Network Working Group D. Mills
Request for Comments: 1059 University of Delaware
July 1988
Network Time Protocol (Version 1)
Specification and Implementation
Status of this Memo
This memo describes the Network Time Protocol (NTP), specifies its
formal structure and summarizes information useful for its
implementation. NTP provides the mechanisms to synchronize time and
coordinate time distribution in a large, diverse internet operating
at rates from mundane to lightwave. It uses a returnable-time design
in which a distributed subnet of time servers operating in a self-
organizing, hierarchical master-slave configuration synchronizes
logical clocks within the subnet and to national time standards via
wire or radio. The servers can also redistribute reference time via
local routing algorithms and time daemons.
The NTP architectures, algorithms and protocols which have evolved
over several years of implementation and refinement are described in
this document. The prototype system, which has been in regular
operation in the Internet for the last two years, is described in an
Appendix along with performance data which shows that timekeeping
accuracy throughout most portions of the Internet can be ordinarily
maintained to within a few tens of milliseconds, even in cases of
failure or disruption of clocks, time servers or nets. This is a
Draft Standard for an Elective protocol. Distribution of this memo
is unlimited.
Table of Contents
1. Introduction 3
1.1. Related Technology 4
2. System Architecture 6
2.1. Implementation Model 7
2.2. Network Configurations 9
2.3. Time Scales 10
3. Network Time Protocol 12
3.1. Data Formats 12
3.2. State Variables and Parameters 13
3.2.1. Common Variables 15
3.2.2. System Variables 17
3.2.3. Peer Variables 18
3.2.4. Packet Variables 19
3.2.5. Clock Filter Variables 19
3.2.6. Parameters 20
Appendices
Appendix A. UDP Header Format 43
Appendix B. NTP Data Format 44
Appendix C. Timeteller Experiments 47
Appendix D. Evaluation of Filtering Algorithms 49
Appendix E. NTP Synchronization Networks 56
List of Figures
Figure 2.1. Implementation Model 8
Figure 3.1. Calculating Delay and Offset 26
Figure 5.1. Clock Registers 34
Figure D.1. Calculating Delay and Offset 50
Figure E.1. Primary Service Network 57
This document describes the Network Time Protocol (NTP), including
the architectures, algorithms and protocols to synchronize local
clocks in a set of distributed clients and servers. The protocol was
first described in RFC-958 [24], but has evolved in significant ways
since publication of that document. NTP is built on the Internet
Protocol (IP) [10] and User Datagram Protocol (UDP) [6], which
provide a connectionless transport mechanism; however, it is readily
adaptable to other protocol suites. It is evolved from the Time
Protocol [13] and the ICMP Timestamp message [11], but is
specifically designed to maintain accuracy and robustness, even when
used over typical Internet paths involving multiple gateways and
unreliable nets.
The service environment consists of the implementation model, service
model and time scale described in Section 2. The implementation
model is based on a multiple-process operating system architecture,
although other architectures could be used as well. The service
model is based on a returnable-time design which depends only on
measured offsets, or skews, but does not require reliable message
delivery. The subnet is a self-organizing, hierarchical master-slave
configuration, with synchronization paths determined by a minimum-
weight spanning tree. While multiple masters (primary servers) may
exist, there is no requirement for an election protocol.
NTP itself is described in Section 3. It provides the protocol
mechanisms to synchronize time in principle to precisions in the
order of nanoseconds while preserving a non-ambiguous date well into
the next century. The protocol includes provisions to specify the
characteristics and estimate the error of the local clock and the
time server to which it may be synchronized. It also includes
provisions for operation with a number of mutually suspicious,
hierarchically distributed primary reference sources such as radio
clocks.
Section 4 describes algorithms useful for deglitching and smoothing
clock-offset samples collected on a continuous basis. These
algorithms began with those suggested in [22], were refined as the
results of experiments described in [23] and further evolved under
typical operating conditions over the last two years. In addition,
as the result of experience in operating multiple-server nets
including radio-synchronized clocks at several sites in the US and
with clients in the US and Europe, reliable algorithms for selecting
good clocks from a population possibly including broken ones have
been developed and are described in Section 4.
The accuracies achievable by NTP depend strongly on the precision of
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the local clock hardware and stringent control of device and process
latencies. Provisions must be included to adjust the software
logical clock time and frequency in response to corrections produced
by NTP. Section 5 describes a logical clock design evolved from the
Fuzzball implementation described in [15]. This design includes
offset-slewing, drift-compensation and deglitching mechanisms capable
of accuracies in order of a millisecond, even after extended periods
when synchronization to primary reference sources has been lost.
The UDP and NTP packet formats are shown in Appendices A and B.
Appendix C presents the results of a survey of about 5500 Internet
hosts showing how their clocks compare with primary reference sources
using three different time protocols, including NTP. Appendix D
presents experimental results using several different deglitching and
smoothing algorithms. Appendix E describes the prototype NTP primary
service net, as well as proposed rules of engagement for its use.
1.1. Related Technology
Other mechanisms have been specified in the Internet protocol suite
to record and transmit the time at which an event takes place,
including the Daytime protocol [12], Time Protocol [13], ICMP
Timestamp message [11] and IP Timestamp option [9]. Experimental
results on measured times and roundtrip delays in the Internet are
discussed in [14], [23] and [31]. Other synchronization protocols
are discussed in [7], [17], [20] and [28]. NTP uses techniques
evolved from both linear and nonlinear synchronization methodology.
Linear methods used for digital telephone network synchronization are
summarized in [3], while nonlinear methods used for process
synchronization are summarized in [27].
The Fuzzball routing protocol [15], sometimes called Hellospeak,
incorporates time synchronization directly into the routing protocol
design. One or more processes synchronize to an external reference
source, such as a radio clock or NTP daemon, and the routing
algorithm constructs a minimum-weight spanning tree rooted on these
processes. The clock offsets are then distributed along the arcs of
the spanning tree to all processes in the system and the various
process clocks corrected using the procedure described in Section 5
of this document. While it can be seen that the design of Hellospeak
strongly influenced the design of NTP, Hellospeak itself is not an
Internet protocol and is unsuited for use outside its local-net
environment.
The Unix 4.3bsd model [20] uses a single master time daemon to
measure offsets of a number of slave hosts and send periodic
corrections to them. In this model the master is determined using an
election algorithm [25] designed to avoid situations where either no
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master is elected or more than one master is elected. The election
process requires a broadcast capability, which is not a ubiquitous
feature of the Internet. While this model has been extended to
support hierarchical configurations in which a slave on one network
serves as a master on the other [28], the model requires handcrafted
configuration tables in order to establish the hierarchy and avoid
loops. In addition to the burdensome, but presumably infrequent,
overheads of the election process, the offset measurement/correction
process requires twice as many messages as NTP per update.
A good deal of research has gone into the issue of maintaining
accurate time in a community where some clocks cannot be trusted. A
truechimer is a clock that maintains timekeeping accuracy to a
previously published (and trusted) standard, while a falseticker is a
clock that does not. Determining whether a particular clock is a
truechimer or falseticker is an interesting abstract problem which
can be attacked using methods summarized in [19] and [27].
A convergence function operates upon the offsets between the clocks
in a system to increase the accuracy by reducing or eliminating
errors caused by falsetickers. There are two classes of convergence
functions, those involving interactive convergence algorithms and
those involving interactive consistency algorithms. Interactive
convergence algorithms use statistical clustering techniques such as
the fault-tolerant average algorithm of [17], the CNV algorithm of
[19], the majority-subset algorithm of [22], the egocentric algorithm
of [27] and the algorithms in Section 4 of this document.
Interactive consistency algorithms are designed to detect faulty
clock processes which might indicate grossly inconsistent offsets in
successive readings or to different readers. These algorithms use an
agreement protocol involving successive rounds of readings, possibly
relayed and possibly augmented by digital signatures. Examples
include the fireworks algorithm of [17] and the optimum algorithm of
[30]. However, these algorithms require large numbers of messages,
especially when large numbers of clocks are involved, and are
designed to detect faults that have rarely been found in the Internet
experience. For these reasons they are not considered further in
this document.
In practice it is not possible to determine the truechimers from the
falsetickers on other than a statistical basis, especially with
hierarchical configurations and a statistically noisy Internet.
Thus, the approach taken in this document and its predecessors
involves mutually coupled oscillators and maximum-likelihood
estimation and selection procedures. From the analytical point of
view, the system of distributed NTP peers operates as a set of
coupled phase-locked oscillators, with the update algorithm
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functioning as a phase detector and the logical clock as a voltage-
controlled oscillator. This similarity is not accidental, since
systems like this have been studied extensively [3], [4] and [5].
The particular choice of offset measurement and computation procedure
described in Section 3 is a variant of the returnable-time system
used in some digital telephone networks [3]. The clock filter and
selection algorithms are designed so that the clock synchronization
subnet self-organizes into a hierarchical master-slave configuration
[5]. What makes the NTP model unique is the adaptive configuration,
polling, filtering and selection functions which tailor the dynamics
of the system to fit the ubiquitous Internet environment.
2. System Architecture
The purpose of NTP is to connect a number of primary reference
sources, synchronized to national standards by wire or radio, to
widely accessible resources such as backbone gateways. These
gateways, acting as primary time servers, use NTP between them to
cross-check the clocks and mitigate errors due to equipment or
propagation failures. Some number of local-net hosts or gateways,
acting as secondary time servers, run NTP with one or more of the
primary servers. In order to reduce the protocol overhead the
secondary servers distribute time via NTP to the remaining local-net
hosts. In the interest of reliability, selected hosts can be
equipped with less accurate but less expensive radio clocks and used
for backup in case of failure of the primary and/or secondary servers
or communication paths between them.
There is no provision for peer discovery, acquisition, or
authentication in NTP. Data integrity is provided by the IP and UDP
checksums. No circuit-management, duplicate-detection or
retransmission facilities are provided or necessary. The service can
operate in a symmetric mode, in which servers and clients are
indistinguishable, yet maintain a small amount of state information,
or in client/server mode, in which servers need maintain no state
other than that contained in the client request. A lightweight
association-management capability, including dynamic reachability and
variable polling rate mechanisms, is included only to manage the
state information and reduce resource requirements. Since only a
single NTP message format is used, the protocol is easily implemented
and can be used in a variety of solicited or unsolicited polling
mechanisms.
