Difference between revisions of "Specific energy"
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− | In [[orbital mechanics]], '''specific energy''' (symbol <math>\epsilon</math>) is the total orbital energy per unit mass of an orbiting body. | + | In [[orbital mechanics]], '''specific energy''' (symbol <math>\epsilon</math>) is the total orbital energy per unit mass of an orbiting body. It is the sum of the kinetic energy and the gravitational potential energy. |
==Circular and elliptical orbits<ref name="SME">J.R. Wertz, D.F. Everett & J.J. Puschell - ''Space mission engineering: The new SMAD''. 2011. pp. 963-970. ISBN 978-1-881883-15-9</ref>== | ==Circular and elliptical orbits<ref name="SME">J.R. Wertz, D.F. Everett & J.J. Puschell - ''Space mission engineering: The new SMAD''. 2011. pp. 963-970. ISBN 978-1-881883-15-9</ref>== | ||
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where <math>a < 0</math> is the [[semi-transverse axis]], <math>\mu</math> is the [[gravitational parameter]] for the body being orbited, <math>r</math> is distance to the body being orbited at some point in time and <math>V</math> is velocity at that time. | where <math>a < 0</math> is the [[semi-transverse axis]], <math>\mu</math> is the [[gravitational parameter]] for the body being orbited, <math>r</math> is distance to the body being orbited at some point in time and <math>V</math> is velocity at that time. | ||
− | ==Mars orbit== | + | ==Mars circular orbit== |
− | + | For Mars, with <math>\mu</math>= 4.280×10<sup>13</sup> m<sup>3</sup>/s<sup>2</sup>, then for a 1 kg mass at 300 km E= | |
− | ==Earth | + | ==Earth circular orbit== |
+ | For Mars, with <math>\mu</math>= 3.986×10<sup>14</sup> m<sup>3</sup>/s<sup>2</sup>, then for a 1 kg mass at 300 km E= | ||
==References== | ==References== |
Latest revision as of 10:50, 26 June 2023
In orbital mechanics, specific energy (symbol ) is the total orbital energy per unit mass of an orbiting body. It is the sum of the kinetic energy and the gravitational potential energy.
Contents
Circular and elliptical orbits[1]
where is the semi-major axis, is the gravitational parameter for the body being orbited, is the distance to the body being orbited at some point in time and is velocity at that time. This relationship comes about because is the kinetic energy and the potential energy of the system.
Parabolic orbits[1]
Since orbital mechanics only concerns itself with changes in orbital energy, the zero could be chosen arbitrarily. It is computationally most convenient to choose the value at escape velocity (i.e. parabolic orbit). This choice makes the semi-major axis inversely proportional to the specific energy and if the mass does not change also to the total orbital energy.
Hyperbolic orbits[1]
where is the semi-transverse axis, is the gravitational parameter for the body being orbited, is distance to the body being orbited at some point in time and is velocity at that time.
Mars circular orbit
For Mars, with = 4.280×1013 m3/s2, then for a 1 kg mass at 300 km E=
Earth circular orbit
For Mars, with = 3.986×1014 m3/s2, then for a 1 kg mass at 300 km E=