Orbit phasing

Co-orbital Rendezvous
Co-orbital Rendezvous
	If the target (satellite) is behind the spacecraft (shuttle) in the same orbit, the spacecraft must speed up to enter a larger, slower phasing orbit to allow the target to catch up.

Phase Orbit
Phase Orbit
	If spacecraft is behind the final position on the same orbit, the spacecraft must slow down to enter a smaller, faster phasing orbit to catch up to final position.

Last updated April 05, 2023

In astrodynamics, orbit phasing is the adjustment of the time-position of spacecraft along its orbit, usually described as adjusting the orbiting spacecraft's true anomaly.^[1] Orbital phasing is primarily used in scenarios where a spacecraft in a given orbit must be moved to a different location within the same orbit. The change in position within the orbit is usually defined as the phase angle, ϕ, and is the change in true anomaly required between the spacecraft's current position to the final position.

t is defined as time elapsed to cover phase angle in original orbit
T₁ is defined as period of original orbit
E is defined as change of eccentric anomaly between spacecraft and final position
e₁ is defined as orbital eccentricity of original orbit
φ is defined as change in true anomaly between spacecraft and final position

This time derived from the phase angle is the required time the spacecraft must gain or lose to be located at the final position within the orbit. To gain or lose this time, the spacecraft must be subjected to a simple two-impulse Hohmann transfer which takes the spacecraft away from, and then back to, its original orbit. The first impulse to change the spacecraft's orbit is performed at a specific point in the original orbit (point of impulse, POI), usually performed in the original orbit's periapsis or apoapsis. The impulse creates a new orbit called the “phasing orbit” and is larger or smaller than the original orbit resulting in a different period time than the original orbit. The difference in period time between the original and phasing orbits will be equal to the time converted from the phase angle. Once one period of the phasing orbit is complete, the spacecraft will return to the POI and the spacecraft will once again be subjected to a second impulse, equal and opposite to the first impulse, to return it to the original orbit. When complete, the spacecraft will be in the targeted final position within the original orbit.

To find some of the phasing orbital parameters, first one must find the required period time of the phasing orbit using the following equation.

T_{2}=T_{1}-t

where

T₁ is defined as period of original orbit
T₂ is defined as period of phasing orbit
t is defined as time elapsed to cover phase angle in original orbit

Once phasing orbit period is determined, the phasing orbit semimajor axis can be derived from the period formula:^[3]

a_{2}=\left({\frac {{\sqrt {\mu }}T_{2}}{2\pi }}\right)^{2/3}

where

a₂ is defined as semimajor axis of phasing orbit
T₂ is defined as period of phasing orbit
μ is defined as Standard gravitational parameter

From the semimajor axis, the phase orbit apogee and perigee can be calculated:

2a_{2}=r_{a}+r_{p}

where

a₂ is defined as semimajor axis of phasing orbit
r_a is defined as apogee of phasing orbit
r_p is defined as perigee of phasing orbit

Finally, the phasing orbit's angular momentum can be found from the equation:

h_{2}={\sqrt {2\mu }}{\sqrt {\frac {r_{a}r_{p}}{r_{a}+r_{p}}}}

where

h₂ is defined as angular momentum of phasing orbit
r_a is defined as apogee of phasing orbit
r_p is defined as perigee of phasing orbit
μ is defined as Standard gravitational parameter

To find the impulse required to change the spacecraft from its original orbit to the phasing orbit, the change of spacecraft velocity, ∆V, at POI must be calculated from the angular momentum formula:

\Delta V=v_{2}-v_{1}={\frac {h_{2}}{r}}-{\frac {h_{1}}{r}}

where

∆V is change in velocity between phasing and original orbits at POI
v₁ is defined as the spacecraft velocity at POI in original orbit
v₂ is defined as the spacecraft velocity at POI in phasing orbit
r is defined as radius of spacecraft from the orbit’s focal point to POI
h₁ is defined as angular momentum of original orbit
h₂ is defined as angular momentum of phasing orbit

Remember that this change in velocity, ∆V, is only the amount required to change the spacecraft from its original orbit to the phasing orbit. A second change in velocity equal to the magnitude but opposite in direction of the first must be done after the spacecraft travels one phase orbit period to return the spacecraft from the phasing orbit to the original orbit. Total change of velocity required for the phasing maneuver is equal to two times ∆V.

