7. Time, Time Scales & Dates
• There are Two meanings of the word time:
- The date of an event on a time scale
- As a time interval between two events
• Time scales :
- A time scale is defined by :
A time unit
A time origin
• Dates :
A date is a number of units on the time scale
3
8. The Second
• The second is the time unit of the International
System of Units (SI)
• It just so happens that the second is relative to that of
Caesium atom transition
• This means that modern time accuracy is based
around time derived from a Caesium device
• This is commonly known as an Atomic Clock
4
9. Clocks
• A clock consists of:
- A period which can be observed e.g. Secs, Mins & Hrs
- A counter which counts the number of periods
- A means for setting the counter to a preset value
- A display of the registered count
u(t) n(t) T(t)
Oscillator Counter Display
N0 start
5
10. Atomic Time Scales
• Origin of Atomic Time Scales :
1 January 1958, at 0hr 0min 0sec - UT2
• International Atomic Time (TAI) :
Based on atomic time scales and implemented by a network of
atomic clocks located all over the earth and operated by the Bureau
International de l’Heure (BIH) in Paris
• Coordinated Universal Time (UTC) :
Timescale based on the time unit of TAI, transmitted on air from the
GPS system
• In 1967 a new SI definition of a second was created based on the
radiation from the caesium-133 atom
• It is correctly defined as "the duration of 9,192,631,770 periods of the
radiation corresponding to the transition between two hyperfine
levels of the ground state of the caesium-133 atom"
6
11. BIPM
• The International Bureau of Weights and Measures
(Bureau International des Poids et Mesures)
• The realization and dissemination of the international time scales is the responsibility of the Time
Section of the BIPM. International Atomic Time (TAI) is the uniform time scale; it is kept as close as
possible to the second of the SI. Coordinated Universal Time (UTC) is an atomic time scale derived
from TAI, to provide a reference scale in step with the irregular rotation of the earth
• Local realizations of UTC exist at the national time laboratories. These laboratories participate in the
calculation of the international time scales by sending their clock data to the BIPM. Most of them are
equipped with commercial caesium beams that provide a practical realization of the second sufficiently
accurate for most applications. More accurate caesium standards exist in a small number of
laboratories; for them, the uncertainties are estimated to be a few parts in 1015. New developments in
clocks using trapped or cooled atoms or ions are leading to improvements well beyond this
• The atomic time scales TAI and UTC are disseminated monthly through the BIPM Circular T. The
Annual Report of the BIPM Time Section provides all relevant information, data and results for the year
previous to its publication. Reports on time-transfer techniques are also issued regularly
• Other activities related to the time scales are developed in the section; these contribute to improving
the calculation algorithms and increasing knowledge about time transfer techniques
7
12. Frequency
Definition:
• the number of occurrences within a given time period
Unit:
• Frequency is expressed in [ Hertz = 1cycle/second ]
1
amplitude 0
1
0 1x10-7 2x10-7 3x10-7 4x10-7 5x10-7 6x10-7
time
8
13. Phase
• Phase is the difference in time relationship between two
same frequency waveforms
• It is usually measured in degrees
• It can be a comparison with an earlier instance of the same
waveform - known as Differential Phase
90°
180° 360°
0°
270°
90 °Phase
Shift 270°Differential Phase Shift
9
14. Round Up
• What are the 2 main time standards?
• What is periodic value of a Caesium
atom?
• What are the 3 main components of a
clock?
• What unit is frequency expressed as?
10
17. What is Synchronisation ?
Definition of Synchronisation
• The timing of all nodes within digital networks to a
common highly accurate and stable clocking source
• To ensure they all use the same data rates to transmit
and receive information
3
18. Why do we need Synchronisation ?
• If synchronisation is not used node clocks operate
asynchronously and the their transmit and receive data
rates would be different.
• This would cause slips or pointer adjustments to occur
frequently, seriously degrading the quality of services
transported by the network
4
19. Types of Synchronisation
3 types of Synchronisation:
1 - Frequency synchronisation
2 - Phase synchronisation
3 - Time synchronisation
5
21. Frequency Synchronisation
• Transmission data is ‘loaded’ and ‘recovered’ from transmission lines
by data processing circuits
• These use a clock edge to denote the transition of one bit to the next
Transmission Link
Data Data
Data
Clock 1 Clock 2
If Clock 1 & 2 are at different speeds then slips
between equipments will occur at the input buffers
7
22. Frequency Sync – Too Fast
Transmission Link
Data Data
Data
Clock 1 Clock 2
• If the frequency of Clock 1 is higher than that of
Clock 2 -
– Data will be clocked into the transmission link at a higher rate than it is
clocked out
– The result will be that data is lost at the receiving end
8
23. Frequency Sync - Too Slow
Transmission Link
Data Data
Data
Clock 1 Clock 2
• If the frequency of Clock 1 is lower than that of
Clock 2 -
– Data will be clocked into the transmission link at a lower rate than it is
clocked out
– The result will be that data is lost at the receiving end
9
24. Phase Synchronisation
System A System B
Clock signal
of system A
t
Clock signal
of system B
t
10
25. Time synchronisation
System A System B
Time signal of system A
14/01/00 14/01/00 14/01/00
08:34:55 08:34:56 08:34:57
t
Time signal of system B
14/01/00 14/01/00 14/01/00
08:34:55 08:34:56 08:34:57
t
11
26. N'wks/Services that require Sync
• Public Switched Telephone Networks
• SONET and SDH transport networks
• Cellular mobile telecom networks - GSM, UMTS etc
• Location Services over Mobile Networks - E911, GSM
03.71, etc
• Ground stations of satellite networks
• Digital Audio Broadcasting (DAB)
• Digital Video Broadcasting (DVB)
• Time distribution for charging & event time stamping
• Next Generation Networks – Wi-Max, MPLS
12
27. Slips
• Slips are the main consequence of poor
synchronisation within SDH / SONET
networks
• Slips can have a detrimental effect on
quality of service
13
28. What Are Slips ?
• A slip occurs when an equipment input buffer
over or underflows due to differences in timing
Slip
Incoming data rate
Outgoing data rate
• This results in information being lost
14
29. Mobile Networks – 2G & 3G
Successful handover requires synchronisation
between base transceiver stations (BTS)
BTS
BTS BTS
BTS
15
30. Cellular Mobile Telecom Networks
Radio carrier frequencies must be synchronised
precisely in order to prevent cross-talk
Radio spectrum
Frequency
16
31. Effects of Frequency Errors
Slip – PDH Environment
FIFO buffer overflows and dumps its contents
Pointer Adjustment – SDH Environment
2Mbit/s transmission VC12 pointer adjustments cause
phase hits of 3.47µs 34 & 140 Mbit/s transmission
Pointer Movement at SDH-PDH boundaries PDH takes
sync from 2 Mbit/s and needs excellent phase
performance
Pointer adjustments will create phase hits
17
32. Services effected by slips
Voice
Uncompressed - only 5% of slips lead to clicks
Compressed - a slip will cause an audible click
Fax
A slip can wipe out several lines
Modem
A slip can cause several seconds of drop out
Compressed video
A slip can wipe out several lines
More slips can freeze frames for several seconds
Encrypted/compressed data protocol
Slips will reduce transmission throughput
Cellular
Dropped calls and poor cell handover
18
33. Implications on Performance
• Poor network synchronisation means that network
performance is not optimized, quality of service is reduced
and customers are lost
• Implementation of synchronisation in network design
enhances Quality of Service for your customers
• Protection of your customers traffic means confidence,
loyalty and ultimately improved business relationships
19
34. Round Up
• So why do we need synchronisation?