It should be recognized that clock synchronization requires by its
nature long periods and multiple comparisons in order to maintain
accurate timekeeping. While only a few measurements are usually
adequate to reliably determine local time to within a second or so,
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periods of many hours and dozens of measurements are required to
resolve oscillator drift and maintain local time to the order of a
millisecond. Thus, the accuracy achieved is directly dependent on
the time taken to achieve it. Fortunately, the frequency of
measurements can be quite low and almost always non-intrusive to
normal net operations.
2.1. Implementation Model
In what may be the most common client/server model a client sends an
NTP message to one or more servers and processes the replies as
received. The server interchanges addresses and ports, overwrites
certain fields in the message, recalculates the checksum and returns
the message immediately. Information included in the NTP message
allows the client to determine the server time with respect to local
time and adjust the logical clock accordingly. In addition, the
message includes information to calculate the expected timekeeping
accuracy and reliability, thus select the best from possibly several
servers.
While the client/server model may suffice for use on local nets
involving a public server and perhaps many workstation clients, the
full generality of NTP requires distributed participation of a number
of client/servers or peers arranged in a dynamically reconfigurable,
hierarchically distributed configuration. It also requires
sophisticated algorithms for association management, data
manipulation and logical clock control. Figure 2.1 shows a possible
implementation model including four processes sharing a partitioned
data base, with a partition dedicated to each peer and interconnected
by a message-passing system.
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+---------+
| Update |
+--------->| +----------+
| |Algorithm| |
| +----+----+ |
| | |
| V V
+----+----+ +---------+ +---------+
| | | Local | | |
| Receive | | +---->| Timeout |
| | | Clock | | |
+---------+ +---------+ +-+-----+-+
A A | |
| | V V
===========================================
Peers Network Peers
Figure 2.1. Implementation Model
The timeout process, driven by independent timers for each peer,
collects information in the data base and sends NTP messages to other
peers in the net. Each message contains the local time the message
is sent, together with previously received information and other
information necessary to compute the estimated error and manage the
association. The message transmission rate is determined by the
accuracy expected of the local system, as well as its peers.
The receive process receives NTP messages and perhaps messages in
other protocols as well, including ICMP, other UDP or TCP time
protocols, local-net protocols and directly connected radio clocks.
When an NTP message is received the offset between the sender clock
and the local clock is computed and incorporated into the data base
along with other information useful for error estimation and clock
selection.
The update algorithm is initiated upon receipt of a message and at
other times. It processes the offset data from each peer and selects
the best peer using algorithms such as those described in Section 4.
This may involve many observations of a few clocks or a few
observations of many clocks, depending on the accuracies required.
The local clock process operates upon the offset data produced by the
update algorithm and adjusts the phase and frequency of the logical
clock using mechanisms such as described in Section 5. This may
result in either a step change or a gradual slew adjustment of the
logical clock to reduce the offset to zero. The logical clock
provides a stable source of time information to other users of the
system and for subsequent reference by NTP itself.
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2.2. Network Configurations
A primary time server is connected to a primary reference source,
usually a radio clock synchronized to national standard time. A
secondary time server derives time synchronization, possibly via
other secondary servers, from a primary server. Under normal
circumstances it is intended that a subnet of primary and secondary
servers assumes a hierarchical master-slave configuration with the
more accurate servers near the top and the less accurate below.
Following conventions established by the telephone industry, the
accuracy of each server is defined by a number called its stratum,
with the stratum of a primary server assigned as one and each level
downwards in the hierarchy assigned as one greater than the preceding
level. With current technology and available receiving equipment,
single-sample accuracies in the order of a millisecond can be
achieved at the radio clock interface and in the order of a few
milliseconds at the packet interface to the net. Accuracies of this
order require special care in the design and implementation of the
operating system, such as described in [15], and the logical clock
mechanism, such as described in Section 5.
As the stratum increases from one, the single-sample accuracies
achievable will degrade depending on the communication paths and
local clock stabilities. In order to avoid the tedious calculations
[4] necessary to estimate errors in each specific configuration, it
is useful to assume the errors accumulate approximately in proportion
to the minimum total roundtrip path delay between each server and the
primary reference source to which it is synchronized. This is called
the synchronization distance.
Again drawing from the experience of the telephone industry, who
learned such lessons at considerable cost, the synchronization paths
should be organized to produce the highest accuracies, but must never
be allowed to form a loop. The clock filter and selection algorithms
used in NTP accomplish this by using a variant of the Bellman-Ford
distributed routing algorithm [29] to compute the minimum-weight
spanning trees rooted on the primary servers. This results in each
server operating at the lowest stratum and, in case of multiple peers
at the same stratum, at the lowest synchronization distance.
As a result of the above design, the subnet reconfigures
automatically in a hierarchical master-slave configuration to produce
the most accurate time, even when one or more primary or secondary
servers or the communication paths between them fail. This includes
the case where all normal primary servers (e.g., backbone WWVB
clocks) on a possibly partitioned subnet fail, but one or more backup
primary servers (e.g., local WWV clocks) continue operation.
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However, should all primary servers throughout the subnet fail, the
remaining secondary servers will synchronize among themselves for
some time and then gradually drop off the subnet and coast using
their last offset and frequency computations. Since these
computations are expected to be very precise, especially in
frequency, even extend outage periods of a day or more should result
in timekeeping errors of not over a few tens of milliseconds.
In the case of multiple primary servers, the spanning-tree
computation will usually select the server at minimum synchronization
distance. However, when these servers are at approximately the same
distance, the computation may result in random selections among them
as the result of normal dispersive delays. Ordinarily this does not
degrade accuracy as long as any discrepancy between the primary
servers is small compared to the synchronization distance. If not,
the filter and selection algorithms will select the best of the
available servers and cast out outlyers as intended.
2.3. Time Scales
Since 1972 the various national time scales have been based on
International Atomic Time (TA), which is currently maintained using
multiple cesium-beam clocks to an accuracy of a few parts in 10^12.
The Bureau International de l'Heure (BIH) uses astronomical
observations provided by the US Naval Observatory and other
observatories to determine corrections for small changes in the mean
rotation period of the Earth. This results in Universal Coordinated
Time (UTC), which is presently decreasing from TA at a fraction of a
second per year. When the magnitude of the correction approaches 0.7
second, a leap second is inserted or deleted in the UTC time scale on
the last day of June or December. Further information on time scales
can be found in [26].
For the most precise coordination and timestamping of events since
1972 it is necessary to know when leap seconds were inserted or
deleted in UTC and how the seconds are numbered. A leap second is
inserted following second 23:59:59 on the last day of June or
December and becomes second 23:59:60 of that day. A leap second
would be deleted by omitting second 23:59:59 on one of these days,
although this has never happened. Leap seconds were inserted on the
following fourteen occasions prior to January 1988 (courtesy US Naval
Observatory):
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1 June 1972 8 December 1978
2 December 1972 9 December 1979
3 December 1973 10 June 1981
4 December 1974 11 June 1982
5 December 1975 12 June 1983
6 December 1976 13 June 1985
7 December 1977 14 December 1987
Table 2.1. Dates of Leap-Second Insertion
Like UTC, NTP operates with an abstract oscillator synchronized in
frequency to the TA time scale. At 0000 hours on 1 January 1972 the
NTP time scale was set to 2,272,060,800, representing the number of
TA seconds since 0000 hours on 1 January 1900. The insertion of leap
seconds in UTC does not affect the oscillator itself, only the
translation between TA and UTC, or conventional civil time. However,
since the only institutional memory assumed by NTP is the UTC radio
broadcast service, the NTP time scale is in effect reset to UTC as
each offset estimate is computed. When a leap second is inserted in
UTC and subsequently in NTP, knowledge of all previous leap seconds
is lost. Thus, if a clock synchronized to NTP in early 1988 was used
to establish the time of an event that occured in early 1972, it
would be fourteen seconds early.
When NTP is used to measure intervals between events that straddle a
leap second, special considerations apply. When it is necessary to
determine the elapsed time between events, such as the half life of a
proton, NTP timestamps of these events can be used directly. When it
is necessary to establish the order of events relative to UTC, such
as the order of funds transfers, NTP timestamps can also be used
directly; however, if it is necessary to establish the elapsed time
between events relative to UTC, such as the intervals between
payments on a mortgage, NTP timestamps must be converted to UTC using
the above table and its successors.
The current formats used by NBS radio broadcast services [2] do not
include provisions for advance notice of leap seconds, so this
information must be determined from other sources. NTP includes
provisions to distribute advance warnings of leap seconds using the
Leap Indicator bits described in Section 3. The protocol is designed
so that these bits can be set manually at the primary clocks and then
automatically distributed throughout the system for delivery to all
logical clocks and then effected as described in Section 5.
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3. Network Time Protocol
This section consists of a formal definition of the Network Time
Protocol, including its data formats, entities, state variables,
events and event-processing procedures. The specification model is
based on the implementation model illustrated in Figure 2.1, but it
is not intended that this model is the only one upon which a
specification can be based. In particular, the specification is
intended to illustrate and clarify the intrinsic operations of NTP
and serve as a foundation for a more rigorous, comprehensive and
verifiable specification.
3.1. Data Formats
All mathematical operations expressed or implied herein are in
two's-complement arithmetic. Data are specified as integer or
fixed-point quantities. Since various implementations would be
expected to scale externally derived quantities for internal use,
neither the precision nor decimal-point placement for fixed-point
quantities is specified. Unless specified otherwise, all quantities
are unsigned and may occupy the full field width, if designated, with
an implied zero preceding the most significant (leftmost) bit.
Hardware and software packages designed to work with signed
quantities will thus yield surprising results when the most
significant (sign) bit is set. It is suggested that externally
derived, unsigned fixed-point quantities such as timestamps be
shifted right one bit for internal use, since the precision
represented by the full field width is seldom justified.
Since NTP timestamps are cherished data and, in fact, represent the
main product of the protocol, a special timestamp format has been
established. NTP timestamps are represented as a 64-bit unsigned
fixed-point number, in seconds relative to 0000 UT on 1 January 1900.
The integer part is in the first 32 bits and the fraction part in the
last 32 bits, as shown in the following diagram.
