1. Which of the following is an inertial frame (where when no force is applied, a body at rest willstay at rest, a body in motion will remain in constant velocity motion)?a. In an airplane that is at cruising altitude, flying straight ahead, without experiencing tur-bulence;b. In a car that is running on a straight highway and switching lanes to avoid colliding intoanother vehicle;c. In a roller coaster that is at the highest point of the whole round;d. On a spinning top whose location barely changes;e.On a fixed point on earth which spins roughly a turn relative to the sun in 24 hours.2. For the setup to the right, draw the free body diagram forthe mass M, assuming no friction between the mass and thesurface it is sliding on.M3. For the same setup, draw the free body diagram for the mass m.mSource: Chih Kuan Tung=4. Use F, ma, to write down the equation of motion for the mass m, and then ΣF = Ma towrite down the equation for mass M. Due to the string, M and m have the same magnitude ofacceleration ne to the right and the other downward. Solve a.

Question 1 The condition when a body at rest stays at rest and when it is in motion it stays moving…

Answered: 1. Which of the following is an…

Principles of Physics: A Calculus-Based Text

5th Edition

ISBN:9781133104261

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter11: Gravity, Planetary Orbits, And The Hydrogen Atom

Section: Chapter Questions

Problem 65P

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In what frame(s) of reference are Kepler's laws valid? Are Kepler's laws purely descriptive, or do they contain causal information?
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Question 4 a) For the structure in figure 9 determine the degrees of freedom. Assume members are extensible. E 20 AL Figure 9 b) In using the method of consistent deformation in analysing structures, the compatibility equation has to be written. Why is this necessary? c) Write the slope deflection equation for the frame in figure 10. 10LN/m AT B D. 4m 4m Figure 10
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Give three examples each of inertial and non-inertial reference frames. Explain them briefly.
3) The new Earth-Pluto SuperShuttle boasts that it can take you between the two planets, which are 5.0 hours apart in 2.5 hours (according to your watch). What time interval is measured by people in the Earth-Pluto frame? What is the shuttle's speed?
2. An object of mass 100 g is at rest. A net force of 2000 dynes is applied for 10 sec. What is the final velocity? How far will the object have moved in the 10sec interval?
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7.2 Engine trouble. In the frame of a moving car, the driver coughs, and at the same moment (by coincidence) a puff of smoke emerges from the tailpipe. In the Earth's frame which is true? a. These two events are again simultaneous. b. The puff of smoke emerges before the driver coughs. c. The driver coughs before the puff of smoke emerges. d. The driver never coughs. Explain your answer in one sentence.

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