Английская Википедия:Equation of time

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Шаблон:Short description Шаблон:Use dmy dates

Файл:Equation of time.svg
The equation of time — above the axis a sundial will appear fast relative to a clock showing local mean time, and below the axis a sundial will appear slow.
Файл:Tijdvereffening-equation of time-en.jpg
This graph shows how many minutes the clock is ahead (+) or behind (−) the apparent sun. See the section "Sign of the equation of time" below.

The equation of time describes the discrepancy between two kinds of solar time. The word equation is used in the medieval sense of "reconciliation of a difference". The two times that differ are the apparent solar time, which directly tracks the diurnal motion of the Sun, and mean solar time, which tracks a theoretical mean Sun with uniform motion along the celestial equator. Apparent solar time can be obtained by measurement of the current position (hour angle) of the Sun, as indicated (with limited accuracy) by a sundial. Mean solar time, for the same place, would be the time indicated by a steady clock set so that over the year its differences from apparent solar time would have a mean of zero.[1]

The equation of time is the east or west component of the analemma, a curve representing the angular offset of the Sun from its mean position on the celestial sphere as viewed from Earth. The equation of time values for each day of the year, compiled by astronomical observatories, were widely listed in almanacs and ephemerides.[2]Шаблон:R

The equation of time can be approximated by a sum of two sine waves (see explanation below):

<math>D = 6.240\, 040\, 77 + 0.017\, 201\, 97(365.25(y-2000) + d)</math>
<math>\Delta t_{ey} = -7.659\sin(D) + 9.863\sin \left(2D + 3.5932 \right)</math> [minutes]

where <math>d</math> represents the number of days since January 1 of the current year, <math>y</math>.

The concept

Файл:L' equazione del tempo. Foro Carolino in piazza Dante, Napoli.jpg
Clock with auxiliary dial displaying the equation of time. Piazza Dante, Naples (1853).

During a year the equation of time varies as shown on the graph; its change from one year to the next is slight. Apparent time, and the sundial, can be ahead (fast) by as much as 16 min 33 s (around 3 November), or behind (slow) by as much as 14 min 6 s (around 11 February). The equation of time has zeros near 15 April, 13 June, 1 September, and 25 December. Ignoring very slow changes in the Earth's orbit and rotation, these events are repeated at the same times every tropical year. However, due to the non-integral number of days in a year, these dates can vary by a day or so from year to year.Шаблон:RefnШаблон:R

The graph of the equation of time is closely approximated by the sum of two sine curves, one with a period of a year and one with a period of half a year. The curves reflect two astronomical effects, each causing a different non-uniformity in the apparent daily motion of the Sun relative to the stars:

  • the obliquity of the ecliptic (the plane of the Earth's annual orbital motion around the Sun), which is inclined by about 23.44 degrees relative to the plane of the Earth's equator; and
  • the eccentricity of the Earth's orbit around the Sun, which is about 0.0167.

The equation of time vanishes only for a planet with zero axial tilt and zero orbital eccentricity.[3] Two examples of planets with large equations of time are Mars and Uranus. On Mars the difference between sundial time and clock time can be as much as 50 minutes, due to the considerably greater eccentricity of its orbit. The planet Uranus, which has an extremely large axial tilt, has an equation of time that makes its days start and finish several hours earlier or later depending on where it is in its orbit.

Sign of the equation of time

The United States Naval Observatory states "the Equation of Time is the difference apparent solar time minus mean solar time", i.e. if the sun is ahead of the clock the sign is positive, and if the clock is ahead of the sun the sign is negative.[4][5] The equation of time is shown in the upper graph above for a period of slightly more than a year. The lower graph (which covers exactly one calendar year) has the same absolute values but the sign is reversed as it shows how far the clock is ahead of the sun. Publications may use either format — in the English-speaking world, the former usage is the more common, but is not always followed. Anyone who makes use of a published table or graph should first check its sign usage. Often, there is a note or caption which explains it. Otherwise, the usage can be determined by knowing that, during the first three months of each year, the clock is ahead of the sundial. The mnemonic "NYSS" (pronounced "nice"), for "new year, sundial slow", can be useful. Some published tables avoid the ambiguity by not using signs, but by showing phrases such as "sundial fast" or "sundial slow" instead.[6]

In this article, and others in English Wikipedia, a positive value of the equation of time implies that a sundial is ahead of a clock.

History

The phrase "equation of time" is derived from the medieval Latin aequātiō diērum, meaning "equation of days" or "difference of days". The word aequātiō (and Middle English equation) was used in medieval astronomy to tabulate the difference between an observed value and the expected value (as in the equation of the centre, the equation of the equinoxes, the equation of the epicycle). Gerald J. Toomer uses the medieval term "equation", from the Latin aequātiō,Шаблон:Refn for Ptolemy's difference between the mean solar time and the apparent solar time. Johannes Kepler's definition of the equation is "the difference between the number of degrees and minutes of the mean anomaly and the degrees and minutes of the corrected anomaly."Шаблон:R

The difference between apparent solar time and mean time was recognized by astronomers since antiquity, but prior to the invention of accurate mechanical clocks in the mid-17th century, sundials were the only reliable timepieces, and apparent solar time was the generally accepted standard. Mean time did not supplant apparent time in national almanacs and ephemerides until the early 19th century. Шаблон:Sfn

