Parabolic trajectory

In astrodynamics or celestial mechanics a parabolic trajectory is a Kepler orbit with the eccentricity equal to 1 and is an unbound orbit that is exactly on the border between elliptical and hyperbolic. When moving away from the source it is called an escape orbit, otherwise a capture orbit. It is also sometimes referred to as a C₃ = 0 orbit (see Characteristic energy).

Under standard assumptions a body traveling along an escape orbit will coast along a parabolic trajectory to infinity, with velocity relative to the central body tending to zero, and therefore will never return. Parabolic trajectories are minimum-energy escape trajectories, separating positive-energy hyperbolic trajectories from negative-energy elliptic orbits.

Velocity

The orbital velocity ( $v$ ) of a body travelling along a parabolic trajectory can be computed as:

v={\sqrt {2\mu  \over r}}

where:

$r$ is the radial distance of the orbiting body from the central body,
$\mu$ is the standard gravitational parameter.

At any position the orbiting body has the escape velocity for that position.

If a body has an escape velocity with respect to the Earth, this is not enough to escape the Solar System, so near the Earth the orbit resembles a parabola, but further away it bends into an elliptical orbit around the Sun.

This velocity ( $v$ ) is closely related to the orbital velocity of a body in a circular orbit of the radius equal to the radial position of orbiting body on the parabolic trajectory:

v={\sqrt {2}}\,v_{o}

where:

$v_{o}$ is orbital velocity of a body in circular orbit.

Equation of motion

For a body moving along this kind of trajectory the orbital equation is:

r={h^{2} \over \mu }{1 \over {1+\cos \nu }}

where:

$r\,$ is the radial distance of the orbiting body from the central body,
$h\,$ is the specific angular momentum of the orbiting body,
$\nu \,$ is the true anomaly of the orbiting body,
$\mu \,$ is the standard gravitational parameter.

Energy

Under standard assumptions, the specific orbital energy ( $\epsilon$ ) of a parabolic trajectory is zero, so the orbital energy conservation equation for this trajectory takes the form:

\epsilon ={v^{2} \over 2}-{\mu  \over r}=0

where:

$v\,$ is the orbital velocity of the orbiting body,
$r\,$ is the radial distance of the orbiting body from the central body,
$\mu \,$ is the standard gravitational parameter.

This is entirely equivalent to the characteristic energy (square of the speed at infinity) being 0:

C_{3}=0

Barker's equation

Barker's equation relates the time of flight $t$ to the true anomaly $\nu$ of a parabolic trajectory:^[1]

t-T={\frac {1}{2}}{\sqrt {\frac {p^{3}}{\mu }}}\left(D+{\frac {1}{3}}D^{3}\right)

where:

$D=\tan {\frac {\nu }{2}}$ is an auxiliary variable
$T$ is the time of periapsis passage
$\mu$ is the standard gravitational parameter
$p$ is the semi-latus rectum of the trajectory ( $p=h^{2}/\mu$ )

More generally, the time (epoch) between any two points on an orbit is

t_{f}-t_{0}={\frac {1}{2}}{\sqrt {\frac {p^{3}}{\mu }}}\left(D_{f}+{\frac {1}{3}}D_{f}^{3}-D_{0}-{\frac {1}{3}}D_{0}^{3}\right)

Alternately, the equation can be expressed in terms of periapsis distance, in a parabolic orbit $r_{p}=p/2$ :

t-T={\sqrt {\frac {2r_{p}^{3}}{\mu }}}\left(D+{\frac {1}{3}}D^{3}\right)

Unlike Kepler's equation, which is used to solve for true anomalies in elliptical and hyperbolic trajectories, the true anomaly in Barker's equation can be solved directly for $t$ . If the following substitutions are made

{\begin{aligned}A&={\frac {3}{2}}{\sqrt {\frac {\mu }{2r_{p}^{3}}}}(t-T)\\[3pt]B&={\sqrt[{3}]{A+{\sqrt {A^{2}+1}}}}\end{aligned}}

then

\nu =2\arctan \left(B-{\frac {1}{B}}\right)

With hyperbolic functions the solution can be also expressed as:^[2]

\nu =2\arctan \left(2\sinh {\frac {\mathrm {arcsinh} {\frac {3M}{2}}}{3}}\right)

where

M={\sqrt {\frac {\mu }{2r_{p}^{3}}}}(t-T)

Radial parabolic trajectory

A radial parabolic trajectory is a non-periodic trajectory on a straight line where the relative velocity of the two objects is always the escape velocity. There are two cases: the bodies move away from each other or towards each other.

There is a rather simple expression for the position as function of time:

r={\sqrt[{3}]{{\frac {9}{2}}\mu t^{2}}}

where

μ is the standard gravitational parameter
$t=0\!\,$ corresponds to the extrapolated time of the fictitious starting or ending at the center of the central body.

At any time the average speed from $t=0\!\,$ is 1.5 times the current speed, i.e. 1.5 times the local escape velocity.

To have $t=0\!\,$ at the surface, apply a time shift; for the Earth (and any other spherically symmetric body with the same average density) as central body this time shift is 6 minutes and 20 seconds; seven of these periods later the height above the surface is three times the radius, etc.

References

^ Bate, Roger; Mueller, Donald; White, Jerry (1971). Fundamentals of Astrodynamics. Dover Publications, Inc., New York. ISBN 0-486-60061-0. p 188
^ Zechmeister, Mathias (2020). "Solving Kepler's equation with CORDIC double iterations". MNRAS. 500 (1): 109–117. arXiv:2008.02894. Bibcode:2021MNRAS.500..109Z. doi:10.1093/mnras/staa2441. Eq.(40) and Appendix C.

[1] Bate, Roger; Mueller, Donald; White, Jerry (1971). Fundamentals of Astrodynamics. Dover Publications, Inc., New York. ISBN 0-486-60061-0. p 188

[2] Zechmeister, Mathias (2020). "Solving Kepler's equation with CORDIC double iterations". MNRAS. 500 (1): 109–117. arXiv:2008.02894. Bibcode:2021MNRAS.500..109Z. doi:10.1093/mnras/staa2441. Eq.(40) and Appendix C.

[1]

[2]

Parabolic trajectory

Velocity

Equation of motion

Energy

Barker's equation

Radial parabolic trajectory

See also

References