A mechanical system consists of a ("long") rigid rod of length d and mass M, and another ("short") rigid rod of length I and mass m. The rods are attached at a fixed 90° angle such that the endpoint of the long rod touches the middle of the short rod; see the figure below. The mass per unit length of the rods is constant. The system can move in a vertical plane (x, y) with the endpoint O of the long rod fixed, so that the system is free to oscillate in the vertical plane about the point O. Gravity acts along the vertical y direction. a) How many degrees of freedom does the system have? [Expect to use a line to answer this question.] X b) Calculate the moment of inertia of the system constituted by the rods about an axis orthog- onal to the plane (x,y) and passing through O. Assume that the widths of the rods are negligible, so that you can effectively treat them as one-dimensional objects. [Expect to use about half a page to answer this question.] c) Determine the distance of the centre of mass of the system from the point O, and write down the gravitational potential of the system. [Expect to use about half a page to answer this question.] d) Write down the Lagrangian of the system and the Euler-Lagrange equations. [Expect to use about half a page to answer this question.] e) Determine the frequency of small oscillations w about the equilibrium position 0 = 0 (the angle is defined in the figure). In what limit does the system reduce to a simple planar pendulum? (A simple pendulum is a point particle moving at a distance d from point O.) Check that w in this limit reduces to the well-known formula for a simple pendulum. [Expect to use about half a page to answer this question.]

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A mechanical system consists of a ("long") rigid rod of length d and mass M, and another ("short") rigid rod of length I and mass m. The rods are attached at a fixed 90° angle such that the endpoint of the long rod touches the middle of the short rod; see the figure below. The mass per unit length of the rods is constant. The system can move in a vertical plane (x, y) with the endpoint O of the long rod fixed, so that the system is free to oscillate in the vertical plane about the point O. Gravity acts along the vertical y direction. 0 d a) How many degrees of freedom does the system have? [Expect to use a line to answer this question.] â b) Calculate the moment of inertia of the system constituted by the rods about an axis orthog- onal to the plane (x, y) and passing through O. Assume that the widths of the rods are negligible, so that you can effectively treat them as one-dimensional objects. [Expect to use about half a page to answer this question.] c) Determine the distance of the centre of mass of the system from the point O, and write down the gravitational potential of the system. [Expect to use about half a page to answer this question.] d) Write down the Lagrangian of the system and the Euler-Lagrange equations. [Expect to use about half a page to answer this question.] e) Determine the frequency of small oscillations w about the equilibrium position 0 = 0 (the angle is defined in the figure). In what limit does the system reduce to a simple planar pendulum? (A simple pendulum is a point particle moving at a distance d from point O.) Check that w in this limit reduces to the well-known formula for a simple pendulum. [Expect to use about half a page to answer this question.]