University of Nicosia Medical School Lectures - Week 1 PDF

Summary

This document contains introductory lectures for a medical physics course at the University of Nicosia Medical School. The lectures cover fundamental physics concepts, including units, quantities, and terminology.

Full Transcript

INTRODUCTION

Dr Anastasia Hadjiconstanti
Prof Vered Aharonson

Aknowledgements: Dr C.Zervides
WELCOME TO THE WORLD OF
 Medicine and Physics

List the Treatment
Chief Obtain Examination and
differential and
complaint history tests
diagnosis evaluation

Use data
Select further Final
to narrow the
tests diagnosis
diagnosis
More than one Only one
likely likely
 MEDICAL PHYSICS - DEFINITION

Two major areas:

1. Application of physics principles to the understanding of the function of the human body
in health and disease (PHYSICS OF PHYSIOLOGY).

2. Application of physics in the instrumentation used in diagnosis, monitoring and treatment
(CLINICAL MEDICAL PHYSICS).
 Topics covered in MED 101
WEEK TOPIC
1 Introduction, Motion and Statics of the body
2 Energy
Kinematics, dynamics, and energetics of human
3
motion and human body collisions
Elastic properties of the body and bone fractures
4
and Thermodynamics
Fluid pressure, fluid flow in the body and motion
5
in fluids
6 Midterm
7 Lungs and breathing
8 Sound, speech and hearing
9 Light, eyes and vision
10 Electric properties of the body
12 Review
 LECTURE LOB’S

1. DESCRIBE THE CONCEPT OF UNITS.

2. DESCRIBE THE CONCEPTS OF ACCURACY, UNCERTAINTY AND SIGNIFICANT FIGURES.

3. DESCRIBE THE CONCEPT OF KINEMATICS (TIME, DISTANCE, DISPLACEMENT, SPEED,
VELOCITY & ACCELERATION)

4. UNDERSTAND THE RELATIONSHIPS BETWEEN TIME, DISPLACEMENT, VELOCITY, AND
ACCELERATION.

5. UNDERSTAND THE DISTINCTION BETWEEN AVERAGE AND INSTANTANEOUS VELOCITY AND
ACCELERATION.
 UNITS I
Physics is not mathematics, although a considerable amount of mathematics can be required
when solving physics problems.

Physics, like all sciences, is based on the verification of theories by experiments.

Physics is about quantities and not about numbers.

A distance of 5 m is different from a time of 5 s, even though the number 5 is used in both
cases.

This is why physicists insist on the use of units.
 UNITS II
A unit is a carefully defined amount of a quantity.

The measurement of each physical quantity on its own units, by comparison with a standard.

The unit is a unique name we assign to measures of that quantity
– In example, meter (m) is the unit for the quantity length.
 UNITS III

Almost all measurable quantities in physics may be expressed in terms of a small number
of fundamental types of quantity.

These fundamental quantities are: LENGTH, TIME, MASS, ELECTRICAL CURRENT,
TEMPERATURE, AMOUNT OF SUBSTANCE AND LUMINOSITY.

Most properties of the physical world not included in this list, may be constructed as a
combination of these fundamental properties,
In example, speed is the ratio of a length to a time.

This fact allows us to define systems of units.
 UNITS IV
A system of units is a convention which defines the standard amounts or units of a set of
fundamental quantities.

These are called base units.

The system of units used almost exclusively in science is the SI system.

The SI system of units is a metric system, i.e., a system based on the number 10.

In this system the unit of length is the metre (m), the unit of time is the second (s) and the
unit of mass is the kilogram (kg).

The other base units in the SI system can be found in the Table that follows.
Origin of the SI units
UNITS V – TABLES FOR SI UNITS
 UNITS VI
There are many other units in use for quantities other than those described by the base SI
units.

The table in the previous slide had a short list of units for such quantities.

Some of these quantities have their own named unit such as the unit of force, the newton.

Such units are often named after famous scientist.

All of these other units can, however,
be expressed as a combination of the six base
SI units.
Some definitions, and medical terminology

A common language is essential for a “Pericarditis“
meaningful communication prefix: peri- = “surrounding”
root: cardi = “heart”
Medical terms are international, suffix: -itis = “inflammation”
derived from Greek and Latin = an inflammation of the area
surrounding the heart
construction of the medical terms:
root (word base) “Phonocardiography“
prefixes phono = sound;
suffixes cardi = heart;
linking or combining vowels graph = write
= graphic recording of heart sounds
 UNITS VII - TERMINOLOGY
This system of units also specifies a set of prefixes which are prepended to the unit to indicate
quantity in powers of 10 : N X 10x {Unit}
N: Numbers
10: Base
x: Exponent

Note: 10-x à 1/10x

Each prefix has a specific name.

