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CS 121 – Quiz 4 Questions 5 and 6. Question 5 We are given Blammo’s initial angle of elevation, initial velocity, and the height of the center of the.

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Presentation on theme: "CS 121 – Quiz 4 Questions 5 and 6. Question 5 We are given Blammo’s initial angle of elevation, initial velocity, and the height of the center of the."— Presentation transcript:

1 CS 121 – Quiz 4 Questions 5 and 6

2 Question 5 We are given Blammo’s initial angle of elevation, initial velocity, and the height of the center of the ring. With this, we can define our xpos and ypos functions: – xpos := (t) -> v0 * cos(θ) * t – ypos := (t) -> v0 * sin(θ) * t – (1 / 2) * g * (t ^ 2) Don’t forget that θ must be in radians. It is given to us in degrees so we need to convert: – convert(51, units, degrees, radians)

3 We want Blammo to fly through the ring halfway through his flight, so we need to find when that is by finding his total flight time and dividing it in half: – peakTime := solve(ypos(t) = 0, t)[2] / 2 Solve will return a list of two solutions because Blammo not only lands on the ground, but also starts on the ground at t = 0. We are interested in the second solution. Also, notice that because we did not define v0, the answer for peakTime is given in terms of v0. This is what we want.

4 We can now find the y position in terms of v0, set it equal to the ring height, and solve for v0. We take the max because we want to ignore the negative root: – v := max(solve(ypos(peakTime) = ringHeight, v0)) We can then find the maximum distance by finding the final x position (at t = 2 * peakTime) in terms of v0, and plugging in the velocity we just calculated: – maxDistance := eval(xpos(2 * peakTime), v0 = v) And the answer: evalf([v, maxDistance])

5 Question 6 We are given the inclination angle (in degrees, don’t forget to convert to radians), the initial velocity (0), and the mass of the object. With this, we can define our v and t functions: – v := (t) -> v0 + 32 * sin(alpha) * t – d := (t) -> v0 * t + 16 * sin(alpha) * (t ^ 2) We can find the time it takes to travel the distance D to the bottom of the incline for part a: – maxTime := max(solve(d(t) = D, t)) And plug this into v for part b: – maxVel := v(maxTime)

6 For part c, we need to define and use the function K: – K := (m, v) -> m * (v ^ 2) – maxKin := K(m, maxVel) And finally, we need to convert to joules: – convert(maxKin, units, (pounds * feet ^ 2) / (seconds ^ 2), joules) For all of these parts, Maple TA expects an approximate answer, so don’t forget to use evalf.

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