biomechanics module testaudio
TRANSCRIPT
Biomechanics Module
Newton’s laws
Musculoskeletal levers and mechanical advantage
Classification of force systems
Vector addition and resolution
Newton’s Laws
Law of Inertia
Law of Acceleration
Law of Action-Reaction
Biomechanics Module
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Law of Inertia (equilibrium)
3 Hall, Basic Biomechanics, 5th ed
Biomechanics Module
Law of Inertia (equilibrium)
Biomechanics Module
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Law of Acceleration
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Biomechanics Module
Law of Acceleration
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Biomechanics Module
Law of Acceleration
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Biomechanics Module
10 pounds
Law of Acceleration
Biomechanics Module
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B
Newton’s Laws
Law of Inertia
Law of Acceleration
Law of Action-Reaction
Biomechanics Module
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Within object
Between objects
Law of Action-Reaction
For every action, there is an equal and opposite
reaction
(Forces occur in pairs)
Between two objects
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Biomechanics Module
Law of Action-Reaction
For every action, there is an equal and opposite
reaction
(Forces occur in pairs)
Between two objects
Objects must be in contact
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Biomechanics Module
Law of Action-Reaction
For every action, there is an equal and opposite
reaction
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Biomechanics Module
Law of Action-Reaction
Ground reaction force
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Hall, Fig 12-1
Body
weightGRF =
Biomechanics Module
Musculoskeletal Levers
Why is Charlie Brown up in the air?
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Biomechanics Module
Musculoskeletal Levers
Why is Charlie Brown up in the air?
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Biomechanics Module
Musculoskeletal Levers
(Force A)(MAA) vs (Force B)(MAB)
Charlie Brown is up in the air if: (Charlie’s force)(MA) < (Linus’ force)(MA)
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Force A
Force Bfulcrum,
pivot point
MAA MAB
Biomechanics Module
Musculoskeletal Levers
Interaction between the forces or loads on the
segment and the joint
Levers: two forces and a pivot point (fulcrum, axis) Internal force (muscle)
External load (gravity etc)
Pivot point (joint)
(N.B. not consistent w/ Levangie)
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Biomechanics Module
Musculoskeletal Levers
First class lever
Second class lever
Third class lever
Differentiated by the relative position of the internal force, external
load, and pivot point
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Biomechanics Module
Musculoskeletal Levers
First class lever
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Internal
force
fulcrum, pi
vot point
Biomechanics Module
Musculoskeletal Levers
Second class lever
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Internal
force
fulcrum,
pivot point
Biomechanics Module
Musculoskeletal Levers
Third class lever
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Internal
force
fulcrum,
pivot point
Biomechanics Module
Mechanical advantage
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Biomechanics Module
Mechanical advantage
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Ext Int
fulcrum,
pivot point
External MA Internal MA=
First Class Lever
Mech Adv = 1 if
fulcrum in middle
Ext
Biomechanics Module
Mechanical advantage
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External MA Internal MA<
Int
fulcrum
Second Class Lever
Mech Adv > 1
Ext
Biomechanics Module
Mechanical advantage
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External MA Internal MA>
Int
fulcrum
Third Class Lever
Mech Adv < 1
Ext
Biomechanics Module
Classification of force systems
Linear same segment
same plane
same line
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Biomechanics Module
Classification of force systems
Linear same segment
same plane
same line
Concurrent same segment
same plane
common point of application
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Biomechanics Module
Classification of force systems
Linear same segment
same plane
same line
Concurrent same segment
same plane
common point of application
Parallel same segment
same plane
parallel to each other