Each prefix has a specific abbreviation.
Nano-, micro-, milli-, centi-, …, kilo-, mega-, giga-, tera-
10-9 …………………………………………………………………………………………………………1012

These prefixes make it easier to refer to very large or very small numbers.
 UNITS VIII – PREFIXES TABLE

There are many more, but these are the ones which will be useful in this course.

Symbol Name Multiplication
p pico 1 x 10-12
n nano 1 x 10-9
μ micro 1 x 10-6
m milli 1 x 10-3
k kilo 1 x 103
M Mega 1 x 106
G Giga 1 x 109
T Tera 1 x 1012
 UNITS IX – CHANGING UNITS

We often need to change the units in which a physical quantity is expressed.

We do so by a method called chain – link conversion.

In this method, we multiply the original measurement by a conversion factor
(a ratio of units that is equal to unity).
 CLASS EXAMPLE I: Changing units

Because 1 min and 60 s are identical time intervals, we have

1min 60 s
=1 and =1
60s 1min
Thus, the ratios can be used as conversion factors.

This is NOT the same as writing or
1 60
=1 =1
60 1
Each number and its unit must be treated together.
 CLASS EXAMPLE II: Changing units

Because multiplying any quantity by unity leaves the quantity unchanged, we can introduce
conversion factors wherever we find them useful.
In chain – link conversion, we use the factors to cancel the unwanted units. For example, to
convert 2 min to seconds, we have

æ 60 s ö
2 min = (2 min) (1) = (2 min) ç ÷ = 120 s
è 1min ø
If you introduce a conversion factor in such a way that unwanted units do not cancel, invert
the factor and try again.

In conversions, the units obey the same algebraic rules as variables and numbers.
 ACCURACY, UNCERTAINTY AND SIGNIFICANT FIGURES I

In science, accuracy and precision have different meanings.

Accuracy refers to how close a given measurement is to an accepted standard.

Precision refers to the reproducibility of a measurement and is not necessarily related to the
accuracy of the measurement.

In general it is desirable to have both good accuracy and precision.

Unfortunately sometimes accuracy is limited by uncontrollable factors, i.e. difficult in
measuring internal parts of the body accurately (amount of mineral in bones).

DEXA has a precision of ≈1% and an accuracy of 3 to 4 % but it is used for managing
osteoporosis.
Accuracy, Precision, Uncertainty - Illustration
Accuracy = a description of how close a
measurement is to the correct or accepted
value of the quantity measured.

Precision = the degree of exactness of a
measurement.

uncertainty = a numeric measure of
confidence in a measurement or result.
A lower uncertainty indicates greater
confidence.

Prof. Vered Aharonson 2018 26
 ACCURACY, UNCERTAINTY AND SIGNIFICANT FIGURES II

The numerical values of physical quantities cannot be given with infinite precision.

A common convention used in science to indicate precision is known as significant figures.
The numerical value of a physical quantity will be given to a number of significant figures,
Depending on the nature of the calculation.

The number of significant figures is, with some conditions, the number of digits given.
In example: he acceleration due to gravity may be given as 9.8 ms−2 or as 9.81 ms−2.
In 9.8 ms−2 there are two digits so there are two significant figures (2 s.f.)
In 9.81 ms−2 there are three significant figures (3 s.f.).

Numbers with more significant figures are more precise than numbers with fewer
significant figures.
Significant Figures - illustration
Even though this ruler is marked in only
centimeters and half-centimeters, if you
estimate, you can use it to report
measurements to a precision of a millimeter.
 ACCURACY, UNCERTAINTY AND SIGNIFICANT FIGURES III

If a physical quantity is given to two significant figures there is an implicit uncertainty in
the final digit.
9.8 ms−1 may be read as 9.8 ± 0.05 ms−1.

This implicit uncertainty implicate on the use of inexact numerical values in calculations.
In example, the solution to a calculation involving quantities given to two significant figures should not
be given to four or five significant figures.

Practically:

How many significant figures should be quoted in a solution of a calculations?

