Problem 2: In this problem you will measure the gravitational constant in a series of "observational experiments," making use of Newton's law vitation and second law of motion as well as Kepler's third law of planetary motion Part (a) Newton measured the centripetal acceleration of the moon in its orbit around Earth by comparing the force Earth exerts on the moor force Earth exerts on an apple. He obtained a value of a, = 2.73×10-3 m/s?. If Newton had taken the mass of Earth to be Mp = 5.99×1024 kg and the n ance between the centers of Earth and the moon to be RME = 3.83×10 m, what value would he have obtained for the gravitational constant, in units o =?/kg²? Part (b) Since measuring the centripetal acceleration of an orbiting body is rather difficult, an alternative approach is to use the body's rotati od instead. Enter an expression for the gravitational constant, in terms of the distance between Earth and the moon, RVF, Earth's mass,Mp, and the me od of rotation around Earth, T. Part (c) Using the expression you entered in part (b) and taking the rotational period of the moon to be T= 27.4 days, what value would New e calculated for the gravitation constant, in units of N•m²/kg?? Take Mp = 5.99×1024 kg and RyE = 3.83×108 m.

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Problem 2: In this problem you will measure the gravitational constant in a series of "observational experiments," making use of Newton's law of gravitation and second law of motion as well as Kepler's third law of planetary motion . Part (a) Newton measured the centripetal acceleration of the moon in its orbit around Earth by comparing the force Earth exerts on the moon with the force Earth exerts on an apple. He obtained a value of a, = 2.73×10-3 m/s?. If Newton had taken the mass of Earth to be Mp = 5.99×1024 kg and the mean distance between the centers of Earth and the moon to be RME = 3.83×10 m, what value would he have obtained for the gravitational constant, in units of N-m?/kg? ; Part (b) Since measuring the centripetal acceleration of an orbiting body is rather difficult, an alternative approach is to use the body's rotational period instead. Enter an expression for the gravitational constant, in terms of the distance between Earth and the moon, RVF, Earth's mass,Mp, and the moon's period of rotation around Earth, T. Part (c) Using the expression you entered in part (b) and taking the rotational period of the moon to be T= 27.4 days, what value would Newton have calculated for the gravitation constant, in units of N-m2/kg? Take Mp = 5.99×1024 kg and RVE = 3.83×10° m. Part (d) The gravitational constant may also be calculated by analyzing the motion of a rocket. Suppose a rocket is launched vertically from the surface or Earth at an initial speed of v;. Its initial distance from the center of Earth is R;, the radius of Earth. Its peak distance, where its speed is momentarily zero is, is Rç. For simplicity, ignore air resistance and Earth's rotation. Enter an expression for the gravitational constant, in terms of v;, R;. Rf and Mg. • Part (e) Suppose a rocket is launched as described in part (d) with an initial speed of v; = 508 m/s and attains a peak altitude of H=12.4 km above the surface of Earth. Taking ME = 5.99×1024 kg and R; = 6.39×10° m, what is the measured value of the gravitational constant, in units of N-m2/kg??