According to Aristotelian law an external force is required to keep a body in motion. However an external force is required to overcome the frictional forces in case of solids and viscous forces in fluids which are always present in nature.


Linear momentum of a body is the quantity of motion contained in the body. Momentum
It is a vector quantity having the same direction as the direction of the velocity. Its SI unit is kg ms–1.



A body continues to be in a state of rest or of uniform motion, unless it is acted upon by some external force to change its state.
Newton’s first law gives the qualitative definition of force according to which force is that external cause which tends to change or actually changes the state of rest or motion of a body.
Newton’s first law of motion is the same as law of inertia given by Galileo.

Inertia is the inherent property of all bodies because of which they cannot change their state of rest or of uniform motion unless acted upon by an external force.


The rate of change of momentum of a body is directly proportional to the external force applied on it and the change takes place in the direction of force applied.
This is the equation of motion of constant mass system. For variable mass system such as rocket propulsion
The SI unit of force is newton. (One newton force is that much force which produces an acceleration of 1ms–2 in a body of mass 1 kg.
The CGS unit of force is dyne. (1N = 105 dyne)
The gravitational unit of force is kg-wt (kg-f) or g-wt (g-f)
1 kg-wt (kg-f) = 9.8 N, 1 g-wt (g-f) = 980 dyne


To every action there is an equal and opposite reaction. For example – walking , swimming , a horse pulling a cart etc.
Action and reaction act on different bodies and hence cannot balance each other. Action and reaction occur simultaneously. Forces always occur in pairs.


A body is said to be in equilibrium when no net force acts on the body.
Then and


If a body is slightly displaced from equilibrium position, it has the tendency to regain its original position, it is said to be in stable equilibrium.
In this case, P.E. is minimum.
So, the centre of gravity is lowest.


If a body, after being displaced from the equilibrium position, moves in the direction of displacement, it is said to be in unstable equilibrium.
In this case, P.E. is maximum.
So, the centre of gravity is highest.


If a body, after being slightly displaced from the equilibrium position has no tendency to come back or to move in the direction of displacement the equilibrium is known to be neutral.
In this case,  P.E. is constant
The centre of gravity remains at constant height.



It is the force with which the earth attracts a body and is called force of gravity, For a body of mass m, where acceleration due to gravity is g, the weight W = mg


The force exerted by the ends of a loaded/stretched string (or chain) is called tension. The tension has a sense of pull at its ends.
Case 1

Case 2     

Case 3
The tension in a  string remains the same throughout the string if
(a) string is massless,
(b) pulley is massless  or pulley is frictionless

Case 4 : String having mass
Let the total mass  of the string be M and length be L. Then mass per unit length is
Let x be the distance of the string from the mass m. Then the mass of the shaded portion of string is
If the string is at rest then the tension T has to balance the wt of shaded portion of string and weight of mass m.
⇒ as x increases, the tension increases. Thus tension is non-uniform in a string having mass.


It measures how strongly one body presses the other body in contact. It acts normal to the surface of contact.
Case 1  
Case 2
Case 3


If an object is connected by spring and spring is stretched or compressed by a distance x, then restoring force on the object F = – kx
where k is a spring contact on force constant.


It is a force which opposes relative motion between the surfaces in contact. f = μN
This will be discussed in detail in later section.


If a body of mass m is placed in a non-inertial frame having acceleration , then it experiences a Pseudo force acting in a direction opposite to the direction of .
Negative sign shows that the pseudo force is always directed in a direction opposite to the direction of the acceleration of the frame.


When the motion of one body is dependent on the other body, the relationship of displacements, velocities and accelerations of the two bodies are called constraint relationships.
Case 1 Pulley string system :
Step 1 : Find the distance of the two bodies from fixed points.
Step 2 : The length of the string remain constant. (We use of this condition)
Therefore X + (X – x) = constant ⇒ 2X – x = constant
Again differentiating we get, 2ap = aB
ap = acceleration of pulley, aB = acceleration of block

Case 2   Here const.  On differentiating w.r.t ‘t’
[Negative sign with dy/dt shows that with increase in time, y decreases]
⇒ cos θ (v1 – v2) = 0
Case 3 Wedge block system : Thin lines represents the condition of wedge block at t = 0 and dotted lines at t = t
Ax = acceleration of wedge towards left
ax, ay = acceleration of block as shown
From Δ ABC ,


Reference frames are coordinate systems in which an event is described.
There are two types of reference frames
  • Inertial frame of reference: These are frames of reference in which Newton’s laws hold good. These frames are at rest with each other or which are moving with uniform speed with respect to each other. All reference frames present on surface of Earth are supposed to be inertial frame of reference.
  • Non – inertial frame of reference: Newton’s law do not hold good in non-inertial reference frame.
  • All accelerated and rotatory reference frames are non – inertial frame of reference. Earth is a non-inertial frame.
Note:- When the observer is in non-inertial reference frame a pseudo force is applied on the body under observation.


