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Circular MotionProf. Mukesh N. TekwaniDepartment of PhysicsI. Y. College,[email protected]. Mukesh N Tekwani
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Circular Motion
2Prof. Mukesh N Tekwani
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Circular Motion3Prof. Mukesh N Tekwani
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Relation Between Linear Velocity and Angular Velocity
4Prof. Mukesh N TekwaniConsider aparticleperforming U.C.M. in an anticlockwise direction.
In a very small time interval dt, theparticlemoves from the point P1to the point P2.
Distance travelled along the arc is ds.
In the same time interval,the radiusvector rotates through an angle d.
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Relation Between Linear Velocity and Angular Velocity
5Prof. Mukesh N Tekwani
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Centripetal ForceUCM is an accelerated motion. Why?UCM is accelerated motion because the velocity of the body changes at every instant (i.e. every moment)But, according to Newtons Second Law, there must be a force to produce this acceleration. This force is called the centripetal force.Therefore, Centripetal force is required for circular motion. No centripetal force +> no circular motion.
6Prof. Mukesh N Tekwani
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Velocity and Speed in UCM
Is speed changing?No, speed is constantIs velocity changing?
Yes, velocity is changing because velocity is a vector and direction is changing at every point 7Prof. Mukesh N Tekwani
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Velocity and Speed in UCMIs speed changing?No, speed is constantIs velocity changing?
Yes, velocity is changing because velocity is a vector and direction is changing at every point 8Prof. Mukesh N Tekwani
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Examples of Centripetal forceA body tied to a string and whirled in a horizontal circle CPF is provided by the tension in the string.9Prof. Mukesh N Tekwani
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Examples of Centripetal forceFor a car travelling around a circular road with uniform speed, the CPF is provided by the force of static friction between tyres of the car and the road.10Prof. Mukesh N Tekwani
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Examples of Centripetal forceIn case of electrons revolving around the nucleus, the centripetal force is provided by the electrostatic force of attraction between the nucleus and the electrons
In case of the motion of moon around the earth, the CPF is provided by the ______ force between Earth and Moon11Prof. Mukesh N Tekwani
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Centripetal ForceCentripetal forceIt is the force acting on a particle performing UCM and this force is along the radius of the circle and directed towards the centre of the circle.
REMEMBER!Centripetal force- acting on a particle performing UCM- along the radius- acting towards the centre of the circle.
12Prof. Mukesh N Tekwani
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Properties of Centripetal ForceCentripetal force is a real force CPF is necessary for maintaining UCM.CPF acts along the radius of the circleCPF is directed towards center of the circle.CPF does not do any workF = mv2/ r
13Prof. Mukesh N Tekwani
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Radial Acceleration
P(x, y)vOXYMNr
xyLet P be the position of the particle performing UCM
r is the radius vector
= t . This is the angular displacement of the particle in time t secs
V is the tangential velocity of the particle at point P.
Draw PM OX
The angular displacement of the particle in time t secs is
LMOP = = t 14Prof. Mukesh N Tekwani
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Radial Acceleration
P(x, y)vOXYMNr
xyThe position vector of the particle at any time is given by:
r = ix + jy
From POM
sin = PM/OP
sin = y / r
y = r sin
But = t
y = r sin t 15Prof. Mukesh N Tekwani
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Radial Acceleration
P(x, y)vOXYMNr
xySimilarly,
From POM
cos = OM/OP
cos = x / r
x = r cos
But = t
x = r cos t 16Prof. Mukesh N Tekwani
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Radial Acceleration17Prof. Mukesh N TekwaniThe velocity of particle at any instant (any time) is called its instantaneous velocity.
The instantaneous velocity is given by
v = dr / dt
v = d/dt [ ir cos wt + jr sin wt]
v = - i r w sin wt + j r w cos wt
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Radial Acceleration18Prof. Mukesh N TekwaniThe linear acceleration of the particle at any instant (any time) is called its instantaneous linear acceleration.
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Radial Acceleration19Prof. Mukesh N TekwaniTherefore, the instantaneous linear acceleration is given by
a = - w2 r
Importance of the negative sign: The negative sign in the above equation indicates that the linear acceleration of the particle and the radius vector are in opposite directions.
ar
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Relation Between Angular Acceleration and Linear Acceleration20Prof. Mukesh N TekwaniThe acceleration of a particle is given by
. (1)
But v = r w
a = .... (2)
r is a constant radius,
But
is the angular acceleration
a = r (3)
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Relation Between Angular Acceleration and Linear Acceleration21Prof. Mukesh N Tekwani
v = w x r
Differentiating w.r.t. time t,
But
and
linear acceleration
a = aT + aR
aT is called the tangential component of linear acceleration
aR is called the radial component of linear acceleration
For UCM, w = constant, so
a = aR in UCM, linear accln is centripetal accln
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Centrifugal Force22Prof. Mukesh N Tekwani
Centrifugal force is an imaginary force (pseudo force) experienced only in non-inertial frames of reference.
This force is necessary in order to explain Newtons laws of motion in an accelerated frame of reference.
