1: Motion

How to Use This Book    xi

Acknowledgments    xiii

Activities

• 1 - Looking Ahead    1
• 2 - Communicating the Position of an Object    3
• 2A - Communicating the Position of an Object (Alternative Version)    7
• 3 - Describing Position    9
• 4 - Using Graphs of Position vs. Time    15
• 5 - Generating Sketches of Position vs. Time    19
• 6 - Translating Graphs of Position vs. Time    23
• 7 - Describing Displacement    27
• 8 - Describing Velocity    31
• 9 - Using Graphs of Velocity vs. Time    35
• 10 - Generating Sketches of Velocity vs. Time    39
• 11 - Translating Graphs of Velocity vs. Time    43
• 12 - Relating Strobe Diagrams to Plots of Position vs. Time and Velocity vs. Time    47
• 13 - Finding and Comparing Velocities    53
• 14 - Relating Graphs of Position vs. Time and Velocity vs. Time    57
• 15 - More Relating Graphs of Position vs. Time and Velocity vs. Time    61
• 16 - Solving Constant-Velocity Problems Using Different Methods    65
• 17 - Solving Constant-Velocity Problems    69
• 18 - Recognizing Accelerated Motion    73
• 19 - Describing Changes in Velocity    75
• 20 - Recognizing Graphs of Acceleration vs. Time    81
• 21 - Generating Sketches of Acceleration vs. Time    85
• 22 - Translating Graphs of Acceleration vs. Time    87
• 23 - Calculating Average Acceleration    89
• 24 - Relating Strobe Diagrams to Graphs of Acceleration vs. Time    93
• 25 - Relating Graphs and Kinematic Functions    97
• 26 - Relating Kinematic Quantities with Kinematic Functions    101
• 27 - Relating Graphs of Position, Velocity, and Acceleration vs. Time    105
• 28 - Comparing Graphs of Velocity vs. Time and Displacement vs. Time    109
• 29 - Translating Between Different Representations of Accelerated Motion    111
• 30 - Graphical Representations of Motion: Reflection and Integration    115
• 31 - Evaluating Procedures for Solving Kinematics Problems    119
• 32 - Executing Procedures for Solving Kinematics Problems    125
• 33 - Generating Procedures for Solving Kinematics Problems    127
• 34 - Solving Constant-Acceleration Problems    129
• 35 - Summarizing and Structuring Kinematics Ideas    133

Reader: Chapter 1—Describing Motion    R1

• 1.0 Introduction    R1
  • six terms used to describe motion    R1
• 1.1 Position    R1-5
  • Describing the position of an object    R1-4
    • definition of the term origin    R1
    • units of position: meter (m), kilometer (km), and centimeter (cm)    R2
    • three representations for position    R2
      • magnitude & direction representation    R2
      • component representation    R3
      • directed line segment representation    R3
    • representing the position in two dimensions    R3
      • magnitude & direction    R3,4
      • component representation    R4
      • directed line segment    R4
    • why we use three different representations    R4
  • Using graphs to describe the position of objects moving in one dimension    R5
• 1.2 Displacement    R6,7
  • Introduction    R6
  • Displacement in one dimension    R6,7
    • symbol for displacement: "delta-x"    R6
    • definition of displacement    R6
    • an example of displacement in all three representations    R6,7
  • Displacement in two dimensions    R7
• 1.3 Velocity    R8-18
  • Introduction    R8,9
    • difference between speed and velocity    R8
    • how we recognize when something has a velocity    R8
    • definition of average velocity (in one dimension)    R8
    • definition of velocity (or instantaneous velocity)    R9
    • definition of speed    R9
  • Representing velocity (in two dimensions)    R9-11
    • using all three representations for velocity    R10
    • how to estimate the components of velocity using a directed line segment    R11
  • Representing velocity at different times (in one dimension)    R12
  • Relationships between graphs of position and velocity    R12-15
    • constant, positive velocity    R13
    • constant, negative velocity    R13
    • changing velocity    R14
    • meaning of the area below velocity vs. time    R14
    • graphs of position vs. time    R15
    • meaning of the slope of position vs. time    R15
  • Using algebra to relate position and velocity    R16,17
    • equation for displacement when velocity is constant    R17
    • equation for position vs. time when velocity is constant    R17
  • Avoiding pitfalls when working with velocity concepts    R18,19
    • definition of average speed    R18
    • why the average speed for a trip is not the average of the speeds during the trip    R18
    • why the average speed for a trip is not the magnitude of the average velocity    R18,19
• 1.4 Acceleration    R19-33
  • Introduction    R19-21
    • how the term acceleration is used in physics compared to how the term is used in everyday language    R19
    • four examples of motion:    R19-21
      • a car moving at constant velocity    R19
      • a car with changing speed but constant direction    R20
      • a car with constant speed but changing direction    R20
      • a thrown ball has changing speed and direction    R21
  • Defining acceleration for straight-line motion (motion in one dimension)    R21-24
    • symbol for acceleration: a_x    R21
    • definition of average acceleration    R21
    • why "negative acceleration" does not mean "slowing down"    R22,23
    • definition of acceleration (or instantaneous acceleration)    R24
  • Representing and interpreting acceleration in one dimension    R24,25
    • using directed line segments for velocity    R24
    • using a number line for velocity    R25
  • Relationships between graphs of acceleration, velocity, and position (vs. time)    R26-28
    • calculations of the slopes of tangent lines    R26
    • verification that the slope of position vs. time is the velocity    R26,27
    • meaning of the slope of velocity vs. time    R27
    • meaning of the area below acceleration vs. time    R28
  • Deriving the kinematic equations for constant acceleration    R28-33
    • acceleration = 0    R29
      • how to find the displacement using a velocity graph    R29
      • equation for the position at time t    R29
    • acceleration <> 0    R30-33
      • how to find velocity using an acceleration graph    R30
      • equation for the velocity at time t    R30
      • how to find position using a velocity graph    R31
      • equation for the position at time t for constant acceleration    R31
      • equation for the squared velocity after displacement "delta-x"    R31
      • how to use graphs to solve problems    R32,33
• 1.5 Kinematics    R34-36
  • Introduction    R34
  • Definitions    R34
    • position    R34
    • displacement    R34
    • average velocity    R34
    • velocity    R34
    • speed    R34
    • average speed    R34
    • average acceleration    R34
    • acceleration    R34
  • Relationships between graphs of motion quantities    R35
    • meaning of the slope of position vs. time    R35
    • meaning of the slope of velocity vs. time    R35
    • meaning of the area below velocity vs. time    R35
    • meaning of the area below acceleration vs. time    R35
    • diagrammatic representation of these relationships    R35
  • Derived equations relating the motion quantities (for constant acceleration)    R35
    • equation for the velocity at time t    R35
    • equation for the position at time t    R35
    • equation for the squared velocity after displacement "delta-x"    R35
    • definitions of symbols used in these derived equations    R35
  • Conclusion    R36
    • why problem solving is so difficult    R36
    • how to simplify kinematics problems    R36
    • why understanding motion is so important    R36