Early astronomy

The irregular daily movement of the Sun was known to the Babylonians.Шаблон:Citation needed

Book III of Ptolemy's Almagest (2nd century) is primarily concerned with the Sun's anomaly, and he tabulated the equation of time in his Handy Tables.[7] Ptolemy discusses the correction needed to convert the meridian crossing of the Sun to mean solar time and takes into consideration the nonuniform motion of the Sun along the ecliptic and the meridian correction for the Sun's ecliptic longitude. He states the maximum correction is Шаблон:Frac time-degrees or Шаблон:Frac of an hour (Book III, chapter 9).[8] However he did not consider the effect to be relevant for most calculations since it was negligible for the slow-moving luminaries and only applied it for the fastest-moving luminary, the Moon.

Based on Ptolemy's discussion in the Almagest, values for the equation of time (Arabic taʿdīl al-ayyām bi layālayhā) were standard for the tables (zij) in the works of medieval Islamic astronomy.[9]

Early modern period

Шаблон:See also

A description of apparent and mean time was given by Nevil Maskelyne in the Nautical Almanac for 1767: "Apparent Time is that deduced immediately from the Sun, whether from the Observation of his passing the Meridian, or from his observed Rising or Setting. This Time is different from that shewn by Clocks and Watches well regulated at Land, which is called equated or mean Time." He went on to say that, at sea, the apparent time found from observation of the Sun must be corrected by the equation of time, if the observer requires the mean time.[1]

The right time was originally considered to be that which was shown by a sundial. When good mechanical clocks were introduced, they agreed with sundials only near four dates each year, so the equation of time was used to "correct" their readings to obtain sundial time. Some clocks, called equation clocks, included an internal mechanism to perform this "correction". Later, as clocks became the dominant good timepieces, uncorrected clock time, i.e., "mean time", became the accepted standard. The readings of sundials, when they were used, were then, and often still are, corrected with the equation of time, used in the reverse direction from previously, to obtain clock time. Many sundials, therefore, have tables or graphs of the equation of time engraved on them to allow the user to make this correction.Шаблон:R

The equation of time was used historically to set clocks. Between the invention of accurate clocks in 1656 and the advent of commercial time distribution services around 1900, there were several common land-based ways to set clocks. A sundial was read and corrected with the table or graph of the equation of time. If a transit instrument was available, the sun's transit across the meridian (the moment the sun appears to be due south or north of the observer) was noted; the clock was then set to noon and offset by the number of minutes given by the equation of time for that date. A third method did not use the equation of time; instead, it used stellar observations to give sidereal time, exploiting the relationship between sidereal time and mean solar time.Шаблон:R

The first tables to give the equation of time in an essentially correct way were published in 1665 by Christiaan Huygens.[10] Huygens, following the tradition of Ptolemy and medieval astronomers in general, set his values for the equation of time so as to make all values positive throughout the year.[10]Шаблон:Refn

Another set of tables was published in 1672–73 by John Flamsteed, who later became the first Astronomer Royal of the new Royal Greenwich Observatory. These appear to have been the first essentially correct tables that gave today's meaning of Mean Time (previously, as noted above, the sign of the equation was always positive and it was set at zero when the apparent time of sunrise was earliest relative to the clock time of sunrise). Flamsteed adopted the convention of tabulating and naming the correction in the sense that it was to be applied to the apparent time to give mean time.[11]

The equation of time, correctly based on the two major components of the Sun's irregularity of apparent motion,Шаблон:Refn was not generally adopted until after Flamsteed's tables of 1672–73, published with the posthumous edition of the works of Jeremiah Horrocks.Шаблон:R

Robert Hooke (1635–1703), who mathematically analyzed the universal joint, was the first to note that the geometry and mathematical description of the (non-secular) equation of time and the universal joint were identical, and proposed the use of a universal joint in the construction of a "mechanical sundial".Шаблон:R

18th and early 19th centuries

The corrections in Flamsteed's tables of 1672–1673 and 1680 gave mean time computed essentially correctly and without need for further offset. But the numerical values in tables of the equation of time have somewhat changed since then, owing to three factors:

  • general improvements in accuracy that came from refinements in astronomical measurement techniques,
  • slow intrinsic changes in the equation of time, occurring as a result of small long-term changes in the Earth's obliquity and eccentricity (affecting, for instance, the distance and dates of perihelion), and
  • the inclusion of small sources of additional variation in the apparent motion of the Sun, unknown in the 17th century but discovered from the 18th century onwards, including the effects of the Moon,Шаблон:Refn Venus and Jupiter.[12]
Файл:Derby Sundial C 5810.JPG
A sundial made in 1812 by Whitehurst & Son, with a circular scale showing the equation of time correction. This is now on display in Derby Museum and Art Gallery.

From 1767 to 1833, the British Nautical Almanac and Astronomical Ephemeris tabulated the equation of time in the sense 'add or subtract (as directed) the number of minutes and seconds stated to or from the apparent time to obtain the mean time'. Times in the Almanac were in apparent solar time, because time aboard ship was most often determined by observing the Sun. This operation would be performed in the unusual case that the mean solar time of an observation was needed. In the issues since 1834, all times have been in mean solar time, because by then the time aboard ship was increasingly often determined by marine chronometers. The instructions were consequently to add or subtract (as directed) the number of minutes stated to or from the mean time to obtain the apparent time. So now addition corresponded to the equation being positive and subtraction corresponded to it being negative.

