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| The intersection of a sphere with a plane that passes through the center of the sphere is called a \emph{great circle}. Note that it is equivalent to say that a great circle of a sphere is any circle that lies on the surface of the sphere and has maximum circumference. Geographically speaking, longitudes are examples of great circles; however, with the exception of the equator, \emph{no} latitude is a great circle. |
The intersection of a sphere with a plane that passes through the center of the sphere is called a \emph{great circle}. Note that it is equivalent to say that a great circle of a sphere is any circle that lies on the surface of the sphere and has maximum circumference. Geographically speaking, longitudes are examples of great circles; however, with the exception of the equator, \emph{no} latitude is a great circle. |
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| Infinitely many great circles pass through two antipodal points of a sphere. Otherwise, two distinct points on a sphere determine a unique great circle. |
Infinitely many great circles pass through two antipodal points of a sphere. Otherwise, two distinct points on a sphere determine a unique great circle. |
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| An arc of a great circle is called a \emph{great arc}. |
An arc of a great circle is called a \emph{great arc}. |
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| Note that great circles and great arcs are geodesics of the surface of the sphere on which they lie. Thus, in spherical geometry, if a sphere is serving as the model, then \PMlinkescapetext{lines} are defined to be great circles of the sphere, and \PMlinkescapetext{line segments} are defined to be great arcs of the sphere. |
Note that great circles and great arcs are geodesics of the surface of the sphere on which they lie. Thus, in spherical geometry, if a sphere is serving as the model, then \PMlinkescapetext{lines} are defined to be great circles of the sphere, and \PMlinkescapetext{line segments} are defined to be great arcs of the sphere. |
