A vertical declining dial (south west) in Eyam Derbyshire England. Eyam (iːm is a small village in Derbyshire, England. The village is best known for being the "plague village" that chose to isolate itself when History The area that is now Derbyshire was first visited probably briefly by humans 200000 years ago during the Aveley Interglacial as evidenced by a Middle England is a Country which is part of the United Kingdom. Its inhabitants account for more than 83% of the total UK population whilst its mainland 53°17′03″N 1°40′29″W / 53.28420, -1.67471

A sundial is a device that measures time by the position of the Sun. The Sun (Sol is the Star at the center of the Solar System. In common designs such as the horizontal sundial, the sun casts a shadow from its style (a thin rod or a sharp, straight edge) onto a flat surface marked with lines indicating the hours of the day. A shadow is an area where direct light from a light source cannot reach due to obstruction by an object As the sun moves across the sky, the shadow-edge progressively aligns with different hour-lines on the plate. Such designs rely on the style being aligned with the axis of the Earth's rotation. Hence, if such a sundial is to tell the correct time, the style must point towards true North (not magnetic North) and the style's angle with horizontal must equal the sundial's geographical latitude. noted by the Chinese Polymath Shen Kuo in the 11th century and possibly the egyptians over 6 millenia ago The Earth's North Magnetic Pole is the wandering point on the Earth's surface at which the Earth's magnetic field points vertically downwards (i Latitude, usually denoted symbolically by the Greek letter phi ( Φ) gives the location of a place on Earth (or other planetary body north or south of the However, many sundials do not fit this description, and operate on different principles.

Introduction

Sundials can be categorized in several ways. ^[1] First, some sundials use a spot of light, or a line of light, to indicate the time, where others use the edge or tip of a shadow. In the former case, the spot of light may be formed by allowing the sun's rays through a small hole or reflecting them from a small circular mirror; a line of light may be formed by allowing the rays through a thin slit or focusing them through a cylindrical lens. A cylindrical lens is a lens which focuses light which passes through onto a line instead of onto a point as a spherical lens would In the other case, the shadow-casting object — the sundial's gnomon — may be a thin rod, or any object with a sharp tip or a straight edge. The gnomon is the part of a Sundial that casts the Shadow. Gnomon (γνώμων is an Ancient Greek word meaning "indicator" "one who Second, sundials employ many types of gnomon. The gnomon may be fixed or moved according to the season; it may be oriented vertically, horizontally, aligned with the Earth's axis, or oriented in an altogether different direction determined by mathematics. Third, sundials may use many types of surfaces to receive the spot or line of light, the shadow-tip or shadow-edge. Planes are the most common surface, but partial spheres, cylinders, cones and even more complicated shapes have been used for greater accuracy or intriguing aesthetics. "Globose" redirects here See also Globose nucleus. A sphere (from Greek σφαίρα - sphaira, "globe A cylinder is one of the most basic curvilinear geometric shapes the Surface formed by the points at a fixed distance from a given Straight line, the axis A cone is a three-dimensional Geometric shape that tapers smoothly from a flat round base to a point called the apex or vertex Fourth, sundials differ in their portability and their need of orientation. The installation of many dials requires knowing the local latitude, the precise vertical direction (e. Latitude, usually denoted symbolically by the Greek letter phi ( Φ) gives the location of a place on Earth (or other planetary body north or south of the g. , by a level or plumb-bob), and the direction to true North. noted by the Chinese Polymath Shen Kuo in the 11th century and possibly the egyptians over 6 millenia ago In contrast, other dials are self-aligning; for example, two dials that operate on different principles, such as a horizontal and analemmatic dial, may be mounted together on one plate, such that their times agree only when the plate is aligned properly. Sundials were an important aspect of the Greek and egypitan civilizations up to the 16th century.

Sundials indicate the local solar time, unless otherwise corrected. Solar times are measures of the apparent position of the Sun on the Celestial sphere. To obtain the standard clock time, three types of corrections need to be made. First, the solar time needs to be corrected for the longitude of the sundial relative to the longitude at which the official time zone is defined. Longitude (ˈlɒndʒɪˌtjuːd or ˈlɒŋgɪˌtjuːd symbolized by the Greek character Lambda (λ is the east-west Geographic coordinate measurement For example, a sundial located west of Greenwich, England but within the same time-zone, shows an earlier time than the official time; it will show "noon" after the official noon has passed, since the sun passes overhead later, since the sundial is further in the west. Greenwich ( ˈɡrɛnɪtʃ GREN-itch /ˈɡrɛnɪdʒ/ GREN-idge or /ˈɡrɪnɪdʒ/ GRIN-idge is a district in south-east London, England is a Country which is part of the United Kingdom. Its inhabitants account for more than 83% of the total UK population whilst its mainland This correction is often made by rotating the hour-lines by an angle equaling the difference in longitudes. Second, the practice of daylight saving time shifts the official time away from solar time by an hour or, in rare cases, by another amount. Daylight saving time ( DST This correction is usually made by numbering the hour-lines with two sets of numbers. Third, the orbit of the Earth is not perfectly circular and its rotational axis not perfectly perpendicular to its orbit, which together produce small variations in the sundial time throughout the year. This correction — which may be as great as 15 minutes — is described by the equation of time. The equation of time is the difference over the course of a year between time as read from a Sundial and time as read from a Clock, measured in an ideal situation A more sophisticated sundial design is required to incorporate this correction automatically; alternatively, a small plaque can be affixed to the sundial giving the offsets at various times of the year.

Apparent motion of the Sun

Top view of an equatorial sundial. The hour lines are spaced equally about the circle, and the shadow of the gnomon (a thin cylindrical rod) rotates uniformly. The height of the gnomon is 5/12 the outer radius of the dial. This animation depicts the motion of the shadow from 3 a. m. to 9 p. m. on mid-summer's day, when the sun is at its highest declination (roughly 23. 5°). Sunset and sunrise occur at 3am and 9pm, respectively, on that day at geographical latitudes near 57. 5°, roughly the latitude of Aberdeen or Gothenburg. Aberdeen ( pronounced; Aiberdeen Obar Dheathain is Scotland 's third most populous city and one of Scotland's 32 local government council Gothenburg ( Swedish:) /jœte'bɔrj/ is a city, a municipality, and an urban area on the west-coast of Sweden.

The principles of sundials can be understood most easily from an ancient model of the Sun's motion. The Sun (Sol is the Star at the center of the Solar System. Science has established that the Earth rotates on its axis, and revolves in an elliptic orbit about the Sun; however, meticulous astronomical observations and physics experiments were required to establish this. For navigational and sundial purposes, it is an excellent approximation to assume that the Sun revolves around a stationary Earth on the celestial sphere, which rotates every 23 hours and 56 minutes about its celestial axis, the line connecting the celestial poles. In Astronomy and Navigation, the celestial sphere is an imaginary rotating Sphere of "gigantic Radius " The north and south celestial poles are the two imaginary points in the sky where the Earth's Axis of rotation, "infinitely extended" intersects the Since the celestial axis is aligned with the axis about which the Earth rotates, its angle with the local horizontal equals the local geographical latitude. Latitude, usually denoted symbolically by the Greek letter phi ( Φ) gives the location of a place on Earth (or other planetary body north or south of the Unlike the fixed stars, the Sun changes its position on the celestial sphere, being at positive declination in summer, at negative declination in winter, and having exactly zero declination (i. The fixed stars (from the Latin stellae fixae) are celestial objects that do not seem to move in relation to the other stars of the night sky In Astronomy, declination (abbrev dec or δ) is one of the two coordinates of the Equatorial coordinate system, the other being either e. , being on the celestial equator) at the equinoxes. The celestial equator is a Great circle on the imaginary Celestial sphere, in the same plane as the Earth 's Equator. An equinox is the event of the Sun passing over the Earth's equator in its annual cycle The path of the Sun on the celestial sphere is known as the ecliptic, which passes through the twelve constellations of the zodiac in the course of a year. The ecliptic is the apparent path that the Sun traces out in the sky during the year Zodiac denotes an annual cycle of twelve stations along the Ecliptic, the apparent path of the sun across the heavens through the Constellations that divide the ecliptic

This model of the Sun's motion helps to understand the principles of sundials. If the shadow-casting gnomon is aligned with the celestial poles, its shadow will revolve at a constant rate, and this rotation will not change with the seasons. The north and south celestial poles are the two imaginary points in the sky where the Earth's Axis of rotation, "infinitely extended" intersects the This is perhaps the most commonly seen design and, in such cases, the same set of hour lines may be used throughout the year. The hour-lines will be spaced uniformly if the surface receiving the shadow is either perpendicular (as in the equatorial sundial) or circularly symmetric about the gnomon (as in the armillary sphere). In other cases, the hour-lines are not spaced evenly, even though the shadow is rotating uniformly. If the gnomon is not aligned with the celestial poles, even its shadow will not rotate uniformly, and the hour lines must be corrected accordingly. The rays of light that graze the tip of a gnomon, or which pass through a small hole, or which reflect from a small mirror, trace out a cone that is aligned with the celestial poles. A cone is a three-dimensional Geometric shape that tapers smoothly from a flat round base to a point called the apex or vertex The corresponding light-spot or shadow-tip, if it falls onto a flat surface, will trace out a conic section, such as a hyperbola, ellipse or (at the North or South Poles) a circle. In Mathematics, a conic section (or just conic) is a Curve obtained by intersecting a cone (more precisely a circular Conical surface In Geometry, a hyperbola ( Greek, "over-thrown" has several equivalent definitions In Mathematics, an ellipse (from the Greek ἔλλειψις literally absence) is a Conic section, the locus of points in a Circles are simple Shapes of Euclidean geometry consisting of those points in a plane which are at a constant Distance, called the This conic section is the intersection of the cone of light rays with the flat surface. This cone and its conic section change with the seasons, as the Sun's declination changes; hence, sundials that follow the motion of such light-spots or shadow-tips often have different hour-lines for different times of the year, as seen in shepherd's dials, sundial rings, and vertical gnomons such as obelisks. Alternatively, sundials may change the angle and/or position of the gnomon relative to the hour lines, as in the analemmatic dial or the Lambert dial.