As the apparent daily movement of the Sun is one revolution per day, that is 360° every 24 hours, and the Sun itself appears as a disc of about 0.5° in the sky, simple sundials can be read to a maximum accuracy of about one minute. Since the equation of time has a range of about 33 minutes, the difference between sundial time and clock time cannot be ignored. In addition to the equation of time, one also has to apply corrections due to one's distance from the local time zone meridian and summer time, if any.

The tiny increase of the mean solar day due to the slowing down of the Earth's rotation, by about 2 ms per day per century, which currently accumulates up to about 1 second every year, is not taken into account in traditional definitions of the equation of time, as it is imperceptible at the accuracy level of sundials.

Major components of the equation

Eccentricity of the Earth's orbit

Файл:Zeitgleichung.png
Equation of time (red solid line) and its two main components plotted separately, the part due to the obliquity of the ecliptic (mauve dashed line) and the part due to the Sun's varying apparent speed along the ecliptic due to eccentricity of the Earth's orbit (dark blue dash & dot line)

The Earth revolves around the Sun. As seen from Earth, the Sun appears to revolve once around the Earth through the background stars in one year. If the Earth orbited the Sun with a constant speed, in a circular orbit in a plane perpendicular to the Earth's axis, then the Sun would culminate every day at exactly the same time, and be a perfect time keeper (except for the very small effect of the slowing rotation of the Earth). But the orbit of the Earth is an ellipse not centered on the Sun, and its speed varies between 30.287 and 29.291 km/s, according to Kepler's laws of planetary motion, and its angular speed also varies, and thus the Sun appears to move faster (relative to the background stars) at perihelion (currently around 3 January) and slower at aphelion a half year later.[13][14][15]

At these extreme points this effect varies the apparent solar day by 7.9 s/day from its mean. Consequently, the smaller daily differences on other days in speed are cumulative until these points, reflecting how the planet accelerates and decelerates compared to the mean.

As a result, the eccentricity of the Earth's orbit contributes a periodic variation which is (in the first-order approximation) a sine wave with:

  • amplitude: 7.66 minutes
  • period: one year
  • zero points: perihelion (at the beginning of January) and aphelion (beginning of July)
  • extreme values: early April (negative) and early October (positive)

This component of the EoT is represented by aforementioned factor a:

<math>a = -7.659\sin(6.240\, 040\, 77 + 0.017\, 201\, 97(365(y-2000) + d))</math>

a = -7.659 * Math.sin(6.24004077 + 0.01720197 * (365*(y-2000) + dayOfYear))

Obliquity of the ecliptic

Файл:Middaysun.gif
Sun and planets at local apparent noon (Ecliptic in red, Sun and Mercury in yellow, Venus in white, Mars in red, Jupiter in yellow with red spot, Saturn in white with rings).

Even if the Earth's orbit were circular, the perceived motion of the Sun along our celestial equator would still not be uniform.[3] This is a consequence of the tilt of the Earth's rotational axis with respect to the plane of its orbit, or equivalently, the tilt of the ecliptic (the path the Sun appears to take in the celestial sphere) with respect to the celestial equator. The projection of this motion onto our celestial equator, along which "clock time" is measured, is a maximum at the solstices, when the yearly movement of the Sun is parallel to the equator (causing amplification of perceived speed) and yields mainly a change in right ascension. It is a minimum at the equinoxes, when the Sun's apparent motion is more sloped and yields more change in declination, leaving less for the component in right ascension, which is the only component that affects the duration of the solar day. A practical illustration of obliquity is that the daily shift of the shadow cast by the Sun in a sundial even on the equator is smaller close to the solstices and greater close to the equinoxes. If this effect operated alone, then days would be up to 24 hours and 20.3 seconds long (measured solar noon to solar noon) near the solstices, and as much as 20.3 seconds shorter than 24 hours near the equinoxes.[13][16][15]

In the figure on the right, we can see the monthly variation of the apparent slope of the plane of the ecliptic at solar midday as seen from Earth. This variation is due to the apparent precession of the rotating Earth through the year, as seen from the Sun at solar midday.

In terms of the equation of time, the inclination of the ecliptic results in the contribution of a sine wave variation with:

  • amplitude: 9.87 minutes
  • period: 1/2 year
  • zero points: equinoxes and solstices
  • extreme values: beginning of February and August (negative) and beginning of May and November (positive).