• What are the 3 main types of
synchronisation?
• What is a slip?
• What can slips cause?
20
36. Network synchronisation
• The objective of network synchronisation is to ensure that
all the telecommunication systems use the same transmit
and receive data rates to avoid slips
• So the clocks in the telecommunication systems must be
synchronised to the same master network clock, or
synchronised to a number of very closely matched master
clocks
2
37. Distribution Layer function
• To generate a primary reference timing signal
• To distribute timing signals from the primary reference
source to nodes and equipment
• To provide protection against failures in the generation
and distribution of timing
3
39. Master-Slave Mechanism
• The clock is injected into the master unit
• The slave unit locks to the incoming clock
rate and is now synchronised to the master
• No slips occur between these elements
Transmission Link
Data Master
Master Slave
Slave
Data + Clock
PRC 1
5
40. Physical synchronisation network
• Not every system in the network can have a direct
connection to the master network clock
• Therefore the telecommunication systems are
synchronised in chains or trees
• Each system clock is the master clock of the subordinate
system clocks slaved to it
• The slave system continually adjusts its own clock to the
incoming signal
• Therefore both the master and slave systems have the
same transmit and receive rates
• There are no slips (WE HOPE!!!!)
6
41. Clock types
The clock elements of the synchronisation distribution
layer are categorised in three ways:
1. Primary Reference Clock (PRC)
- This is defined by ITU-T recommendation G.811
2. Synchronisation Supply Unit (SSU)
- The purpose of these elements is to provide
filtering and regeneration
- Defined by ITU-T recommendation G.812
3. SDH Equipment Clock (SEC)
- These devices have an internal SDH Equipment
Clock (SEC) that is normally synchronised to a
traffic or an external timing input signal
- Defined by ITU-T recommendation G.813
7
43. Sync Distribution (SD) Trails - 1
• The clock frequency along an SD trail is the SAME as
the head-end, i.e. PRC, SSU or SEC
• SD trails can be very long or very short
• There can be hundreds of SD trails in a synchronisation
network
9
44. Sync Distribution (SD) Trails - 2
• There are several types of SD trails:
– PRC SD trail - when the head-end is a PRC
– SSU SD trail - when the head-end is a SSU
– SEC SD trail - when the head-end is a SEC
• SSU and SEC SD trails are created only when the PRC
SD trail is broken
10
45. Physical synchronisation networknetwork
Physical synchronisation
clock quality clock quality
traceable back traceable back
to the SEC to the SSU
SEC SSU
SEC SD trail PRC SSU SD trail
PRC SD trail clock quality
traceable back
to the PRC
11
46. Slip Rate due to Freq Deviation
For 2 Mbit/s signals, frame duration = 125
microseconds:
– 10-11 = 1 slip in 4.8 months PRC G.811
– 10-10 = 1 slip in 14.5 days SSU G.812
– 10-9 = 1 slip in 1.45 days SSU G.812
– 10-8 = 6.9 slips per day SEC G.813
– 10-7 = 2.9 slips per hour SEC G.813
– 10-6 = 28.8 slips per hour SEC G.813
– 10-5 = 4.8 slips per minute SEC G.813
12
47. Calculating Slip Rates
Normal Calculation for Slip Rates per observation period
is:
Slip Rate = F x T x D
L
F= Frequency Offset
T= Observation Time
D= Data Rate
L= Frame Length
13
48. Calculating Slip Rates – Exercise!
Calculate the Slip Rate for the following conditions:
F= Frequency Offset = 1 x 10E-08
T= Observation Time = 86400 Seconds (1 day)
D= Data Rate = 2.048Mbps x 10E+06
L= Frame Length = 256
What clock quality would this slip rate equal?
14
49. Calculating Slip Rates – Result
The Solution:
F (1x10E-08) x T(86400) x D(2.048x10E+06)
L(256)
= 6.912 or 7 slips per day!
F= Frequency Offset = 1 x 10E-08
T= Observation Time = 86400 Seconds
D= Data Rate = 2.048E+06
L= Frame Length = 256
So 7 slips per day is G.813 or SEC in HOLDOVER
15
50. Sync Distribution (SD) Trails - 3
• The synchronisation distribution trails are not perfect:
what comes out is not exactly what went in
• This is due to:
- Equipment and cables generate jitter and wander
- Excessive jitter or wander causes slips
- Equipment or cables can fail
16
51. Jitter
• Pattern, or pattern-dependent, jitter is sometimes called "flanging". This
type of jitter is not random; it generally results from sub-harmonics
• Viewed in the time domain, this type of jitter appears as multiple modes.
Pattern jitter is deterministic jitter that can be attributed to a unique
source. All other jitter is stochastic (random) in nature
Jitter can be quantitatively expressed in the following ways:
– In unit intervals (UIs). One UI is one cycle of the clock frequency. Jitter
expressed in UIs describes the magnitude of the jitter as a decimal fraction of
one UI
– In degrees. Jitter expressed in degrees describes the magnitude of the jitter in
units of degree for which one cycle equals 360°
– In absolute time. Jitter expressed in units of time describes the magnitude of
the jitter in appropriate orders of magnitude, usually picoseconds.
– As a power measurement in units of radians or unit intervals squared, which
is often expressed in decibels relative to one cycle squared
17
52. Wander
• Because it involves low frequencies for long periods,
wander data can consist of hours of phase information.