Terminology

The 'shadow-maker' of the sundial is called a gnomon. ^[2] The linear feature that casts the shadow from which the time can be read is often called a style. ^[3][2] On a standard garden (horizontal) sundial, this line is the top edge of the gnomon. The style should be parallel to the Earth's axis of rotation, and point to the celestial pole.

The sun casts a shadow from the gnomon or style to a surface called the dial face or dial plate (often shortened to face).

The line on the dial plate perpendicularly beneath the style is called the substyle^[2], that is below the style. The angle the style makes perpendicularly with the dial plate is called the substyle height, an unusual use of the word height to mean an angle. On many wall dials, the substyle is not the same as the noon line. The angle, on the dial plate, the noon line makes to the substyle is called the substyle distance, an unusual use of the word distance to mean an angle.

Some sundials indicate both the time and the date by the shadow of a particular point on the gnomon. That point is called the nodus. The nodus may be the tip of a gnomon with an arbitrary (usually horizontal or vertical) orientation^[2]. A few sundials have both a style and a nodus, with the nodus in the form of a small sphere or a notch on a polar-pointing style.

In addition to the Hour line, the face of the dial can contain further information , such as the horizon, the equator and the tropics. These lines are referred to as the dial furniture.

It is traditional for a sundial to have a motto. A motto (from the Italian word motto, meaning witticism sentence is a phrase meant to formally describe the general motivation or intention of a social group The motto is usually in the form of an epigram, and often represents the sense of humor of the dial maker. ^[4]

A dial is said to be equiangular if its hour-lines are straight and spaced equally. Most equiangular sundials have a fixed gnomon style aligned with the Earth's rotational axis, as well as a shadow-receiving surface that is symmetrical about that axis; examples include the equatorial dial, the equatorial bow, the armillary sphere, the cylindrical dial and the conical dial. However, some other designs are equiangular, such as the Lambert dial.

Casting light instead of shadow

Benoy Sun Clock showing 6:00pm - 18. 00 hours

Most of the sundials described below use shadow to indicate time, whether it be the shadow-edge of the style, or the shadow-point of the nodus. However, light may be used in equivalent ways. Nodus-based sundials may use a small hole or mirror to isolate a single ray of light; the former are sometimes called aperture dials. The oldest example is perhaps the antiborean sundial (antiboreum), a spherical nodus-based sundial that faces true North; a ray of sunlight enters from the South through a small hole located at the sphere's pole and falls on the hour and date lines inscribed within the sphere, which resemble lines of longitude and latitude, respectively, on a globe. noted by the Chinese Polymath Shen Kuo in the 11th century and possibly the egyptians over 6 millenia ago ^[5]

Light may also be used to replace the shadow-edge of a gnomon. Whereas the style usually casts a sheet of shadow, an equivalent sheet of light can be created by allowing the sun's rays through a thin slit, reflecting them from a long, slim mirror (usually half-cylindrical), or focusing them through a cylindrical lens. A cylindrical lens is a lens which focuses light which passes through onto a line instead of onto a point as a spherical lens would For illustration, the Benoy Dial uses a cylindrical lens to create a sheet of light, which falls as a line on the dial surface. Benoy dials can be seen throughout Great Britain, such as^[6]

• Carnfunnock Country Park Antrim Northern Ireland
• Upton Hall British Horological Institute Newark-on-Trent Nottinghamshire UK
• Within the collections of St Edmundsbury Heritage Service Bury St Edmunds^[7] UK
• Longleat Warminster Wiltshire UK
• Jodrell Bank Science Centre and Arboretum
• Birmingham Botanical Gardens Edgbaston UK
• Science Museum UK - (inventory number 1975-318)

Any celestial body, such as a star or the Sun, appears to rotate about the celestial axis over the course of a 24-hour day. Northern Ireland (Tuaisceart Éireann Ulster Scots: Norlin Airlann) is a Country within the United Kingdom, lying in the northeast of Newark-on-Trent (generally shortened to Newark) is a Market town in Nottinghamshire in the East Midlands region of England. Nottinghamshire (abbreviated Notts) is an English county in the East Midlands, which borders South Yorkshire, Lincolnshire, Leicestershire Bury St Edmunds is a town in the county of Suffolk, England and formerly the County town of West Suffolk. Warminster is a town in western Wiltshire, England, by-passed by the A36, and near Frome and Westbury. Etymology The county formerly 'Wiltonshire' or 'Wiltunscir' (9th century is named after the former county town of Wilton (itself named after the River Wylye The Jodrell Bank Observatory (originally the Jodrell Bank Experimental Station, then the Nuffield Radio Astronomy Laboratories from 1966 to 1999 is an Observatory An arboretum is a collection of trees Related collections include a fruticetum (from the Latin frutex, meaning shrub and a viticetum a collection of vines The Birmingham Botanical Gardens are botanical gardens situated in Edgbaston, Birmingham, England. Edgbaston is an area in the city of Birmingham in England. It is also a formal district, managed by its own District committee. For science museums in general check out Science museum. The Science Museum on Exhibition Road, South Kensington, London is part A star is a massive luminous ball of plasma. The nearest star to Earth is the Sun, which is the source of most of the Energy on Earth Over the course of the year, the stars keep their position on the celestial sphere, but the Sun and planets change their positions. The Sun (Sol is the Star at the center of the Solar System. A planet, as defined by the International Astronomical Union (IAU is a celestial body Orbiting a Star or stellar remnant that is In particular, the Sun appears to move through the zodiac constellations. Zodiac denotes an annual cycle of twelve stations along the Ecliptic, the apparent path of the sun across the heavens through the Constellations that divide the ecliptic

Sundials with fixed axial gnomon

The most commonly observed sundials are those in which the shadow-casting style is fixed in position and aligned with the Earth's rotational axis, being oriented with true North and South, and making an angle with the horizontal equal to the geographical latitude. noted by the Chinese Polymath Shen Kuo in the 11th century and possibly the egyptians over 6 millenia ago Latitude, usually denoted symbolically by the Greek letter phi ( Φ) gives the location of a place on Earth (or other planetary body north or south of the This axis is aligned with the celestial poles, which is closely, but not perfectly, aligned with the (present) pole star Polaris. The north and south celestial poles are the two imaginary points in the sky where the Earth's Axis of rotation, "infinitely extended" intersects the A pole star is a visible star especially a prominent one that is approximately aligned with the Earth 's Axis of rotation; that is a star whose apparent position Polaris (α UMi / α Ursae Minoris / Alpha Ursae Minoris commonly North(ern Star or Pole Star, and sometimes Lodestar For illustration, the celestial axis points vertically at the true North Pole, where it points horizontally on the equator. The North Pole, also known as the Geographic North Pole or Terrestrial North Pole, is subject to the caveats explained below defined as the point in the northern The equator (sometimes referred to colloquially as "the Line") is the intersection of the Earth 's surface with the plane perpendicular to the At Jaipur, a famous location for sundials, the gnomons of such sundials are raised 26°55" above horizontal, since that is the local latitude. Jaipur ( Hindi: जयपुर also popularly known as the Pink City, is the capital of Rajasthan state, India.

The Jantar Mantar in Jaipur is a famous collection of sundials; photographed from the largest, 27-meter sundial, the Samrat Yantra (the Supreme Instrument). The Jantar Mantar is a collection of architectural astronomical instruments built by Maharaja - meaning King - Jai Singh II at his then new capital of Jaipur Jaipur ( Hindi: जयपुर also popularly known as the Pink City, is the capital of Rajasthan state, India. The metre or meter is a unit of Length. It is the basic unit of Length in the Metric system and in the International 26°55′29″N 75°49′29″E / 26.9247, 75.8248

On any given day, the Sun appears to rotate uniformly about this axis, at about 15° per hour, making a full circuit (360°) in 24 hours. A linear gnomon aligned with this axis will cast a sheet of shadow (a half-plane) that, falling opposite to the Sun, likewise rotates about the celestial axis at 15° per hour. The shadow is seen by falling on a receiving surface that is usually flat, but which may be spherical, cylindrical, conical or of other shapes. If the shadow falls on a surface that is symmetrical about the celestial axis (as in an armillary sphere, or an equatorial dial), the surface-shadow likewise moves uniformly; the hour-lines on the sundial are equally spaced. However, if the receiving surface is not symmetrical (as in most horizontal sundials), the surface shadow generally moves non-uniformly and the hour-lines are not equally spaced; one exception is the Lambert dial described below.