This format allows convenient multiple-precision arithmetic and
conversion to Time Protocol representation (seconds), but does
complicate the conversion to ICMP Timestamp message representation
(milliseconds). The precision of this representation is about 0.2
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nanosecond, which should be adequate for even the most exotic
requirements.
Timestamps are determined by copying the current value of the logical
clock to a timestamp variable when some significant event, such as
the arrival of a message, occurs. In order to maintain the highest
accuracy, it is important that this be done as close to the hardware
or software driver associated with the event as possible. In
particular, departure timestamps should be redetermined for each
link-level retransmission. In some cases a particular timestamp may
not be available, such as when the host is rebooted or the protocol
first starts up. In these cases the 64-bit field is set to zero,
indicating the value is invalid or undefined.
Note that since some time in 1968 the most significant bit (bit 0 of
the Integer Part) has been set and that the 64-bit field will
overflow some time in 2036. Should NTP be in use in 2036, some
external means will be necessary to qualify time relative to 1900 and
time relative to 2036 (and other multiples of 136 years).
Timestamped data requiring such qualification will be so precious
that appropriate means should be readily available. There will exist
an 0.2-nanosecond interval, henceforth ignored, every 136 years when
the 64-bit field will be zero and thus considered invalid.
3.2. State Variables and Parameters
Following is a tabular summary of the various state variables and
parameters used by the protocol. They are separated into classes of
system variables, which relate to the operating system environment
and logical clock mechanism; peer variables, which are specific to
each peer operating in symmetric mode or client mode; packet
variables, which represent the contents of the NTP message; and
parameters, which are fixed in all implementations of the current
version. For each class the description of the variable is followed
by its name and the procedure or value which controls it. Note that
variables are in lower case, while parameters are in upper case.
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System Variables Name Control
-------------------------------------------------------
Logical Clock sys.clock update
Clock Source sys.peer selection
algorithm
Leap Indicator sys.leap update
Stratum sys.stratum update
Precision sys.precision system
Synchronizing Distance sys.distance update
Estimated Drift Rate sys.drift system
Reference Clock Identifier sys.refid update
Reference Timestamp sys.reftime update
Table 3.1. System Variables
Peer Variables Name Control
-------------------------------------------------------
Peer Address peer.srcadr system
Peer Port peer.srcport system
Local Address peer.dstadr system
Local Port peer.dstport system
Peer State peer.state receive,
transmit
Reachability Register peer.reach receive,
transmit
Peer Timer peer.timer system
Timer Threshold peer.threshold system
Leap Indicator peer.leap receive
Stratum peer.stratum receive
Peer Poll Interval peer.ppoll receive
Host Poll Interval peer.hpoll receive,
transmit
Precision peer.precision receive
Synchronizing Distance peer.distance receive
Estimated Drift Rate peer.drift receive
Reference Clock Identifier peer.refid receive
Reference Timestamp peer.reftime receive
Originate Timestamp peer.org receive
Receive Timestamp peer.rec receive
Filter Register peer.filter filter
algorithm
Delay Estimate peer.delay filter
algorithm
Offset Estimate peer.offset filter
algorithm
Dispersion Estimate peer.dispersion filter
Table 3.2. Peer Variables
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Packet Variables Name Control
-------------------------------------------------------
Peer Address pkt.srcadr transmit
Peer Port pkt.srcport transmit
Local Address pkt.dstadr transmit
Local Port pkt.dstport transmit
Leap Indicator pkt.leap transmit
Version Number pkt.version transmit
Stratum pkt.stratum transmit
Poll pkt.poll transmit
Precision pkt.precision transmit
Synchronizing Distance pkt.distance transmit
Estimated Drift Rate pkt.drift transmit
Reference Clock Identifier pkt.refid transmit
Reference Timestamp pkt.reftime transmit
Originate Timestamp pkt.org transmit
Receive Timestamp pkt.rec transmit
Transmit Timestamp pkt.xmt transmit
Table 3.3. Packet Variables
Parameters Name Value
-------------------------------------------------------
NTP Version NTP.VERSION 1
NTP Port NTP.PORT 123
Minimum Polling Interval NTP.MINPOLL 6 (64 sec)
Maximum Polling Interval NTP.MAXPOLL 10 (1024
sec)
Maximum Dispersion NTP.MAXDISP 65535 ms
Reachability Register Size PEER.WINDOW 8
Shift Register Size PEER.SHIFT 4/8
Dispersion Threshold PEER.THRESHOLD 500 ms
Filter Weight PEER.FILTER .5
Select Weight PEER.SELECT .75
Table 3.4. Parameters
Following is a description of the various variables used in the
protocol. Additional details on formats and use are presented in
later sections and appendices.
3.2.1. Common Variables
The following variables are common to the system, peer and packet
classes.
Peer Address (peer.srcadr, pkt.srcadr) Peer Port (peer.srcport,
pkt.srcport)
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These are the 32-bit Internet address and 16-bit port number of
the remote host.
Local Address (peer.dstadr, pkt.dstadr) Local Port (peer.dstport,
pkt.dstport)
These are the 32-bit Internet address and 16-bit port number of
the local host. They are included among the state variables to
support multi-homing.
Leap Indicator (sys.leap, peer.leap, pkt.leap)
This is a two-bit code warning of an impending leap second to be
inserted in the NTP time scale. The bits are set before 23:59 on
the day of insertion and reset after 00:01 on the following day.
This causes the number of seconds (rollover interval) in the day
of insertion to be increased or decreased by one. In the case of
primary servers the bits are set by operator intervention, while
in the case of secondary servers the bits are set by the protocol.
The two bits are coded as follows:
00 no warning (day has 86400 seconds)
01 +1 second (day has 86401 seconds)
seconds)
10 -1 second (day has 86399 seconds)
seconds)
11 alarm condition (clock not synchronized)
In all except the alarm condition (11) NTP itself does nothing
with these bits, except pass them on to the time-conversion
routines that are not part of NTP. The alarm condition occurs
when, for whatever reason, the logical clock is not synchronized,
such as when first coming up or after an extended period when no
outside reference source is available.
Stratum (sys.stratum, peer.stratum, pkt.stratum)
This is an integer indicating the stratum of the logical clock. A
value of zero is interpreted as unspecified, one as a primary
clock (synchronized by outside means) and remaining values as the
stratum level (synchronized by NTP). For comparison purposes a
value of zero is considered greater than any other value.
Peer Poll Interval (peer.ppoll, pkt.poll)
This is a signed integer used only in symmetric mode and
indicating the minimum interval between messages sent to the peer,
in seconds as a power of two. For instance, a value of six
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indicates a minimum interval of 64 seconds. The value of this
variable must not be less than NTP.MINPOLL and must not be greater
than NTP.MAXPOLL.
This is a signed integer indicating the precision of the logical
clock, in seconds to the nearest power of two. For instance, a
60-Hz line-frequency clock would be assigned the value -6, while a
1000-Hz crystal-derived clock would be assigned the value -10.
This is a code identifying the particular reference clock or
server. The interpretation of the value depends on the stratum.
For stratum values of zero (unspecified) or one (primary clock),
the value is an ASCII string identifying the reason or clock,
respectively. For stratum values greater than one (synchronized
by NTP), the value is the 32-bit Internet address of the reference
server.
This is the local time, in timestamp format, when the logical
clock was last updated. If the logical clock has never been
synchronized, the value is zero.
3.2.2. System Variables
The following variables are used by the operating system in order to
synchronize the logical clock.
Logical Clock (sys.clock)
This is the current local time, in timestamp format. Local time
is derived from the hardware clock of the particular machine and
increments at intervals depending on the design used. An
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RFC 1059 Network Time Protocol July 1988
appropriate design, including slewing and drift-compensation
mechanisms, is described in Section 5.
Clock Source (sys.peer)
This is a selector identifying the current clock source. Usually
this will be a pointer to a structure containing the peer
variables.
3.2.3. Peer Variables
Following is a list of state variables used by the peer management
and measurement functions. There is one set of these variables for
every peer operating in client mode or symmetric mode.
Peer State (peer.state)
This is a bit-encoded quantity used for various control functions.
Host Poll Interval (peer.hpoll)
This is a signed integer used only in symmetric mode and
indicating the minimum interval between messages expected from the
peer, in seconds as a power of two. For instance, a value of six
indicates a minimum interval of 64 seconds. The value of this
variable must not be less than NTP.MINPOLL and must not be greater
than NTP.MAXPOLL.
Reachability Register (peer.reach)
This is a code used to determine the reachability status of the
peer. It is used as a shift register, with bits entering from the
least significant (rightmost) end. The size of this register is
specified as PEER.SHIFT bits.
Peer Timer (peer.timer)
This is an integer counter used to control the interval between
transmitted NTP messages.
Timer Threshold (peer.threshold)
This is the timer value which, when reached, causes the timeout
procedure to be executed.
Originate Timestamp (peer.org, pkt.org)
This is the local time, in timestamp format, at the peer when its
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latest NTP message was sent. If the peer becomes unreachable the
value is set to zero.
Receive Timestamp (peer.rec, pkt.rec)
This is the local time, in timestamp format, when the latest NTP
message from the peer arrived. If the peer becomes unreachable
the value is set to zero.
3.2.4. Packet Variables
Following is a list of variables used in NTP messages in addition to
the common variables above.
Version Number (pkt.version)
This is an integer indicating the version number of the sender.
NTP messages will always be sent with the current version number
NTP.VERSION and will always be accepted if the version number
matches NTP.VERSION. Exceptions may be advised on a case-by-case
basis at times when the version number is changed.
Transmit Timestamp (pkt.xmt)
This is the local time, in timestamp format, at which the NTP
message departed the sender.
3.2.5. Clock Filter Variables
When the filter and selection algorithms suggested in Section 4 are
used, the following state variables are defined. There is one set of
these variables for every peer operating in client mode or symmetric
mode.
Filter Register (peer.filter)
This is a shift register of PEER.WINDOW bits, where each stage is
a tuple consisting of the measured delay concatenated with the
measured offset associated with a single observation.
Delay/offset observations enter from the least significant
(rightmost) right and are shifted towards the most significant
(leftmost) end and eventually discarded as new observations
arrive. The register is cleared to zeros when (a) the peer
becomes unreachable or (b) the logical clock has just been reset
so as to cause a significant discontinuity in local time.
