3.2 Motion With Constant Acceleration

Slides:

Advertisements

Similar presentations

Motion and Force A. Motion 1. Motion is a change in position

Advertisements

A graph of the instantaneous velocity of an object over a specified period of time Time is independent (x-axis) Velocity is dependent (y-axis) Remember,

Speed and Acceleration

Relationships. Direct Proportion Two quantities are directly proportional if an increase in one causes an increase in the other. Example: y = 2 x Example:

By Rachael Jefferson. Acceleration is the rate of change in velocity with respect to time. A avg = ∆v/∆t = (v f -v i )/(t f -t i ) Notice how this form.

Motion Graphing Position vs. Time Graphs

Graphing Motion Position vs. Time Stationary objects

A Mathematical Model of Motion

Motion in One Dimension Average Versus Instantaneous.

February 22, 2012 What does the slope of a Position vs. Time graph tell us? What does the slope of a Velocity vs. Time graph tell us?

Accelerated Motion Chapter 3.1 Page 57.  The most important thing to notice in motion diagrams is the distance between successive positions!  If the.

x (m) t (s) 0 What does the y-intercept represent?. x (m) t (s) 0.

Scalar (Dot) Product. Scalar Product by Components.

2 Motion in One Dimension Displacement, velocity, speed Acceleration Motion with Constant Acceleration Integration Hk: 13, 27, 51, 59, 69, 81, 83, 103.

Plotting graphs Drawing best fit lines (or curves) Calculating slope = calculating velocity Describing Motion: Position vs Time Graphs.

Plot and interpret position-time graphs A position time graph shows an objects change in position over a period of time.

Displacement vs Time, Velocity vs Time, and Acceleration vs Time Graphs.

Describing Motion Chapter 3. What is a motion diagram?  A Motion diagram is a useful tool to study the relative motion of objects.  From motion diagrams,

Science Starter! 1.Obtain worksheet from teacher’s lab table. 2.Complete questions 1-3 on front of worksheet with your 3 O’CLOCK PARTNER. 3.Attempt (use.

Motion Graphs, kinematics - 2

Graphing motion.

Motion Graphs Let’s go over the basics.. Acceleration vs. time graphs (a vs. t) These graphs are boring, and will only have a straight line above the.

How to read a motion graph.

Equations of Motion. Velocity-Time Equation v f =v i +at.

Instantaneous Velocity The velocity at an instant of time. For a curved graph, use very small intervals of time.

1.1Motion and Motion Graphs. Kinematics Terminology Scalar vs. Vector Scalar: quantities that have only a size, but no direction – ie: distance, speed.

Motion Quiz. 1. The slope of a position (distance) vs time graph equals what quantity of the motion?

Describing Motion.

Motion with Constant Acceleration Interpret position-time graphs for motion with constant acceleration. Determine mathematical relationships among position,

Intro to Motion. Displacement The vector of distance travelled Units= meters Xf= final displacement, where you end up Xi= initial displacement, where.

Graphical Model of Motion. We will combine our Kinematics Equations with our Graphical Relationships to describe One Dimensional motion! We will be looking.

Motion graphs Position (displacement) vs. time Distance vs. time

Interpreting Motion Graphs

Position vs. Time (PT) graphs Velocity vs. Time (VT) graphs

Motion Graphs Learning Target: Be able to relate position, velocity, and acceleration quantitatively and qualitatively.

Velocity vs Time Graphs

Speed vs. Velocity.

Motion Graphs Position-Time (also called Distance-Time or Displacement-Time) d t At rest.

SECTION 3.2 MOTION WITH CONSTANT ACCELERATION

Motion in One Dimension (Velocity vs. Time) Chapter 5.2

Motion with Constant Acceleration

Non-Constant Velocity

In this section you will:

Today we will: Use different acceleration equations to solve for displacement, final velocity, initial velocity, and time. Begin review for test.

Graphing exercise Phet Simulation.

Graphs of Motion Please read about acceleration on pages 64 and 65. Be prepared to define acceletation. Objective(s)/SWBAT (Students will be able to):

Acceleration = Change in velocity / change in time

Velocity and Acceleration

Describing Motion Chapter 3.

Chapter 2 Objectives Describe motion in terms of changing velocity.

Review Section 2.1 Frame of Reference: Refers to the viewpoint of the problem and con not be changed. Displacement = Δx = Xf - Xi Average Velocity = Δx.

Motion and Force A. Motion 1. Motion is a change in position

Graphing Motion Walk Around

Velocity vs Time Graphs

Motion in One Dimension

Pictures worth even MORE words now!

Velocity and Acceleration

11.6 Acceleration - Review.

Understanding Motion Graphs

Describing Motion: Acceleration

Motion All motion is relative Name some types of motion

Aim: How do we analyze position-time or Displacement-time graphs?

The integral represents the area between the curve and the x-axis.

I. Changing Motion An object speeds up or down.

Chapter 4, Section 3 Acceleration.

acceleration vs time graphs

Velocity-Time Graphs for Acceleration

Velocity vs Time Graphs

Journal Entry 5 Accelerated Motion, Pt I

In this section you will:

Presentation transcript:

3.2 Motion With Constant Acceleration

3.2 Motion with Constant Acceleration If you know average acceleration (ā) during a time interval, you can find Δv. ā = Δv/Δt  Δv = ā·Δt  vf – vi=āΔt vf=vi + āΔt NOTE: if acceleration is constant; ā = a

3.2 Motion with Constant Acceleration vf=vi + āΔt (is the equation we just found) Can you rearrange the above equation to find time? Δt = (vf – vi)/a

Practice Problems 18a

Practice Problem 18b

Practice Problem 18c

Practice Problem 19

Practice Problem 20

Practice Problem 21

Position with Constant Acceleration Look at table 3-2; it is a position vs. time graph; the curved line shows it is accelerating. We can use the slopes from position/time graph to create a velocity vs. time graph

Position with Constant Acceleration However…a position vs. time graph cannot be created from velocity vs. time graph because there is no information about position, but it DOES tell information about displacement RECALL… v = Δd/Δt …therefore… Δd = vΔt

Picture of Velocity vs. time graph Area under a line = Δd = vΔt Therefore…area = the object’s displacement

Example Problem #3

Problem 22a

Problem 23

More Displacement…