Mitigation Rules and the prefer Keyword


Introduction

The mechanics of the NTP algorithms which select the best data sample from each available peer and the best subset of the peer population have been finely crafted to resist network jitter, faults in the network or peer operations, and to deliver the best possible accuracy. Most of the time these algorithms do a good job without requiring explicit manual tailoring of the configuration file. However, there are times when the accuracy can be improved by some careful tailoring. The following sections explain how to do this using explicit configuration items and special signals, when available, that are generated by some radio clocks.

In order to provide robust backup sources, primary (stratum-1) servers are usually operated in a diversity configuration, in which the server operates with a number of remote peers in addition to one or more radio or modem clocks operating as local peers. In these configurations the suite of algorithms used in NTP to refine the data from each peer separately and to select and weight the data from a number of peers are used with the entire ensemble of remote peers and local peers. As the result of these algorithms, a set of survivors are identified which can presumably provide the most reliable and accurate time. Ordinarily, the individual clock offsets of the survivors are combined on a weighted average basis to produce an offset used to control the system clock.

However, because of small but significant systematic time offsets between the survivors, it is in general not possible to achieve the lowest jitter and highest stability in these configurations. This happens because the selection algorithm tends to clockhop between survivors of substantially the same quality, but showing small systematic offsets between them. In addition, there are a number of configurations involving pulse-per-second (PPS) signals, modem backup services and other special cases, so that a set of mitigation rules becomes necessary to select a single peer from among the survivors. These rules are based on a set of special characteristics of the various peers and reference clock drivers specified in the configuration file.

The prefer Peer

The mitigation rules are designed to provide an intelligent selection between various peers of substantially the same statistical quality. They is designed to provide the best quality time without compromising the normal operation of the NTP algorithms. The mitigation scheme in its present form is not an integral component of the NTP Version 3 specification RFC- 1305. but is to be included in the version 4 specification when it is published. The scheme is based on the concept of prefer peer, which is specified by including the prefer keyword with the associated server or peer command in the configuration file. This keyword can be used with any peer or server, but is most commonly used with a radio clock. While the scheme does not forbid it, it does not seem useful to designate more than one peer as preferred, since the additional complexities to mitigate among them do not seem justified from on-air experience.

The prefer scheme works on the set of peers that have survived the sanity checks and intersection algorithms of the clock selection procedures. Ordinarily, the members of this set can be considered truechimers and any one of them could in principle provide correct time; however, due to various error contributions, not all can provide the most accurate and stable time. The job of the clustering algorithm, which is invoked at this point, is to select the best subset of the survivors providing the least variance in the combined ensemble average, compared to the variance in each member of the subset separately. The detailed operation of the clustering algorithm, which is given in the specification, is not important here, other than to point out it operates in rounds, where a survivor, presumably the worst of the lot, is discarded in each round until one of several termination conditions is met.

In the prefer scheme the clustering algorithm is modified so that the prefer peer is never discarded; on the contrary, its potential removal becomes a termination condition. If the original algorithm were about to toss out the prefer peer, the algorithm terminates right there. The prefer peer can still be discarded by the sanity checks and intersection algorithms, of course, but it will always survive the clustering algorithm. If it does not survive or for some reason it fails to provide updates, it will eventually become unreachable and the clock selection will remitigate to select the next best source.

Along with this behavior, the clock selection procedures are modified so that the combining algorithm is not used when a prefer peer is present. Instead, the offset of the prefer peer is used exclusively as the synchronization source. In the usual case involving a radio clock and a flock of remote stratum-1 peers, and with the radio clock designated a prefer peer, the result is that the high quality radio time disciplines the server clock as long as the radio itself remains operational and with valid time, as determined from the remote peers, sanity checks and intersection algorithm.

Peer Classification

In order to understand the effects of the various intricate schemes involved, it is necessary to understand some arcane details on how the algorithms decide on a synchronization source, when more than one source is available. This is done on the basis of a set of explicit mitigation rules, which define special classes of remote and local peers as a function of configuration declarations and reference clock driver type:

  1. The prefer peer is designated using the prefer keyword with the server or peer commands. All other things being equal, this peer will be selected for synchronization over all other survivors of the clock selection procedures.
  2. When a PPS signal is connected via the PPS Clock Discipline driver (type 22), this is called the PPS peer. This driver provides precision clock corrections only within one second, so is always operated in conjunction with another peer or reference clock driver, which provides the seconds numbering. The PPS peer is active only under conditions explained below.
  3. When the Undisciplined Local Clock driver (type 1) is configured, this is called the local clock peer. This is used either as a backup reference source (stratum greater than zero), should all other synchronization sources fail, or as the primary reference source (stratum zero) in cases where the kernel time is disciplined by some other means of synchronization, such as the NIST lockclock scheme, or another synchronization protocol, such as the Digital Time Synchronization Service (DTSS).
  4. When a modem driver such as the Automated Computer Time Service driver (type 18) is configured, this is called the modem peer. This is used either as a backup reference source, should all other primary sources fail, or as the (only) primary reference source.
  5. Where support is available, the PPS signal may be processed directly by the kernel, as described in the A Kernel Model for Precision Timekeeping page. This is called the kernel discipline. The PPS signal can discipline the kernel in both frequency and time. The frequency discipline is active as long as the PPS interface device and signal itself is operating correctly, as determined by the kernel algorithms. The time discipline is active only under conditions explained below.

Reference clock drivers operate in the manner described in the Reference Clock Drivers page and its dependencies. The drivers are ordinarily operated at stratum zero, so that as the result of ordinary NTP operations, the server itself operates at stratum one, as required by the NTP specification. In some cases described below, the driver is intentionally operated at an elevated stratum, so that it will be selected only if no other survivor is present with a lower stratum. In the case of the PPS peer or kernel time discipline, these sources appear active only if the prefer peer has survived the intersection and clustering algorithms, as described below, and its clock offset relative to the current local clock is less than a specified value, currently 128 ms.

The modem clock drivers are a special case. Ordinarily, the update interval between modem calls to synchronize the system clock is many times longer than the interval between polls of either the remote or local peers. In order to provide the best stability, the operation of the clock discipline algorithm changes gradually from a phase-lock mode at the shorter update intervals to a frequency-lock mode at the longer update intervals. If both remote or local peers together with a modem peer are operated in the same configuration, what can happen is that first the clock selection algorithm can select one or more remote/local peers and the clock discipline algorithm will optimize for the shorter update intervals. Then, the selection algorithm can select the modem peer, which requires a much different optimization. The intent in the design is to allow the modem peer to control the system clock either when no other source is available or, if the modem peer happens to be marked as prefer, then it always controls the clock, as long as it passes the sanity checks and intersection algorithm. There still is room for suboptimal operation in this scheme, since a noise spike can still cause a clockhop either way. Nevertheless, the optimization function is slow to adapt, so that a clockhop or two does not cause much harm.

The local clock driver is another special case. Normally, this driver is eligible for selection only if no other source is available. When selected, vernier adjustments introduced via the configuration file or remotely using the ntpdc program can be used to trim the local clock frequency and time. However, if the local clock driver is designated the prefer peer, this driver is always selected and all other sources are ignored. This behavior is intended for use when the kernel time is controlled by some means external to NTP, such as the NIST lockclock algorithm or  another time synchronization protocol such as DTSS. In this case the only way to disable the local clock driver is to mark it unsynchronized using the leap indicator bits. In the case of modified kernels with the ntp_adjtime() system call, this can be done automatically if the external synchronization protocol uses it to discipline the kernel time.

Mitigation Rules

The mitigation rules apply in the intersection and clustering algorithms described in the NTP specification. The intersection algorithm first scans all peers with a persistent association and includes only those that satisfy specified sanity checks. In addition to the checks required by the specification, the mitigation rules require either the local- clock peer or modem peer to be included only if marked as the prefer peer. The intersection algorithm operates on the included population to select only those peers believed to represent the correct time. If one or more peers survive the operation, processing continues in the clustering algorithm. Otherwise, if there is a modem peer, it is declared the only survivor; otherwise, if there is a local-clock peer, it is declared the only survivor. Processing then continues in the clustering algorithm.

The clustering algorithm repeatedly discards outlyers in order to reduce the residual jitter in the survivor population. As required by the NTP specification, these operations continue until either a specified minimum number of survivors remain or the minimum select dispersion of the population is greater than the maximum peer dispersion of any member. The mitigation rules require an additional terminating condition which stops these operations at the point where the prefer peer is about to be discarded.

The mitigation rules establish the choice of system peer, which determine the stratum, reference identifier and several other system variables which are visible to clients of the local server. In addition, they establish which source or combination of sources control the local clock.

