chron job
scheduling 4. Security protocol with limited time windows for key
exchange.
Server and Router log file time tag accuracy is essential to network
diagnostic tools. Such tools are used to determine the root cause of
a network failure or security breach. Often it is important to
determine the order in which certain events occur amongst a number of
network devices. The "Date modified" fields of files may also be
part of this type of analysis.
Often Chron jobs perform operations on files depending on the times
in the "Date modified" attributes files. These files might reside on
more than one computer or server.
Many security protocols, such as Kerberos, depend on authentication
"tickets" which expire after a short time. This means that an
authenticating server gives a ticket to a client, which the client
can send to another server for some service which requires
authentication. The time limit is intended to reduce the threat of
the "Man in the middle attack." To work the two servers need to have
clocks synchronized to a time error which is smaller than the ticket
time out period. To increase security there is a desire to reduce
the ticket time interval. As the time interval becomes shorter the
need for server clock agreement is increased. The trend over time is
to reduce the ticket time out period.
3.5.1. ToD/Internet Requirements
The requirements for the ToD/Internet are summarized as follows:
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Synchronization Type (e.g. time, frequency or phase): time
Frequency stability: no requirement
Frequency accuracy : no requirement
Uncalibrated time/time stability: no requirement
Uncalibrated time/time accuracy: 10 ms
Stabilization Time : 1 hour
Jitter on recovered timing signal: 100 ms
Wander on recovered timing signal: 10 ms
What expected network characteristics (WAN, LAN, MAN, private, public,
etc)?: All network types
Does the application require security? (if so, which one:
authentication, encryption, traceability, others): Authentication
sometimes used
Reliability requirements (e.g. fault tolerance): high availability.
Clients must see multiple servers
Traceability to a specific clock, clock quality, path, time:
Not important
Holdover requirement: 1 hour to 1 year. Depends on server redundancy
architecture
Cost (consumer, enterprise, carrier): 0 - $10,000 USD (1)
Auto-configuration (plug and play):
Manageability (how much effort the operator needs to put in to manage
this application?) - In-band or out-of-band of protocol (MIBs?):
30-90 minutes to configure a new server, 5 minutes to configure
a new client. Almost no management after initial deployment.
Scale and scalability: system must cover entire IT infrastructure of
organization. Any 1 server will cover 1 building or campus.
(1) The free option implies pointing all clients at ntp servers
available on the public internet.
3.6. Networking
Editor's note: need more info on this application.
3.6.1. Networking SLA Requirements
The requirements for the Networking SLA are summarized as follows:
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Synchronization Type (e.g. time, frequency or phase):
Frequency stability:
Frequency accuracy :
Uncalibrated time/time stability:
Uncalibrated time/time accuracy:
Stabilization Time :
Jitter on recovered timing signal:
Wander on recovered timing signal:
What expected network characteristics (WAN, LAN, MAN, private, public,
etc)?:
Does the application require security? (if so, which one:
authentication, encryption, traceability, others):
Reliability requirements (e.g. fault tolerance):
Traceability to a specific clock, clock quality, path, time:
Holdover requirement:
Cost (consumer, enterprise, carrier):
Auto-configuration (plug and play):
Manageability (how much effort the operator needs to put in to manage
this application?) - In-band or out-of-band of protocol (MIBs?):
Scale and scalability:
3.6.2. Networking CDR Requirements
The requirements for the Network CDR are summarized as follows:
Synchronization Type (e.g. time, frequency or phase):
Frequency stability:
Frequency accuracy :
Uncalibrated time/time stability:
Uncalibrated time/time accuracy:
Stabilization Time :
Jitter on recovered timing signal:
Wander on recovered timing signal:
What expected network characteristics (WAN, LAN, MAN, private, public,
etc)?:
Does the application require security? (if so, which one:
authentication, encryption, traceability, others):
Reliability requirements (e.g. fault tolerance):
Traceability to a specific clock, clock quality, path, time:
Holdover requirement:
Cost (consumer, enterprise, carrier):
Auto-configuration (plug and play):
Manageability (how much effort the operator needs to put in to manage
this application?) - In-band or out-of-band of protocol (MIBs?):
Scale and scalability:
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3.7. Legal Uses of Time
With legal uses of time is meant the cases where high precision wall-
clock is needed, just as in the ToD case, but with where the time
source is traceable to UTC in a secure manner, i.e. through a
certificate chain. It's also important for the legal-time case that
the certificate chain is set-up so that it provides for an audit
trail, where the ToD provided at any given moment can be traced to a
known source or standard (i.e. a national timescale or time
laboratory). One typical application that would benefit from high
accuracy legal time is event correlation in computer systems logs,
and similar applications.