Some types of sundials are designed with a fixed gnomon that is not aligned with the celestial poles, such as a vertical obelisk. Such sundials are covered below under the section, "Nodus-based sundials".

Equatorial sundials

An equatorial sundial in the Forbidden City, Beijing. The Forbidden City was the Chinese imperial Palace from the mid- Ming Dynasty to the end of the Qing Dynasty. 39°54′57″N 116°23′25″E / 39.9157, 116.3904 The gnomon points true North and its angle with horizontal equals the local latitude. noted by the Chinese Polymath Shen Kuo in the 11th century and possibly the egyptians over 6 millenia ago Latitude, usually denoted symbolically by the Greek letter phi ( Φ) gives the location of a place on Earth (or other planetary body north or south of the Closer inspection of the full-size image reveals the "spider-web" of date rings and hour-lines.

The distinguishing characteristic of the equatorial dial (also called the equinoctial dial) is the planar surface that receives the shadow, which is exactly perpendicular to the gnomon's style. ^[8] This plane is called equatorial, because it is parallel to the equator of the Earth and of the celestial sphere. If the gnomon is fixed and aligned with the Earth's rotational axis, the sun's apparent rotation about the Earth casts a uniformly rotating sheet of shadow from the gnomon; this produces a uniformly rotating line of shadow on the equatorial plane. Since the sun rotates 360° in 24 hours, the hour-lines on an equatorial dial are all spaced 15° apart (360/24). The uniformity of their spacing makes this type of sundial easy to construct. Both sides of the equatorial dial must be marked, since the shadow will be cast from below in winter and from above in summer. Near the equinoxes in spring and autumn, the sun moves on a circle that is nearly the same as the equatorial plane; hence, no clear shadow is produced on the equatorial dial at those times of year, a drawback of the design. An equinox is the event of the Sun passing over the Earth's equator in its annual cycle

A nodus is sometimes added to equatorial sundials, which allows the sundial to tell the time of year. On any given day, the shadow of the nodus moves on a circle on the equatorial plane, and the radius of the circle measures the declination of the sun. In Astronomy, declination (abbrev dec or δ) is one of the two coordinates of the Equatorial coordinate system, the other being either The ends of the gnomon bar may be used as the nodus, or some feature along its length. An ancient variant of the equatorial sundial has only a nodus (no style) and the concentric circular hour-lines are arranged to resemble a spider-web. ^[9]

Horizontal sundial in thyme garden (Minnesota. Thyme (ˈtaɪm is a well known herb in common usage the name may refer to either the any or all members of the plant Genus Thymus, Minnesota ( Native Americans demonstrated the name to early settlers )June 17, 2007 at 12:21. Events 1462 - Vlad III the Impaler attempts to assassinate Mehmed II ( The Night Attack) forcing him to retreat Year 2007 ( MMVII) was a Common year starting on Monday of the Gregorian calendar in the 21st century. 44°51′39. 3″N, 93°36′58. 4″W

Horizontal sundials

In the horizontal sundial (also called a garden sundial), the plane that receives the shadow is aligned horizontally, rather than being perpendicular to the style as in the equatorial dial. ^[10] Hence, the line of shadow does not rotate uniformly on the dial face; rather, the hour lines are spaced according to the rule^[11]

where λ is the sundial's geographical latitude, θ is the angle between a given hour-line and the noon hour-line (which always points towards true North) on the plane, and t is the number of hours before or after noon. Latitude, usually denoted symbolically by the Greek letter phi ( Φ) gives the location of a place on Earth (or other planetary body north or south of the noted by the Chinese Polymath Shen Kuo in the 11th century and possibly the egyptians over 6 millenia ago For example, the angle θ of the 3pm hour-line would equal the arctangent of sin(λ), since tan(45°) = 1. When λ equals 90° (at the North Pole), the horizontal sundial becomes an equatorial sundial; the style points straight up (vertically), and the horizontal plane is aligned with the equatorial place; the hour-line formula becomes θ = 15° × t, as for an equatorial dial. The North Pole, also known as the Geographic North Pole or Terrestrial North Pole, is subject to the caveats explained below defined as the point in the northern However, a horizontal sundial is impractical on the Earth's equator, where λ equals 0°, the style would lie flat in the plane and cast no shadow. The equator (sometimes referred to colloquially as "the Line") is the intersection of the Earth 's surface with the plane perpendicular to the

The chief advantages of the horizontal sundial are that it is easy to read, and the sun lights the face throughout the year. All the hour-lines intersect at the point where the gnomon's style crosses the horizontal plane. Since the style is aligned with the Earth's rotational axis, the style points true North and its angle with the horizontal equals the sundial's geographical latitude λ. noted by the Chinese Polymath Shen Kuo in the 11th century and possibly the egyptians over 6 millenia ago Latitude, usually denoted symbolically by the Greek letter phi ( Φ) gives the location of a place on Earth (or other planetary body north or south of the A sundial designed for one latitude can be used in another latitude, provided that the sundial is tilted upwards or downwards by an angle equal to the difference in latitude. For example, a sundial designed for a latitude of 40° can be used at a latitude of 45°, if the sundial plane is tilted upwards by 5°, thus aligning the style with the Earth's rotational axis. ^[12]

Vertical sundials

Two vertical dials at Houghton Hall Norfolk UK 52°49′39″N 0°39′27″E / 52.827469, 0.657616. Houghton Hall is a Country house in Norfolk, England. It was built for the de facto first British Prime Minister, Sir Robert Norfolk (ˈnɔrfək is a low-lying county in East Anglia, England, United Kingdom. The United Kingdom of Great Britain and Northern Ireland, commonly known as the United Kingdom, the UK or Britain,is a Sovereign state located The left and right dials face South and East, respectively. Both styles are parallel, their angle to the horizontal equaling the latitude. The East-facing dial is a polar dial with parallel hour-lines, the dial-face being parallel to the style.

In the common vertical dial, the shadow-receiving plane is aligned vertically; as usual, the gnomon's style is aligned with the Earth's axis of rotation. ^[13] As in the horizontal dial, the line of shadow does not move uniformly on the face; the sundial is not equiangular. If the face of the vertical dial points directly south, the angle of the hour-lines is instead described by the formula^[14]

where λ is the sundial's geographical latitude, θ is the angle between a given hour-line and the noon hour-line (which always points due north) on the plane, and t is the number of hours before or after noon. Latitude, usually denoted symbolically by the Greek letter phi ( Φ) gives the location of a place on Earth (or other planetary body north or south of the For example, the angle θ of the 3pm hour-line would equal the arctangent of cos(λ), since tan(45°) = 1. Interestingly, the shadow moves counter-clockwise on a South-facing vertical dial, whereas it runs clockwise on horizontal and equatorial dials.

An East-facing polar dial in Doubs, France 47°30′N 6°48′E / 47.50, 6.80. This article is about the country For a topic outline on this subject see List of basic France topics. It receives no afternoon sunlight; the hour-lines near noon are spaced widely, as the sun's rays become parallel to the dial's face.

Dials that face due South, North, East or West are called vertical direct dials. ^[15] If the face of a vertical dial does not face due South, the hours of sunlight that the dial receives may be limited. For example, a vertical dial that faces due East will tell time only in the morning hours; in the afternoon, the sun does not shine on its face. Vertical dials that face due East or West are polar dials, which will be described below. Vertical dials that face North are rarely used, since they tell time only before 6am or after 6pm, by local solar time. For non-direct vertical dials — those that face in non-cardinal directions — the mathematics of arranging the hour-lines becomes more complicated, and is often done by observation; such dials are said to be declining dials. ^[16]

Vertical dials are commonly mounted on the walls of buildings, such as town-halls, cupolas and church-towers, where they are easy to see from far away. In Architecture, a cupola or lantern is a radially symmetrical ornamental structure (often dome-shaped or quadrilateral located on top of a larger In some cases, vertical dials are placed on all four sides of a rectangular tower, providing the time throughout the day. The face may be painted on the wall, or displayed in inlaid stone; the gnomon is often a single metal bar, or a tripod of metal bars for rigidity. If the wall of the building does not face in a cardinal direction such as due South, the hour lines must be corrected. Since the gnomon's style is aligned with the Earth's rotation axis, it points true North and its angle with the horizontal equals the sundial's geographical latitude; consequently, its angle with the vertical face of the dial equals the colatitude, or 90°-latitude. noted by the Chinese Polymath Shen Kuo in the 11th century and possibly the egyptians over 6 millenia ago Latitude, usually denoted symbolically by the Greek letter phi ( Φ) gives the location of a place on Earth (or other planetary body north or south of the In Spherical coordinates, colatitude is the Complementary angle of the Latitude, i

Polar dials

In polar dials, the shadow-receiving plane is aligned parallel to the gnomon-style. ^[17] Thus, the shadow slides sideways over the surface, moving perpendicularly to itself as the sun rotates about the style. As with the gnomon, the hour-lines are all aligned with the Earth's rotational axis. When the sun's rays are nearly parallel to the plane, the shadow moves very quickly and the hour lines are spaced far apart. The direct East- and West-facing dials are examples of a polar dial. However, the face of a polar dial need not be vertical; it need only be parallel to the gnomon. Thus, a plane inclined at the angle of latitude (relative to horizontal) under the similarly inclined gnomon will be a polar dial. The perpendicular spacing X of the hour-lines in the plane is described by the formula

where H is the height of the style above the plane, and t is the time (in hours) before or after the center-time for the polar dial. The center time is the time when the style's shadow falls directly down on the plane; for an East-facing dial, the center time will be 6am, for a West-facing dial, this will be 6pm, and for the inclined dial described above, it will be noon. When t approaches ±6 hours away from the center time, the spacing X diverges to infinity; this occurs when the sun's rays become parallel to the plane. Infinity (symbolically represented with ∞) comes from the Latin infinitas or "unboundedness

Vertical declining dials

Effect of declining on a sundial's hour-lines. A vertical dial, at a latitude of 51° N, designed to face due South (far left) shows all the hours from 6am to 6pm, and has converging hour-lines symmetrical about the noon hour-line. By contrast, a West-facing dial (far right) is polar, with parallel hour lines, and shows only hours after noon. At the intermediate orientations of South-Southwest, Southwest, and West-Southwest, the hour lines are asymmetrical about noon, with the morning hour-lines ever more widely spaced.

