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diff --git a/doc/kstars/ecliptic.docbook b/doc/kstars/ecliptic.docbook new file mode 100644 index 00000000..3061dd1b --- /dev/null +++ b/doc/kstars/ecliptic.docbook @@ -0,0 +1,58 @@ +<sect1 id="ai-ecliptic"> +<sect1info> +<author> +<firstname>John</firstname> +<surname>Cirillo</surname> +</author> +</sect1info> +<title>The Ecliptic</title> +<indexterm><primary>Ecliptic</primary> +<seealso>Ecliptic Coordinates</seealso> +</indexterm> +<para> +The ecliptic is an imaginary <link linkend="ai-greatcircle">Great Circle</link> +on the <link linkend="ai-csphere">Celestial Sphere</link> along which the Sun +appears to move over the course of a year. Of course, it is really the +Earth's orbit around the Sun causing the change in the Sun's apparent +direction. The ecliptic is inclined from the <link linkend="ai-cequator">Celestial +Equator</link> by 23.5 degrees. The two points where the Ecliptic crosses +the Celestial Equator are known as the <link +linkend="ai-equinox">Equinoxes</link>. +</para><para> +Since our solar system is relatively flat, the orbits of the planets are +also close to the plane of the ecliptic. In addition, the constellations of the +zodiac are located along the ecliptic. This makes the ecliptic a very useful +line of reference to anyone attempting to locate the planets or the +constellations of the zodiac, since they all literally <quote>follow the +Sun</quote>. +</para><para> +Because of the 23.5-degree tilt of the Ecliptic, the +<firstterm>Altitude</firstterm> of the Sun at noon changes over the course of the +year, as it follows the path of the Ecliptic across the sky. This causes the +seasons. In the Summer, the Sun is high in the sky at noon, +and it remains above the <link linkend="ai-horizon">Horizon</link> for more than +twelve hours. Whereas, in the winter, the Sun is low in the sky at noon, and remains +above the Horizon for less than twelve hours. In addition, sunlight is received at +the Earth's surface at a more direct angle in the Summer, which means that a given +area at the surface receives more energy per second in the Summer than in Winter. +The differences in day duration and in energy received per unit area lead to the +differences in temperature we experience in Summer and Winter. +</para> +<tip> +<para>Exercises:</para> +<para> +Make sure your location is set to somewhere that is not very near the equator +for these experiments. Open the <guilabel>Configure &kstars;</guilabel> window, and +switch to Horizontal coordinates, with the Opaque Ground shown. Open the +<guilabel>Set Time</guilabel> window +(<keycombo action="simul">&Ctrl;<keycap>S</keycap></keycombo>),and change the +Date to sometime in the middle of Summer, and the Time to 12:00 Noon. Back in +the Main Window, point toward the Southern Horizon (press <keycap>S</keycap>). +Note the height of the Sun above the Horizon at Noon in the Summer. Now, change +the Date to something in the middle of Winter (but keep the Time at 12:00 Noon). +The Sun is now much lower in the Sky. You will also notice that the day durations +are different if you open the <guilabel>What's Up Tonight?</guilabel> tool for +each date. +</para> +</tip> +</sect1> |