3.7.1. Legal Uses of Time Requirements
There are timing applications for which accuracy and other
characteristics are legally mandated, such as:
o Pay-by-time services (e.g., parking meters, taxicab meters, coin-
operated laundries),
o First-arrival succeeds applications (e.g., races, stock-market
exchanges),
o Devices that require accurate frequency for calibration (e.g.,
police radar, RF broadcast).
For such applications the legal requirements usually dictate both
precision and accuracy, and frequently also traceability and security
considerations. There also may be requirements for keeping of logs
for some amount of time, for certification of correct operation by
qualified personnel, and specification of the national timing
standard to be used.
Due to the large number of disparate applications covered by legal
uses of time, it is not useful to attempt to codify all the possible
requirements in a table, however, the following is a typical subset
of requirements.
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Synchronization Type (e.g. time, frequency or phase): usually time,
some frequency
Frequency stability:
Frequency accuracy : 100 ppm
Uncalibrated time/time stability:
Uncalibrated time/time accuracy: from 10s of ms to better than 1 second
Stabilization Time :
Jitter on recovered timing signal:
Wander on recovered timing signal:
What expected network characteristics (WAN, LAN, MAN, private, public,
etc)?: private well-engineered IP networks, public Internet
Does the application require security? (if so, which one: definitely
authentication, encryption, traceability, others):
Reliability requirements (e.g. fault tolerance): Yes, but not always
specified
Traceability to a specific clock, clock quality, path, time: to national
standard
Holdover requirement:
Cost (consumer, enterprise, carrier):
Auto-configuration (plug and play):
Manageability (how much effort the operator needs to put in to manage
this application?) - In-band or out-of-band of protocol (MIBs?):
Scale and scalability: usually not an issue
3.8. Metrology
Metrology for time and frequency is today mostly using tailored
equipment and cabling for time/frequency transfer when doing
laboratory work. However, in the future, using IP over existing
networks in the laboratories would allow for greater flexibility and
reuse of existing infrastructure rather than building out more
special purpose infrastructure.
3.8.1. Metrology Requirements
We should distinguish between "primary" metrology of time and
frequency performed in national metrology laboratories and some other
timing centers (which deals with highly accurate and stable frequency
standards, typically cesium standards and hydrogen masers and which
ensures synchronization with a nanosecond accuracy) and applied
metrology that mainly calibrates oscillators and clocks used as
"secondary" standards in research organizations and industry. The
use of time and frequency transfer in packet networks is limited in
"primary" metrology, as it operates with frequency accuracy and
stability in the order of 1e-14 and better and time accuracy in
nanoseconds (1 ns represents 1 foot of the light path in vacuum). In
turn, time and frequency transfer through packet networks is quite
challenging for applied metrology - it can profit from any
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improvement of transfer accuracy, therefore the values in table 8
should be considered as minimum target values. Whenever possible,
accuracy of distributed time should be better then time accuracy
provided by a GPS receiver. Short distance application (over LAN)
usually require better accuracy than long distance application using
WAN.
Note: some applications might belong into both metrology and
measurement application groups.
