Mollweide projection: Difference between revisions

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	] levels measured by the ]. Projected using the Mollweide projection.]]		] levels measured by the ]. Projected using the Mollweide projection.]]
			The projection is:

		⚫	:<math>x = \frac{2 \sqrt 2}{\pi} \lambda \cos\left(\theta \right),</math>
⚫	==Properties==
⚫	The Mollweide is a ] projection in which the ] is represented as a straight horizontal line perpendicular to a central ] one-half its length. The other ]s compress near the poles, while the other meridians are equally spaced at the equator. The meridians at 90 degrees east and west form a perfect circle, and the whole earth is depicted in a proportional 2:1 ellipse. The proportion of the area of the ellipse between any given parallel and the equator is the same as the proportion of the area on the globe between that parallel and the equator, but at the expense of shape distortion, which is significant at the perimeter of the ellipse, although not as severe as in the ].

⚫	Shape distortion may be diminished by using an ''interrupted'' version. A ''sinusoidal interrupted'' Mollweide projection discards the central meridian in favor of alternating half-meridians which terminate at right angles to the equator. This has the effect of dividing the globe into lobes shape. In contrast, a ''parallel interrupted'' Mollweide projection uses multiple disjoint central meridians, giving the effect of multiple ellipses joined at the equator. More rarely, the project can be drawn obliquely to shift the areas of distortion to the oceans, allowing the continents to remain truer to form.

⚫	The Mollweide, or its properties, has inspired the creation of several other projections, including the ], ] and the ].<ref>, ] Professional Paper 1395, John P. Snyder, 1987, pp. 249–252</ref>

	==Mathematical Formulation==
	The projection transforms from latitude and longitude to map coordinates through the following equations:<ref name="MathWorldMollweide">{{MathWorld\|title=Mollweide Projection\|urlname=MollweideProjection\|author=Weisstein, Eric W.}}</ref>

⚫	:<math>x = \frac{2 \sqrt 2}{\pi} ~~\left(~~ \lambda ~~- \lambda_{0} \right)~~ \cos \left( \theta \right),</math>

	:<math>y = \sqrt 2 \sin \left( \theta \right),\,</math>		:<math>y = \sqrt 2 \sin\left(\theta \right),\,</math>

	where <math>\theta\,</math> is an auxiliary angle defined by		where <math>\theta\,</math> is an auxiliary angle defined by

	:<math>2 \theta + \sin ~~\left~~( 2 \theta ~~\right~~) = \pi \sin ~~\left~~( \varphi ~~\right~~) \qquad (1)</math>		:<math>2 \theta + \sin(2 \theta) = \pi \sin(\varphi)\qquad (1)</math>

	and ''λ'' is the longitude, ~~''λ<sub>0</sub>'' is~~ the central meridian, and ''φ'' is the latitude.		and ''λ'' is the longitude from the central meridian, and ''φ'' is the latitude.

	Equation (1) may be solved with rapid convergence (but slow near the poles) using ] iteration:~~<ref name="MathWorldMollweide"/>~~		Equation (1) may be solved with rapid convergence (but slow near the poles) using ] iteration:

	:<math> \theta_0 = \varphi,\,</math>		:<math> \theta_0 = \varphi,\,</math>
		⚫	:<math> \theta_{n+1} = \theta_n - \frac{(2\theta_n + \sin(2\theta_n) - \pi \sin(\varphi))}{2 + 2\cos(2\theta_n)}.\,</math>

⚫	:<math> \theta_{n+1} = \theta_n - \frac{2 \theta_n + \sin ~~\left~~( 2 \theta_n ~~\right~~) - \pi \sin ~~\left~~( \varphi ~~\right~~)}{2 + 2 \cos ~~\left~~( 2 \theta_n ~~\right~~)}.\,</math>

	If ''φ'' = ±π/2, then also θ = ±π/2. In that case the iteration should be bypassed; otherwise, ] may result.		If ''φ'' = ±π/2, then also θ = ±π/2. In that case the iteration should be bypassed; otherwise, ] may result.

		⚫	==Properties==
	There exists a ] inverse transformation:<ref name="MathWorldMollweide"/>
		⚫	The Mollweide is a ] projection in which the ] is represented as a straight horizontal line perpendicular to a central ] one-half its length. The other ]s compress near the poles, while the other meridians are equally spaced at the equator. The meridians at 90 degrees east and west form a perfect circle, and the whole earth is depicted in a proportional 2:1 ellipse. The proportion of the area of the ellipse between any given parallel and the equator is the same as the proportion of the area on the globe between that parallel and the equator, but at the expense of shape distortion, which is significant at the perimeter of the ellipse, although not as severe as in the ].

		⚫	Shape distortion may be diminished by using an ''interrupted'' version. A ''sinusoidal interrupted'' Mollweide projection discards the central meridian in favor of alternating half-meridians which terminate at right angles to the equator. This has the effect of dividing the globe into lobes shape. In contrast, a ''parallel interrupted'' Mollweide projection uses multiple disjoint central meridians, giving the effect of multiple ellipses joined at the equator. More rarely, the project can be drawn obliquely to shift the areas of distortion to the oceans, allowing the continents to remain truer to form.
	:<math> \varphi = \sin^{-1} \left, \,</math>
	:<math> \lambda = \lambda_{0} + \frac{\pi x}{2 \sqrt{2} \cos \theta}, \,</math>

		⚫	The Mollweide, or its properties, has inspired the creation of several other projections, including the ], ] and the ].<ref>, ] Professional Paper 1395, John P. Snyder, 1987, pp. 249–252</ref>
	where ''θ'' can be found by the relation

	:<math>\theta = \sin^{-1} \left( \frac{y}{\sqrt{2}} \right). \,</math>

	The inverse transformations allow one to find the latitude and longitude corresponding to the map coordinates ''x'' and ''y''.

