Acceleration due to gravity: Difference between revisions

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imported>'Dragon' Dave McKee
m (New page: 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: r...)
 
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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>.  
                                  r
The modulus of ''g'' is <math>g = G \frac{M}{r^2}</math>.
                      r      Mr                                    M
 
                      g = G 2 . The modulus of g is g = G 2
Here ''G'' is the gravitational constant, ''G'' = 6.67428&times;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''.
                                  r
If the source of the gravitational field has a spherical shape, then ''r'' is the sphere’s radius. Taking into
                              r                                    r
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 * 10 11 N m 2 / kg 2 , r is the distance between a body of
                                                    r
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.
                                rp
A normal section (on the equatorial plane) is almost an ellipse, so, ''r'' can be done by:
                                              x              m
 
                                                r
<math>r = \sqrt{{r_e}^2 cos^2 \theta + {r_p}^2 sin^2 \theta}</math>
                                                            y
 
                                          q
 
                                O                    re
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.
                  r = re2 cos2 θ + rp2 sin2 θ
 
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 20:11, 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