Textbook Question
Bill can throw a ball vertically at a speed 1.5 times faster than Joe can. How many times higher will Bill's ball go than Joe's?
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Ch. 02 - Describing Motion: Kinematics in One Dimension
Giancoli Douglas5th editionPhysics for Scientists and EngineersISBN: 9780137488179
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Table of contents
- Ch. 01 - Introduction, Measurement, Estimating10
- Ch. 02 - Describing Motion: Kinematics in One Dimension30
- Ch. 03 - Kinematics in Two or Three Dimensions; Vectors15
- Ch. 04 - Dynamics: Newton's Laws of Motion16
- Ch. 05 - Using Newton's Laws: Friction, Circular Motion, Drag Forces22
- Ch. 06 - Gravitation and Newton's Synthesis10
- Ch. 07 - Work and Energy21
- Ch. 08 - Conservation of Energy33
- Ch. 09 - Linear Momentum26
- Ch. 10 - Rotational Motion41
- Ch. 11 - Angular Momentum; General Rotation27
- Ch. 12 - Static Equilibrium; Elasticity and Fracture27
- Ch. 13 - Fluids28
- Ch. 14 - Oscillations14
- Ch. 15 - Wave Motion35
- Ch. 16 - Sound5
- Ch. 17 - Temperature, Thermal Expansion, and the Ideal Gas Law40
- Ch. 18 - Kinetic Theory of Gases18
- Ch. 19 - Heat and the First Law of Thermodynamics31
- Ch. 20 - Second Law of Thermodynamics32
- Ch. 21 - Electric Charge and Electric Field7
- Ch. 23 - Electric Potential20
- Ch. 24 - Capacitance, Dielectrics, Electric Energy, Storage15
- Ch. 25 - Electric Current and Resistance32
- Ch. 26 - DC Circuits22
- Ch. 27 - Magnetism21
- Ch. 28 - Sources of Magnetic Field24
- Ch. 29 - Electromagnetic Induction and Faraday's Law21
- Ch. 30 - Inductance, Electromagnetic Oscillations, and AC Circuits42
- Ch. 31 - Maxwell's Equations and Electromagnetic Waves25
- Ch. 32 - Light: Reflection and Refraction42
- Ch. 33 - Lenses and Optical Instruments21
- Ch. 34 - The Wave Nature of Light: Interference and Polarization26
- Ch. 35 - Diffraction24
- Ch. 36 - The Special Theory of Relativity29
- Ch. 38 - Quantum Mechanics1
- Ch. 40 - Molecules and Solids6
- Ch. 43 - Elementary Particles3
- Ch. 44 - Astrophysics and Cosmology9
Giancoli Douglas5th editionPhysics for Scientists and EngineersISBN: 9780137488179Not the one you use?Change textbook
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Giancoli Douglas 5th editionCh. 02 - Describing Motion: Kinematics in One DimensionProblem 102c
Giancoli Douglas 5th editionCh. 02 - Describing Motion: Kinematics in One DimensionProblem 102cChapter 2, Problem 102c
Figure 2–55 shows the position vs. time graph for two bicycles, A and B. At which instant(s) are the bicycles passing each other? Which bicycle is passing the other?
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Analyze the position vs. time graph provided in the problem. Identify the curves corresponding to bicycles A and B. Note that the point where the two curves intersect represents the instant(s) when the bicycles are at the same position (i.e., passing each other).
Determine the time coordinate(s) of the intersection point(s) on the graph. These time values indicate when the bicycles are passing each other.
To identify which bicycle is passing the other, observe the slopes of the curves (representing their velocities) at the intersection point(s). The slope is the derivative of the position with respect to time.
If the slope of bicycle A's curve is greater than that of bicycle B at the intersection point, bicycle A is overtaking bicycle B. Conversely, if the slope of bicycle B's curve is greater, bicycle B is overtaking bicycle A.
Summarize the findings: Specify the time(s) when the bicycles pass each other and indicate which bicycle is passing the other based on the slope analysis.
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Position vs. Time Graph
A position vs. time graph visually represents the location of an object over time. The x-axis typically denotes time, while the y-axis indicates position. The slope of the graph indicates the object's velocity; a steeper slope means a higher speed. When two objects' graphs intersect, it signifies that they are at the same position at that specific time.
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03:04
Curved Position-Time Graphs & Acceleration
Relative Motion
Relative motion refers to the calculation of the motion of an object as observed from another moving object. In the context of the bicycles, understanding which bicycle is moving faster or slower relative to the other is crucial for determining which one is passing the other. This concept helps in analyzing how the position of one bicycle changes in relation to the other over time.
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04:27Intro to Relative Motion (Relative Velocity)
Intersection Points
Intersection points on a position vs. time graph indicate moments when two objects occupy the same position. To find when the bicycles pass each other, one must identify the time(s) at which their graphs intersect. This analysis reveals not only the instant of passing but also which bicycle is ahead or behind at that moment, providing insight into their relative speeds.
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08:35Angular Momentum of a Point Mass
Related Practice
Textbook Question
A robot used in a pharmacy picks up a medicine bottle at t = 0. It accelerates at 0.20 m/s² for 4.5 s, then travels without acceleration for 68 s and finally decelerates at ―0.40 m/s² for 2.5 s to reach the counter where the pharmacist will take the medicine from the robot. From how far away did the robot fetch the medicine?
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Textbook Question
A parachutist bails out of an airplane, and freely falls 75 m (ignore air friction). Then the parachute opens, and her acceleration is ― 1.5 m/s² (up). The parachutist reaches the ground with a speed of 1.5 m/s. From how high did she bail out of the plane?
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Textbook Question
Figure 2–55 shows the position vs. time graph for two bicycles, A and B. Which bicycle has the larger average velocity?
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