This component of the EoT is represented by the aforementioned factor "b":

<math>b = 9.863\sin \left( 2 (6.240\, 040\, 77 + 0.017\, 201\, 97 (365(y-2000)+ d)) + 3.5932 \right)</math>

Secular effects

The two above mentioned factors have different wavelengths, amplitudes and phases, so their combined contribution is an irregular wave. At epoch 2000 these are the values (in minutes and seconds with UT dates):

Point Value Date
minimum −14 min 15 s 11 February
zero 0 min Шаблон:00 s 15 April
maximum +3 min 41 s 14 May
zero 0 min Шаблон:00 s 13 June
minimum −6 min 30 s 26 July
zero 0 min Шаблон:00 s 1 September
maximum +16 min 25 s 3 November
zero 0 min Шаблон:00 s 25 December

Шаблон:Citation needed

E.T. = apparent − mean. Positive means: Sun runs fast and culminates earlier, or the sundial is ahead of mean time. A slight yearly variation occurs due to presence of leap years, resetting itself every 4 years. The exact shape of the equation of time curve and the associated analemma slowly change over the centuries, due to secular variations in both eccentricity and obliquity. At this moment both are slowly decreasing, but they increase and decrease over a timescale of hundreds of thousands of years.[17]

On shorter timescales (thousands of years) the shifts in the dates of equinox and perihelion will be more important. The former is caused by precession, and shifts the equinox backwards compared to the stars. But it can be ignored in the current discussion as our Gregorian calendar is constructed in such a way as to keep the vernal equinox date at 20 March (at least at sufficient accuracy for our aim here). The shift of the perihelion is forwards, about 1.7 days every century. In 1246 the perihelion occurred on 22 December, the day of the solstice, so the two contributing waves had common zero points and the equation of time curve was symmetrical: in Astronomical Algorithms Meeus gives February and November extrema of 15 m 39 s and May and July ones of 4 m 58 s. Before then the February minimum was larger than the November maximum, and the May maximum larger than the July minimum. In fact, in years before −1900 (1901 BCE) the May maximum was larger than the November maximum. In the year −2000 (2001 BCE) the May maximum was +12 minutes and a couple seconds while the November maximum was just less than 10 minutes. The secular change is evident when one compares a current graph of the equation of time (see below) with one from 2000 years ago, e.g., one constructed from the data of Ptolemy.Шаблон:Sfn

Graphical representation

Файл:EquationofTimeandAnalemma.gif
Animation showing equation of time and analemma path over one year.

Practical use

If the gnomon (the shadow-casting object) is not an edge but a point (e.g., a hole in a plate), the shadow (or spot of light) will trace out a curve during the course of a day. If the shadow is cast on a plane surface, this curve will be a conic section (usually a hyperbola), since the circle of the Sun's motion together with the gnomon point define a cone. At the spring and autumnal equinoxes, the cone degenerates into a plane and the hyperbola into a line. With a different hyperbola for each day, hour marks can be put on each hyperbola which include any necessary corrections. Unfortunately, each hyperbola corresponds to two different days, one in each half of the year, and these two days will require different corrections. A convenient compromise is to draw the line for the "mean time" and add a curve showing the exact position of the shadow points at noon during the course of the year. This curve will take the form of a figure eight and is known as an analemma. By comparing the analemma to the mean noon line, the amount of correction to be applied generally on that day can be determined.

The equation of time is used not only in connection with sundials and similar devices, but also for many applications of solar energy. Machines such as solar trackers and heliostats have to move in ways that are influenced by the equation of time.

Civil time is the local mean time for a meridian that often passes near the center of the time zone, and may possibly be further altered by daylight saving time. When the apparent solar time that corresponds to a given civil time is to be found, the difference in longitude between the site of interest and the time zone meridian, daylight saving time, and the equation of time must all be considered.[18]

Calculating the equation of time

The equation of time is obtained from a published table, or a graph. For dates in the past such tables are produced from historical measurements, or by calculation; for future dates, of course, tables can only be calculated. In devices such as computer-controlled heliostats the computer is often programmed to calculate the equation of time. The calculation can be numerical or analytical. The former are based on numerical integration of the differential equations of motion, including all significant gravitational and relativistic effects. The results are accurate to better than 1 second and are the basis for modern almanac data. The latter are based on a solution that includes only the gravitational interaction between the Sun and Earth, simpler than but not as accurate as the former. Its accuracy can be improved by including small corrections.

The following discussion describes a reasonably accurate (agreeing with almanac data to within 3 seconds over a wide range of years) algorithm for the equation of time that is well known to astronomers.Шаблон:R It also shows how to obtain a simple approximate formula (accurate to within 1 minute over a large time interval), that can be easily evaluated with a calculator and provides the simple explanation of the phenomenon that was used previously in this article.

Mathematical description

The precise definition of the equation of time isШаблон:R

<math>\mathrm{EOT}=\mathrm{GHA}-\mathrm{GMHA}</math>

The quantities occurring in this equation are

  • EOT, the time difference between apparent solar time and mean solar time;
  • GHA, the Greenwich Hour Angle of the apparent (actual) Sun;
  • GMHA = Universal Time − Offset, the Greenwich Mean Hour Angle of the mean (fictitious) Sun.

Here time and angle are quantities that are related by factors such as: 2Шаблон:Pi radians = 360° = 1 day = 24 hours. The difference, EOT, is measurable since GHA is an angle that can be measured and Universal Time, UT, is a scale for the measurement of time. The offset by Шаблон:Pi = 180° = 12 hours from UT is needed because UT is zero at mean midnight while GMHA = 0 at mean noon.Шаблон:Refn Both GHA and GMHA, like all physical angles, have a mathematical, but not a physical discontinuity at their respective (apparent and mean) noon. Despite the mathematical discontinuities of its components, EOT is defined as a continuous function by adding (or subtracting) 24 hours in the small time interval between the discontinuities in GHA and GMHA.