The requirements for the Metrology are summarized as follows:
Synchronization Type (e.g. time, frequency or phase): Time and
frequency
Frequency stability: 1 ppb, lowest possible phase noise
Frequency accuracy : 1 ppb
Uncalibrated time/time stability: Lowest possible phase noise
Uncalibrated time/time accuracy: 1 us
Stabilization Time : Not important, 1 hour is acceptable
Jitter on recovered timing signal: 1 us
Wander on recovered timing signal: 1 us
What expected network characteristics (WAN, LAN, MAN, private,
public, etc)?: Any that can offer required parameters
Does the application require security? (if so, which one:
authentication, encryption, traceability, others):
Authentication is required when public networks are used
Reliability requirements (e.g. fault tolerance): Low fault
tolerance, user should know whether expected parameters
were assured or not
Traceability to a specific clock, clock quality, path, time: Very
important
Holdover requirement:
Cost (consumer, enterprise, carrier): Cost should correspond with
provided parameters
Auto-configuration (plug and play): Important at client side
Manageability (how much effort the operator needs to put in to
manage this application?) - In-band or out-of-band of
protocol (MIBs?): Both provider and customer should accept
network related configuration, long distribution path might
require calibration
Scale and scalability:
3.9. Sensor Networks
More generally, there is growing interest in clock synchronization in
massively parallel sensor networks. Advances in wireless
communications have enabled the development of low power miniature
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sensors that collect and disseminate data from their immediate
environment. Although each sensor has limited processing power,
through distributed processing the network becomes capable of
performing various tasks of data fusion, but only assuming a common
time base can be established.
3.9.1. Sensors Networks Requirements
The requirements for the Sensor are summarized as follows.
Synchronization Type (e.g. time, frequency or phase): time
Frequency stability: 1%
Frequency accuracy : 1000ppm
Uncalibrated time/time stability: 1 part per hundred
Uncalibrated time/time accuracy: 1 second
Stabilization Time : intermediate
Jitter on recovered timing signal: several seconds up to 1 milliHz
Wander on recovered timing signal: less than one second above 1 milliHz
What expected network characteristics (WAN, LAN, MAN, private, public,
etc)?: distributed hop-to-hop network
Does the application require security? (if so, which one:
authentication, encryption, traceability, others): authentication,
encryption
Reliability requirements (e.g. fault tolerance): intermediate
Traceability to a specific clock, clock quality, path, time: one master
Holdover requirement: 1% wander per 10 days
Cost (consumer, enterprise, carrier): depends on application, from very
low to intermediate
Auto-configuration (plug and play): strong requirement as there are
many sensors
Manageability (how much effort the operator needs to put in to manage
this application?) - In-band or out-of-band of protocol
(MIBs?): in-band, self organizing, little to no storage on device
Scale and scalability: must scale to 1000s of intercommunicating sensors
4. Network Dependencies
When using packet networks to transfer timing, packet delay
variation, propagation asymmetry, and maximum permissible packet rate
all have a significant bearing on the accuracy with which the client
is able to determine absolute time. Thus the network environment has
a large bearing on the quality of time that can be delivered.
Timing distribution is highly sensitive to packet delay variation,
and thus can deteriorate under congestion conditions. Furthermore
the disciplining of the client's oscillator (the sole component of
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frequency transfer, and a critical component of time transfer) is a
function that should not be disrupted. When the service is disrupted
the client needs to go into "holdover" mode, and its accuracy will
consequently be degraded. Depending on the relative quality of the
client's clock and the required quality after disciplining, a
relatively high packet rate may be required.
Packet delay variation can to some extent be addressed by traffic
engineering, thus time transfer within a constrained network
environment might reasonably be expected to deliver a higher quality
time service than can be achieved between two arbitrary hosts
connected to the Internet. Greater gains can probably be obtained by
deploying equipment that incorporates IEEE 1588 style on-the-fly
packet timestamp correction (or any other form of on-path support),
or follow-up message mechanisms that report the packet storage and
forward delays to the client. However one can only be sure that such
techniques are available along the entire path in a well-controlled
environment. Therefore, time transfer protocols should not assume
the availability of on path support, but utilizes it where available.
