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The tension in any part of the string is equal to the force that pulls the string at the ends (assuming for simplicity that the string is basically weightless).
When a force is applied on a string, a restoring force is developed in it in opposite direction of external force.This restoring force of string is tension.
unless the string is broken up,the force of pulling will be applied along the continuous part of the string when the string is in full stretched condition.
the force apply on string it vibrate this vibration is called tension of the string
A falling elephant encounters a greater force of air resistance than a falling feather does. The force of air resistance can't be greater than the weight of the falling object. When the force of air resistance is equal to the weight of the falling object, the object stops accelerating, its falling speed becomes constant, and the force of air resistance doesn't get any bigger. So the force of air resistance against a falling feather can't be greater than the weight of the feather. But the force of air resistance against a falling elephant can be, and undoubtedly is, greater than the weight of a feather.
Centripetal force is the force necessary to apply to an object to get it to orbit; like spinning a rock on a string. It you are holding on to the string, you will feel a centrifugal force.
No. The force keeping a ball on a string moving in a circle is centripetal force, i.e. force pulling the ball to the center of the circle.
Falling with Force - 2009 was released on: USA: March 2009
Gravity is a force that accelerates the falling object towards the ground.
Gravitational force
no force act on it
gravitinal force]