What if the numbers used in the calculation have different numbers of significant
figures?
 ACCURACY, UNCERTAINTY AND SIGNIFICANT FIGURES IV
For our purposes, three simple rules of thumb will suffice:

1. Use all available digits in the calculation.
Round the solution and not the intermediate steps.

1. When multiplying or dividing two numbers the solution should be rounded to the same
number of significant figures as the number in the calculation that had the least
significant figures.
𝟐. 𝟑×𝟑. 𝟏𝟓𝟏𝟓𝟗 = 𝟕. 𝟐𝟒𝟖𝟔𝟓𝟕 = 𝟕. 𝟐

3. When adding or subtracting numbers the solution should be rounded to the same
number of decimal places as the number in the calculation that had the least number of
decimal places.
𝟏𝟎. 𝟏 + 𝟏𝟐. 𝟑𝟔𝟕 + 𝟎. 𝟒𝟓𝟗 = 𝟐𝟏. 𝟗𝟐𝟔 = 𝟐𝟏. 𝟗 (𝟏 𝒅. 𝒑. )
 ACCURACY, UNCERTAINTY AND SIGNIFICANT FIGURES V
Example Number of Scientific
Significant Notation
Figures
Leading zeros are never significant.
Imbedded zeros are always 0.00682 3 6.82 x 10-3 Leading zeros
significant. are not
Trailing zeros are significant only if significant
the decimal point is specified. 1.072 4 1.072 (x 100) Imbedded zeros
are always
Hint: Change the number to scientific significant.
notation. It is easier to see.
300 1 3 x 102 Trailing zeros are
significant only if
300. 3 3.00 x 102 the decimal
point is specified
300.0 4 3.000 x 102
32
ACCURACY, UNCERTAINTY AND SIGNIFICANT FIGURES VI
CLASS EXAMPLE III

When adding or subtracting numbers the solution should be rounded to the same
number of decimal places as the number in the calculation with the least number of
decimal places.
33
ACCURACY, UNCERTAINTY AND SIGNIFICANT FIGURES VIII
CLASS EXAMPLE IV

The answer must be rounded off to 2 significant
figures, since 1.6 only has 2 significant figures.

The answer must be rounded off to 3 significant
figures, since 45.2 has only 3 significant figures
 KINEMATICS I

MOTION

The universe, earth, and everything in it, moves.
Even seemingly stationary things, such as roadway,
move with Earth’s rotation!

The classification and comparison of motions (called Kinematics) is often challenging.

What exactly do you measure, and how do you compare?
 KINEMATICS II

Position
To locate an object means to find its position relative to some reference point, often the
origin (or zero point) of an axis.

The origin is where x = 0, y = 0.

The x and y axes are always perpendicular to each other.

Objects positioned to the right of the origin of coordinated (0) on the x axis have
an x coordinate to be positive; then points to the left of 0 have a negative x
coordinate.

The position along the y axis is usually considered positive when above 0, and
negative when below 0.
 KINEMATICS III

Distance and displacement

The distance an object travels is defined as the length of the path that the object took in travelling
from one place to another.

Distance is a scalar quantity.

Displacement, on the other hand, is the distance travelled, but with a direction associated.

Δ𝑥 = 𝑥! − 𝑥"
Displacement is a vector quantity.

For example, if the particle moves from x1 = 5m to x2= 200 m and the back to x1 = 5m, the
displacement from start to finish is zero.
 KINEMATICS IV
Speed and Velocity
An important aspect of the motion of a moving object is how fast it is moving – its speed or
velocity.

The average velocity, defined as the displacement divided by the elapsed time.

Δ𝐱
𝐯=
Δt

The SI unit for average velocity is the meter per second (m/s).

Velocity, is used to signify both the magnitude (numerical value) of how fast an object is
moving and also the direction in which is moving.
 KINEMATICS V
Speed and Velocity

Average speed is a different way of describing “how
fast” a particle moves.

The average velocity involves the particle’s
displacement
The average speed involves the total distance
covered, independent of direction.
 KINEMATICS VI
Acceleration

An object whose velocity is changing is said to be accelerating. For instance, a whose velocity
increases in magnitude from zero to 80 km/h is accelerating.

Acceleration specifies how rapidly the velocity of an object is changing.

Average acceleration is defined as the change in velocity divided by the time taken to make this
change.
𝛥𝒗
𝛼=
𝛥𝑡

A common unit of acceleration is the meter per second per second, m / s 2.
 ACCELERATION DUE TO GRAVITY
All objects falling freely towards the Earth have the same acceleration.

The value of this constant acceleration is given by : 𝒈 = 𝟗. 𝟖𝟏 𝒎⁄𝒔𝟐.

g is called the acceleration due to gravity.
CLASS EXAMPLE V

Which of the following graphs represents an object at rest?

