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Leap second

February 15, 2024

A leap second is a one-second adjustment that is occasionally applied to Coordinated Universal Time (UTC), to accommodate the difference between precise time (International Atomic Time (TAI), as measured by atomic clocks) and imprecise observed solar time (UT1), which varies due to irregularities and long-term slowdown in the Earth's rotation. The UTC time standard, widely used for international timekeeping and as the reference for civil time in most countries, uses TAI and consequently would run ahead of observed solar time unless it is reset to UT1 as needed. The leap second facility exists to provide this adjustment. The leap second was introduced in 1972 and since then 27 leap seconds have been added to UTC.[1]

Screenshot of the UTC clock from time.gov during the leap second on 31 December 2016.

Because the Earth's rotational speed varies in response to climatic and geological events,[2] UTC leap seconds are irregularly spaced and unpredictable. Insertion of each UTC leap second is usually decided about six months in advance by the International Earth Rotation and Reference Systems Service (IERS), to ensure that the difference between the UTC and UT1 readings will never exceed 0.9 seconds.[3][4]

This practice has proven disruptive, particularly in the twenty-first century and especially in services that depend on precise timestamping or time-critical process control. And since not all computers are adjusted by leap-second, they will display times differing from those that have been adjusted.[5] After many years of discussions by different standards bodies, in November 2022, at the 27th General Conference on Weights and Measures, it was decided to abandon the leap second by or before 2035.[6][7]

History edit

 
Graph showing the difference between UT1 and UTC. Vertical segments correspond to leap seconds.

In about 140 CE, Ptolemy, the Alexandrian astronomer, sexagesimally subdivided both the mean solar day and the true solar day to at least six places after the sexagesimal point, and he used simple fractions of both the equinoctial hour and the seasonal hour, none of which resemble the modern second.[8] Muslim scholars, including al-Biruni in 1000, subdivided the mean solar day into 24 equinoctial hours, each of which was subdivided sexagesimally, that is into the units of minute, second, third, fourth and fifth, creating the modern second as 160 of 160 of 124 = 186,400 of the mean solar day in the process.[9] With this definition, the second was proposed in 1874 as the base unit of time in the CGS system of units.[10] Soon afterwards Simon Newcomb and others discovered that Earth's rotation period varied irregularly,[11] so in 1952, the International Astronomical Union (IAU) defined the second as a fraction of the sidereal year. In 1955, considering the tropical year to be more fundamental than the sidereal year, the IAU redefined the second as the fraction 131,556,925.975 of the 1900.0 mean tropical year. In 1956, a slightly more precise value of 131,556,925.9747 was adopted for the definition of the second by the International Committee for Weights and Measures, and in 1960 by the General Conference on Weights and Measures, becoming a part of the International System of Units (SI).[12]

Eventually, this definition too was found to be inadequate for precise time measurements, so in 1967, the SI second was again redefined as 9,192,631,770 periods of the radiation emitted by a caesium-133 atom in the transition between the two hyperfine levels of its ground state.[13] That value agreed to 1 part in 1010 with the astronomical (ephemeris) second then in use.[14] It was also close[quantify] to 186,400 of the mean solar day as averaged between years 1750 and 1892.

However, for the past several centuries, the length of the mean solar day has been increasing by about 1.4–1.7 ms per century, depending on the averaging time.[15][16][17] By 1961, the mean solar day was already a millisecond or two longer than 86400 SI seconds.[18] Therefore, time standards that change the date after precisely 86400 SI seconds, such as the International Atomic Time (TAI), would become increasingly ahead of time standards tied to the mean solar day, such as Universal Time (UT).

When the Coordinated Universal Time (UTC) standard was instituted in 1960, based on atomic clocks, it was felt necessary to maintain agreement with UT, which, until then, had been the reference for broadcast time services. From 1960 to 1971, the rate of UTC atomic clocks was offset from a pure atomic time scale by the BIH to remain synchronized with UT2, a practice known as the "rubber second".[19] The rate of UTC was decided at the start of each year, and was offset from the rate of atomic time by −150 parts per 1010 for 1960–1962, by −130 parts per 1010 for 1962–63, by −150 parts per 1010 again for 1964–65, and by −300 parts per 1010 for 1966–1971.[20] Alongside the shift in rate, an occasional 0.1 s step (0.05 s before 1963) was needed. This predominantly frequency-shifted rate of UTC was broadcast by MSF, WWV, and CHU among other time stations. In 1966, the CCIR approved "stepped atomic time" (SAT), which adjusted atomic time with more frequent 0.2 s adjustments to keep it within 0.1 s of UT2, because it had no rate adjustments.[21] SAT was broadcast by WWVB among other time stations.[20]

In 1972, the leap-second system was introduced so that the UTC seconds could be set exactly equal to the standard SI second, while still maintaining the UTC time of day and changes of UTC date synchronized with those of UT1.[13] By then, the UTC clock was already 10 seconds behind TAI, which had been synchronized with UT1 in 1958, but had been counting true SI seconds since then. After 1972, both clocks have been ticking in SI seconds, so the difference between their displays at any time is 10 seconds plus the total number of leap seconds that have been applied to UTC as of that time; as of May 2023, 27 leap seconds have been applied to UTC, so the difference is 10 + 27 = 37 seconds.

Insertion of leap seconds edit

Announced leap seconds to date[22]
Year 30 Jun 31 Dec
1972 +1 +1
1973 0 +1
1974 0 +1
1975 0 +1
1976 0 +1
1977 0 +1
1978 0 +1
1979 0 +1
1980 0 0
1981 +1 0
1982 +1 0
1983 +1 0
1984 0 0
1985 +1 0
1986 0 0
1987 0 +1
1988 0 0
1989 0 +1
1990 0 +1
1991 0 0
1992 +1 0
1993 +1 0
1994 +1 0
1995 0 +1
1996 0 0
1997 +1 0
1998 0 +1
1999 0 0
2000 0 0
2001 0 0
2002 0 0
2003 0 0
2004 0 0
2005 0 +1
2006 0 0
2007 0 0
2008 0 +1
2009 0 0
2010 0 0
2011 0 0
2012 +1 0
2013 0 0
2014 0 0
2015 +1 0
2016 0 +1
2017 0 0
2018 0 0
2019 0 0
2020 0 0
2021 0 0
2022 0 0
2023 0 0
2024 0
Year 30 Jun 31 Dec
Total 11 16
27
Current TAI − UTC
37

The scheduling of leap seconds was initially delegated to the Bureau International de l'Heure (BIH), but passed to the International Earth Rotation and Reference Systems Service (IERS) on 1 January 1988. IERS usually decides to apply a leap second whenever the difference between UTC and UT1 approaches 0.6 s, in order to keep the difference between UTC and UT1 from exceeding 0.9 s.

The UTC standard allows leap seconds to be applied at the end of any UTC month, with first preference to June and December and second preference to March and September. As of May 2023, all of them have been inserted at the end of either 30 June or 31 December. IERS publishes announcements every six months, whether leap seconds are to occur or not, in its "Bulletin C". Such announcements are typically published well in advance of each possible leap second date – usually in early January for 30 June and in early July for 31 December.[23][24] Some time signal broadcasts give voice announcements of an impending leap second.

Between 1972 and 2020, a leap second has been inserted about every 21 months, on average. However, the spacing is quite irregular and apparently increasing: there were no leap seconds in the six-year interval between 1 January 1999 and 31 December 31, 2004 but there were nine leap seconds in the eight years 1972–1979. Since the introduction of leap seconds, 1972 has been the longest year on record: 366 days and two seconds.

Unlike leap days, which begin after 28 February, 23:59:59 local time,[a] UTC leap seconds occur simultaneously worldwide; for example, the leap second on 31 December 2005, 23:59:60 UTC was 31 December 2005, 18:59:60 (6:59:60 p.m.) in U.S. Eastern Standard Time and 1 January 2006, 08:59:60 (a.m.) in Japan Standard Time.

Process edit

When it is mandated, a positive leap second is inserted between second 23:59:59 of a chosen UTC calendar date and second 00:00:00 of the following date. The definition of UTC states that the last day of December and June are preferred, with the last day of March or September as second preference, and the last day of any other month as third preference.[25] All leap seconds (as of 2019) have been scheduled for either 30 June or 31 December. The extra second is displayed on UTC clocks as 23:59:60. On clocks that display local time tied to UTC, the leap second may be inserted at the end of some other hour (or half-hour or quarter-hour), depending on the local time zone. A negative leap second would suppress second 23:59:59 of the last day of a chosen month so that second 23:59:58 of that date would be followed immediately by second 00:00:00 of the following date. Since the introduction of leap seconds, the mean solar day has outpaced atomic time only for very brief periods and has not triggered a negative leap second.

Slowing rotation of the Earth edit

See also: ΔT (timekeeping)
 
Deviation of day length from SI based day with shorter days resulting from faster planetary rotation.

Leap seconds are irregularly spaced because the Earth's rotation speed changes irregularly. Indeed, the Earth's rotation is quite unpredictable in the long term, which explains why leap seconds are announced only six months in advance.

A mathematical model of the variations in the length of the solar day was developed by F. R. Stephenson and L. V. Morrison,[17] based on records of eclipses for the period 700 BCE to 1623 CE, telescopic observations of occultations for the period 1623 until 1967 and atomic clocks thereafter. The model shows a steady increase of the mean solar day by 1.70 ms (±0.05 ms) per century, plus a periodic shift of about 4 ms amplitude and period of about 1,500 yr.[17] Over the last few centuries, rate of lengthening of the mean solar day has been about 1.4 ms per century, being the sum of the periodic component and the overall rate.[26]

The main reason for the slowing down of the Earth's rotation is tidal friction, which alone would lengthen the day by 2.3 ms/century.[17] Other contributing factors are the movement of the Earth's crust relative to its core, changes in mantle convection, and any other events or processes that cause a significant redistribution of mass. These processes change the Earth's moment of inertia, affecting the rate of rotation due to the conservation of angular momentum. Some of these redistributions increase Earth's rotational speed, shorten the solar day and oppose tidal friction. For example, glacial rebound shortens the solar day by 0.6 ms/century and the 2004 Indian Ocean earthquake is thought to have shortened it by 2.68 microseconds.[27]

It is a mistake, however, to consider leap seconds as indicators of a slowing of Earth's rotation rate; they are indicators of the accumulated difference between atomic time and time measured by Earth rotation.[28] The plot at the top of this section shows that in 1972 the average length of day was approximately 86400.003 seconds and in 2016 it was approximately 86400.001 seconds, indicating an overall increase in Earth's rotation rate over that time period. Positive leap seconds were inserted during that time because the annual average length of day remained greater than 86400 SI seconds, not because of any slowing of Earth's rotation rate.[29]

In 2021, it was reported that Earth was spinning faster in 2020 and experienced the 28 shortest days since 1960, each of which lasted less than 86399.999 seconds.[30] This caused engineers worldwide to discuss a negative leap second and other possible timekeeping measures, some of which could eliminate leap seconds.[31]

Future of leap seconds edit

The TAI and UT1 time scales are precisely defined, the former by atomic clocks (and thus independent of Earth's rotation) and the latter by astronomical observations (that measure actual planetary rotation and thus the solar time at the Greenwich meridian). UTC (on which civil time is usually based) is a compromise, stepping with atomic seconds but periodically reset by a leap second to match UT1.