According to the definitions of the angles on the celestial sphere Шаблон:Nowrap (see hour angle)
where:

  • GAST is the Greenwich apparent sidereal time (the angle between the apparent vernal equinox and the meridian in the plane of the equator). This is a known function of UT.[19]
  • Шаблон:Math is the right ascension of the apparent Sun (the angle between the apparent vernal equinox and the actual Sun in the plane of the equator).

On substituting into the equation of time, it is

<math>\mathrm{EOT} = \mathrm{GAST} - \alpha - \mathrm{UT} + \mathrm{offset}</math>

Like the formula for GHA above, one can write Шаблон:Nowrap, where the last term is the right ascension of the mean Sun. The equation is often written in these terms asШаблон:RШаблон:R

<math>\mathrm{EOT} = \alpha_M - \alpha</math>

where Шаблон:Nowrap. In this formulation a measurement or calculation of EOT at a certain value of time depends on a measurement or calculation of Шаблон:Math at that time. Both Шаблон:Math and Шаблон:Math vary from 0 to 24 hours during the course of a year. The former has a discontinuity at a time that depends on the value of UT, while the latter has its at a slightly later time. As a consequence, when calculated this way EOT has two, artificial, discontinuities. They can both be removed by subtracting 24 hours from the value of EOT in the small time interval after the discontinuity in Шаблон:Math and before the one in Шаблон:Math. The resulting EOT is a continuous function of time.

Another definition, denoted Шаблон:Math to distinguish it from EOT, is

<math>E = \mathrm{GMST} - \alpha - \mathrm{UT} + \mathrm{offset}</math>

Here Шаблон:Nowrap, is the Greenwich mean sidereal time (the angle between the mean vernal equinox and the mean Sun in the plane of the equator). Therefore, GMST is an approximation to GAST (and Шаблон:Math is an approximation to EOT); eqeq is called the equation of the equinoxes and is due to the wobbling, or nutation of the Earth's axis of rotation about its precessional motion. Since the amplitude of the nutational motion is only about 1.2 s (18″ of longitude) the difference between EOT and Шаблон:Math can be ignored unless one is interested in subsecond accuracy.

A third definition, denoted Шаблон:Math to distinguish it from EOT and Шаблон:Math, and now called the Equation of Ephemeris TimeШаблон:R (prior to the distinction that is now made between EOT, Шаблон:Math, and Шаблон:Math the latter was known as the equation of time) is

<math>\Delta t = \Lambda - \alpha</math>

here Шаблон:Math is the ecliptic longitude of the mean Sun (the angle from the mean vernal equinox to the mean Sun in the plane of the ecliptic).

The difference Шаблон:Nowrap is 1.3 s from 1960 to 2040. Therefore, over this restricted range of years Шаблон:Math is an approximation to EOT whose error is in the range 0.1 to 2.5 s depending on the longitude correction in the equation of the equinoxes; for many purposes, for example correcting a sundial, this accuracy is more than good enough.

Right ascension calculation

The right ascension, and hence the equation of time, can be calculated from Newton's two-body theory of celestial motion, in which the bodies (Earth and Sun) describe elliptical orbits about their common mass center. Using this theory, the equation of time becomes

<math>\Delta t = M + \lambda_p - \alpha</math>

where the new angles that appear are

To complete the calculation three additional angles are required:

Файл:EquationOfTimeGeom.svg
The celestial sphere and the Sun's elliptical orbit as seen by a geocentric observer looking normal to the ecliptic showing the 6 angles (Шаблон:Math) needed for the calculation of the equation of time. For the sake of clarity the drawings are not to scale.

All these angles are shown in the figure on the right, which shows the celestial sphere and the Sun's elliptical orbit seen from the Earth (the same as the Earth's orbit seen from the Sun). In this figure Шаблон:Math is the obliquity, while Шаблон:Math is the eccentricity of the ellipse.

Now given a value of Шаблон:Math, one can calculate Шаблон:Math by means of the following well-known procedure:Шаблон:R

First, given Шаблон:Math, calculate Шаблон:Math from Kepler's equation:Шаблон:R

<math>M = E - e\sin{E}</math>

Although this equation cannot be solved exactly in closed form, values of Шаблон:Math can be obtained from infinite (power or trigonometric) series, graphical, or numerical methods. Alternatively, note that for Шаблон:Math, Шаблон:Math, and by iteration:Шаблон:R

<math>E \approx M + e\sin{M}</math>

This approximation can be improved, for small Шаблон:Math, by iterating again,

<math>E \approx M + e\sin{M} + \frac{1}{2}e^2\sin{2M}</math>,

and continued iteration produces successively higher order terms of the power series expansion in Шаблон:Math. For small values of Шаблон:Math (much less than 1) two or three terms of the series give a good approximation for Шаблон:Math; the smaller Шаблон:Math, the better the approximation.

