azimuthal plane - significado y definición. Qué es azimuthal plane
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Qué (quién) es azimuthal plane - definición

MAP PROJECTION
Lambert azimuthal projection; Azimuthal equal-area projection; Lambert net; Schmidt plot; Lambert asimuthal projection; LEAA projection; Lambert Azimuthal Equal Area; Lambert azimuthal equal area; Azimuthal equal area; Laea; Lambert azimuthal map projection
  • The Lambert azimuthal equal-area projection with [[Tissot's indicatrix]] of deformation.
  • Animation of a Lambert projection. Each grid cell maintains its area throughout the transformation. In this animation, points on the equator remain always on the <math>z=0</math> plane.
  • In this animated Lambert projection, the south pole is held fixed.
  • Lambert azimuthal equal-area projection of the world. The center is 0° N 0° E. The antipode is 0° N 180° E, near [[Kiribati]] in the [[Pacific Ocean]]. That point is represented by the entire circular boundary of the map, and the ocean around that point appears along the entire boundary.
  • cross section]]al view of the sphere and a plane tangent to it at ''S''. Each point on the sphere (except the antipode) is projected to the plane along a circular arc centered at the point of tangency between the sphere and plane.

Supplementary Ideographic Plane         
  • A map of the Supplementary Ideographic Plane. Each numbered box represents 256 code points.
  • A map of the Supplementary Special-purpose Plane. Each numbered box represents 256 code points.
  • A map of the Tertiary Ideographic Plane. Each numbered box represents 256 code points.
  • A map of the Supplementary Multilingual Plane. Each numbered box represents 256 code points.
CONTINUOUS GROUP OF 65536 CODE POINTS IN THE UNICODE CODED CHARACTER SET
Basic multilingual plane; Basic Multilingual Plane; Supplementary Multilingual Plane; Plane One; Plane Zero; Plane Fifteen; Plane Sixteen; Supplementary Ideographic Plane; Plane Two; Supplementary Special-purpose Plane; Plane Fourteen; Plane 0; Plane 1; Plane 2; Plane 14; Plane 15; Plane 16; Astral character; Mapping of Unicode character planes; Unicode plane; Supplementary characters; Unicode planes; Tertiary Ideographic Plane; Private Use Plane; Astral plane (Unicode); Plane 15 (Unicode); Plane 16 (Unicode); Private use plane; Private use plane (Unicode); UCS-PUP15; PUP15; PUP16; UCS-PUP16; PUP15 (Unicode); PUP16 (Unicode); Supplementary plane; Unicode BMP; Private Use Planes; Plane 4; Plane 5; Plane 6; Plane 7; Plane 8; Plane 9; Plane 10; Plane 11; Plane 12; Plane 13; Supplemental Multilingual Plane; Supplemental Ideographic Plane; Supplemental Special-purpose Plane; Plane (unicode)
<text, standard> (SIP) The third plane (plane 2) defined in Unicode/ISO 10646, designed to hold all the ideographs descended from Chinese writing (mainly found in Vietnamese, Korean, Japanese and Chinese) that aren't found in the {Basic Multilingual Plane}. The BMP was supposed to hold all ideographs in modern use; unfortunately, many Chinese dialects (like Cantonese and Hong Kong Chinese) were overlooked; to write these, characters from the SIP are necessary. This is one reason even non-academic software must support characters outside the BMP. Unicode home (http://unicode.org). (2002-06-19)
Plane (geometry)         
  • right
FLAT, TWO-DIMENSIONAL SURFACE
Infinite Plane; Infinite plane; Plane coordinates; Plane coordinate; 2-dimensional space; Euclidean 2-space; Euclidean two-dimensional space; Two-dimensional Euclidean space; Plane (geometry)
In mathematics, a plane is a flat, two-dimensional surface that extends indefinitely.In Euclidean geometry it extends infinitely, but in, e.
Basic Multilingual Plane         
  • A map of the Supplementary Ideographic Plane. Each numbered box represents 256 code points.
  • A map of the Supplementary Special-purpose Plane. Each numbered box represents 256 code points.
  • A map of the Tertiary Ideographic Plane. Each numbered box represents 256 code points.
  • A map of the Supplementary Multilingual Plane. Each numbered box represents 256 code points.
CONTINUOUS GROUP OF 65536 CODE POINTS IN THE UNICODE CODED CHARACTER SET
Basic multilingual plane; Basic Multilingual Plane; Supplementary Multilingual Plane; Plane One; Plane Zero; Plane Fifteen; Plane Sixteen; Supplementary Ideographic Plane; Plane Two; Supplementary Special-purpose Plane; Plane Fourteen; Plane 0; Plane 1; Plane 2; Plane 14; Plane 15; Plane 16; Astral character; Mapping of Unicode character planes; Unicode plane; Supplementary characters; Unicode planes; Tertiary Ideographic Plane; Private Use Plane; Astral plane (Unicode); Plane 15 (Unicode); Plane 16 (Unicode); Private use plane; Private use plane (Unicode); UCS-PUP15; PUP15; PUP16; UCS-PUP16; PUP15 (Unicode); PUP16 (Unicode); Supplementary plane; Unicode BMP; Private Use Planes; Plane 4; Plane 5; Plane 6; Plane 7; Plane 8; Plane 9; Plane 10; Plane 11; Plane 12; Plane 13; Supplemental Multilingual Plane; Supplemental Ideographic Plane; Supplemental Special-purpose Plane; Plane (unicode)
<text, standard> (BMP) The first plane defined in Unicode/ISO 10646, designed to include all scripts in active modern use. The BMP currently includes the Latin, Greek, Cyrillic, Devangari, hiragana, katakana, and Cherokee scripts, among others, and a large body of mathematical, APL-related, and other miscellaneous characters. Most of the Han ideographs in current use are present in the BMP, but due to the large number of ideographs, many were placed in the Supplementary Ideographic Plane. Unicode home (http://unicode.org). (2002-03-19)

Wikipedia

Lambert azimuthal equal-area projection

The Lambert azimuthal equal-area projection is a particular mapping from a sphere to a disk. It accurately represents area in all regions of the sphere, but it does not accurately represent angles. It is named for the Swiss mathematician Johann Heinrich Lambert, who announced it in 1772. "Zenithal" being synonymous with "azimuthal", the projection is also known as the Lambert zenithal equal-area projection.

The Lambert azimuthal projection is used as a map projection in cartography. For example, the National Atlas of the US uses a Lambert azimuthal equal-area projection to display information in the online Map Maker application, and the European Environment Agency recommends its usage for European mapping for statistical analysis and display. It is also used in scientific disciplines such as geology for plotting the orientations of lines in three-dimensional space. This plotting is aided by a special kind of graph paper called a Schmidt net.