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Introduction

Complex numbers are the numbers which are expressed in the form of a+ib where i is an imaginary number called iota and has the value of (√-1). 

Complex Numbers - Introduction and Examples (with Solutions), Quantitative Aptitude - UPSC

Example: 3 + 5i is a complex number, where 3 is a real number and 5i is an imaginary number. Therefore, the combination of both numbers is a complex one.


See the table below to differentiate between a real number and an imaginary number:
Complex Numbers - Introduction and Examples (with Solutions), Quantitative Aptitude - UPSC

  • The main application of these numbers is to represent periodic motions such as water waves, alternating current, light waves, etc., which relies on sine or cosine waves etc. 
  • There are certain formulas which are used to solve the problems based on complex numbers. 
  • Also, the mathematical operations such as addition, subtraction and multiplication are performed on these numbers.

The key concepts are highlighted in this lesson will include the following:

  • Introduction
  • Algebraic Operation on Complex Numbers
  • Formulas
  • Power of iota (i)
  • Identities
  • Modulus and Conjugate of a Complex Number
  • Examples
  • Argand Plane & Polar Representation of Complex Number


Complex Numbers Definition

The complex number is basically the combination of a real number and an imaginary number

The real numbers are the numbers which we usually work on to do the mathematical calculations. But the imaginary numbers are not generally used for calculations but only in the case of imaginary numbers. 

Let us check the definitions for both the numbers:
1. What are Real Numbers?

  • Any number which is present in a number system such as positive, negative, zero, integer, rational, irrational, fractions, etc. are real numbers. It is represented as Re().
    Example: 12, -45, 0, 1/7, 2.8, √5 are all real numbers.

2. What are Imaginary Numbers?

  • The numbers which are not real are imaginary numbers. When we square an imaginary number, it gives a negative result. It is represented as Im().
    Example: √-2, √-7, √-11 are all imaginary numbers.
  • In the 16th century, the complex numbers were introduced, which made it possible to solve the equation x2  +1 = 0. The roots of the equation are of form x = ±√-1 and no real roots exist. Thus, with the introduction of complex numbers, we have Imaginary roots.
  • We denote √-1 with the symbol ‘i’, where i denotes Iota (Imaginary number).
  • An equation of the form z= a+ib, where a and b are real numbers, is defined to be a complex number. The real part is denoted by Re z = a and the imaginary part is denoted by Im z = b.

Algebraic Operation on Complex numbers

There can be four types of algebraic operation on complex numbers.
The four operations on the complex numbers include:

  1. Addition
  2. Subtraction
  3. Multiplication
  4. Division


Quadratic Equations: Complex Numbers

When we solve a quadratic equation of the form ax2+bx+c = 0, the roots of the equations can be determined in three forms:

  1. Two Distinct Real Roots
  2. Similar Root
  3. No Real roots (Complex Roots)


Complex Number Formulas

  1. Addition
    (a + ib) + (c + id) = (a + c) + i(b + d)
  2. Subtraction
    (a + ib) – (c + id) = (a – c) + i(b – d)
  3. Multiplication
    When two complex numbers are multiplied by each other, the multiplication process should be similar to the multiplication of two binomials. It means that FOIL method (Distributive multiplication process) is used.
    (a + ib) (c + id) = (ac – bd) + i(ad + bc)
  4. Division
    (a + ib) / (c + id) = (ac+bd)/ (c2 + d2) + i(bc – ad) / (c2 + d2)
    Question for Complex Numbers - Introduction and Examples (with Solutions), Quantitative Aptitude
    Try yourself:What type of number is  −17i?
    View Solution

    Question for Complex Numbers - Introduction and Examples (with Solutions), Quantitative Aptitude
    Try yourself:What is (4 + 3i) + (2 + 2i)?
    View Solution

Power of Iota (i)

Depending upon the power of “i”, it can take the following values:

  • i4k+1 = i
  • i4k+2 = -1
  • i4k+3 =  -i
  • i4k = 1

Where k can have an integral value (positive or negative).Complex Numbers - Introduction and Examples (with Solutions), Quantitative Aptitude - UPSCSimilarly, we can find for the negative power of i, which are as follows:

  • i-1 = 1 / i
    Multiplying and dividing the above term with i, we have:
    i-1 = i / i  ×  i/i  × i-1  = i / i2 = i / -1 = -i / 1 = -i

Note: √-1 × √-1 = √(-1  × -1) = √1 = 1 contradicts to the fact that i2 = -1.