Next, knowing Шаблон:Math, calculate the true anomaly Шаблон:Math from an elliptical orbit relationШаблон:R

<math>\nu=2\arctan\left(\sqrt{\frac{1+e}{1-e}}\tan\tfrac12 E \right)</math>

The correct branch of the multiple valued function Шаблон:Math to use is the one that makes Шаблон:Math a continuous function of Шаблон:Math starting from Шаблон:Math. Thus for Шаблон:Math use Шаблон:Math, and for Шаблон:Math use Шаблон:Math. At the specific value Шаблон:Math for which the argument of Шаблон:Math is infinite, use Шаблон:Math. Here Шаблон:Math is the principal branch, Шаблон:Math; the function that is returned by calculators and computer applications. Alternatively, this function can be expressed in terms of its Taylor series in Шаблон:Math, the first three terms of which are:

<math>\nu \approx E + e\sin{E} + \frac{1}{4} e^2\sin{2E}</math>.

For small Шаблон:Math this approximation (or even just the first two terms) is a good one. Combining the approximation for Шаблон:Math with this one for Шаблон:Math produces

<math>\nu \approx M + 2e\sin{M} + \frac{5}{4} e^2\sin{2M}</math>.

The relation Шаблон:Math is called the equation of the center; the expression written here is a second-order approximation in Шаблон:Math. For the small value of Шаблон:Math that characterises the Earth's orbit this gives a very good approximation for Шаблон:Math.

Next, knowing Шаблон:Math, calculate Шаблон:Math from its definition:

<math>\lambda = \nu + \lambda_p</math>

The value of Шаблон:Math varies non-linearly with Шаблон:Math because the orbit is elliptical and not circular. From the approximation for Шаблон:Math:

<math>\lambda \approx M + \lambda_p + 2e\sin{M} + \frac{5}{4}e^2\sin{2M}</math>.

Finally, knowing Шаблон:Math calculate Шаблон:Math from a relation for the right triangle on the celestial sphere shown aboveШаблон:R

<math>\alpha = \arctan \left(\cos{\varepsilon}\tan{\lambda}\right)</math>

Note that the quadrant of Шаблон:Math is the same as that of Шаблон:Math, therefore reduce Шаблон:Math to the range 0 to 2Шаблон:Pi and write

<math>\alpha = \arctan \left( \cos{\varepsilon}\tan{\lambda} + k\pi \right)</math>,

where Шаблон:Math is 0 if Шаблон:Math is in quadrant 1, it is 1 if Шаблон:Math is in quadrants 2 or 3 and it is 2 if Шаблон:Math is in quadrant 4. For the values at which tan is infinite, Шаблон:Math.

Although approximate values for Шаблон:Math can be obtained from truncated Taylor series like those for Шаблон:Math,Шаблон:R it is more efficacious to use the equationШаблон:R

<math>\alpha = \lambda - \arcsin \left( y\sin\left( \alpha + \lambda \right) \right)</math>

where Шаблон:Math. Note that for Шаблон:Math, Шаблон:Math and iterating twice:

<math>\alpha \approx \lambda - y\sin{2\lambda} + \frac{1}{2}y^2\sin{4\lambda}</math>.

Equation of time

The equation of time is obtained by substituting the result of the right ascension calculation into an equation of time formula. Here Шаблон:Math is used; in part because small corrections (of the order of 1 second), that would justify using Шаблон:Math, are not included, and in part because the goal is to obtain a simple analytical expression. Using two-term approximations for Шаблон:Math and Шаблон:Math allows Шаблон:Math to be written as an explicit expression of two terms, which is designated Шаблон:Math because it is a first order approximation in Шаблон:Math and in Шаблон:Math.

1) <math>\Delta t_{ey} = -2e\sin{M} + y\sin \left( 2M + 2\lambda_p \right) = -7.659\sin{M} + 9.863\sin \left( 2M + 3.5932 \right)</math> minutes

This equation was first derived by Milne,Шаблон:R who wrote it in terms of Шаблон:Math. The numerical values written here result from using the orbital parameter values, Шаблон:Math = Шаблон:Val, Шаблон:Math = Шаблон:Val° = Шаблон:Val radians, and Шаблон:Math = Шаблон:Val° = Шаблон:Val radians that correspond to the epoch 1 January 2000 at 12 noon UT1. When evaluating the numerical expression for Шаблон:Math as given above, a calculator must be in radian mode to obtain correct values because the value of Шаблон:Math in the argument of the second term is written there in radians. Higher order approximations can also be written,Шаблон:R but they necessarily have more terms. For example, the second order approximation in both Шаблон:Math and Шаблон:Math consists of five termsШаблон:R

2) <math>\Delta t_{e^2y^2} = \Delta t_{ey} - \frac{5}{4}e^2\sin{2M} + 4ey\sin{M}\cos \left( 2M + 2\lambda_p \right) - \frac{1}{2}y^2\sin \left( 4M + 4\lambda_p \right)</math>

This approximation has the potential for high accuracy, however, in order to achieve it over a wide range of years, the parameters Шаблон:Math, Шаблон:Math, and Шаблон:Math must be allowed to vary with time.Шаблон:RШаблон:R This creates additional calculational complications. Other approximations have been proposed, for example, Шаблон:MathШаблон:R[20] which uses the first order equation of the center but no other approximation to determine Шаблон:Math, and Шаблон:Math[21] which uses the second order equation of the center.