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Delay Estimate (peer.delay)
This is a signed, fixed-point number indicating the latest delay
estimate output from the filter, in seconds. While the number is
signed, only those values greater than zero represent valid delay
estimates.
Offset Estimate (peer.offset)
This is a signed, fixed-point number indicating the latest offset
estimate output from the filter, in seconds.
Dispersion Estimate (peer.dispersion)
This is a fixed-point number indicating the latest dispersion
estimate output from the filter, in scrambled units.
3.2.6. Parameters
Following is a list of parameters assumed for all implementations
operating in the Internet system. It is necessary to agree on the
values for these parameters in order to avoid unnecessary network
overheads and stable peer associations.
Version Number (NTP.VERSION)
This is the NTP version number, currently one (1).
NTP Port (NTP.PORT)
This is the port number (123) assigned by the Internet Number Czar
to NTP.
Minimum Polling Interval (NTP.MINPOLL)
This is the minimum polling interval allowed by any peer of the
Internet system, currently set to 6 (64 seconds).
Maximum Polling Interval (NTP.MAXPOLL)
This is the maximum polling interval allowed by any peer of the
Internet system, currently set to 10 (1024 seconds).
Maximum Dispersion (NTP.MAXDISP)
This is the maximum dispersion assumed by the filter algorithms,
currently set to 65535 milliseconds.
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Reachability Register Size (PEER.WINDOW)
This is the size of the Reachability Register (peer.reach),
currently set to eight (8) bits.
Shift Register Size (PEER.SHIFT)
When the filter and selection algorithms suggested in Section 4
are used, this is the size of the Clock Filter (peer.filter) shift
register, in bits. For crystal-stabilized oscillators a value of
eight (8) is suggested, while for mains-frequency oscillators a
value of four (4) is suggested. Additional considerations are
given in Section 5.
Dispersion Threshold (PEER.THRESHOLD)
When the filter and selection algorithms suggested in Section 4
are used, this is the threshold used to discard noisy data. While
a value of 500 milliseconds is suggested, the value may be changed
to suit local conditions on particular peer paths.
Filter Weight (PEER.FILTER)
When the filter algorithm suggested in Section 4 is used, this is
the filter weight used to discard noisy data. While a value of
0.5 is suggested, the value may be changed to suit local
conditions on particular peer paths.
Select Weight (PEER.SELECT)
When the selection algorithm suggested in Section 4 is used, this
is the select weight used to discard outlyers. data. While a
value of 0.75 is suggested, the value may be changed to suit local
conditions on particular peer paths.
3.3. Modes of Operation
An NTP host can operate in three modes: client, server and
symmetric. The mode of operation is determined by whether the source
port (peer.srcport) or destination port (peer.dstport) peer variables
contain the assigned NTP service port number NTP.PORT (123) as shown
in the following table.
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peer.srcport peer.dstport Mode
-------------------------------------------
not NTP.PORT not NTP.PORT not possible
not NTP.PORT NTP.PORT server
NTP.PORT not NTP.PORT client
NTP.PORT NTP.PORT symmetric
A host operating in client mode occasionally sends an NTP message to
a host operating in server mode. The server responds by simply
interchanging addresses and ports, filling in the required
information and returning the message to the client. Servers then
need retain no state information between client requests. Clients
are free to manage the intervals between sending NTP messages to suit
local conditions.
In symmetric mode the client/server distinction disappears. Each
host maintains a table with as many entries as active peers. Each
entry includes a code uniquely identifying the peer (e.g., Internet
address and port), together with status information and a copy of the
timestamps last received. A host operating in symmetric mode
periodically sends NTP messages to each peer including the latest
copy of the timestamps. The intervals between sending NTP messages
are managed jointly by the host and each peer using the polling
variables peer.ppoll and peer.hpoll.
When a pair of peers operating in symmetric mode exchange NTP
messages and each determines that the other is reachable, an
association is formed. One or both peers must be in active state;
that is, sending messages to the other regardless of reachability
status. A peer not in active state is in passive state. If a peer
operating in passive state discovers that the other peer is no longer
reachable, it ceases sending messages and reclaims the storage and
timer resources used by the association. A peer operating in client
mode is always in active state, while a peer operating in server mode
is always in passive state.
3.4. Event Processing
The significant events of interest in NTP occur upon expiration of
the peer timer, one of which is dedicated to each peer operating in
symmetric or client modes, and upon arrival of an NTP message from
the various peers. An event can also occur as the result of an
operator command or detected system fault, such as a primary clock
failure. This section describes the procedures invoked when these
events occur.
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3.4.1. Timeout Procedure
The timeout procedure is called in client and symmetric modes when
the peer timer (peer.timer) reaches the value of the timer threshold
(peer.threshold) variable. First, the reachability register
(peer.reach) is shifted one position to the left and a zero replaces
the vacated bit. Then an NTP message is constructed and sent to the
peer. If operating in active state or in passive state and
peer.reach is nonzero (reachable), the peer.timer is reinitialized
(resumes counting from zero) and the value of peer.threshold is set
to:
Then the clock selection algorithm is called, which may result in a
new clock source (sys.peer). In other cases the protocol ceases
operation and the storage and timer resources are reclaimed for
subsequent use.
An NTP message is constructed as follows (see Appendices A and B for
formats). First, the IP and UDP packet variables are copied from the
peer variables (note the interchange of source and destination
addresses and ports):
Note that the order of copying should be designed so that the time to
perform the copy operations themselves does not degrade the
measurement accuracy, which implies that the sys.clock values should
be copied last. The reason for the choice of zeros to fill the
pkt.org and pkt.rec packet variables in the symmetric unreachable
case is to avoid the use of old data after a possibly extensive
period of unreachability. The reason for the choice of sys.clock to
fill these variables in the client case is that, if for some reason
the NTP message is returned by the recipient unaltered, as when
testing with an Internet-echo server, this convention still allows at
least the roundtrip time to be accurately determined without special
handling.
3.4.2. Receive Procedure
The receive procedure is executed upon arrival of an NTP message. If
the version number of the message (pkt.version) does not match the
current version number (NTP.VERSION), the message is discarded;
however, exceptions may be advised on a case-by-case basis at times
when the version number is changed.
If the clock of the sender is unsynchronized (pkt.leap = 11), or the
receiver is in server mode or the receiver is in symmetric mode and
the stratum of the sender is greater than the stratum of the receiver
(pkt.stratum > sys.stratum), the message is simply returned to the
sender along with the timestamps. In this case the addresses and
ports are interchanged in the IP and UDP headers:
Finally, the message is forwarded to the sender and the server
receive procedure terminated at this point.
If the above is not the case, the source and destination Internet
addresses and ports in the IP and UDP headers are matched to the
correct peer. If there is a match, processing continues at the next
step below. If there is no match and symmetric mode is not indicated
(either pkt.srcport or pkt.dstport not equal to NTP.PORT), the
message must be a reply to a previously sent message from a client
which is no longer in operation. In this case the message is dropped
and the receive procedure terminated at this point.
If there is no match and symmetric mode is indicated, (both
pkt.srcport and pkt.dstport equal to NTP.PORT), an implementation-
specific instantiation procedure is called to create and initialize a
new set of peer variables and start the peer timer. The following
peer variables are set from the IP and UDP headers:
The remaining peer variables are undefined and set to zero.
Assuming that instantiation is complete and that match occurs, the
least significant bit of the reachability register (peer.reach) is
set, indicating the peer is now reachable. The following peer
variables are copied (rescaled as necessary) from the NTP packet
variables and system variables:
If either or both the pkt.org or pkt.rec packet variables are zero,
the sender did not have reliable values for them, so the receive
procedure is terminated at this point. If both of these variables
are nonzero, the roundtrip delay and clock offset relative to the
peer are calculated as follows. Number the times of sending and
receiving NTP messages as shown in Figure 3.1 and let i be an even
integer. Then t(i-3), t(i-2) and t(i-1) and t(i) are the contents of
the pkt.org, pkt.rec, pkt.xmt and peer.rec variables respectively.
The roundtrip delay d and clock offset c of the receiving peer
relative to the sending peer is:
d = (t(i) - t(i-3)) - (t(i-1) - t(i-2))
c = [(t(i-2) - t(i-3)) + (t(i-1) - t(i))]/2 .
This method amounts to a continuously sampled, returnable-time
system, which is used in some digital telephone networks. Among the
advantages are that the order and timing of the messages is
unimportant and that reliable delivery is not required. Obviously,
the accuracies achievable depend upon the statistical properties of
the outbound and inbound net paths. Further analysis and
experimental results bearing on this issue can be found in
Appendix D.
The c and d values are then input to the clock filter algorithm to
produce the delay estimate (peer.delay) and offset estimate
(peer.offset) for the peer involved. If d becomes nonpositive due to
low delays, long polling intervals and high drift rates, it should be
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considered invalid; however, even under these conditions it may
still be useful to update the local clock and reduce the drift rate
to the point that d becomes positive again. Specification of the
clock filter algorithm is not an integral part of the NTP
specification; however, one found to work well in the Internet
environment is described in Section 4.
When a primary clock is connected to the host, it is convenient to
incorporate its information into the data base as if the clock were
represented by an ordinary peer. The clocks are usually polled once
or twice a minute and the returned timecheck used to produce a new
update for the logical clock. The update procedure is then called
with the following assumed peer variables:
In this case the peer.delay and peer.refid can be constants
reflecting the type and accuracy of the clock. By convention, the
value for peer.delay is ten times the expected mean error of the
clock, for instance, 10 milliseconds for a WWVB clock and 1000
milliseconds for a less accurate WWV clock, but with a floor of 100
milliseconds. Other peer variables such as the peer timer and
reachability register can be used to control the polling interval and
to confirm the clock is operating correctly. In this way the clock
filter and selection algorithms operate in the usual way and can be
used to mitigate the clock itself, should it appear to be operating
correctly, yet deliver bogus time.