	==See also==		==See also==

Revision as of 03:42, 19 September 2013

The Mollweide projection is a pseudocylindrical map projection generally used for global maps of the world (or sky). Also known as the Babinet projection, homalographic projection, homolographic projection, and elliptical projection. As its more explicit name Mollweide equal area projection indicates, it sacrifices accuracy of angle and shape in favor of accurate proportions in area. It is used primarily where accurate representation of area takes precedence over shape, for instance small maps depicting global distributions.

The projection was first published by mathematician and astronomer Karl (or Carl) Brandan Mollweide (1774 – 1825) of Leipzig in 1805. It was popularized by Jacques Babinet in 1857, giving it the name homalographic projection. The variation homolographic arose from frequent nineteenth century usage in star atlases.

The projection is:

x={\frac {2{\sqrt {2}}}{\pi }}\lambda \cos \left(\theta \right),

y={\sqrt {2}}\sin \left(\theta \right),\,

where $\theta \,$ is an auxiliary angle defined by

2\theta +\sin(2\theta )=\pi \sin(\varphi )\qquad (1)

and λ is the longitude from the central meridian, and φ is the latitude.

Equation (1) may be solved with rapid convergence (but slow near the poles) using Newton–Raphson iteration:

\theta _{0}=\varphi ,\,

\theta _{n+1}=\theta _{n}-{\frac {(2\theta _{n}+\sin(2\theta _{n})-\pi \sin(\varphi ))}{2+2\cos(2\theta _{n})}}.\,

If φ = ±π/2, then also θ = ±π/2. In that case the iteration should be bypassed; otherwise, division by zero may result.

Properties

The Mollweide is a pseudocylindrical projection in which the equator is represented as a straight horizontal line perpendicular to a central meridian one-half its length. The other parallels compress near the poles, while the other meridians are equally spaced at the equator. The meridians at 90 degrees east and west form a perfect circle, and the whole earth is depicted in a proportional 2:1 ellipse. The proportion of the area of the ellipse between any given parallel and the equator is the same as the proportion of the area on the globe between that parallel and the equator, but at the expense of shape distortion, which is significant at the perimeter of the ellipse, although not as severe as in the sinusoidal projection.

Shape distortion may be diminished by using an interrupted version. A sinusoidal interrupted Mollweide projection discards the central meridian in favor of alternating half-meridians which terminate at right angles to the equator. This has the effect of dividing the globe into lobes shape. In contrast, a parallel interrupted Mollweide projection uses multiple disjoint central meridians, giving the effect of multiple ellipses joined at the equator. More rarely, the project can be drawn obliquely to shift the areas of distortion to the oceans, allowing the continents to remain truer to form.

The Mollweide, or its properties, has inspired the creation of several other projections, including the Goode's homolosine, van der Grinten and the Boggs eumorphic.

References

Flattening the Earth: Two Thousand Years of Map Projections, John P. Snyder, 1993, pp. 112–113, ISBN 0-226-76747-7.
Gannon, Megan (December 21, 2012). "New 'Baby Picture' of Universe Unveiled". Space.com. Retrieved December 21, 2012.
Bennett, C.L.; Larson, L.; Weiland, J.L.; Jarosk, N.; Hinshaw, N.; Odegard, N.; Smith, K.M.; Hill, R.S.; Gold, B.; Halpern, M.; Komatsu, E.; Nolta, M.R.; Page, L.; Wollack, E.; Dunkley, J.; Kogut, A.; Limon, M.; Meyer, S.S.; Tucker, G.S.; Wright, E.L. (December 20, 2012). "Nine-Year Wilkinson Microwave Anisotropy Probe (WMAP) Observations: Final Maps and Results". arXiv:1212.5225. Retrieved December 22, 2012. {{cite journal}}: |first14= missing |last14= (help); Cite journal requires |journal= (help)
Map Projections – A Working Manual, USGS Professional Paper 1395, John P. Snyder, 1987, pp. 249–252

External links

Map projection

By surface

Cylindrical

Mercator-conformal	Gauss–Krüger Transverse Mercator Oblique Mercator
Equal-area	Balthasart Behrmann Gall–Peters Hobo–Dyer Lambert Smyth equal-surface Trystan Edwards
Cassini Central Equirectangular Gall stereographic Gall isographic Miller Space-oblique Mercator Web Mercator

Pseudocylindrical

Equal-area	Collignon Eckert II Eckert IV Eckert VI Equal Earth Goode homolosine Mollweide Sinusoidal Tobler hyperelliptical
Kavrayskiy VII Wagner VI Winkel I and II

Conical

Pseudoconical

Azimuthal
(planar)

General perspective	Gnomonic Orthographic Stereographic
Equidistant Lambert equal-area

Bonne	Sinusoidal Werner
Bottomley	Sinusoidal Werner
Cylindrical	Balthasart Behrmann Gall–Peters Hobo–Dyer Lambert cylindrical equal-area Smyth equal-surface Trystan Edwards
Tobler hyperelliptical	Collignon Mollweide
Albers Briesemeister Eckert II Eckert IV Eckert VI Equal Earth Goode homolosine Hammer Lambert azimuthal equal-area Quadrilateralized spherical cube Strebe 1995

Equidistant in
some aspect

Gnomonic

Gnomonic

Loxodromic

Retroazimuthal
(Mecca or Qibla)

Planar	Gnomonic Orthographic Stereographic
Central cylindrical

Polyhedral

See also
Interruption (map projection) Latitude Longitude Tissot's indicatrix Map projection of the tri-axial ellipsoid

Categories:

Revision as of 03:42, 19 September 2013

Properties

See also

References

External links