Rotational dynamics as per class 12 Maharashtra State Board syllabus

CHAPTER 1.
ROTATIONAL DYNAMICS
By- Miss Rutticka Kedare (New India School Jr. College, Kothrud)

• Recap: MECHANIC
S A branch of physics dealing with particles (or
objects) either at rest or in motion.
STATICS KINETICS
Study of objects at
rest
Study of moving objects
Kinematics
Dynamics
• In this we study of motion without
considering the causes
• Eg. distance., displacement, speed,
velocity, acceleration, etc.
• Study of motion along with its causes
• To study distance, velocity etc. along with
the force or torque which has caused the
motion of that object.
• Eg. Momentum, force, energy, power, etc.
• Branches of Dynamics: Fluid Dynamics,
Aerodynamics, etc.
To understand the terms : Motion, Kinematics and Dynamics let us see next slide

• “Motion”? “It is a change in the position of an object with time.”
• Example, a rolling ball
• In this as the ball moves from Point A
to Point B , we can also observe the
changes in time given at top right
corner
time
A B
Changing positions
Kinematics: study motion without
cause
Dynamics: study motion with cause

Throwing a ball
(Kinematics-
distance velocity)
Force applied by
his hand is the
cause for above
motion (Dynamics)
Consider what is happening here,
So when we say Dynamics, we will study this motion (throwing ball) along with its cause
(applied force)

In class 11, we studied motion but along a line i.e. a linear motion, here we will study
rotational motion but with its causes. Hence the name Rotational Dynamics.
Before we go ahead, understand the difference between Rotational and Circular Motion.
Circular: object moving in circle around
a point or another object.
Eg. The black point in below video is
in circular motion
Rotational: object is “turning” around
itself eg. Rotation of earth around itself

• Do you recall? (from textbook)
1) Circular motion? Motion of an object along a circular path.
2) Centre of Mass: It is an imaginary point that we consider inside a body
where whole mass of the body is supposed to be concentrated.
• It gets shifted as per our position.
• You can balance objects at their point
of Centre of Mass , eg. a baseball bat.

3) Kinematic
Equations:
4) Real Forces:
• Arises due to actual
interaction between
objects, or simply put
whose source and effect
both can be seen.
• Eg. Throwing a ball
5) Rigid Body:
• Idealisation of solid body
• Distance between any two points inside
a rigid body remains constant with time.
Pseudo Forces:
• only effect can be seen
or felt, source many
times unknown.
• Eg. Inside an elevator,
you feel lighter when it
is moving down and
heavier when it is
going up.

CONTENTS:
The topics in present chapter are as follows:
1. Horizontal Circular Motion: a) Kinematics and Dynamics. b) Its application.
2. Vertical Circular Motion
3. Moment of Inertia, M.I. (analogous to mass) and Torque in terms of M.I.
4. Radius of Gyration
5. Theorem of parallel and perpendicular axis
6. Angular Momentum
7. Rolling Motion

Analogies between Linear and Rotational Motion:
Linear (or Translational) Rotational
Displacement of object on
straight line- (x)
Velocity along straight line-
(v)
V =
𝑑𝑥
𝑑𝑡
Acceleration along a
straight line- (a)
a =
𝑑𝑣
𝑑𝑡
Displacement in circular motion-
Angular Displacement (θ theta)
Unit: Radian (rad)
Velocity along a circular motion-
Angular Velocity (ω omega)
Unit: (rad/m)
ω =
𝑑θ
𝑑𝑡
Acceleration in circular motion-
Angular Acceleration ( α alpha)
Unit: (rad/m2)
α =
𝑑ω
𝑑𝑡

In textbook, The first part of
lesson talks about topics
considering
Horizontal Circular motion:
eg. A pendulum
• UCM
• Non-UCM
• Centripetal & Centrifugal
Force and Its applications
In second half of lesson
we discuss
vertical circular motion.
Eg. rolling wheel
It is possible to discuss UCM, Non-UCM , Centripetal and Centrifugal force for Vertical Circle also,
it is simply not being discussed here.

Uniform Circular Motion Non Uniform Circular Motion
Eg. Fan moving with constant speed
Eg. When Fan is switched ON its
speed goes on increasing ( when put
OFF speed goes on decreasing)
Speed of particle remains constant
Speed of particle either increases or
decreases
Acceleration responsible is
“Centripetal Acceleration” also called
as “radial acceleration” whose value
remains constant. ( 𝑎 𝑟 )
Value of radial acceleration goes on
changing( 𝑎 𝑟 )
Magnitude of 𝑎 𝑟 remains constant. Magnitude of 𝑎 𝑟 is not constant.
Angular acceleration (α) is zero
For increasing speed, α is along the
direction of ω. For decreasing speed, α
is opposite to the direction of ω
Involves only Centripetal force
With Centripetal force involves
additional forces due to non zero α

Centripetal Force Centrifugal Force
The acceleration required for circular motion is
provided by Centripetal force
Centrifugal force is the pseudo force that
arises due to acceleration of frame of reference.
Frame of reference is steady Frame of reference is accelerated.
Always directed towards the centre Always directed away from centre
It is real force. It is non-real force. But we cannot call it
“imaginary” because its effects are seen
Eg. Satellite orbiting around the earth Eg. Mud flowing away from tyre
Resultant force, F = - mω2 𝑟 Resultant force, F = + mω2 𝑟

APPLICATIONS OF UCM
1) Vehicle along a horizontal circular track.
(Vertical Section)
C
Forces acting on car:
1) Weight (mg) downward
2) Normal reaction (N) upward
3) Static friction (fs ) sideways inward provides Centripetal force
When we consider moving car as our frame of reference, centripetal force is
balanced by centrifugal force
• Aim: to find equation of v

To find v, we shall consider following two conditions,
Normal reaction(N) balances weight (mg) of car i.e. N = mg ------ (1)
Static force (fs ) is balanced by centrifugal force, i.e. fs = + mω2r ------ (2)
If we divide (2) by (1) we get since v = r ω.
From the above box,
we can see a direct proportionality in fs and
v, also if we consider the equation for static
friction, the first term equals μ.