3.4.3. Update Procedure
The update procedure is called when a new delay/offset estimate is
available. First, the clock selection algorithm determines the best
peer on the basis of estimated accuracy and reliability, which may
result in a new clock source (sys.peer). If sys.peer points to the
peer data structure with the just-updated estimates, the state
variables of that peer are used to update the system state variables
Finally, the logical clock procedure is called with peer.offset as
argument to update the logical clock (sys.clock) and recompute the
estimated drift rate (sys.drift). It may happen that the logical
clock may be reset, rather than slewed to its final value. In this
case the peer variables of all reachable peers are are updated as
follows:
and the clock selection algorithm is called again, which results in a
null clock source (sys.peer = 0). A new selection will occur when
the filters fill up again and the dispersion settles down.
Specification of the clock selection algorithm and logical clock
procedure is not an integral part of the NTP specification. A clock
selection algorithm found to work well in the Internet environment is
described in Section 4, while a logical clock procedure is described
in Section 5. The clock selection algorithm described in Section 4
usually picks the server at the highest stratum and minimum delay
among all those available, unless that server appears to be a
falseticker. The result is that the algorithms all work to build a
minimum-weight spanning tree relative to the primary servers and thus
a hierarchical master-slave system similar to those used by some
digital telephone networks.
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3.4.4. Initialization Procedures
Upon reboot the NTP host initializes all system variables as follows:
sys.clock <- best available estimate
sys.leap <- 11 (unsynchronized)
sys.stratum <- 0 (undefined)
sys.precision <- as required
sys.distance <- 0 (undefined)
sys.drift <- as determined
sys.refid <- 0 (undefined)
sys.reftime <- 0 (undefined)
The logical clock sys.clock is presumably undefined at reboot;
however, in some designs such as the Fuzzball an estimate is
available from the reboot environment. The sys.precision variable is
determined by the intrinsic architecture of the local hardware clock.
The sys.drift variable is determined as a side effect of subsequent
logical clock updates, from whatever source.
Next, an implementation-specific instantiation procedure is called
repeatedly to establish the set of client peers or symmetric (active)
peers which will actively probe other servers during regular
operation. The mode and addresses of these peers is determined using
information read during the reboot procedure or as the result of
operator commands.
4. Filtering Algorithms
A very important factor affecting the accuracy and reliability of
time distribution is the complex of algorithms used to deglitch and
smooth the offset estimates and to cast out outlyers due to failure
of the primary reference sources or propagation media. The
algorithms suggested in this section were developed and refined over
several years of operation in the Internet under widely varying net
configurations and utilizations. While these algorithms are believed
the best available at the present time, they are not an integral part
of the NTP specification.
There are two algorithms described in the following, the clock filter
algorithm, which is used to select the best offset samples from a
given clock, and the clock selection algorithm, which is used to
select the best clock among a hierarchical set of clocks.
4.1. Clock Filter Algorithm
The clock filter algorithm is executed upon arrival of each NTP
message that results in new delay/offset sample pairs. New sample
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RFC 1059 Network Time Protocol July 1988
pairs are shifted into the filter register (peer.filter) from the
left end, causing first zeros then old sample pairs to shift off the
right end. Then those sample pairs in peer.filter with nonzero delay
are inserted on a temporary list and sorted in order of increasing
delay. The delay estimate (peer.delay) and offset estimate
(peer.offset) are chosen as the delay/offset values corresponding to
the minimum-delay sample. In case of ties an arbitrary choice is
made.
The dispersion estimate (peer.dispersion) is then computed as the
weighted sum of the offsets in the list. Assume the list has
PEER.SHIFT entries, the first m of which contain valid samples in
order of increasing delay. If X(i) (0 =< i < PEER.SHIFT) is the
offset of the ith sample, then,
d(i) = |X(i) - X(0)| if i < m and |X(i) - X(0)| < 2^15
d(i) = 2^15 - 1 otherwise
peer.dispersion = Sum(d(i)*w^i) ,
(0 =< i < PEER.SHIFT)
where w < 1 is a weighting factor experimentally adjusted to match
typical offset distributions. The peer.dispersion variable is
intended for use as a quality indicator, with increasing values
associated with decreasing quality. The intent is that samples with
a peer.dispersion exceeding a configuration threshold will not be
used in subsequent processing. The prototype implementation uses a
weighting factor w = 0.5, also called PEER.FILTER, and a threshold
PEER.THRESHOLD of 500 ms, which insures that all stages of
peer.filter are filled and contain offsets within a few seconds of
each other.
4.2. Clock Selection Algorithm
The clock selection algorithm uses the values of peer.delay,
peer.offset and peer.dispersion calculated by the clock filter
algorithm and is called when these values change or when the
reachability status changes. It constructs a list of candidate
estimates according to a set of criteria designed to maximize
accuracy and reliability, then sorts the list in order of estimated
precision. Finally, it repeatedly casts out outlyers on the basis of
dispersion until only a single candidate is left.
The selection process operates on each peer in turn and inspects the
various data captured from the last received NTP message header, as
well as the latest clock filter estimates. It selects only those
peers for which the following criteria are satisfied:
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RFC 1059 Network Time Protocol July 1988
1. The peer must be reachable and operating in client or symmetric
modes.
2. The peer logical clock must be synchronized, as indicated by the
Leap Indicator bits being other than 11.
3. If the peer is operating at stratum two or greater, it must not
be synchronized to this host, which means its reference clock
identifier (peer.refid) must not match the Internet address of
this host. This is analogous to the split-horizon rule used in
some variants of the Bellman-Ford routing algorithm.
4. The sum of the peer synchronizing distance (peer.distance) plus
peer.delay must be less than 2^13 (8192) milliseconds. Also, the
peer stratum (peer.stratum) must be less than eight and
peer.dispersion must be less than a configured threshold
PEER.THRESHOLD (currently 500 ms). These range checks were
established through experience with the prototype implementation,
but may be changed in future.
For each peer which satisfies the above criteria, a sixteen-bit
keyword is constructed, with the low-order thirteen bits the sum of
peer.distance plus peer.delay and the high-order three bits the
peer.stratum reduced by one and truncated to three bits (thus mapping
zero to seven). The keyword together with a pointer to the peer data
structure are inserted according to increasing keyword values and
truncated at a maximum of eight entries. The resulting list
represents the order in which peers should be chosen according to the
estimated precision of measurement. If no keywords are found, the
clock source variable (sys.peer) is set to zero and the algorithm
terminates.
The final procedure is designed to detect falsetickers or other
conditions which might result in gross errors. Let m be the number
of samples remaining in the list. For each i (0 =< i < m) compute
the dispersion d(i) of the list relative to i:
d(i) = Sum(|X(j) - X(i)|*w^j) ,
(0 =< j < m)
where w < 1 is a weighting factor experimentally adjusted for the
desired characteristic (see below). Then cast out the entry with
maximum d(i) or, in case of ties, the maximum i, and repeat the
procedure. When only a single entry remains in the list, sys.peer is
set as its peer data structure pointer and the peer.hpoll variable in
that structure is set to NTP.MINPOLL as required by the logical clock
mechanism described in Section 5.
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This procedure is designed to favor those peers near the head of the
list, which are at the highest stratum and lowest delay and
presumably can provide the most precise time. With proper selection
of weighting factor w, also called PEER.SELECT, entries will be
trimmed from the tail of the list, unless a few outlyers disagree
significantly with respect to the remaining entries, in which case
the outlyers are discarded first.
In order to see how this procedure works to select outlyers, consider
the case of three entries and assume that one or more of the offsets
are clustered about zero and others are clustered about one. For w =
0.75 as used in the prototype implementations and multiplying by 16
for convenience, the first entry has weight w^0 = 16, the second w^1
= 12 and the third w^2 = 9. Table X shows for all combinations of
peer offsets the calculated dispersion about each of the three
entries, along with the results of the procedure.
In the four cases where peer 0 and peer 1 disagree, the outcome is
determined by peer 2. Similar outcomes occur in the case of four
peers. While these outcomes depend on judicious choice of w, the
behavior of the algorithm is substantially the same for values of w
between 0.5 and 1.0.
4.3. Variable-Rate Polling
As NTP service matures in the Internet, the resulting network traffic
can become burdensome, especially in the primary service net. In
this expectation, it is useful to explore variable-rate polling, in
which the intervals between NTP messages can be adjusted to fit
prevailing network conditions of delay dispersion and loss rate. The
prototype NTP implementation uses this technique to reduce the
network overheads to one-sixteenth the maximum rate, depending on
observed dispersion and loss.
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The prototype implementation adjusts the polling interval peer.hpoll
in response to the reachability register (peer.reach) variable along
with the dispersion (peer.dispersion) variable. So long as the clock
source variable (sys.peer) does not point to the peer data structure,
peer.reach is nonzero (reachable) and peer.dispersion is less than
the PEER.THRESHOLD parameter, the value of peer.hpoll is increased by
one for each call on the update procedure, subject to a maximum of
NTP.MAXPOLL. Following the timeout procedure, if peer.reach
indicates messages have not been received for the preceding two
polling intervals (low-order two bits are zero), the value of
peer.hpoll is decreased by one, subject to a minimum of NTP.MINPOLL.
If peer.reach becomes zero (unreachable), the value of peer.hpoll is
set to NTP.MINPOLL.
The result of the above mechanism is that the polling intervals for
peers not selected for synchronization and in symmetric mode creep
upwards once the filter register (peer.filter) has filled and the
peer.dispersion has settled down, but decrease again in case
peer.dispersion increases or the loss rate increases or the peer
becomes unreachable.
5. Logical Clocks
In order to implement a logical clock, the host must be equipped with
a hardware clock consisting of an oscillator and interface and
capable of the required precision and stability. The logical clock
is adjusted by means of periodic offset corrections computed by NTP
or some other time-synchronization protocol such as Hellospeak [15]
or the Unix 4.3bsd TSP [20]. Following is a description of the
Fuzzball logical clock, which includes provisions for precise time
and frequency adjustment and can maintain time to within a
millisecond and frequency to within a day per millisecond.
The logical clock is implemented using a 48-bit Clock Register, which
increments at 1000-Hz (at the decimal point), a 32-bit Clock-Adjust
Register, which is used to slew the Clock Register in response to
offset corrections, and a Drift-Compensation Register, which is used
to trim the oscillator frequency. In some interface designs such as
the DEC KWV11, an additional hardware register, the Counter Register,
is used as an auxiliary counter. The configuration and decimal point
of these registers are shown in Figure 5.1.