The time variable, Шаблон:Math, can be written either in terms of Шаблон:Math, the number of days past perihelion, or Шаблон:Math, the number of days past a specific date and time (epoch):

3) <math>M = \frac{2\pi}{t_Y} n</math> days <math>= M_D + \frac{2\pi}{t_Y} D</math> days <math>= 6.240\, 040\, 77 + 0.017\, 201\, 97D</math>
4) <math>M = 6.240\, 040\, 77 + 0.017\, 201\, 97D</math>
Файл:EquationOfTime612.png
Curves of Шаблон:Math and Шаблон:Math along with symbols locating the daily values at noon (at 10-day intervals) obtained from the Multiyear Interactive Computer Almanac vs Шаблон:Math (day) for the year 2000

Here Шаблон:Math is the value of Шаблон:Math at the chosen date and time. For the values given here, in radians, Шаблон:Math is that measured for the actual Sun at the epoch, 1 January 2000 at 12 noon UT1, and Шаблон:Math is the number of days past that epoch. At periapsis Шаблон:Math, so solving gives Шаблон:Math = Шаблон:Val. This puts the periapsis on 4 January 2000 at 00:11:41 while the actual periapsis is, according to results from the Multiyear Interactive Computer Almanac[22] (abbreviated as MICA), on 3 January 2000 at 05:17:30. This large discrepancy happens because the difference between the orbital radius at the two locations is only 1 part in a million; in other words, radius is a very weak function of time near periapsis. As a practical matter this means that one cannot get a highly accurate result for the equation of time by using Шаблон:Math and adding the actual periapsis date for a given year. However, high accuracy can be achieved by using the formulation in terms of Шаблон:Math.

When Шаблон:Math, M is greater than 2Шаблон:Pi and one must subtract a multiple of 2Шаблон:Pi (that depends on the year) from it to bring it into the range 0 to 2Шаблон:Pi. Likewise for years prior to 2000 one must add multiples of 2Шаблон:Pi. For example, for the year 2010, Шаблон:Math varies from Шаблон:Val on 1 January at noon to Шаблон:Val on 31 December at noon; the corresponding Шаблон:Math values are Шаблон:Val and Шаблон:Val and are reduced to the range 0 to 2Шаблон:Pi by subtracting 10 and 11 times 2Шаблон:Pi respectively.

One can always write:

5) Шаблон:Math

where:

The resulting equation for years after 2000, written as a sum of two terms, given 1), 4) and 5), is:

<math>a = -7.659\sin(6.240\, 040\, 77 + 0.017\, 201\, 97(365.25(y-2000) + d))</math>

<math>b = 9.863\sin \left( 2 (6.240\, 040\, 77 + 0.017\, 201\, 97 (365.25(y-2000)+ d)) + 3.5932 \right)</math>

6) <math>\Delta t_{ey} = a + b</math> [minutes]

In plain text format:

7) EoT =  -7.659sin(6.24004077 + 0.01720197(365*(y-2000) + d)) + 9.863sin( 2 (6.24004077 + 0.01720197 (365*(y-2000) + d)) + 3.5932 ) [minutes]

Term "a" represents the contribution of eccentricty, term "b" represents contribution of obliquity.

The result of the computations is usually given as either a set of tabular values, or a graph of the equation of time as a function of Шаблон:Math. A comparison of plots of Шаблон:Math, Шаблон:Math, and results from MICA all for the year 2000 is shown in the figure. The plot of Шаблон:Math is seen to be close to the results produced by MICA, the absolute error, Шаблон:Nowrap, is less than 1 minute throughout the year; its largest value is 43.2 seconds and occurs on day 276 (3 October). The plot of Шаблон:Math is indistinguishable from the results of MICA, the largest absolute error between the two is 2.46 s on day 324 (20 November).

Remark on the continuity of the equation of time

For the choice of the appropriate branch of the Шаблон:Math relation with respect to function continuity a modified version of the arctangent function is helpful. It brings in previous knowledge about the expected value by a parameter. The modified arctangent function is defined as:

<math>\arctan_\eta x = \arctan x + \pi\operatorname{round}{\left( \frac{\eta - \arctan x}{\pi} \right)}</math>.

It produces a value that is as close to Шаблон:Math as possible. The function Шаблон:Math rounds to the nearest integer.

Applying this yields:

<math>\Delta t(M) = M + \lambda_p - \arctan_{M + \lambda_p} \left( \cos{\varepsilon}\tan{\lambda} \right)</math>.

The parameter Шаблон:Math arranges here to set Шаблон:Math to the zero nearest value which is the desired one.