• Because phase transients are of importance, high
temporal resolution is also needed. So to provide a
concise measure of synchronisation quality, three wander
parameters have been defined and are used to specify
performance limits:
- TIE Time Interval Error (wander in ns)
- MTIE Maximum Time Interval Error (related to Peak-
to-Peak wander)
- TDEV Time Deviation (related to RMS wander)
18
53. Definition of Jitter
Definition of Jitter : ITU- Rec G.810
• The short term variations of the significant instances of a
digital signal from their reference positions in time
• Greater than 10Hz in modulation frequency
• Jitter is caused by the sync trail equipment
Ideal
Jittered
Sampling (reading) points
19
54. Definition of Wander
• The long term variations of the significant instances of a digital
signal from their reference positions in time
• Less than 10Hz in modulation frequency
• Wander is caused by the interaction of technologies in a network
Ideal
Wander
Sampling points Sampling points
20
55. Main Causes of Jitter/Wander
Jitter/Wander is caused by the sync trail equipment
For Example:
– MUX / Switch equipment PLL
– Poor equipment component quality
– Proximity of components to EMI
– Microprocessor noise
– Equipment Transfer functions
– Length of transmission paths due to cable expansion
and contractions
– Inter-reaction of different technologies e.g. SDH,
PDH, ATM
21
56. PLL Effects on Reference Signals
• PLL can overcompensate and oscillate above and
below the reference
• PLL can under-compensate and take too long to get to
the reference
• Changes in Temperature effect the stability of the
OCXO
• Jitter is generated by granularity (steps) in correction
voltage applied to the OCXO
22
58. Cable Expansion/Contraction
Wc = 80ps/Km/oC, for fibre optical cable
Wc = 725ps/Km/oC, for copper cable
20oC
1010111001010101000001100101000100010
40oC Cable has expanded - the bits come out later
1010111001010101000001100101000100010
0oC Cable has contracted - the bits come out earlier
1010111001010101000001100101000100010
24
59. ITU-T G.823 Model of Wander
• Specifies the maximum network limits for jitter and
wander that should not be exceeded
• Specifies the minimum equipment tolerance to jitter
and wander based on the 2048 kbit/s hierarchy
• The jitter control philosophy is based on the need:
- to recommend a maximum network limit that should not
be exceeded at any hierarchical interface
- to recommend a consistent framework for the
specification of individual digital equipments
- to provide sufficient information and guidelines for
organizations to measure and study jitter accumulation
in any network configuration
25
60. ITU-T G.823 Wander formula
• The maximum relative wander between the slave clock
and the data input at a node is:
Dwpk = WequipPk + WconnectionsPk + < / = 18µs
• The formula allows the planner to calculate the
accumulated Wander by simply adding the sum of each
element within the network
• This total must be less than 18µs to adhere to G.823
26
61. ITU-T G.823 Network Wander
PRC
PRC
Cable A Cable C
Wa = 6 Microseconds Wc = 6 Microseconds
Total Wander =
18microseconds
Equipment Wander = Slave Slave Equipment Wander =
Slave Slave
1 microsecond 1 microsecond
Cable B
Wb = 4 Microseconds
This diagram demonstrates the effect of accumulative wander
27
62. The control of jitter and wander
• SDH requires that jitter and wander be kept below
tight network limits.
• This is achieved by inserting narrow-bandwidth SSUs
in the synchronisation chain (SEC bandwidth is
relatively wide).
• Narrow-bandwidth SSUs attenuate jitter and wander
components that lie outside the SSU bandwidth.
28
63. Sync Distribution in SDH - Rules
PRC
SEC SEC SEC
N x SECs
SEC SEC SEC
N = 20 Max
Level 1 SASE SASE SASE Level = 10 Max
SEC SEC SEC
N x SECs
Maximum 60
SEC SEC SEC
SECs in a
single trail
Level 2 SASE SASE SASE
SEC SEC SEC
N x SECs
SEC SEC SEC
29
64. Synchronisation reference chain
• See ITU-T G.803 or ETS 300 462-2
• The ITU-T/ETS synchronisation reference chain meets
the network limits on jitter and wander:
– Not more than 60 SECs in a chain
– Not more than 20 SECs between two SSUs
– Not more than 10 SSUs in the chain
30
65. Distribution Layer composition
The SDH Synchronisation distribution layer
is comprised of 3 parts:
1. Clocks
2. Equipment
3. Links
31
66. Round Up
• What are the two main causes of
synchronisation problems?
• What equipment is normally at the top of
a sync tree?
• What is the maximum allowed wander
under G.823?
32
68. Distribution Layer Clocks
• The clock element of the synchronisation
distribution layer is categorised in three ways:
1. Primary Reference Clock (PRC)
2. Synchronisation Supply Unit (SSU)
3. SDH Equipment Clock (SEC)
2
69. PRC Systems
• The PRC System is a master clock used to
synchronise the entire network with a frequency
accuracy of < 1 x 10-11
• This is defined by ITU-T recommendation G.811.
• A complete Primary Reference Clock consists of
the following:
– 3 separate Primary Reference Sources
– Reference Selector
– Tracking Unit
– Output Distribution Unit
3
71. Primary Reference Source
• This is a single source of G.811 Reference which
is used to feed a PRC or can be used as a
standalone reference
• This can take two forms:
1. Caesium reference source
2. Off air source i.e. GPS, Loran, GLONASS
5
72. Caesium PRS
• These elements are usually
expensive items but provide the
network with its own source of
synchronisation
– The beam can last up to 10 years
before requiring a re-tube
– They provide a stability of 1x10-11
over 20 years
– Where two beams are compared
the maximum difference between
the two beams equates to 2x10-11
which will result in 1 slip every 72
days on E1 links
– This is the standard set by ITU and
can be found in ITU-T G.811
6
73. Off-air PRS
• Off-air Primary Reference Sources provide an excellent
alternative or additional reference to Caesium
• This is a single source of G.811 Reference which is used
to feed a PRC or can be used as a standalone reference
• Off-air Primary Reference Sources include:
– Global Positioning Systems (GPS)
– Loran
– GLONASS
GPS is the most commonly used
7
74. GPS as a PRS
• The raw GPS signal contains various
information including UTC time and
identification data for navigation purposes
• The GPS satellites contain Caesium beams
which are used to provide the accuracy needed
for time and location information
• In Telecoms it is the stability of the Satellites
Caesium that is of interest. Therefore receivers
used in telecoms are specific to the requirement
• The signal is received by the GPS receiver and
is converted into a useable source for slaving a
local oscillator. The resulting output is G.811
compliant and therefore is suitable to be used
within a PRC
8
75. PRS Operation
• Three PRS sources are fed into an SASE (Stand Alone
Synchronisation Equipment). This forms the hub of the
PRC
• The SASE is normally configured to be completely
redundant. It will contain an input stage, a prioritising
and selection mechanism to determine which source it
will utilise, a tracking oscillator unit and an output stage
9
76. Which PRS is Best?
• Technically both are perfectly acceptable sources. The
differing factor is mainly down to cost
• On the surface GPS looks like a cheap option, but
beware, it is not always easy to obtain permission from
landlords to fit antenna systems and the cost of
installation can be more than the cost of the units
• When deciding on a solution look at the cost of each of
the options and consult your vendor as to what is most
cost effective
• Most common forms of PRC use a combination of
different types of PRS
10
77. Oscillators
• PLL – Phase Lock Loop
– The Most common form of slaving an oscillator
– This function employs a feedback mechanism which
feeds the Oscillator output into a comparator where
the signal is compared with the input and the
difference is sent as correction voltages to the
oscillator
11
78. Phase Lock Loop
Simple Block Diagram of a Phase Lock Loop
Phase
Comparator
Error
Error Correction
Voltage
Input S1 + Pulses Low Pass Voltage
Controlled
Filter Output
Referenc Oscillator
e
-
S2
Frequency
Divider
(optional) Feedback Path
12
79. Slaved Oscillator Mechanisms
• DDS – Direct Digital Synthesis
– A mechanism in which the Oscillator is free
running and the output signal is synthesised in
software with the incoming reference signal to
produce a stable output
13
82. Synchronisation Elements
• SASE - Stand Alone Synchronisation Equipment
• SSU - Synchronisation Supply Unit
• TNC - Transit Node Clock
• CTO - Compact Tracking Oscillator
• BITS - Building Integrated Timing Supply
– All refer to the same class of equipment
– Used with PRCs or standalone for regenerating timing
signals
– Modular by design and configured to be redundant to
allow for single or multiple internal and/or external
failures
2
83. The SASE
• SASE stands for Stand Alone
Synchronisation Equipment (Element)
• The purpose of these elements is to provide
filtering, regeneration and distribution of a
primary reference signal
• This is achieved by simple yet highly
accurate equipment
• The equipment is designed to be very
resilient to internal and external failures
therefore all components are at least
duplicated
3
85. SASE – Input Section
• Inputs
– Most SASEs have multiple input capability, allowing
the unit to select from a number of references
– The amount and type of inputs are dependent upon
the make and model. For regeneration purposes, 2
or 3 inputs are sufficient
5
86. SASE – Reference Selectors
• Reference Selectors
– Within each SASE will be the reference selector.