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RFC 1059 Network Time Protocol July 1988
Clock Register
0 16 32
+---------------+---------------+---------------+
| | | |
+---------------+---------------+---------------+
A
decimal point
Clock-Adjust Register
0 16
+---------------+---------------+
| | |
+---------------+---------------+
A
decimal point
Drift-Compensation Register
0 16
+---------------+
| |
+---------------+
A
decimal point
Counter Register
0 16
+---------------+
| |
+---------------+
A
decimal point
Figure 5.1. Clock Registers
The Clock Register, Clock-Adjust Register and Drift-Compensation
Register are implemented in memory. In typical clock interface
designs such as the DEC KWV11, the Counter Register is implemented as
a buffered counter driven by a crystal oscillator. A counter
overflow is signalled by an interrupt, which results in an increment
of the Clock Register at bit 15 and the propagation of carries as
required. The time of day is determined by reading the Counter
Register, which does not disturb the counting process, and adding its
value to that of the Clock Register with decimal points aligned.
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In other interface designs such as the LSI-11 event-line mechanism,
each tick of the clock is signalled by an interrupt at intervals of
16-2/3 or 20 ms, depending on interface and mains frequency. When
this occurs the appropriate increment in milliseconds, expressed to
32 bits in precision, is added to the Clock Register with decimal
points aligned.
5.1. Uniform Phase Adjustments
Left uncorrected, the logical clock runs at the rate of its intrinsic
oscillator. A correction is introduced as a signed 32-bit integer in
milliseconds, which is added to the Drift-Compensation Register and
also replaces bits 0-15 of the Clock-Adjust Register, with bits 16-31
set to zero. At adjustment intervals of CLOCK.ADJ a correction
consisting of two components is computed. The first (phase)
component consists of the Clock-Adjust Register shifted right
CLOCK.PHASE bits, which is then subtracted from the Clock-Adjust
Register. The second (frequency) component consists of the Drift-
Compensation Register shifted right CLOCK.FREQ bits. The sum of the
phase and frequency components is the correction, which is then added
to the Clock Register. Operation continues in this way until a new
correction is introduced.
Care is required in the implementation to insure monotonicity of the
Clock Register and to preserve the highest precision while minimizing
the propagation of roundoff errors. This can be done by buffering
the corrections and adding them to the increment at the time the
Clock Register is next updated. Monotonicity is insured with the
parameters shown in Table 5.1, as long as the increment is at least 2
ms. This table shows the above parameters and others discussed below
for both a crystal-stabilized oscillator and a mains-frequency
oscillator.
Parameter Name Crystal Mains
-------------------------------------------------------------------
Update Interval CLOCK.ADJ 4 sec 1 sec
Phase Shift CLOCK.PHASE -8 -9
Frequency Shift CLOCK.FREQ -16 -16
Maximum Aperture CLOCK.MAX +-128 ms +-256 ms
Shift Register Size PEER.SHIFT 8 4
Host Poll Interval peer.hpoll NTP.MINPOLL NTP.MINPOLL
(64 sec) (64 sec)
Table 5.1. Clock Parameters
The above design constitutes a second-order phase-lock loop which
adjusts the logical clock phase and frequency to compensate for the
intrinsic oscillator jitter, wander and drift. Simulation of a loop
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with parameters chosen from Table 5.1 for a crystal-stabilized
oscillator and the clock filter described in Section 4 results in the
following transient response: For a phase correction of 100 ms the
loop reaches zero error in 34 minutes, overshoots 7 ms in 76 minutes
and settles to less than 1 ms in about four hours. The maximum
frequency error is about 6 ppm at 40 minutes and returns to less than
1 ppm in about eight hours. For a frequency correction of 10 ppm the
loop settles to within 1 ppm in about nine hours and to within 0.1
ppm in about a day. These characteristics are appropriate for
typical computing equipment using board-mounted crystals without oven
temperature control.
In those cases where mains-frequency oscillators must be used, the
loop parameters must be adapted for the relatively high jitter and
wander characteristics of the national power grid, in which diurnal
peak-to-peak phase excursions can exceed four seconds. Simulation of
a loop with parameters chosen from Table 5.1 for a mains-frequency
oscillator and the clock filter described in Section 4 results in a
transient response similar to the crystal-stabilized case, but with
time constants only one-fourth those in that case. When presented
with actual phase-offset data for typical Summer days when the jitter
and wander are the largest, the loop errors are in the order of a few
tens of milliseconds, but not greater than 150 ms.
The above simulations assume the clock filter algorithm operates to
select the oldest sample in the shift register at each step; that
is, the filter operates as a delay line with delay equal to the
polling interval times the number of stages. This is a worst-case
scenario, since the larger the overall delay the harder it is to
maintain low loop errors together with good transient response. The
parameters in Table 5.1 were experimentally determined with this
scenario and the constraint that the polling interval could not be
reduced below 64 seconds. With these parameters it is not possible
to increase the polling interval above 64 seconds without significant
increase in loop error or degradation of transient response. Thus,
when a clock is selected according to the algorithms of Section 4,
the polling interval peer.hpoll is always set at NTP.MINPOLL.
5.2. Nonuniform Phase Adjustments
When the magnitude of a correction exceeds a maximum aperture
CLOCK.MAX, the possibility exists that the clock is so far out of
synchronization with the reference source that the best action is an
immediate and wholesale replacement of Clock Register contents,
rather than a graduated slewing as described above. In practice the
necessity to do this is rare and occurs when the local host or
reference source is rebooted, for example. This is fortunate, since
step changes in the clock can result in the clock apparently running
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backward, as well as incorrect delay and offset measurements of the
synchronization mechanism itself.
Considerable experience with the Internet environment suggests the
values of CLOCK.MAX tabulated in Table 5.1 as appropriate. In
practice, these values are exceeded with a single time-server source
only under conditions of the most extreme congestion or when multiple
failures of nodes or links have occured. The most common case when
the maximum is exceeded is when the time-server source is changed and
the time indicated by the new and old sources exceeds the maximum due
to systematic errors in the primary reference source or large
differences in the synchronizing path delays.
5.3. Maintaining Date and Time
Conversion from NTP format to the common date and time formats used
by application programs is simplified if the internal local-clock
format uses separate date and time registers. The time register is
designed to roll over at 24 hours, give or take a leap second as
determined by the Leap Indicator bits, with its overflows
(underflows) incrementing (decrementing) the date register. The date
and time registers then indicate the number of days and seconds since
some previous reference time, but uncorrected for leap seconds.
On the day prior to the insertion of a leap second the Leap Indicator
bits are set at the primary servers, presumably by manual means.
Subsequently, these bits show up at the local host and are passed to
the logical clock procedure. This causes the modulus of the time
register, which is the length of the current day, to be increased or
decreased by one second as appropriate. On the day following
insertion the bits are turned off at the primary servers. While it
is possible to turn the bits off automatically, the procedure
suggested here insures that all clocks have rolled over and will not
be reset incorrectly to the previous day as the result of possible
corrections near the instant of rollover.
5.4. Estimating Errors
After an NTP message is received and until the next one is received,
the accuracy of the local clock can be expected to degrade somewhat.
The magnitude of this degradation depends on the error at the last
update time together with the drift of the local oscillator with
respect to time. It is possible to estimate both the error and drift
rate from data collected during regular operation. These data can be
used to determine the rate at which NTP neighbors should exchange NTP
messages and thus control net overheads.
NTP messages include the local-clock precision of the sender, as well
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RFC 1059 Network Time Protocol July 1988
as the reference time, estimated drift and a quantity called the
synchronizing distance. The precision of the local clock, together
with its peer clocks, establishes the short-term jitter
characteristics of the offset estimates. The reference time and
estimated drift of the sender provide an error estimate at the time
the latest update was received. The synchronizing distance provides
an estimate of error relative to the primary reference source and is
used by the filtering algorithms to improve the quality and
reliability of the offset estimates.
Estimates of error and drift rate are not essential for the correct
functioning of the clock algorithms, but do improve the accuracy and
adjustment with respect to net overheads. The estimated error allows
the recipient to compute the rate at which independent samples are
required in order to maintain a specified estimated error. The
estimated drift rate allows the recipient to estimate the optimum
polling interval.
It is possible to compute the estimated drift rate of the local clock
to a high degree of precision by simply adding the n offsets received
during an interval T to an accumulator. If X1 and X2 are the values
of the accumulator at the beginning and end of T, then the estimated
drift rate r is:
X2 - X1 n
r = ------- --- .
n T
The intrinsic (uncorrected) drift rate of typical crystal oscillators
under room-temperature conditions is in the order of from a few parts
per million (ppm) to as much as 100 ppm, or up to a few seconds per
day. For most purposes the drift of a particular crystal oscillator
is constant to within perhaps one ppm. Assuming T can be estimated
to within 100 ms, for example, it would take about a day of
accumulation to estimate r to an uncertainty in the order of one ppm.
Some idea of the estimated error of the local clock can be derived
from the variance of the offsets about the mean per unit time. This
can be computed by adding the n offset squares received during T to
an accumulator. If Y1 and Y2 are the values of the accumulator at
the beginning and end of T, then the estimated error s is:
Y2 - Y1 (X2 - X1)^2 n
s = ( ------- - ----------- ) --- .
n n * n T
The quantities r and s have direct utility to the peer as noted
above. However, they also have indirect utility to the recipient of
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RFC 1059 Network Time Protocol July 1988
an NTP message sent by that peer, since they can be used as weights
in such algorithms as described in [22], as well as to improve the
estimates during periods when offsets are not available. It is most
useful if the latest estimate of these quantities are available in
each NTP message sent; however, considerable latitude remains in the
details of computation and storage.
The above formulae for r and s imply equal weighting for offsets
received throughout the accumulation interval T. One way to do this
is using a software shift register implemented as a circular buffer.
A single pointer points to the active entry in the buffer and
advances around one entry as each new offset is stored. There are
two accumulators, one for the offset and the other for its squares.
When a new offset arrives, a quantity equal to the new offset minus
the old (active) entry is added to the first accumulator and the
square of this quantity is added to the second. Finally, the offset
is stored in the circular buffer.
