1. Motion & Movement

2. Learning Objectives Can define what a force is
Can explain Newtons 3 laws of motion
Understand the 3 types of motion
Can place this information into a variety of sporting examples

3. Success Criteria Can define Force
Can recall Newtons 3 laws with examples
Can place the types of motion into examples

4. WHAT IS A FORCE?
With a partner 30 seconds discuss

5. FORCE is
A push or pull that alters, or tends to alter, the state of motion of a body
The force applied to the trampoline to allow the downward phase of a jump to change to the upward phase of the next jump
On mini whiteboard give an example and show me

6. 1995?
This is a perfect example of when everything came together within a sporting context.
It shows ultimate knowledge, control and
execution of internal and external forces to
break the World Record.
A distance that still stands since 1995

7. Jonathan Edwards http://www.youtube.com/watch?v=dFt9Yzp484c

8. FORCE FORCE is push or pull the unit is the NEWTON
(10 N is approx the weight of 1 kg)
force changes the state of motion of an object
force causes acceleration or deceleration or change of direction
the more force the bigger the acceleration
force changes the shape of an object
WEIGHT, FRICTION, REACTION FORCES, AIR RESISTANCE / FLUID FRICTION
all these forces affect the sportsperson

9. The 3 Laws

10. Newton’s First Law - INERTIA
An object will continue in a state of rest
or uniform motion unless acted upon by
an external force.
If an unbalanced force acts on an object, it will accelerate in the direction of the unbalanced force.
If an object is given a certain initial velocity and there are no unbalanced forces acting on it, the object will continue along its original path in a straight line.

11. INERTIA
Give 3 examples from sport where you may see this law in practise: 1. 2. 3.
Staying in the blocks in a 100m sprint
A cricket ball will keep travelling after being hit for a 6
The High Jumper will keep going up over the bar
Where is the only location where inertia cannot be influenced?
In space inertia cannot be influenced by external factors therefore on Earth everything can be influenced. The sprinter will not stay in the blocks for ever and the ball will fall and the higher jumper won’t always clear a height...why?

12. Newton’s Second Law - Acceleration
When a force acts on an object, the
object is accelerated by an amount
directly proportional to the force
applied and inversely proportional
to the mass of the object
(F = ma) force = mass x acceleration
The greater the force being exerted on an object, the faster the object moves.
The greater the mass of the object, the
slower the object will move in relation to a lighter object with the same force applied.   
A big mass (tennis ball) is harder to accelerate than a smaller mass (table tennis ball).
Simply: 10N force against a tennis ball or a shot putt which travels furthest

13. Newton’s Second Law - Hockey
If a player strikes the ball, its acceleration
is determined by the mass of the ball
and how hard the player hits it (F = ma).
If the ball were heavier (larger mass), it would accelerate less.
If the player hits the ball harder (larger force), the ball accelerates more quickly. F M A

14. Newton’s Second Law - Baseball
A baseball player on deck getting ready to bat adds weights to their bat to practice swinging, and to warm up their muscles. 
If the total mass of the weights added is equal to the initial mass of the bat, then the weight is doubled. 
If the batter swings at a constant speed (a), and applies a uniform force throughout (F), we can apply Newton’s Second Law.
When he removes the weights, the mass is cut in half, and the acceleration will be twice as fast as before. 
A batter gets an advantage if he uses Newton’s Second Law before stepping onto the plate.

15. Newton’s Second Law - Baseball
Q1. A batter swings with 200N of force on deck circle, with weights attached making the bat twice as heavy as usual. What is the bat’s acceleration: a) on the on deck circle? b) at the plate when the weights have been removed? Q2. A bat has an acceleration of 80m/s2. What force was applied to the bat? Q3. A batter at the plate swings with a force of 100N. What is the bat’s acceleration? How does this compare to the answer to Q1.b?
Note: A bat has a mass of 2 kg.

16. Newton’s Second Law - Baseball
A1. a) F = ma b) F = ma a = F/m a = F/m a = 200N/4kg a = 200N/2kg a = 50m/s2 a = 100m/s2 A2. F = ma F = 2kg x 80m/s2 F = 160N A3. F = ma The force applied is a = F/m half that in Q1.b, a = 100N/2kg therefore, the a = 50m/s2 acceleration is halved.

