Tutorials in Introductory Physics
1st Edition
ISBN: 9780130970695
Author: Peter S. Shaffer, Lillian C. McDermott
Publisher: Addison Wesley
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Textbook Question
Chapter 15.1, Problem 2cTH
Next, we expand the section of the previous graph in the very small box near
Position and time coordinates are given below for points in the interval from
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Check out a sample textbook solutionStudents have asked these similar questions
Based on the table given (image attached),
a. Draw the distance vs. time graph. Find the slope.b. Describe the graph line. What does it imply?
Please help by DRAWING and give the solutions like the one in the picture and USE the formulas that are in the second picture.
(the problems are all related.)
1. The same ball is tossed upward at the top of a 80 m tall building at 30m/s. Find the distances covered and the velocities in 1 second intervals.
2. The ball is thrown down from the top of the 80 m tall building at 30 m/s. Find the distances covered and the velocities in 1 second intervals.
Supply what is asked with the correct integer values, i.e. no decimal places. Do not forget the negative sign (-) if needed.
The position vs. time graph of a moving particle for a time interval of 23 seconds is shown below. Each square unit in the horizontal axis corresponds to one second, and each square unit in the vertical axis corresponds to one
meter
10
en
position (m)
What is the instantaneous velocity of the particle at t = 11 s?
What is the average velocity of the particle from t= 17 s to t= 18 s?
m/s
m/s
Chapter 15 Solutions
Tutorials in Introductory Physics
Ch. 15.1 - Describe the motion. During which periods of time,...Ch. 15.1 - Find the object’s instantaneous velocity at each...Ch. 15.1 - For each of the following intervals, find the...Ch. 15.1 - In which of the cased from part c, if any, is the...Ch. 15.1 - In the interval from t=0s to t=6s , does the...Ch. 15.1 - In the small box on the graph above is a portion...Ch. 15.1 - Next, we expand the section of the previous graph...Ch. 15.1 - All three graphs are representations of the same...Ch. 15.1 - Suppose that the object is speeding up. Which of...Ch. 15.1 - Suppose that the object is slowing down. Which of...
Ch. 15.1 - Describe how you could use these devices to...Ch. 15.1 - Describe how you could use these devices to...Ch. 15.2 - In each of the following exercises, a motion will...Ch. 15.2 - In each of the following exercises, a motion will...Ch. 15.2 - In each of the following exercises, a motion will...Ch. 15.2 - In each of the following exercises, a motion will...Ch. 15.2 - In each of the following exercises, a motion will...Ch. 15.2 - In each of the following exercises, a motion will...Ch. 15.2 - In each of the following exercises, a motion will...Ch. 15.2 - In each of the following exercises, a motion will...Ch. 15.2 - There are several answers for most of the...Ch. 15.2 - There are several answers for most of the...Ch. 15.2 - There are several answers for most of the...Ch. 15.3 - A ball rolls up, then down an incline. Sketch an...Ch. 15.3 - Sketch x versus t, v versus t, and a versus t...Ch. 15.3 - Sketch x versus t, v versus t, and a versus t...Ch. 15.3 - Sketch x versus