train:lectures:positionalastro

Differences

This shows you the differences between two versions of the page.

Link to this comparison view

Both sides previous revision Previous revision
Next revision		 Previous revision
train:lectures:positionalastro [2024/03/18 12:41] Roy Proutytrain:lectures:positionalastro [2024/03/18 16:10] (current) Roy Prouty
Line 59: Line 59:
 \\ \\
 \\ \\
-[{{:train:lectures:celestialsphere-ecliptic.png?400|}} +[{{:train:lectures:celestialsphere-ecliptic.png?400|Rough geometry of the two planes, the Ecliptic and Celestial Equator. These intersect and give us the Equinoxes of date. The two planes are inclined to one another by the tilt of the Earth's rotation axis $~24^\circ$ .}}]
-Rough geometry of the two planes, the Ecliptic and Celestial Equator. These intersect and give us the Equinoxes of date. The two planes are inclined to one another by the tilt of the Earth's rotation axis ~24 deg .]+
 \\ \\
 \\ \\
-The March Equinox is chosen to be the zero-point for the Equatorial Coordinate analogous to latitude -- the Right Ascension or RA. RA is measured eastward along the Celestial Equator starting at the March Equinox.+The March Equinox is chosen to be the zero-point for the Equatorial Coordinate analogous to latitude -- the Right Ascension or RA. RA($\alpha$) is measured eastward along the Celestial Equator starting at the March Equinox.
 ==Milankovitch Cycles== ==Milankovitch Cycles==
 The specific location of the CNP/CSP/CEq do change over time in cycles known as {{https://en.wikipedia.org/wiki/Milankovitch_cycles|Milankovitch Cycles}}. These cycles are symptomatic of the Precession/Nutation of the Earth's rotation axes, Orbital Eccentricity, and Orbital Obliquity. They're due to the gravitational effects of the masses in our Solar System being more in-line with the Ecliptic than our Celestial Equator! How fun!?   The specific location of the CNP/CSP/CEq do change over time in cycles known as {{https://en.wikipedia.org/wiki/Milankovitch_cycles|Milankovitch Cycles}}. These cycles are symptomatic of the Precession/Nutation of the Earth's rotation axes, Orbital Eccentricity, and Orbital Obliquity. They're due to the gravitational effects of the masses in our Solar System being more in-line with the Ecliptic than our Celestial Equator! How fun!?  
 \\ \\
 \\ \\
-==== Note on Units ====+=== Note on Units ===
 Degrees, Minutes, Seconds -- of arc! Degrees, Minutes, Seconds -- of arc!
 As we're all aware, the circle is split into 360 friendly units called degrees. By the time more precise units were called for (~13th Century CE), mathematicians hadn't yet introduced the radian (1720s CE). So the units of increased precision were introduced as the minute pieces of the degree (minutes of arc) and the second-most minute pieces of the degree (secundus minutae, seconds of arc). The degree is the same one you're familiar with, denoted by the raised circle ($^\circ$). The minutes and seconds of arc (also called arcminutes and arcseconds) are denoted by one or two 'ticks', respectively. In this way, $1^\circ = 60'$ and $1' = 60''$ AND $1^\circ = 3600''$. As we're all aware, the circle is split into 360 friendly units called degrees. By the time more precise units were called for (~13th Century CE), mathematicians hadn't yet introduced the radian (1720s CE). So the units of increased precision were introduced as the minute pieces of the degree (minutes of arc) and the second-most minute pieces of the degree (secundus minutae, seconds of arc). The degree is the same one you're familiar with, denoted by the raised circle ($^\circ$). The minutes and seconds of arc (also called arcminutes and arcseconds) are denoted by one or two 'ticks', respectively. In this way, $1^\circ = 60'$ and $1' = 60''$ AND $1^\circ = 3600''$.
Line 79: Line 78:
 \\ \\
 \\ \\
 +Declination is measured in degrees, minutes of arc and seconds of arc with $360^\circ$ if traversing any Great Circle containing the CNP and CSP. Right Ascension is measured in hours, minutes, and seconds with $24^h$ if traversing the full Celestial Equator. As we shall see, changes in $\alpha$ correspond to different angular rotations of the Earth -- or different times of day! These units can be confusing. Minutes of arc (or arcminutes) are NOT the same as minutes of RA. Furthermore, the notation of $\alpha$ & $\delta$ (RA & DEC) can be confusing. They can be given in their fully qualified notation $(D_1^\circ~D_2'~D_3'', R_1^h, R_2^m, R_3^s)$, as degree-decimals, or some fun mixture of the two! When looking at a very small Field of View, angular measures in $\alpha$ will frequently just be in terms of arcminutes or arcseconds. Pay careful attention to these notations and values. Be sure you understand the differences between them!
 +\\
 +\\
 +==== Reconciling LCHS and Eq Systems ====
 With this Equatorial Coordinate System, an observer  With this Equatorial Coordinate System, an observer 
 [{{:train:lectures:screen_shot_2024-03-18_at_12.35.44_pm.png?400|The LHCS projected onto the Celestial Sphere centered on the fundamental plane of the  Equatorial Coordinate System.}}] [{{:train:lectures:screen_shot_2024-03-18_at_12.35.44_pm.png?400|The LHCS projected onto the Celestial Sphere centered on the fundamental plane of the  Equatorial Coordinate System.}}]
 \\ \\
 \\ \\
 +For an observer at a positive latitude, $\lambda$, r ($\lambda=~39^\circ$ for MD):
 +  - the CNP will be located at $(ALT=\lambda^\circ, AZ=0^\circ)$
 +  - the CSP will never be above the local horizon (Why?)
 +  - the CEq will intersect the local meridian at $(ALT=90^\circ - \lambda, AZ=180^\circ)$
 +  - Zenith will see changing RA, depending on the local time, but the $\delta$ will always be $\lambda^\circ$
 +
 +=====Stellarium Exercises=====
 +Using Stellarium, let’s all do the following together …
 +
 +  - Set location to Baltimore. Note the (lat, lon)
 +      - Identify the Ecliptic
 +      - Set the date to your birthday and tell me your “Sun sign” – ugh
 +      - Explore Local Horizon Grid
 +          - Find the Pole Star and find its (alt, az) – what should it be?
 +          - Enable the Local Meridian
 +          - Play time forward and watch star paths
 +      - Explore Equatorial Grid
 +          - Enable CEq
 +          - Play time forward and watch star paths 
 +          - Set location to North Pole, South Pole, Equator, etc
 +      - Determine (alt, az) of a star in Orion, determine (RA, DEC)
 +      - Determine exact time (ET) of March Equinox
 +      - Back in Baltimore, identify the set of stars that never set
 +          - These stars comprise the Circumpolar Region of our Local Horizon
 +          - How does this region change with latitude?
 +      - With Local Meridian on over Equatorial Grid: Define Transits & Sidereal Time
 +          - Look up current Sidereal Time: https://www.localsiderealtime.com/ 
  
 +----
  
 +Written by Roy Prouty 20240318\\
 +Reviewed by