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Local time

Local time refers to the time observed at a specific geographic location on Earth, determined by the Sun's position relative to that location's meridian, with noon marking the Sun's transit overhead.^[1] It serves as a solar-based timekeeping system that varies continuously with longitude, reflecting the Earth's rotation and the natural progression of day and night at each site.^[1] There are two primary forms of local time: apparent local time, which is based on the actual position of the Sun as observed (e.g., via a sundial) and varies slightly due to the Earth's elliptical orbit and axial tilt, and local mean time, which uses a hypothetical "mean Sun" that moves uniformly across the sky to provide a more consistent measure averaging out these irregularities.^[1] The difference between apparent and mean local time is known as the equation of time, which can reach up to about 16 minutes throughout the year.^[1] These variations ensure that local time aligns closely with local solar noon, when the Sun reaches its highest point, but they complicate uniform scheduling across regions.^[1] In modern usage, local time has largely been supplanted by standard time, which assigns a single mean time to broad zones (typically 15 degrees of longitude wide) for practical reasons like transportation and communication, with the first U.S. adoption occurring on November 18, 1883, via railroad coordination.^[1] Standard time approximates local mean time at the zone's central meridian but can differ by up to 30 minutes or more at zone edges, leading to occasional adjustments like daylight saving time to better sync with solar patterns.^[1] Despite this, local time remains relevant in astronomy, navigation, and precise solar observations, where exact alignment with celestial events is essential.^[2]

Fundamentals

Definition

Local time, often referred to as local solar time, is the measure of time based on the apparent position of the Sun in the sky at a specific geographic location, defined by its longitude. It is determined such that local solar noon—when the Sun reaches its highest point in the sky by transiting the local meridian—corresponds to 12:00 local time at that longitude.^[3] This astronomical basis makes local time a direct reflection of the Sun's transit across the local meridian.^[4] The variation in local time arises from the Earth's rotation, which completes a full 360-degree turn relative to the Sun in 24 hours, resulting in a time difference of 4 minutes for every degree of longitude.^[5] Thus, locations separated by one degree of longitude experience solar noon offset by 4 minutes, creating a continuous gradient of time across the globe.^[6] For example, at the Prime Meridian (0° longitude), local solar noon precisely defines 12:00 local time, serving as a reference for calculating offsets elsewhere.^[7] A location 15° east would have solar noon 1 hour earlier relative to the Prime Meridian.^[8] This system renders local time inherently variable and tied to precise longitudinal position, contrasting with uniform timekeeping methods designed for broader coordination.^[7]

Distinction from Standard Time

Standard time refers to the official civil time observed within a specific geographic region, established as a fixed offset from Coordinated Universal Time (UTC), such as UTC-5 for Eastern Standard Time. This system prioritizes uniformity across an entire time zone, disregarding the precise local solar position to enable coordinated activities like rail scheduling and telecommunications.^[9]^[10] In contrast, local time—specifically local mean solar time—is calculated based on the average position of the Sun relative to the observer's longitude, resulting in a time that varies continuously with location. The primary distinction arises from the width of time zones, which generally cover about 15 degrees of longitude to approximate one hour of time difference; consequently, local time at the edges of a zone can deviate by as much as 30 minutes from the standard time referenced to the zone's central meridian.^[5]^[11] This deviation has practical implications, as public clocks and schedules adhere to standard time for seamless regional synchronization, rather than adjusting for solar alignment, which would complicate daily operations. For example, in New York City (at approximately 74°W), local mean solar noon occurs about 4 minutes before 12:00 PM Eastern Standard Time due to its position relative to the zone's standard meridian at 75°W.^[12]^[5]