t, v versus t, and a versus t...Ch. 15.3 - Describe the motion of an object: For which the...Ch. 15.3 - Describe the motion of an object: b. For which the...Ch. 15.3 - Describe the motion of an object: c. For which the...Ch. 15.3 - Describe the motion of an object: d. For which the...Ch. 15.3 - Two carts roll toward each other on a level table....Ch. 15.3 - Two carts roll toward each other on a level table....Ch. 15.3 - Two carts roll toward each other on a level table....Ch. 15.3 - In this problem, a Cart moves in various ways on a...Ch. 15.3 - In this problem, a Cart moves in various ways on a...Ch. 15.3 - In this problem, a Cart moves in various ways on a...Ch. 15.3 - Carts A and B move along a horizontal track. The...Ch. 15.3 - Carts A and B move along a horizontal track. The...Ch. 15.3 - Carts A and B move along a horizontal track. The...Ch. 15.3 - Carts A and B move along a horizontal track. The...Ch. 15.3 - Two cars, C and D, travel in the same direction on...Ch. 15.3 - Two cars, P and Q, travel in the same direction on...Ch. 15.3 - Two cars, P and Q, travel in the same direction on...Ch. 15.4 - Prob. 1aTHCh. 15.4 - Prob. 1bTHCh. 15.4 - Describe how you would determine the acceleration...Ch. 15.4 - Copy vG and vH (placed “tailtotail”) in the space...Ch. 15.4 - Generalize your results above and from tutorial to...Ch. 15.4 - For each instant, state whether the object is...Ch. 15.4 - The diagram at right illustrates how the...Ch. 15.4 - For each of the instants 14, compare your...Ch. 15.4 - Choose a point about 1/8th of the way around the...Ch. 15.4 - Prob. 3bTHCh. 15.4 - How would you characterize the direction of v as...Ch. 15.4 - Each of the following statements in incorrect....Ch. 15.4 - On the diagram at right, draw vectors that...Ch. 15.4 - On the diagram at right, draw vectors that...Ch. 15.4 - Draw arrows on the diagram at points AG to...Ch. 15.4 - Next to each of the labeled points, state whether...Ch. 15.4 - Draw arrows on the diagram below to show the...Ch. 15.4 - On the diagram at right, draw velocity vectors for...Ch. 15.4 - On the diagram at right, draw the acceleration...Ch. 15.4 - How does the magnitude of the acceleration at E...Ch. 15.5 - Reference frame of boat B: Complete the upper...Ch. 15.5 - Reference frame of boat A: Complete the diagram at...Ch. 15.5 - Is the speed of the kayak in the frame of boat A...Ch. 15.5 - Rank the following quantities in order of...Ch. 15.5 - A third riverboat, boat C, moves downstream so as...Ch. 15.5 - Prob. 2aTHCh. 15.5 - A car, a truck, and a traffic cone are on a...Ch. 15.5 - The relationship vcar,cone=vcar,truck+vtruck,cone...Ch. 15.5 - Car P moves to the west with constant speed v0...Ch. 15.5 - Car P moves to the west with constant speed v0...Ch. 15.5 - Car P moves to the west with constant speed v0...Ch. 15.5 - Car P moves to the west with constant speed v0...Ch. 15.5 - Car P moves to the west with constant speed v0...Ch. 15.5 - A bicycle coasts up a hill while a car drives up...Ch. 15.5 - A bicycle coasts up a hill while a car drives up...Ch. 15.5 - A bicycle coasts up a hill while a car drives up...Ch. 15.5 - A bicycle coasts up a hill while a car drives up...Ch. 15.5 - A bicycle coasts up a hill while a car drives up...Ch. 15.5 - A bicycle coasts up a hill while a car drives up...
