If you know the net force on an object, you can determin the effect of the net force on the objects motion. (I got this answer from my text book. Therefore, it's right)
You must know the the direction so then you know if you either subtract or add. For example , if the the direction of the force is in opposite then you would have to subract each net force.
Gravity provides a force; any net force will result in an acceleration, i.e., a change of motion.
Net Force, Or Net Resultant Force, or Resultant force
I'd call it the resultant, but "net force" is a good name too.
you can the effect of the net force in the object motion
If you know the net force on an object, you can determin the effect of the net force on the objects motion. (I got this answer from my text book. Therefore, it's right)
Zero net force has no effect on an object's motion whatsoever.
This would be known as the net-force.
As net force is constant, from Force= mass *acceleration mass becomes inversely proportional to acceleration (net force being the constant between them) ..thus if mass increases, the acceleration decreases. ( mass= net force* 1/acceleration) so the objects slows down.
You must know the the direction so then you know if you either subtract or add. For example , if the the direction of the force is in opposite then you would have to subract each net force.
Gravity provides a force; any net force will result in an acceleration, i.e., a change of motion.
Inertia will not be affected when "net" or "net force" is zero.
Net Force, Or Net Resultant Force, or Resultant force
I'd call it the resultant, but "net force" is a good name too.
Net force and interference are related because net force is a force and interference is putting a force on something.
Net force is zero. So it would be at rest