Everything about The Mercator Projection totally explained
The
Mercator projection is a
cylindrical map projection presented by the
Flemish geographer and cartographer
Gerardus Mercator, in
1569. It became the standard map projection for nautical purposes because of its ability to represent lines of constant
true bearing or
true course, known as
rhumb lines, as straight
line segments. While the direction and shapes are accurate on a Mercator projection, it distorts size, in an increasing degree away from the equator.
Properties and historical details
Mercator's 1569 edition was a large
planisphere measuring 202 by 124 cm, printed in eighteen separate sheets. As in all
cylindrical projections,
parallels and
meridians are straight and perpendicular to each other. In accomplishing this, the unavoidable east-west stretching of the map, which increases as distance away from the
equator increases, is accompanied by a corresponding north-south stretching, so that at every point location, the east-west scale is the same as the north-south scale, making the projection
conformal. A Mercator map can never fully show the polar areas, since
linear scale becomes infinitely high at the poles. Being a conformal projection, angles are preserved around all locations, however scale varies from place to place, distorting the size of geographical objects. In particular, areas closer to the poles are more affected, transmitting an image of the geometry of the planet which is more distorted the closer to the poles. At latitudes higher than 70° north or south, the Mercator projection is practically unusable.
All lines of constant
bearing (
rhumb lines or
loxodromes — those making constant angles with the meridians), are represented by straight segments on a Mercator map. This is precisely the type of route usually employed by ships at sea, where
compasses are used to indicate geographical directions and to steer the ships. The two properties,
conformality and straight
rhumb lines, make this projection uniquely suited to marine navigation: courses and bearings are measured using wind-roses or protractors, and the corresponding directions are easily transferred from point to point, on the map, with the help of a
parallel ruler or a pair of
navigational squares.
The name and explanations given by Mercator to his world map (
Nova et Aucta Orbis Terrae Descriptio ad Usum Navigatium Emendate: "new and augmented description of Earth corrected for the use of navigation") show that it was expressly conceived for the use of marine navigation. Although the method of construction isn't explained by the author, Mercator probably used a graphical method, transferring some rhumb lines previously plotted on a globe to a square
graticule, and then adjusting the spacing between parallels so that those lines became straight, making the same angle with the meridians as in the globe.
The development of the Mercator projection represented a major breakthrough in the nautical cartography of the
16th century. However, it was much ahead of its time, since the old navigational and surveying techniques were not compatible with its use in navigation. Two main problems prevented its immediate application: the impossibility of determining the longitude at sea with adequate accuracy and the fact that
magnetic directions, instead of
geographical directions, were used in navigation. Only in the middle of the
18th century, after the
marine chronometer was invented and the spatial distribution of
magnetic declination was known, could the Mercator projection be fully adopted by navigators.
Several authors are associated with the development of Mercator projection:
- German Erhard Etzlaub (c. 1460–1532), who had engraved miniature "compass maps" (about 10x8 cm) of Europe and parts of Africa, latitudes 67°–0°, to allow adjustment of his portable pocket-size sundials, was for decades declared to have designed "a projection identical to Mercator’s". This has since proven to be an error, tracing back to doubtable research in 1917.
Portuguese mathematician and cosmographer Pedro Nunes (1502–1578), who first described the loxodrome and its use in marine navigation, and suggested the construction of several large-scale nautical charts in the cylindrical equidistant projection to represent the world with minimum angle distortion (1537).
English mathematician Edward Wright (c. 1558–1615), who formalized the mathematics of Mercator projection (1599), and published accurate tables for its construction (1599, 1610).
English mathematicians Thomas Harriot (1560–1621) and Henry Bond (c.1600–1678) who, independently (c. 1600 and 1645), associated the Mercator projection with its modern logarithmic formula, later deduced by calculus.
Mathematics of the projection
The following equations determine the x and y coordinates of a point on a Mercator map from its latitude φ and longitude λ (with λ0 being the longitude in the center of map):
This is the inverse of the Gudermannian function:
»
Further Information
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