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Representing Motion Chapter 2 (pg 30-55)

Representing Motion

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Representing Motion . Chapter 2 ( pg 30-55). Do Now. Why is it important to describe and analyze motion ? How fast? How far? Slowing/Speeding? Rest/Constant velocity What are some of the different types of motion ? Translational – motion along a straight line - PowerPoint PPT Presentation

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Page 1: Representing  Motion

Representing Motion Chapter 2 (pg 30-55)

Page 2: Representing  Motion

Do Now

• Why is it important to describe and analyze motion?• How fast?• How far?• Slowing/Speeding?• Rest/Constant velocity

• What are some of the different types of motion?• Translational – motion along a straight line• Circular – motion along a circular path • Rotational – Rotation about a fixed point

Page 3: Representing  Motion

Chapter Objectives

●Represent motion through the use of words, motion diagrams, and graphs.

●Use the terms position, distance, displacement, and time interval in a scientific manner to describe motion.

Page 4: Representing  Motion

Motion • Motion is instinctive

• Eyes will notice moving objects more readily than stationary ones

• Object changes position

• Motion can occur in many directions and paths

Page 5: Representing  Motion

(2.1)Picturing Motion (2.2) Where and When? • Analyze motion diagrams to describe motion.

• Develop a particle model to represent a moving object.

• Define coordinate systems for motion problems and recognize

that it affects the sign of an object’s position.

• Define displacement.

• Use a motion diagram to answer questions about an object’s

position or displacement.

Page 6: Representing  Motion

Picturing Motion

• A description of motion relates to a PLACE and TIME.• Answers the questions WHERE? and

WHEN?

PLACE

TIME

Page 7: Representing  Motion

Motion Diagrams • Series of images showing the

positions of a moving object at equal time intervals.

Page 8: Representing  Motion

Particle Model • Simplified version of a

motion diagram in which the object in motion is replaced by a series of single points. • Size of object much less

than the distance moved • Internal motions of object

ignored

Page 9: Representing  Motion

Particle Model

Page 10: Representing  Motion

Motion Diagram & Particle Model

Page 11: Representing  Motion

Practice

•Draw a particle model for the motion diagram above of a car coming to a stop.

Page 12: Representing  Motion

Describe the motion of the bird…

Draw a particle model….

Page 13: Representing  Motion

Use the particle model to draw motion diagrams for two runners in a race. When the first runner crosses the finish line, the second runner is ¾ of the way to the finish line.

• First Runner

• Second Runner Must have same number of particles to represent equal

time.

Page 14: Representing  Motion

How are the two particle models different? Describe the motion of each.

A.

B.

A. Eight time intervals & Constant velocity (equal spacing)

B. Five time Intervals & speeding up (spacing is getting farther)

Page 15: Representing  Motion

Which statement describes best the motion diagram of an object in motion?

A. a graph of the time data on a horizontal axis and the position on a vertical axis

B. a series of images showing the positions of a moving object at equal time intervals

C. a diagram in which the object in motion is replaced by a series of single points

D. a diagram that tells us the location of the zero point of the object in motion and the direction in which the object is moving

Page 16: Representing  Motion

What is the purpose of drawing a motion diagram or a particle model?

A. to calculate the speed of the object in motion

B. to calculate the distance covered by the object in a particular time

C. to check whether an object is in motion

D. to calculate the instantaneous velocity of the object in motion

Page 17: Representing  Motion

Coordinate System• Tells you the location of the zero point of the

variable you are studying and the direction in which the values of the variable increase.

• ORIGIN• The point at which both variables have the

value zero

Page 18: Representing  Motion

Coordinate System• Motion is RELATIVE

• You can define a coordinate system any way you want, but some are more useful than others.

Page 19: Representing  Motion

Coordinate systems

• This coordinate system works as well but is not as convenient to use as the first one.

• Try to always pick your origin where motion begins.

Axis of the coordinate system

Page 20: Representing  Motion

Position & Distance • You can indicate how far an object is from the

origin by drawing an arrow from the origin to the point representing the object.

• The two arrows indicate the runner’s POSITION at two different times. (vector)• Separation between an object and the origin

• The length of how far an object is from the origin indicates DISTANCE. (scalar)

Page 21: Representing  Motion

Refer to the figure and calculate the distance between the two signals?

A. 3 m

B. 8 m

C. 5 m

D. 5 cm

Page 22: Representing  Motion

Vectors & Scalars

• SCALARS: quantities that are just numbers without any direction• Magnitude (number) only • Examples: time, volume, mass,

temperature

• VECTORS: quantities that have both magnitude (size) and direction• Represented by arrows • Examples: velocity, acceleration, force, momentum

Tail

Tip

Page 23: Representing  Motion

Vector Addition: Tail to Tip • Just like you can add scalars, you can also add vectors.

• Algebraically (look at later) & Graphically • Place vectors tail to tip

• Place the tail of the 2nd vector next to the tip of the 1st vector• RESULTANT - the vector that represents the sum of two or more

other vectors• is drawn from the tail of the first vector to the tip of the last vector.

Page 24: Representing  Motion

Example: Add the three vectors

Vector 1

Vector 2

Vector 3

Page 25: Representing  Motion

Resultant

Like scalars, vectors can be added in different order and still have the same resultant.

