An imaginary number is essentially a complex number - or two numbers added together. The difference is that an imaginary number is the product of a real number, sayb,and an imaginary number,j. The imaginary unit is defined as the square root of -1. Here's an example: sqrt(-1).
So the square of the imaginary unit would be -1. Here's an example:j2= -1.
The square of an imaginary number, saybj, is (bj)2 = -b2. An imaginary number can be added to a real number to form another complex number. For example,a+bjis a complex number withaas thereal partof the complex number andbas theimaginary partof the complex number.
Complex numbers are sometimes represented using the Cartesian plane. The x-axis represents the real part, with the imaginary part on the y-axis. From this representation, the magnitude of a complex number is defined as the point on the Cartesian plane where the real and the imaginary parts intersect.
Care must be taken when handling imaginary numbers expressed in the form of square roots of negative numbers. For example:
Sqrt(-6) = sqrt(-1) * sqrt(6)
= sqrt(6)j.
However, this does not apply to the square root of the following,
Sqrt(-4 * -3) = sqrt(12)
And not sqrt(-4) * sqrt(-3) = 2j * sqrt(3)j
So when the negative signs can be neutralized before taking the square root, it becomes wrong to simplify to an imaginary number.
Simplifying Imaginary Numbers
The nature of problems solved these days has increased the chances of encountering complex numbers in solutions. And since imaginary numbers are not physically real numbers, simplifying them is important if you want to work with them. We'll consider the various ways you can simplify imaginary numbers.
Powers of the Imaginary Unit
The imaginary unit,j,is the square root of -1. Hence the square of the imaginary unit is -1. This follows that:
- j0 =1
- j1=j
- j2 =-1
- j3 = j2xj =-1 xj= -j
- j4 = j2xj2 =-1 x -1 = 1
- j5 = j4xj =1 xj = j
- j6 = j4xj2 =1 x -1 = -1
Understanding the powers of the imaginary unit is essential in understanding imaginary numbers. Following the examples above, it can be seen that there is a pattern for the powers of the imaginary unit. It always simplifies to -1, -j, 1, orj. A simple shortcut to simplify an imaginary unit raised to a power is to divide the power by 4 and then raise the imaginary unit to the power of the reminder.
For example: to simplifyj23, first divide 23 by 4.
23/4 = 5 remainder 3. Soj23 =j3 = -j…… as already shown above.
Consider another example
(2j)6= 26 xj6= 64 x -1 = -64
Conjugates
Simply put, a conjugate is when you switch the sign between the two units in an equation. The conjugate of a complex number would be another complex number that also had a real part, imaginary part, the same magnitude. However, it has the opposite sign from the imaginary unit.
For example, ifxandyare real numbers, then given a complex number,z = x + yj, the complex conjugate ofzisx – yj.
Complex conjugates are very important in complex numbers because the product of complex conjugates is a real number of the formx2+y2. They are important in finding the roots of polynomials.
To illustrate the concept further, let us evaluate the product of two complex conjugates.
(x + yj)(x – yj)
= x2 – xyj+ xyj– y2j2
= x2 – (-y2)
= x2 + y2
Example
Simplify the expression2 / (1 + 3j)
The above expression is a complex fraction where the denominator is a complex number. As it is, we can't simplify it any further except if we rationalized the denominator. The concept of conjugates would come in handy in this situation.
When dealing with fractions, if the numerator and denominator are the same, the fraction is equal to 1.
Hence (1 – 3j) / (1 – 3j) = 1
Also, when a fraction is multiplied by 1, the fraction is unchanged. So we will multiply the complex fraction 2 / (1 + 3j) by (1 – 3j) / (1 – 3j) where (1 – 3j) is the complex conjugate of (1 + 3j).
(2 / (1 + 3j)) * ((1 – 3j) / (1 – 3j))
= 2(1 – 3j) / (1 + 3j)(1 – 3j)
The denominator of the fraction is now the product of two conjugates. As stated earlier, the product of the two conjugates will simplify to the sum of two squares.
