Jump to content

Main menu Navigation ●Main page ●Contents ●Current events ●Random article ●About Wikipedia ●Contact us ●Donate Contribute ●Help ●Learn to edit ●Community portal ●Recent changes ●Upload file

●Create account ●Log in ●Create account ● Log in Pages for logged out editors learn more ●Contributions ●Talk

(Top) 1 Non-escape trajectory 2 Parabolic trajectory 3 Hyperbolic trajectory 4 Examples 5 See also 6 References 7 Footnotes

Characteristic energy

●العربية ●Italiano ●Slovenčina ●Slovenščina Edit links ●Article ●Talk ●Read ●Edit ●View history Tools Actions ●Read ●Edit ●View history General ●What links here ●Related changes ●Upload file ●Special pages ●Permanent link ●Page information ●Cite this page ●Get shortened URL ●Download QR code ●Wikidata item Print/export ●Download as PDF ●Printable version Appearance From Wikipedia, the free encyclopedia

Inastrodynamics, the characteristic energy ( $C_{3}$ ) is a measure of the excess specific energy over that required to just barely escape from a massive body. The units are length² time⁻², i.e. velocity squared, or energy per mass.

Every object in a 2-body ballistic trajectory has a constant specific orbital energy $\epsilon$ equal to the sum of its specific kinetic and specific potential energy:

\epsilon ={\frac {1}{2}}v^{2}-{\frac {\mu }{r}}={\text{constant}}={\frac {1}{2}}C_{3},

\epsilon ={\frac {1}{2}}v^{2}-{\frac {\mu }{r}}={\text{constant}}={\frac {1}{2}}C_{3},

where

\mu =GM

is the standard gravitational parameter of the massive body with mass

M

, and

r

is the radial distance from its center. As an object in an escape trajectory moves outward, its kinetic energy decreases as its potential energy (which is always negative) increases, maintaining a constant sum.

Note that C₃istwice the specific orbital energy $\epsilon$ of the escaping object.

Non-escape trajectory[edit]

A spacecraft with insufficient energy to escape will remain in a closed orbit (unless it intersects the central body), with

C_{3}=-{\frac {\mu }{a}}<0

C_{3}=-{\frac {\mu }{a}}<0

where

$\mu =GM$ is the standard gravitational parameter,
$a$ is the semi-major axis of the orbit's ellipse.

If the orbit is circular, of radius r, then

C_{3}=-{\frac {\mu }{r}}

C_{3}=-{\frac {\mu }{r}}

Parabolic trajectory[edit]

A spacecraft leaving the central body on a parabolic trajectory has exactly the energy needed to escape and no more:

C_{3}=0

C_{3}=0

Hyperbolic trajectory[edit]

A spacecraft that is leaving the central body on a hyperbolic trajectory has more than enough energy to escape:

C_{3}={\frac {\mu }{|a|}}>0

C_{3}={\frac {\mu }{|a|}}>0

where

$\mu =GM$ is the standard gravitational parameter,
$a$ is the semi-major axis of the orbit's hyperbola (which may be negative in some convention).

Also,

C_{3}=v_{\infty }^{2}

C_{3}=v_{\infty }^{2}

where

v_{\infty }

is the asymptotic velocity at infinite distance. Spacecraft's velocity approaches

v_{\infty }

as it is further away from the central object's gravity.

Examples[edit]

MAVEN, a Mars-bound spacecraft, was launched into a trajectory with a characteristic energy of 12.2 km²/s² with respect to the Earth.^[1] When simplified to a two-body problem, this would mean the MAVEN escaped Earth on a hyperbolic trajectory slowly decreasing its speed towards ${\sqrt {12.2}}{\text{ km/s}}=3.5{\text{ km/s}}$ . However, since the Sun's gravitational field is much stronger than Earth's, the two-body solution is insufficient. The characteristic energy with respect to Sun was negative, and MAVEN – instead of heading to infinity – entered an elliptical orbit around the Sun. But the maximal velocity on the new orbit could be approximated to 33.5 km/s by assuming that it reached practical "infinity" at 3.5 km/s and that such Earth-bound "infinity" also moves with Earth's orbital velocity of about 30 km/s.

The InSight mission to Mars launched with a C₃ of 8.19 km²/s².^[2] The Parker Solar Probe (via Venus) plans a maximum C₃ of 154 km²/s².^[3]

Typical ballistic C₃ (km²/s²) to get from Earth to various planets: Mars 8-16,^[4] Jupiter 80, Saturn or Uranus 147.^[5] To Pluto (with its orbital inclination) needs about 160–164 km²/s².^[6]

References[edit]

Wie, Bong (1998). "Orbital Dynamics". Space Vehicle Dynamics and Control. AIAA Education Series. Reston, Virginia: American Institute of Aeronautics and Astronautics. ISBN 1-56347-261-9.

Footnotes[edit]

^ Atlas V set to launch MAVEN on Mars mission, nasaspaceflight.com, 17 November 2013.

^ ULA (2018). "InSight Launch Booklet" (PDF).

^ JHUAPL. "Parker Solar Probe: The Mission". parkersolarprobe.jhuapl.edu. Retrieved 2018-07-22.

^ Delta-Vs and Design Reference Mission Scenarios for Mars Missions

^ NASA studies for Europa Clipper mission

^ New Horizons Mission Design

Gravitational orbits

Types

General

Geocentric

About
other points

Parameters

Shape Size	$e$ Eccentricity $a$ Semi-major axis $b$ Semi-minor axis $Q$ , $q$ Apsides
Orientation	$i$ Inclination $Ω$ Longitude of the ascending node $ω$ Argument of periapsis $ϖ$ Longitude of the periapsis
Position	$M$ Mean anomaly $ν$ , $θ$ , $f$ True anomaly $E$ Eccentric anomaly $L$ Mean longitude $l$ True longitude
Variation	$T$ Orbital period $n$ Mean motion $v$ Orbital speed $t 0$ Epoch

Maneuvers

Orbital
mechanics

List of orbits

Retrieved from "https://en.wikipedia.org/w/index.php?title=Characteristic_energy&oldid=1192195838" Categories: ●Astrodynamics ●Orbits ●Energy (physics) ●This page was last edited on 28 December 2023, at 03:54 (UTC). ●Text is available under the Creative Commons Attribution-ShareAlike License 4.0; additional terms may apply. By using this site, you agree to the Terms of Use and Privacy Policy. Wikipedia® is a registered trademark of the Wikimedia Foundation, Inc., a non-profit organization. ●Privacy policy ●About Wikipedia ●Disclaimers ●Contact Wikipedia ●Code of Conduct ●Developers ●Statistics ●Cookie statement ●Mobile view