A declining dial is any non-horizontal, planar dial that does not face in a cardinal direction, such as (true) North, South, East or West. This is about the direction for other uses see North (disambiguation. South is one of Cardinal directions and is opposite to the North. The Experimental Advanced Superconducting Tokamak (EAST internal designation HT-7U is an experimental Superconducting Tokamak Magnetic fusion energy This article refers to the cardinal direction for other uses see West (disambiguation. ^[18] As usual, the gnomon's style is aligned with the Earth's rotational axis, but the hour-lines are not symmetrical about the noon hour-line. For a vertical dial, the angle θ between the noon hour-line and another hour-line is given by the formula^[19]

where λ is the sundial's geographical latitude, t is the time before or after noon, and η is the angle of declination from true South. Latitude, usually denoted symbolically by the Greek letter phi ( Φ) gives the location of a place on Earth (or other planetary body north or south of the South is one of Cardinal directions and is opposite to the North. When such a dial faces South (η=0°), this formula reduces to the formula given above, tan θ = cos λ tan(15° × t).

When a sundial is not aligned with a cardinal direction, the substyle of its gnomon is not aligned with the noon hour-line. The angle β between the substyle and the noon hour-line is given by the formula^[20]

tanβ = sinηcotλ

If a vertical sundial faces true South or North (η=0° or 180°, respectively), the correction β=0° and the substyle is aligned with the noon hour-line.

Reclining dials

The sundials described above have gnomons that are aligned with the Earth's rotational axis and cast their shadow onto a plane. If the plane is neither vertical nor horizontal nor equatorial, the sundial is said to be reclining or inclining. ^[21] Such a sundial might be located on a South-facing roof, for example. The hour-lines for such a sundial can be calculated by slightly correcting the horizontal formula above^[22]

where χ is the desired angle of reclining, λ is the sundial's geographical latitude, θ is the angle between a given hour-line and the noon hour-line (which always points due north) on the plane, and t is the number of hours before or after noon. Latitude, usually denoted symbolically by the Greek letter phi ( Φ) gives the location of a place on Earth (or other planetary body north or south of the For example, the angle θ of the 3pm hour-line would equal the arctangent of sin(λ+χ), since tan(45°) = 1. When χ equals 90° (in other words, a South-facing vertical dial), we obtain the vertical formula above, since sin(λ+90°) = cos(λ).

Some authors use a more specific nomenclature to describe the orientation of the shadow-receiving plane. If the plane's face points downwards towards the ground, it is said to be proclining or inclining, whereas a dial is said to be reclining when the dial face is pointing away from the ground.

Reclining-declining dials

Some sundials both decline and recline, in that their shadow-receiving plane is not oriented with a cardinal direction (such as true North) and is neither horizontal nor vertical nor equatorial. noted by the Chinese Polymath Shen Kuo in the 11th century and possibly the egyptians over 6 millenia ago For example, such a sundial might be found on a roof that was not oriented in a cardinal direction. The formulae describing the spacing of the hour-lines on such dials are rather complicated. ^[23] The angle θ between the noon hour-line and another hour-line has two components θ = θ₁ + θ₂, described by the formulae^[24]

tanθ₁ = tanηtanχ

where λ is the sundial's geographical latitude, t is the time before or after noon, and χ and η are the angles of inclination and declination, respectively. Latitude, usually denoted symbolically by the Greek letter phi ( Φ) gives the location of a place on Earth (or other planetary body north or south of the

As in the simpler declining dial, the gnomon-substyle is not aligned with the noon hour-line. ^[25] The general formula for the angle β between the substyle and the noon-line is given by^[26]

Spherical sundials

Equatorial bow sundial in Hasselt 50°55′47″N, 5°20′31″E,Belgium. ||-||-||} Hasselt is a Belgian City and municipality, and capital of the Flemish province of Limburg. The rays pass through the narrow slot, forming a uniformly rotating sheet of light that falls on the circular bow. The hour-lines are equally spaced; in this image, the local solar time is roughly 15:00 hours (3 pm). On September 10, a small ball, welded into the slot casts a shadow on centre of the hour band.

The surface receiving the shadow need not be a plane, but can can have any shape, provided that the sundial maker is willing to mark the hour-lines. If the style is aligned with the Earth's rotational axis, a spherical shape is convenient since the hour-lines are equally spaced, as they are on the equatorial dial above; the sundial is equiangular. This is the principle behind the armillary sphere and the equatorial bow sundial. ^[27] However, some equiangular sundials — such as the Lambert dial described below — are based on other principles.

In the equatorial bow sundial, the gnomon is a bar, slot or stretched wire parallel to the celestial axis. The face is a semicircle (corresponding to the equator of the sphere, with markings on the inner surface. This pattern, built a couple of meters wide out of temperature-invariant steel invar, was used to keep the trains running on time in France before World War I. Invar®, also known generically as FeNi36 ( 64FeNi in the US is a Nickel Steel Alloy notable for its uniquely low Coefficient ^[28]

Among the most precise sundials ever made are two equatorial bows constructed of marble found in Yantra mandir. Marble is a nonfoliated Metamorphic rock resulting from the Metamorphism of Limestone, composed mostly of Calcite (a crystalline form of The Jantar Mantar is a collection of architectural astronomical instruments built by Maharaja - meaning King - Jai Singh II at his then new capital of Jaipur ^[29] This collection of sundials and other astronomical instruments was built by Maharaja Jai Singh II at his then-new capital of Jaipur, India between 1727 and 1733. The situation on his accession When Jai Singh sat on the ancestral throne at Amber he had barely enough resources to pay for the support of 1000 cavalry—this abysmal situation Jaipur ( Hindi: जयपुर also popularly known as the Pink City, is the capital of Rajasthan state, India. The larger equatorial bow is called the Samrat Yantra (The Supreme Instrument); standing at 27 meters, its shadow moves visibly at 1 mm per second, or roughly a hand's breadth (6 cm) every minute. The metre or meter is a unit of Length. It is the basic unit of Length in the Metric system and in the International

Cylindrical dial with central style. 41°38′26″N, 2°21′34″E Cardedeu, Spain. Cardedeu is a village near Barcelona in Catalonia, Spain. It's near Granollers the capital of Vallès Oriental.

Cylindrical, conical, and other non-planar sundials

Other non-planar surfaces may be used to receive the shadow of the gnomon. For example, the gnomon may be aligned with the celestial poles and located also along the symmetry axis of a cone or a cylinder. Due to the symmetry, the hour lines on such surfaces will be equally spaced, as on an equatorial dial or an armillary sphere. The conical dial is very old, and was the basis for one type of chalice sundial; the style was a vertical pin within a conical goblet, within which were inscribed the hour lines.

As an elegant alternative, the gnomon may be located on the circumference of a cylinder or sphere, rather than at its center of symmetry. In that case, the hour lines are again spaced equally, but at double the usual angle, due to the geometrical inscribed angle theorem. In Geometry, an inscribed angle is formed when two Secant lines of a Circle (or in a Degenerate case, when one Secant line and This is the basis of some modern sundials, but it was also used in ancient times; in one type, the edges of a half-cylindrical gnomon served as the styles. ^[30]

Just as the armillary sphere is largely open for easy viewing of the dial, such non-planar surfaces need not be complete. For example, a cylindrical dial could be rendered as a helical ribbon-like surface, with a thin gnomon located either along its center or at its periphery.

Adjustments to calculate clock time from a sundial reading

The most common reason for a sundial to differ from clock time is that the sundial has not been oriented correctly or its hour lines have not been drawn correctly. For example, most commercial sundials are designed as horizontal sundials as described above. To be accurate such sundials must have been designed for that latitude and their style must be parallel to the Earth's rotational axis; the style must be aligned with true North and its angle with the horizontal must equal the local geographical latitude. noted by the Chinese Polymath Shen Kuo in the 11th century and possibly the egyptians over 6 millenia ago Latitude, usually denoted symbolically by the Greek letter phi ( Φ) gives the location of a place on Earth (or other planetary body north or south of the To align the style, the sundial can sometimes be tilted slightly on its north south axis.

Summer (daylight saving) time correction

Some areas of the world practice daylight saving time, which shifts the official time, usually by one hour. Daylight saving time ( DST This shift must be added to the sundial's time to make it agree with the official time.

