They are not.
Gravitation is a force and forces (if they can overcome friction) will cause accceleration. The two are not the same.
And what is the question?If you want to figure out the mass of the planet: First, use the formula for centripetal acceleration to get the acceleration. Then, use the gravitation formula to calculate the mass required to produce that acceleration.And what is the question?If you want to figure out the mass of the planet: First, use the formula for centripetal acceleration to get the acceleration. Then, use the gravitation formula to calculate the mass required to produce that acceleration.And what is the question?If you want to figure out the mass of the planet: First, use the formula for centripetal acceleration to get the acceleration. Then, use the gravitation formula to calculate the mass required to produce that acceleration.And what is the question?If you want to figure out the mass of the planet: First, use the formula for centripetal acceleration to get the acceleration. Then, use the gravitation formula to calculate the mass required to produce that acceleration.
Gravitation can be expressed as either an acceleration or a force per unit mass.[Acceleration] = [Length/Time2][Force per unit mass] = [mass-length/Time2] per [mass] = [length/time2]
Same as anywhere else. You can use the formula F = ma (force equals mass times acceleration) and solve for acceleration (a = F/m). Force might be gravitation, in specific cases - or the thrust from the rocket engine. Of course, SOME data must be known to figure out acceleration.Same as anywhere else. You can use the formula F = ma (force equals mass times acceleration) and solve for acceleration (a = F/m). Force might be gravitation, in specific cases - or the thrust from the rocket engine. Of course, SOME data must be known to figure out acceleration.Same as anywhere else. You can use the formula F = ma (force equals mass times acceleration) and solve for acceleration (a = F/m). Force might be gravitation, in specific cases - or the thrust from the rocket engine. Of course, SOME data must be known to figure out acceleration.Same as anywhere else. You can use the formula F = ma (force equals mass times acceleration) and solve for acceleration (a = F/m). Force might be gravitation, in specific cases - or the thrust from the rocket engine. Of course, SOME data must be known to figure out acceleration.
Gravitation acts as a force on all kinds of objects, pulling them down. According to Newton's Second Law of motion, this causes an acceleration (assuming other forces can be ignored).Gravitation acts as a force on all kinds of objects, pulling them down. According to Newton's Second Law of motion, this causes an acceleration (assuming other forces can be ignored).Gravitation acts as a force on all kinds of objects, pulling them down. According to Newton's Second Law of motion, this causes an acceleration (assuming other forces can be ignored).Gravitation acts as a force on all kinds of objects, pulling them down. According to Newton's Second Law of motion, this causes an acceleration (assuming other forces can be ignored).
I don't quite understand why you mix "gravitation" and "weightless" in the question. The gravitational acceleration of Earth is 9.8 m/sec2 near the surface; further away, it will gradually decrease. The presence of air - if that is what you referring to - is quite irrelevant to the fact that there is gravitation.
Acceleration is directly proportional to the net force. Net force is equal to the mass times acceleration, taking this into consideration we can clearly see that acceleration is inversely proportional to mass.By Armah Ishmael Ryesa
Yes. It is an adjective meaning "of, relating to, or involving gravitation." It is used terms such as "gravitational acceleration" and "gravitational lensing."
"One g" is a term used to compare the effect of an acceleration, or gravitation, with Earth's gravitation. On Earth, gravitation produces an acceleration of 9.8 m/sec2; so that amount of acceleration is 1 G; 2 x 9.8 meters per second square is 2 G, etc. Meters per second square are the standard SI unit, so they are easier to deal with in formulae, but if you get a result in meter per second square, it is often converted to "G", to make it easier to visualize, especially in non-technical writing (like in science fiction).
The universal gravitational constant, which appears in Newton's Law of Universal Gravitation, can be used to calculate the gravitational attraction between any two masses, anywhere in the universe, not just here on Earth. Whereas the acceleration of gravity, g, is the specific acceleration caused by the planet Earth, at its surface where we live.
The weight is simply the mass multiplied by the gravitation. If the mass is in kg. and the gravitation is in meters per square second, the weight is in Newton.
Acceleration due to gravity is due to the force of gravitation exerted on a body by the earth. All bodies get attracted towards the centre of the earth. So the acceleration is always pointed vertically downwards.
That is because Earth attracts objects with a certain force (through gravitation). If the gravitational force were more, the acceleration would be more. If the gravitational force were less, the acceleration would also be less.