Daily Motion of the Sun
Daily motion (diurnal motion) along a circle with center on the Earth’s axis
Clockwise in the north temperate zone Counterclockwise in the south
temperate zone Up and down in the tropics Don’t worry about CW or CCW in the
tropics
Yearly Motion of the Sun Yearly motion (annual motion) along the
ecliptic The ecliptic great circle is the
intersection of the celestial sphere with the ecliptic plane
The Sun drifts eastward (counterclockwise when viewed from above the NCP) with respect to the stars in the course of the year
Yearly Motion of the Sun 2
Yearly Motion of the Sun 3
We cannot see the ecliptic, but we deduce its position by considering which stars are close to the Sun at the time of sunrise or sunset
Heliacal Rising
Heliacal (/hɪˈlaɪəkəl/) rising is the first visible appearance of a star on the eastern horizon before sunrise
On the previous morning, sunlight made the star invisible
Dog Days
Sirius is the brightest star in the night sky
In ancient Egypt, the helical rising of Sirius coincided with the annual flooding of the Nile
Sirius is also known as the Dog Star because of its prominence in the constellation Canis Major (Big Dog)
Dog Days 2
The Dog Days refers to the hottest days of summer
At the time of the ancient Greeks this were the days when star Sirius rose just before or at the same time as sunrise (heliacal rising)
Equinoxes and Solstices
The equinoxes are the intersections of the celestial equator and the ecliptic
The solstices are the points on the ecliptic furthest from the celestial equator
These geocentric definitions agree with the heliocentric ones given earlier
Equinoxes and Solstices 2
Equinoxes and Solstices 3 The spring equinox is both a time and a
place! The spring equinox is the moment when
the Sun is at the spring equinox You finish the race when you reach the
finish! The spring equinox is the intersection
point where the counterclockwise motion is up
Equinoxes and Solstices 4 At the time of the equinoxes, day and
night are equally long everywhere on Earth
Equinox = equal night At the time of the solstices, the rising
position of the Sun reaches its extreme northern or southern positions, so the Sun stands still before turning
Solstice = Sun standing Tropic = (Sun) turning
Equinoxes and Solstices 5 Apparent diameter of the Sun is 0.5° At the equinox the centre of the Sun is
above the horizon for 12 hours Sunrise is defined to be when the upper
limb of the Sun crosses the horizon, so day is actually longer than night at the equinox
In addition, refraction bends light over the horizon
Equinoxes and Solstices 6 The change in rising position of the Sun
along the horizon is fastest around the equinoxes, and slowest around the solstices
Around the equinoxes, the declination (distance from the celestial equator) will change by 0.5° per day
Near the solstices, it will stay fixed for almost a week
Celestial Coordinates In order to set up a coordinate system
on a sphere, we need a great circle and a base point on it
On the Earth, there is only one natural great circle, on the Celestial Sphere there are three: horizon, celestial equator and ecliptic
There are therefore three coordinate systems on the celestial sphere
Horizon Coordinate System Base circle: horizon, base point:
north point Altitude and azimuth Azimuth is measured clockwise
from 0° to 360° and tracks the daily path of the Sun in the north temperate zone
90 – altitude is called the zenith distance
Horizon Coordinate System 2
Equatorial Coordinate System
Base circle: celestial equator, base point: vernal equinox
Declination and right ascension RA is measured counterclockwise
in hours from 0h to 24h and tracks the time difference in meridian passage of stars
Equatorial Coordinate System 2
Ecliptic Coordinate System Base circle: ecliptic, base point: vernal
equinox (Celestial) latitude and (Celestial)
longitude Longitude is measured
counterclockwise from 0° to 360° and tracks the Sun’s annual motion
Celestial latitude and longitude is not relative to the celestial equator!
Comparing Coordinate Systems Azimuth is measured in the opposite
direction from RA and longitude Horizon system is local, the two other are
global For stars, the horizon coordinates change
with time, while the two other are fixed Horizon for simple observations Equatorial for tracking stars Ecliptic for tracking Sun, Moon and
planets
Comparing Coordinate Systems 2
The latitude of the Moon is always less than 5°
For the planets, the latitudes are less than 3° except for Mercury, which can go up to 7°
The ex-planet Pluto could go up to 17°