The irregularity and unpredictability of UTC leap seconds is problematic for several areas, especially computing (see below). With increasing requirements for accuracy in automation systems and high-frequency trading,[32] this raises a number of issues. Consequently, the long-standing practice of inserting leap seconds is under review by the relevant international standards body.[33]

International proposals for elimination of leap seconds edit

On 5 July 2005, the Head of the Earth Orientation Center of the IERS sent a notice to IERS Bulletins C and D subscribers, soliciting comments on a U.S. proposal before the ITU-R Study Group 7's WP7-A to eliminate leap seconds from the UTC broadcast standard before 2008 (the ITU-R is responsible for the definition of UTC).[b] It was expected to be considered in November 2005, but the discussion has since been postponed.[35] Under the proposal, leap seconds would be technically replaced by leap hours as an attempt to satisfy the legal requirements of several ITU-R member nations that civil time be astronomically tied to the Sun.

A number of objections to the proposal have been raised. P. Kenneth Seidelmann, editor of the Explanatory Supplement to the Astronomical Almanac, wrote a letter lamenting the lack of consistent public information about the proposal and adequate justification.[36] In an op-ed for Science News, Steve Allen of the University of California, Santa Cruz said that the process has a large impact on astronomers.[37] Allen has an extensive online site devoted to the issues and the history of leap seconds,[38] including a set of references about the proposal and arguments against it.[39]

At the 2014 General Assembly of the International Union of Radio Scientists (URSI), Demetrios Matsakis, the United States Naval Observatory's Chief Scientist for Time Services, presented the reasoning in favor of the redefinition and rebuttals to the arguments made against it.[40] He stressed the practical inability of software programmers to allow for the fact that leap seconds make time appear to go backwards, particularly when most of them do not even know that leap seconds exist. The possibility of leap seconds being a hazard to navigation was presented, as well as the observed effects on commerce.

The United States formulated its position on this matter based upon the advice of the National Telecommunications and Information Administration[41] and the Federal Communications Commission (FCC), which solicited comments from the general public.[42] This position is in favor of the redefinition.[43][c]

In 2011, Chunhao Han of the Beijing Global Information Center of Application and Exploration said China had not decided what its vote would be in January 2012, but some Chinese scholars consider it important to maintain a link between civil and astronomical time due to Chinese tradition. The 2012 vote was ultimately deferred.[45] At an ITU/BIPM-sponsored workshop on the leap second, Han expressed his personal view in favor of abolishing the leap second,[46] and similar support for the redefinition was again expressed by Han, along with other Chinese timekeeping scientists, at the URSI General Assembly in 2014.

At a special session of the Asia-Pacific Telecommunity Meeting on 10 February 2015, Chunhao Han indicated China was now supporting the elimination of future leap seconds, as were all the other presenting national representatives (from Australia, Japan, and the Republic of Korea). At this meeting, Bruce Warrington (NMI, Australia) and Tsukasa Iwama (NICT, Japan) indicated particular concern for the financial markets due to the leap second occurring in the middle of a workday in their part of the world.[d] Subsequent to the CPM15-2 meeting in March/April 2015 the draft gives four methods which the WRC-15 might use to satisfy Resolution 653 from WRC-12.[49]

Arguments against the proposal include the unknown expense of such a major change and the fact that universal time will no longer correspond to mean solar time. It is also answered that two timescales that do not follow leap seconds are already available, International Atomic Time (TAI) and Global Positioning System (GPS) time. Computers, for example, could use these and convert to UTC or local civil time as necessary for output. Inexpensive GPS timing receivers are readily available, and the satellite broadcasts include the necessary information to convert GPS time to UTC. It is also easy to convert GPS time to TAI, as TAI is always exactly 19 seconds ahead of GPS time. Examples of systems based on GPS time include the CDMA digital cellular systems IS-95 and CDMA2000. In general, computer systems use UTC and synchronize their clocks using Network Time Protocol (NTP). Systems that cannot tolerate disruptions caused by leap seconds can base their time on TAI and use Precision Time Protocol. However, the BIPM has pointed out that this proliferation of timescales leads to confusion.[50]

At the 47th meeting of the Civil Global Positioning System Service Interface Committee in Fort Worth, Texas, in September 2007, it was announced that a mailed vote would go out on stopping leap seconds. The plan for the vote was:[51]

  • April 2008: ITU Working Party 7A will submit to ITU Study Group 7 project recommendation on stopping leap seconds
  • During 2008, Study Group 7 will conduct a vote through mail among member states
  • October 2011: The ITU-R released its status paper, Status of Coordinated Universal Time (UTC) study in ITU-R, in preparation for the January 2012 meeting in Geneva; the paper reported that, to date, in response to the UN agency's 2010 and 2011 web-based surveys requesting input on the topic, it had received 16 responses from the 192 Member States with "13 being in favor of change, 3 being contrary."[52]
  • January 2012: The ITU makes a decision.

In January 2012, rather than decide yes or no per this plan, the ITU decided to postpone a decision on leap seconds to the World Radiocommunication Conference in November 2015. At this conference, it was again decided to continue using leap seconds, pending further study and consideration at the next conference in 2023.[53]

In October 2014, Włodzimierz Lewandowski, chair of the timing subcommittee of the Civil GPS Interface Service Committee and a member of the ESA Navigation Program Board, presented a CGSIC-endorsed resolution to the ITU that supported the redefinition and described leap seconds as a "hazard to navigation".[54]

Some of the objections to the proposed change have been addressed by its supporters. For example, Felicitas Arias, who, as Director of the International Bureau of Weights and Measures (BIPM)'s Time, Frequency, and Gravimetry Department, was responsible for generating UTC, noted in a press release that the drift of about one minute every 60–90 years could be compared to the 16-minute annual variation between true solar time and mean solar time, the one hour offset by use of daylight time, and the several-hours offset in certain geographically extra-large time zones.[55]

Proposed alternatives to the leap second are the leap hour, which requires changes only once every few centuries;[56] and the leap minute, with changes coming every half-century.[1][57]

On 18 November 2022, the General Conference on Weights and Measures (CGPM) resolved to eliminate leap seconds by or before 2035. The difference between atomic and astronomical time will be allowed to grow to a larger value yet to be determined. A suggested possible future measure would be to let the discrepancy increase to a full minute, which would take 50 to 100 years, and then have the last minute of the day taking two minutes in a "kind of smear" with no discontinuity. The year 2035 for eliminating leap seconds was chosen considering Russia's request to extend the timeline to 2040, since, unlike the United States's global navigation satellite system, GPS, which does not adjust its time with leap seconds, Russia's system, GLONASS, does adjust its time with leap seconds.[6][7]

Issues created by insertion (or removal) of leap seconds edit

Calculation of time differences and sequence of events edit

To compute the elapsed time in seconds between two given UTC dates requires the consultation of a table of leap seconds, which needs to be updated whenever a new leap second is announced. Since leap seconds are known only 6 months in advance, time intervals for UTC dates further in the future cannot be computed.

Missing leap seconds announcement edit

Although BIPM announces a leap second 6 months in advance, most time distribution systems (SNTP, IRIG-B, PTP) announce leap seconds at most 12 hours in advance,[citation needed][58] sometimes only in the last minute and some even not at all (DNP 03).[citation needed]

Implementation differences edit

Not all clocks implement leap seconds in the same manner. Leap seconds in Unix time are commonly implemented by repeating 23:59:59 or adding the time-stamp 23:59:60. Network Time Protocol (SNTP) freezes time during the leap second,[59] some time servers declare "alarm condition".[citation needed] Other schemes smear time in the vicinity of a leap second, spreading out the second of change over a longer period. This aims to avoid any negative effects of a substantial (by modern standards) step in time.[60][61] This approach has led to differences between systems, as leap smear is not standardized and several different schemes are used in practice.[62]

Textual representation of the leap second edit

The textual representation of a leap second is defined by BIPM as "23:59:60". There are programs that are not familiar with this format and may report an error when dealing with such input.

Binary representation of the leap second edit

Most computer operating systems and most time distribution systems represent time with a binary counter indicating the number of seconds elapsed since an arbitrary epoch; for instance, since 1970-01-01 00:00:00 in POSIX machines or since 1900-01-01 00:00:00 in NTP. This counter does not count positive leap seconds, and has no indicator that a leap second has been inserted, therefore two seconds in sequence will have the same counter value. Some computer operating systems, in particular Linux, assign to the leap second the counter value of the preceding, 23:59:59 second (59–59–0 sequence), while other computers (and the IRIG-B time distribution) assign to the leap second the counter value of the next, 00:00:00 second (59–0–0 sequence).[citation needed] Since there is no standard governing this sequence, the timestamp of values sampled at exactly the same time can vary by one second. This may explain flaws in time-critical systems that rely on timestamped values.[63]

Other reported software problems associated with the leap second edit

Several models of global navigation satellite receivers have software flaws associated with leap seconds:

  • Some older versions of Motorola Oncore VP, UT, GT, and M12 GPS receivers had a software bug that would cause a single timestamp to be off by a day if no leap second was scheduled for 256 weeks. On 28 November 2003, this happened. At midnight, the receivers with this firmware reported 29 November 2003, for one second and then reverted to 28 November 2003.[64][65]
  • Older Trimble GPS receivers had a software flaw that would insert a leap second immediately after the GPS constellation started broadcasting the next leap second insertion time (some months in advance of the actual leap second), rather than waiting for the next leap second to happen. This left the receiver's time off by a second in the interim.[66][67]
  • Older Datum Tymeserve 2100 GPS receivers and Symmetricom Tymeserve 2100 receivers apply a leap second as soon as the a leap second notification is received, instead of waiting for the correct date. The manufacturers no longer supports these models and no corrected software is available. A workaround has been described and tested, but if the GPS system rebroadcasts the announcement, or the unit is powered off, the problem will occur again.[68]
  • Four different brands of navigational receivers that use data from BeiDou satellites were found to implement leap seconds one day early.[69] This was traced to a bug related to how the BeiDou protocol numbers the days of the week.