Orbit phasing can also be referenced as co-orbital rendezvous ^[4] like a successful approach to a space station in a docking maneuver. Here, two spacecraft on the same orbit but at different true anomalies rendezvous by either one or both of the spacecraft entering phasing orbits which cause them to return to their original orbit at the same true anomaly at the same time.

Phasing maneuvers are also commonly employed by geosynchronous satellites, either to conduct station-keeping maneuvers to maintain their orbit above a specific longitude, or to change longitude altogether.

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In celestial mechanics, an orbit is the curved trajectory of an object such as the trajectory of a planet around a star, or of a natural satellite around a planet, or of an artificial satellite around an object or position in space such as a planet, moon, asteroid, or Lagrange point. Normally, orbit refers to a regularly repeating trajectory, although it may also refer to a non-repeating trajectory. To a close approximation, planets and satellites follow elliptic orbits, with the center of mass being orbited at a focal point of the ellipse, as described by Kepler's laws of planetary motion.

In astronautics, the Hohmann transfer orbit is an orbital maneuver used to transfer a spacecraft between two orbits of different altitudes around a central body. Examples would be used for travel between low Earth orbit and the Moon, or another solar planet or asteroid. In the idealized case, the initial and target orbits are both circular and coplanar. The maneuver is accomplished by placing the craft into an elliptical transfer orbit that is tangential to both the initial and target orbits. The maneuver uses two impulsive engine burns: the first establishes the transfer orbit, and the second adjusts the orbit to match the target.

<span class="mw-page-title-main">Orbital mechanics</span> Field of classical mechanics concerned with the motion of spacecraft

Orbital mechanics or astrodynamics is the application of ballistics and celestial mechanics to the practical problems concerning the motion of rockets and other spacecraft. The motion of these objects is usually calculated from Newton's laws of motion and the law of universal gravitation. Orbital mechanics is a core discipline within space-mission design and control.

In gravitationally bound systems, the orbital speed of an astronomical body or object is the speed at which it orbits around either the barycenter or, if one body is much more massive than the other bodies of the system combined, its speed relative to the center of mass of the most massive body.

In celestial mechanics, the mean anomaly is the fraction of an elliptical orbit's period that has elapsed since the orbiting body passed periapsis, expressed as an angle which can be used in calculating the position of that body in the classical two-body problem. It is the angular distance from the pericenter which a fictitious body would have if it moved in a circular orbit, with constant speed, in the same orbital period as the actual body in its elliptical orbit.

In spaceflight, an orbital maneuver is the use of propulsion systems to change the orbit of a spacecraft. For spacecraft far from Earth an orbital maneuver is called a deep-space maneuver (DSM).

Orbital inclination change is an orbital maneuver aimed at changing the inclination of an orbiting body's orbit. This maneuver is also known as an orbital plane change as the plane of the orbit is tipped. This maneuver requires a change in the orbital velocity vector (delta-v) at the orbital nodes.

<span class="mw-page-title-main">Parabolic trajectory</span> Type of orbit

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).

<span class="mw-page-title-main">Hyperbolic trajectory</span>

In astrodynamics or celestial mechanics, a hyperbolic trajectory or hyperbolic orbit is the trajectory of any object around a central body with more than enough speed to escape the central object's gravitational pull. The name derives from the fact that according to Newtonian theory such an orbit has the shape of a hyperbola. In more technical terms this can be expressed by the condition that the orbital eccentricity is greater than one.

In astrodynamics or celestial mechanics, an elliptic orbit or elliptical orbit is a Kepler orbit with an eccentricity of less than 1; this includes the special case of a circular orbit, with eccentricity equal to 0. In a stricter sense, it is a Kepler orbit with the eccentricity greater than 0 and less than 1. In a wider sense, it is a Kepler orbit with negative energy. This includes the radial elliptic orbit, with eccentricity equal to 1.

A circular orbit is an orbit with a fixed distance around the barycenter; that is, in the shape of a circle.

In celestial mechanics, the specific relative angular momentum of a body is the angular momentum of that body divided by its mass. In the case of two orbiting bodies it is the vector product of their relative position and relative linear momentum, divided by the mass of the body in question.

