CHS Physics Instantaneous Velocity &Acceleration.

Slides:

Advertisements

Similar presentations

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

Advertisements

Describing Motion: Kinematics in One Dimension

Warm Up A particle moves vertically(in inches)along the x-axis according to the position equation x(t) = t4 – 18t2 + 7t – 4, where t represents seconds.

R. Field 1/17/2013 University of Florida PHY 2053Page 1 1-d Motion: Position & Displacement We locate objects by specifying their position along an axis.

Kinematics Notes Motion in 1 Dimension Physics C 1-D Motion

Meanings of the Derivatives. I. The Derivative at the Point as the Slope of the Tangent to the Graph of the Function at the Point.

Derivatives - Equation of the Tangent Line Now that we can find the slope of the tangent line of a function at a given point, we need to find the equation.

Graphing motion. Displacement vs. time Displacement (m) time(s) Describe the motion of the object represented by this graph This object is at rest 2m.

Linear Motion III Acceleration, Velocity vs. Time Graphs.

VELOCITY-TIME GRAPHS: UNIFORM AND NON-UNIFORM MOTION

Analysis of a position vs. time graph Analysis of a velocity vs. time graph What can be determined from a position vs. time graph? What can be determined.

Constant Velocity and Uniform Acceleration Teacher Excellence Workshop June 18, 2008.

Practicing with Graphs

Motion with Constant Acceleration

Acceleration. Changing Motion Objects with changing velocities cover different distances in equal time intervals.

Acceleration Section 5.3 Physics.

What is the rate change in position called?

Motion in One Dimension

A Mathematical Model of Motion

Uniform Motion. 1) Uniform (rectilinear) motion a) Constant Speed b) straight line c) same direction 2) Speed a) Distance covered in a period of time.

Every slope is a derivative. Velocity = slope of the tangent line to a position vs. time graph Acceleration = slope of the velocity vs. time graph How.

Science Starter! Complete the worksheet “Science Starter!” (on teacher’s desk).

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

Take out the guided reading notes from yesterday and continue working on them - you have 15 minutes before we start notes Take out the guided reading notes.

Linear Kinematics : Velocity & Acceleration. Speed Displacement - the change in position in a particular direction and is always a straight line segment.

Physics Chapter 5. Position-Time Graph  Time is always on the x axis  The slope is speed or velocity Time (s) Position (m) Slope = Δ y Δ x.

Change in position along x-axis = (final position on x-axis) – (initial position on x-axis)

Acceleration & Speed How fast does it go?. Definition of Motion Event that involves a change in the position or location of something.

Quick Quiz Consider the graph at the right. The object whose motion is represented by this graph is ... (include all that are true): moving in the positive.

Chapter 3: Acceleration and Accelerated Motion Unit 3 Accelerated Motion.

Position, Velocity, and Acceleration. Position x.

Acceleration and non-uniform motion.

Kinematics- Acceleration Chapter 5 (pg ) A Mathematical Model of Motion.

Accelerated Motion Merrill Physics Principles and Problems.

Which line represents the greater speed? Graphing motion The greater the speed, the steeper the slope.

Ch1: 1D Kinematics 1.Recall main points: position, displacement, velocity and acceleration (geometrically and algebraically) 2.Discuss Pre-lecture and.

Velocity Acceleration AND. Changing velocities means it is NON-uniform motion - this means the object is accelerating. m/s 2 m/s /s OR = ∆t∆t ∆v∆v a P(m)

Motion Review. What is the difference between an independent and dependent variable?

Ch 2 Velocity ~Motion in One Dimension~. Scalar versus Vector Scalar – quantity that only has magnitude Vector – quantity that has magnitude and direction.

§3.2 – The Derivative Function October 2, 2015.

2.1 Position, Velocity, and Speed 2.1 Displacement  x  x f - x i 2.2 Average velocity 2.3 Average speed  

position time position time tangent!  Derivatives are the slope of a function at a point  Slope of x vs. t  velocity - describes how position changes.

Scalar- number and units Vector- number, unit and direction Position (x)- The location of an object Distance (d)- change in position without regard to.

Accelerated Motion Chapter 3.

READ PAGES Physics Homework. Terms used to describe Physical Quantities Scalar quantities are numbers without any direction Vector quantities that.

Meanings of the Derivatives. I. The Derivative at the Point as the Slope of the Tangent to the Graph of the Function at the Point.

Constant, Average and Instantaneous Velocity Physics 11.

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

§3.1 – Tangent Lines, Velocity, Rate of Change October 1, 2015.

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

Graphs of a falling object And you. Objective 1: Graph a position –vs- time graph for an object falling from a tall building for 10 seconds Calculate.

Graphical Interpretation of Motion in One Dimension

CHAPTER 3 ACCELERATED MOTION

Accelerated Motion Chapter 3.

Position vs. time graphs Review (x vs. t)

Describing Motion.

Motion in One Dimension

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):

Day 7 UNIT 1 Motion Graphs x t Lyzinski Physics.

2.2C Derivative as a Rate of Change

Kinematics Formulae & Problems Day #1

2.7/2.8 Tangent Lines & Derivatives

30 – Instantaneous Rate of Change No Calculator

Velocity-Time Graphs for Acceleration

Presentation transcript:

CHS Physics Instantaneous Velocity &Acceleration

Recall that this is the velocity at any particular instant in time If the direction is removed, it becomes Instantaneous Speed The slope of a line on a position/time plot is the average velocity

Limit Calculation Eventually the calculation ceases to change This is then the slope of a tangent to the curve

The Derivative Taking a Derivative is the same as calculating the Limit The Derivative of the equation gives an equation for the slope of any tangent

The Position Function The Derivative of the position function is the Instantaneous Velocity

Sample Problem 2-2 Plot Velocity vs. Time by analyzing Position vs. Time Break the x(t) plot into three segments The slope of the line is the velocity

Go Backwards The displacement of the elevator? The Area under the curve is displacement Integrating the Function yields displacement

Check Your Understanding Work through Sample Problem 2-3 –An example of derivation and calculating instantaneous velocity CHECKPOINT 3 –Which function shows constant velocity? –Which shows negative velocity?

Average Acceleration Rate of change of velocity

Instantaneous Acceleration Acceleration at any particular instant in time

Col. J. P. Strapp Accelerated to 1020 km/h (634 mi/h) –Photos 1 and 2 Quickly Stopped!! –Photos 3 through 6 –Problem 30E What a Nut!!

Comparing Directions Problem Solving Tactic, page 18 If velocity and acceleration have the same sign, then what is happening to the speed? What do opposite signs indicate?

Sample Problem 2-4 Let’s take a close look