Not at all. The mutual gravitational force that attracts the satellite and the earth toward
each other is exactly what keeps the satellite in orbit. Without it, the satellite would just
take off in a straight line away from the vicinity of the earth.
Yes it is. Two different forces act on the satellite to keep it in orbit. Without either, the concept of satellites would never have worked out. Firstly, there is the gravitational pull of the planet to keep it from floating away. Without it, the satellite will simply float away from the target planet. Secondly, there is the centripetal force as a result of a satellite's continuous orbit. It continually pushes the satellite outward as it orbits the planet. Without it, the satellite will be pulled by the gravitational pull of the planet and crash back into the planet. Thus both forces work in tandem to ensure the survival of satellites.
The gravitational pull is causing the satellite to orbit around because the pull is the same all the way around. If it ever managed to leave the gravitational pull, it would just wander pretty aimlessly and even then it would go in a straight line. Hope this helps! Comment: In more "scientific" words : 1. The satellite has a velocity that is along the line of its orbit ( in other words "tangential" to the orbit, at any instant). 2. The planet, that the satellite orbits, is trying to pull the satellite in the direction of the planet. 3. The combination of these things results in the curved path. The satellite is constantly being diverted from its direction at a tangent to the orbit by gravity.
Gravitational Pull.
Satellites A (APEX)
Tides are caused by the gravitational pull of the moon.
The gravitational pull of the earth causes a bulge on the opposite side of the moon. The gravitational pull of the earth is greater than the gravitational pull of the sun.
Earth's gravitational pull
A Satellite is any object that orbits another object that has a stronger gravitational pull. For example, the Moon is the Earth's natural satellite. Mars has several, as do Saturn and Jupiter. All of the planets, including Earth, are satellite bodies of the Sun (Sol), since they all orbit the Sun, which has a much stronger gravitational pull.
determining its mass from its gravitational pull on a spacecraft, satellite, or planet.
A satellite needs fuel to keep moving because when it's in space there is no air resistance and the gravitational pull and friction won't effect it.
The gravitational pull is causing the satellite to orbit around because the pull is the same all the way around. If it ever managed to leave the gravitational pull, it would just wander pretty aimlessly and even then it would go in a straight line. Hope this helps! Comment: In more "scientific" words : 1. The satellite has a velocity that is along the line of its orbit ( in other words "tangential" to the orbit, at any instant). 2. The planet, that the satellite orbits, is trying to pull the satellite in the direction of the planet. 3. The combination of these things results in the curved path. The satellite is constantly being diverted from its direction at a tangent to the orbit by gravity.
More massive planets have more gravitational pull. If a satellite were to pass by Earth and Jupiter at the same distance from each planet, the satellite would be more attracted to start orbiting Jupiter because of its pull. The more massive a planet is the more likely it is to get a satellite to orbit it.
Gravitational Pull.
No. "Pull" is a force, not an acceleration.
A satellite will orbit due to a gravitational field, which is formed by the gravitational force between the satellite and stellar body. This force is equal to the product of the gravitational constant, and the masses of both objects divided by the square of the distance separating them.
All materials with mass exert a gravitational pull.
All obects have a gravitational pull. The larger it is, the stronger the pull.
The reason that satellites stay in orbit around Earth is because of two factors. Velocity and the gravitational pull between the satellite and the Earth.