Secular effects

The difference between the MICA and Шаблон:Math results was checked every 5 years over the range from 1960 to 2040. In every instance the maximum absolute error was less than 3 s; the largest difference, 2.91 s, occurred on 22 May 1965 (day 141). However, in order to achieve this level of accuracy over this range of years it is necessary to account for the secular change in the orbital parameters with time. The equations that describe this variation are:Шаблон:RШаблон:R

<math>\begin{align}

e &= 1.6709 \times 10^{-2} - 4.193 \times 10^{-5}\left(\frac{D}{36\,525}\right) - 1.26\times 10^{-7}\left(\frac{D}{36525}\right)^2 \\ \varepsilon &= 23.4393-0.013\left(\frac{D}{36\,525}\right) - 2\times 10^{-7}\left(\frac{D}{36\,525}\right)^2 + 5\times 10^{-7}\left(\frac{D}{36\,525}\right)^3\mbox{ degrees} \\ \lambda_\mathrm{p} &= 282.938\,07 + 1.7195\left(\frac{D}{36\,525}\right) + 3.025\times 10^{-4}\left(\frac{D}{36\,525}\right)^2\mbox{ degrees} \end{align}</math> According to these relations, in 100 years (Шаблон:Math = Шаблон:Val), Шаблон:Math increases by about 0.5% (1.7°), Шаблон:Math decreases by about 0.25%, and Шаблон:Math decreases by about 0.05%.

As a result, the number of calculations required for any of the higher-order approximations of the equation of time requires a computer to complete them, if one wants to achieve their inherent accuracy over a wide range of time. In this event it is no more difficult to evaluate Шаблон:Math using a computer than any of its approximations.

In all this note that Шаблон:Math as written above is easy to evaluate, even with a calculator, is accurate enough (better than 1 minute over the 80-year range) for correcting sundials, and has the nice physical explanation as the sum of two terms, one due to obliquity and the other to eccentricity that was used previously in the article. This is not true either for Шаблон:Math considered as a function of Шаблон:Math or for any of its higher-order approximations.

Alternative calculation

Another procedure for calculating the equation of time can be done as follows.[20] Angles are in degrees; the conventional order of operations applies.

Шаблон:Mvar = Шаблон:Sfrac

where Шаблон:Mvar is the Earth's mean angular orbital velocity in degrees per day, a.k.a. "the mean daily motion".

<math>A = \left( D + 9 \right) n</math>

where Шаблон:Mvar is the date, counted in days starting at 1 on 1 January (i.e. the days part of the ordinal date in the year). 9 is the approximate number of days from the December solstice to 31 December. Шаблон:Mvar is the angle the Earth would move on its orbit at its average speed from the December solstice to date Шаблон:Mvar.

<math>B = A + 0.0167\cdot\frac{360^{\circ}}{\pi}\sin \left( \left( D - 3 \right) n \right)</math>

Шаблон:Mvar is the angle the Earth moves from the solstice to date Шаблон:Mvar, including a first-order correction for the Earth's orbital eccentricity, 0.0167 . The number 3 is the approximate number of days from 31 December to the current date of the Earth's perihelion. This expression for Шаблон:Mvar can be simplified by combining constants to:

<math> B = A + 1.914^{\circ}\cdot\sin\left( \left( D - 3 \right) n \right)</math>.
<math>C=\frac{A-\arctan\frac{\tan B}{\cos 23.44^\circ}}{180^\circ}</math>

Here, Шаблон:Mvar is the difference between the angle moved at mean speed, and at the angle at the corrected speed projected onto the equatorial plane, and divided by 180° to get the difference in "half-turns". The value 23.44° is the tilt of the Earth's axis ("obliquity"). The subtraction gives the conventional sign to the equation of time. For any given value of Шаблон:Mvar, Шаблон:Math (sometimes written as Шаблон:Math) has multiple values, differing from each other by integer numbers of half turns. The value generated by a calculator or computer may not be the appropriate one for this calculation. This may cause Шаблон:Mvar to be wrong by an integer number of half-turns. The excess half-turns are removed in the next step of the calculation to give the equation of time:

<math>\mathrm{EOT} = 720\left( C - \operatorname{nint}{C} \right)</math> minutes

The expression Шаблон:Math means the nearest integer to Шаблон:Mvar. On a computer, it can be programmed, for example, as Шаблон:Nowrap. Its value is 0, 1, or 2 at different times of the year. Subtracting it leaves a small positive or negative fractional number of half turns, which is multiplied by 720, the number of minutes (12 hours) that the Earth takes to rotate one half turn relative to the Sun, to get the equation of time.

Compared with published values,[6] this calculation has a root mean square error of only 3.7 s. The greatest error is 6.0 s. This is much more accurate than the approximation described above, but not as accurate as the elaborate calculation.

Addendum about solar declination

Шаблон:Main article The value of Шаблон:Mvar in the above calculation is an accurate value for the Sun's ecliptic longitude (shifted by 90°), so the solar declination Шаблон:Mvar becomes readily available:

<math>\delta = -\arcsin\left( \sin 23.44^{\circ}\cdot\cos B \right)</math>

which is accurate to within a fraction of a degree.

See also

Notes and footnotes

Notes

Шаблон:Reflist

Footnotes

Шаблон:Reflist

References

Шаблон:Refbegin

Шаблон:Refend

External links

Шаблон:Commons category

Шаблон:Time measurement and standards

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  11. Ошибка цитирования Неверный тег <ref>; для сносок Flamsteed не указан текст
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  20. 20,0 20,1 Ошибка цитирования Неверный тег <ref>; для сносок Williams не указан текст
  21. Ошибка цитирования Неверный тег <ref>; для сносок ApproxSolCoord не указан текст
  22. Ошибка цитирования Неверный тег <ref>; для сносок MICA не указан текст