A. (A).
B. (B).
C. (C).
D. (D).
E. (E).

Figure: Graphs Describing Object Motion or Lack of.
 SUMMARY I
Physics requires the use of units.

Fundamental physical quantities are: LENGTH, TIME, MASS, ELECTRICAL CURRENT,
TEMPERATURE, AMOUNT OF SUBSTANCE AND LUMINOSITY.

The SI system of units is a metric system, a system based on the number 10.

elapsed time (Δt ) The time interval between two events.

distance (d or Δx) The length of a path between two spatial positions.

displacement (d or Δx) The vector equivalent of distance, which specifies the distance and
direction of one point in space relative to another. It depends only on the initial and final
spatial positions, and is independent of the path taken from one position to the other.
 SUMMARY II
speed (v) A scalar measure of the rate of motion. The SI unit of speed is metres per
second (m/s or m/s).

velocity (v) A vector measure of the rate of motion, which specifies both the magnitude
and direction of the rate of motion.

acceleration (a) A measure of the rate of change of the velocity. Acceleration is a vector
quantity. The SI units of acceleration are 𝒎⁄𝒔𝟐.

All objects falling freely towards the Earth have the same acceleration.

The value of this constant acceleration is given by : 𝒈 = 𝟗. 𝟖𝟏 𝒎⁄𝒔𝟐.

g is called the acceleration due to gravity.
 REFERENCES
Authors Title Edition Publisher Year ISBN
Kirsten
Franklin, Paul Introduction to Biological
John Wiley &
Muir, Terry Physics for the Health and 1st Edition 2010 9780470665930
Sons
Scott and Paul Life Sciences
Yates
J.R. Cameron,
Medical
J.G. Skofronick
Physics of the body 2nd Edition Physics 2017 9781930524941
and R.M.
Publishing
Grant

I.P. Herman Physics of the Human Body 2nd Edition Springer 2016 978331923930
Martin Zinke Cengage
Physics of the Life Sciences 3rd Edition 2016 9780176558697
Allmag Learning
R.K.Hobbie Intermediate Physics for
5th Edition Springer 2015 9783319126814
and B.J.Roth Medicine and Biology
FORCES AND NEWTON’S LAWS

Dr Anastasia Hadjiconstanti
Prof Vered Aharonson

Aknowledgements: Dr C.Zervides
 LECTURE LOB’S
6. DESCRIBE THE CONCEPT OF FORCE.

7. UNDERSTAND THE RELATIONSHIP BETWEEN FORCE AND MOTION.

8. IDENTIFY ACTION-REACTION PAIRS OF FORCES.

9. UNDERSTAND NORMAL, FRICTION AND TENSION FORCES.
 FORCE I
The Oxford English Dictionary gives a number of definitions of the noun ‘force’.

But in physics terminology force is a measurable influence that causes something to move.

Or: Force is anything that is measurable and causes a change in the motion of an object.

Newton’s first law:
Any object continues at rest,
or at constant velocity,
unless an external force acts on it.
 FORCE II
An external force gives an object an acceleration.

The acceleration produced is proportional to the force applied, and the constant of
proportionality is the mass.

Newton’s second law is summarised by the following equation:

𝑭 = 𝒎𝜶

The SI unit of force is the newton.

One newton (1 N) is the force which would accelerate a 1 kg mass at an acceleration of 1 m/s2.
 FORCE III
Since any object of mass m near the surface of the Earth falls with acceleration downwards,
there must be a force acting on it.
This downward force is due the earth’s gravity.
The acceleration is called acceleration of gravity , and is the same for any object moving under
the sole influence of gravity
This important quantity has a special symbol to denote it : the symbol g.

The direction of this force is down toward the center of the Earth.

The magnitude of the force, W, is: 𝑾 = 𝒎𝒈 – this is the object’s weight
Note: the weight of an object is a FORCE not a MASS !!

When we step on our bathroom scales and are told our mass in kilograms, we are being
given our weight in Newton with a zero removed.
 FORCE IV

Question

The force of gravity acts on an object when is falling. When an object is at rest on the
Earth, the gravitational force on it does not disappear. This force, continues to act.

Why, then, doesn’t the object move?

From Newton’s second law, the net force on an object that remains at rest is zero. There
must be another force on the object to balance the gravitational force.
 FORCE V – THE Normal Force

For an object resting on a table, the table exerts an
upward force.
The table is compressed slightly beneath the object.
The force exerted by the table is often called a
contact force, since it occurs when two objects are in
contact.
When a contact force acts perpendicular to the
common surface of contact, it is called the normal
force (“normal” means perpendicular);
!
It is labeled F
N
 FORCE VI - Newton’s third law
Newton’s third law states that forces come in pairs.