Historical Development

Pre-Modern Timekeeping

In ancient civilizations, particularly Egypt around 1500 BCE, timekeeping relied on observations of the sun's position to determine local time, with sundials serving as one of the earliest devices for this purpose.^[13] These shadow clocks, often portable, divided the sunlit day into segments based on the shadow cast by a gnomon at solar noon, when the sun reached its zenith.^[14] Complementing sundials, water clocks or clepsydrae were also developed in Egypt during the same period, using the steady flow of water to measure intervals independently of sunlight, though still calibrated to local solar observations for daily synchronization.^[15] Such instruments allowed communities to structure activities around apparent solar time, reflecting the position of the sun relative to the observer's longitude. During the medieval and early modern periods in Europe, timekeeping remained decentralized, with individual towns and cities setting their mechanical clocks independently based on local solar noon to maintain consistency within their boundaries.^[16] By the 14th century, as public clocks proliferated in urban centers, this practice resulted in hundreds of distinct local times across the continent, each varying slightly due to differences in longitude and leading to practical discrepancies in coordination between locations. These clocks, often housed in church towers or town halls, were adjusted daily using sundials or astronomical observations to align with the sun's highest point, ensuring that noon marked the midpoint of daylight for that specific locale. The inconsistencies of such local timekeeping became increasingly problematic with expanding travel and communication in the 19th century, particularly as railways highlighted the need for synchronization. In Britain, for instance, the Great Western Railway adopted "railway time" based on London mean time in November 1840 to resolve scheduling errors caused by local variations of up to 20 minutes, though this met resistance from communities reluctant to alter their sun-based clocks.^[17] Similar challenges arose in the United States, where over 100 local times operated before 1884, creating chaos for rail timetables and intercity travel as trains traversed regions with differing noons.^[18] This patchwork system underscored the limitations of observation-based local time in an era of growing mobility, where even short distances could result in significant temporal offsets.

Introduction of Standard Time Zones

The expansion of railroads and telegraphic networks in the 19th century necessitated a shift from the inconsistent local times prevalent in the pre-modern era to a coordinated system of standard time zones, primarily to synchronize schedules and communications across vast distances. Canadian engineer Sir Sandford Fleming, motivated by delays in transcontinental rail travel, proposed a global system of 24 time zones divided by 15-degree meridians of longitude in 1879, advocating for universal adoption to streamline international coordination. In the United States, major railroads implemented this concept domestically by adopting four standard time zones—Eastern, Central, Mountain, and Pacific—on November 18, 1883, marking a pivotal "Day of Two Noons" when clocks were reset nationwide to eliminate over 100 local times used by various rail lines. This momentum culminated in the International Meridian Conference held in Washington, D.C., from October 1 to November 1, 1884, attended by representatives from 25 nations. The conference unanimously selected the Greenwich Meridian as the prime meridian (0° longitude) and recommended the division of the world into 24 standard time zones, each spanning 15 degrees of longitude and differing by one hour, with Greenwich Mean Time (GMT) serving as the reference. Although the resolutions were non-binding, they provided an international framework that influenced subsequent national adoptions, resolving long-standing disputes over meridian selection that had hindered global navigation and commerce. Adoption spread unevenly but steadily across Europe and beyond. Britain legally established GMT as its national standard time through the Statutes (Definition of Time) Act on August 2, 1880, unifying the country's previously varied local times. France followed in 1891 by adopting Paris Mean Time as its uniform national standard, initially resisting GMT but eventually aligning with international norms. By the 1920s, full international coordination was achieved through conferences under the International Telegraph Union (ITU's predecessor), which standardized time signals via radio and telegraphy, ensuring most nations had implemented time zones aligned with the 1884 recommendations.