Several software vendors have distributed software that has not properly functioned with the concept of leap seconds:

  • NTP specifies a flag to inform the receiver that a leap second is imminent. However, some NTP server implementations have failed to set their leap second flag correctly.[70][71][72][73] Some NTP servers have responded with the wrong time for up to a day after a leap second insertion.[74]
  • A number of organizations reported problems caused by flawed software following the leap second that occurred on 30 June 2012. Among the sites which reported problems were Reddit (Apache Cassandra), Mozilla (Hadoop),[75] Qantas,[76] and various sites running Linux.[77]
  • Despite the publicity given to the 2015 leap second, a small number of network failures occurred due to leap second-related software errors of some routers.[78] Several older versions of the Cisco Systems NEXUS 5000 Series Operating System NX-OS (versions 5.0, 5.1, 5.2) are affected by leap second bugs.[79]

Some businesses and service providers have been impacted by leap-second related software bugs:

There were misplaced concerns that farming equipment using GPS navigation during harvests occurring on 31 December 2016, would be affected by the 2016 leap second.[85] GPS navigation makes use of GPS time, which is not impacted by the leap second.[86]

Due to a software error, the UTC time broadcast by the NavStar GPS system was incorrect by about 13 microseconds on 25–26 January 2016.[87][88]

Workarounds for leap second problems edit

The most obvious workaround is to use the TAI scale for all operational purposes and convert to UTC for human-readable text. UTC can always be derived from TAI with a suitable table of leap seconds. The Society of Motion Picture and Television Engineers (SMPTE) video/audio industry standards body selected TAI for deriving timestamps of media.[89] IEC/IEEE 60802 (Time sensitive networks) specifies TAI for all operations. Grid automation is planning to switch to TAI for global distribution of events in electrical grids. Bluetooth mesh networking also uses TAI.[90]

Instead of inserting a leap second at the end of the day, Google servers implement a "leap smear", extending seconds slightly over a 24-hour period centered on the leap second.[61] Amazon followed a similar, but slightly different, pattern for the introduction of the 30 June 2015, leap second,[91] leading to another case of the proliferation of timescales. They later released an NTP service for EC2 instances which performs leap smearing.[92] UTC-SLS was proposed as a version of UTC with linear leap smearing, but it never became standard.[93]

It has been proposed that media clients using the Real-time Transport Protocol inhibit generation or use of NTP timestamps during the leap second and the second preceding it.[94]

NIST has established a special NTP time server to deliver UT1 instead of UTC.[95] Such a server would be particularly useful in the event the ITU resolution passes and leap seconds are no longer inserted.[96] Those astronomical observatories and other users that require UT1 could run off UT1 – although in many cases these users already download UT1-UTC from the IERS, and apply corrections in software.[97]

See also edit

  • Clock drift, phenomenon where a clock gains or loses time compared to another clock
  • DUT1, which describes the difference between coordinated universal time (UTC) and universal time (UT1)
  • Dynamical time scale
  • Leap year, a year containing one extra day or month

Notes edit

  1. ^ Only the Gregorian calendar's leap days begin after 28 February. The leap days of other calendars begin at different local times in their own years (Ethiopian calendar, Iranian calendars, Indian national calendar, etc.).
  2. ^ The Wall Street Journal noted that the proposal was considered by a U.S. official at the time to be a "private matter internal to the ITU."[34]
  3. ^ The FCC has posted its received comments, which can be found using their search engine for proceeding 04–286 and limiting the "received period" to those between 27 January and 18 February 2014, inclusive.[44]
  4. ^ In addition to publishing the video of the special session,[47] the Australian Communications and Media Authority has a transcript of that session and a web page with draft content of the Conference Preparatory Meeting report and solutions for ITU-R WRC-15 Agenda Item 1.14.[48]