Time-zone (longitude) correction

A time zone can cover 60° of longitude, so any point within that zone will experience time difference with the reference longitude, equivalent to 4 minutes of time per degree. For illustration, sunsets and sunrises occur at a later "official" time in the far western edge of a time-zone, compared to those observed at the far eastern edge. As an example, if a sundial is located at a longitude 5° west of the reference longitude, its time will read 20 minutes slow, since the sun appears to revolve around the Earth at 15° per hour. This is a constant correction throughout the year. For equiangular dials such as the equatorial, spherical or Lambert dials, this correction can be made by rotating the dial surface by an angle equalling the difference in longitude, without changing the gnomon position or orientation. However, this method does not work for other dials, such as a horizontal dial; the correction must be applied by the viewer.

Equation of time correction

The Equation of Time - above the axis the dial will appear fast, and below the dial will appear slow.

Although the Sun appears to rotate nearly uniformly about the Earth, it is not perfectly uniform, due to the ellipticity of the Earth's orbit (the fact that the Earth's orbit about the Sun is not perfectly circular) and the tilt (obliquity) of the Earth's rotational axis relative to the plane of its orbit. Therefore, sundials time varies from standard clock time. On four days of the year, the correction is effectively zero, but on others, it can be as much as a quarter-hour early or late. The amount of correction is described by the equation of time. The equation of time is the difference over the course of a year between time as read from a Sundial and time as read from a Clock, measured in an ideal situation This correction is universal; it does not depend on the local latitude of the sundial.

In some sundials, the equation of time correction is provided as a plaque affixed to the sundial. In more sophisticated sundials, however, the equation can be incorporated automatically. For example, some equatorial bow sundials are supplied with a small wheel that sets the time of year; this wheel in turn rotates the equatorial bow, offsetting its time measurement. In other cases, the hour lines may be curved, or the equatorial bow may be shaped like a vase, which exploits the changing altitude of the sun over the year to effect the proper offset in time. ^[31] A heliochronometer is a precision sundial that corrects apparent solar time to mean solar time or another standard time. Solar times are measures of the apparent position of the Sun on the Celestial sphere. Solar times are measures of the apparent position of the Sun on the Celestial sphere. Standard time is the result of synchronizing clocks in different geographical locations within a Time zone to the same time rather than using the local meridian as Heliochronometers usually indicate the minutes to within 1 minute of Universal Time. See this discussion of the limits of Sundial Accuracy.

An analemma may be added to many types of sundials to correct apparent solar time to mean solar time or another standard time. Solar times are measures of the apparent position of the Sun on the Celestial sphere. Standard time is the result of synchronizing clocks in different geographical locations within a Time zone to the same time rather than using the local meridian as These usually have hour lines shaped like "figure eights" (analemmas) according to the equation of time. Analemma was also a book by Ptolemy. In Astronomy, an analemma ( IPA: /ˌænəˈlɛmə/ Latin for the pedestal of a The equation of time is the difference over the course of a year between time as read from a Sundial and time as read from a Clock, measured in an ideal situation This compensates for the slight eccentricity in the Earth's orbit that causes up to a 15 minute variation from mean solar time. This is a type of dial furniture seen on more complicated horizontal and vertical dials.

Movable-gnomon sundials

In addition to the sundials have a gnomon that is designed to be moved over the course of the year. In other words, the position of the gnomon relative to the center of the hour lines can vary. The advantage of such dials is that the gnomon need not be aligned with the celestial poles and may even be perfectly vertical (the analemmatic dial). A second advantage is that such dials, when combined with a fixed-gnomon sundial, allow the user to determine true North with no other aid; the two sundials are correctly aligned if and only if the time on the two sundials agrees. noted by the Chinese Polymath Shen Kuo in the 11th century and possibly the egyptians over 6 millenia ago This is a useful property for portable sundials.

Universal ring dial. The dial is suspended from the cord shown in the upper left; the suspension point on the vertical meridian ring can be changed to match the local latitude. The center bar is twisted until a sunray passes through the small hole and falls on the horizontal equatorial ring.

Universal equinoctial ring dial

A universal equinoctial ring dial (sometimes called a ring dial for brevity, although the term is ambiguous) is a portable version of an armillary sundial,^[32] or was inspired by the mariner's astrolabe. The mariner's astrolabe, also called sea astrolabe, is not an Astrolabe proper but rather a graduated circle with an Alidade used to measure ^[33] It was likely invented by William Oughtred around 1600 and became common throughout Europe. William Oughtred ( March 5, 1575 – June 30, 1660) was an English Mathematician. ^[34]

In its simplest form, the style is a thin slit that allows the sun's rays to fall on the hour-lines of a equatorial ring. As usual, the style is aligned with the Earth's axis; to do this, the user may orient the dial towards true North and suspend the ring dial vertically from the appropriate point on the meridian ring. noted by the Chinese Polymath Shen Kuo in the 11th century and possibly the egyptians over 6 millenia ago Such dials may be made self-aligning with the addition of a more complicated central bar, instead of a simple slit-style. This bar could pivot about its end points and held a perforated slider that was positioned to the month and day according to a scale scribed on the bar. The time was determined by rotating the bar towards the sun so that the light shining through the hole fell on the equatorial ring. This forced the user to rotate the instrument, which had the effect of aligning the instrument's vertical ring with the meridian.

When not in use, the equatorial and meridian rings can be folded together into a small disk.

In 1610, Edward Wright created the sea ring, which mounted a universal ring dial over a magnetic compass. Edward Wright ( baptised 8 October 1561 died November 1615 was an English Mathematician and Cartographer noted for his book Certaine Errors This permitted mariners to determine the time and magnetic variation in a single step. ^[35]

Analemmatic sundials

Analemmatic sundial

A typical analemmatic sundial, also known as a 'Human Sundial'. The person acts as the gnomon, standing in the proper position for the month. This sundial has a second, inner dial to show the daylight saving time. Daylight saving time ( DST

An analemmatic sundial uses a vertical gnomon and its hour lines are the vertical projection of the hour lines of a circular equatorial sundial onto a flat plane. ^[36] Therefore, the analemmatic sundial is an ellipse, where the short axis is aligned North-South and the long axis is aligned East-West. In Mathematics, an ellipse (from the Greek ἔλλειψις literally absence) is a Conic section, the locus of points in a The noon hour line points true North, where as the hour lines for 6am and 6pm point due West and East, respectively; the ratio of the short to long axes equals the sine sin(λ) of the local geographical latitude, denoted λ. Latitude, usually denoted symbolically by the Greek letter phi ( Φ) gives the location of a place on Earth (or other planetary body north or south of the All the hour lines converge to a single center; the angle θ of a given hour line with the noon hour is given by the formula^[37]

where t is the time (in hours) before or after noon. However, the vertical gnomon does not always stand at the center of the hour lines; rather, to show the correct time, the gnomon must be moved northwards from the center by the distance^[38]

Y = Wcos(λ)tan(δ)

where W is the width of the ellipse and δ is the Sun's declination at that time of year. In Astronomy, declination (abbrev dec or δ) is one of the two coordinates of the Equatorial coordinate system, the other being either The declination measures how far the sun is above the celestial equator; at the equinoxes, δ=0 whereas it equals roughly ±23. The celestial equator is a Great circle on the imaginary Celestial sphere, in the same plane as the Earth 's Equator. An equinox is the event of the Sun passing over the Earth's equator in its annual cycle 5° at the summer and winter solstices. Solstices occur twice a year when the tilt of the Earth's axis is most oriented toward or away from the Sun, causing the Sun to reach its northernmost and southernmost extremes

Accurate dials of this type fit nicely in a public square, using a ball at the tip of a flagpole as the nodus, with the face painted on or inlaid in the pavement. A less accurate version of the sundial is to lay out the hour marks on concrete, and then let the user stand in a square marked with the month. In middle latitudes, the ellipse with the hour-marks should be about six meters wide, so the shadow of the head of the beholder will fall near it most of the time. ^[39] The month squares are arranged to correct the sundial for the time of year. The user's head then forms the gnomon of the dial. If the sundial is molded into the concrete, it resists vandalism and is engaging and reasonably accurate. ^[40]

Lambert dials

The Lambert dial is another movable-gnomon sundial. ^[41] In contrast to the elliptical analemmatic dial, the Lambert dial is circular with evenly spaced hour lines, making it an equiangular sundial, similar to the equatorial, spherical, cylindrical and conical dials described above. The gnomon of a Lambert dial is neither vertical or aligned with the Earth's rotational axis; rather, it is tilted northwards by an angle α = 45° - (λ/2), where λ is the geographical latitude. Latitude, usually denoted symbolically by the Greek letter phi ( Φ) gives the location of a place on Earth (or other planetary body north or south of the Thus, a Lambert dial located at latitude 40° would have a gnomon tilted away from vertical by 25° in a northerly direction. To read the correct time, the gnomon must also be moved northwards by a distance

Y = Rtan(α)tan(δ)

where R is the radius of the Lambert dial and δ again indicates the Sun's declination for that time of year.

