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Motion In A Plane Class 11 Physics Notes

MOTION IN A PLANE

SCALARS AND VECTORS

• it must have magnitude.
• it must have direction.
• it must satisfy parallelogram law of vector addition.

TYPES OF VECTORS

and are like vectors. These are also called parallel vectors or collinear vectors.

Here and are equal vectors

and are unlike vectors.

Here and are negative vectors,

Vector which has unit magnitude. It represents direction only. For example take a vector . Unit vector in the direction of is ,  which is denoted as . , is read as “B cap” or "B caret".

A set of unit vectors, having the directions of the positive x, y and z axes of three dimensional rectangular coordinate system are denoted by . They are called orthogonal unit vectors because angle between any of the two unit vectors is 90º.

• The sum of a finite vector and the zero vector is equal to the finite vector

i.e.,

• The multiplication of a zero vector by a finite number n is equal to the zero vector

• The multiplication of a finite by a zero is equal to zero vector

i.e.,  

=  

     

LAWS  OF VECTOR  ALGEBRA

• (Commutative law of addition)
• (Associative law of addition)
• 
• 
• 
• 

ADDITION OF VECTORS

TRIANGLE LAW OF VECTOR ADDITION

Magnitude of is given by

where is the angle between and.

Direction of : Let the resultant makes an angle with the direction of . Then from right angle triangle QNO,

• || is maximum, if cosθ = 1, θ = 0° (parallel vector)

Rmax   = A + B

• || is minimum, if cosθ = –1, θ = 180° (opposite vector)  

Rmin  

• If the vectors A and B are orthogonal,

i.e.,

PARALLELOGRAM LAW OF VECTOR ADDITION

Let the two vectors and, inclined at angle are represented by sides of parallelogram OPQS, then resultant vector is represented by diagonal of the parallelogram.

If < 90° , (acute angle)  =+, is called main (major) diagonal of parallelogram

If > 90° , (obtuse angle) =+, is called minor diagonal.

POLYGON LAW OF VECTOR ADDITION

So,

or,

• Resultant of two unequal vectors cannot be zero.
• Resultant of three coplanar vectors may or may not be zero.
• Minimum no. of coplanar vectors for zero resultant is 2 (for equal magnitude) and 3 (for unequal magnitude).
• Resultant of three non coplanar vectors cannot be zero. Minimum number of non coplanar vectors whose sum can be zero is four.
• Polygon law should be used only for diagram purpose for calculation of resultant vector (For addition of more than 2 vectors) we use components of vector.

1. If , then is a null vector.
2. Null vector or zero vector is defined as a vector whose magnitude is zero and direction indeterminate. Null vector differs from ordinary zero in the sense that ordinary zero is not associated with direction.
3. is called a unit vector. It is unit less and dimensionless vector. Its magnitude is 1. It represents direction only.
4. If , then  and , where are unit vectors of A and B respectively.
5. A vector can be divided or multiplied by a scalar.
6. Vectors of the same kind can only be added or subtracted. It is not possible to add or subtract the vectors of different kind. This rule is also valid for scalars.
7. Vectors of same as well as different kinds can be multiplied.
8. A vector can have any number of components. But it can have only three rectangular components in space and two rectangular components in a plane. Rectangular components are mutually perpendicular.
9. The minimum number of unequal non-coplanar whose vector sum is zero is 4.
10. When

, where is modulus or magnitude of vector.

11. makes 45° with both X and Y-axes. It makes angle 90° with Z-axis.
12. makes angle 54.74° with each of the X, Y and Z-axes.
13. 
14. If then angle between and is .
15. Magnitude of a vector is independent of coordinate axes system.
16. Component of a vector perpendicular to itself is zero.
17. Resultant of two vectors is maximum when θ = 0°, Rmax = A + B
18. Resultant of two vectors is minimum when θ = 180° , Rmin = A – B
19. The magnitude of resultant of and can vary between (A + B) and (A – B)

SUBTRACTION OF VECTORS

   

and is (180° – θ).

RESOLUTION OF A VECTOR

RECTANGULAR COMPONENTS OF A VECTOR IN PLANE

The vector may be written as

where is the component of vector in X-direction and is the component of vector  in the Y-direction.

⇒ A cos θ and A sin θ are the magnitudes of the components of in X and Y-direction respectively.

Also

RECTANGULAR COMPONENTS OF A VECTOR IN 3D

Three rectangular components along X, Y and Z direction are given by Therefore, vector may be written as

and

If , and are the angles subtended by the rectangular components of vector then

cos = cos = and cos =

Also, cos2 + cos2 + cos2 = 1

  

PRODUCT OF TWO VECTORS

SCALAR OR DOT PRODUCT

i.e.,   =  A B cosθ

e.g.

