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Newton’s 3 rd Law Action-reaction pairs Inclined coordinate system Massless ropes and massless, frictionless pulleys Coupled objects Lecture 6: Newton’s.

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Presentation on theme: "Newton’s 3 rd Law Action-reaction pairs Inclined coordinate system Massless ropes and massless, frictionless pulleys Coupled objects Lecture 6: Newton’s."— Presentation transcript:

1 Newton’s 3 rd Law Action-reaction pairs Inclined coordinate system Massless ropes and massless, frictionless pulleys Coupled objects Lecture 6: Newton’s Third Law

2 Newton’s 3 rd Law Common version: For every action there is an equal and opposite reaction. * * This is problematic because it suggests that first there is an action and then there is a reaction. Better version:

3 Action-reaction pairs

4 Example: object at rest on a table Forces of action-reaction pair act on two different objects

5 Object on inclined plane Normal = perpendicular Normal force must be perpendicular to surface Weight: vertically down

6 Object on inclined plane Choose axis in direction of acceleration. Draw components of weight vector Identify θ in the weight triangle

7 Components of weight vector In this coordinate system:

8 Coupled objects: ropes and pulleys We make the following approximations: massless, un-stretchable rope → tension is constant throughout the rope massless, frictionless pulley → tension remains constant as rope passes over pulley Caution: If mass and spatial extension of the pulley are taken into account, the tension does not remain constant! We will study this with Rotational Motion in lectures 18-21.

9 Example with coupled objects Two blocks are connected by a massless string. A block of mass m is on a frictionless inclined plane that makes angle θ with the vertical, while a block of mass M hangs over a massless and frictionless pulley. Derive an expression for the acceleration of the blocks in terms of relevant system parameters.

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