Normally this is duplicated for redundancy. This
section contains the priority table and selection
criteria for the units inputs
– Selection can be made by the following methods
• Automatic
• Manual
• Forced
• Synchronisation Status Message (SSM)
6
87. SASE - Selection Modes
Selection Modes
Automatic – This mode will choose the highest
available priority source set within the
priority table
Manual – This mode will only switch to another
available input by manual intervention
Forced – This mode will stay fixed to its intended
sync source at all times
SSM – The selection is dictated by the incoming
SSM information
7
88. SASE - Fltering & Holdover
• Filtering & Holdover section
– This section of the unit provides the filtering of the
reference signal. This can be achieved using two
techniques:
- Phase Lock Loop - PLL
- Direct Digital Synthesis - DDS
– This section should be duplicated for redundancy
– All SASEs employ a mechanism which prevents phase
and frequency jumps when switching between channels
8
89. SASE – Output Section
• Output Stages
– Most SASE output arrays allow for different output frequencies to
be used. 2.048Mhz is the most common for SDH but 1MHz,
10MHz, E1 Framed, etc. can all be generated by the SASE.
Consult your vendor if specific frequencies are required
– Again these can be configured to provide protection in the event
of a hardware failure
– Cards can be fitted with differing protocols. In some units the
framing and bit pattern of E1 or T1 signals can be altered to
generate AIS and other states. Units may also have the ability to
change output protocol by means of software, e.g. 2.048Mbps to
2.048Mhz
9
90. Which SASE Configuration?
• When deciding which equipment is right for your network, it
is important to look at the application first
• SASEs can be fitted with an array of different cards and
clock types
• Review the importance of the location and the equipment
the SASE is to be connected to, before deciding on
oscillator types and configuration
• Typically, SASEs should be used within the core of the
transmission network
10
91. SDU – Sync Distribution Unit
• The purpose of the SDU is to
expand the capacity of an SASE
O/P
• The SDU typically has two I/Ps
and no Hold over capability
• The SDU will have a large O/P
capacity - consider it as an
amplifier for Synchronisation
signals
• An SDU will typically be
referenced from an SASE or
SSU
11
93. SDU – Inputs
• SDU Inputs
– The SDU will normally have two input Interface Units, these
are typically 2Mhz. Jitter can be filtered on these units
– The SDU I/P reference source are often derived from an
associated SASE / SSU
– SDUs can be daisy-chained: however the lack of holdover
and wander filtering make this undesirable
– Some manufacturers have incorporated a HOU (Hold Over
Unit) capability - this is normally for a single channel
13
94. SDU – Outputs
• SDU Outputs
– The SDU is designed as a low cost, high O/P capacity
option
– Most SDU output arrays allow for different output
frequencies to be used. 2.048Mhz is the most common for
SDH but 1MHz, 10MHz, E1 Framed, etc. can all be
generated by the SASE. Consult your vendor if specific
frequencies are required
– Again, these can be configured to provide protection in the
event of a hardware failure
14
95. SDH Elements
• With the possible exception (depending on manufacturer) of the
Optical Line Amplifiers, all the following equipments contain SECs
(SDH Equipment Clocks) and should be counted within the trail
count for SDH design:
– Add Drop Multiplexers -- Microwave Systems
– Cross-Connects -- Regenerators
– Optical Line Amplifiers
This internal SEC is normally synchronised to a traffic or external
timing input signal
Traffic & Traffic &
timing 1 SEC timing
input output
External External
timing
n timing
input output
15
96. SDH Equipment Clock (SEC)
Synchronous Equipment Timing Source (SETS)
STM-N
input Selector C
External
timing output
(2MHz or
1.5 Mbit/s, or
SDH Equipment 2Mbit/s)
PDH
input Clock
Synchronous
Equipment NE
External timing Timing
input Generator internal
(2 MHz or timing
1.5 Mbit/s or
2Mbit/s)
16
97. SDH SEC features
• Input synchronisation signals are:
• STM-N aggregates and tributaries
• 2Mbit/s tributaries
• 2MHz and 2Mbit/s (non traffic) timing inputs
• Input selection is determined by:
• a priority table, that is user definable
• Synchronisation Status Message (SSM) on the STM-
N and 2Mbit/s interfaces
• Output synchronisation signals are:
• All STM-N aggregates and tributaries
• 2MHz and 2Mbit/s (non traffic) timing outputs
17
98. SEC Timing options
• Line timing:
in nodes not equipped with a node clock (SSU)
• External timing:
in nodes equipped with a node clock
• Tributary timing:
only in exceptional cases, e.g. during the evolution
from PDH to SDH
• Internal timing:
when all synchronisation reference signals are lost
(= holdover mode)
18
99. SEC Line Timing
• Line timing: in nodes not equipped with a node clock
(SSU)
• Timing is extracted from the STM-N (optical overhead)
• In normal operating conditions timing is traceable to a
G.811 primary reference
Line timing
STM-N
STM- STM-N
STM-
19
100. SEC External Timing
• External timing: in nodes equipped with a node clock
• Used for synchronisation injection points within the
network
• Normally either a 2 MHz or 2 Mbit/s reference signal
• Node clock traceable to G.811 Primary Refence
Source
• Node Clock has G.812 holdover capability
External timing
STM-N
STM- STM-N
STM-
2 MHz or 2Mbit/s
20
101. SEC Internal Timing
• Internal timing: when all external timing references
are lost
• Intended for failure conditions
• SEC Clock has G.813 holdover capability
Internal timing
STM-N
STM- STM-N
STM-
21
102. SEC Timing Outputs
• If a 1.5Mbit/s, 2MHz, 2Mbit/s synchronisation output is
derived from the Synchronous Equipment Timing
Generator (SETG), then it is called a SETG locked output
• If a 1.5Mbit/s, 2MHz, 2Mbit/s synchronisation output is
directly derived from the OC-N or STM-N input, then it is
called a non-SETG locked output
• The 2MHz timing output can be squelched when :
• The SEC enters hold-over or free-run mode
• The input SSM falls below the set threshold
22
103. SEC - Selection Modes
• Automatic – This mode will choose the highest
available priority source set within the
priority table
• Manual – This mode will only switch to another
available input by manual intervention
• Forced – This mode will stay fixed to its intended
sync source at all times
• SSM – The selection is dictated by the incoming
SSM information
23
105. Round Up
• What are the 3 main equipment types found in the
sync distribution layer?
• What is a SEC?
• What provides the higher clock order - PRS or SEC?
• What is the difference between a SASE and an SEC?