Altitude-based sundials

Altitude dials measure the height of the sun in the sky, rather than its rotation about the celestial axis. They are not oriented towards true North, but rather towards the sun and generally held vertically. noted by the Chinese Polymath Shen Kuo in the 11th century and possibly the egyptians over 6 millenia ago The sun's elevation is indicted by the position of a nodus, either the shadow-tip of a gnomon, or a spot of light. The time is read from where the nodus falls on a set of hour-curves that vary with the time of year. Since the sun's altitude is the same at times equally spaced about noon (e. g. , 9am and 3pm), the user had to know whether it were morning or afternoon. Many of these dials are portable and simple to use, although they are not well-suited for travelers, since their hour-curves are specific for a given latitude. Latitude, usually denoted symbolically by the Greek letter phi ( Φ) gives the location of a place on Earth (or other planetary body north or south of the

Human shadows

The length of a human shadow (or of any vertical object) can be used to measure the sun's elevation and, thence, the time. ^[42] The Venerable Bede gave a table for estimating the time from the length of one's shadow in feet, on the assumption that a monk's height is six times the length of his foot. Bede (ˈbiːd (also Saint Bede, the Venerable Bede, or (from Latin Beda (beda (c Such shadow lengths will vary with the geographical latitude and with the time of year. Latitude, usually denoted symbolically by the Greek letter phi ( Φ) gives the location of a place on Earth (or other planetary body north or south of the For example, the shadow length at noon is short in summer months, and long in winter months.

Chaucer evokes this method a few times in his Canterbury Tales, as in his Parson's Tale

An equivalent type of sundial using a vertical rod of fixed length is known as a backstaff dial. The backstaff or back-quadrant, is a navigational instrument that was used to measure the altitude of a celestial body in particular the sun or moon

Shepherd dials

A shepherd's dial consists of curved hour-lines drawn on a cylinder. The horizontal pointer is placed over the date and pointed at the sun to determine the time.

A shepherd's dial — also known as a pillar dial, a cylinder dial or chilindre — is a portable cylindrical sundial with a gnomon that juts out perpendicularly. ^[43] When held vertically and pointed at the Sun, it measures the altitude of the Sun, from which the hour can be calculated if the day is known. The hour curves are inscribed on the cylinder for reading the time. Shepherd's dials are sometimes hollow, so that the gnomon can be stored within when not in use.

Shepherd's dials appear in several works of literature. For example, in the Chaucer's Canterbury Tales, the monk says,

Similarly, the shepherd's dial is evoked in Shakespeare's Henry VI, Part 3,

The cylindrical shepherd's dial can be unrolled into a flat plate. In one simple version,^[44] the front and back of the plate each have three columns, corresponding to pairs of months with roughly the same solar declination (June-July, May-August, April-September, March-October, February-November, and January-December). The top of each column has a hole for inserting the shadow-casting gnomon, a peg. Only two times are marked on the column below, one for noon and the other for mid-morning/mid-afternoon.

Ring dials

In a ring dial (also known as an Aquitaine or a perforated ring dial), the ring is hung vertically and oriented sideways towards the sun. ^[45] A beam of light passes through a small hole in the ring and falls on hour-curves that are inscribed on the inside of the ring.

Card dials (Capuchin dials)

Card dials are another form of altitude dial. ^[46] A card is aligned edge-on with the sun and tilted so that a ray of light passes through an aperture onto a specified spot, thus determining the sun's altitude. A weighted string hangs vertically downwards from a hole in the card, and carries a bead or knot. The position of the bead on the hour-lines of the card gives the time. In more sophisticated versions such as the Capuchin dial, there is only one set of hour-lines, i. e. , the hour lines do not vary with the seasons. Instead, the position of the hole from which the weighted string hangs is varied according to the season.

Nodus-based sundials

Kraków. 50°03′41″N 19°56′24″E / 50.0614, 19.9400 The shadow of the cross-shaped nodus moves along a hyperbola which shows the time of the year,indicated here by the zodiac figures. In Geometry, a hyperbola ( Greek, "over-thrown" has several equivalent definitions It is 1:50pm on the 16th July, 25 days after the summer solstice. Solstices occur twice a year when the tilt of the Earth's axis is most oriented toward or away from the Sun, causing the Sun to reach its northernmost and southernmost extremes

Another type of sundial follows the motion of a single point of light or shadow, which may be called the nodus. For example, the sundial may follow the sharp tip of a gnomon's shadow, e. g. , the shadow-tip of a vertical obelisk (e. An obelisk (from Greek ὀβελίσκος - obeliskos, diminutive of ὀβελός - obelos, "spit nail pointed pillar" g. , the Solarium Augusti) or the tip of the horizontal marker in a shepherd's dial. The Solarium Augusti, the largest Sundial the ancient world has known was Alternatively, sunlight may be allowed to pass through a small hole or reflected from a small (e. g. , coin-sized) circular mirror, forming a small spot of light whose position may be followed. In such cases, the rays of light trace out a cone over the course of a day; when the rays fall on a surface, the path followed is the intersection of the cone with that surface. A cone is a three-dimensional Geometric shape that tapers smoothly from a flat round base to a point called the apex or vertex Most commonly, the receiving surface is a geometrical plane, so that the path of the shadow-tip or light-spot traces out a conic section such as a hyperbola or an ellipse. In Mathematics, a conic section (or just conic) is a Curve obtained by intersecting a cone (more precisely a circular Conical surface In Geometry, a hyperbola ( Greek, "over-thrown" has several equivalent definitions In Mathematics, an ellipse (from the Greek ἔλλειψις literally absence) is a Conic section, the locus of points in a The collection of hyperbolae was called a pelekonon (axe) by the Greeks, because it resembles a double-bladed ax, narrow in the center (near the noonline) and flaring out at the ends (early morning and late evening hours).

Reflection sundials

Isaac Newton developed a convenient and inexpensive sundial, in which a small mirror is placed on the sill of a south-facing window. Sir Isaac Newton, FRS (ˈnjuːtən 4 January 1643 31 March 1727) Biography Early years See also Isaac Newton's early life and achievements ^[47] The mirror acts like a nodus, casting a single spot of light on the ceiling. Depending on the geographical latitude and time of year, the light-spot follows a conic section, such as the hyperbolae of the pelikonon. Latitude, usually denoted symbolically by the Greek letter phi ( Φ) gives the location of a place on Earth (or other planetary body north or south of the Using the ceiling as a sundial surface has several advantages; it exploits unused space and may be very accurate, if large.

Multiple dials

Sundials are sometimes combined into multiple dials. If two or more dials that operate on different principles — say, such as an analemmatic dial and a horizontal or vertical dial — are combined, the resulting multiple dial becomes self-aligning. In other words, the direction of true North need not be determined; the dials are oriented correctly when they read the same time. noted by the Chinese Polymath Shen Kuo in the 11th century and possibly the egyptians over 6 millenia ago This is a significant advantage in portable dials. However, the most common forms combine dials based on the same principle, and thus are not self-aligning.

Several sundials arrayed on the faces of a cube. The styles are all parallel and meant to be aligned with the Earth's rotation axis. Such an array of sundials is not self-aligning, however.

Diptych (tablet) sundial

Diptych sundial in the form of a mandolin, circa 1612. A mandolin is a musical instrument in the Lute family (plucked or strummed The gnomon-style is a string stretched between a horizontal and vertical face. This sundial also has a small nodus (a bead on the string) that tells time on the hyperbolic pelikinon, just above the date on the vertical face.

The diptych consisted of two small flat faces, joined by a hinge. A diptych (pronounced "dip-tick" dip'tik (or US: 'dɪp ^[48] Diptychs usually folded into little flat boxes suitable for a pocket. The gnomon was a string between the two faces. When the string was tight, the two faces formed both a vertical and horizontal sundial. These were made of white ivory, inlaid with black lacquer markings. The gnomons were black braided silk, linen or hemp string. With a knot or bead on the string as a nodus, and the correct markings, a diptych (really any sundial large enough) can keep a calendar well-enough to plant crops. A common error describes the diptych dial as self-aligning. This is not correct for diptych dials consisting of a horizontal and vertical dial using a string gnomon between faces, no matter the orientation of the dial faces. Since the string gnomon is continuous, the shadows must meet at the hinge; hence, any orientation of the dial will show the same time on both dials. ^[49]

Multiface (Facet-headed) dials

A common multiple dial is to place sundials on every face of a Platonic solid, usually a cube. In Geometry, a Platonic solid is a convex Regular polyhedron. A cube is a three-dimensional solid object bounded by six square faces facets or sides with three meeting at each vertex. ^[50] Extremely ornate sundials can be composed in this way, by applying a sundial to every surface of a solid object. In some cases, the sundials are formed as hollows in a solid object, e. g. , a cylindrical hollow aligned with the Earth's rotational axis (in which the edges play the role of styles) or a spherical hollow in the ancient tradition of the hemisphaerium or the antiboreum. (See the History section below. ) In some cases, these multiface dials are small enough to sit on a desk, whereas in others, they are large stone monuments.

Such multiface dials have the advantage of receiving light (and, thus, telling time) at every hour of the day. They can also be designed to give the time in different time-zones simultaneously. However, they are generally not self-aligning, since their various dials generally use the same principle to tell time, that of a gnomon-style aligned with the Earth's axis of rotation. Self-aligning dials require that at least two independent principles are used to tell time, e. g. , a horizontal dial (in which the style is aligned with the Earth's axis) and an analemmatic dial (in which the style is not). In many cases, the multiface dials are erected never to be moved and, thus, need be aligned only once.

