Acceleration due to gravity: Difference between revisions
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Considering a body with the mass ''M'' as a source of a gravitational field, the strength of that field, or the | Considering a body with the mass ''M'' as a source of a gravitational field, the strength of that field, or the | ||
gravitational acceleration, is given by | gravitational acceleration, is given by <math>\vec g = -G \frac{M}{r^2} \frac{\dot{r}}{r}</math>. | ||
The modulus of ''g'' is <math>g = G \frac{M}{r^2}</math>. | |||
Here ''G'' is the gravitational constant, ''G'' = 6.67428×10<sup>-11</sup> Nm<sup>2</sup>/kg<sup>2</sup>, ''r'' is the distance between a body of mass ''m'' and the center of the gravitational field, <math>\vec r</math> is the vector radius of that body having the mass ''m''. | |||
If the source of the gravitational field has a spherical shape, then ''r'' is the sphere’s radius. Taking into | |||
account that the Earth is an oblate spheroid, the distance ''r'' is not that of a sphere and varies from the | |||
Here G is the gravitational constant, G = 6.67428 | |||
mass m and the center of the gravitational field, r is the vector radius of that body having the mass m. | |||
If the source of the gravitational field has a spherical shape, then r is the sphere’s radius. Taking into | |||
account that the Earth is an oblate spheroid, the distance r is not that of a sphere and varies from the | |||
equator to the poles. | equator to the poles. | ||
A normal section (on the equatorial plane) is almost an ellipse, so, ''r'' can be done by: | |||
<math>r = \sqrt{{r_e}^2 cos^2 \theta + {r_p}^2 sin^2 \theta}</math> | |||
where ''r<sub>e</sub>'' and ''r<sub>p</sub>'' are the equatorial radius and polar radius, respectively and ''θ'' is the latitude, or | |||
A normal section (on the equatorial plane) is almost an ellipse, so, r can be done by: | the angle made by ''r'' with the equatorial plane. | ||
where r e and r p are the equatorial radius and polar radius, respectively and θ is the latitude, or | |||
the angle made by r with the equatorial plane. | |||
References | References | ||
1. V.Dorobantu and Simona Pretorian, Physics between fear and respect, Vol. 3, Edited by Politehnica | 1. V.Dorobantu and Simona Pretorian, Physics between fear and respect, Vol. 3, Edited by Politehnica | ||
Timisoara, 2007, ISBN 978-973-625-493-2 | Timisoara, 2007, ISBN 978-973-625-493-2 | ||
Revision as of 21:11, 23 February 2008
Considering a body with the mass M as a source of a gravitational field, the strength of that field, or the gravitational acceleration, is given by . The modulus of g is .
Here G is the gravitational constant, G = 6.67428×10-11 Nm2/kg2, r is the distance between a body of mass m and the center of the gravitational field, is the vector radius of that body having the mass m. If the source of the gravitational field has a spherical shape, then r is the sphere’s radius. Taking into account that the Earth is an oblate spheroid, the distance r is not that of a sphere and varies from the equator to the poles. A normal section (on the equatorial plane) is almost an ellipse, so, r can be done by:
where re and rp are the equatorial radius and polar radius, respectively and θ is the latitude, or
the angle made by r with the equatorial plane.
References
1. V.Dorobantu and Simona Pretorian, Physics between fear and respect, Vol. 3, Edited by Politehnica
Timisoara, 2007, ISBN 978-973-625-493-2