References edit

  1. ^ a b Martin, Cassie (19 January 2024). "50 years ago, timekeepers deployed the newly invented leap second". 50 Years Ago. Science News. p. 4.
  2. ^ "IERS science background". Frankfurt am Main: IERS. 2013. from the original on 29 August 2016. Retrieved 6 August 2016.
  3. ^ Gambis, Danie (5 January 2015). "Bulletin C 49". Paris: IERS. from the original on 30 May 2015. Retrieved 5 January 2015.
  4. ^ James Vincent (7 January 2015). "2015 is getting an extra second and that's a bit of a problem for the internet". The Verge. from the original on 17 March 2017.
  5. ^ Finkleman, David; Allen, Steve; Seago, John; Seaman, Rob; Seidelmann, P. Kenneth (2011). "The Future of Time: UTC and the Leap Second". American Scientist. 99 (4): 312–319. arXiv:1106.3141. doi:10.1511/2011.91.312. S2CID 118403321.
  6. ^ a b "Do not adjust your clock: scientists call time on the leap second". World News. The Guardian. Agence France-Presse. 18 November 2022.
  7. ^ a b Gibney, Elizabeth (18 November 2022). "The leap second's time is up: world votes to stop pausing clocks". Nature. 612 (7938): 18. Bibcode:2022Natur.612...18G. doi:10.1038/d41586-022-03783-5. ISSN 0028-0836. PMID 36400956.
  8. ^ Ptolemy; G. J. Toomer (1998). Ptolemy's Alemagest. Toomer, G. J. Princeton, New Jersey: Princeton University Press. pp. 6–7, 23, 211–216. ISBN 978-0-691-00260-6.
  9. ^ al-Biruni (1879). The chronology of ancient nations: an English version of the Arabic text of the Athâr-ul-Bâkiya of Albîrûnî, or "Vestiges of the Past". Sachau, C. Edward. Oriental Translation Fund of Great Britain & Ireland. pp. 141–149, 158, 408, 410. from the original on 14 November 2017. Used for mean new moons, both in Hebrew calendar cycles and in equivalent astronomical cycles.
  10. ^ Everett, J. D. (1875). Illustrations of the centimetre-gramme-second (C.G.S.) system of units. Taylor and Francis. p. 83.
  11. ^ Pearce, J. A. (1928). "The Variability of the Rotation of the Earth". Journal of the Royal Astronomical Society of Canada. 22: 145–147. Bibcode:1928JRASC..22..145P.
  12. ^ Seidelmann, P. Kenneth, ed. (1992). Explanatory Supplement to the Astronomical Almanac. Mill Valley, California: University Science Books. pp. 79–80. ISBN 0-935702-68-7. from the original on 14 November 2017.
  13. ^ a b "Leap Seconds". Time Service Department, United States Naval Observatory. Retrieved 19 November 2022.
  14. ^ Wm Markowitz (1988) 'Comparisons of ET (Solar), ET (Lunar), UT and TDT', in (eds.) A K Babcock & G A Wilkins, 'The Earth's Rotation and Reference Frames for Geodesy and Geophysics', IAU Symposia #128 (1988), at pp 413–418.
  15. ^ DD McCarthy and AK Babcock (1986), "The Length of the Day Since 1658", Phys. Earth Planet Inter., No. 44, pp. 281–292
  16. ^ RA Nelson, DD McCarthy, S Malys, J Levine, B Guinot, HF Fliegel, RL Beard, and TR Bartholomew, (2001) "The Leap Second: its History and Possible Future" (2001), Metrologia 38, pp. 509–529
  17. ^ a b c d Stephenson, F.R.; Morrison, L.V. (1995). "Long-term fluctuations in the Earth's rotation: 700 BC to AD 1990". Philosophical Transactions of the Royal Society of London A. 351 (1695): 165–202. Bibcode:1995RSPTA.351..165S. doi:10.1098/rsta.1995.0028. S2CID 120718607.
  18. ^ McCarthy, D D; Hackman, C; Nelson, R A (2008). "The Physical Basis of the Leap Second" (PDF). Astronomical Journal. 136 (5): 1906–1908. Bibcode:2008AJ....136.1906M. doi:10.1088/0004-6256/136/5/1906. (PDF) from the original on 12 March 2021. Retrieved 26 February 2022.
  19. ^ Jespersen, James; Fitz-Randolph, Jane (1999). From Sundials To Atomic Clocks: Understanding Time and Frequency (PDF). National Institute of Standards and Technology. p. 109.
  20. ^ a b Blair, Byron E., ed. (May 1974), NBS Monograph 140: Time and Frequency: Theory and Fundamentals (PDF), p. 8
  21. ^ McCarthy, Dennis D.; Seidelmann, P. Kenneth. Time: From Earth Rotation to Atomic Physics (second ed.). For provisional limited use, the CCIR in 1966 approved "Stepped Atomic Time," which used the atomic second with frequent 200 ms adjustments made in order to be within 0.1 s of UT2.
  22. ^ "TAI−UTC (1972-01-01 – 2024-06-28)". 4 July 2023. Retrieved 4 July 2023.
  23. ^ Gambis, Daniel (4 July 2008). "Bulletin C 36". Paris: IERS EOP PC, Observatoire de Paris. from the original on 6 October 2009. Retrieved 18 April 2010.
  24. ^ Andrea Thompson (8 December 2008). "2008 Will Be Just a Second Longer". Live Science. from the original on 12 December 2008. Retrieved 29 December 2008.
  25. ^ "International Telecommunication Union Radiocommunications sector recommendation TF.460-6: Standard-frequency and time-signal emissions". from the original on 17 October 2016. Retrieved 9 February 2017.
  26. ^ Steve Allen (8 June 2011). "Extrapolations of the difference (TI – UT1)". ucolick.org. from the original on 4 March 2016. Retrieved 29 February 2016.
  27. ^ Cook-Anderson, Gretchen; Beasley, Dolores (10 January 2005). "NASA Details Earthquake Effects on the Earth". National Aeronautics and Space Administration (press release). from the original on 27 January 2011.
  28. ^ Chester, Geoff (15 June 2015). "Wait a second… 2015 will be a little longer". CHIPS Articles: The Department of the Navy's Information Technology Magazine. Retrieved 4 March 2021.
  29. ^ Plait, Phil (31 December 2008). "Followup: Leap Seconds". Discover Magazine: Bad Astronomy. Retrieved 5 March 2021.
  30. ^ Jones, Graham; Bikos, Konstantin (6 January 2021) [2020-12-23]. "Earth is in a hurry in 2020". timeanddate.com. Retrieved 6 March 2021.
  31. ^ Knapton, Sarah (4 January 2021). "The Earth is spinning faster now than at any time in the past half century". The Daily Telegraph. Archived from the original on 12 January 2022. Retrieved 11 February 2021.
  32. ^ "Time Split to the Nanosecond Is Precisely What Wall Street Wants". The New York Times. 29 June 2018. Retrieved 13 December 2022.
  33. ^ Dwyer, Colin (29 December 2016). "With A Leap Second, 2016 Promises To Linger Just A Little Bit Longer". NPR. from the original on 2 January 2023. Retrieved 24 February 2023.
  34. ^ "Why the U.S. Wants To End the Link Between Time and Sun". The Wall Street Journal. from the original on 7 November 2017. Retrieved 31 October 2017.
  35. ^ "Leap second talks are postponed". BBC News. from the original on 7 November 2017. Retrieved 31 October 2017.
  36. ^ P. Kenneth Seidelmann. "UTC redefinition or change". IGS Mail (Mailing list).
  37. ^ Cowen, Ron (22 April 2006). "To Leap or Not to Leap: Scientists debate a timely issue". Science News. from the original on 26 May 2023. Retrieved 26 May 2023.
  38. ^ Steve Allen. "UTC might be redefined without Leap Seconds". from the original on 3 June 2017. Retrieved 31 October 2017.
  39. ^ "nc1985wp7a Proposed US Contribution to ITU-R WP 7A". from the original on 1 January 2017. Retrieved 31 October 2017.
  40. ^ Demetrios Matsakis (18 August 2014). "Comments on the Debate over the Proposal to Redefine UTC" (PDF). (PDF) from the original on 8 February 2017. Retrieved 31 October 2017.
  41. ^ "United States Proposals, Proposal for the Work of the Conference, Agenda Item 1.14" (PDF). National Telecommunications and Information Administration.
  42. ^ "FCC Seeks Comment On Recommendations Approved By The Advisory Committee For The 2015 World Radiocommunication Conference" (PDF). Federal Communications Commission. 28 January 2014. (PDF) from the original on 29 July 2014.
  43. ^ "Preliminary Views and Proposals Regarding WRC-15 Agenda Items" (PPT). Organization of American States. from the original on 29 July 2014.
  44. ^ "Search for Filings Results". fcc.gov. from the original on 1 July 2015.
  45. ^ Merali, Zeeya (8 November 2011). "Time is running out for the leap second". Nature. 479 (7372): 158. Bibcode:2011Natur.479..158M. doi:10.1038/479158a. PMID 22071738. S2CID 8220495.
  46. ^ Han, Chunhao (19 September 2013). "Conception, Definition and Realization of Time Scale in GNSS" (PDF). (PDF) from the original on 5 September 2014.
  47. ^ Information Session on the WRC-15 agenda item 1.14 – Coordinated Universal Time (UTC). YouTube. 15 April 2015. from the original on 18 November 2015.
  48. ^ . acma.gov.au. Archived from the original on 8 September 2015.
  49. ^ "RESOLUTION 653 (WRC-12) Future of the Coordinated Universal Time time-scale" (PDF). International Telecommunication Union. (PDF) from the original on 2 July 2015.
  50. ^ CCTF Strategy Document, International Bureau of Weights and Measures, May 2016, pp. 21–25
  51. ^ (PDF). 25 September 2007. p. 9. Archived from the original (PDF) on 14 June 2011. Retrieved 18 November 2007.
  52. ^ "WP7D – Status of Coordinated Universal Time (UTC) study in ITU-R" (Word 2007). International Telecommunication Union – Radiocommunication Sector (ITU-R) Release: 2. 4 October 2011. from the original on 23 March 2014. Retrieved 24 October 2011. To date, the BR received replies from 16 different Member States for the latest survey (out of a total of 192 Member States, 55 of which participate in the formation of UTC) – 13 being in favor of the change, 3 being contrary.
  53. ^ (Press release). International Telecommunication Union. 19 November 2015. Archived from the original on 29 January 2016.
  54. ^ "CGSIC opinion on the redefinition of UTC now under consideration by the International Telecommunication Union (ITU)". from the original on 23 October 2014.
  55. ^ "The proposed redefinition of Coordinated Universal Time, UTC" (PDF) (Press release). BIPM. 13 October 2011. (PDF) from the original on 18 January 2015.
  56. ^ "Scientists propose 'leap hour' to fix time system". New Scientist. 14 May 2012 [2008-12-18]. Retrieved 3 September 2022 – via The New Indian Express.
  57. ^ Richtel, Matt (3 November 2023). "A Giant Leap for the Leap Second. Is Humankind Ready?". The New York Times. ISSN 0362-4331. Retrieved 23 January 2024.
  58. ^ A Resilient Architecture for the Realization and Distribution of Coordinated Universal Time to Critical Infrastructure Systems in the United States (Technical report). November 2021. doi:10.6028/NIST.TN.2187.
  59. ^ "NIST Internet Time Service (ITS)". NIST. 10 February 2010.
  60. ^ Kevin Gross (March 2014), RTP and Leap Seconds, RFC 7164
  61. ^ a b "Leap Smear". Google Inc. Retrieved 26 May 2023.
  62. ^ Dimarcq, Noël; Tavella, Patrizia (17 November 2022). "Draft Resolution D: 'On the use and future development of UTC'". Bureau International des Poids et Mesures. p. 7.
  63. ^ Benzler, Justus; Clark, Samuel J. (30 March 2005). "Toward a Unified Timestamp with explicit precision". Demographic Research. 12 (6): 107–140. doi:10.4054/DemRes.2005.12.6. ISSN 1435-9871. PMC 2854819. PMID 20396403.
  64. ^ "256-Week Leap Second Bug". 2 July 2013. from the original on 4 March 2016.
  65. ^ . 2 July 2013. Archived from the original on 18 January 2013.
  66. ^ "Leap-second problem with older GPS receivers". 19 November 2014. from the original on 29 November 2014.
  67. ^ "How Leap Seconds Can Interfere with GNSS Receivers". 13 May 2015. from the original on 6 March 2016.
  68. ^ "Symmetricom TymServe 2100-GPS currently fails with GPS offset". time-nuts (Mailing list). from the original on 17 February 2015.
  69. ^ "BeiDou Numbering Presents Leap-Second Issue". GPS World. 3 March 2015.
  70. ^ Malone, David. "NTP Leap Bits". from the original on 22 July 2014. Retrieved 1 December 2019.
  71. ^ Malone, David (2016). "The Leap Second Behaviour of NTP Servers" (PDF). Proc.Traffic Monitoring and Analysis workshop. (PDF) from the original on 23 October 2016. Retrieved 23 October 2016.
  72. ^ Cao, Yi; Veitch, Darryl (15–19 April 2018). Network Timing, Weathering the 2016 Leap Second. IEEE Infocom 2018. Honolulu, Hawaii. pp. 1826–1834. doi:10.1109/INFOCOM.2018.8486286. hdl:10453/130538.
  73. ^ Veitch, Darryl; Vijayalayan, Kanthaiah (1 April 2016). "Network Timing and the 2015 Leap Second". Proc. of PAM 2016. Heraklion, Crete, Greece. pp. 385–396. doi:10.1007/978-3-319-30505-9_29. hdl:10453/43923.
  74. ^ "NTP Events". satsignal.eu. from the original on 18 July 2014.
  75. ^ "'Leap Second' Bug Wreaks Havoc Across Web". Wired. 1 July 2012. from the original on 28 March 2014.
  76. ^ "Leap second crashes Qantas and leaves passengers stranded". News Limited. 1 July 2012. from the original on 1 July 2012.
  77. ^ "Anyone else experiencing high rates of Linux server crashes during a leap second day?". Serverfault.com. from the original on 9 July 2012.
  78. ^ Shulman, Eden. "Beta Boston". Boston Globe. from the original on 29 September 2015. Retrieved 27 September 2015.
  79. ^ "Cisco Bug: CSCub38654 – N5K: Switch hang/lock up may occur due to Leap second update". Cisco. 24 July 2015. from the original on 8 March 2016.
  80. ^ Sarah Knapton (1 July 2015). "Leap Second confuses Twitter and Android". The Daily Telegraph. from the original on 6 October 2015.
  81. ^ Clarke, Gavin (8 August 2016). "Power cut crashes Delta's worldwide flight update systems". The Register. from the original on 4 January 2017. Retrieved 3 January 2017.
  82. ^ "How and why the leap second affected Cloudflare DNS". Cloudflare. 1 January 2017. from the original on 2 January 2017.
  83. ^ "#12914 runtime: time: expose monotonic clock source". GitHub. from the original on 20 March 2017. Retrieved 5 January 2017.
  84. ^ . Intercontinental Exchange. Archived from the original on 5 May 2015.
  85. ^ "Got a second – the world time needs it". ABC Rural. 30 December 2016. from the original on 2 January 2017. Retrieved 3 January 2017.
  86. ^ How fast is the earth moving? Rhett Herman, a physics professor at Radford University in Virginia, supplies the following answer, Scientific American, 26 October 1998
  87. ^ "Air Force Official Press Release – GPS Ground System Anomaly" (PDF).
  88. ^ Yao, Jian; Lombardi, Michael A.; Novick, Andrew N.; Patla, Bijunath; Sherman, Jeff A.; Zhang, Victor. "The effects of the January 2016 UTC offset anomaly on GPS-controlled clocks monitored at NIST" (PDF).
  89. ^ Paul Briscoe (14 May 2013). "Network-Based Timing and Synchronization" (PDF).
  90. ^ "Mesh Model Bluetooth® Specification" (PDF download). Bluetooth Technology Website. 13 July 2017. Retrieved 14 December 2019. See sections 5.1.1 and A.1.
  91. ^ Jeff Barr (18 May 2015). "Look Before You Leap – The Coming Leap Second and AWS (Updated)". Amazon Web Services.
  92. ^ Randall Hunt (29 November 2017). "Keeping Time With Amazon Time Sync Service". Amazon Web Services. Retrieved 8 March 2018.
  93. ^ Kuhn, Markus (2005). "UTC with Smoothed Leap Seconds (UTC-SLS)". www.cl.cam.ac.uk.
  94. ^ Kevin Gross (March 2014). RTP and Leap Seconds. doi:10.17487/RFC7164. RFC 7164.
  95. ^ "UT1 NTP Time Dissemination". National Institute of Standards and Technology. 11 December 2015. Retrieved 31 August 2019.
  96. ^ Wallace, Patrick (2003). "The UTC Problem and its Solution" (PDF). Proceedings of Colloquium on the UTC Time Scale. Torino. (PDF) from the original on 18 January 2015.
  97. ^ Luzum, Brian (2013). The Role of the IERS in the Leap Second (PDF). BIPM/ITU Workshop on the Future of the International Time Scale. (PDF) from the original on 15 July 2014.