Free body diagram of a mass is a separate diagram of that mass. All forces acting on the mass are sketched. A FBD is drawn to visualise the direct forces acting on a body.

Case 1 : Masses M1 and M2 are tied to a string, which goes over a frictionless pulley
  1. If M2 > M1 and they move with acceleration a
FBD of M1, FBD of M2
where T is the tension in the string.
It gives and
  1. If the pulley begins to move with acceleration f, downwards

Case 2 : Three masses M1, M2 and M3 are connected with strings as shown in the figure and lie on a frictionless surface. They are pulled with a force F attached to M1.
The forces on M2 and M3 are as follows
and ;    
Acceleration of the system is

Case 3 :  Two blocks of masses M1 and M2 are suspended vertically from a rigid support with the help of strings as shown in the figure. The mass M2 is pulled down with a force F.
The tension between the masses M1 and M2 will be T2 = F + M2g
Tension between the support and the mass M1 will be T1 = F + (M1 + M2)g

Case 4 : Two masses M1 and M2 are attached to a string which passes over a pulley attached to the edge of a horizontal table. The mass M1 lies on the frictionless surface of the table.
Let the tension in the string be T and the acceleration of the system be a. Then
T = M1a ...(1)
M2g – T = M2a ...(2)
Adding eqns. (1) and (2), we get

Case 5 : Two masses M1 and M2 are attached to the ends of a string, which passes over a frictionless pulley at the top of the inclined plane of inclination θ. Let the tension in the string be T.
  1. When the mass M1 moves upwards with acceleration a.
From the FBD of M1 and M2,
T – M1g sin θ = M1a ...(1)
M2g – T = M2a ...(2)
Solving eqns. (1) and (2) we get,
FBD of mass M1
  1. When the mass M1 moves downwards with acceleration a.
Equation of motion for M1 and M2,
M1g sin θ – T = M1a ...(1)
T – M2g = M2a ...(2)
Solving eqns. (1) and (2) we get,

  • If (M2/M1 = sinθ) then the system does not accelerate.
  • Changing position of masses, does not affect the tension. Also, the acceleration of the system remains unchanged.
  • If M1 = M2 = M (say), then

Case 6 : Two masses M1 and M2 are attached to the ends of a string over a pulley attached to the top of a double inclined plane of angle of inclination α and β.
Let M2 move downwards with acceleration a and the tension in the string be T then
FBD of M1
Equation of motion for M1
T – M1g sin α = M1a
or T = M1g sin α + M1a ...(1)

FBD of M2   
Equation of motion for M2
M2g sinβ – T = M2a
or   T = M2g sin β  – M2a ...(2)
Using eqn. (1) and (2) we get,
M1g sin α + M1a = M2g sin β – M2a
Solving we get,  

Case 7 : A person/monkey climbing a rope

  • A person of mass M climbs up a rope with acceleration a. The tension in the rope will be M(g+a).
T – Mg = Ma ⇒ T = M(g + a)
  • If the person climbs down along the rope with acceleration a, the tension in the rope will be M(g–a).
Mg – T = Ma ⇒ T = M(g – a)
  • When the person climbs up or down with uniform speed, tension in the string will be Mg.

Case 8 : A body starting from rest moves along a smooth inclined plane of length l, height h and having angle of inclination θ.
FBD of body
(where N=R is normal reaction applied by plane on the body of mass m)
For downward motion, along the inclined plane,
By work-energy theorem loss in P.E. = gain in K.E.
Also, from the figure, h = l sin θ.      
  • Acceleration down the plane is g sin θ.
  • Its velocity at the bottom of the inclined plane will be
  • Time taken to reach the bottom will be  
  • If angles of inclination are θ1 and θ2 for two inclined planes  
Keeping the length constant then

Case 9 : Weight of  a man in a lift :
  1. When lift is accelerated upward
In this case the man also moves in upward direction with an acceleration
Then from Newton’ second law
N – mg = ma or N = m(g + a)
or Wapp = m(g + a) (as W = mg)
Where Wapp is apparent weight of the man in the lift, Wo is the real weight, N is the reaction of lift on the man. It is clear that N = Wapp
When the lift moves upward and if we measure the weight of the man by any means (such as spring balance) then we observe more weight (i.e., Wapp) than the real weight (Wo) Wapp >Wo
  1. When lift is accelerated downward
In this case from Newton’s second law
mg – N = ma
or N = m(g – a) = Wo(1– a/g)
or W'app= Wo(1– a/g)  
If we measure the weight of man by spring balance, we observe deficiency because Wapp< Wo.

