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Team Operation with Complex Numbers Teachers
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In this section, we shall look at a new concept called an imaginary number. Consider the square root of 2. We know that this yields the non-repeating decimal
Now, what is the square root of -2? You might think that there is no solution to the square root of a negative number. However, this is not true! In fact, this is where the imaginary number comes into play. The concept of an imaginary number stems from the imaginary unit, denoted by the letter i, and is represented by the following derivation:
Thus, the square root of -2 is simply
As a matter of fact, we can add real and imaginary numbers together. This structure of numbers leads us to the idea of a complex number.
A complex number is an algebraic expression that includes the factor i = √-1 and is written in the form z = a + bi.
The standard form of complex numbers is
where
Re (z) = a is the real part of the complex number z
Im (z) = b is the imaginary part of the complex number z
This is also denoted by
There are two important subclasses of complex numbers: for a complex number z = a + bi
If Im (z) = 0, then z = a is a real number
If Re (z) = 0, then z = bi is said to be purely imaginary
Complex numbers have a range of applications. For instance, they are widely used in the field of electrical engineering and quantum mechanics. Complex numbers also help us solve polynomial equations that do not have any real solutions: have a look at Graph and Solve Quadratic Equations which explains how to do this.
We can conduct basic arithmetic operations with complex numbers such as addition, subtraction, multiplication, and division.
In this section we will explain the most important operations you should be able to perform with complex numbers:
To add complex numbers, simply add the corresponding real and imaginary parts. The same rule applies when subtracting complex numbers.
Let z1 and z2 be two complex numbers with z1 = a + bi and z2 = c + di, where a, b, c, and d are real numbers.
Distributing the positive sign in the second term (to both the real and imaginary parts) and collecting like terms, we obtain
Distributing the negative sign in the second term (to both the real and imaginary parts) and collecting like terms, we obtain
Let α = 3 - 2i and β = 5 + 7i be two complex numbers
Calculate α + β
Determine α - β
The Scalar Multiplication of Complex Numbers is the multiplication of a real number and a complex number. In this case, the real number is also called the scalar.
To multiply a complex number by a scalar, simply multiply both the real and imaginary parts by the scalar separately.
Let z = a + bi be a complex number and c be a scalar, where a, b and c are real numbers.
Let α = 3 - 2i and β = 5 + 7i be two complex numbers
Find 7α
In this case, we are multiplying the complex number α by the real number 7 (also called scalar).
Evaluate 2β
In this case, we are multiplying the complex number β by the real number 2 (also called scalar).
Multiplying complex numbers is exactly the same as the binomial expansion technique: apply the FOIL method and combine like terms.
This is how the FOIL method works, step-by-step.
Let z1 and z2 be two complex numbers with z1 = a + bi and z2 = c + di, where a, b, c, and d are real numbers. To multiply them
Noting that i2 = -1, we obtain
Simplifying this, we get
Let α = 3 - 2i and β = 5 + 7i be two complex numbers.
Find α x β
If you have a fraction of complex numbers, multiply the numerator and denominator by the complex conjugate of the denominator.
For a complex number z = a + bi, the complex conjugate of z is denoted by z* = a - bi.
After that, expand and simplify the expression to the standard form of complex numbers. The result is given by the following formula:
When dividing complex numbers be sure to write the final answer in its standard form.
Let's see in practice and step-by-step how to perform complex numbers division. Let z1 and z2 be two complex numbers with z1 = a + bi and z2 = c + di, where a, b, c, and d are real numbers. Dividing z1 by z2, we obtain
The complex conjugate of the denominator, z2 is z2* = c - di.
Now multiplying both the numerator and denominator by z2*, we get
Expanding this expression, we obtain
Finally, combining like terms, we have
Let α = 3 - 2i and β = 5 + 7i be two complex numbers. Here, β is the denominator. The complex conjugate of β is β* = 5 - 7i.
Calculate α ÷ β
Here, β is the denominator. The complex conjugate of β is β* = 5 - 7i. Thus, multiplying the numerator and denominator by β* yields:
| Operation | Formula |
| Addition | |
| Subtraction | |
| Scalar Multiplication | |
| Multiplication | |
| Division |
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How do you do operations with complex numbers?
How to do operations with complex numbers: To conduct operations with complex numbers, we must first identify the real and imaginary parts of the complex number.
How do you divide operations with complex numbers?
How to divide complex numbers:
What are the mathematical operations of complex numbers?
Operations with complex numbers include addition, subtraction, multiplication and division.
How do you solve operations with complex numbers?
How to solve operations with complex numbers: To solve operations with complex numbers, we must first identify the real part and imaginary part of the complex number and then perform the given arithmetic procedure
What are the rules of complex numbers?
The rules of a complex number refer to the relationship between a given complex number say z = a + bi and its complex conjugate z* = a - bi.
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