Further reading edit

External links edit

 
Wikimedia Commons has media related to Leap second.
  • IERS Bulletins, including Bulletin C (leap second announcements)
  • LeapSecond.com – A web site dedicated to precise time and frequency
  • NIST FAQ about leap year and leap second
  • The leap second: its history and possible future
  • "Support for the leap second". Microsoft Support. 4 October 2018.
  • Dan Cuomo (17 October 2018). "Leap Seconds for the IT Pro: What you need to know". Windows Server – Networking Blog.
  • Travis Luke (24 October 2018). "Leap Seconds for the AppDev: What you should know". Windows Server – Networking Blog.
  • "Leap Second Readiness Tips". www.orolia.com. Orolia. 31 December 2018.
  • Judah Levine's Everyday Time and Atomic Time series
    • Judah Levine (31 March 2021). "Everyday Time and Atomic Time: Part One". National Institute of Standards and Technology.
    • Judah Levine (7 April 2021). "Everyday Time and Atomic Time: Part Two". National Institute of Standards and Technology.
    • Judah Levine (14 April 2021). "Everyday Time and Atomic Time: Part Three". National Institute of Standards and Technology.
    • Judah Levine (21 April 2021). "Everyday Time and Atomic Time: Part Four". National Institute of Standards and Technology.
    • Judah Levine (28 April 2021). "Everyday Time and Atomic Time: Part Five". National Institute of Standards and Technology.