Centrifugal force is acts along the radius but is directed away from the centre of the circle.
Direction of centrifugal force is always opposite to that of the centripetal force.
Centrifugal force
Centrifugal force is always present in rotating bodies
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Examples of Centrifugal Force23Prof. Mukesh N Tekwani
When a car in motion takes a sudden turn towards left, passengers in the car experience an outward push to the right. This is due to the centrifugal force acting on the passengers.
The children sitting in a merry-go-round experience an outward force as the merry-go-round rotates about the vertical axis.
Centripetal and Centrifugal forces DONOT constitute an action-reaction pair. Centrifugal force is not a real force. For action-reaction pair, both forces must be real.
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Banking of Roads24Prof. Mukesh N Tekwani
When a car is moving along a curved road, it is performing circular motion. For circular motion it is not necessary that the car should complete a full circle; an arc of a circle is also treated as a circular path.
We know that centripetal force (CPF) is necessary for circular motion. If CPF is not present, the car cannot travel along a circular path and will instead travel along a tangential path.
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Banking of Roads25Prof. Mukesh N Tekwani
The centripetal force for circular motion of the car can be provided in two ways:Frictional force between the tyres of the car and the road.Banking of Roads
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Friction between Tyres and Road26Prof. Mukesh N Tekwani
The centripetal force for circular motion of the car is provided by the frictional force between the tyres of the car and the road.
Let m = mass of the carV = speed of the car, andR = radius of the curved road.
Since centripetal force is provided by the frictional force, CPF = frictional force (provide by means equal to )
( is coefficient of friction between tyres & road)
So and
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Friction between Tyres and Road27Prof. Mukesh N Tekwani
Thus, the maximum velocity with which a car can safely travel along a curved road is given by
If the speed of the car increases beyond this value, the car will be thrown off (skid).
If the car has to move at a higher speed, the frictional force should be increased. But this cause wear and tear of tyres.
The frictional force is not reliable as it can decrease on wet roads
So we cannot rely on frictional force to provide the centripetal force for circular motion.
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Friction between Tyres and Road28Prof. Mukesh N Tekwani
R1 and R2 are reaction forces due to the tyres
mg is the weight of the car, acting vertically downwards
F1 and F2 are the frictional forces between the tyres and the road.
These frictional forces act towards the centre of the circular path and provide the necessary centripetal force.
Center of circular path
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Friction between Tyres and Road29Prof. Mukesh N Tekwani
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Friction between Tyres and Road Car Skidding30Prof. Mukesh N Tekwani
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Banked Roads31Prof. Mukesh N Tekwani
What is banking of roads?
The process of raising the outer edge of a road over the inner edge through a certain angle is known as banking of road.
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Banking of Roads32Prof. Mukesh N Tekwani
Purpose of Banking of Roads:Banking of roads is done:To provide the necessary centripetal force for circular motionTo reduce wear and tear of tyres due to frictionTo avoid skiddingTo avoid overturning of vehicles
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Banked Roads33Prof. Mukesh N Tekwani
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Banked Roads34Prof. Mukesh N Tekwani
What is angle of banking?
R
R cos W = mgR sin The angle made by the surface of the road with the horizontal surface is called as angle of banking.Horizontal Surface of road
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Banked Roads35Prof. Mukesh N Tekwani
Consider a car moving along a banked road.
Letm = mass of the carV = speed of the car isangleof banking
R
R cos W = mgR sin
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Banked Roads36Prof. Mukesh N Tekwani
The forces acting on the car are:
(i) Its weightmgacting vertically downwards.
(ii) The normal reactionRacting perpendicular to the surface of the road.
R
R cos W = mgR sin
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Banked Roads37Prof. Mukesh N Tekwani
The normal reaction can be resolved (broken up) into two components:
R cos is the vertical component
R sin is the horizontal component
R
R cos W = mgR sin
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Banked Roads38Prof. Mukesh N Tekwani
Since the vehicle has no vertical motion, the weight is balanced by the vertical component
R cos = mg (1)
(weight is balanced by vertical component means weight is equal to vertical component)
R
R cos W = mgR sin
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Banked Roads39Prof. Mukesh N Tekwani
The horizontal component is the unbalanced component . This horizontal component acts towards the centre of the circular path.
This component provides the centripetal force for circular motion
R sin = (2)
R
R cos W = mgR sin
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Banked Roads40Prof. Mukesh N Tekwani
Dividing (2) by (1), we get
R sin =
mgR cos = tan-1 ( )
So,
tan =
Therefore, the angle of banking is independent of the mass of the vehicle.
The maximum speed with which the vehicle can safely travel along the curved road is
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Banked Roads41Prof. Mukesh N Tekwani
Smaller radius: larger centripetal force is required to keep it in uniform circular motion.A car travels at a constant speed around two curves. Where is the car most likely to skid? Why?
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Conical Pendulum42Prof. Mukesh N Tekwani
Definition:
A conical pendulum is a simple pendulum which is given a motion so that the bob describes a horizontal circle and the string describes a cone.