  1. When lift is at rest or moving with constant velocity
From Newton’s second law   
N –mg = 0  or N = mg
In this case spring balance gives the true weight of the man.

Case 10 : Three masses M1, M2 and M3 are placed on a smooth surface in contact with each other as shown in the figure. A force F pushes them as shown in the figure and the three masses move with acceleration a,
⇒ F – F1 = m1a ...(i)
⇒ F1 – F2 = m2a ...(ii)
⇒ F2 = M3 a ...(iii)
Adding eqns. (i), (ii) and (iii) we get,

  • When a man jumps with load on his head, the apparent weight of the load and the man is zero.
  • If a person sitting in a train moving with uniform velocity throws a coin vertically up, then coin will fall back in his hand.
  • If the train is uniformly accelerated, the coin will fall behind him.
  • If the train is retarded uniformly, then the coin will fall in front of him.


A system is said to be isolated, when no external force acts on it. For such isolated system, the linear momentum is constant i.e., conserved.
The linear momentum is defined as
where is the velocity of the body, whose mass is m. The direction of is same as the direction of the velocity of the body. It is a vector quantity.  From Newton’s second law,
i.e., time rate of change in momentum of the body is equal to total external force applied on the body.
If or = constant   .....(3)
This is called law of conservation of  momentum.
Now let us consider a rigid body consisting of a large number of particles moving with different velocities, then total linear momentum of the rigid body is equal to the summation of individual linear momentum of all particles
where are individual linear momentum of first, second and nth particle respectively.
If this rigid body is isolated i.e., no external force is applied on it, then constant (from Newton’s second law).
Further we know that internal forces (such as intermolecular forces etc.) also act inside the body, but these can only change individual linear momentum of the particles
(i.e., p1, p2.........), but their total momentum remains constant.


If a gun of mass M fires a bullet of mass m with velocity v. Then from law of conservation of momentum, as initially bullet & gun are at rest position i.e., initial momentum is zero, so final momentum (gun + bullet) must also be zero.
Since on firing, the bullet moves with velocity in forward direction, then from Newton’s third law, the gun moves in backward direction . So,     
Initial momentum = final momentum
(–ve sign shows that the vel. of gun will have the opposite direction to that of bullet)


According to Newton’s second law the rate of change of momentum of a particle is equal to the total external force applied on it (particle) i.e.,
or  or   ...(ii)
Where is momentum of the particle at initial time ti and when we apply some external force its final momentum is at time tf . The quantity on R.H.S in equation (ii) is called the impulse.
We can write equation (ii) as
So, the impulse of the force is equal to the change in momentum of the particle. It is known as impulse momentum theorem.
Force vary with time and impulse is area under force versus time curve
Force constant with time i.e., constant with time (shown by horizontal line) and it would give same impulse to particle in time Δt = tf–ti as time varying force described.

It is a vector quantity having a magnitude equal to the area under the force-time curve as shown in fig. (a). In this figure, it is assumed that force varies with time and is non-zero in time interval Δt = tf–ti. Fig.(b) shows the time averaged force   i.e., it is constant in time interval Δt, then equation (iii) can be written as
The direction of impulsive vector I is same as the direction of change in momentum. Impulse I has same dimensions as that of momentum i.e, [MLT–1]


It is based on principle of conservation of linear momentum.
In rocket, the fuel burns and produces gases at high temperature. These gases are ejected out of the rocket from nozzle at the backside of rocket and the ejecting gas exerts a forward force on the rocket which accelerates it.
Let the gas ejects at a rate
and at constant velocity u w.r.t. rocket then from the conservation of linear momentum
where M = M0 - rt and M0 is mass of rocket with fuel and solving this equation,
we get
where v = velocity of rocket w.r.t. ground.