The size of the circular buffer depends on the accumulation interval
T and the rate offsets are produced. In many reachability and
routing algorithms, such as GGP, EGP and local-net control
algorithms, peers exchange messages on the order of once or twice a
minute. If NTP peers exchanged messages at a rate of one per minute
and if T were one day, the circular buffer would have to be 1440
words long; however, a less costly design might aggregate the data
in something like half-hour segments, which would reduce the length
of the buffer to 48 words while not significantly affecting the
quality of the data.
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6. References
1. Lamport, L., "Time, Clocks and the Ordering of Events in a
Distributed System", Communications of the ACM, Vol. 21, No. 7,
pgs. 558-565, July 1978.
2. "Time and Frequency Dissemination Services", NBS Special
Publication No. 432, US Department of Commerce, 1979.
3. Lindsay, W., and A. Kantak, "Network Synchronization of Random
Signals", IEEE Trans. Comm., COM-28, No. 8, pgs. 1260-1266,
August 1980.
4. Braun, W., "Short Term Frequency Effects in Networks of Coupled
Oscillators", IEEE Trans. Comm., COM-28, No. 8, pgs. 1269-1275,
August 1980.
5. Mitra, D., "Network Synchronization: Analysis of a Hybrid of
Master-Slave and Mutual Synchronization", IEEE Trans. Comm.
COM-28, No. 8, pgs. 1245-1259, August 1980.
6. Postel, J., "User Datagram Protocol", RFC-768, USC/Information
Sciences Institute, August 1980.
7. Mills, D., "Time Synchronization in DCNET Hosts", IEN-173, COMSAT
Laboratories, February 1981.
8. Mills, D., "DCNET Internet Clock Service", RFC-778, COMSAT
Laboratories, April 1981.
9. Su, Z., "A Specification of the Internet Protocol (IP) Timestamp
Option", RFC-781, SRI International, May 1981.
10. Defense Advanced Research Projects Agency, "Internet Protocol",
RFC-791, USC/Information Sciences Institute, September 1981.
11. Defense Advanced Research Projects Agency, "Internet Control
Message Protocol", RFC-792, USC/Information Sciences Institute,
September 1981.
12. Postel, J., "Daytime Protocol", RFC-867, USC/Information Sciences
Institute, May 1983.
13. Postel, J., "Time Protocol", RFC-868, USC/Information Sciences
Institute, May 1983.
14. Mills, D., "Internet Delay Experiments", RFC-889, M/A-COM
Linkabit, December 1983.
Mills [Page 40]
RFC 1059 Network Time Protocol July 1988
15. Mills, D., "DCN Local-Network Protocols", RFC-891, M/A-COM
Linkabit, December 1983.
16. Gusella, R., and S. Zatti, "TEMPO - A Network Time Controller for
a Distributed Berkeley UNIX System", IEEE Distributed Processing
Technical Committee Newsletter 6, No. SI-2, pgs. 7-15, June 1984.
Also in: Proc. Summer 1984 USENIX, Salt Lake City, June 1984.
17. Halpern, J., Simons, B., Strong, R., and D. Dolly, "Fault-
Tolerant Clock Synchronization", Proc. Third Annual ACM Symposium
on Principles of Distributed Computing, pgs. 89-102, August 1984.
18. Lundelius, J., and N. Lynch, "A New Fault-Tolerant Algorithm for
Clock Synchronization:, Proc. Third Annual ACM Symposium on
Principles of Distributed Computing, pgs. 75-88, August 1984.
19. Lamport, L., and P. Melliar-Smith "Synchronizing Clocks in the
Presence of Faults", JACM 32, No. 1, pgs. 52-78, January 1985.
20. Gusella, R., and S. Zatti, "The Berkeley UNIX 4.3BSD Time
Synchronization Protocol: Protocol Specification", Technical
Report UCB/CSD 85/250, University of California, Berkeley, June
1985.
21. Marzullo, K., and S. Owicki, "Maintaining the Time in a
Distributed System", ACM Operating Systems Review 19, No. 3, pgs.
44-54, July 1985.
22. Mills, D., "Algorithms for Synchronizing Network Clocks", RFC-
956, M/A-COM Linkabit, September 1985.
23. Mills, D., "Experiments in Network Clock Synchronization", RFC-
957, M/A-COM Linkabit, September 1985.
24. Mills, D., "Network Time Protocol (NTP)", RFC-958, M/A-COM
Linkabit, September 1985.
25. Gusella, R., and S. Zatti, "An Election Algorithm for a
Distributed Clock Synchronization Program", Technical Report
UCB/CSD 86/275, University of California, Berkeley, December
1985.
26. Sams, H., "Reference Data for Engineers: Radio, Electronics,
Computer and Communications (Seventh Edition)", Indianapolis,
1985.
27. Schneider, F., "A Paradigm for Reliable Clock Synchronization",
Technical Report TR 86-735, Cornell University, February 1986.
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RFC 1059 Network Time Protocol July 1988
28. Tripathi, S., and S. Chang, "ETempo: A Clock Synchronization
Algorithm for Hierarchical LANs - Implementation and
Measurements", Systems Research Center Technical Report TR-86-48,
University of Maryland, 1986.
29. Bertsekas, D., and R. Gallager, "Data Networks", Prentice-Hall,
Englewood Cliffs, NJ, 1987.
30. Srikanth, T., and S. Toueg. "Optimal Clock Synchronization", JACM
34, No. 3, pgs. 626-645, July 1987.
31. Rickert, N., "Non Byzantine Clock Synchronization - A Programming
Experiment", ACM Operating Systems Review 22, No. 1, pgs. 73-78,
January 1988.
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Appendix A. UDP Header Format
An NTP packet consists of the UDP header followed by the NTP data
portion. The format of the UDP header and the interpretation of its
fields are described in [6] and are not part of the NTP
specification. They are shown below for completeness.
UDP source port number. In the case of a client request this
field is assigned by the client host, while for a server reply
it is copied from the Destination Port field of the client
request. In the case of symmetric mode, both the Source Port
and Destination Port fields are assigned the NTP service-port
number 123.
Destination Port
UDP destination port number. In the case of a client request
this field is assigned the NTP service-port number 123, while
for a server reply it is copied from the Source Port field of
the client request. In the case of symmetric mode, both the
Source Port and Destination Port fields are assigned the NTP
service-port number 123.
Length
Length of the request or reply, including UDP header, in
octets
Checksum
Standard UDP checksum
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Appendix B. NTP Data Format - Version 1
The format of the NTP data portion, which immediately follows the UDP
header, is shown below along with a description of its fields.
Two-bit code warning of impending leap-second to be inserted
at the end of the last day of the current month. Bits are
coded as follows:
00 no warning
01 +1 second (following minute has 61 seconds)
10 -1 second (following minute has 59 seconds)
11 alarm condition (clock not synchronized)
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Version Number (VN)
Three-bit code indicating the version number, currently one
(1).
Reserved
Three-bit field consisting of all zeros and reserved for
future use.
Stratum
Integer identifying stratum level of local clock. Values are
defined as follows:
Signed integer indicating the maximum interval between
successive messages, in seconds to the nearest power of two.
Precision
Signed integer indicating the precision of the local clock, in
seconds to the nearest power of two.
Synchronizing Distance
Fixed-point number indicating the estimated roundtrip delay to
the primary synchronizing source, in seconds with fraction
point between bits 15 and 16.
Estimated Drift Rate
Fixed-point number indicating the estimated drift rate of the
local clock, in dimensionless units with fraction point to the
left of the most significant bit.
Reference Clock Identifier
Code identifying the particular reference clock. In the case
of type 0 (unspecified) or type 1 (primary reference), this is
a left-justified, zero-filled ASCII string, for example:
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RFC 1059 Network Time Protocol July 1988
Type Code Meaning
---------------------------------------------------
0 DCN Determined by DCN routing algorithm
1 WWVB WWVB radio clock (60 kHz)
1 GOES GOES satellite clock (468 MHz)
1 WWV WWV radio clock (5/10/15 MHz)
(and others as necessary)
In the case of type 2 and greater (secondary reference), this
is the 32-bit Internet address of the reference host.
Reference Timestamp
Local time at which the local clock was last set or corrected.
Originate Timestamp
Local time at which the request departed the client host for
the service host.
Receive Timestamp
Local time at which the request arrived at the service host.
Transmit Timestamp
Local time at which the reply departed the service host for
the client host.
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RFC 1059 Network Time Protocol July 1988
Appendix C. Timeteller Experiments
In order to update data collected in June 1985 and reported in RFC-
957, a glorious three-day experiment was carried out in January 1988
with all the hosts and gateways listed in the NIC data base. Four
packets were sent at five-second intervals to each host and gateway
using UDP/NTP, UDP/TIME and ICMP/TIMESTAMP protocols and the clock
offsets (in milliseconds) for each protocol averaged with respect to
local time, which is synchronized via NTP to a radio-clock host.
While the ICMP/TIMESTAMP protocol has much finer granularity
(milliseconds) than UDP/TIME (seconds), it has no provisions for the
date, so is not suitable as a time-synchronization protocol;
however, it was included in the experiments both as a sanity check
and in order to assess the precision of measurement.
In the latest survey of 5498 hosts and 224 gateways, 46 responded to
UDP/NTP requests, 1158 to UDP/TIME and 1963 to ICMP/TIMESTAMP. By
contrast, in the 1985 survey of 1775 hosts and 110 gateways, 163
responded to UDP/TIME requests and 504 to ICMP/TIMESTAMP. At that
time there were no UDP/NTP implementations. There are many more
hosts and gateways listed in the rapidly growing domain-name system,
but not listed in the NIC data base, and therefore not surveyed. The
results of the survey are given in Table C.1, which shows for each of
the three protocols the error X for which the distribution function
P[x =< X] has the value shown.
It can be seen that ten percent of the UDP/NTP responses show errors
of 11 milliseconds or less and that ten percent of the UDP/TIME
responses show errors greater than 807135 milliseconds (about 13
minutes). Fifty percent of the UDP/NTP timetellers are within 364
milliseconds, while fifty percent of the UDP/TIME tellers are within
126232 milliseconds (just over two minutes). Surprisingly,
ICMP/TIMESTAMP responses show errors even larger than UDP/TIME.
