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Other forces and the mass of the object.
Newton's second law of motion states that an object's acceleration is directly related to the net force applied and inversely related to the mass of the object.
The upward force would have to overcome gravity, so the force should be F > -mg. Since the upward force and gravity work in opposite direction you can disregard the mass of the object (they cancel: F(gravity) = F(upward) => mg = -m(g+x)) . Consequently the object's mass is irrelevant.
It takes no force to 'move' an object. There are trillions of objects that are moving right now with no forces acting on them. It only takes force to 'accelerate' an object ... to change its motion, by changing its speed or the direction of its motion. force=mass*acceleration As mass increases, so does the force needed to change the object's motion.
force of friction= coefficient of friction x force of normal force of normal is mass x whatever force that is acting on it (usually gravity)
Mass
No, mass is the measure of matter in an object. Weight is the measure of gravitational force needed to keep the object grounded.
Force happens when an object of mass is accelerated, and the equation to calculate force is : force=mass/acceleration
. The amount of Force needed to make an object change its motion depends on the Mass of the object and the Force required
Other forces and the mass of the object.
The main of force needed tio move an object is the objects mass, f= ma.
Newton's second law of motion states that an object's acceleration is directly related to the net force applied and inversely related to the mass of the object.
F = ma. The force applied to an object creates an acceleration depending on the mass of the object.
The upward force would have to overcome gravity, so the force should be F > -mg. Since the upward force and gravity work in opposite direction you can disregard the mass of the object (they cancel: F(gravity) = F(upward) => mg = -m(g+x)) . Consequently the object's mass is irrelevant.
Newton's Second Law: force = mass x acceleration
Mass is defined as resistance to acceleration, so one could measure how much force is needed to accelerate the object.
Mass ?