25
108. SDH Sync Link connections - 1
• Supported by an SDH multiplex section trail
i.e. the timing information is carried by the STM-N data rate
(N x 155 Mbit/s) by a retimed PDH E1 connection
• SDH regenerator timing generators are not counted as
elements of the synchronisation distribution layer, they
belong to the synchronisation link connection
• The SDH multiplex section trail may be supported by an
optical transport layer such as DWDM (dense Wavelength
Division Multiplexing) or OTN (Optical Transport Network)
2
110. Types of Oscillators in Links
• Oscillators are a common section of all of the three
clock types described
• Various types of oscillators exist and their selection is
based upon the application, i.e. PRC, SASE or SEC,
that they are to be utilised within
• The main types of crystal oscillators are:
– Caesium
– High Quality Rubidium
– Low Quality Rubidium
– High Stability Double Oven OCXO
– Single Oven OCXO
– Temperature Controlled TCXO
4
111. Rubidium Oscillators
• Atomic Standard Tracking Oscillators are extremely stable and thus
are very suitable for using within a telecom network
• Typically these oscillators are used within a Primary Reference
System as Slaved units to Caesium or GPS
• These are usually the most expensive tracking oscillators available
• They have a life span varying from 6 to 12 years, depending on
Manufacturer
• The longer life span of Rubidium oscillators is achieved using DDS
rather than PLL techniques within the clock element
• Usually Maintenance Free
• Holdover Quality dependent on Manufacturer, typically 1x10-11/mth
5
112. Single Oven OCXO
• Relatively inexpensive OCXO
• Provides Holdover of 1x10-9 to 1x10-10 per day depending
on Manufacturer
• Usually suited for Standby oscillators within SASEs or as
Local Node Clock Systems
• They will also be found in Large transit Switches and X-
Connects
6
113. High Stab. Double Oven OCXO
• Life span of 20+ years
• Maintenance free
• Lower cost than Rubidium
• Holdover is typically 1x10-11/day
• Can be used in a Primary Reference System or as a
SASE Oscillator
7
114. Temperature Controlled TCXO
• Inexpensive Oscillators
• Maintenance free
• Used in a majority of Telecom equipment
such as Multiplexers and Radio Systems
• Holdover of 1x10-6 per day or less
8
115. Typical Oscillator Performance
Oscillator Type Holdover Quality Slip Rate
(Typical) (Worst Case)
Rubidium 1x10-11/m 1 after month
Low cost 5x10-11/m 1 after week
Rubidium
High Stability 1x10-11/d 1 after 3.5 days
Double Oven
OCXO
Single Oven 2x10-10/d 1 after 1 day
OCXO
TCXO 2x10-6/d 1400 per day
9
116. Oscillator Characteristics
• Oscillators are susceptible to changes in
temperature and stability of rectified
power
• Variations in these conditions can affect
the performance of the oscillator
10
117. Retimed PDH Sync Link - 1
• PDH path layers supported by SDH path layers
are not suitable for transporting synchronisation
• Retiming is used when E1 traffic signals
transported over SDH are used as
synchronisation links (e.g. to synchronise distant
PABXs or GSM BTSs)
• Retiming is applied on E1 traffic signals affected
by excessive wander (e.g. from pointer
adjustments)
• Retiming buffers can be integrated in the SDH
network element or the SASE
11
118. Retimed PDH Sync Link - 2
SDH
network element
SEC
STM- timing signal
N PDH
SEC tributary
output Retiming re-timed
re-
Buffer PDH
PDH signal
tributary
Retiming re-timed
re-
output
Buffer PDH
PDH signal
tributary
output Retiming re-timed
re-
Buffer PDH
signal
12
119. Retiming
• The retiming buffer transmits the incoming traffic at
the data rate of the SEC timing signal, thus removing
the excessive wander
• The long-term frequency (data rate) of the E1 traffic
signal must be synchronized to the network PRC
• Slips will occur if the SEC has lost its
synchronisation to the PRC
13
120. Round Up
• What is the synchronisation link layer?
• How is synchronisation transported from
site to site?
• How is synchronisation delivered within
the node?
• Name 3 Oscillator types
14
122. Master-Slave Principle
• A designated master clock is used as a
reference frequency generator
• The frequency generated by the master clock
is disseminated to all other clocks which are
slaved to the master clock
2
123. Master-Slave Mechanism
• The clock is injected into the master unit
• The slave unit locks to the incoming clock
rate and is synchronised to the master
• No slips occur between these elements
Transmission Link
Data Master
Master Slave
Slave
Data + Clock
PRC 1
3
125. Principle of trail redundancy
• Each slave clock should get at least two
reference signals from the master clock via
geographically separate trails
• Sometimes it is not possible to fulfil this
principle for all nodes of the network
(depending on connectivity)
5
126. Hierarchy of Quality Levels
• There is a hierarchy of clock quality levels
• The higher the clock quality level, the higher
the frequency accuracy of the clock
• Frequency accuracy =
– either overall free-run accuracy or holdover accuracy
over a limited time period
6
128. Weak Hierarchical Distribution
RULE
• A clock of a given quality level must always (even
under failure conditions) take timing (directly or
indirectly) from a source clock with the same or
higher quality level
8
129. Implementing the Rule
Question:
• How can we implement the Weak Hierarchical
Distribution Rule? ..........
Answer:
• By implementing the Strong Hierarchical Distribution
Rule:
« A clock of a given quality level must take
timing (directly) from a clock with the same
or higher quality level »
• Or by the use of SSM signalling
9
132. Sync network with SSM
• There is a link failure within a chain of SECs
• The SSM signalling prevents the downstream SSU from
following a SEC in holdover mode
• Instead, the downstream SSU enters holdover mode and
becomes the source clock for the cut off sub-network
12
133. The control of jitter and wander
• SDH requires that jitter and wander be kept below tight
network limits
• This is achieved by inserting narrow-bandwidth SSUs
in the synchronisation chain (SEC bandwidth is
relatively wide)
• Narrow-bandwidth SSUs attenuate jitter and wander
components that lie outside the SSU bandwidth
13
134. Sync Distribution in SDH
PRC
SEC SEC SEC
N x SECs N = 20 Max
SEC SEC SEC
Level 1 SASE SASE SASE
Maximum 60
SEC SEC SEC SECs in a
N x SECs single trail
SEC SEC SEC
Level 2 SASE SASE SASE
Maximum 10
SEC SEC SEC
SASEs in a
N x SECs single trail
SEC SEC SEC
14
135. Synchronisation reference chain
• See ITU-T G.803 or ETS 300 462-2
• The ITU-T/ETS synchronisation reference chain meets the
network limits on jitter and wander:
– Not more than 60 SECs in a chain
– Not more than 20 SECs between two SSUs
– Not more than 10 SSUs in the chain
15
137. Synchronisation Signalling layer
Function:
• To provide the source clock quality level from clock
to clock down the synchronisation chains, in order
to:
– Enable clocks to select the best available
reference timing signal
– Enable clocks to go into holdover mode if
reference timing signals are of low quality
– Prevent timing loops in SDH chains and rings
17
138. SDH Sync Status Messages
• The clock source quality level is indicated by the
Synchronisation Status Message (SSM)
• In SDH, the message set is:
• QL-PRC = PRC, G.811
• QL-SSU-A = SSU, G.812 Type I or V
• QL-SSU-B = SSU, G.812 Type VI
• QL-SEC = SEC, G.813 Option 1
• QL-DNU = Do not use
18
139. SSM Transmission Channels
• The timing quality level carried by STM-N signals (SDH)
is indicated by the S1 byte in the STM-N Multiplex
Section Over Head (MSOH)
• The timing quality level carried over 2048 kbit/s
synchronisation signals is indicated in one of the bits Sa4
to Sa8 in Time Slot Zero (TS0)
• 1544 kbit/s T1 signals: see ITU-T Rec. G.704
• 34 Mbit/s E3 and 140 Mbit/s E4 signals: see ITU-T Rec.
