230 likes | 263 Views
Chapter 2 Kinematics in One Dimension. Dynamics Dynamics : branch of physics describing the motion of an object and the relationship between that motion and other physics concepts
E N D
Chapter 2 Kinematics in One Dimension
Dynamics • Dynamics: branch of physics describing the motion of an object and the relationship between that motion and other physics concepts • Kinematics is a part of dynamics. In kinematics we are interested in the description of motion, without the description of the cause of the motion • Any motion involves three concepts used to study objects in motion: 1) Displacement 2) Velocity 3) Acceleration
Linear motion In this chapter we will consider moving objects: • Along a straight line • With every portion of an object moving in the same direction and at the same rate (particle-like motion)
Types of physical quantities • In physics, quantities can be divided into such general categories as scalars, vectors, matrices, etc. • Scalars – physical quantities that can be described by their value only • Vectors – physical quantities that can be described by their value(magnitude) and direction
Distance, position, and displacement • Distance (scalar) a total length of the path traveled regardless of direction (SI unit: m) • In each instance we choose an origin – a reference point, convenient for further calculations • Position of an object (vector) is described by the shortest distance from the origin and direction relative to the origin • Displacement (vector) – a change from position xi to position xf
Velocity and speed • Average speed (scalar) - a ratio of distance traveled (over a time interval) to that time interval (SI unit: m/s) • Average velocity (vector) - a ratio of displacement (over a time interval) to that time interval • Instantaneous velocity (vector) – velocity at a given instant • Instantaneous speed (scalar) – a magnitude of an instantaneous velocity
Instantaneous velocity • The instantaneous velocity is the slope of the line tangent to the x vs. t curve • This would be the green line • The light blue lines show that as Δt gets smaller, they approach the green line
Chapter 2 Problem 9 A tourist being chased by an angry bear is running in a straight line toward his car at a speed of 4.0 m/s. The car is a distance d away. The bear is 26 m behind the tourist and running at 6.0 m/s. The tourist reaches the car safely. What is the maximum possible value for d?
Acceleration • Average acceleration (vector) - a ratio of change of velocity (over a time interval) to that time interval (SI unit = (m/s)/s = m/s2) • Instantaneous acceleration (vector) – a rate of change of velocity at a given instant
Acceleration • The blue line is the average acceleration • The slope (green line) of the velocity-time graph is the acceleration
Case of constant acceleration • Average and instantaneous accelerations are the same • Conventionally • Then
Case of constant acceleration • Average and instantaneous accelerations are the same • Conventionally • Then
Case of constant acceleration To help you solve problems
Chapter 2 Problem 40 A Boeing 747 “Jumbo Jet” has a length of 59.7 m. The runway on which the plane lands intersects another runway. The width of the intersection is 25.0 m. The plane decelerates through the intersection at a rate of 5.70 m/s2 and clears it with a final speed of 45.0 m/s. How much time is needed for the plane to clear the intersection?
Case of free-fall acceleration • At sea level of Earth’s mid-latitudes all objects fall (in vacuum) with constant (downward) acceleration of a = - g ≈ - 9.8 m/s2≈ - 32 ft/s2 • Conventionally, free fall is along a vertical (upward) y-axis
Chapter 2 Problem 63 While standing on a bridge 15.0 m above the ground, you drop a stone from rest. When the stone has fallen 3.20 m, you throw a second stone straight down. What initial velocity must you give the second stone if they are both to reach the ground at the same instant? Take the downward direction to be the negative direction.