By far we discussed this application by considering the vehicle as a point, but in reality when we
have to consider the 4 tyres of car and their respective weights, normal reactions and also frictional
forces and centripetal forces.
In such case as the forces are not balanced, torque is produced causing the vehicle to “topple”
• In circular motion car toppled because frictional force
is not balanced by centripetal force.
• This can happen for two wheeler also.
When two wheeler is moving on a circular track, the rider must keep his bike at certain inclination to
ground to avoid toppling.
Eg. While taking turn the bike racer tilts himself.

• Talking about a driving bike or car on a circular path, takes us to our next application
2) Well of Death ( मौत का कु आ) : It is a cylindrical wall on which stuntmen drive car or
bike
Again, we consider the forces acting on the car:
1) Weight (mg)----- vertically downward
2) Normal reaction (N) ---- acting horizontally towards centre
3) Static friction (fs ) vertically upwards between the tyre and
wall (static because it must prevent downward slipping)
Now in this case the two cases are,
Weight (mg) is balanced by static force (fs ) i.e. fs = mg ------ (1)
Normal reaction (N) provides Centripetal force i.e. N = + mω2r ------ (2)
(Notice that in previous application frictional force was providing centripetal force while here
normal reaction is doing it)

1. Vehicle along circular track 2) Well of Death:
That means when fs balances Centripetal
force, we get v max
when N balances
Centripetal force, we
get v min
(Notice that in first application frictional force was providing centripetal force
while in second normal reaction is doing it)

• Again throughout the derivation we assumed the car or bike to be a point
particle, but this is not the case in reality.
• Also, during revolutions the two wheeler is in fact aligned at a particular angle
to the wall, this is to avoid toppling. Thus the bike is never perfectly 90 degree
with horizontal.
• This gives us following interpretations,
1) If the angle between bike and wall is θ = 90° then it imposes lower limit on
speed.
2) If the angle is θ = 0° (unbanked road, first application) this imposes upper limit.
3) For 0º ≤ θ ≤ 90º, the turning speed has both upper and lower limit.
The θ here is in fact Banking Angle, which takes us to our next application.

• As we discussed in previous application, when taking a turn, the static force
(fs) between tyre and road surface provides the necessary centripetal force,
i.e. fs balances the centrifugal force(avoiding the vehicle to skid away from
track)
• But this fs has upper limit of θ = 0°, also its value changes for non-uniform
surfaces (say, when you have a rough road). Therefore, we cannot depend
only on this frictional force, between tyres and road surface, to keep the
vehicle on track when taking turn…! Hence, it is necessary to “bank” the
road surface.
• Banking of road means the outer edge of curved roads are slightly lifted or
we can say, the surface of roads are made such that they are tilted at some
angle to horizontal.
• The speed limit on road is determined by this
Banking angle. The racing tracks are banked at
Higher angles than road through ghats.
3) Vehicle on a banked road

mg
N We resolve this N into its components because
it is neither along Y axis or along X axis
N cos θ
N sinθ
θ
Considering the car to be a point and ignoring non-conservative forces like friction, air resistance etc. we
make the list of forces involved.
1) Weight (mg) vertically downwards
2) Normal reaction (N) perpendicular to the surface of road, resolved into its components
From figure, we get, N cosθ = mg ------- (1) and N sinθ = mv2/r ------- (2)
Dividing (2) by (1) we get, tan θ = v2/rg i.e.
θ =tan−1
(v2/rg) Also, v = r g tan θ

• CASES:
1) Most Safe Speed:
The equation v = r g tan θ gives us the value of most safe speed on any road ( not minimum or
maximum speed)
2) Banking Angle:
This helps us in designing a road and is given by θ =tan−1
(v2/rg)
3) Speed limits:
When started this discussion we ignored the forces due to friction, but in reality we have to consider
them, therefore our formula for v slightly changes.
Let us consider same diagram but now with friction forces.
Forces involved here are,
i. Weight( mg) vertically downward
ii. Normal reaction perpendicular to road surface
iii. Frictional force along the road surface.
N and fs are further resolved into its components.
(Derivation in word document)

Therefore, in this equation,
for μs ≥ tan θ then vmin = 0
True for ROUGH
ROADS, which are
banked at smaller angles
Case c: When speed v1 is less than safe speed i.e.
and
(we did (c) case to find out how lower one can go than safe speed, so as to still be able to take turn)
Case d: When speed v2 is more than safe speed i.e. and
Therefore, in this equation, for μs = cot θ then vmax =
∞
But maximum value for μs = 1, therefore for θ ≥ 45º,
vmax = ∞.
What they mean here is that if your road is heavily banked
i.e. you have banking angle to be 45 degree you can literally
drive with infinite speed. NOT POSSIBLE IN REALITY !!

Case e:
• Therefore we have our next case where we take friction to be zero i.e. μs = 0, this takes
us back to the equation of safest speed, where we do not consider (as in take help ) of
friction, v = r g tan θ

Rotational dynamics as per class 12 Maharashtra State Board syllabus

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Rotational dynamics as per class 12 Maharashtra State Board syllabus