Therefore, for an imaginary number, √a × √b is not equal to √ab.

Question for Complex Numbers - Introduction and Examples (with Solutions), Quantitative Aptitude
Try yourself:What is  (3 + 2i) (4 − 2i)?
View Solution

Identities

Let us see some of the identities:

  • (z+ z2)2 = (z1)+ (z2)2 + 2 z1 × z2
  • (z– z2)2 = (z1)+ (z2)2 – 2 z1 × z2
  • (z1)– (z2)2 =  (z+ z2)(z– z2)
  • (z+ z2)3 = (z1)3 + 3(z1)2 z +3(z2)2 z1 + (z2 )3
  • (z– z2)3 = (z1)3 – 3(z1)2 z +3(z2)2 z1 – (z2 )3


Modulus and Conjugate

Let z=a+ib be a complex number.

Complex Numbers - Introduction and Examples (with Solutions), Quantitative Aptitude - UPSCThe Modulus of z is represented by |z|:
Complex Numbers - Introduction and Examples (with Solutions), Quantitative Aptitude - UPSC 
The conjugate of “z” is denoted by:
Mathematically, Complex Numbers - Introduction and Examples (with Solutions), Quantitative Aptitude - UPSC


Argand Plane and Polar Representation

  • Similar to the XY plane, the Argand(or complex) plane is a system of rectangular coordinates in which the complex number a+ib is represented by the point whose coordinates are a and b.
  • We find the real and complex components in terms of r and θ, where r is the length of the vector and θ is the angle made with the real axis.
    Complex Numbers - Introduction and Examples (with Solutions), Quantitative Aptitude - UPSC


Problems and Solutions

Example 1: Simplify 
a) 16i + 10i(3-i)
b) 11i + 13i – 2i
Solution: 

a) 16i + 10i(3-i)

= 16i + 10i(3) + 10i (-i)
= 16i +30i – 10i2
= 46 i – 10 (-1)
= 46i + 10

b) 11i + 13i – 2i = 22i

Question for Complex Numbers - Introduction and Examples (with Solutions), Quantitative Aptitude
Try yourself:What is the value of 7i * 5i?
View Solution


Example 2: Express the following in a+ib form.
Complex Numbers - Introduction and Examples (with Solutions), Quantitative Aptitude - UPSC
And then find the Modulus and Conjugate of the complex number.
Solution:
Given
Complex Numbers - Introduction and Examples (with Solutions), Quantitative Aptitude - UPSC
Complex Numbers - Introduction and Examples (with Solutions), Quantitative Aptitude - UPSC
Modulus:
Complex Numbers - Introduction and Examples (with Solutions), Quantitative Aptitude - UPSC
Conjugate:
Complex Numbers - Introduction and Examples (with Solutions), Quantitative Aptitude - UPSC

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FAQs on Complex Numbers - Introduction and Examples (with Solutions), Quantitative Aptitude - UPSC

1. What are complex numbers?
Ans. Complex numbers are numbers that can be expressed in the form a + bi, where a and b are real numbers, and i represents the imaginary unit, which is defined as the square root of -1.
2. What are the algebraic operations on complex numbers?
Ans. The algebraic operations on complex numbers include addition, subtraction, multiplication, and division. Addition and subtraction are performed by adding or subtracting the real and imaginary parts separately. Multiplication is done by using the distributive property and combining like terms. Division is performed by multiplying the numerator and denominator by the conjugate of the denominator.
3. How are complex numbers used in solving quadratic equations?
Ans. Complex numbers are used in solving quadratic equations when the discriminant (b^2 - 4ac) is negative. In such cases, the roots of the quadratic equation are complex conjugates of each other, which means they have the same real part and opposite imaginary parts.
4. What are the modulus and conjugate of a complex number?
Ans. The modulus of a complex number a + bi is the distance of the point (a, b) from the origin in the complex plane and is denoted by |a + bi|. It can be calculated using the formula |a + bi| = √(a^2 + b^2). The conjugate of a complex number a + bi is obtained by changing the sign of the imaginary part and is denoted by a - bi.
5. What is the Argand plane and polar representation of complex numbers?
Ans. The Argand plane is a coordinate plane where the real numbers are represented on the x-axis and the imaginary numbers are represented on the y-axis. Complex numbers can be plotted as points on this plane. The polar representation of a complex number a + bi is given by r(cosθ + i sinθ), where r is the modulus of the complex number and θ is the argument or angle made by the complex number with the positive x-axis.
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