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However, the maximum error shown in all three protocols exceeded the
range that could be recorded, in this case about 12 days. Clearly,
there are good timetellers and bad.
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RFC 1059 Network Time Protocol July 1988
Appendix D. Evaluation of Filtering Algorithms
A number of algorithms for deglitching and filtering time-offset data
were described in RFC-956. These fall in two classes: majority-
subset algorithms, which attempt to separate good subsets from bad by
comparing their means, and clustering algorithms, which attempt to
improve the estimate by repeatedly casting out outlyers. The former
class was suggested as a technique to select the best (i.e. the most
reliable) clocks from a population, while the latter class was
suggested as a technique to improve the offset estimate for a single
clock given a series of observations.
Following publication of RFC-956 and after further development and
experimentation using typical Internet paths, a better algorithm was
found for casting out outlyers from a continuous stream of offset
observations spaced at intervals in the order of minutes. The
algorithm is described as a variant of a median filter, in which a
window consisting of the last n sample offsets is continuously
updated and the median sample selected as the estimate. However, in
the modified algorithm the outlyer (sample furthest from the median)
is then discarded and the entire process repeated until only a single
sample offset is left, which is then selected as the estimate.
The modified algorithm was found to be more resistant to glitches and
to provide a more accurate estimate than the unmodified one. It has
been implemented in the NTP daemons developed for the Fuzzball and
Unix operating systems and been in regular operation for about two
years. However, recent experiments have shown there is an even
better one which provides comparable accuracy together with a much
lower computational burden. The key to the new algorithm became
evident through an examination of scatter diagrams plotting sample
offset versus roundtrip delay.
To see how a scatter diagram is constructed, it will be useful to
consider how offsets and delays are computed. Number the times of
sending and receiving NTP messages as shown in Figure D.1 and let i
be an even integer. Then the timestamps t(i-3), t(i-2) and t(i-1)
and t(i) are sufficient to calculate the offset and delay of each
peer relative to the other.
The roundtrip delay d and clock offset c of the receiving peer
relative to the sending peer are:
d = (t(i) - t(i-3)) - (t(i-1) - t(i-2))
c = [(t(i-2) - t(i-3)) + (t(i-1) - t(i))]/2 .
Two implicit assumptions in the above are that the delay distribution
is independent of direction and that the intrinsic drift rates of the
client and server clocks are small and close to the same value. If
this is the case the scatter diagram would show the samples
concentrated about a horizontal line extending from the point (d,c)
to the right. However, this is not generally the case. The typical
diagram shows the samples dispersed in a wedge with apex (d,c) and
opening to the right. The limits of the wedge are determined by
lines extending from (d,c) with slopes +0.5 and -0.5, which
correspond to the locus of points as the delay in one direction
increases while the delay in the other direction does not. In some
cases the points are concentrated along these two extrema lines, with
relatively few points remaining within the opening of the wedge,
which would correspond to increased delays on both directions.
Upon reflection, the reason for the particular dispersion shown in
the scatter diagram is obvious. Packet-switching nets are most often
operated with relatively small mean queue lengths in the order of
one, which means the queues are often idle for relatively long
periods. In addition, the routing algorithm most often operates to
minimize the number of packet-switch hops and thus the number of
queues. Thus, not only is the probability that an arriving NTP
packet finds a busy queue in one direction reasonably low, but the
probability of it finding a busy queue in both directions is even
lower.
From the above discussion one would expect that, at low utilizations
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RFC 1059 Network Time Protocol July 1988
and hop counts the points should be concentrated about the apex of
the wedge and begin to extend rightward along the extrema lines as
the utilizations and hop counts increase. As the utilizations and
hop counts continue to increase, the points should begin to fill in
the wedge as it expands even further rightward. This behavior is in
fact what is observed on typical Internet paths involving ARPANET,
NSFNET and other nets.
These observations cast doubt on the median-filter approach as a good
way to cast out offset outlyers and suggests another approach which
might be called a minimum filter. From the scatter diagrams it is
obvious that the best offset samples occur at the lower delays.
Therefore, an appropriate technique would be simply to select from
the n most recent samples the sample with lowest delay and use its
associated offset as the estimate. An experiment was designed to
test this technique using measurements between selected hosts
equipped with radio clocks, so that delays and offsets could be
determined independent of the measurement procedure itself.
The raw delays and offsets were measured by NTP from hosts at U
Maryland (UMD) and U Delaware (UDEL) via net paths to each other and
other hosts at Ford Research (FORD), Information Sciences Institute
(ISI) and National Center for Atmospheric Research (NCAR). For the
purposes here, all hosts can be assumed synchronized to within a few
milliseconds to NBS time, so that the delays and offsets reflect only
the net paths themselves.
The results of the measurements are given in Table D.1 (UMD) and
Table D.2 (UDEL), which show for each of the paths the error X for
which the distribution function P[x =< X] has the value shown. Note
that the values of the distribution function are shown by intervals
of decreasing size as the function increases, so that its behavior in
the interesting regime of low error probability can be more
accurately determined.
The results suggest that accuracies less than a few seconds can
usually be achieved for all but one percent of the measurements, but
that accuracies degrade drastically when the remaining measurements
are included. Note that in the case of the UMD measurements to FORD
almost half the measurements showed gross errors, which was due to
equipment failure at that site. These data were intentionally left
in the sample set to see how well the algorithms dealt with the
problem.
The next two tables compare the results of minimum filters (Table
D.3) and median filters (Table D.4) for various n when presented with
the UMD - - NCAR raw sample data. The results show consistently
lower errors for the minimum filter when compared with the median
filter of nearest value of n. Perhaps the most dramatic result of
both filters is the greatly reduced error at the upper end of the
range. In fact, using either filter with n at least three results in
no errors greater than 100 milliseconds.
While the UMD - NCAR data above represented a path across the NSFNET
Backbone, which normally involves only a few hops via Ethernets and
56-Kbps links, the UDEL - NCAR path involves additional ARPANET hops,
which can contribute substantial additional delay dispersion. The
following Table D.5. shows the results of a minimum filter for
various n when presented with the UDEL - NCAR raw sample data. The
range of error is markedly greater than the UMD - NCAR path above,
especially near the upper end of the distribution function.
Based on these data, the minimum filter was selected as the standard
algorithm. Since its performance did not seem to much improve for
values of n above eight, this value was chosen as the standard.
Network Time Protocol (Version 1): Specification and Implementation.
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Appendix E. NTP Synchronization Networks
This section discusses net configuration issues for implementing a
ubiquitous NTP service in the Internet system. Section E.1 describes
the NTP primary service net now in operation, including an analysis
of failure scenarios. Section E.2 suggests how secondary service
nets, which obtain wholesale time from the primary service net, can
be configured to deliver accurate and reliable retail time to the
general host population.
E.1. Primary Service Network
The primary service net consists of five primary servers, each of
which is synchronized via radio or satellite to a national time
standard and thus operates at stratum one. Each server consists of
an LSI-11 Fuzzball, a WWVB or GOES radio clock and one or more net
interfaces. Some servers provide switching and gateway services as
well. Table E.1 shows the name, Internet address, type of clock,
operating institution and identifying code.
Name Address Clock Operating Institution and (Code)
----------------------------------------------------------------------
DCN5.ARPA 128.4.0.5 WWVB U Delaware, Newark, DE (UDEL)
FORD1.ARPA 128.5.0.1 GOES Ford Research, Dearborn, MI
(FORD)
NCAR.NSF.NET 128.116.64.3 WWVB National Center for Atmospheric
Research, Boulder, CO (NCAR)
UMD1.UMD.EDU 128.8.10.1 WWVB U Maryland, College Park, MD
(UMD)
WWVB.ISI.EDU 128.9.2.129 WWVB USC Information Sciences
Institute, Marina del Rey, CA
(ISI)
Table E.1. Primary Servers
Figure E.1 shows how the five primary servers are interconnected as
NTP peers. Note that each server actively probes two other servers
(along the direction of the arrows), which means these probes will
continue even if one or both of the two probed servers are down. On
the other hand, each server is probed by two other servers, so that
the result, assuming all servers are up, is that every server peers
with every other server.
All of the five primary servers shown are directly connected to a
radio clock and thus normally operate at stratum one. However, if
the radio clock itself becomes disabled or the propagation path to
its synchronizing source fails, then the server drops to stratum two
and synchronizes via NTP with its neighbor at the smallest
synchronizing distance. If a radio clock appears to operate
correctly but delivers incorrect time (falseticker), the server may
remain synchronized to the clock. However, gross discrepancies will
become apparent via the NTP peer paths, which will ordinarily result
in an operator alarm.
Assume that, if a radio clock appears up, it is a truechimer;
otherwise, the clock appears down. Then the above configuration will
continue to provide correct time at all primary servers as long as at
least one radio clock is up, all servers are up and the servers
remain connected to each other through the net. The fact that the
graph and all of its subgraphs are completely connected lends an
incredible resilience to the configuration.
If some radio clocks appear up but are in fact falsetickers, the
primary servers connected to those clocks will not provide correct
time. However, as the consequents of the voting procedure and
complete connectivity of the graph and its subgraphs, any combination
of two falsetickers or of one falseticker and one down server will be
detected by their truechimer neighbors.
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RFC 1059 Network Time Protocol July 1988
E.2. Secondary Service Networks
A secondary server operating at stratum n > 1 ordinarily obtains
synchronization using at least three peer paths, two with servers at
stratum n-1 and one or more with servers at stratum n. In the most
robust configurations a set of servers agree to provide backup
service for each other, so distribute some of their peer paths over
stratum-(n-1) servers and others over stratum-n servers in the same
set. For instance, in the case of a stratum-2 service net with two
secondary servers and the primary service net of Figure E.1, there
are five possible configurations where each stratum-1 path ends on a
different primary server. Such configurations can survive the loss
of three out of the four stratum-1 servers or net paths and will
reject a single falseticker on one of the two stratum-1 paths for
each server.
Ordinary hosts can obtain retail time from primary or secondary
service net using NTP in client/server mode, which does not require
dedicated server resources as does symmetric mode. It is anticipated
that ordinary hosts will be quite close to a secondary server,
perhaps on the same cable or local net, so that the frequency of NTP
request messages need only be high enough, perhaps one per hour or
two, to trim the drift from the local clock.