  1. If there is a prefer peer and it is the local-clock peer or the modem peer; or, if there is a prefer peer and the kernel time discipline is active, choose the prefer peer as the system peer and its offset as the system clock offset. If the prefer peer is the local-clock peer, an offset can be calculated by the driver to produce a frequency offset in order to correct for systematic frequency errors. In case a source other than NTP is controlling the system clock, corrections determined by NTP can be ignored by using the disable pll in the configuration file. If the prefer peer is the modem peer, it must be the primary source for the reasons noted above. If the kernel time discipline is active, the system clock offset is ignored and the corrections handled directly by the kernel.
  2. If the above is not the case and there is a PPS peer, then choose it as the system peer and its offset as the system clock offset.
  3. If the above is not the case and there is a prefer peer (not the local-clock or modem peer in this case), then choose it as the system peer and its offset as the system clock offset.
  4. If the above is not the case and the peer previously chosen as the system peer is in the surviving population, then choose it as the system peer and average its offset along with the other survivors to determine the system clock offset. This behavior is designed to avoid excess jitter due to clockhopping, when switching the system peer would not materially improve the time accuracy.
  5. If the above is not the case, then choose the first candidate in the list of survivors ranked in order of synchronization distance and average its offset along with the other survivors to determine the system clock offset. This is the default case and the only case considered in the current NTP specification.

Using the Pulse-per-Second (PPS) Signal

Most radio clocks are connected using a serial port operating at speeds of 9600 bps or higher. The accuracy using typical timecode formats, where the on-time epoch is indicated by a designated ASCII character, like carriage-return <cr>, is limited to a millisecond at best and a few milliseconds in typical cases. However, some radios produce a PPS signal which can be used to improve the accuracy with typical workstation servers to the order of a few tens of microseconds. The details of how this can be accomplished are discussed in the Pulse-per-second (PPS) Signal Interfacing page. The following paragraphs discuss how the PPS signal is affected by the mitigation rules.

First, it should be pointed out that the PPS signal is inherently ambiguous, in that it provides a precise seconds epoch, but does not provide a way to number the seconds. In principle and most commonly, another source of synchronization, either the timecode from an associated radio clock, or even one or more remote NTP servers, is available to perform that function. In all cases, a specific, configured peer or server must be designated as associated with the PPS signal. This is done using the prefer keyword as described previously. The PPS signal can be associated in this way with any peer, but is most commonly used with the radio clock generating the PPS signal.

The PPS signal can be used in two ways to discipline the local clock, one using a special PPS driver described in the PPS Clock Discipline page, the other using PPS signal support in the kernel, as described in the A Kernel Model for Precision Timekeeping page. In either case, the signal must be present and within nominal jitter and wander error tolerances. In addition, the associated prefer peer must have survived the sanity checks and intersection algorithms and the dispersion settled below 1 s. This insures that the radio clock hardware is operating correctly and that, presumably, the PPS signal is operating correctly as well. Second, the absolute offset of the local clock from that peer must be less than 128 ms, or well within the 0.5-s unambiguous range of the PPS signal itself. In the case of the PPS driver, the time offsets generated from the PPS signal are propagated via the clock filter to the clock selection procedures just like any other peer. Should these pass the sanity checks and intersection algorithms, they will show up along with the offsets of the prefer peer itself. Note that, unlike the prefer peer, the PPS peer samples are not protected from discard by the clustering algorithm. These complicated procedures insure that the PPS offsets developed in this way are the most accurate, reliable available for synchronization.

The PPS peer remains active as long as it survives the intersection algorithm and the prefer peer is reachable; however, like any other clock driver, it runs a reachability algorithm on the PPS signal itself. If for some reason the signal fails or displays gross errors, the PPS peer will either become unreachable or stray out of the survivor population. In this case the clock selection remitigates as described above.

When kernel support for the PPS signal is available, the PPS signal is interfaced to the kernel serial driver code via a modem control lead. As the PPS signal is derived from external equipment, cables, etc., which sometimes fail, a good deal of error checking is done in the kernel to detect signal failure and excessive noise. The way in which the mitigation rules affect the kernel discipline is as follows.

The autoconfigure process normally detects the presence of the kernel support and compiles the required interface code. In order to operate, the PPS signal must be present and within nominal jitter and wander error tolerances. In the NTP daemon, the PPS discipline is active only when the prefer peer is among the survivors of the clustering algorithm, and its absolute offset is within 128 ms, as in the PPS driver. Under these conditions the kernel disregards updates produced by the NTP daemon and uses its internal PPS source instead. The kernel maintains a watchdog timer for the PPS signal; if the signal has not been heard or is out of tolerance for more than some interval, currently two minutes, the kernel discipline is declared inoperable and operation continues as if it were not present.


David L. Mills (mills@udel.edu)