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- I PRELIMINARY QUESTIONS 1. One of the timing devices Galileo used was his pulse. Drop a rubber ball from a height of about 2 m and try to determine how many pulse beats elapsed before it hits the ground. What was the timing problem that Galileo encountered? 2. Now measure the time it takes for the rubber ball to fall 2 m, using a watch or clock with a second hand or seconds display. Did the results improve substantially? 3. Roll the hard ball down an incline that makes an angle of about 10° with the horizontal. First use your pulse and then your watch or clock to measure the time of descent. 4. Do you think that during Galileo's day it was possible to get useful data for any of these experiments? Why?arrow_forwardThe graph below shows the speed of an object plotted versus time. Each of the increments on the speed axis is 3 m/s. Each of the increments on the time axis is 2 seconds. Again, each graph inflection point cooresponds to tick marks on the axes. Use the graph to answer the following four questions. What is the total distance travelled by the object (that is, from point A to F)?arrow_forwardSupply what is asked with the correct integer values, i.e. no decimal places. Do not forget the negative sign (-) if needed. The position vs. time graph of a moving particle for a time interval of 23 seconds is shown below. Each square unit in the horizontal axis corresponds to one second, and each square unit in the vertical axis corresponds to one meter. a. What is the displacement of the particle for the entire 23 seconds? __m b. What is the distance traveled by the particle for the entire 23 seconds? __m c. What is the average speed of the particle from t = 0 s to t = 5 s? __m/s d. What is the instantaneous velocity of the particle at t = 11 s? __ m/s e. What is the average velocity of the particle from t = 17 s to t = 18 s? __ m/sarrow_forward
- Explain why we only consider one dimensional motion when using a single motion sensor. Based on the definition of velocity, describe what you should observe in the velocity vs. time graph if you were measuring a stationary, distant object and you suddenly slid and object into the beam from the side [hint: think about the behavior of the position graph in this case.]arrow_forwardMake the proper representation for each of the following problems and solve completely. 1. A euglena swims with a speed of 3.5 µm/s, and swim across the ends of the diameter of an 8.0 cm petri dish. Find the time it takes to swim across the ends of the petri dish. 2. A dog runs 100m away from its master in a straight line in 9.0s, and then runs halfway back in one-third the time. Compute a) its average speed and b) its average velocity. 3. A jeepney starts from rest and moves with an acceleration of 0.5 m/s² until it reaches the velocity 5 m/s, runs at this speed for a time, then applies the break to decelerate at 1.0 m/s² until it stops in 30 seconds. What is the total displacement of the jeepney?arrow_forwardSupply what is asked with the correct integer values, i.e. no decimal places. Do not forget the negative sign (-) if needed. The position vs. time graph of a moving particle for a time interval of 23 seconds is shown below. Each square unit in the horizontal axis corresponds to one second, and each square unit in the vertical axis corresponds to one meter. What is the distance traveled by the particle for the entire 23 seconds? m What is the average speed of the particle from t = 0 s to t = 5 s? m/s What is the instantaneous velocity of the particle at t = 11 s? m/s What is the average velocity of the particle from t = 17 s to t = 18 s? m/sarrow_forward
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- A car is moving in a positive direction to the right, at the moment we begin to observe it (consider t = 0 sec), the position of the car is 30 m, it has an initial velocity of 20 m / sec and an initial acceleration of - 36m / sec2, it is known that the rate of change of the acceleration is constant and is 18.a) Find the equations for Acceleration, Velocity, and Position. Make your graphs.b) For what instant of time does the speed of the car take its minimum value, and what is that value?c) In the graph of the position, which represents part “b”, is it a minimum, maximum or an inflection point? What is the value of the position for that instant of time? Justify your answer.d) How many times does the car move to the left? Justify your answer.e) At what instant of time is the value of the position 150? - Only subsections "d" and "e" to be resolvedarrow_forwardWrite the actual function that you expect the velocity to obey as a function of time (recall that the initial velocity was 17 m/s). Your function should be a function of time (i.e. the t variable should be left as an independent variable) but all other values should be filled in with numbers. Based on your answer above, what type of curve would you expect the position vs. time function to obey? i.A constant (horizontal) curve? ii.A linear curve? iii.A quadratic (parabolic) curve? iv.Another type of curve, such as cubic, exponential, sine, square root, etc...? Circle an answer from above and explain how you use your answer to the above question and the relationship between position and velocity to arrive at your conclusion.arrow_forwardA car is moving in a positive direction to the right, at the moment we begin to observe it (consider t = 0 sec), the position of the car is 30 m, it has an initial velocity of 20 m / sec and an initial acceleration of - 36m / sec2, it is known that the rate of change of the acceleration is constant and is 18.a) Find the equations for Acceleration, Velocity, and Position. Make your graphs.b) For what instant of time does the speed of the car take its minimum value, and what is that value?c) In the graph of the position, which represents part “b”, is it a minimum, maximum or an inflection point? What is the value of the position for that instant of time? Justify your answer.d) How many times does the car move to the left? Justify your answer.e) At what instant of time is the value of the position 150?arrow_forward
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