For every force that is applied to a body, there is a force applied by that body.

The force applied by one object on another object is called the action.

If the ‘action’ is the force exerted by an object A on an object B.

Then according to Newton’s third law, object B will exert a force of equal size, but in the opposite direction, on
object A.

This second force is the ‘reaction’ to the force exerted by object A.

Remember: the “action” force and the “reaction” force are acting on different
objects.
 FORCE VII - CLASS EXAMPLE I

The two forces are both acting on the statue, which remains at
rest, so the vector sum of these two forces must be zero (Newton’s
second law).
Hence FG and FN must be of equal magnitude and in opposite
directions. But they are not the equal and opposite
forces as per Newton’s third law. Why?

The action and reaction forces of Newton’s third law act on
different objects, whereas the two forces shown in figure act on
the same object.
FORCE VIII - CLASS EXAMPLES II
 KINDS OF FORCE

Fundamental Forces of nature Specific Forces

1. Electromagnetic force 1. Normal force
2. Gravitational force 2. Tension force
3. Strong nuclear forces. 3. Friction force
4. Weak nuclear forces
 TENSION I

When a cord (or a rope, cable, or other such object) is attached to a body and pulled
tight, the cord pulls on the body with a force directed away from the body and along
the cord.

The force is often called a tension force because the cord
is said to be in state tension (or to be under tension).
 TENSION II

The cable is assumed to be:

Massless: meaning its mass is negligible
compared to the body’s mass) and
Unstretchable: the cable exists only as a
connection between the two bodies. It pulls on
both bodies with the same force magnitude T
 FRICTION I
If we either attempt to slide or slide a body over a surface, the motion is resisted by a
bonding between the body and the surface.

The resistance is considered to be a single force, called either the frictional force or
simply friction.

This force is directed along the surface, opposite the direction of the intended
motion.

In the first case (tends to move) the resistance is called static friction while in the
second case (motion) is called kinetic friction.
 FRICTION II

The coefficients calculated from

f = μN

are known as the coefficients of static and kinetic friction, respectively.

The coefficient of kinetic friction is always smaller than the coefficient of static friction.
 SUMMARY I
Newton’s first law states that any object continues at rest, or at constant velocity,
unless an external force acts on it.

Newton’s second law is summarised by the following equation:

𝑭 = 𝒎𝜶

Newton’s third law states that forces come in pairs.

For every force that is applied to a body, there is a force applied by that body.

The force applied by one object on another object is referred to as the action.
 SUMMARY II

Normal force (N) The perpendicular component of the contact force between two
objects in physical contact with each other.

Tension force (T ) A force that tends to stretch intermolecular bonds.

Friction force ( f ) A force that resists the relative motion between two surfaces in
contact.
 REFERENCES
Authors Title Edition Publisher Year ISBN
Kirsten
Franklin, Paul Introduction to Biological
John Wiley &
Muir, Terry Physics for the Health and 1st Edition 2010 9780470665930
Sons
Scott and Paul Life Sciences
Yates
J.R. Cameron,
Medical
J.G. Skofronick
Physics of the body 2nd Edition Physics 2017 9781930524941
and R.M.
Publishing
Grant

I.P. Herman Physics of the Human Body 2nd Edition Springer 2016 978331923930
Martin Zinke Cengage
Physics of the Life Sciences 3rd Edition 2016 9780176558697
Allmag Learning
R.K.Hobbie Intermediate Physics for
5th Edition Springer 2015 9783319126814
and B.J.Roth Medicine and Biology
STATICS OF THE BODY

Dr Anastasia Hadjiconstanti
Prof Vered Aharonson

Aknowledgements: Dr C.Zervides
 LECTURE LOB’S

10. DESCRIBE THE CONCEPT OF EQUILIBRIUM.

11.DESCRIBE THE CONCEPT OF TORQUE.

12.EXPLAIN MOTION IN ONE PLANE AND LEVERS.

13.INVESTIGATE STATICS IN THE BODY.

14.INVESTIGATE THE PRINCIPLE OF MOMENTS.

15.DESCRIBE THE CONCEPT OF CENTRE OF GRAVITY / CENTRE OF MASS.
 INTRODUCTION I
We will investigate the statics of the body by:

reviewing forces, torques, and equilibrium,

then applying these conditions to statics in a plane and a lever.