17. Newton’s Third Law - Reaction
“For every action there is an equal
and opposite reaction”
For every force between two objects there is always an equal but oppositely directed force.
The normal reaction force is
the support force exerted upon
an object which is in contact
with another stable object.
Question:
When hitting a baseball, if we call the force on the bat against the ball the action force, what is the reaction force?
Normal reaction force
Weight

18. The reaction force is the force exerted by the ball on the bat.
Newton’s Third Law
When a swimmer turns, the pool wall pushes against the swimmer with the same force as the swimmer pushes against the pool wall.
When a weightlifter pushes against the ground, the ground pushes against the weightlifter with the same force.
When a tennis player hits a ball with their racquet, the tennis ball exerts an equal but opposite force on the player’s racquet.
Can you think of any more examples?
Answer:
The reaction force is the force exerted by the ball on the bat.

19. Newton’s Third Law - Hockey
For every force exerted by an object, an equal and opposite force is exerted on the object.

20. Homework Sentence Summary:
Write a series of sentences to summarise Newton’s Laws.
Give examples of two Olympic sports you can show Newton’s Laws working.
Write an equation for the 2nd law

21. Success Criteria Can define Force
Can recall Newtons 3 laws with examples
Can place the types of motion into examples

22. MOTION

23. MOTION Motion is movement and is divided into 3 main categories:
LINEAR MOTION
GENERAL MOTION
ANGULAR MOTION

24. LINEAR MOTION
When a body moves in a straight or curved line with its parts moving the same distance in the same direction at the same speed
E.g.. A tobogganist
Shot put ( curved line with no spin imparted at release)
What else?......Show me......
Linear motion occurs when a force is applied through the centre of mass of the body/object

25. ANGULAR MOTION
When a body or part of a body moves in a circle or part of a circle about a particular point called the axis of rotation.
-Bicycle wheel
-Movement around our joints (fixed points)
-Front crawl in swimming (ARMS)
-The high bar in men’s Olympic gymnastics

26. GENERAL MOTION A combination of linear and angular motion
Javelin thrower
Wheel chair athlete
Sprinter
Swimmer
This is by far the most common motion type in
Sport

27. Examples of motion in sport
Linear:
Angular:
General:

28. TASK
IN GROUPS USING AS MANY DIFFERENT SPORTS AS YOU CAN THINK OF, LIST:
Three examples of pure linear motion
Three examples of pure angular motion
Three examples of general motion

29. CENTRE OF MASS
The ‘Centre of Mass’ is where the weight of a body tends to be concentrated.
This is the point at which the body is ‘balanced in all directions’
Therefore in objects such a tennis balls and shot
putts the c.o.m. Would be at the very core.

30. However c. o. m. can be outside the body
However c.o.m. can be outside the body. In humans this is not in the same position but moves constantly as we do.
A coit used in primary schools for play the c.o.m. Is in the centre, but there is nothing there

31. A prime example in sport is the high jump At this moment the c. o. m
A prime example in sport is the high jump At this moment the c.o.m. is outside the body underneath the back

33. It is only really feasible in moving objects especially people and animals that the c.o.m. Is identified if the body is STABLE. Stability is important for balance, gymnastics is a good example such as the beam

34. Stability is dependent upon these factors:
Position of the centre of mass
Base of support
Performers line of gravity
Mass of the performer

35. Stability This is a stable position because….
It would become less stable by……
Stability
Centre of Mass
Base of Support
Line of Gravity

36. Centre of Mass and Application of Force
The direction of the force being applied, in relation to the centre of mass, will dictate if the motion is linear or angular.
If the line of the force is through the centre of mass the resulting motion will be linear. This is called a direct force.
If the line of force passes outside the centre of mass the motion will be angular.
This is called an eccentric force.

37. Centre of Mass and Application of Force
Ball spins – angular motion.
Ball goes up but with no spin – linear motion.
Liner Motion
Angular Motion
Force applied through centre of mass – direct force.
Force applied to side of ball – eccentric force.
The more spin needed the greater the force and the further away from the centre of mass it needs to be applied.