The exact relationship is given by Newton's law of universal gravitation: F=G*m1*m2/R**2, where G is a constant that applies to all matter; m1 and m2 are the masses of the two attracting bodies, respectively; and R is the separation between their centers of gravity.
In the case of mechanical energy, work = force x distance.
In the case of mechanical energy, work = force x distance.
In the case of mechanical energy, work = force x distance.
In the case of mechanical energy, work = force x distance.
Work = force x distance traveled (only when the force and distance are acting in the same direction)
f=m*a+dp/dt
meaning where f is force and m is mass a is acceleration dp is change in momentum and dt is change in time
In the case of mechanical energy, work = force x distance.
Work = (force) multiplied by (distance)
Mass
Gravitational force depends on distance and mass. Thus, the formula for calculating gravitational force between 2 objects with a given distance: G[(mass 1)(mass 2)]/distance squared. G is universal gravitational constant: 6.67x10 raised to -11 power. Sorry if it's a little confusing to read...since I can't do basic math operations here.
It is true that the force of gravity can be described as a force field. Any object having mass will create a gravitational attraction in all directions, with decreasing intensity as the distance from the object increases. Fields are like that. It is different from a force that results from being hit by a baseball, which is exerted only at a specific location.
Where f = the gravitational force, G = the gravitational constant, m1 = the mass of the first body, m2 = the mass of the second body and d = the distance (note: sometimes r is used for radius) between the centres of gravity of the two bodies:f = (Gm1m2) / d2
Force of gravity, Fg, is directly proportional to the product of the masses of the two interacting objects and inversely proportional to the square of the distance between them. Fg = Gm1m2/r2 Therefore, when either of the masses increase, Fg increases proportionally.
The gravitation attraction force between two point masses is directly proportional to the product of their masses and inversely proportional to the square of their separation distance.
More mass --> more gravitational force Greater distance --> less gravitational force
The gravitational force varies directly as the mass and inversely as the square of the distance.
Gravitational force F = mass x g where g is the gravitational acceleration.
mass and distance form an inverse relationship when related to gravity. The larger the mass(es) the greater the gravitational pull. The closer the distance, the greater the gravitational pull.
The greater the mass the more gravitational force an object has, the greater distance, say from the ground the greater potential energy, the greater gravitational force. hope that helps :]
Gravitational force is dependent on mass and distance.
Mass and distance of separation.
F = GmM/r2
If you increase the mass, you increase the gravitational force proportionally. If you increase the distance between two masses, you decrease the gravitational force between them by and amount proportional to the square of the distance.
Distance.
Gravitational force is a force that acts between any objects that have mass. It is proportional to both masses, and inversely proportional to the square of the distance. In other words, greater mass means more gravitational force, greater distance means less gravitational force.