Relation to Solar Time

Apparent Solar Time

Apparent solar time refers to the measurement of time derived from the actual position of the Sun in the sky as observed from a specific location on Earth. It is based on the diurnal motion of the true Sun, where the hour angle of the Sun determines the progression of time throughout the day. This form of timekeeping directly reflects the Sun's apparent path across the celestial sphere, without any adjustments for uniformity.^[19] Local noon in apparent solar time occurs precisely when the Sun reaches its highest point in the sky, crossing the observer's local meridian. At this moment, the Sun's hour angle is zero, marking 12:00 in apparent solar time for that locality. Prior to noon, the time counts backward from this point, while afterward it progresses forward, providing a direct indicator of the Sun's position relative to the meridian. This makes apparent solar time inherently tied to the observer's longitude and the instantaneous solar position.^[20] Apparent solar time is traditionally measured using a sundial, which casts a shadow based on the Sun's rays to indicate the hour. The sundial's markings align with the Sun's apparent motion, allowing for straightforward observation of time at any given location. However, this time varies from day to day because the Earth's orbit around the Sun is elliptical, causing the planet to move at uneven speeds, and because of the 23.44° axial tilt, which affects the Sun's declination throughout the year. These factors result in the rate of the Sun's diurnal motion undergoing seasonal changes.^[19]^[21] A key characteristic of apparent solar time is the fluctuation in the length of the apparent solar day, defined as the interval between two successive local noons. This length varies between approximately 23 hours 59 minutes 38 seconds and 24 hours 0 minutes 30 seconds over the course of a year, primarily due to the combined effects of orbital eccentricity and axial obliquity. In late December, for instance, the solar day can be about 30 seconds longer than the average 24 hours, while it shortens by up to 22 seconds around early September. Apparent solar time can thus be simply expressed as the elapsed time since the previous local solar noon, as directly observed through the Sun's position.^[20]^[22]^[23]

Mean Solar Time and the Equation of Time

Mean solar time serves as a standardized approximation of solar time, representing the average position of the Sun over the course of a year to ensure uniform 24-hour days. It assumes a fictitious "mean Sun" that travels across the sky at a constant speed along the celestial equator, completing one full circuit every 365.2422 days, which aligns with the tropical year. This concept forms the foundation for modern clock time, allowing for consistent timekeeping independent of the Sun's irregular apparent motion.^[20] The equation of time quantifies the discrepancy between apparent solar time—based on the actual position of the Sun—and mean solar time, arising from two primary astronomical factors: the obliquity of Earth's axial tilt (approximately 23.44°) and the eccentricity of Earth's orbit around the Sun (approximately 0.0167). The tilt causes the Sun's path to vary in speed due to changes in the Earth's rotational rate relative to its orbital position, contributing up to ±10 minutes of variation, while the orbital eccentricity leads to faster motion near perihelion and slower near aphelion, adding up to ±7.5 minutes. Overall, the equation of time fluctuates by up to ±16 minutes throughout the year.^[20] A simplified annual model for the equation of time E in minutes is given by

E \approx -7.5 \cos\left(\frac{2\pi (t + 10)}{365}\right) + 10 \sin\left(\frac{4\pi (t - 80)}{365}\right),

where t is the day of the year (starting from January 1). This approximation captures the dominant periodic components from the obliquity and eccentricity effects, though more precise calculations incorporate additional terms for accuracy.^[20] The yearly variation of the equation of time is visually represented by the analemma, a figure-eight shaped curve formed by plotting the Sun's position in the sky at the same mean solar time each day over a year; the horizontal extent of this loop corresponds to the equation of time's fluctuations, with extremes reaching a minimum of about -14 minutes in early February and a maximum of about +16 minutes in early November. When positive, the equation indicates that apparent solar time is ahead of mean solar time (the Sun reaches the meridian earlier than the mean Sun), and when negative, it lags behind. This pattern repeats annually, enabling corrections for precise solar observations.^[20]

Time Zone Implementation

Longitude-Based Calculations

Local mean time at a given location is calculated based on its longitude relative to the Prime Meridian at Greenwich, which serves as the reference for Coordinated Universal Time (UTC). The Earth completes one full rotation of 360° in 24 hours, resulting in a time difference of 15° of longitude per hour. This relationship allows for a straightforward determination of the time offset from UTC. The formula for local mean time is given by:

\text{Local mean time} = \text{UTC} + \frac{\text{longitude (degrees)}}{15}

where longitude is measured positive for east of Greenwich and negative for west. Equivalently, since each degree of longitude corresponds to 4 minutes of time (as 60 minutes per hour divided by 15° per hour equals 4 minutes per degree), the offset can be computed as longitude multiplied by 4 minutes.^[24] For example, a location at 90° E longitude has a time offset of $90 / 15 = 6 hours ahead of UTC, so its local mean time is UTC + 6 hours. This calculation yields mean solar time, which assumes a uniform rotation rate; for exact apparent solar time, an additional correction known as the equation of time must be applied to account for variations in the Earth's elliptical orbit and axial tilt.^[24]

Major Time Zone Standards

The global time zone system is structured around 24 standard time zones, each ideally encompassing 15 degrees of longitude to align with Earth's 24-hour rotation cycle, with offsets ranging from UTC-12 to UTC+12 relative to Coordinated Universal Time (UTC). These zones are labeled by their UTC offsets, where UTC+0 serves as the reference for Greenwich Mean Time (GMT), historically based on the prime meridian at the Royal Observatory in Greenwich, England. This framework facilitates international coordination, though actual boundaries often adjust for geographical and administrative needs.^[25]^[26]^[27] Deviations from the 15-degree ideal occur frequently due to national policies and historical precedents, resulting in zones that are narrower, wider, or offset by non-hourly increments. For instance, India's single time zone, Indian Standard Time (IST) at UTC+5:30, covers the entire country, which spans approximately 29 degrees of longitude from 68°7'E to 97°25'E, leading to significant variations in local solar time across regions. Half-hour offsets like IST, along with quarter-hour ones such as Nepal Time (NPT) at UTC+5:45, reflect compromises to better approximate mean solar time or maintain national unity, affecting only a few countries including Iran (UTC+3:30) and parts of Australia (UTC+8:45 in the Eucla region of Western Australia).^[28]^[29]^[30]^[31] Political decisions further shape time zones, prioritizing borders and administrative efficiency over strict longitudinal divisions. China, for example, adopted a uniform UTC+8 (China Standard Time) in 1949, encompassing its vast territory that stretches over 60 degrees of longitude from about 73°E to 135°E, effectively compressing what could be five separate zones into one for national cohesion. Such adjustments ensure that contiguous regions share the same clock time, though they can create discrepancies from local apparent solar time. The International Date Line, marking the transition between calendar days, approximates the 180° meridian but incorporates zigzags to circumvent landmasses and island chains, such as those in the Aleutians and Fiji, preventing the split of political entities across date boundaries.^[32]^[33]^[34]

Modern Applications

In astronomy, local time serves as a foundational reference for positioning celestial objects relative to an observer's meridian. Local sidereal time (LST), which measures the Earth's rotation against the fixed stars, is derived from local mean solar time by accounting for the planet's orbital motion around the Sun, which causes sidereal days to be about 4 minutes shorter than solar days. This derivation enables astronomers to predict when stars will cross the local meridian, essential for scheduling observations and aligning telescopes. The utility of LST in astronomy is further highlighted through its role in calculating the local hour angle (HA) of a celestial body, which quantifies the object's angular position westward from the observer's meridian along the celestial equator. The formula is HA = LST - right ascension (α), expressed in hours, allowing precise determination of a star's altitude and azimuth for observation planning.^[35] For instance, observing the transit of a circumpolar star near local noon—when the Sun crosses the meridian—helps establish the exact alignment of the local meridian, providing a reference for accurate positional measurements in both historical and contemporary astronomical surveys.^[36] In navigation, local time has long been integral to determining geographic position, particularly longitude. Historically, mariners relied on comparing local apparent time, observed via the Sun's meridian passage at local noon, with the fixed time at the Greenwich prime meridian carried by a chronometer. John Harrison's H4 marine chronometer, completed in 1761 after decades of innovation, achieved accuracy within seconds per day despite shipboard conditions, enabling reliable longitude calculations that reduced maritime losses from navigational errors.^[37] This method transformed seafaring by converting the time difference into degrees of longitude (15 degrees per hour). Contemporary navigation builds on this principle through the Global Positioning System (GPS), where satellite signals broadcast precise atomic time traceable to Coordinated Universal Time (UTC). Receivers compute position by measuring signal travel times, yielding longitude from which local mean time is derived by adjusting UTC for the location's offset; this integration ensures sub-meter accuracy for fixes in aviation, maritime, and terrestrial applications.^[38]