When a body is in motion on a rough surface, or when an object moves through water (i.e., viscous medium), then velocity of the body decreases constantly even if no external force is applied on the body. This is due to friction.
So “an opposing force which comes into existence, when two surfaces are in contact with each other and try to move relative to one another, is called friction”.
Frictional force acts along the common surface between the two bodies in such a direction so as to oppose the relative movement of the two bodies.

The force of static friction fs between book and rough surface is opposite to the applied external force Fext. The force of static friction fs =
When exceeds the certain maximum value of static friction, the book starts accelerating and during motion Kinetic frictional force is present.
A graph versus | f | shown in figure. It is clear that fs, ,max > fk
Fig.(a) shows a book on a horizontal rough surface. Now if we apply external force , on the book, then the book will remain stationary if is not too large. If we increase then frictional force f also increase up to (called maximum force of static friction or limiting friction) and = μsN. At any instant when is slightly greater than then the book moves and accelerates to the right.
Fig.(b) when the book is in motion, the retarding frictional force become less than
Fig.(c) is equal to μkN. When the book is in motion, we call the retarding frictional force as the force of kinetic friction fk.
Since fk<, so it is clear that we require more force to start motion than to maintain it against friction.
By experiment one can find that and fk are proportional to normal force N acting on the book (by rough surface) and depends on the roughness of the two surfaces in contact.

Note :
  • The force of static friction between any two surfaces in contact is opposite to and given by and (when the body just moves in the right direction).
where N = W = weight of book and μs is called coefficient of static friction, fs is called force of static friction and  is called limiting friction or maximum value of static friction.
  • The force of kinetic friction is opposite to the direction of motion and is given by fk = μkN
    where μk is coefficient of kinetic friction.
  • The value of μk and μs depends on the nature of surfaces and μk is always less then μs.


Now we consider a book on an inclined plane & it just moves or slips, then by definition
Now from figure, and R = mg cosθ
μs= tanθ   or θ = tan–1s)
where angle θ is called the angle of friction or angle of repose


  • The force of kinetic friction is less than the force of static friction and the force of rolling friction is less than force of kinetic friction i.e.,
fr <  fk  <  fs    or μrolling < μkinetic < μstatic
hence it is easy to roll the drum in comparison to sliding it.
  • Frictional force does not oppose the motion in all cases, in fact in some cases the body moves due to it.
In the figure, book B moves to the right due to friction between A and B. If book A is totally smooth (i.e., frictionless) then book B does not move to the right. This is because of no force applies on the book B in the right direction.


  • The force of friction is independent of area of surfaces in contact and relative velocity between them (if it is not too high).
  • The force of friction depends on the nature of material of surfaces in contact (i.e., force of adhesion). μ depends upon nature of the surface. It is independent of the normal reaction.
  • The force of friction is directly proportional to normal reaction i.e., F ∝ N or F = mn.
While solving a problem having friction involved, follow the given methodology


The name rolling friction is a misnomer. Rolling friction has nothing to do with rolling. Rolling friction occurs during rolling as well as sliding operation.

When a body is kept on a surface of another body it causes a depression (an exaggerated view shown in the figure). When the body moves, it has to overcome the depression. This is the cause of rolling friction.

Note:- Rolling friction will be zero only when both the bodies in contact are rigid. Rolling friction is very small as compared to sliding friction. Work done by rolling friction is zero.


If work done on a particle is zero in complete round trip, the force is said to be conservative. The gravitational force, electrostatics force, elastic force etc., are conservative forces. On the other hand if the work done on a body is not zero during a complete round trip, the force is said to be non-conservative. The frictional force, viscous force etc. are non-conservative forces.
Figure shows three processes A, B and C by which we can reach from an initial position to final position. If force is conservative, then work done is same in all the three processes i.e., independent of the path followed between initial and final position. If force is non conservative then work done from i to f is different in all three paths A, B and C.

Hence it is clear that work done in conservative force depends only on initial & final position irrespective of the path followed between initial & final position. In case of non-conservative forces the work done depends on the path followed between initial and final position.

We can say also that there is no change in kinetic energy of the body in complete round trip in case of conservative force. While in case of non-conservative forces, when a body return to its initial position after completing the round trip, the kinetic energy of the body may be more or less than the kinetic energy with which it starts.