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Biomechanics Module
Fun with Forces
Vector addition Composition
Tip to tail
Parallelogram
Vector resolution Graphical
Trigonometric
Application to human movement Parallel forces
Perpendicular forces
Biomechanics Module
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Vector addition
Composition Works with collinear vectors
Same direction (addition)
Opposite direction (“subtraction”)
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Hall, Fig 3-11, 3-12
Biomechanics
+ =
+ =
Vector addition
Addition (composition)
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Hall, Fig 3-11, 3-12
Works with collinear vectors
Biomechanics
Vector addition
Addition (composition)
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Hall, Fig 3-11, 3-12
Works with collinear vectors
Biomechanics
Vector Addition
Tip to tail Concurrent vectors (vectors which can intersect)
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Hall, Fig 3-13
Biomechanics
+ =
+ =
=
=
Vector addition
Addition – tip to tail
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Hall, Fig 3-13
Biomechanics
Vector addition
Addition – tip to tail
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Hall, Fig 3-13
Biomechanics
Vector Addition
Addition – parallelogram
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Hall, Fig 3-13
Biomechanics
+ =
+ =
=
=
Vector addition
Addition – parallelogram
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Hall, Fig 3-13
Biomechanics
Vector addition
Addition – parallelogram
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Hall, Fig 3-13
Biomechanics
Vector Resolution
Resolving a vector into perpendicular components
Methods: Graph paper
Trigonometry
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Biomechanics
Vector Resolution
Graphically
40 Hall, Fig 3-15
Biomechanics
Vector Resolution
Graphically
41 Hall, Fig 3-15
Biomechanics
Vector Resolution
Graphically
42 Hall, Fig 3-15
Biomechanics
Vector Resolution
Trigonometric
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Hall, Fig 3-15
Angle Sin Cos
0 0 1
30 0.50 0.87
45 0.71 0.71
55 0.82 0.57
60 0.87 0.5
90 1 0
Biomechanics
60
°
30°
opposite
oppositeadjacent
adja
cent
Vector Resolution
Trigonometric
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Hall, Fig 3-15
Angle Sin Cos
0 0 1
30 0.50 0.87
45 0.71 0.71
55 0.82 0.57
60 0.87 0.5
90 1 0
Biomechanics
60°
30°
opposite
oppositeadjacent
adja
cent
Vector Resolution
Trigonometric
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Hall, Fig 3-15
Angle Sin Cos
0 0 1
30 0.50 0.87
45 0.71 0.71
55 0.82 0.57
60 0.87 0.5
90 1 0
Biomechanics
60°
30°
opposite
oppositeadjacent
adja
cent
8.7
5.0
10
Vector Resolution
Trigonometric
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Hall, Fig 3-15
Angle Sin Cos
0 0 1
30 0.50 0.87
45 0.71 0.71
55 0.82 0.57
60 0.87 0.5
90 1 0
Biomechanics
60°
30°
opposite
oppositeadjacent
adja
cent
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Vector Resolution
Trigonometric
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Hall, Fig 3-15
Angle Sin Cos
0 0 1
30 0.50 0.87
45 0.71 0.71
55 0.82 0.57
60 0.87 0.5
90 1 0
Biomechanics
60°
30°
opposite
oppositeadjacent
adja
cent
8.7
5.0
8.7
5.0
10 10
Vector Resolution
Trigonometric
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Hall, Fig 3-15
55
°
Angle Sin Cos
0 0 1
30 0.50 0.87
45 0.71 0.71
55 0.82 0.57
60 0.87 0.5
90 1 0
Biomechanics
20cos(55) = 11.4
20sin
(55)
= 1
6.4
Vector Resolution
Trigonometric
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Hall, Fig 3-15
55°
45°
30°
Angle Sin Cos
0 0 1
30 0.50 0.87
45 0.71 0.71
55 0.82 0.57
60 0.87 0.5
90 1 0
Biomechanics
Hypotenuse = 100
Vector Resolution
Trigonometric
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Hall, Fig 3-15
55°
45°
30°
Angle Sin Cos
0 0 1
30 0.50 0.87
45 0.71 0.71
55 0.82 0.57
60 0.87 0.5
90 1 0
Biomechanics
Hypotenuse = 100
82
57
71
71
87
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Vector Resolution
Trigonometric How does angle change the composition?
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Angle Sin Cos
0 0 1
30 0.50 0.87
45 0.71 0.71
55 0.82 0.57
60 0.87 0.5
90 1 0
Biomechanics
90° 60° 45° 30° 0°
Application to human movement
Resolve force into:
Perpendicular force
Rotation
Parallel force
Compression
Position dependent
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perpendicular
parallel
Biomechanics Module
End of Biomechanics Module
Don’t forget to take the quiz
Biomechanics Module
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