Role in Computing and Global Systems

In computing systems, local time is managed through specialized databases and APIs that maintain offsets from Coordinated Universal Time (UTC) to ensure accurate representation across regions. The Internet Assigned Numbers Authority (IANA) maintains the tz database (tzdb), a comprehensive repository of historical and projected local time data for over 400 zones worldwide, including UTC offsets and rules for transitions like daylight saving time.^[39] This database serves as the foundation for libraries in programming languages, allowing developers to compute local times reliably; for instance, Java's ZonedDateTime class in the java.time package combines a LocalDateTime with a ZoneId from the tzdb to derive the appropriate offset and adjust timestamps accordingly, preventing errors in international applications.^[40] Global synchronization relies on protocols like the Network Time Protocol (NTP), defined in RFC 5905, which distributes UTC timestamps from stratum servers to client devices over IP networks, achieving sub-millisecond accuracy in ideal conditions.^[41] Once synchronized to UTC, systems apply local offsets from the tzdb to display or process times in the user's zone, facilitating coordination in distributed environments such as cloud services and financial trading platforms. However, challenges arise with irregularities like leap seconds—insertions into UTC to align with Earth's rotation—which can disrupt monotonic time in distributed systems; NTP mitigates this by signaling leap seconds in advance via leap indicators, but applications must handle "smearing" or step adjustments to avoid desynchronization during the 61st-second event, as outlined in NTP implementation guidelines.^[42] In 2022, the 27th General Conference on Weights and Measures adopted Resolution 4, calling for the discontinuation of leap seconds in UTC no later than 2035 to prevent such disruptions.^[43] A practical example is email communication, where the Date header in RFC 5322 specifies the sender's local time with an offset, but receiving clients use zone information from the tzdb to convert and display it in the recipient's local time, ensuring contextual relevance without ambiguity. For unambiguous representation in computing and data exchange, the ISO 8601 standard, profiled in RFC 3339 for Internet protocols, recommends expressing times in UTC with explicit offsets (e.g., 2025-11-14T10:30:00+00:00) or the 'Z' suffix for UTC, promoting interoperability in APIs, logs, and databases while avoiding reliance on implicit local assumptions.^[44]

Special Cases

Effects of Daylight Saving Time

Daylight saving time (DST) involves a seasonal adjustment where clocks are advanced by one hour, typically during warmer months, to make better use of evening daylight for energy conservation and lifestyle benefits. This forward shift creates a "summer local time" that deviates from standard time zones, effectively postponing clock time relative to solar events. The concept originated with British builder William Willett, who proposed advancing clocks by 80 minutes in total across spring Sundays in a 1907 pamphlet titled The Waste of Daylight, aiming to reduce artificial lighting needs.^[45] Although Willett's idea faced initial rejection, it gained traction during World War I as governments sought energy savings; Germany became the first nation to implement DST on April 30, 1916, soon followed by the United Kingdom on May 21, 1916, France on June 14, 1916, and the United States in 1918 via the Standard Time Act.^[45]^[46] The primary impact of DST on local time is a further misalignment with solar noon, the moment when the sun reaches its highest point. In standard time, solar noon approximately aligns with 12:00 p.m. clock time in the center of a time zone, but during DST, this shifts to around 1:00 p.m., extending daylight into later evening hours while shortening mornings.^[47] This adjustment alters daily routines, such as later sunrises and sunsets on the clock, to promote outdoor activities and reduce peak evening energy use for lighting, though it does not change the actual length of daylight.^[48] Globally, DST is observed in over 70 countries, primarily in the Northern Hemisphere, affecting more than 1 billion people with varying implementation dates.^[49] In the European Union, uniform rules were established through Council Directive 81/358/EEC in 1981, standardizing the transition to the last Sunday in March and reversion on the last Sunday in September across member states to facilitate cross-border coordination. In the United States, the Energy Policy Act of 2005 extended the DST period by about a month, shifting the start to the second Sunday in March and the end to the first Sunday in November, effective from 2007, to further energy-saving goals.^[50] As of 2025, there are ongoing debates and legislative efforts in the European Union and the United States to abolish DST and adopt permanent standard or daylight time, though no widespread changes have been implemented.^[51] DST does not alter Coordinated Universal Time (UTC), which remains a fixed reference; instead, it modifies the offset of local time zones, such as Eastern Daylight Time (EDT) at UTC-4 compared to Eastern Standard Time (EST) at UTC-5.^[52] This ensures global synchronization while allowing regional adjustments for daylight optimization.^[47]

