JEE Exam  >  JEE Notes  >  Physics for JEE Main & Advanced  >  Resolution, Addition & Subtraction of Vectors

Resolution, Addition & Subtraction of Vectors | Physics for JEE Main & Advanced PDF Download

Resolution of Vectors

  • Breaking down a vector into its components is like expressing a number as the sum of two others. Consider the vector "Resolution, Addition & Subtraction of Vectors | Physics for JEE Main & Advanced" on an X-Y plane. 
  • By drawing and constructing, we form a parallelogram, applying the Parallelogram law of vector addition. This yields two vectors, Resolution, Addition & Subtraction of Vectors | Physics for JEE Main & Advancedx, and Resolution, Addition & Subtraction of Vectors | Physics for JEE Main & Advancedy, which are the components of the original vector Resolution, Addition & Subtraction of Vectors | Physics for JEE Main & Advanced.

Representing Vector on X-Y PlaneRepresenting Vector on X-Y Plane

  • To find the magnitudes of these components, we use trigonometry. The x-component (Resolution, Addition & Subtraction of Vectors | Physics for JEE Main & Advancedx) is the magnitude of Resolution, Addition & Subtraction of Vectors | Physics for JEE Main & Advanced times the cosine of the angle (θ), while the y-component (Resolution, Addition & Subtraction of Vectors | Physics for JEE Main & Advancedy) is the magnitude of Resolution, Addition & Subtraction of Vectors | Physics for JEE Main & Advanced times the sine of θ. 
  • The subtended angle touches one component, and the other is automatically determined.
  • In coordinate systems, unit vectors î, ĵ, and k̂ represent X, Y, and Z axes. These unit vectors have a magnitude of 1. Expressing a vector in component form involves multiplying its magnitude by the cosine or sine of the angle, depending on the axis, and then attaching the corresponding unit vector.

Components of a VectorComponents of a Vector

  • In simple terms, a vector a can be expressed as a sum of its x and y components: Resolution, Addition & Subtraction of Vectors | Physics for JEE Main & Advancedx = |Resolution, Addition & Subtraction of Vectors | Physics for JEE Main & Advanced| cos θ î and Resolution, Addition & Subtraction of Vectors | Physics for JEE Main & Advancedy = |Resolution, Addition & Subtraction of Vectors | Physics for JEE Main & Advanced| sin θ ĵ. Therefore, Resolution, Addition & Subtraction of Vectors | Physics for JEE Main & Advanced = Resolution, Addition & Subtraction of Vectors | Physics for JEE Main & Advancedx + Resolution, Addition & Subtraction of Vectors | Physics for JEE Main & Advancedy can be written as (|Resolution, Addition & Subtraction of Vectors | Physics for JEE Main & Advancedx cos θ ) î + (|Resolution, Addition & Subtraction of Vectors | Physics for JEE Main & Advancedysin θ ) ĵ in component form.

Ex. A ball is thrown with an initial velocity of 70 feet per second., at an angle of 35° with the horizontal. Find the vertical and horizontal components of the velocity.

Ans. Let v represent the velocity and use the given information to write v in unit vector form:

v =70(cos(35°))i+70(sin(35°))j

Simplify the scalars, we get:

v ≈57.34i+40.15j 

Since the scalars are the horizontal and vertical components of v,

Therefore, the horizontal component is 57.34 feet per second and the vertical component is 40.15 feet per second.

Addition of Vectors

In vectors, both magnitude and direction matter, therefore the process of addition differs from simple algebraic addition. 

Here are some crucial points regarding vector addition:

  1.  The addition or composition of vectors means finding the resultant of many vectors acting on a body.
  2. Geometric Addition: Vectors are combined geometrically, considering both magnitude and direction.
  3. Independence: Vectors undergoing addition behave independently of each other as if the presence of one does not affect the behavior of the other.

Ex. Find the addition of vectors PQ and QR, where PQ = (3, 4) and QR = (2, 6)
Solution.
We will perform the vector addition by adding their corresponding components
PQ + QR = (3, 4) + (2, 6)
= (3 + 2, 4 + 6)
= (5, 10).

Graphical Representation of Vector Addition

To visualize the sum of vectors a and b (i.e., a + b), one can shift vector b so that its initial point coincides with the terminal point of vector a. The resulting vector, starting from the initial point of a to the terminal point of b, represents the sum a + b.