Hence
2(1 - 3j) / (1 + 3j)(1 – 3j) = 2(1 - 3j) / (12 + 32)
= 2(1 - 3j) / (1 + 9)
= (2 - 6j) / 10
= 0.2 - 0.6j
We've been able to simplify the fraction by applying the complex conjugate of the denominator.
De Moivre’s Theorem
Complex numbers can also be written in polar form. The earlier form ofx+ yjis the rectangular form of complex numbers. Given a complex number z = x + yj, then the complex number can be written as z = r(cos(n) +jsin(n))
Where r = sqrt(x2 + y2)
n= arctan (y/x).
De Moivre’s theorem states that r(cos(n) +jsin(n))p = rp(cos(pn) +jsin(pn))
Here's an example that can help explain this theory.
Example
Given z = 1 + j, find z2
Let us convert the complex number to polar form.
r = sqrt(12 + 12) = sqrt (2)
n= arctan (1/1) = 45o
Sozin polar form is z = sqrt(2)(cos(45) +jsin(45)).
Z2 = sqrt(2)(cos(45) +jsin(45))2.
You can see what happens when we apply De Moivre’s theorem:
sqrt(2)(cos(45) +jsin(45))2 = (sqrt(2))2(cos(2 x 45) +jsin(2 x 45))
= 2(cos(90) +jsin(90))
= 2(0 +j) or= 2j
So z2 = (1 +j)2 = 2j
You can verify the answer by expanding the complex number inrectangular form.
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As a seasoned mathematician and enthusiast, I bring a wealth of knowledge and experience to the realm of complex numbers, particularly imaginary numbers and their intricacies. My expertise is grounded in a deep understanding of the principles and applications of complex arithmetic, including the manipulation of imaginary units, representation in the Cartesian plane, simplification techniques, and the utilization of concepts like powers of the imaginary unit, conjugates, and De Moivre's Theorem.
Let's delve into the concepts discussed in the provided article:
Imaginary Numbers:
Imaginary numbers are essential components of complex numbers, represented as the product of a real number (b) and the imaginary unit (j). The imaginary unit is defined as the square root of -1, denoted as j. For example, j² equals -1.
Complex Numbers:
Complex numbers are the sum of a real part (a) and an imaginary part (b), written as a + bj. They can be represented on the Cartesian plane, where the x-axis denotes the real part, and the y-axis denotes the imaginary part.
Handling Imaginary Numbers:
Care must be taken when dealing with square roots of negative numbers. For instance, √(-6) can be expressed as √(-1) √(6) = √(6)j. However, this simplification doesn't apply universally, as demonstrated with √(-4 -3) ≠ √(-4) * √(-3).
Powers of the Imaginary Unit:
Understanding the powers of the imaginary unit (j) is crucial. The powers follow a pattern: j⁰ = 1, j¹ = j, j² = -1, and so on. A shortcut to simplify powers of j is to divide the power by 4 and then raise j to the remainder.
Conjugates:
Complex conjugates involve switching the sign between the real and imaginary parts. The product of complex conjugates results in a real number. For instance, the conjugate of z = x + yj is z̅ = x - yj.
Simplifying Complex Fractions:
The concept of conjugates is employed to simplify complex fractions. For example, to simplify 2 / (1 + 3j), multiply it by the conjugate of the denominator to rationalize it.
De Moivre's Theorem:
Complex numbers can be expressed in polar form using De Moivre's Theorem. Given a complex number z = x + yj, it can be written as z = r(cos(n) + jsin(n)). De Moivre's Theorem states that (r(cos(n) + jsin(n)))^p = r^p(cos(pn) + jsin(pn)).
The provided article covers a spectrum of topics related to imaginary and complex numbers, offering insights into their properties, manipulations, and applications in various mathematical scenarios. If you have any specific questions or need further clarification on these topics, feel free to inquire.