Challenges in Polar Regions

In polar regions, particularly above the Arctic Circle (approximately 66.5°N) and below the Antarctic Circle (66.5°S), the phenomena of polar day and polar night fundamentally disrupt traditional concepts of local solar time. During the polar day, which lasts from about March to September in the Arctic and September to March in the Antarctic, the sun remains above the horizon for up to six months, resulting in continuous daylight that eliminates the daily rising and setting cycle essential for defining solar noon or apparent local time. For instance, in June, locations like the North Pole experience 24-hour daylight, rendering standard solar-based timekeeping irrelevant as there is no observable midday shadow or sunset to align with. Similarly, the polar night brings prolonged darkness, further decoupling human activities from natural light cues and complicating the synchronization of local time with astronomical events.^[53]^[54] To address these irregularities, polar research stations and expeditions adopt practical timekeeping systems rather than longitude-based local time, often relying on Coordinated Universal Time (UTC) for international coordination or the standard time of the operating or supplying country. In Antarctica, no uniform daylight saving time (DST) is observed across the continent; instead, stations follow their nation's conventions, such as McMurdo Station using New Zealand time (UTC+12/13), including daylight saving time, chosen for logistical alignment with supply flights from Christchurch. Other bases, like the Amundsen-Scott South Pole Station, also adhere to New Zealand time (UTC+12/13), while the British Halley VI Station uses GMT (UTC+0) year-round. In the Arctic, transient operations like ships in the central ice cap select arbitrary time zones—such as Moscow time for coordination with Russian vessels—or maintain UTC to impose structure amid the lack of fixed zones at the pole itself. This approach ensures operational efficiency but highlights the artificial nature of time in environments where solar patterns provide no natural reference.^[55]^[53]^[56] A notable example is Svalbard, Norway, where Central European Time (CET, UTC+1) is used despite the archipelago's high latitude (78°N), leading to extended periods of midnight sun from late April to late August that enable 24/7 operations without reliance on traditional day-night divisions. This continuous light fosters round-the-clock research and tourism but challenges sleep patterns and routine scheduling, as the absence of darkness blurs temporal boundaries.^[57]^[58] Navigation in polar regions faces additional complications from magnetic variations and auroral effects, which indirectly impact time-sensitive observations and positioning reliant on local time references. The auroral zones, centered near the magnetic poles, experience frequent geomagnetic storms that disrupt magnetic compasses—causing erratic readings due to rapid field fluctuations—and degrade GPS signals through ionospheric scintillation, particularly during polar cap patches associated with auroras. These disturbances, common in high latitudes, can delay or skew astronomical and geophysical observations that require precise local time alignment for data logging, such as tracking satellite passes or celestial navigation. Radio communications, vital for synchronizing time across remote teams, are also intermittently blacked out by auroral-induced absorption, further hindering real-time coordination in areas where solar time is already obsolete.^[59]^[60]