The packet rate between the time-server and its client also has a
bearing on the quality of the time transfer, because at a higher rate
the smart filter has a better chance of extracting the "good"
packets. How the packet rate relates to the accuracy is dependent on
the filter algorithm in use. In a controlled environment it is
possible to ensure that there is adequate bandwidth, and that the
server is not overloaded. In such an environment the onus moves from
protecting the server from overload, to ensuring that the server can
satisfy the needs of all of the clients.
Congested and overloaded paths might influence the quality of timing
transfer. In a constrained network environment, it's assumed that a
service provider will ensure that packet delivery is done in
according to the timing transfer needs of the network operator.
5. Network Topology
Editor's note: This section needs to be discussed.
6. Security Considerations
Time and frequency services are a significant element of network
infrastructure, and are critical for certain emerging applications.
Hence time and frequency transfer services MUST be protected from
being compromised, and for some of the applications described above
such as legal time, the ability to provide and audit trail to the
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timing source. One possible threat is a false time or frequency
server being accepted instead of a true one, thus enabling an
attacker to alter the time and frequency service provided. Other
possible scenarios are to be able to distinguish between trusted
clients and non-trusted clients when providing service.
Any protection mechanism must be designed in such a way that it does
not degrade the quality of the time transfer. Such a mechanism
SHOULD also be relatively lightweight, as client restrictions often
dictate a low processing and memory footprint, and because the server
may have extensive fan-out.
The following authentication mechanisms need to be considered:
1. of server by client (depending on the application)
2. of client by server (depending on the application)
3. transactions (depending on the application)
7. IANA Considerations
No IANA actions are required as a result of the publication of this
document.
8. Acknowledgements
The authors wish to thank Stewart Bryant, Yaakov Stein, Karen
O'Donoghue, Laurent Montini, Antti Pietilainen, Stefano Ruffini,
Vladimir Smotlacha, Greg Dowd, Doug Arnold and the LXI Consortium
Technical Committee for input on this draft.
9. Informative References
[1588] IEEE, "1588-2008 Standard for A Precision Clock
Synchronization Protocol for Networked Measurement and
Control Systems".
[G8261] ITU-T, "Recommendation G.8261/Y.1361 - Timing and
synchronization aspects in packet networks", April 2008.
[G8262] ITU-T, "Recommendation G.8262/Y.1362 - Timing
Characteristics of Synchronous Ethernet Equipment Slave
Clock (EEC)", July 2010.
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[G8264] ITU-T, "Recommendation G.8264/Y.1364 - Distribution of
timing through packet networks", 2008.
[RFC1305] Mills, D., "Network Time Protocol (Version 3)
Specification, Implementation", RFC 1305, March 1992.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC4197] Riegel, M., "Requirements for Edge-to-Edge Emulation of
Time Division Multiplexed (TDM) Circuits over Packet
Switching Networks", RFC 4197, October 2005.
[RFC4553] Vainshtein, A. and YJ. Stein, "Structure-Agnostic Time
Division Multiplexing (TDM) over Packet (SAToP)",
RFC 4553, June 2006.
[RFC5086] Vainshtein, A., Sasson, I., Metz, E., Frost, T., and P.
Pate, "Structure-Aware Time Division Multiplexed (TDM)
Circuit Emulation Service over Packet Switched Network
(CESoPSN)", RFC 5086, December 2007.
[RFC5087] Stein, Y(J)., Shashoua, R., Insler, R., and M. Anavi,
"Time Division Multiplexing over IP (TDMoIP)", RFC 5087,
December 2007.
