Nodal precession

Description

A non-rotating body of planetary scale or larger would be pulled by gravity into a sphere. Virtually all bodies rotate, however. The centrifugal force deforms the body so that it has an equatorial bulge. Because of the bulge the gravitational force on the satellite is not directly toward the center of the central body, but is offset toward the equator. Whichever hemisphere the satellite is in it is preferentially pulled slightly toward the equator. This creates a torque on the orbit. This torque does not reduce the inclination; rather, it causes a torque-induced gyroscopic precession, which causes the orbital nodes to drift with time.

Equation

The rate of precession depends on the inclination of the orbital plane to the equatorial plane, as well as the orbital eccentricity.

For a satellite in a prograde orbit around Earth, the precession is westward (nodal regression), the node and satellite move in opposite directions. A good approximation of the precession rate is

ω p = − 3 2 R E 2 ( a ( 1 − e 2 ) ) 2 J 2 ω cos ⁡ i

where

ω p is the precession rate (rad/s) R E is the body's equatorial radius (6 378.137 km for Earth) a is the semi-major axis of the satellite orbit e is the eccentricity of the satellite orbit ω is its angular frequency of the satellite's motion ( 2 π radians divided by its period) i its inclination J 2 is the body's second dynamic form factor ( − 5 C 20 = 1.08262668 × 10 − 3 for Earth.)

This last quantity is related to the oblateness as follows:

J 2 = 2 ε E 3 − R E 3 ω E 2 3 G M E

where

ε E is the central body's oblateness R E is central body's equatorial radius ω E is the central body's rotation rate (7.292115×10⁻⁵ rad/s for Earth) G M E is the product of the universal constant of gravitation and the central body's mass (3.986004418×10¹⁴ m³/s² for Earth.)

The nodal progression of low Earth orbits is typically a few degrees per day to the west (negative). For a satellite in a circular 800 km altitude orbit at 56° inclination about Earth

R E = 6.378137 × 10 6 m J 2 = 1.08262668 × 10 − 3

The orbital period is 6052.4 s, so the angular velocity is 0.001038 rad/s. The precession is therefore

ω p = − 3 2 6378137 2 ( 7178137 ( 1 − 0 2 ) ) 2   1.08262668 × 10 − 3   0.001038   cos ⁡ 56 ∘ ω p = − 7.44 × 10 − 7   r a d / s

This is equivalent to -3.683 degrees/day, so the orbit plane will make one complete turn (in inertial space) in 98 days.

The apparent motion of the sun is approximately +1° per day (360° per year / 365.2422 days per tropical year ≈ 0.9856473° per day), so apparent motion of the sun relative to the orbit plane is about 2.8° per day, resulting in a complete cycle in about 127 days. For retrograde orbits ω is negative, so the precession becomes positive. (Alternatively, ω can be thought of as positive but the inclination is greater than 90°, so the cosine of the inclination is negative.) In this case it is possible to make the precession approximately match the apparent motion of the sun, resulting in a sun-synchronous orbit.