In the gravitational two-body problem, the specific orbital energy $of two orbiting bodies is the constant sum of their mutual potential energy and their total kinetic energy, divided by the reduced mass. According to the orbital energy conservation equation, it does not vary with time:$

In astrodynamics, an orbit equation defines the path of orbiting body $around central body relative to, without specifying position as a function of time. Under standard assumptions, a body moving under the influence of a force, directed to a central body, with a magnitude inversely proportional to the square of the distance, has an orbit that is a conic section with the central body located at one of the two foci, or the focus.$

In orbital mechanics, mean motion is the angular speed required for a body to complete one orbit, assuming constant speed in a circular orbit which completes in the same time as the variable speed, elliptical orbit of the actual body. The concept applies equally well to a small body revolving about a large, massive primary body or to two relatively same-sized bodies revolving about a common center of mass. While nominally a mean, and theoretically so in the case of two-body motion, in practice the mean motion is not typically an average over time for the orbits of real bodies, which only approximate the two-body assumption. It is rather the instantaneous value which satisfies the above conditions as calculated from the current gravitational and geometric circumstances of the body's constantly-changing, perturbed orbit.

Spacecraft flight dynamics is the application of mechanical dynamics to model how the external forces acting on a space vehicle or spacecraft determine its flight path. These forces are primarily of three types: propulsive force provided by the vehicle's engines; gravitational force exerted by the Earth and other celestial bodies; and aerodynamic lift and drag.

In astronautics and aerospace engineering, the bi-elliptic transfer is an orbital maneuver that moves a spacecraft from one orbit to another and may, in certain situations, require less delta-v than a Hohmann transfer maneuver.

Tisserand's criterion is used to determine whether or not an observed orbiting body, such as a comet or an asteroid, is the same as a previously observed orbiting body.

In general relativity, Lense–Thirring precession or the Lense–Thirring effect is a relativistic correction to the precession of a gyroscope near a large rotating mass such as the Earth. It is a gravitomagnetic frame-dragging effect. It is a prediction of general relativity consisting of secular precessions of the longitude of the ascending node and the argument of pericenter of a test particle freely orbiting a central spinning mass endowed with angular momentum $.$

In geometry, the major axis of an ellipse is its longest diameter: a line segment that runs through the center and both foci, with ends at the two most widely separated points of the perimeter. The semi-major axis is the longest semidiameter or one half of the major axis, and thus runs from the centre, through a focus, and to the perimeter. The semi-minor axis of an ellipse or hyperbola is a line segment that is at right angles with the semi-major axis and has one end at the center of the conic section. For the special case of a circle, the lengths of the semi-axes are both equal to the radius of the circle.

References

↑ "Orbital Mechanics". Archived from the original on 2013-12-16. Retrieved 2013-12-13.
↑ Curtis, Howard D (2014). Orbital Mechanics for Engineering Students (Third Edition). Butterworth-Heinemann. p. 312-316. ISBN 978-0-08-097747-8.
↑ Francis, Hale J (1994). Introduction To Space Flight. Prentice-Hall, Inc.. p. 33. ISBN 0-13-481912-8.
↑ Sellers, Jerry Jon (2005). Understanding Space An Introduction to Astronautics (Third Edition). McGraw-Hill. p. 213-214. ISBN 978-0-07-340775-3.

General

Curtis, Howard D (2014). Orbital Mechanics for Engineering Students (Third ed.). Butterworth-Heinemann. ISBN 978-0-08-097747-8.
Francis, Hale J (1994). Introduction To Space Flight. Prentice-Hall, Inc. ISBN 0-13-481912-8.
Sellers, Jerry Jon; Marion, Jerry B. (2005). Understanding Space An Introduction to Astronautics (Third ed.). McGraw-Hill. ISBN 978-0-07-340775-3.
Hall, Christopher D.; Collazo-Perez, Victor (November 2003). "Minimum-Time Orbital Phasing Maneuvers". Journal of Guidance, Control, and Dynamics. 26 (6). Retrieved January 2, 2023.
Phasing Maneuver

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[1] "Orbital Mechanics". Archived from the original on 2013-12-16. Retrieved 2013-12-13.

[2] Curtis, Howard D (2014). Orbital Mechanics for Engineering Students (Third Edition). Butterworth-Heinemann. p. 312-316. ISBN 978-0-08-097747-8.

[3] Francis, Hale J (1994). Introduction To Space Flight. Prentice-Hall, Inc.. p. 33. ISBN 0-13-481912-8.

[4] Sellers, Jerry Jon (2005). Understanding Space An Introduction to Astronautics (Third Edition). McGraw-Hill. p. 213-214. ISBN 978-0-07-340775-3.

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Orbit phasing

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References

General