We will analyse examples of statics in the body including:
the lower arm, knee.

hips,

shoulder,
 INTRODUCTION II
Some of these are related to injuries in the body (hip & back).

The study of forces in equilibrium is called “STATICS” – the study of bodies which are not
accelerating.

A system is in dynamic equilibrium when it is in equilibrium and also in motion, which implies
that the system is travelling at constant velocity and/or rotating at a constant rate.

We will focus on the study of the force balance
of an object at rest.

STATICS is a very important area of biomechanics.
 REVIEW OF FORCES, TORQUES AND EQUILIBRIUM I
Each force F can be resolved into components in the x, y, and z
directions (Fx, Fy, Fz).

In a static condition the sum of the forces F in each of the x, y,
and z directions is zero:

! 𝑭𝒙 = 𝟎, ! 𝑭𝒚 = 𝟎, ! 𝑭𝒛 = 𝟎.

These forces can be in balance EITHER for the entire body OR
for any part of the body.
 REVIEW OF FORCES, TORQUES AND EQUILIBRIUM II
Each torque τ can be resolved into components in the x, y, and z directions (τx, τy, τz).

In a static condition, the torques τ about the x, y, and z axes also each sum to zero for the
entire body and for any body part:

! 𝝉𝒙 = 𝟎, ! 𝝉𝒚 = 𝟎, ! 𝝉𝒛 = 𝟎.
 REVIEW OF FORCES, TORQUES AND EQUILIBRIUM III
A system is said to be in equilibrium when the net force on that system is zero and the
net torque on the system is also zero.

A system is in static equilibrium when it is in equilibrium and stationary.

Static equilibrium occurs when:

a seesaw is perfectly balanced, or

in the ankle when an individual stands on tip toe, or

in the elbow joint when an individual holds an object.
 REVIEW OF FORCES, TORQUES AND EQUILIBRIUM IV

A system is in stable equilibrium if it will return to equilibrium after it has been subject to a
small displacement.

A system is in an unstable equilibrium if it will not return to this equilibrium having been
subject to a small displacement.

Clearly, an object with a much narrower top and broader base will be more unstable when
placed on its top and more stable when placed on its base.
 STANDING: STABILITY I
Stability is essential during standing, as well as during any type of motion.

First consider the body as a rigid mass.

The criterion for overall stability during standing is for the center of mass to be over
the area spanned by the feet.

This means that a vertical line passing
through the center of mass passes
in this area of the support base.
 STANDING: STABILITY II
Otherwise, torques would not be balanced => unstable => topple over.

When the center of mass is above the area spanned by the feet:

the right foot causes a - torque and

the left foot causes a + torque, and

they cancel out.
 STANDING: STABILITY III
When the center of mass is to the left of the foot area both torques are negative.

When it is to the right both torques are positive.

The torques cannot balance in either case, and there is instability.

STAND UP AND TRY IT! TRY TO LEAN OVER!
 STANDING: STABILITY IV
We are most stable when the line of gravity is near the center of the support base.

When we lean the line of gravity can pass through the periphery of this base or outside this
base.

The term center of gravity is also often used in stability analysis.
 WHAT IS A TORQUE I?
Torque is the tendency of a force to rotate an object about:

an axis,

fulcrum (the point at which a lever pivots) or

pivot.

Torque can be thought of as a twist.

The physical quantity which causes an object to begin to rotate or move in a circle, or to
change its rate of rotation, is a torque.

A torque is not a force in the Newtonian sense: it is a moment.
 WHAT IS A TORQUE II?
The amount of turning produced by the force applied to a rod will depend:

on the magnitude of the force (F) and

the length of the rod (d).

The product of these two factors gives the torque, τ:

𝝉 = 𝐅𝐝

Torque is measured in units of N m.

The torque provides us with a useful way to measure the turning effect (i.e., the tendency to
cause rotation) of a force applied to a rod, which we call a moment arm or lever.
 WHAT IS A TORQUE III?
CLASS EXAMPLE I
𝝉 = 𝐅𝐝

A longer lever arm (distance from the point at which the force
is applied to the axis of rotation) is very helpful in rotating
objects.
It actually defines the rotating ability of the force.

https://youtu.be/46mPNzoScKs
 WHAT IS A TORQUE IV?
Positive torque :

=> motion in the counter-clockwise direction.

Negative torque:

=> motion in the clockwise direction.

Any force that causes a counterclockwise rotation about a pivot point is said to cause a
positive torque.

Any force that causes a clockwise rotation is said to cause a negative torque.
WHAT IS A TORQUE V?
 STATICS: MOTION IN ONE PLANE AND LEVERS I
Many problems involve motion in one plane.