G-832
19
140. SSM Algorithm
• Always select the highest quality input and if a number
of equal quality timing inputs are available, then select
the highest priority timing input
• In locked mode, the output SSMs are set to the
selected input SSM e.g. G.811 in = G.811 out
• The SSM in the return direction of the selected input is
automatically set to Do Not Use (DNU)
20
141. If all inputs are bad ...
• The SEC enters holdover mode…
• The SEC memorises the phase and frequency values of the
last known good input, but quickly drifts toward 4.6 x 10-6
• The SEC will be in free-run mode if it has never locked to a
higher level reference signal
• Ext Clock Out signals should be squelched
• Output SSM STM-n value is set to G.813 (unless manually
set)
• Unfortunately, SECs inject jitter on to the PRC signal and
accumulative jitter can cause slips
21
142. SDH ring sync protection
• Automatic SSM correction and automatic
synchronisation distribution trail reconfiguration under
failure conditions
– Using the SSM algorithm
• Revertive operation
– SD trails returns to the original paths when the
failed section or the failed network element has
been repaired
• No operator action is needed
22
143. Revertive/Non-Rev Switching
• Revertive switching will allow previously disqualified
inputs to be re-qualified and re-selected as the selected
source
• Non-Revertive switching will not allow previously
disqualified inputs to be re-selected if they return to a
useable reference
• Pro’s & Con’s are associated with either option. The
operator must decide which method to use as a standard
for the whole network
23
146. Centralised or Distributed PRC
• Two methods of deploying PRCs are utilised
in today’s networks:
– Centralised
– Distributed
• A combination of both methods is also a valid
strategy for Synchronisation
2
147. Centralised PRCs - 1
• This method was typically used by operators when PDH
systems were used as the main transmission media.
• This method, utilised 2 or 3 fully equipped PRC’s located
separately. The clock was embedded within the E1 bearer
on the Primary Multiplexers and distributed over the PDH to
the Exchanges.
• Each PRC system typically employed three Caesium beams
for redundancy.
• These systems were expensive to purchase and required
maintenance to be carried out.
3
148. Centralised PRCs - 2
• In today’s networks the Centralised PRC is still supported
and is still valid for timing SDH.
• With the onslaught of new technologies and transport
mechanisms, new operators have approached the issue of
network synchronisation differently.
• Preferring to have multiple low cost PRS clocks situated all
around the network – Distributed PRCs.
4
149. Physical View
The PRC distributes timing through master slave
Synchronous Equipment Clocks.
All elements are traceable to the PRC
SEC SEC
SEC SEC
SEC
Equipment Clocks
PRC SEC SEC SEC SEC
SEC PRC = Primary
Reference Clock
SEC
SEC
SEC
5
150. Distributed PRS - 1
• There are many primary reference sources distributed in the
network
• The most common form of PRS utilised for this purpose is GPS
• The GPS satellite system distributes USNO-UTC-derived time and
timing to all GPS-clocks
• Each GPS-clock is the master of a synchronization subnetwork
• This is also referred to as decentralised PRCs
6
151. Distributed PRS - 2
• This mode of clocking is favoured by the new
operators. Mainly due to having isolated sites or
regions which are linked by lines, leased from the
incumbent carrier
• In this instance, trace-ability is lost when transported
over another operator's network. Therefore, installing
primary reference sources at all sites ensured
synchronisation quality is maintained
7
152. Distributed PRS - 3
Leased Transmission
Link
Data Master
Master Master
Master
Data + Clock
PRS 1 PRS 2
• Each element or node is timed by a separate high stability clock
• These are virtually identical speeds (accuracy of 1x1011)
• Will cause one slip every 72 days - perfectly acceptable
8
153. Physical View
Region 1
Region 2
SEC SEC
SEC SEC SEC
SEC
PRC PRC
SEC
SEC Local SEC
SEC Equipment
Clocks
SEC SEC
SEC
Timing Feeds
Traffic Links PRC
SEC
SEC
PRC… Primary Reference
Clock Region 3
SEC…SDH Element Clock
9
154. Mixed sync distribution - 1
• Mixed synchronisation network architectures offer a
combination of benefits from centralised and
distributed PRS solutions
• Less wander due to short synchronisation chains
• Simplified network design
• Easy to modify the network (evolution)
• Low risk of creating timing loops
10
155. Mixed sync distribution - 2
n n n n n n
G G G
n n n n n n
M
n n n n n n
G G G
n n n n n n
central node equipment
G GPS-clock M master n clock clock
Sub-network
clock
11
156. Sync entirely based on GPS
• It is technically feasible to deploy one GPS-clock per node
• Less wander due to very short synchronization chains
• Very simple network design
• Easy to modify the network (evolution)
• Very low risk of creating timing loops
• Not robust enough, since there is only one synchronization
reference signal available (dual GPS receivers do not provide
protection against interference and jamming!) - no trail
redundancy
• Not economical for very large networks with many nodes, because
of total equipment cost
12
157. Which Strategy is Best? - 1
• There are benefits and drawbacks to both options. Both
methods are perfectly acceptable
• With distributed GPS there is a cost impact for installation
and technically speaking there are multiple boundaries
inside the network
• Plan for a failure. If one GPS fails the network must be able
to recover from a standby GPS or if possible from a GPS at
an adjacent site
13
158. Which Strategy is Best? - 2
• With a centralised PRC careful planning is required to
prevent timing loops
• Inter oscillator chain length can be large, so regenerator
units such as SASE’s are required
• If planned correctly this can be a more cost effective way of
synchronising the network
• All elements will be traceable to one Master Clock
14
159. Equipment cost model
Total
equipment
cost GPS-BASED SYNCHRONISATION
DISTRIBUTION:
(single GPS + SASE) per node
WIRED (PDH- OR SDH-BASED)
SYNCHRONIZATION
DISTRIBUTION:
one central PRC with 3 Cs clocks,
and one SASE per node
number of nodes or
60-80 synchronisation sub
networks
15
160. Sync from a co-operating N'wk - 1
• Most common when there is no PRC in the network
• All clocks in the network are slaved to synchronization
signals from a co-operating network
• Under normal operating conditions all slave clocks
operate at the same frequency as the PRC in the co-
operating network
• There are normally no slip for on-net and off-net traffic
to the co-operating network
16
161. Sync from a co-operating N'wk - 2
• The clock signals from the co-operating network
may be received at only a few synchronisation
gateway nodes
• The clock signals from the co-operating network
may also be received at every node, or at every
sub-network
17
162. Sync from a co-op N'wk - Issues
• The network’s synchronisation performance is
dependent on the quality of the synchronisation
signals from the co-operating network
• There must be an agreement with the co-operating
operator on service level
• The cost to lease the synchronisation signals can be
high
18
163. Agreement on sync interfaces
• Physical interface specification (e.g. 2 Mbit/s, G.703)
• SSM configuration
• Guaranteed synchronization quality (e.g. G.823 Network Limit)
• Upstream synchronisation chain length (number of clocks)
• Guaranteed availability of agreed quality (e.g. 0.9999)
• Mean Time to Repair in case of failure
• Worst case quality degradation in case of failure (e.g. max.
frequency error, max. frequency drift, max. jitter & wander)
• Alarming method in case of failure (e.g. SSM)
• Quality monitoring criteria
19
164. Round Up
• What is a master slave clock
arrangement?
