Yes, it determines the motion and state the object is in.
The centre of gravity does not, by itself, determine whether an object is at rest or in motion. The location of the centre of gravity, relative to where the object is supported, can contribute one of many forces that can act on the object. And it is is the [vector] sum of these forces which determines whether the object remains at rest or in uniform motion.
the net force which is the vector sum of the forces. If that sum = 0 then no motion occurs
The total vector force on an object determines the change in its velocity. That change is also known as acceleration.
The equation is F = M A, where F is the Force required to stop the object, M is the object's Mass, and A is its Acceleration. Note that its acceleration in this case is the rate at which you are DE-ACCELERATING the object to stop it.
Yes, it determines the motion and state the object is in.
The centre of gravity does not, by itself, determine whether an object is at rest or in motion. The location of the centre of gravity, relative to where the object is supported, can contribute one of many forces that can act on the object. And it is is the [vector] sum of these forces which determines whether the object remains at rest or in uniform motion.
the net force which is the vector sum of the forces. If that sum = 0 then no motion occurs
The total vector force on an object determines the change in its velocity. That change is also known as acceleration.
The extent of resistance to a change of motion is determined by an objects mass. The mass of the object is measured in kilograms.
The total vector force on an object determines the change in its velocity. That change is also known as acceleration.
The motion of molecules determines
The equation is F = M A, where F is the Force required to stop the object, M is the object's Mass, and A is its Acceleration. Note that its acceleration in this case is the rate at which you are DE-ACCELERATING the object to stop it.
The equation is F = M A, where F is the Force required to stop the object, M is the object's Mass, and A is its Acceleration. Note that its acceleration in this case is the rate at which you are DE-ACCELERATING the object to stop it.
The equation is F = M A, where F is the Force required to stop the object, M is the object's Mass, and A is its Acceleration. Note that its acceleration in this case is the rate at which you are DE-ACCELERATING the object to stop it.
when can you say that the object is in motion
the mass of the object determines the amount of inertia in an object