Appendix A. Existing Time and Frequency Transfer Mechanisms
In this section we will discuss existing mechanisms for transfer of
time information, frequency information, or both. It should be noted
that a sufficiently accurate time transfer service may be used to
derive an accurate frequency transfer. Indeed, this is exactly what
happens in a GPS disciplined frequency standard. On the other hand,
an accurate frequency transfer service, while itself unable to
transfer absolute time, is usually used to support and improve the
performance of the time transfer service. Indeed, implementations of
NTP or IEEE 1588 clients can be considered to consist of two phases.
First, a local oscillator is locked to the server's frequency using
incoming information from the incoming packets, and then the local
time set based on the server's time and the propagation latency. By
maintaining a local frequency source, the client requires relatively
infrequent updates, and can continue functioning during short periods
of network outage. Moreover, it can be shown that this method
results in significantly better time transfer accuracy than methods
that do not discipline a local clock.
Time transfer mechanisms can be divided into three classes. The
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first class consists of mechanisms that use radio frequency
transport, while the second mechanism uses dedicated "wires" (which
for our purposes include optical fibers). The third, which will be
our main focus, exploits a Packet Switched Network for transfer of
timing information. Advantages and disadvantages of these three
methods are discussed in the following subsections.
A.1. Radio-based Timing Transfer Methods
The transfer of time by radio transmission is one of the oldest
methods available, and is still the most accurate wide area method.
In particular, there are two navigation systems in wide use that can
be used for time transfer, The LOng RAnge Navigation (LORAN)
terrestrial radio system, and the Global Navigation Satellite System
(GNSS). In both cases the user needs to be able to receive the
transmitted signal, requiring access to a suitable antenna. In
certain situations, e.g. basement communications rooms and urban
canyons, the required signal may not be receivable.
Radio systems have high accuracy, far better than what we will later
see can be achieved by existing PSN technologies. However coverage
is limited; eLORAN for example only covers North America, and GPS
does not have good coverage near the poles.
Although civilian use is sanctioned, the GPS was developed and is
operated by the U.S. Department of Defense as a military system. For
this reason there are political concerns that rules out its use in
certain countries. The European Union is working on an alternative
system called Galileo, which will be run as a commercial enterprise.
In addition, GPS has some well-documented multi-hour outages, and is
considered vulnerable to jamming. One major PTT also reports that
they see a 2% per year failure rate for the antenna/receiver/
clock-out chain.
While a radio-based timing service may be acceptable for some sites,
it is frequently impractical to use on a per equipment basis. Hence,
some form of local timing distribution is usually also required.
A.2. Dedicated Wire-based Timing Transfer Methods
The use of dedicated networks in the wide area does not scale well.
Such services were available in the past, but for reasons of cost and
accuracy have been superseded by GPS based solutions.
In the local area, one new technique is emerging as a mechanism for
time transport, namely DOCSIS Timing Interface(DTI). DTI was
designed by DOCSIS for the distribution of time in a cable head-end
in support of media access control. Time transfer is packet-based
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over a multi-stage hub and spoke dedicated network. It uses a single
twisted-pair in half-duplex to eliminate inaccuracies due to the
length differences between the pairs in a multi-pair cable.
The DTI approach is applicable for special applications, but the need
for a dedicated network imposes significant drawbacks for the general
time transfer case.
Synchronous Ethernet is a technique that has recently been approved
by ITU-T, it provides frequency distribution over Ethernet links.
Modern dedicated-media full-duplex Ethernet, in both copper and
optical physical layer variants, transmits continuously. One can
thus elect to derive the physical layer transmitter clock from a high
quality frequency reference, instead of the conventional 100 ppm
crystal-derived transmitter rate. The receiver at the other end of
the link automatically locks onto the physical layer clock of the
received signal, and thus itself gain access to a highly accurate and
stable frequency reference. Then, in TDM fashion, this receiver
could lock the transmission clock of its other ports to this
frequency reference. Apart from some necessary higher layer packet
based configuration and OAM operations to transport synchronization
status messaging, the solution is entirely physical layer, and has no
impact on higher layers.
