The centripetal acceleration is equal to velocity squared over radius. a=v^2/r
You've conflated your cause and your effect. The object's speed and the
curvature of its path are determined by the centripetal acceleration.
None of them depend directly on the other. However, centripetal acceleration can be calculated as a = v2/r.
The acceleration due to gravity does not depend on the mass. For example, if you have two objects, one of which has 10 times the mass of another, it will be attracted with 10 times the force; however, it will also have 10 times the inertia, so the acceleration will be the same.
Mass and Acceleration. Force = Mass x Acceleration
velocity and distance.
mass and acceleration.
Centripetal acceleration = V2/R = (4)2/(0.5) = 32 meters/sec2The centripetal acceleration doesn't depend on the stone's mass.(The centripetal force does.)The centripetal acceleration doesn't "act on" the stone.(The centripetal force does.)The centripetal force acting on the stone is F = M A = (0.25) (32) = 8 newtons.
None of them depend directly on the other. However, centripetal acceleration can be calculated as a = v2/r.
The acceleration due to gravity does not depend on the mass. For example, if you have two objects, one of which has 10 times the mass of another, it will be attracted with 10 times the force; however, it will also have 10 times the inertia, so the acceleration will be the same.
According to Newton's Second Law, the "effect" (the acceleration) would depend on the objects' masses. For more mass, there would be less acceleration.
Mass and Acceleration. Force = Mass x Acceleration
The acceleration due to gravity on earth doesn't depend on the mass of the falling object. All falling objects on the same planet fall with the same acceleration. On earth, the acceleration is 9.8 meters/sec2 .
Acceleration is change in velocity. So it depends on both velocity and time.
mass and acceleration.
velocity and distance.
The answer will depend on what elements of the circle are labelled.
The answer would depend on a 3-dimensional WHAT! It is not a 3-d circle, for example.The answer would depend on a 3-dimensional WHAT! It is not a 3-d circle, for example.The answer would depend on a 3-dimensional WHAT! It is not a 3-d circle, for example.The answer would depend on a 3-dimensional WHAT! It is not a 3-d circle, for example.
The mass of the objects and the distance between them.