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Transcript
Newton 3 & Vectors
Action/Reaction
• When you lean
against a wall,
you exert a
force on the
wall.
• The wall
simultaneously
exerts an
equal and
opposite force
on you.
You Can OnlyTouch as Hard
as You Are Touched
• He can hit the
massive bag with
considerable
force.
• But with the same
punch he can
exert only a tiny
force on the
tissue paper in
midair.
Newton’s Cradle
• The impact forces between the blue and
yellow balls move the yellow ball and stop
the blue ball.
Naming Action & Reaction
• When action
is “A exerts
force on B,”
• Reaction is
then simply
“B exerts
force on A.”
Vectors
• A Vector has 2
aspects
– Magnitude (r)
(size)
– Direction
(sign or angle) (q)
Vectors can be represented by arrows
Length represents the magnitude
The angle represents the direction
Reference Systems
q
q
Vector Quantities
•
•
•
•
•
•
Displacement
Velocity
Acceleration
Force
Momentum
(3 m, N) or (3 m, 90o)
Vector Addition
Finding the Resultant
Head to Tail Method
Resultant
Resultant
Parallelogram Method
A Simple Right Angle
Example
Your teacher walks 3 squares south and then 3
squares west. What is her displacement from
her original position?
This asks a compound question: how far has she
walked AND in what direction has she walked?
Problem can be solved
using the Pythagorean
E theorem and some
knowledge of right
3 squares
triangles.
N
3 squares
W
Resultant
S
4.2 squares, 225o
A W
A  (136m,56 )
o
W  (64m,305 )
o
Scale :1cm  20m
Getting the Answer
Resultant
1.
Measure the length of the
resultant (the diagonal). (6.4
cm)
2.
Convert the length using the
scale. (128 m)
3.
Measure the direction counterclockwise from the x-axis. (28o)
A  W  (128m, 28 )
o
Boat in River Velocity
vboat , shore  vboat , water  vwater , shore
Airplane Velocity Vectors
v plane, ground  v plane, air  vair , ground
Rope Tensions
• Nellie Newton
hangs motionless
by one hand from
a clothesline. If
the line is on the
verge of
breaking, which
side is most likely
to break?
Where is Tension Greater?
• (a) Nellie is in equilibrium – weight is balanced by
vector sum of tensions
• (b) Dashed vector is vector sum of two tensions
• (c) Tension is greater in the right rope, the one
most likely to break
Vector Components
Resolving into Components
• A vector can be
broken up into 2
perpendicular
vectors called
components.
• Often these are in
the x and y
direction.
Components Diagram 1
A = (50 m/s,60o)
Resolve A into x and y components.
Let 1 cm = 10 m/s
1. Draw the coordinate system.
2. Select a scale.
N
3. Draw the vector to scale.
5 cm
60o
W
E
S
Components Diagram 2
A = (50 m/s, 60o)
Resolve A into x and y components.
4. Complete the rectangle
Let 1 cm = 10 m/s
N
Ay = 43 m/s
W
E
Ax = 25 m/s
S
a. Draw a line from the
head of the vector
perpendicular to the xaxis.
b. Draw a line from the
head of the vector
perpendicular to the yaxis.
5. Draw the components along
the axes.
6. Measure components and
apply scale.
Vector Components
Vertical
Component
Ay= A sin q
Horizontal
Component
Ax= A cos q
Signs of Components
(x,y) to (R,q)
qq
D  Dx  D y
2
2
 Dy 

  tan 
 Dx 


1
q  360  
o
• Sketch the x and y components in
the proper direction emanating
from the origin of the coordinate
system.
• Use the Pythagorean theorem to
compute the magnitude.
• Use the absolute values of the
components to compute angle  -the acute angle the resultant
makes with the x-axis
• Calculate q based on the quadrant