Thus the equilibrium equations can be reduced to three:

! 𝑭𝒙 = 𝟎, ! 𝑭𝒚 = 𝟎, ! 𝝉𝒛 = 𝟎.

These problems can be classified as one of three types of levers.
 STATICS: MOTION IN ONE PLANE AND LEVERS II
For a system in static equilibrium, all torques are balanced so that there is no net torque.

Since there is no net ‘tendency to rotate’, the system will remain motionless.

At equilibrium, the sum of the clockwise moments equals the sum of the counterclockwise
moments.

This condition is called the PRINCIPLE OF MOMENTS.

Therefore, at equilibrium we can write:

! 𝑭𝒄𝒘𝒅𝒄𝒘 = ! 𝑭𝒄𝒄𝒘𝒅𝒄𝒄𝒘
 STATICS: MOTION IN ONE PLANE AND LEVERS III
First class lever, weight (load) + muscle (effort) act on opposite sides of fulcrum and in the
same direction.

LEAST COMMON LEVER IN THE BODY.

One type of the first class lever is a seesaw or teeter totter.

A second type is the head atop the spinal cord.
 STATICS: MOTION IN ONE PLANE AND LEVERS IV
Second class lever, muscle (effort) + weight (load) act on same side of fulcrum, and weight
(load) nearer the fulcrum.

SECOND MOST COMMON LEVER IN THE BODY.

One example is standing on tiptoes.
 STATICS: MOTION IN ONE PLANE AND LEVERS V
Third class levers, muscle (effort) + weight (load) are on same side of fulcrum, with muscle
(effort) nearer to the fulcrum.

MOST COMMON LEVER IN THE BODY.

One example of a third class lever is the balancing of the lower arm by the biceps brachii
inserted on the radius.
STATICS: MOTION IN ONE PLANE AND LEVERS VI
 STATICS: MOTION IN ONE PLANE AND LEVERS VII
In the human body…

https://www.youtube.com/watch?v=d1wS_OlJzmI&ab_channel=Bifrost
 IN CLASS EXAMPLE 1
Find for each type of lever, the muscle force M needed to maintain equilibrium.

Positive torque

𝒅𝒘
& 𝝉𝒛 = 𝟎 ⇒ 𝑾𝒅𝒘 − 𝑴𝒅𝒎 = 𝟎 ⇒ 𝑴 = 𝑾
𝒅𝒎
Negative torque

Positive torque

𝒅𝒘
& 𝝉𝒛 = 𝟎 ⇒ 𝑴𝒅𝒎 − 𝑾𝒅𝒘 = 𝟎 ⇒ 𝑴 = 𝑾
𝒅𝒎
Negative torque

Positive torque

𝒅𝒘
& 𝝉𝒛 = 𝟎 ⇒ 𝑴𝒅𝒎 − 𝑾𝒅𝒘 = 𝟎 ⇒ 𝑴 = 𝑾
𝒅𝒎
Negative torque
 STATICS IN THE BODY: THE LOWER ARM
Examine the equilibrium of the forearm balanced by the contraction of the biceps brachii
inserted on the radius.

In equilibrium, the biceps brachii force counters the potential rotation about the elbow joint by
the weight held in the hand.
 IN CLASS EXAMPLE 2
The elbow joint is essentially a hinge. The forearm rotates about the elbow joint, and the
muscles of the upper arm, in particular the biceps muscle, attach to the bones of the forearm
just below the joint. In this example we will calculate the force which the biceps muscle must
apply to the forearm to hold a 4 kg weight horizontally in the hand.

The mass of the forearm and the mass held in the hand both contribute to the
clockwise moment, giving a total clockwise moment of
𝑚 𝑚
2.5 𝑘𝑔×9.81 " ×0.15 𝑚 + 4 𝑘𝑔×9.81 " ×0.40 𝑚 = 19.37 𝑁𝑚
𝑠 𝑠

The only counter-clockwise moment is provided by the biceps muscle, thus if
the weight is held stationary the clockwise and counter-clockwise moments
must be equal so that 𝐹 ×0.04 𝑚 = 19.37 𝑁𝑚
#$%&'(