• What is a centralised PRC system?
• What is a de-centralised PRC system?
• Which system is best?
• Give two examples of a PRS
20
166. Standardisation Bodies
• International level : ITU Recommendations
• Regional level, Europe: ETSI Legally binding standards
• USA: ANSI Legally binding standards
• Industry level: e.g. TIA Industry standards
• Company level: e.g. Bellcore Internal standards
ITU : International Telecommunication Union
ETSI : European Telecommunications Standards Institute
ANSI : American National Standards Institute
TIA: Telecommunication Industry Association
2
168. ITU-T Rec. G.810
• Definitions for synchronisation networks
• Includes the definitions of time error, MTIE,
TDEV, etc.
4
169. ITU-T Rec. G.803
• Architecture of SDH transport networks
• Section 8.2: architecture of SDH-based
synchronisation networks
• Section 8.2.4: synchronization network
reference chain
5
170. ITU-T Rec. G.823 (11/98)
• The control of jitter and wander in PDH networks
based on the 2048 kbit/s hierarchy:
1. Maximum network limits on jitter and wander
2. Minimum equipment tolerance to jitter and wander
6
171. G.823 - What does it specify?
• Network limits for traffic interfaces
• Network limits for synchronization interfaces
• Jitter and wander tolerance of traffic interfaces
7
172. ITU-T Rec. G.824
• The control of jitter and wander in PDH networks
based on the 1544 kbit/s hierarchy
• Similar to ITU-T Rec. G.823, but for the 1544 kbit/s
based PDH network
8
173. ITU-T Rec. G.825
• The control of jitter and wander in SDH networks
based on the 2048 kbit/s hierarchy
• Similar to ITU-T Rec. G.823, but for SDH networks
9
174. ITU-T Rec. G.811
• Specification for Primary Reference Clocks (PRC)
• It is an equipment specification
• Specifies only one PRC type
10
175. G.811 - What does it specify?
• Frequency accuracy
• Noise generation
• Phase discontinuity in case of internal
protection switching
11
176. ITU-T Rec. G.812 (6/98)
• Specification for Node Clocks (Node Clock is the
ITU-T term for SSU)
• It is an equipment specification
• Specifies six SSU types
12
177. ITU-T Rec. G.812 - SSU Types
SSU Type Which hierarchy? Primary Application Which case?
Type I 2048 kbit/s Sync. chains as long as G.803 reference chains
Type II 1544 kbit/s Distribution hubs (1) single input reference
;
Type III 1544 kbit/s End offices (1)
Type IV 1544 kbit/s If used in SDH: must also comply with G.813 option 2
Type V 1544 & 2048 kbit/s Existing (2)transit nodes; same as TNC G.812 - 1988
Type VI 2048 kbit/s Existing (2)local nodes; same as LNC G.812 - 1988
Note (1): see Bellcore terminology
Note (2): prior to introduction of SDH
13
178. G.812 - What does it specify?
• Frequency Accuracy
• Pull-in, hold-in, and pull-out ranges
• Noise tolerance
• Noise generation
• Noise transfer
• Transient response in case of input reference
switching
• Holdover performance
• Phase discontinuity in case of internal protection
switching
14
179. ITU-T Rec. G.813
• Specification for SDH Equipment Clocks (SEC)
• It is an equipment specification
• Specifies two SEC types:
– SEC Option A: 2048 kbit/s hierarchy
– SEC Option B: 1544 kbit/s hierarchy
15
180. G.813 - What does it specify?
• Frequency Accuracy
• Pull-in, hold-in, and pull-out ranges
• Noise tolerance
• Noise generation
• Noise transfer
• Transient response in case of input reference
switching
• Holdover performance
• Phase response to input signal interruption
• Phase discontinuity in case of internal protection
switching
16
181. Round Up
• What does ITU-T G.811 specify?
• What does ITU-T G.812 specify?
• What does ITU-T G.813 specify?
• How many levels are defined under
G.812?
17
184. What’s driving the industry?
•Networks migrating to Packet but
mission-critical Comms and Data
need accurate timing Today:
Hybrid Network
•Must continue to provide the same Ethernet Base
Station
quality of synchronisation delivered TDM
today by TDM
Core
•Can this be done without the need Network
to retain the T1/E1 links used today Future:
to transfer synchronisation? Ethernet-only
Base
Station
2
2
2
185. Sync-E and IEEE1588V2 compared
Synchronous Ethernet delivers Frequency Only Application Frequency Time
GSM 50 ppb N/A
• Regular heartbeat on link signal provides frequency UMTS/ W-CDMA 50 ppb N/A
synchronization.