PROPERTIES OF SCALAR OR DOT PRODUCT

2. =  A (B cosθ) =  B (A cosθ)

3. Dot product of two vectors is commutative.
4. 
5.  Dot product is distributive.
6. = (Ax Bx + Ay By + Az Bz)

VECTOR OR CROSS PRODUCT

= (AB sin θ)

The direction of perpendicular to the plane containing vectors and in the sense of advance of a right handed screw rotated from to is through the smaller angle between them.

e.g.,

PROPERTIES OF VECTOR OR CROSS PRODUCT

1. 
2. 
   
3. 
4.   (not commutative)     
5.  (follows distributive law)
6. 

 

= (Ay Bz – Az By) + (Az Bx – Ax Bz) + (Ax By – Ay Bx)

7. The cross product of two vectors represents the area of the parallelogram formed by them.

8. A unit vector which is perpendicular to A as well as B is
   

1. 
2. tan θ =
3. 
4. 
5. If , then
6. 
7. If then angle between and is .
8. If then
9. Division by a vector is not defined. Because, it is not possible to divide by a direction.
10. The sum and product of vectors is independent of coordinate axes system.

CONDITION OF ZERO RESULTANT VECTOR

i.e.

LAMI'S THEOREM

      

or,

MOTION IN A PLANE OR MOTION IN TWO DIMENSIONS

x = ux t +axt2 y = uyt +ayt2

x = y =

VELOCITY

Average velocity

Instantaneous velocity       

The magnitude of  v =

The direction of the velocity, ∴

ACCELERATION

Average acceleration

Instantaneous acceleration

RELATIVE VELOCITY IN TWO DIMENSIONS

• Relative velocity of A w.r.t B

• Relative velocity of B w.r.t. A

Therefore, and

PROJECTILE MOTION

• A uniform velocity in the horizontal direction, which does not change (if there is no air resistance)
• A uniformly changing velocity in the vertical direction due to gravity.

TYPES OF PROJECTILE

• Oblique projectile : In this, the body is given an initial velocity making an angle with the horizontal and it moves under the influence of gravity along a parabolic path.
• Horizontal projectile : In this, the body is given an initial velocity directed along the horizontal and then it moves under the influence of gravity along a parabolic path.

x  = uxt  + axt2

∴   t =    …… (1)

y  = uyt  + ayt2  ⇒ 0 + gt2

y = gt2 …… (2)

From equations (1) and (2) we get  y = which is the equation of a parabola.

v =

tanβ = =

T = and

and x = u cosθ.t

ay =  and  x = u cosθ.t

EQUATION OF TRAJECTORY

y = uyt + ayt2

y = u sinθ t + gt2 ...(2)

y = x tanθ which is the equation of a parabola. Hence the path followed by the projectile is parabolic.

   

.

and at θ = 45º ( maximum value of sin2θ = 1)

1. The horizontal range of the projectile is same at two angles of projection for θ and (90° – θ).
2. The height attained by the projectile above the ground is the largest when the angle of projection with the horizontal is 90° (vertically upward projection). In such a case time of flight is largest but the range is the smallest (zero).
3. If the velocity of projection is doubled. The maximum height attained and the range become 4 times, but the time of flight is doubled.
4. When the horizontal range of the projectile is maximum, (θ = 45°), then the maximum height attained is ¼th of the range.
5. For a projectile fired from the ground, the maximum height is attained after covering a horizontal distance equal to half of the range.

PROJECTILE ON AN INCLINED PLANE

ux = u cos (θ –) along the incline, + x-axis)

uy = u sin (θ –) along the incline, + y-axis)

or

OB = u cos θ t =

OA =

Since  

           

i.e., sin (2θ – α) = 1 or  

or Rmax(on inclined plane)

where Rmax (on horizontal plane) .

so T is max when sin (θ – α) is maximum i.e.,  sin (θ –α) = 1 or

1. Equation of trajectory of an oblique projectile in terms of range (R) is

2. There are two unique times at which the projectile is at the same height h(< H) and the sum of these two times.

Since, h = (u sin θ)t is a quadratic in time, so it has two unique roots t1 and t2 (say) such that sum of roots
(t1 + t2) is and product (t1t2) is .

The time lapse (t1– t2) is

UNIFORM AND NON-UNIFORM CIRCULAR MOTION

UNIFORM CIRCULAR MOTION

i.e.,

i.e.,

Magnitude of the centrifugal force

NON-UNIFORM CIRCULAR MOTION

1. Angular displacement behaves like vector, when its magnitude is very small. It follows laws of vector addition.
2. Angular velocity and angular acceleration are axial vectors.
3. Centripetal acceleration always directed towards the centre of the circular path and is always perpendicular to the instantaneous velocity of the particle.
4. Circular motion is uniform if aT = rα = 0, that is angular velocity remains constant and radial acceleration is constant.
5. When aT or α is present, angular velocity varies with time and net acceleration is
6. If aT = 0 or α = 0, no work is done in circular motion.