February 15, 2024
leap, second, leap, second, second, adjustment, that, occasionally, applied, coordinated, universal, time, accommodate, difference, between, precise, time, international, atomic, time, measured, atomic, clocks, imprecise, observed, solar, time, which, varies, . A leap second is a one second adjustment that is occasionally applied to Coordinated Universal Time UTC to accommodate the difference between precise time International Atomic Time TAI as measured by atomic clocks and imprecise observed solar time UT1 which varies due to irregularities and long term slowdown in the Earth s rotation The UTC time standard widely used for international timekeeping and as the reference for civil time in most countries uses TAI and consequently would run ahead of observed solar time unless it is reset to UT1 as needed The leap second facility exists to provide this adjustment The leap second was introduced in 1972 and since then 27 leap seconds have been added to UTC 1 Screenshot of the UTC clock from time wbr gov during the leap second on 31 December 2016 Because the Earth s rotational speed varies in response to climatic and geological events 2 UTC leap seconds are irregularly spaced and unpredictable Insertion of each UTC leap second is usually decided about six months in advance by the International Earth Rotation and Reference Systems Service IERS to ensure that the difference between the UTC and UT1 readings will never exceed 0 9 seconds 3 4 This practice has proven disruptive particularly in the twenty first century and especially in services that depend on precise timestamping or time critical process control And since not all computers are adjusted by leap second they will display times differing from those that have been adjusted 5 After many years of discussions by different standards bodies in November 2022 at the 27th General Conference on Weights and Measures it was decided to abandon the leap second by or before 2035 6 7 Contents 1 History 2 Insertion of leap seconds 2 1 Process 3 Slowing rotation of the Earth 4 Future of leap seconds 4 1 International proposals for elimination of leap seconds 5 Issues created by insertion or removal of leap seconds 5 1 Calculation of time differences and sequence of events 5 2 Missing leap seconds announcement 5 3 Implementation differences 5 4 Textual representation of the leap second 5 5 Binary representation of the leap second 5 6 Other reported software problems associated with the leap second 6 Workarounds for leap second problems 7 See also 8 Notes 9 References 10 Further reading 11 External linksHistory edit nbsp Graph showing the difference between UT1 and UTC Vertical segments correspond to leap seconds In about 140 CE Ptolemy the Alexandrian astronomer sexagesimally subdivided both the mean solar day and the true solar day to at least six places after the sexagesimal point and he used simple fractions of both the equinoctial hour and the seasonal hour none of which resemble the modern second 8 Muslim scholars including al Biruni in 1000 subdivided the mean solar day into 24 equinoctial hours each of which was subdivided sexagesimally that is into the units of minute second third fourth and fifth creating the modern second as 1 60 of 1 60 of 1 24 1 86 400 of the mean solar day in the process 9 With this definition the second was proposed in 1874 as the base unit of time in the CGS system of units 10 Soon afterwards Simon Newcomb and others discovered that Earth s rotation period varied irregularly 11 so in 1952 the International Astronomical Union IAU defined the second as a fraction of the sidereal year In 1955 considering the tropical year to be more fundamental than the sidereal year the IAU redefined the second as the fraction 1 31 556 925 975 of the 1900 0 mean tropical year In 1956 a slightly more precise value of 1 31 556 925 9747 was adopted for the definition of the second by the International Committee for Weights and Measures and in 1960 by the General Conference on Weights and Measures becoming a part of the International System of Units SI 12 Eventually this definition too was found to be inadequate for precise time measurements so in 1967 the SI second was again redefined as 9 192 631 770 periods of the radiation emitted by a caesium 133 atom in the transition between the two hyperfine levels of its ground state 13 That value agreed to 1 part in 1010 with the astronomical ephemeris second then in use 14 It was also close quantify to 1 86 400 of the mean solar day as averaged between years 1750 and 1892 However for the past several centuries the length of the mean solar day has been increasing by about 1 4 1 7 ms per century depending on the averaging time 15 16 17 By 1961 the mean solar day was already a millisecond or two longer than 86400 SI seconds 18 Therefore time standards that change the date after precisely 86400 SI seconds such as the International Atomic Time TAI would become increasingly ahead of time standards tied to the mean solar day such as Universal Time UT When the Coordinated Universal Time UTC standard was instituted in 1960 based on atomic clocks it was felt necessary to maintain agreement with UT which until then had been the reference for broadcast time services From 1960 to 1971 the rate of UTC atomic clocks was offset from a pure atomic time scale by the BIH to remain synchronized with UT2 a practice known as the rubber second 19 The rate of UTC was decided at the start of each year and was offset from the rate of atomic time by 150 parts per 1010 for 1960 1962 by 130 parts per 1010 for 1962 63 by 150 parts per 1010 again for 1964 65 and by 300 parts per 1010 for 1966 1971 20 Alongside the shift in rate an occasional 0 1 s step 0 05 s before 1963 was needed This predominantly frequency shifted rate of UTC was broadcast by MSF WWV and CHU among other time stations In 1966 the CCIR approved stepped atomic time SAT which adjusted atomic time with more frequent 0 2 s adjustments to keep it within 0 1 s of UT2 because it had no rate adjustments 21 SAT was broadcast by WWVB among other time stations 20 In 1972 the leap second system was introduced so that the UTC seconds could be set exactly equal to the standard SI second while still maintaining the UTC time of day and changes of UTC date synchronized with those of UT1 13 By then the UTC clock was already 10 seconds behind TAI which had been synchronized with UT1 in 1958 but had been counting true SI seconds since then After 1972 both clocks have been ticking in SI seconds so the difference between their displays at any time is 10 seconds plus the total number of leap seconds that have been applied to UTC as of that time as of May 2023 update 27 leap seconds have been applied to UTC so the difference is 10 27 37 seconds Insertion of leap seconds editAnnounced leap seconds to date 22 Year 30 Jun 31 Dec1972 1 11973 0 11974 0 11975 0 11976 0 11977 0 11978 0 11979 0 11980 0 01981 1 01982 1 01983 1 01984 0 01985 1 01986 0 01987 0 11988 0 01989 0 11990 0 11991 0 01992 1 01993 1 01994 1 01995 0 11996 0 01997 1 01998 0 11999 0 02000 0 02001 0 02002 0 02003 0 02004 0 02005 0 12006 0 02007 0 02008 0 12009 0 02010 0 02011 0 02012 1 02013 0 02014 0 02015 1 02016 0 12017 0 02018 0 02019 0 02020 0 02021 0 02022 0 02023 0 02024 0Year 30 Jun 31 DecTotal 11 1627Current TAI UTC37The scheduling of leap seconds was initially delegated to the Bureau International de l Heure BIH but passed to the International Earth Rotation and Reference Systems Service IERS on 1 January 1988 IERS usually decides to apply a leap second whenever the difference between UTC and UT1 approaches 0 6 s in order to keep the difference between UTC and UT1 from exceeding 0 9 s The UTC standard allows leap seconds to be applied at the end of any UTC month with first preference to June and December and second preference to March and September As of May 2023 update all of them have been inserted at the end of either 30 June or 31 December IERS publishes announcements every six months whether leap seconds are to occur or not in its Bulletin C Such announcements are typically published well in advance of each possible leap second date usually in early January for 30 June and in early July for 31 December 23 24 Some time signal broadcasts give voice announcements of an impending leap second Between 1972 and 2020 a leap second has been inserted about every 21 months on average However the spacing is quite irregular and apparently increasing there were no leap seconds in the six year interval between 1 January 1999 and 31 December 31 2004 but there were nine leap seconds in the eight years 1972 1979 Since the introduction of leap seconds 1972 has been the longest year on record 366 days and two seconds Unlike leap days which begin after 28 February 23 59 59 local time a UTC leap seconds occur simultaneously worldwide for example the leap second on 31 December 2005 23 59 60 UTC was 31 December 2005 18 59 60 6 59 60 p m in U S Eastern Standard Time and 1 January 2006 08 59 60 a m in Japan Standard Time Process edit When it is mandated a positive leap second is inserted between second 23 59 59 of a chosen UTC calendar date and second 00 00 00 of the following date The definition of UTC states that the last day of December and June are preferred with the last day of March or September as second preference and the last day of any other month as third preference 25 All leap seconds as of 2019 have been scheduled for either 30 June or 31 December The extra second is displayed on UTC clocks as 23 59 60 On clocks that display local time tied to UTC the leap second may be inserted at the end of some other hour or half hour or quarter hour depending on the local time zone A negative leap second would suppress second 23 59 59 of the last day of a chosen month so that second 23 59 58 of that date would be followed immediately by second 00 00 00 of the following date Since the introduction of leap seconds the mean solar day has outpaced atomic time only for very brief periods and has not triggered a negative leap second Slowing rotation of the Earth editSee also DT timekeeping nbsp Deviation of day length from SI based day with shorter days resulting from faster planetary rotation Leap seconds are irregularly spaced because the Earth s rotation speed changes irregularly Indeed the Earth s rotation is quite unpredictable in the long term which explains why leap seconds are announced only six months in advance A mathematical model of the variations in the length of the solar day was developed by F R Stephenson and L V Morrison 17 based on records of eclipses for the period 700 BCE to 1623 CE telescopic observations of occultations for the period 1623 until 1967 and atomic clocks thereafter The model shows a steady increase of the mean solar day by 1 70 ms 0 05 ms per century plus a periodic shift of about 4 ms amplitude and period of about 1 500 yr 17 Over the last few centuries rate of lengthening of the mean solar day has been about 1 4 ms per century being the sum of the periodic component and the overall rate 26 The main reason for the slowing down of the Earth s rotation is tidal friction which alone would lengthen the day by 2 3 ms century 17 Other contributing factors are the movement of the Earth s crust relative to its core changes in mantle convection and any other events or processes that cause a significant redistribution of mass These processes change the Earth s moment of inertia affecting the rate of rotation due to the conservation of angular momentum Some of these redistributions increase Earth s rotational speed shorten the solar day and oppose tidal friction For example glacial rebound shortens the solar day by 0 6 ms century and the 2004 Indian Ocean earthquake is thought to have shortened it by 2 68 microseconds 27 It is a mistake however to consider leap seconds as indicators of a slowing of Earth s rotation rate they are indicators of the accumulated difference between atomic time and time measured by Earth rotation 28 The plot at the top of this section shows that in 1972 the average length of day was approximately 86400 003 seconds and in 2016 it was approximately 86400 001 seconds indicating an overall increase in Earth s rotation rate over that time period Positive leap seconds were inserted during that time because the annual average length of day remained greater than 86400 SI seconds not because of any slowing of Earth s rotation rate 29 In 2021 it was reported that Earth was spinning faster in 2020 and experienced the 28 shortest days since 1960 each of which lasted less than 86399 999 seconds 30 This caused engineers worldwide to discuss a negative leap second and other possible timekeeping measures some of which could eliminate leap seconds 31 Future of leap seconds editThis section needs additional citations for verification Please help improve this article by adding citations to reliable sources in this section Unsourced material may be challenged and removed Find sources Leap second news newspapers books scholar JSTOR December 2023 Learn how and when to remove this template message The TAI and UT1 time scales are precisely defined the former by atomic clocks and thus independent of Earth s rotation and the latter by astronomical observations that measure actual planetary rotation and thus the solar time at the Greenwich meridian UTC on which civil time is usually based is a compromise stepping with atomic seconds but periodically reset by a leap second to match UT1 The irregularity and unpredictability of UTC leap seconds is problematic for several areas especially computing see below With increasing requirements for accuracy in automation systems and high frequency trading 32 this raises a number of issues Consequently the long standing practice of inserting leap seconds is under review by the relevant international standards body 33 International proposals for elimination of leap seconds edit On 5 July 2005 the Head of the Earth Orientation Center of the IERS sent a notice to IERS Bulletins C and D subscribers soliciting comments on a U S proposal before the ITU R Study Group 7 s WP7 A to eliminate leap seconds from the UTC broadcast standard before 2008 the ITU R is responsible for the definition of UTC b It was expected to be considered in November 2005 but the discussion has since been postponed 35 Under the proposal leap seconds would be technically replaced by leap hours as an attempt to satisfy the legal requirements of several ITU R member nations that civil time be astronomically tied to the Sun A number of objections to the proposal have been raised P Kenneth Seidelmann editor of the Explanatory Supplement to the Astronomical Almanac wrote a letter lamenting the lack of consistent public information about the proposal and adequate justification 36 In an op ed for Science News Steve Allen of the University of California Santa Cruz said that the process has a large impact on astronomers 37 Allen has an extensive online site devoted to the issues and the history of leap seconds 38 including a set of references about the proposal and arguments against it 39 At the 2014 General Assembly of the International Union of Radio Scientists URSI Demetrios Matsakis the United States Naval Observatory s Chief Scientist for Time Services presented the reasoning in favor of the redefinition and rebuttals to the arguments made against it 40 He stressed the practical inability of software programmers to allow for the fact that leap seconds make time appear to go backwards particularly when most of them do not even