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A ZonedDateTime holds state equivalent to three separate objects, a LocalDateTime , a ZoneId and the resolved ZoneOffset . The offset and local date-time are ...FramesUses of Class java.time ...
[42]
RFC 5905 - Network Time Protocol Version 4 - IETF Datatracker
... synchronization function of the NTP program. A timestamp T(t) represents either the UTC date or time offset from UTC at running time t. Which meaning is ...
[43]
Executive Summary: Computer Network Time Synchronization
May 3, 2023 · The UTC timescale is disciplined with respect to International Atomic Time (TAI) by inserting leap seconds at intervals of about 18 months.Missing: challenges | Show results with:challenges
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RFC 3339 - Date and Time on the Internet: Timestamps
This document defines a date and time format for use in Internet protocols that is a profile of the ISO 8601 standard for representation of dates and times ...
[45]
History of Daylight Saving Time (DST)
Sep 11, 2025 · In 1905, independently from Hudson, British builder William Willett suggested setting the clocks ahead 20 minutes on each of the four Sundays in ...
[46]
World War I and Daylight Savings Time | Teaching with the Library
Mar 9, 2017 · The first law in the US to establish daylight saving time, passed on March 19, 1918, in the midst of the nation's involvement in World War I.
[47]
Daylight Saving Time
... local time. During the "energy crisis" years, Congress enacted earlier starting dates for Daylight Saving Time. In 1974, Daylight Saving Time began on 6 ...
[48]
https://www.timeanddate.com/time/dst/about.html
[49]
Daylight Saving Time Statistics - DST worldwide - Time and Date
Number of Countries Using DST DST is controversial. More than 140 countries have used it at some point, but about half of them have since abolished it again.
[50]
H.R.6 - 109th Congress (2005-2006): Energy Policy Act of 2005
(Sec. 110) Amends the Uniform Time Act of 1966 to extend standard daylight time from March to November (currently it runs from April to October).
[51]
Daylight Saving Time Rules | NIST
Mar 2, 2010 · The new changes were enacted by the Energy Policy Act of 2005, which extended the length of DST in the interest of reducing energy consumption.
[52]
What time zones are used at the North Pole and South Pole?
The rotation of the Earth means that time zones are dictated by the lines of longitude connecting the two poles.
[53]
What Time Is It at the North Pole?
The Arctic is like no other place on Earth; a vast, floating ice cap with no permanent population, no set timezone, and no normal daylight hours. These factors ...
[54]
Time Zones in Antarctica
McMurdo Station follows New Zealand Standard Time (NZST) during standard time and New Zealand Daylight Time (NZDT) during the DST period in New Zealand. The ...McMurdo Station · South Pole · Weather
[55]
Time Has No Meaning at the North Pole | Scientific American
Mar 13, 2020 · Sea captains choose their own time in the central Arctic. They may maintain the time zones of bordering countries—or they may switch based ...
[56]
Current Local Time in Longyearbyen, Svalbard, Norway
Current Local Time in Longyearbyen, Svalbard, Norway ; Time Zone. CET (Central European Time) UTC/GMT +1 hour ; DST started. Mar 30, 2025. Forward 1 hour ; DST ...
[57]
The midnight sun in Svalbard
It occurs in Longyearbyen in Svalbard from April 19th until August 23rd. The midnight sun by itself is a fantastic experience in itself, though it's not just ...
[58]
[PDF] CHAPTER 33 POLAR NAVIGATION - The Nautical Almanac
3308. The magnetic storms centered in the auroral zones dis- rupt radio frequency navigation and communications and alter magnetic compass sensibility. The ...
[59]
GPS scintillation effects associated with polar cap patches and ...
Aug 4, 2014 · We directly compare the relative GPS scintillation levels associated with regions of enhanced plasma irregularities called auroral arcs, polar ...1. Introduction · 2. Observations · 3. Discussion