Let us consider a particle of mass m attached to a string of length R let the particle be rotated about its centre O.
At t = 0 the particle start with velocity u from the point A (lowest point of vertical circle) and at time t its position is P. Then the tension at point P is given by
or      ...(1)
So tension at point A (lowest point of vertical circle) is
    (θ  = 0º)    ...(2)
and tension at point B (highest point of vertical circle) is
(θ =180º)    ...(3)
Where is centripetal force required for the particle to move in a vertical circle.
Now from law of conservation of energy
or,    ...(4)
(change in kinetic energy of particle)  = (change in potential energy of particle)
Or (loss in kinetic energy of the particle) = (gain in potential energy)

In conservative force system (such as gravity force) the mechanical energy (i.e., kinetic energy + potential energy) must be constant.
Total energy will be constant
Now from eqns.(2) and (3), we get
or TA = TB + 6mg                    ...(6)

So it is clear from eqn. (6) that tension in string at lowest point of vertical circle is greater then the tension at highest point of vertical circle by 6mg.

If we reduce the velocity vA in equation (2), then TA will be reduce and at some critical velocity vc, TB will be zero, then put TB = 0 and vB = vC in equation (3) and we obtain
In this condition the necessary centripetal force at point B is provided by the weight of the particle [see again equation (3)] then from equation (4), we get
then the tension at the point A will be
Hence if we rotate a particle in a vertical circle and tension in string at highest point is zero, then the tension at lowest point of vertical circle is 6 times of the weight of the particle.

  • The body will complete the vertical circle if its velocity at lowest point is equal to or greater than
  • The body will oscillate about the lowest point if its velocity at lowest point is less then . This will happen when the velocity at the halfway mark, i.e.
  • The string become slack and fails to describe the circle when its velocity at lowest point lies between


To safely negotiate a curve of radius r, a cyclist should bend at an angle θ with the vertical.
Which is given by tan θ = .
Angle θ is also called as angle of banking.


A vehicle can safely negotiate a curve of radius r on a rough level road when coefficient of sliding friction is related to the velocity as.
Now consider a case when a vehicle is moving in a circle, the centrifugal force is whereas m is mass of vehicle, r = radius of circle and v is its velocity.
The frictional force is static since wheels are in rolling motion because point of contact with the surface is at rest


A vehicle can safely negotiate a curve of radius r on a smooth (frictionless) road, when the angle θ of  banking of the road is given by
When the banked surface is smooth, the force acting will be gravity and normal force only.
Balancing forces


The maximum velocity with which a vehicle can safely negotiate a curve of radius r on a rough inclined road is given by
v2 =
where μ is the coefficient of friction of the rough surface on which the vehicle is moving, and θ is the angle of inclined road with the horizontal.
Suppose a vehicle is moving in a circle of radius r on a rough inclined road whose coefficient of friction is and angle of banking is θ.
Let velocity of object (vehicle) be V.
If we apply pseudo force on body, centrifugal force is
when v is max. and friction force will be acting down the slope.
Balancing the force horizontally, ...(1)
Balancing the force vertically,   ...(2)
when v = maximum,  f = fmax = fs = μN ...(3)
From eqn. (2),   
From eqns.(1) and (3),  
Now in the case of minimum velocity with which body could move in a circular motion, the direction of friction will be opposite to that one in maximum velocity case.

Whenever a particle is moving on the circular path then there must be some external force which will provide the necessary centripetal acceleration to the particle. For examples :

Here the centripetal force is provided by the gravitational force.

Here the required centripetal force is provided by the Coulombian force

Here the centripetal force is provided by the tension.
Horizontal circle
Vertical circle
At point A,
At point B,        

At point C,


Consider an inextensible string of length l which is fixed at one end, A. At the other end is attached a particle P of mass m describing a circle with constant angular velocity ω in a horizontal plane.
As P rotates, the string AP traces out the surface of a cone. Consequently the system is known as a conical pendulum.
Vertically, ... (1)
Horizontally, ... (2)
In triangle AOP, ... (3)
and ... (4)
Several interesting facts can be deduced from these equations :
  • It is impossible for the string to be horizontal.
This is seen from eqn.(1) in which cannot be zero. Hence θ cannot be 90°.
  • The tension is always greater than mg.
This also follows from eqn. (1)  as cos θ < 1 (θ is acute but not zero).  Hence, T > mg
  • The tension can be calculated without knowing the inclination of the string since, from eqn. (2) and (3)
  • The vertical depth h of P below A is independent of the length of the string since from eqn. (1) and (4)  but  

which is independent of l.

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Laws of Motion | Physics Notes for IITJEE/NEET
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