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Conical Pendulum43Prof. Mukesh N Tekwani
Definition:
A conical pendulum is a simple pendulum which is given such a motion that the bob describes a horizontal circle and the string describes a cone.
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Conical Pendulum44Prof. Mukesh N Tekwani
Consider a bob of mass m revolving in a horizontal circle of radius r.
Letv = linear velocity of the bobh = heightT = tension in the string = semi vertical angle of the coneg = acceleration due to gravityl = length of the stringT cos
T sin
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Conical Pendulum45Prof. Mukesh N Tekwani
The forces acting on the bob at position A are:
Weight of the bob acting vertically downward
Tension T acting along the string.
T cos
T sin
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Conical Pendulum46Prof. Mukesh N Tekwani
The tension T in the string can be resolved (broken up) into 2 components as follows:
Tcos acting vertically upwards. This force is balanced by the weight of the bobT cos = mg ..(1)
T cos
T sin
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Conical Pendulum47Prof. Mukesh N Tekwani
(ii) T sin acting along the radius of the circle and directed towards the centre of the circle
T sin provides the necessary centripetal force for circular motion.
T sin = .(2)
Dividing (2) by (1) we get,
.(3)T cos
T sin
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Conical Pendulum48Prof. Mukesh N Tekwani
T cos
T sin
This equation gives the speed of the bob.
But v = rw
rw =
Squaring both sides, we get
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Conical Pendulum49Prof. Mukesh N Tekwani
T cos
T sin
From diagram, tan = r / h
r 2w2 = rg
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Conical Pendulum50Prof. Mukesh N Tekwani
T cos
T sin
Periodic Time of Conical Pendulum
But
Solving this & substituting sin = r/l we get,
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Conical Pendulum51Prof. Mukesh N Tekwani
T cos
T sin
Factors affecting time period of conical pendulum: The period of the conical pendulum depends on the following factors:
Length of the pendulumAngle of inclination to the verticalAcceleration due to gravity at the given place
Time period is independent of the mass of the bob
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Vertical Circular Motion Due to Earths Gravitation52Prof. Mukesh N Tekwani
Consider an object of mass m tied to the end of an inextensible string and whirled in a vertical circle of radius r.
mgT1Orv1AT2Bv2v3C
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Vertical Circular Motion Due to Earths Gravitation53Prof. Mukesh N Tekwani
mgT1Orv1AT2Bv2v3CHighest Point A:Let the velocity be v1
The forces acting on the object at A (highest point) are:Tension T1 acting in downward directionWeight mg acting in downward direction
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Vertical Circular Motion Due to Earths Gravitation54Prof. Mukesh N Tekwani
mgT1Orv1AT2Bv2v3CAt the highest point A:
The centripetal force acting on the object at A is provided partly by weight and partly by tension in the string:
(1)
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Vertical Circular Motion Due to Earths Gravitation55Prof. Mukesh N Tekwani
mgT1Orv1AT2Bv2v3CLowest Point B:Let the velocity be v2
The forces acting on the object at B (lowest point) are:Tension T2 acting in upward directionWeight mg acting in downward direction
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Vertical Circular Motion Due to Earths Gravitation56Prof. Mukesh N Tekwani
mgT1Orv1AT2Bv2v3CAt the lowest point B:
(2)
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Vertical Circular Motion Due to Earths Gravitation57Prof. Mukesh N Tekwani
mgT1Orv1AT2Bv2v3CLinear velocity of object at highest point A:
The object must have a certain minimum velocity at point A so as to continue in circular path.
This velocity is called the critical velocity. Below the critical velocity, the string becomes slack and the tension T1 disappears (T1 = 0)
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Vertical Circular Motion Due to Earths Gravitation58Prof. Mukesh N Tekwani
mgT1Orv1AT2Bv2v3CLinear velocity of object at highest point A:
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Vertical Circular Motion Due to Earths Gravitation59Prof. Mukesh N Tekwani
mgT1Orv1AT2Bv2v3CLinear velocity of object at highest point A:
This is the minimum velocity that the object must have at the highest point A so that the string does not become slack.
If the velocity at the highest point is less than this, the object can not continue in circular orbit and the string will become slack.
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Vertical Circular Motion Due to Earths Gravitation60Prof. Mukesh N Tekwani
mgT1Orv1AT2Bv2v3CLinear velocity of object at lowest point B:
When the object moves from the lowest position to the highest position, the increase in potential energy is mg x 2r
By the law of conservation of energy,KEA + PEA = KEB + PEB
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Vertical Circular Motion Due to Earths Gravitation61Prof. Mukesh N Tekwani
mgT1Orv1AT2Bv2v3CLinear velocity of object at lowest point B:
At the highest point A, the minimum velocity must be
Using this in
we get,
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Vertical Circular Motion Due to Earths Gravitation62Prof. Mukesh N Tekwani
mgT1Orv1AT2Bv2v3CLinear velocity of object at lowest point B:
Therefore, the velocity of the particle is highest at the lowest point.If the velocity of the particle is less than this it will not complete the circular path.
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