Frictionless incline and required force

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If I had to push a box with a certain weight 'm' up an incline, would I just need a force 'slightly greater' than 'mg'? (Assuming I applied the force parallel and up the incline)
 
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I have figure that out, and the only force acting, in this case, is gravity. So that would mean I would need a force mgx in the opposite direction but slightly greater correct? (mgx is the x-component of mg)
 
Oh right. Ok, now am I correct in saying that that opposing force has to be 'slightly greater' in order to push the box up the incline?
 
Yes, slightly greater the component of the weight, that is, slightly greater than mg(sin theta), where theta is the angle that the incline makes above the horizontal. We say here "slightly greater" because presumably it starts from rest, so you have to apply a slightly greater force to get it moving by accelerating it to some small speed, and once it is in motion you merely have to apply exactly mg sin theta force to keep it moving at that constant speed. This of course assumes no friction or retarding forces are acting, just gravity force down the plane.
 
You say that once it's in motion you only have to apply the same force, but wouldn't that just keep the box at rest on the incline?
 
So, in this example, if you we're applying the required force to push it up hill how would you bring the box to rest?
 
Well you could let go of it and it would come to a temporary stop before reversing direction and accelerating down the incline to a greater and greater speed. But if you want to bring it to a permanent rest, you have to apply a force slightly less than mg sin theta to stop it ( decelerate it to zero speed), then once it stops apply exactly mg sin theta to keep it at rest.