Textbook Question
FIGURE P3.26 shows vectors A and B. Find D = 2A +B Write your answer in component form.
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3. Vectors
Adding Vectors by Components
13:40 minutesProblem 9
Textbook Question
A runner is training for an upcoming marathon by running around a 100-m-diameter circular track at constant speed. Let a coordinate system have its origin at the center of the circle with the x-axis pointing east and the y-axis north. The runner starts at (x,y) = (50m, 0m) and runs 2.5 times around the track in aclockwise direction. What is his displacement vector? Give your answer as a magnitude and direction.
Verified step by step guidance1
Step 1: Understand the problem. The runner is moving in a circular path with a diameter of 100 m, which means the radius of the circle is 50 m. The runner starts at the point (50 m, 0 m) on the positive x-axis and runs 2.5 times around the circle in a clockwise direction. We need to find the displacement vector, which is the straight-line distance and direction from the starting point to the final point.
Step 2: Calculate the total angular displacement. One full circle corresponds to an angular displacement of 2π radians. Since the runner completes 2.5 revolutions, the total angular displacement is 2.5 × 2π radians. This equals 5π radians. Since the motion is clockwise, the angular displacement is negative: -5π radians.
Step 3: Determine the final angular position. The runner starts at an angle of 0 radians (on the positive x-axis). To find the final angular position, add the total angular displacement to the initial angle. Since -5π radians is equivalent to -π radians (after subtracting multiples of 2π to bring it within one full circle), the final angular position is -π radians. This corresponds to the point (-50 m, 0 m) on the negative x-axis.
Step 4: Calculate the displacement vector. The displacement vector is the straight-line vector from the starting point (50 m, 0 m) to the final point (-50 m, 0 m). The x-component of the displacement is Δx = -50 m - 50 m = -100 m, and the y-component is Δy = 0 m - 0 m = 0 m. Thus, the displacement vector is (-100 m, 0 m).
Step 5: Find the magnitude and direction of the displacement vector. The magnitude of the displacement vector is given by the formula: . Substituting Δx = -100 m and Δy = 0 m, the magnitude is 100 m. The direction is the angle of the vector relative to the positive x-axis, which is 180° (or π radians) since the vector points directly to the left.
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Displacement
Displacement is a vector quantity that refers to the change in position of an object. It is defined as the shortest straight-line distance from the initial position to the final position, along with the direction of that line. In this case, the runner's displacement will be determined by the coordinates of his starting and ending points after completing the laps around the circular track.
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Circular Motion
Circular motion refers to the movement of an object along the circumference of a circle. When an object moves in a circular path at constant speed, it experiences centripetal acceleration directed towards the center of the circle. Understanding circular motion is essential for analyzing the runner's path and determining how many laps he completes around the track.
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Vector Components
Vector components are the projections of a vector along the axes of a coordinate system. Any vector can be broken down into its horizontal (x-axis) and vertical (y-axis) components. For the runner's displacement, calculating the vector components will help in determining both the magnitude and direction of the displacement vector after running around the track.
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