know that leap seconds exist The possibility of leap seconds being a hazard to navigation was presented as well as the observed effects on commerce The United States formulated its position on this matter based upon the advice of the National Telecommunications and Information Administration 41 and the Federal Communications Commission FCC which solicited comments from the general public 42 This position is in favor of the redefinition 43 c In 2011 Chunhao Han of the Beijing Global Information Center of Application and Exploration said China had not decided what its vote would be in January 2012 but some Chinese scholars consider it important to maintain a link between civil and astronomical time due to Chinese tradition The 2012 vote was ultimately deferred 45 At an ITU BIPM sponsored workshop on the leap second Han expressed his personal view in favor of abolishing the leap second 46 and similar support for the redefinition was again expressed by Han along with other Chinese timekeeping scientists at the URSI General Assembly in 2014 At a special session of the Asia Pacific Telecommunity Meeting on 10 February 2015 Chunhao Han indicated China was now supporting the elimination of future leap seconds as were all the other presenting national representatives from Australia Japan and the Republic of Korea At this meeting Bruce Warrington NMI Australia and Tsukasa Iwama NICT Japan indicated particular concern for the financial markets due to the leap second occurring in the middle of a workday in their part of the world d Subsequent to the CPM15 2 meeting in March April 2015 the draft gives four methods which the WRC 15 might use to satisfy Resolution 653 from WRC 12 49 Arguments against the proposal include the unknown expense of such a major change and the fact that universal time will no longer correspond to mean solar time It is also answered that two timescales that do not follow leap seconds are already available International Atomic Time TAI and Global Positioning System GPS time Computers for example could use these and convert to UTC or local civil time as necessary for output Inexpensive GPS timing receivers are readily available and the satellite broadcasts include the necessary information to convert GPS time to UTC It is also easy to convert GPS time to TAI as TAI is always exactly 19 seconds ahead of GPS time Examples of systems based on GPS time include the CDMA digital cellular systems IS 95 and CDMA2000 In general computer systems use UTC and synchronize their clocks using Network Time Protocol NTP Systems that cannot tolerate disruptions caused by leap seconds can base their time on TAI and use Precision Time Protocol However the BIPM has pointed out that this proliferation of timescales leads to confusion 50 At the 47th meeting of the Civil Global Positioning System Service Interface Committee in Fort Worth Texas in September 2007 it was announced that a mailed vote would go out on stopping leap seconds The plan for the vote was 51 April 2008 ITU Working Party 7A will submit to ITU Study Group 7 project recommendation on stopping leap seconds During 2008 Study Group 7 will conduct a vote through mail among member states October 2011 The ITU R released its status paper Status of Coordinated Universal Time UTC study in ITU R in preparation for the January 2012 meeting in Geneva the paper reported that to date in response to the UN agency s 2010 and 2011 web based surveys requesting input on the topic it had received 16 responses from the 192 Member States with 13 being in favor of change 3 being contrary 52 January 2012 The ITU makes a decision In January 2012 rather than decide yes or no per this plan the ITU decided to postpone a decision on leap seconds to the World Radiocommunication Conference in November 2015 At this conference it was again decided to continue using leap seconds pending further study and consideration at the next conference in 2023 53 In October 2014 Wlodzimierz Lewandowski chair of the timing subcommittee of the Civil GPS Interface Service Committee and a member of the ESA Navigation Program Board presented a CGSIC endorsed resolution to the ITU that supported the redefinition and described leap seconds as a hazard to navigation 54 Some of the objections to the proposed change have been addressed by its supporters For example Felicitas Arias who as Director of the International Bureau of Weights and Measures BIPM s Time Frequency and Gravimetry Department was responsible for generating UTC noted in a press release that the drift of about one minute every 60 90 years could be compared to the 16 minute annual variation between true solar time and mean solar time the one hour offset by use of daylight time and the several hours offset in certain geographically extra large time zones 55 Proposed alternatives to the leap second are the leap hour which requires changes only once every few centuries 56 and the leap minute with changes coming every half century 1 57 On 18 November 2022 the General Conference on Weights and Measures CGPM resolved to eliminate leap seconds by or before 2035 The difference between atomic and astronomical time will be allowed to grow to a larger value yet to be determined A suggested possible future measure would be to let the discrepancy increase to a full minute which would take 50 to 100 years and then have the last minute of the day taking two minutes in a kind of smear with no discontinuity The year 2035 for eliminating leap seconds was chosen considering Russia s request to extend the timeline to 2040 since unlike the United States s global navigation satellite system GPS which does not adjust its time with leap seconds Russia s system GLONASS does adjust its time with leap seconds 6 7 Issues created by insertion or removal of leap seconds editCalculation of time differences and sequence of events edit To compute the elapsed time in seconds between two given UTC dates requires the consultation of a table of leap seconds which needs to be updated whenever a new leap second is announced Since leap seconds are known only 6 months in advance time intervals for UTC dates further in the future cannot be computed Missing leap seconds announcement edit Although BIPM announces a leap second 6 months in advance most time distribution systems SNTP IRIG B PTP announce leap seconds at most 12 hours in advance citation needed 58 sometimes only in the last minute and some even not at all DNP 03 citation needed Implementation differences edit Not all clocks implement leap seconds in the same manner Leap seconds in Unix time are commonly implemented by repeating 23 59 59 or adding the time stamp 23 59 60 Network Time Protocol SNTP freezes time during the leap second 59 some time servers declare alarm condition citation needed Other schemes smear time in the vicinity of a leap second spreading out the second of change over a longer period This aims to avoid any negative effects of a substantial by modern standards step in time 60 61 This approach has led to differences between systems as leap smear is not standardized and several different schemes are used in practice 62 Textual representation of the leap second edit The textual representation of a leap second is defined by BIPM as 23 59 60 There are programs that are not familiar with this format and may report an error when dealing with such input Binary representation of the leap second edit Most computer operating systems and most time distribution systems represent time with a binary counter indicating the number of seconds elapsed since an arbitrary epoch for instance since 1970 01 01 00 00 00 in POSIX machines or since 1900 01 01 00 00 00 in NTP This counter does not count positive leap seconds and has no indicator that a leap second has been inserted therefore two seconds in sequence will have the same counter value Some computer operating systems in particular Linux assign to the leap second the counter value of the preceding 23 59 59 second 59 59 0 sequence while other computers and the IRIG B time distribution assign to the leap second the counter value of the next 00 00 00 second 59 0 0 sequence citation needed Since there is no standard governing this sequence the timestamp of values sampled at exactly the same time can vary by one second This may explain flaws in time critical systems that rely on timestamped values 63 Other reported software problems associated with the leap second edit Several models of global navigation satellite receivers have software flaws associated with leap seconds Some older versions of Motorola Oncore VP UT GT and M12 GPS receivers had a software bug that would cause a single timestamp to be off by a day if no leap second was scheduled for 256 weeks On 28 November 2003 this happened At midnight the receivers with this firmware reported 29 November 2003 for one second and then reverted to 28 November 2003 64 65 Older Trimble GPS receivers had a software flaw that would insert a leap second immediately after the GPS constellation started broadcasting the next leap second insertion time some months in advance of the actual leap second rather than waiting for the next leap second to happen This left the receiver s time off by a second in the interim 66 67 Older Datum Tymeserve 2100 GPS receivers and Symmetricom Tymeserve 2100 receivers apply a leap second as soon as the a leap second notification is received instead of waiting for the correct date The manufacturers no longer supports these models and no corrected software is available A workaround has been described and tested but if the GPS system rebroadcasts the announcement or the unit is powered off the problem will occur again 68 Four different brands of navigational receivers that use data from BeiDou satellites were found to implement leap seconds one day early 69 This was traced to a bug related to how the BeiDou protocol numbers the days of the week Several software vendors have distributed software that has not properly functioned with the concept of leap seconds NTP specifies a flag to inform the receiver that a leap second is imminent However some NTP server implementations have failed to set their leap second flag correctly 70 71 72 73 Some NTP servers have responded with the wrong time for up to a day after a leap second insertion 74 A number of organizations reported problems caused by flawed software following the leap second that occurred on 30 June 2012 Among the sites which reported problems were Reddit Apache Cassandra Mozilla Hadoop 75 Qantas 76 and various sites running Linux 77 Despite the publicity given to the 2015 leap second a small number of network failures occurred due to leap second related software errors of some routers 78 Several older versions of the Cisco Systems NEXUS 5000 Series Operating System NX OS versions 5 0 5 1 5 2 are affected by leap second bugs 79 Some businesses and service providers have been impacted by leap second related software bugs In 2015 interruptions occurred with Twitter Instagram Pinterest Netflix Amazon and Apple s music streaming series Beats 1 80 Leap second software bugs in Linux reportedly affected the Altea airlines reservation system used by Qantas and Virgin Australia in 2015 81 Cloudflare was affected by a leap second software bug Its DNS resolver implementation incorrectly calculated a negative number when subtracting two timestamps obtained from the Go programming language s time Now function which then used only a real time clock source 82 This could have been avoided by using a monotonic clock source which has since been added to Go 1 9 83 The Intercontinental Exchange parent body to 7 clearing houses and 11 stock exchanges including the New York Stock Exchange chose to cease operations for 61 minutes at the time of the 30 June 2015 leap second 84 There were misplaced concerns that farming equipment using GPS navigation during harvests occurring on 31 December 2016 would be affected by the 2016 leap second 85 GPS navigation makes use of GPS time which is not impacted by the leap second 86 Due to a software error the UTC time broadcast by the NavStar GPS system was incorrect by about 13 microseconds on 25 26 January 2016 87 88 Workarounds for leap second problems editThe most obvious workaround is to use the TAI scale for all operational purposes and convert to UTC for human readable text UTC can always be derived from TAI with a suitable table of leap seconds The Society of Motion Picture and Television Engineers SMPTE video audio industry standards body selected TAI for deriving timestamps of media 89 IEC IEEE 60802 Time sensitive networks specifies TAI for all operations Grid automation is planning to switch to TAI for global distribution of events in electrical grids Bluetooth mesh networking also uses TAI 90 Instead of inserting a leap second at the end of the day Google servers implement a leap smear extending seconds slightly over a 24 hour period centered on the leap second 61 Amazon followed a similar but slightly different pattern for the introduction of the 30 June 2015 leap second 91 leading to another case of the proliferation of timescales They later released an NTP service for EC2 instances which performs leap smearing 92 UTC SLS was proposed as a version of UTC with linear leap smearing but it never became standard 93 It has been proposed that media clients using the Real time Transport Protocol inhibit generation or use of NTP timestamps during the leap second and the second preceding it 94 NIST has established a special NTP time server to deliver UT1 instead of UTC 95 Such a server would be particularly useful in the event the ITU resolution passes and leap seconds are no longer inserted 96 Those astronomical observatories and other users that require UT1 could run off UT1 although in many cases these users already download UT1 UTC from the IERS and apply corrections in software 97 See also editClock drift phenomenon where a clock gains or loses time compared to another clock DUT1 which describes the difference between coordinated universal time UTC and universal time UT1 Dynamical time scale Leap year a year containing one extra day or monthNotes edit Only the Gregorian calendar s leap days begin after 28 February The leap days of other calendars begin at different local times in their own years Ethiopian calendar Iranian calendars Indian national calendar etc The Wall Street Journal noted that the proposal was considered by a U S official at the time to be a private matter internal to the ITU 34 The FCC has posted its received comments which can be found using their search engine for proceeding 04 286 and limiting the received period to those between 27 January and 18 February 2014 inclusive 44 In addition to publishing the video of the special session 47 the Australian Communications and Media Authority has a transcript of that session and a web page with draft content of the Conference Preparatory Meeting report and solutions for ITU R WRC 15 Agenda Item 1 14 48 References edit a b Martin Cassie 19 January 2024 50 years ago timekeepers deployed the newly invented leap second 50 Years Ago Science News p 4 IERS science background Frankfurt am Main IERS 2013 Archived from the original on 29 August 2016 Retrieved 6 August 2016 Gambis Danie 5 January 2015 Bulletin C 49 Paris IERS Archived from the original on 30 May 2015 Retrieved 5 January 2015 James Vincent 7 January 2015 2015 is getting an extra second and that s a bit of a problem for the internet The Verge Archived from the original on 17 March 2017 Finkleman David Allen Steve Seago