At first sight it would seem that the only application of Synchronous
Ethernet was in frequency transfer (it has no intrinsic time transfer
mechanism). However, the quality of packet-based time transfer
mechanism can be considerably enhanced if used in conjunction with
Synchronous Ethernet as a frequency reference.
A.3. Transfer Using Packet Networks
When using a PSN to transfer timing, a server sends timing
information in the form of packets to one or multiple clients. When
there are multiple clients, the timing packets may be multicast.
Software/hardware in the client recovers the frequency and/or time of
the server based on the packet arrival time and the packet contents.
There are two well-known protocols capable of running over a general-
purpose packet network, NTP [RFC1305], and IEEE 1588 [1588]. NTP is
the product of the IETF, and is currently undergoing revision to
version 4. PTP (a product of the IEEE Test and Measurement
community) is specified in a limited first version (1588-2002), and
the second version (1588-2008)was approved recently.
It is important that NTP, IEEE-1588 or any other future packet based
time transfer mechanism do not break each other if they run in the
same network.
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A.3.1. NTP summary description
NTP is widely deployed, but existing implementations deliver accuracy
on the order of 10 milliseconds. This accuracy is not adequate for
the applications described above. Current NTP suffers from the fact
that it was designed to operate over the Internet, and the routers
and switches make no special concessions to NTP for preservation of
time transfer accuracy. Furthermore, typical update rates are low
and can not be significantly increased due to scalability issues in
the server. In addition most NTP time servers and time receivers
have a relatively unsophisticated implementation that further
degrades the final time quality. However, proprietary NTP
implementations that use other algorithms and update-rates have
proved that NTP packet formats can be used for higher accuracy.
A.3.2. IEEE1588 summary description
The information exchange component of IEEE 1588 is a protocol known
as Precision Time Protocol (PTP). PTP version 1 (1588-2002) was a
time transfer protocol that exclusively used multicast technique and
it was primarily developed for Industrial Automation and Test and
Measurement applications. It is widely anticipated that wide scale
deployment of PTP will be based on PTP version 2 (1588-2008).
IEEE Std 1588-2008 can be considered to consist of several
components:
1. A configuration and control protocol
2. A time transfer protocol
3. A time correction protocol
4. Physical mapping
The configuration and control protocol is based on the multicast
approach of IEEE Std 1588-2002 (multicast IP with recommended TTL=1,
UDP, PTP payload with equipment identifier in the payload). The
rationale for this approach was that the equipment needed to be "plug
and play" (no configuration), was required to map to physical media
other than Ethernet, and had to have a very low memory and processor
footprint. IEEE Std 1588-2008 includes Unicast messages.
The time transfer protocol is a standard two-way time transfer
approach used in other packet-based approaches. Like all such
approaches it is subject to inaccuracies due to variable store and
forward delays in the packet switches, and due to the assumption of
symmetric propagation delays. For IEEE Std 1588-2008, the time
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transfer packets (in both directions) may be operated in a multicast
or unicast mode.
The time correction protocol is used to correct for propagation,
store and forward delays in the packet switches. This again may be
operated multicast or unicast. This mechanism requires some level of
hop-by-hop hardware support. This mechanism may also be considered a
concept in its own right and may be adapted to enhance other packet
time transfer protocols such as NTP.
The IEEE Std 1588-2008 specification describes how the PTP operates
over the Ethernet/IP/UDP protocol stack. It includes annexes that
describe PTP operation over pure layer 2 Ethernet, and over a number
of specialist media.
The mappings of interest for telecommunications are PTP over UDP/IP,
PTP over MPLS , and perhaps PTP over Ethernet. They may operate in
unicast or multicast. Issues of a suitable control management and
OAM environment for these applications are largely in abeyance, as
are considerations about the exact nature of the network environment.
