Equations derived from spherical trigonometry allow for the conversion from equatorial coordinates to ecliptic coordinates. As points in the ecliptic have no latitude (β=0º) and the East point of the horizon has a right ascension 6^h higher than that of the meridian (or 90º more in hour angle), the equation that determines East Point's longitude can be written as:

${\displaystyle \tan \lambda }$ _EP${\displaystyle ={\tan(\theta _{\rm {L}}+90^{\circ }) \over \cos \varepsilon }\Leftrightarrow \lambda }$ _EP${\displaystyle =\arctan \left({-1 \over \tan(\theta _{\rm {L}})\cos \varepsilon }\right)}$ 

where ${\displaystyle \theta _{\rm {L}}}$  is the local sidereal time and ${\displaystyle \varepsilon }$  is the obliquity of the ecliptic.^[1] The equation can also be derived from the Ascendant at the equator (${\displaystyle \phi }$ =0º).

• Angles in the degrees ( ° ), minutes ( ' ), and seconds ( " ) of sexagesimal measure must be converted to decimal before calculations are performed. Whether they are converted to decimal degrees or radians depends upon the particular calculating machine or program.
• Angles in the hours ( ^h ), minutes ( ^m ), and seconds ( ^s ) of time measure must be converted to decimal degrees or radians before calculations are performed.     (1^h = 15°     1^m = 15'     1^s = 15")
• Angles greater than 360° (2π) or less than 0° may need to be reduced to the range 0° - 360° (0 - 2π) depending upon the particular calculating machine or program.
• When L.S.T. is 0^h 0^m 0^s (${\displaystyle \theta _{\rm {L}}}$ =0º), East Point's longitude is 90º.
• Inverse trigonometric functions are quadrant-ambiguous, and results should be carefully evaluated by taking into account that λ_EP is roughly 90º more than λ_MC.
• For the past 5 million years, Earth's obliquity has varied between 22.042500° and 24.50444°.^[2] The effect on λ_EP is less than 0.53°. For values referred to the standard equinox J2000.0 use 23.4392911°; for J1950.0 use 23.4457889°.

• Ascendant (astrology)
• Accidental Ascendant