John Seaman Rob Seidelmann P Kenneth 2011 The Future of Time UTC and the Leap Second American Scientist 99 4 312 319 arXiv 1106 3141 doi 10 1511 2011 91 312 S2CID 118403321 a b Do not adjust your clock scientists call time on the leap second World News The Guardian Agence France Presse 18 November 2022 a b Gibney Elizabeth 18 November 2022 The leap second s time is up world votes to stop pausing clocks Nature 612 7938 18 Bibcode 2022Natur 612 18G doi 10 1038 d41586 022 03783 5 ISSN 0028 0836 PMID 36400956 Ptolemy G J Toomer 1998 Ptolemy s Alemagest Toomer G J Princeton New Jersey Princeton University Press pp 6 7 23 211 216 ISBN 978 0 691 00260 6 al Biruni 1879 The chronology of ancient nations an English version of the Arabic text of the Athar ul Bakiya of Albiruni or Vestiges of the Past Sachau C Edward Oriental Translation Fund of Great Britain amp Ireland pp 141 149 158 408 410 Archived from the original on 14 November 2017 Used for mean new moons both in Hebrew calendar cycles and in equivalent astronomical cycles Everett J D 1875 Illustrations of the centimetre gramme second C G S system of units Taylor and Francis p 83 Pearce J A 1928 The Variability of the Rotation of the Earth Journal of the Royal Astronomical Society of Canada 22 145 147 Bibcode 1928JRASC 22 145P Seidelmann P Kenneth ed 1992 Explanatory Supplement to the Astronomical Almanac Mill Valley California University Science Books pp 79 80 ISBN 0 935702 68 7 Archived from the original on 14 November 2017 a b Leap Seconds Time Service Department United States Naval Observatory Retrieved 19 November 2022 Wm Markowitz 1988 Comparisons of ET Solar ET Lunar UT and TDT in eds A K Babcock amp G A Wilkins The Earth s Rotation and Reference Frames for Geodesy and Geophysics IAU Symposia 128 1988 at pp 413 418 DD McCarthy and AK Babcock 1986 The Length of the Day Since 1658 Phys Earth Planet Inter No 44 pp 281 292 RA Nelson DD McCarthy S Malys J Levine B Guinot HF Fliegel RL Beard and TR Bartholomew 2001 The Leap Second its History and Possible Future 2001 Metrologia 38 pp 509 529 a b c d Stephenson F R Morrison L V 1995 Long term fluctuations in the Earth s rotation 700 BC to AD 1990 Philosophical Transactions of the Royal Society of London A 351 1695 165 202 Bibcode 1995RSPTA 351 165S doi 10 1098 rsta 1995 0028 S2CID 120718607 McCarthy D D Hackman C Nelson R A 2008 The Physical Basis of the Leap Second PDF Astronomical Journal 136 5 1906 1908 Bibcode 2008AJ 136 1906M doi 10 1088 0004 6256 136 5 1906 Archived PDF from the original on 12 March 2021 Retrieved 26 February 2022 Jespersen James Fitz Randolph Jane 1999 From Sundials To Atomic Clocks Understanding Time and Frequency PDF National Institute of Standards and Technology p 109 a b Blair Byron E ed May 1974 NBS Monograph 140 Time and Frequency Theory and Fundamentals PDF p 8 McCarthy Dennis D Seidelmann P Kenneth Time From Earth Rotation to Atomic Physics second ed For provisional limited use the CCIR in 1966 approved Stepped Atomic Time which used the atomic second with frequent 200 ms adjustments made in order to be within 0 1 s of UT2 TAI UTC 1972 01 01 2024 06 28 4 July 2023 Retrieved 4 July 2023 Gambis Daniel 4 July 2008 Bulletin C 36 Paris IERS EOP PC Observatoire de Paris Archived from the original on 6 October 2009 Retrieved 18 April 2010 Andrea Thompson 8 December 2008 2008 Will Be Just a Second Longer Live Science Archived from the original on 12 December 2008 Retrieved 29 December 2008 International Telecommunication Union Radiocommunications sector recommendation TF 460 6 Standard frequency and time signal emissions Archived from the original on 17 October 2016 Retrieved 9 February 2017 Steve Allen 8 June 2011 Extrapolations of the difference TI UT1 ucolick org Archived from the original on 4 March 2016 Retrieved 29 February 2016 Cook Anderson Gretchen Beasley Dolores 10 January 2005 NASA Details Earthquake Effects on the Earth National Aeronautics and Space Administration press release Archived from the original on 27 January 2011 Chester Geoff 15 June 2015 Wait a second 2015 will be a little longer CHIPS Articles The Department of the Navy s Information Technology Magazine Retrieved 4 March 2021 Plait Phil 31 December 2008 Followup Leap Seconds Discover Magazine Bad Astronomy Retrieved 5 March 2021 Jones Graham Bikos Konstantin 6 January 2021 2020 12 23 Earth is in a hurry in 2020 timeanddate com Retrieved 6 March 2021 Knapton Sarah 4 January 2021 The Earth is spinning faster now than at any time in the past half century The Daily Telegraph Archived from the original on 12 January 2022 Retrieved 11 February 2021 Time Split to the Nanosecond Is Precisely What Wall Street Wants The New York Times 29 June 2018 Retrieved 13 December 2022 Dwyer Colin 29 December 2016 With A Leap Second 2016 Promises To Linger Just A Little Bit Longer NPR Archived from the original on 2 January 2023 Retrieved 24 February 2023 Why the U S Wants To End the Link Between Time and Sun The Wall Street Journal Archived from the original on 7 November 2017 Retrieved 31 October 2017 Leap second talks are postponed BBC News Archived from the original on 7 November 2017 Retrieved 31 October 2017 P Kenneth Seidelmann UTC redefinition or change IGS Mail Mailing list Cowen Ron 22 April 2006 To Leap or Not to Leap Scientists debate a timely issue Science News Archived from the original on 26 May 2023 Retrieved 26 May 2023 Steve Allen UTC might be redefined without Leap Seconds Archived from the original on 3 June 2017 Retrieved 31 October 2017 nc1985wp7a Proposed US Contribution to ITU R WP 7A Archived from the original on 1 January 2017 Retrieved 31 October 2017 Demetrios Matsakis 18 August 2014 Comments on the Debate over the Proposal to Redefine UTC PDF Archived PDF from the original on 8 February 2017 Retrieved 31 October 2017 United States Proposals Proposal for the Work of the Conference Agenda Item 1 14 PDF National Telecommunications and Information Administration FCC Seeks Comment On Recommendations Approved By The Advisory Committee For The 2015 World Radiocommunication Conference PDF Federal Communications Commission 28 January 2014 Archived PDF from the original on 29 July 2014 Preliminary Views and Proposals Regarding WRC 15 Agenda Items PPT Organization of American States Archived from the original on 29 July 2014 Search for Filings Results fcc gov Archived from the original on 1 July 2015 Merali Zeeya 8 November 2011 Time is running out for the leap second Nature 479 7372 158 Bibcode 2011Natur 479 158M doi 10 1038 479158a PMID 22071738 S2CID 8220495 Han Chunhao 19 September 2013 Conception Definition and Realization of Time Scale in GNSS PDF Archived PDF from the original on 5 September 2014 Information Session on the WRC 15 agenda item 1 14 Coordinated Universal Time UTC YouTube 15 April 2015 Archived from the original on 18 November 2015 WRC 15 Agenda item 1 14 Coordinated Universal Time UTC acma gov au Archived from the original on 8 September 2015 RESOLUTION 653 WRC 12 Future of the Coordinated Universal Time time scale PDF International Telecommunication Union Archived PDF from the original on 2 July 2015 CCTF Strategy Document International Bureau of Weights and Measures May 2016 pp 21 25 47th CGSIC Meeting Timing Subcommittee PDF 25 September 2007 p 9 Archived from the original PDF on 14 June 2011 Retrieved 18 November 2007 WP7D Status of Coordinated Universal Time UTC study in ITU R Word 2007 International Telecommunication Union Radiocommunication Sector ITU R Release 2 4 October 2011 Archived from the original on 23 March 2014 Retrieved 24 October 2011 To date the BR received replies from 16 different Member States for the latest survey out of a total of 192 Member States 55 of which participate in the formation of UTC 13 being in favor of the change 3 being contrary Coordinated Universal Time UTC to retain leap second Press release International Telecommunication Union 19 November 2015 Archived from the original on 29 January 2016 CGSIC opinion on the redefinition of UTC now under consideration by the International Telecommunication Union ITU Archived from the original on 23 October 2014 The proposed redefinition of Coordinated Universal Time UTC PDF Press release BIPM 13 October 2011 Archived PDF from the original on 18 January 2015 Scientists propose leap hour to fix time system New Scientist 14 May 2012 2008 12 18 Retrieved 3 September 2022 via The New Indian Express Richtel Matt 3 November 2023 A Giant Leap for the Leap Second Is Humankind Ready The New York Times ISSN 0362 4331 Retrieved 23 January 2024 A Resilient Architecture for the Realization and Distribution of Coordinated Universal Time to Critical Infrastructure Systems in the United States Technical report November 2021 doi 10 6028 NIST TN 2187 NIST Internet Time Service ITS NIST 10 February 2010 Kevin Gross March 2014 RTP and Leap Seconds RFC 7164 a b Leap Smear Google Inc Retrieved 26 May 2023 Dimarcq Noel Tavella Patrizia 17 November 2022 Draft Resolution D On the use and future development of UTC Bureau International des Poids et Mesures p 7 Benzler Justus Clark Samuel J 30 March 2005 Toward a Unified Timestamp with explicit precision Demographic Research 12 6 107 140 doi 10 4054 DemRes 2005 12 6 ISSN 1435 9871 PMC 2854819 PMID 20396403 256 Week Leap Second Bug 2 July 2013 Archived from the original on 4 March 2016 Motorola Oncore receivers and Leap Second bug 2 July 2013 Archived from the original on 18 January 2013 Leap second problem with older GPS receivers 19 November 2014 Archived from the original on 29 November 2014 How Leap Seconds Can Interfere with GNSS Receivers 13 May 2015 Archived from the original on 6 March 2016 Symmetricom TymServe 2100 GPS currently fails with GPS offset time nuts Mailing list Archived from the original on 17 February 2015 BeiDou Numbering Presents Leap Second Issue GPS World 3 March 2015 Malone David NTP Leap Bits Archived from the original on 22 July 2014 Retrieved 1 December 2019 Malone David 2016 The Leap Second Behaviour of NTP Servers PDF Proc Traffic Monitoring and Analysis workshop Archived PDF from the original on 23 October 2016 Retrieved 23 October 2016 Cao Yi Veitch Darryl 15 19 April 2018 Network Timing Weathering the 2016 Leap Second IEEE Infocom 2018 Honolulu Hawaii pp 1826 1834 doi 10 1109 INFOCOM 2018 8486286 hdl 10453 130538 Veitch Darryl Vijayalayan Kanthaiah 1 April 2016 Network Timing and the 2015 Leap Second Proc of PAM 2016 Heraklion Crete Greece pp 385 396 doi 10 1007 978 3 319 30505 9 29 hdl 10453 43923 NTP Events satsignal eu Archived from the original on 18 July 2014 Leap Second Bug Wreaks Havoc Across Web Wired 1 July 2012 Archived from the original on 28 March 2014 Leap second crashes Qantas and leaves passengers stranded News Limited 1 July 2012 Archived from the original on 1 July 2012 Anyone else experiencing high rates of Linux server crashes during a leap second day Serverfault com Archived from the original on 9 July 2012 Shulman Eden Beta Boston Boston Globe Archived from the original on 29 September 2015 Retrieved 27 September 2015 Cisco Bug CSCub38654 N5K Switch hang lock up may occur due to Leap second update Cisco 24 July 2015 Archived from the original on 8 March 2016 Sarah Knapton 1 July 2015 Leap Second confuses Twitter and Android The Daily Telegraph Archived from the original on 6 October 2015 Clarke Gavin 8 August 2016 Power cut crashes Delta s worldwide flight update systems The Register Archived from the original on 4 January 2017 Retrieved 3 January 2017 How and why the leap second affected Cloudflare DNS Cloudflare 1 January 2017 Archived from the original on 2 January 2017 12914 runtime time expose monotonic clock source GitHub Archived from the original on 20 March 2017 Retrieved 5 January 2017 ICE Market Update Leap Second Impact Intercontinental Exchange Archived from the original on 5 May 2015 Got a second the world time needs it ABC Rural 30 December 2016 Archived from the original on 2 January 2017 Retrieved 3 January 2017 How fast is the earth moving Rhett Herman a physics professor at Radford University in Virginia supplies the following answer Scientific American 26 October 1998 Air Force Official Press Release GPS Ground System Anomaly PDF Yao Jian Lombardi Michael A Novick Andrew N Patla Bijunath Sherman Jeff A Zhang Victor The effects of the January 2016 UTC offset anomaly on GPS controlled clocks monitored at NIST PDF Paul Briscoe 14 May 2013 Network Based Timing and Synchronization PDF Mesh Model Bluetooth Specification PDF download Bluetooth Technology Website 13 July 2017 Retrieved 14 December 2019 See sections 5 1 1 and A 1 Jeff Barr 18 May 2015 Look Before You Leap The Coming Leap Second and AWS Updated Amazon Web Services Randall Hunt 29 November 2017 Keeping Time With Amazon Time Sync Service Amazon Web Services Retrieved 8 March 2018 Kuhn Markus 2005 UTC with Smoothed Leap Seconds UTC SLS www cl cam ac uk Kevin Gross March 2014 RTP and Leap Seconds doi 10 17487 RFC7164 RFC 7164 UT1 NTP Time Dissemination National Institute of Standards and Technology 11 December 2015 Retrieved 31 August 2019 Wallace Patrick 2003 The UTC Problem and its Solution PDF Proceedings of Colloquium on the UTC Time Scale Torino Archived PDF from the original on 18 January 2015 Luzum Brian 2013 The Role of the IERS in the Leap Second PDF BIPM ITU Workshop on the Future of the International Time Scale Archived PDF from the original on 15 July 2014 Further reading editAhuja Anjana 30 October 2005 Savouring the last leap second in history New Straits Times p F10 Grossman Wendy M 1 November 2005 Wait a Second Scientific American Vol 293 no 5 pp 12 13 doi 10 1038 scientificamerican1105 24 Finkleman David Allen Steve Seago John Seaman Rob Seidelmann P Kenneth 2011 The Future of Time UTC and the Leap Second American Scientist 99 4 312 319 arXiv 1106 3141 doi 10 1511 2011 91 312 S2CID 118403321 Kamp Poul Henning 2011 The One Second War Communications of the ACM 54 5 44 48 doi 10 1145 1941487 1941505 McCarthy Dennis D Seidelmann P Kenneth 2009 TIME From Earth Rotation to Atomic Physics Weinheim Wiley VCH doi 10 1002 9783527627943 ISBN 978 3527407804 External links edit nbsp Wikimedia Commons has media related to Leap second IERS Bulletins including Bulletin C leap second announcements LeapSecond com A web site dedicated to precise time and frequency NIST FAQ about leap year and leap second The leap second its history and possible future Support for the leap second Microsoft Support 4 October 2018 Dan Cuomo 17 October 2018 Leap Seconds for the IT Pro What you need to know Windows Server Networking Blog Travis Luke 24 October 2018 Leap Seconds for the AppDev What you should know Windows Server Networking Blog Leap Second Readiness Tips www orolia com Orolia 31 December 2018 Judah Levine s Everyday Time and Atomic Time series Judah Levine 31 March 2021 Everyday Time and Atomic Time Part One National Institute of Standards and Technology Judah Levine 7 April 2021 Everyday Time and Atomic Time Part Two National Institute of Standards and Technology Judah Levine 14 April 2021 Everyday Time and Atomic Time Part Three National Institute of Standards and Technology Judah Levine 21 April 2021 Everyday Time and Atomic Time Part Four National Institute of Standards and Technology Judah Levine 28 April 2021 Everyday Time and Atomic Time Part Five National Institute of Standards and Technology Retrieved from https en wikipedia org w index php title Leap second amp oldid 1198314161, wikipedia, wiki, book, books, library,

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