Prismatic dials

Prismatic dials are a special case of polar dials, in which the sharp edges of a prism of a concave polygon serve as the styles and the sides of the prism receive the shadow. General right and uniform prisms A right prism is a prism in which the joining edges and faces are perpendicular to the base faces In Geometry a polygon (ˈpɒlɨɡɒn ˈpɒliɡɒn is traditionally a plane figure that is bounded by a closed path or circuit ^[51] Examples include a three-dimensional cross or star of David on gravestones.

Unusual sundials

A digital sundial found in the Sundial Park of Genk in Flanders, Belgium. Genk is a City and municipality located in the Belgian province of Limburg near Hasselt. Flanders (Vlaanderen Flandre Flandern is a geographical region located in parts of present day Belgium, France, and the Netherlands. The Kingdom of Belgium is a Country in northwest Europe. It is a founding member of the European Union and hosts its headquarters as well as those 50°33′44″N 4°41′51″E / 50.5622, 4.6975 The sun's rays are filtered by a carefully designed set of screens to produce different digits over the course of the day. The golden style points towards true North and the style's angle with horizontal equals the sundial's geographical latitude.

Bifilar sundial

Discovered by the German mathematician Hugo Michnik, the bifilar sundial has two non-intersecting threads parallel to the dial. Usually the second thread is orthogonal to the first. ^[52][53]

The intersection of the two threads' shadows gives the solar time.

Digital sundial

Main article: Digital sundial

A digital sundial uses light and shadow to 'write' the time in numerals rather than marking time with position. A digital sundial is a clock that indicates the current time with numerals formed by the sunlight striking it A digital sundial is a clock that indicates the current time with numerals formed by the sunlight striking it One such design uses two parallel masks to screen sunlight into patterns appropriate for the time of day.

Analog calculating sundial

A horizontal sundial with a face cut on a cardioid keeps clock time, while still resembling a conventional garden sundial. Cardioid is Closed curve with one Cusp. Definition In Geometry, the cardioid is an Epicycloid with one Cusp. The cardioid shape connects the intersections between the solar-time marks of a conventional sundial, and the equal-angles of a true clock-time face. The place where The shadow crosses the cardioid's edge, and the clock time can be read from the underlying clock-time dial. The sundial is adjusted for daylight saving time by rotating the underlying equal-angle clock-time face. The sun-time face does not move.

Globe dial

The globe dial is a sphere aligned with the Earth's rotational axis, and equipped with a spherical vane. ^[54] Similar to sundials with a fixed axial style, a globe dial determines the time from the Sun's azimuthal angle in its apparent rotation about the earth. This angle can be determined by rotating the vane to give the smallest shadow. This style of sundial was popularized by Thomas Jefferson at his home in Monticello. Thomas Jefferson (April 13 1743 – July 4 1826 was the third President of the United States (1801–1809 the principal author of the Declaration of Independence Monticello (mɒntəˈtʃɛloʊ located near Charlottesville, Virginia, was the estate of Thomas Jefferson, the principal author of the United States

Noon marks

Noon-mark from Ste. Marie-Madeleine church in Avenches, Switzerland. Avenches is a Swiss municipality in the canton of Vaud, located in the district of Avenches, of which it is the capital Switzerland (English pronunciation; Schweiz Swiss German: Schwyz or Schwiiz Suisse Svizzera Svizra officially the Swiss Confederation 46°52′50″N 7°02′26″E / 46.8805, 7.0405 The analemma is the narrow figure-8 shape, which plots the equation of time (in degrees, not time, 1°=4minutes) versus the altitude of the sun at noon at the sundial's location. The equation of time is the difference over the course of a year between time as read from a Sundial and time as read from a Clock, measured in an ideal situation The altitude is measured vertically, the equation of time horizontally.

The simplest sundials do not give the hours, but rather note the exact moment of 12:00 noon. ^[55] In centuries past, such dials were used to correct mechanical clocks, which were sometimes so inaccurate as to lose or gain significant time in a single day.

In U. S. colonial-era houses, a noon-mark can often be found carved into a floor or windowsill. ^[56] Such marks indicate local noon, and they provide a simple and accurate time reference for households that do not possess accurate clocks. In modern times, some Asian countries, post offices have set their clocks from a precision noon-mark. These in turn provided the times for the rest of the society. The typical noon-mark sundial was a lens set above an analemmatic plate. Analemma was also a book by Ptolemy. In Astronomy, an analemma ( IPA: /ˌænəˈlɛmə/ Latin for the pedestal of a The plate has an engraved figure-eight shape. , which corresponds to plotting the equation of time (described above) versus the solar declination. The equation of time is the difference over the course of a year between time as read from a Sundial and time as read from a Clock, measured in an ideal situation When the edge of the sun's image touches the part of the shape for the current month, this indicates that it is 12:00 noon.

History

The earliest sundials known from the archaeological record are obelisks (3500 BC) and shadow clocks (1500 BC) from ancient Egypt and Babylon. An obelisk (from Greek ὀβελίσκος - obeliskos, diminutive of ὀβελός - obelos, "spit nail pointed pillar" This article is about the country of Egypt For a topic outline on this subject see List of basic Egypt topics. Babylon was a City-state of ancient Mesopotamia, the remains of which can be found in present-day Al Hillah, Babil Province, Iraq Presumably, humans were telling time from shadow-lengths at an even earlier date, but this is hard to verify. In roughly 700 BC, the Old Testament describes a sundial — the "dial of Ahaz" mentioned in Isaiah 38:8 and II Kings 20:11 — which was likely of Egyptian or Babylonian design. In Western Christianity, the Old Testament refers to the books that form the first of the two-part Christian Biblical canon. Sundials are believed to have existed in China since ancient times, but very little is known of their history.

Hemispherical Greek sundial from Ai Khanoum, Afghanistan, 3rd-2nd century BCE. Ai-Khanoum or Ay Khanum (lit “Lady Moon” in Uzbek, probably the historical Alexandria on the Oxus, also possibly later named Eucratidia Afghanistan /æfˈgænɪstæn/ officially the Islamic Republic of Afghanistan ( Pashto: د افغانستان اسلامي جمهوریت,

The ancient Greeks developed many of the principles and forms of the sundial. Sundials are believed to have been introduced into Greece by Anaximander of Miletus, c. Anaximander ( Ancient Greek:) (c 610 BC–c 546 BC was a Pre-Socratic Greek philosopher who lived in Miletus 560 BC. According to Herodotus, the Greeks sundials were initially derived from the Babylonian counterparts. Herodotus of Halicarnassus ( Greek: Hēródotos Halikarnāsseús) was a Greek Historian who lived in the 5th century BC ( 484 BC&ndash The Greeks were well-positioned to develop the science of sundials, having founded the science of geometry, and in particular discovering the conic sections that are traced by a sundial nodus. Geometry ( Greek γεωμετρία; geo = earth metria = measure is a part of Mathematics concerned with questions of size shape and relative position In Mathematics, a conic section (or just conic) is a Curve obtained by intersecting a cone (more precisely a circular Conical surface The mathematician and astronomer Theodosius of Bithynia (ca. Theodosius of Bithynia (ca 160 BC–ca 100 BC was a Greek astronomer and mathematician who wrote the Sphaerics, a book on the geometry of the sphere 160 BC-ca. 100 BC) is said to have invented a universal sundial that could be used anywhere on Earth.

The Romans adopted the Greek sundials, so much so that Plautus complained in one of his plays about his day being "chopped into pieces" by the ubiquitous sundials. Titus Maccius Plautus (c 254–184 BCE commonly known as Plautus, was a Roman Playwright. Writing in ca. 25 BC, the Roman author Vitruvius listed all the known types of dials in Book IX of his De Architectura, together with their Greek inventors. Marcus Vitruvius Pollio (born c 80–70 BC died after c 15 BC was a Roman Writer, Architect and Engineer (possibly praefectus fabrum De architectura ( Latin: "On architecture" is a treatise on Architecture written by the Roman Architect Vitruvius ^[57] All of these are believed to be nodus-type sundials, differing mainly in the surface that receives the shadow of the nodus.

• the hemicyclium of Berosus the Chaldean: a truncated, concave, hemispherical surface
• the hemispherium or scaphe of Aristarchus of Samos: a full, concave, hemispherical surface
• the discus (a disc on a plane surface) of Aristarchus of Samos: a fully circular equatorial dial with nodus
• the arachne (spiderweb) of Eudoxus of Cnidus or Apollonius of Perga: half a circular equatorial dial with nodus
• the plinthium or lacunar of Scopinas of Syracuse: an example in the Circus Flaminius)
• the pros ta historoumena (universal dial) of Parmenio
• the pros pan klima of Theodosius of Bithynia and Andreas
• the pelekinon of Patrocles: the classic double-bladed axe design of hyperbolae on a planar surface
• the cone of Dionysodorus: a concave, conical surface
• the quiver of Apollonius of Perga
• the conarachne
• the conical plinthium
• the antiboreum: a hemispherium that faces North, with the sunlight entering through a small hole. Berossus (also Berossos or Berosus; Greek: Βήρωσσος was a Hellenistic -era Babylonian writer and astronomer who The scaphe (or skaphe, also scaphium or scaphion) was a Sundial said to have been invented by Aristarchus ( 3rd century BC Aristarchus (Ἀρίσταρχος 310 BC - ca 230 BC) was a Greek Astronomer and Mathematician, born on the island of In Geometry, a disk (also spelled disc) is the region in a plane bounded by a Circle. Aristarchus (Ἀρίσταρχος 310 BC - ca 230 BC) was a Greek Astronomer and Mathematician, born on the island of Eudoxus of Cnidus ( Greek Εὔδοξος ὁ Κνίδιος (410 or 408 BC &ndash 355 or 347 BC was a Greek Astronomer, Mathematician This page is a glossary of architecture. A Aisle - subsidiary space alongside the body of a building separated from it by columns piers or Syracuse (Siracusa Sicilian: Sarausa, Classical Greek: / transliterated Syrakousai) is a historic City in The Circus Flaminius was a large circular area of land in Rome that contained a small race-track reserved for mysterious games and various other buildings and monuments Parmenion (also Parmenio) (in Greek, Παρμενίων, ca 400&ndash Ecbatana, 330 BC was a Macedonian general in the service Theodosius of Bithynia (ca 160 BC–ca 100 BC was a Greek astronomer and mathematician who wrote the Sphaerics, a book on the geometry of the sphere A cone is a three-dimensional Geometric shape that tapers smoothly from a flat round base to a point called the apex or vertex Dionysodorus of Caunus (ca 250 BCE - ca 190 BCE was an ancient Greek mathematician