It is also worth noting the existence of a second IEEE effort, IEEE
802.1AS. This group is specifying the protocol and procedures to
ensure synchronization across Bridged and Virtual Bridged Local Area
Networks for time sensitive applications such as audio and video.
For these LAN media the transmission delays are assumed to be fixed
and symmetrical. IEEE 802.1AS specifies the use of IEEE 1588
specifications where applicable in the context of IEEE Standards
802.1D and 802.1Q. Synchronization to an externally provided timing
signal (e.g., a recognized timing standard such as UTC or TAI) is not
part of this standard but is not precluded. IEEE 802.1AS will
specify how stations attached to bridged LANs to meet the respective
jitter, wander, and time synchronization requirements for time-
sensitive applications.
Appendix B. Other Forums Working in this Problem Space
The NTP WG is the IETF group working on time distribution, but is
presently only documenting NTPv4 and is not working on new algorithms
or protocols. It is expected that many participants of the NTP WG
will participate in the TICTOC effort.
The PWE3 WG has discussed frequency distribution for the TDM PW
application, however it is not chartered to develop protocols for
this purpose. It is expected that participants of the PWE3 WG who
were active in the TDM PW discussions will participate in the TICTOC
effort.
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The IEEE approved the version 2 of the IEEE 1588 protocol (IEEE Std
1588- 2008) that will run over more types of PSNs. The protocol to
be specified contains elements that will be of use in an IETF
environment, but is unlikely to be regarded as being a complete,
robust solution in such an environment. If the IEEE 1588 structure
is deemed to be a suitable platform, then the IETF could contribute
an Internet profile, including a complete distributed systems
environment suitable for our purposes. Alternatively, the IETF could
perhaps borrow some of the delay correction mechanisms and
incorporate them into a development of a new version of NTP.
In addition, IEEE 802.1AS is working on Timing and Synchronization
for Time-Sensitive Applications in Bridged Local Area Networks,
basing itself on the IEEE 1588 standard.
ITU-T SG15 Question 13 has produced Recommendation G.8261 "Timing and
synchronization aspects in packet networks" [G8261]. This
Recommendation defines requirements for various scenarios, outlines
the functionality of frequency distribution elements, and provides
measurement guidelines. It does not specify algorithms to be used
for attaining the performance needed. ITU-T has also consented
G.8262 "Timing Characteristics of Synchronous Ethernet Equipment
Slave Clock (EEC)" [G8262], and G.8264 "Distribution of timing
through packet networks" [G8264]. G.8262 specifies the requirements
for Synchronous Ethernet clocks and G.8264 defines the protocol for
Synchronization Status Message (SSM) for Synchronous Ethernet. To
date the ITU-T has focused on Ethernet infrastructure, but this is
likely to extend to an MPLS environment. Two new work items,
G.paclock.bis and G.pacmod.bis extend the work, and in particular,
G.pacmod.bis intends to introduce time transfer. The scope for
G.paclock.bis is to define the requirements for packet-based clocks.
This is an area where the IETF, with its expertise in IP and MPLS
networks, may co-operate with the ITU.
Authors' Addresses
Silvana Rodrigues
IDT
603 March Road
Ottawa K2K 2M5
Canada
Phone: +1 613 592-0714
Email: silvana.rodrigues@idt.com
Rodrigues, et al. Expires September 5, 2011 [Page 31]
Internet-Draft TICTOC March 2011
Peter Meyer
Zarlink
400 March Road
Ottawa K2K 3H4
Canada
Phone: +1 613 592-0200
Email: Peter.Meyer@zarlink.com
Kurti Erik Lindqvist
Netnod
Bellmansgatan 30
Stockholm S-118 47
Sweden
Phone: +46 708 30 60 01
Email: kurtis@kurtis.pp.se
Rodrigues, et al. Expires September 5, 2011 [Page 32]