Vector 1

Vector 2

Vector 3

RESULTANT

Vector 1

Vector 2

Vector 3

RESULTANT

Page 26: Representing  Motion

Distance vs. Displacement• DISTANCE

• Actual length traveled• Scalar measurement • Path dependent

• DISPLACEMENT• Change in position• Vector measurement • Path independent

∆x = xf – xi

Page 27: Representing  Motion

Distance vs. Displacement

• Find distance and displacement for the following races:

Race Distance Displacement

100 m

400 m

1 mile

Page 28: Representing  Motion

PracticeEx: Jared walks 75 m down the block heading east when he realizes he dropped his book. He turns around and walks 15 m until he finds his book.

• Draw vectors to represent Jared’s motion.• Find the distance that Jarred walked.• Find Jared’s displacement.

Page 29: Representing  Motion

What is displacement?

• A. the vector drawn from the initial position to the final position of the motion in a coordinate system

• B. the distance between the initial position and the final position of the motion in a coordinate system

• C. the amount by which the object is displaced from the initial position

• D. the amount by which the object moved from the initial position

Page 30: Representing  Motion

Ch. 2.3 Objectives

• Develop position-time graphs for moving objects.

• Use position-time graphs to interpret an object’s position or displacement.

• Make motion diagrams, pictorial representations, and position-time graphs that are equivalent in describing an object’s motion.

Page 31: Representing  Motion

Graphs• Named as y-axis vs. x-axis • Also as Dependent vs. Independent

• Ex. Position vs. time• Place position on the y-axis and time on the x-axis

Always play close attention to the units.

Units are key to analyzing graphs…

Page 32: Representing  Motion

Analyzing Graphs

Slope:Look at the units of the slope to

see if it corresponds to a measurement.

Area: look at the units for the area under the curve to see if it corresponds to a measurement.

Page 33: Representing  Motion

Position-Time Graphs

x-axis: Independent

variable

SLOPE: Rise/Runm =

Velocity

Where?&

When?

Area (m*s) No Meaning

y-axis Dependent

Variable

Page 34: Representing  Motion

From the following position-time graph of two brothers running a 100-m dash, at what time do both brothers have the same position? At what position?

At about 6 seconds

At about 60 meters

Page 35: Representing  Motion

Position-Time Graphs

• When does runner B pass runner A?• 45 seconds into the race

• Where does runner B pass runner A?• 190 m

Page 36: Representing  Motion

Position-Time Graphs• What is the displacement of the runner between 5 s

and 10 s? 10 m

Page 37: Representing  Motion

What is happening in this graph?

Page 38: Representing  Motion

What is happening in each?

A.

B.

C.

D.

Page 39: Representing  Motion

Position-Time Graph - SLOPE

• Analyze the units • Slope = rise over run

• m = ∆y / ∆x • Slope = m / s • m/s is the unit for velocity

• The slope of a position-time graph is the average velocity

Page 40: Representing  Motion

Position-Time Graph - AREA• Analyze units only • Area under the curve

• Area of a triangle A = ½ b * h• ½ is a constant and has no units• Base has units of time (s)• Height has units of position (m)

• Area = (m)(s)

• We do not have any measurements that have the units (s)(m): thus the area of a position-time graph does not have any meaning.

Page 41: Representing  Motion

Ch. 2.4 Objectives

• Define Velocity

• Differentiate between speed and velocity

• Create pictorial, physical, and mathematical

models of motion problems

Page 42: Representing  Motion

Average Velocity • Defined as the change in position, divided by the

time during which the change occurred.• How fast in a given direction?• Vector quantity

• Same direction as the displacement (Δx)

𝒗𝒂𝒗𝒈=∆ 𝒙∆ 𝒕 =

𝒙 𝒇− 𝒙 𝒊

𝒕 𝒇− 𝒕𝒊

Page 43: Representing  Motion

Average Speed• The absolute value of the slope of a

position-time graph.• It describes how fast the object is moving.

𝑠=𝑑𝑡

Page 44: Representing  Motion

Instantaneous Velocity

• Velocity at a given instant • Slope of the line drawn on the x-t graph at the given

instant • Need calculus to find unless object moving at a

constant velocity

Page 45: Representing  Motion

Velocity vs. Speed

• Speed is the distance divided by the time during which the distance was traveled.• Scalar (No direction)

Race Distance (m) Displacement (m)

Time (s) Speed (m/s) Velocity (m/s)

100 m 20

400 m 80

1 mile 400

Page 46: Representing  Motion

Position-Time Graphs - Velocity

Suppose you recorded two joggers in one motion diagram, as shown in the figure above. From one frame to the next, you can see that the position of the jogger in red shorts changes more than that of the one wearing blue.

What would the x-t graph look like if they both started at the same time?

Page 47: Representing  Motion

Position-Time Graphs• You can create a position-time graph if you know the

position and time of the joggers at different points.

• Need a minimum of two data points in order to create a x-t graph.

Page 48: Representing  Motion

Position-Time Graphs (velocity)• Can find the velocity of each jogger by calculating the

slope of the line. • Red Jogger

• v = m = (6m – 2 m)/ (3s – 1s)• v = 2 m/s

• Blue Jogger• v = m = (3m – 2m) / (3s – 2s)• v = 1 m/s

Page 49: Representing  Motion

What is happening?

1 - Compare the velocities for each of the segments.

2- Rate the segments in increasing speed.