The nodus-based obelisk sundial, Solarium Augusti, in a 19th century representation, with the Mausoleum of Augustus in the background (left). An obelisk (from Greek ὀβελίσκος - obeliskos, diminutive of ὀβελός - obelos, "spit nail pointed pillar" The Mausoleum of Augustus was a large tomb built by the Roman Emperor Augustus in 28 BC on the Campus Martius in Rome.

The Romans built a very large sundial in 10 BC, the Solarium Augusti, which is a classic nodus-based obelisk casting a shadow on a planar pelekinon. The Solarium Augusti, the largest Sundial the ancient world has known was ^[58]

A modern hemispherium in Gyeongbok Palace in Seoul, South Korea. Gyeongbok Palace (경복궁 Gyeongbokgung) is a palace located in northern Seoul, South Korea. Seoul ( soʊl is the Capital and largest City of South Korea. South Korea, officially the Republic of Korea and often referred to as Korea ( Korean: 대한민국 tɛː 37°34′43″N 126°58′38″E / 37.578611, 126.977222 The tip of the pointer serves as the nodus; the height of the nodus-shadow within the bowl gives the time of the year. Since the picture was taken on 24 November, the sun is low in the sky, and the nodus-shadow higher in the bowl.

The Greek dials were inherited and developed further by the Islamic Caliphate cultures and the post-Renaissance Europeans. Since the Greek dials were nodus-based with straight hour-lines, they indicated unequal hours — also called temporary hours — that varied with the seasons, since every day was divided into twelve equal segments; thus, hours were shorter in winter and longer in summer. The idea of using hours of equal time length throughout the year was the innovation of Abul-Hasan near the beginning of the 13th century, based on developments in trigonometry by Albategni. The concept became known in western sundials at least from the year 1400. However, it is unknown when the practice of aligning the style with the Earth's rotational axis was introduced.

The onset of the Renaissance saw an explosion of new designs. Italian astronomer Giovanni Padovani published a treatise on the sundial in 1570, in which he included instructions for the manufacture and laying out of mural (vertical) and horizontal sundials. Giovanni Padovani (or Paduani) (b c 1512 was an Italian mathematician and astronomer. Giuseppe Biancani's Constructio instrumenti ad horologia solaria (ca. Giuseppe Biancani (in Latin, Josephus Blancanus) (1566-1624 was an Italian Jesuit astronomer mathematician and selenographer, after 1620) discusses how to make a perfect sundial, with accompanying illustrations.

The oldest sundial in England is incorporated into the Bewcastle Cross ca. A tide is an obsolete or archaic term for time period or season such as Yuletide eventide shrovetide Eastertide noontide etc The Bewcastle Cross is an Anglo-Saxon High cross located in Cumbria, England. 800 AD. The dial is divided into four tides, covering the parts of the working day in areas influenced by the Vikings, a maritime culture which noted the passage of time in the progression of the two high and two low tides each day.

The custom of measuring time by one's shadow has persisted since ancient times. In Aristophanes' play, Assembly of Women, Praxagora asks her husband to return when his shadow reaches 10 feet (3. Aristophanes (Ἀριστοφάνης ˌærɪˈstɒfəniːz in English ca 0 m). The Venerable Bede also gave instructions to his follows, how to interpret their shadow lengths to know what time it is

Sundial mottoes

Further information: List of sundial mottoes

Illustration of Father Time and a sundial motto: "Grow old along with me; the best is yet to be. Bede (ˈbiːd (also Saint Bede, the Venerable Bede, or (from Latin Beda (beda (c Sundials are often provided with a motto to reflect the sentiments of its maker or owner Father Time (known as Pakiž in some countries is a Personification of Time. "

Sundials are associated with the passage of time, and it has become common to inscribe a motto into a sundial, often one that prompts the viewer to reflect on the transience of the world and the inevitability of death, e. g. , "Do not kill time, for it will surely kill thee. " A more cheerful popular motto is "I count only the sunny hours. " Another is "I am a sundial, and I make a botch of what is done far better by a watch. " Various collections of sundial mottoes have been published over the past few centuries.

See also

• Foucault pendulum
• Francesco Bianchini
• Moondial
• Nocturnal - device for determining time by the stars at night. The Foucault pendulum (fuːˈkoʊ "foo-KOH" or Foucault's pendulum, named after the French physicist Léon Foucault, was conceived as For Giovanni Bianchini (1410-ca 1469 see Giovanni Bianchini. Francesco Bianchini ( December 13, 1662 &ndash March Moondial is also the name of a television series Moondials are time pieces similar to a Sundial. A nocturnal is an instrument used to determine the time based on the position of a certain Star in the night sky
• Scottish sundial — the ancient renaissance sundials of Scotland. Scottish sundials of the Renaissance period are not just more numerous than in any other country they are also stylistically unique
• Tide (time) - devisions of the day on early sundials. A tide is an obsolete or archaic term for time period or season such as Yuletide eventide shrovetide Eastertide noontide etc

Footnotes

Bibliography

• Earle AM (1971). Sundials and Roses of Yesterday. Rutland, VT: Charles E. Tuttle. ISBN 0-8048-0968-2, LCCN 74-142763. The Library of Congress Control Number or LCCN is a serially based system of numbering cataloging records in the Library of Congress in the United   Reprint of the 1902 book published by Macmillan (New York).
• A. P. Herbert, Sundials Old and New,Methuen & Co. Ltd, 1967.
• Mayall RN, Mayall MW (1994). Sundials: Their Construction and Use, 3rd ed. , Cambridge, MA: Sky Publishing. ISBN 0-933346-71-9.  
• Hugo Michnik, Theorie einer Bifilar-Sonnenuhr, Astronomishe Nachrichten, 217(5190), p. 81-90, 1923
• Rohr RRJ (1996). Sundials: History, Theory, and Practice, translated by G. Godin, New York: Dover. ISBN 0-486-29139-1.   Slightly amended reprint of the 1970 translation published by University of Toronto Press (Toronto). The original was published in 1965 under the title Les Cadrans solaires by Gauthier-Villars (Montrouge, France).
• Frederick W. Sawyer, Bifilar gnomonics, JBAA (Journal of the British Astronomical association), 88(4):334–351, 1978
• Gerard L'E. Turner, Antique Scientific Instruments, Blandford Press Ltd. 1980 ISBN 0-7137-1068-3
• Make A Sundial, (The Education Group British Sundial Society) Editors Jane Walker and David Brown, British Sundial Society 1991 ISBN 0-9518404-0
• Waugh AE (1973). Sundials: Their Theory and Construction. New York: Dover Publications. ISBN 0-486-22947-5.  
• "Illustrating Shadows", Simon Wheaton-Smith, ISBN 0-9765286-8-1, LCN: 2005900674
  • also see "Illustrating More Shadows", Simon Wheaton-Smith, both books are over 300 pages long.

External links

Sundial Societies, Groups and Organizations

• British Sundial Society
• North American Sundial Society
• De Zonnewijzerkring - Dutch Sundial Society (in English)
• Societat Catalana de Gnomònica - Catalonian Sundial Society
• Zonnewijzerkring Vlaanderen - Flemish Sundial Society
• Coordinamento Gnomonico Italiano (CGI) - Italian Sundial Society
• La Commission des Cadrans solaires du Québec (CCSQ) - Commission on Sundials of Quebec
• Asociación de Amigos de los Relojes de Sol (AARS) - Spain, Association of Friends of the Sundial

General sundial links

• Sundial Websites Catalogue An indexed and edited site of Sundial related sites.
• Sunbeams and Sundials Children's guide to the sun, the seasons and sundials.
• The Sundial Primer Details of all aspects of sundial maths.
• A major source of information Information about sundial design and building, small indoor, glass, clay, and concrete, designing programs in many languages for sundials, and VRML models.
• Sundial links a collection of sundial links ordered by date.
• Article by Denis Roegel on drawing sundials with the Metapost graphical language. MetaPost refers to both a Programming language and the only known interpreter of the MetaPost programming language
• The Analemmas of Vitruvius and Ptolemy describes the use of these ancient analemmas in laying out shadow traces for different days on horizontal sundials.
• (Polish) Wilanów Palace Sundial.