UMTS/ W-CDMA
250 ppb N/A
femtocells
16 ppb, suggested
GSM, UMTS, LTE
to meet 50ppb RF N/A
IEEE1588V2 delivers Frequency, Phase & ToD Network Interface
specification
• less than 100 nanosecond (target 50nS) CDMA2000 50 ppb
Should +/-3µs, shall +/-
time-of-day precision over Ethernet LAN. 10µs
TD-SCDMA 50 ppb +/- 1.5µs
• Less than 1µs time-of-day precision over LTE (FDD) 50 ppb N/A
switched Ethernet WAN. +/- 1.5µs small cell, +/-
LTE (TDD) 50 ppb
5µs large cell
• stable frequency (1.6x10-8 or 16ppb) +/- 1-32µs,
recovery (from time-of-day reference). LTE MBSFN 50 ppb implementation
dependent
LTE-A CoMP (Network +/- 500 ns (0.5 µs),
1588V2 CAN MEET & EXCEED MOBILE MIMO)
50 ppb
pre-standard
NETWORK REQUIREMENTS
2 ppm absolute, +/-1 - 8 µs,
WiMAX (TDD) ~50 ppb between implementation
base stations dependent
3
186. Building a N'wk with SyncE/1588v2
G.8260
(Definition) Agreed Ongoing Consent
Definitions / G.8260 Dec2011
terminology (metrics)
Frequency: G.826x Time/Phase:G.827x
G.8261 G.8271
Basics
SyncE NetwkJitter-Wander: G.8271.1
Network Included in G.8261 (NetwkPDV_time/phase
requirements G.8261.1 G.8271.2
(NetwkPDV_frequency) may be needed in future
G.8262 G.8272 73.1-GM
Clock (SyncE) PRTC
73.2 BC
G.8263 G.8273 73.3 TC
G.8264
(SyncE-architecture)
Methods G.8275
G.8265
(Packet-architecture-Frequency))
(Packet-architecture-time)
G.8265.1 G.8275.1
Profiles (PTPprofileFrequency) (PTPprofileTime/phase)
G.8265.m G.8275.n
(PTP Profile frequency m) (PTPprofileTime/phase n)
ITU-T Standards
4
187. Synchronous Ethernet (SyncE)
– Line rate of the Ethernet Interface used to transfer timing
– No impact/demand on packet layers
– Defines the use of a high stability oscillator to generate
line frequency
– Ethernet ‘Classic’: ±100ppm
– Synchronous Ethernet: ±4.6ppm
– ITU-T Standards in place
• G.8262: Timing Characteristics for Synchronous
Ethernet Equipment
• G.8261: Timing & Synchronisation in Packet Networks
• G.8264: Distribution of Timing Through Packet Networks
(ESMC)
5
188. Challenges
• Cost: All interfaces need to be Sync-E compatible
• Cannot be used with existing Ethernet equipment
when transferring synchronisation
~
PRC
~
PRC
6
192. Sync architecture for Sync-E
PRC
G.812
Type I
(SSU)
Number of G.812 type I
clocks < 10 SEC SEC
G.8262 is
Number of G.813 option 1 SEC EEC
Compatible
clocks < 20 with
G.813
SEC EEC
Total number of
G.813 clocks in a
sychronisation trail SEC SEC
should not exceed 60
G.812
Type I
(SSU)
10
197. Introducing ESMC
• ESMC: Ethernet Synchronization Messaging Channel
• ESMC has been built first and foremost as the transport
channel for SSM (QL) over Synchronous Ethernet links
• Key outcome: Simple and efficient
• ESMC does not aim to become a complex protocol
• However, in the future it may support some extensions
• It is not a control plane and does not need a control plane
15
198. G.8264 – ESMC testing
Stimulus to EEC Response from EEC
1.ESMC = PRC
1. ESMC = PRC 2.Wander locked to Synchronisation
Clock Source
Reference with Freq
10MHz, 2.048MHz, E1, T1
1.ESMC changes to EEC1/2 offset
2.Wander shows offset as
2. ESMC = DNU
EEC now locked to local
clock
Paragon GUI
1.ESMC changes to PRC &
3. ESMC = PRC
2.Wander locked to reference TimeMonitor
Change QL of
•Wander Graph Port 2 ESMC
shows Line EEC
Clock Rate 100M/1G SyncE
switching into Port 1 (Wander free)
and out of
Holdover
ESMC with EEC
•ESMC Graph defined QL
shows ESMC
messages
changing state
to reflect status
16
200. Packet Sync Technologies
• Separate packet flow used to transfer timing
– Timestamps embedded in packets to transfer timing
– Two-way protocol employed to measure delay between
Master and Slave devices
• Able to transfer frequency (syntonisation) and phase/time-
of-day (synchronisation)
• Standards define devices/techniques to reduce uncertainty
(Peer-to-peer & End-to-end Transparent Clocks) and to
create hierarchical clocking topology (Ordinary Clocks,
Boundary Clocks)
2
201. Standards
• IEEE: 1588v2; Precision Timing Protocol, PTP
• IETF: RFC1305; Network Time Protocol, NTPv3,
RFC5905: NTPv4 (TICTOC group) Deployed
by Ericsson
• ITU-T: G.8264; Distribution of Timing through
Packet Networks
3
202. IEEE 1588v2 (PTP)
Benefits:
– 1588v2 Standard ratified March 2008
– Independent of services
– Suitable for layered/complex clock distribution
topologies
– Compatible with currently deployed packet networks
Drawbacks:
– Cost: Extra bandwidth required
– Protocol assumes symmetrical delays in up- and
down-stream paths
– Sensitivity to PDV
4
203. IEEE1588 Network Sync - 1
Phase 1 - Establishes the Master-Slave hierarchy via the
session protocol and a local state machine
5
204. Phase 1 - Session Management
Session Start-up
Master Slave
Clock Clock
ce)
Signalling (Re
quest Announ Announce and Signaling
Signalling (Ac
messages configure and
knowledge)
maintain the clocking
quest Sync) structure - they include:
Signalling (Re
Signalling (A
cknow ledge
)
• Clocking Topology
• Grand Master identity
p)
quest Del_res and priority
Signalling (Re
Signalling (A
cknowledge
• Timestamps
)
• Current UTC offset
6
206. Phase 2 – Slave Clock Sync
Propagation Delay Message Exchange
Master Slave
Clock Clock
t1
Sync
t-ms Clock Output must comply with the
t2 relevant ITU-T clock specification
(MTIE & TDEV specification)
Follow_Up
t3 G.81x series of specifications
t-sm
Delay_Req (G.823/4 for TDM delivery)
t4
Delay_Resp
8
207. Time Transfer Example
Assume at an instant in time:
Master clock value = 100 seconds
Slave clock value = 150 seconds
Master Clock Slave Clock Data At
(the slave clock error = 50 seconds)
Slave Clock
One way path delay = 2 seconds
Sync message is sent at t = 100 seconds
t1 For illustration, Delay_Req is sent 5 seconds after
sync (t •2s the Sync message is received:
1)
t2 t1 = 100 seconds
Round Trip Delay
t2 = 152 seconds
RTD = (t2 - t1) + (t4 - t3)
(150+2)
RTD = (152 - 100) + (109 - 157)
t)
re q(ues t3 RTD = 4 seconds
delay_ t3 = 157 seconds
(152+5) Slave clock error eliminated
t4
delay_
re sp(on Slave Clock Error = (t2 - t1) - (RTD ÷ 2)
s e) (t4
) = (152 - 100) - (4 ÷ 2)
= 50 seconds
t4 = 109 seconds
(100+2+2+5) Round trip error eliminated
If the slave clock is adjusted by -50 seconds, the
Master & Slave will be synchronized.
9
208. Influences on 1588v2 Accuracy
Packet Delay Variation Prolonged Packet
(PDV) appears as a Loss (Outage)
–Causes clock recovery process
change in frequency or to enter holdover
phase of the recovered
clock Slave Performance
–Increases with number of Vendor A – PDV tolerance – X
network elements and traffic load Vendor B – PDV tolerance – Y
–Multiple causes, including
queuing delays, routing changes, Packet Delay, Packet
congestion, use of switches
versus routers, etc. Loss, and Packet
Errors are not an
Network asymmetry issue for packet timing
protocols
10
209. Today’s test challenges (G.8261)
• Building a ref. network/designing algorithms is time-
consuming and expensive
• Not repeatable (varying behaviour) and inconsistent (many
different implementations)
• Does it truly represent YOUR network?
11
210. 1588v2 Slave (Ordinary Clock)
• In a network with legacy routers, PDV and Asymmetry
accumulation (in each direction) can be significant
• Slave clock recovery is a challenge
PDV Accumulation
Master Router Router Router Router Slave
Clock Clock
12