Graphical Representation of Vector AdditionGraphical Representation of Vector Addition

Triangle’s Law of Vector Addition

The Triangle’s Law states that if two vectors A and B are represented by two sides of a triangle, taken in the same order, then their resultant is represented by the third side of the triangle, taken in the opposite order. Mathematically, this is expressed as A + B = -C.

Triangle Law of Vector AdditionTriangle Law of Vector Addition

Law of Parallelogram Addition of Vectors

The Law of Parallelogram addition of Vectors offers an alternative perspective. If two vectors P and Q are represented by two adjacent sides of a parallelogram, both pointing outwards, then their resultant is given by the diagonal drawn through the intersection of the two vectors. The magnitude and direction of the resultant can be calculated using specific formulas.

Parallelogram Addition of VectorsParallelogram Addition of Vectors

When combining two vectors using the parallelogram method, the magnitude of the resulting vector (R) is determined by the formula: 

(AC)2 = (AE)2 + (EC)

or R2 = (P + Q cos θ)2 + (Q sin θ)2                              

or R = √(P2+ Q2 )+ 2PQcos θ 

This formula essentially relates the lengths of the vectors involved (P and Q) and the angle (θ) between them.

The direction of the resulting vector, relative to vector P, is given by:

tan θ = CE/AE = Qsinθ/(P+Qcosθ)
θ = tan-1 [Qsinθ/(P+Qcosθ)]   

Question for Resolution, Addition & Subtraction of Vectors
Try yourself:What is the formula for finding the magnitude of the resulting vector when two vectors are added using the parallelogram method?
View Solution

Special Cases in Vector Addition

(a) When θ = 0°, cos θ = 1, sin θ = 0°

Substituting for cos θ in equation R = √(P2+ Q2 )+ 2PQcos θ, we get,

R = √(P2+ Q2 )+ 2PQcos θ

   = (P+ Q)2

or R = P+Q (maximum)

Substituting for sin θ  and cos θ  in equation θ = tan-1 [Qsinθ/(P+Qcosθ)], we get,

θ = tan-1 [Qsinθ/(P+Qcosθ)]  

   = tan-1 [(Q×0)/(P+(Q×1))]

  = tan-1(0)

 = 0°

The resultant of two vectors acting in the same direction is equal to the sum of the two. The direction of the resultant coincides with those of the two vectors.

(b) When θ = 180°, cos θ = -1, sin θ = 0°

Substituting for cos θ in equation R = √(P2+ Q2 )+ 2PQcos θ, we get,

R = √(P2+ Q2 )+ 2PQ(-1)

  =√P2+ Q22PQ

   = (P –  Q)(minimum)

or R = P – Q (minimum)

Substituting for sin θ  and cos θ  in equation θ = tan-1 [Qsinθ/(P+Qcosθ)], we get,

θ = tan-1 [Qsinθ/(P+Qcosθ)]  

   = tan-1 [(Q×0)/(P+(Q×(-1)))]

  = tan-1(0)

 = 0°

This magnitude of the resultant of two vectors acting in opposite directions is equal to the difference in magnitudes of the two and represents the minimum value. The direction of the resultant is in the direction of the bigger one.

 (c) When  θ = 90°, cos θ = 0 , sin θ = 1

Substituting for cos θ in equation R = √(P2+ Q2 )+ 2PQcos θ, we get,

R = √(P2+ Q2 )+ (2PQ×0)

   = √P2+ Q2 

Substituting for sin θ  and cos θ  in equation θ = tan-1 [Qsinθ/(P+Qcosθ)], we get,

θ = tan-1 [Qsinθ/(P+Qcosθ)]  

   = tan-1 [(Q×1)/(P+(Q×(0)))] 

  = tan-1(Q/P)

The resultant of two vectors acting at right angles to each other is equal to the square root of the sum of the squares of the magnitudes of the two vectors. The direction of the resultant depends upon their relative magnitudes. 

Ex. Two vectors are given along with their components: A = (2,3) and B = (2,-2). Calculate the magnitude and the angle of the sum C using their components.
Solution.