19.37 𝑁𝑚
𝐹#$%&'( = = 𝟒𝟖𝟒 𝑵
0.04 𝑚
IN CLASS EXAMPLE 2 COMMENT
Thus holding a 4 kg weight in the hand (i.e., at the end of a lever arm)
requires that the biceps muscle supply enough force to hold a 49 kg
weight if that weight were not at the end of a lever. The arm is
optimised for speed rather than strength. The lever arrangement by
which we lift objects in our hands does not maximise lifting strength.
However this organisation of muscles and limbs does greatly increase
the speed with which the hand is able to move. The human arm is
better at throwing spears than it is at lifting rocks. Note that this
analysis also explains why it is easier to lift heavy weights if they are
tucked into the arm rather than held in the hand.
 CENTRE OF GRAVITY / CENTRE OF MASS I
Could we consider a single point where the weight of the object is acting?

pivot point
 CENTRE OF GRAVITY / CENTRE OF MASS II
In order to make use of the full power of the principle of moments, we will make use of
another concept.

The centre of mass or the centre of gravity when dealing with a uniform gravitational field.

When a long ruler is carefully balanced on a pivot, the pivot point is located at the centre of
gravity.

pivot point
EXERCISE FOR HOME
Find the muscle force M needed to provide balance when the biceps brachii is inserted 4 cm
from the elbow joint. The forearm is 0.146H long and the hand length is 0.108H where H is
the body height. The weight in the hand is about (0.146 +0.108/2)H = 0.2H from the elbow
joint. Note that H = 180 cm and the weight W = 100 N. Assume that forearm and upper arm
make a 90 degree angle and neglect the mass of the forearm.
 SUMMARY I
The study of forces in equilibrium is called “STATICS”.

In a static condition the sum of the forces F in each of the x, y, and z directions is zero:

! 𝑭𝒙 = 𝟎, ! 𝑭𝒚 = 𝟎, ! 𝑭𝒛 = 𝟎.

In a static condition, the torques τ about the x, y, and z axes also each sum to zero for the
entire body and for any body part:

! 𝝉𝒙 = 𝟎, ! 𝝉𝒚 = 𝟎, ! 𝝉𝒛 = 𝟎.
 SUMMARY II
static equilibrium A static equilibrium occurs when a system is in equilibrium and stationary.

dynamic equilibrium A dynamic equilibrium occurs when a system is in equilibrium and also in
motion. Dynamic equilibrium implies that the system has constant velocity and rate of
rotation.

stable equilibrium An equilibrium is stable if the system will return to equilibrium if it is
subject to a small displacement.

unstable equilibrium An equilibrium is unstable if the system will not return to this
equilibrium if it is subject to a small displacement.
 SUMMARY III
Torque is the tendency of a force to rotate an object about:

an axis,
fulcrum (the point at which a lever pivots) or
pivot.

Positive torque :
=> motion in the counter-clockwise direction.

Negative torque:
=> motion in the clockwise direction.
 SUMMARY IV
Many problems involve motion in one plane.

Thus the equilibrium equations can be reduced to three:

! 𝑭𝒙 = 𝟎, ! 𝑭𝒚 = 𝟎, ! 𝝉𝒛 = 𝟎.

These problems can be classified as one of three types of levers.

First class lever, weight (load) + muscle (effort) act on opposite sides of fulcrum and in the
same direction.

LEAST COMMON LEVER IN THE BODY.
 SUMMARY V
Second class lever, muscle (effort) + weight (load) act on same side of fulcrum, and weight
(load) nearer the fulcrum.

SECOND MOST COMMON LEVER IN THE BODY.

Third class levers, muscle (effort) + weight (load) are on same side of fulcrum, with muscle
(effort) nearer to the fulcrum.

MOST COMMON LEVER IN THE BODY.
 SUMMARY VI
centre of mass The point at which the total mass of a body may be considered to be
concentrated (for many purposes) in analysing its motion.

centre of gravity The point where the total weight of a material body may be thought to be
concentrated. In a uniform gravitational field, this coincides with the centre of mass, but the
centre of mass does not require a gravitational field.
 REFERENCES

Authors Title Edition Publisher Year ISBN
Kirsten
Franklin, Paul Introduction to Biological
John Wiley &
Muir, Terry Physics for the Health and 1st Edition 2010 9780470665930
Sons
Scott and Pa Life Sciences
ul Yates
I.P. Herman Physics of the Human Body 2nd Edition Springer 2016 978331923930
Martin Zinke Cengage
Physics of the Life Sciences 3rd Edition 2016 9780176558697
Allmag Learning
R.K.Hobbie Intermediate Physics for
5th Edition Springer 2015 9783319126814
and B.J.Roth Medicine and Biology
Physics in Biology and Academic
P. Davidovits 4th Edition 2012 9780763730406
Medicine Press