by ristein » Sat Dec 25, 2010 3:25 am
North is up in the image. Since the eclipse occurred very nearly at the time of the winter solstice, the ecliptic (the apparent path of the sun against the stars) was oriented nearly exactly east-west (horizontal in the image).
The 13.1° angle of the apparent motion of the stars is caused by a combination of (1) the 5.1° inclination of the moon's orbital plane with respect to the ecliptic plane and (2) the topocentric correction (8.0°) due to motion of the observatory with respect to the earth-moon barycenter.
For very distant objects (>> 1 AU), the topocentric correction is small and often neglected. For objects such as near-Earth comets and asteroids and, evidently, for the moon, there can be a substantial difference between the topocentric and geocentric systems.
Image details- telescope: Takahashi FSQ-106N four-inch refractor, focal length 528mm - mount: Paramount ME equatorial - camera: Orion StarShoot Pro V1 - image scale: 3.05 arcsec/pixel - site: Blue Mountain Vista Observatory (New Ringgold PA) - acquisition and processing: MaxIm DL 5.10 - Observation date: 2010.12.21 UT 08:10:11 - Photoshop combination of low-stretched and high-stretched versions of a stack of 31 eight-second exposures aligned on the moon.
Richard Steinberg, Ph.D.
Professor of Physics
Drexel University
Philadelphia, PA 19104
Animation at
http://www.physics.drexel.edu/~steinber ... _movie.gif
Copyright: Richard Steinberg
[img2]http://www.physics.drexel.edu/~steinberg/astro2/solar_system/moon/Lunar_Motion-31x8sec.jpg[/img2]
North is up in the image. Since the eclipse occurred very nearly at the time of the winter solstice, the ecliptic (the apparent path of the sun against the stars) was oriented nearly exactly east-west (horizontal in the image).
The 13.1° angle of the apparent motion of the stars is caused by a combination of (1) the 5.1° inclination of the moon's orbital plane with respect to the ecliptic plane and (2) the topocentric correction (8.0°) due to motion of the observatory with respect to the earth-moon barycenter.
For very distant objects (>> 1 AU), the topocentric correction is small and often neglected. For objects such as near-Earth comets and asteroids and, evidently, for the moon, there can be a substantial difference between the topocentric and geocentric systems.
Image details- telescope: Takahashi FSQ-106N four-inch refractor, focal length 528mm - mount: Paramount ME equatorial - camera: Orion StarShoot Pro V1 - image scale: 3.05 arcsec/pixel - site: Blue Mountain Vista Observatory (New Ringgold PA) - acquisition and processing: MaxIm DL 5.10 - Observation date: 2010.12.21 UT 08:10:11 - Photoshop combination of low-stretched and high-stretched versions of a stack of 31 eight-second exposures aligned on the moon.
Richard Steinberg, Ph.D.
Professor of Physics
Drexel University
Philadelphia, PA 19104
Animation at http://www.physics.drexel.edu/~steinberg/astro2/solar_system/moon/Eclipse-the_movie.gif
Copyright: Richard Steinberg