Let us represent the components of the given vectors as: In the vector A, Ax = 2 and Ay = 3

In the vector B, Bx = 2 and By = -2

Now, adding the two vectors,
A + B = (2, 3) + (2, -2) = (4, 1)
It can also be written as:
C = (4, 1)
Here in C, C= 4 and Cy = 1
The magnitude of the resultant vector C can be calculated as:
|C| = √ ((Cx)2+(Cy)2)
|C| = √ ((4)2 + (1)2)
= √ (16 + 1)
|C| = √ 17 = 4.123 units (Approximately)
The angle can be calculated as follows:
Φ = tan-1 (Cy/ Cx)
Φ = tan-1 (1/4)
Φ ≈ 14.04 degrees

Vector Subtraction

Vector subtraction is a process equivalent to adding the negative of the vector to be subtracted. For instance, if subtracting vector B from vector A, it is essentially the same as adding B to -A.

Vector SubtractionVector Subtraction

Properties of Vector Addition

The properties of vector addition further enhance its utility:

  • Commutativity: The order of vectors in addition does not influence the result, showcasing the commutative property.

Resolution, Addition & Subtraction of Vectors | Physics for JEE Main & Advanced

  • Associativity: While adding three or more vectors, the grouping of vectors does not affect the result, demonstrating the associative property.

Resolution, Addition & Subtraction of Vectors | Physics for JEE Main & Advanced

  • Distributivity: Scalar multiplication distributes over vector addition, offering a convenient mathematical feature.

These properties make vector addition a versatile and powerful operation, applicable in various mathematical and physical scenarios.

Question for Resolution, Addition & Subtraction of Vectors
Try yourself:
What is the magnitude and direction of the resultant vector when two vectors of equal magnitude act in the same direction?
View Solution

The document Resolution, Addition & Subtraction of Vectors | Physics for JEE Main & Advanced is a part of the JEE Course Physics for JEE Main & Advanced.
All you need of JEE at this link: JEE
289 videos|635 docs|179 tests

Top Courses for JEE

FAQs on Resolution, Addition & Subtraction of Vectors - Physics for JEE Main & Advanced

1. What is vector resolution and how is it calculated?
Ans. Vector resolution is the process of breaking down a vector into its components along the coordinate axes. It is calculated using trigonometry, where the magnitude of the vector is multiplied by the cosine of the angle between the vector and the coordinate axis to find the component along that axis.
2. How is vector addition performed and what are the properties of vector addition?
Ans. Vector addition is performed by adding the corresponding components of the vectors. The properties of vector addition include commutativity (order of addition does not matter), associativity (grouping of vectors does not matter), and the existence of an identity element (zero vector).
3. What are some special cases in vector addition?
Ans. Some special cases in vector addition include when vectors are collinear (same direction), anti-parallel (opposite direction), or perpendicular to each other. In these cases, the addition of vectors simplifies to adding or subtracting their magnitudes.
4. How is vector subtraction different from vector addition?
Ans. Vector subtraction involves adding the negative of a vector to another vector. This is equivalent to adding the two vectors in the opposite order. The result is a vector that points from the tip of the second vector to the tip of the first vector.
5. How are vectors added graphically and algebraically?
Ans. Vectors can be added graphically by placing the tail of the second vector at the tip of the first vector and drawing a vector from the tail of the first vector to the tip of the second vector. Algebraically, vectors are added by adding their corresponding components along the coordinate axes.
289 videos|635 docs|179 tests
Download as PDF
Explore Courses for JEE exam

Top Courses for JEE

Signup for Free!
Signup to see your scores go up within 7 days! Learn & Practice with 1000+ FREE Notes, Videos & Tests.
10M+ students study on EduRev
Related Searches

shortcuts and tricks

,

practice quizzes

,

Addition & Subtraction of Vectors | Physics for JEE Main & Advanced

,

Addition & Subtraction of Vectors | Physics for JEE Main & Advanced

,

Viva Questions

,

Free

,

Summary

,

Semester Notes

,

Resolution

,

MCQs

,

pdf

,

Important questions

,

Addition & Subtraction of Vectors | Physics for JEE Main & Advanced

,

Sample Paper

,

Extra Questions

,

Resolution

,

past year papers

,

video lectures

,

Previous Year Questions with Solutions

,

Resolution

,

ppt

,

mock tests for examination

,

Exam

,

study material

,

Objective type Questions

;