Some of the special products we discovered in lesson 1.08 Factoring using appropriate methods are actually mathematical identities. We will explore what these are in this lesson and how they are different from equations, and we will learn how to prove or verify that they hold true for all values of the variables within them.
While an equation might be true for some specific value of variables within it, a mathematical identity is true for every value of the variables within it. Many of the patterns used in factoring polynomials are mathematical identities.
One mathematical identity we have worked with already is the difference of squares, m^2-n^2=(m-n)(m+n). It is easily proven using a geometric diagram such as the one above.
Another familiar identity we have previously used is {a^{2} + 2 a b + b^{2} = \left(a + b\right)^{2}} when factoring perfect square trinomials. Two more important identities are the sum of cubes and difference of cubes.
In the proof of an identity, it is our job to prove both sides are equal, so we must work with one side of the equation and show that algebraic manipulation leads to the other side. We cannot manipulate both sides of the equation at once because changing both sides assumes that both sides are already equal.
We can extend our knowledge of complex numbers and polynomial identities to find complex factors of polynomials. Using the fact that i^2=-1, we can often rewrite a constant term and factor the expression further. For example,
\begin{aligned}x^2+3&=x^2-3i^2\\&=\left(x+\sqrt{3}i\right)\left(x-\sqrt{3}i\right)\end{aligned}
The perfect square trinomial identity is \left(a+b\right)^2=a^2+2ab+b^2.
Prove the identity.
Use the identity to evaluate 98^2.
Prove x^{n}-1=\left(x-1\right)\left(x^{n-1}+x^{n-2}+\ldots+x+1\right) where n is any positive integer.
Write each polynomial as a product of linear factors. Leave your answer in terms of i.
4x^4+35x^2-9
4x^2-12ix-9
Verify the identity \left(a+bi\right)^4=\left(\left(a^2-b^2\right)+2abi\right)^2.
Important identities we use often are:
We can verify identities mathematically through algebraic manipulation or using geometric diagrams. These identities can be help us describe numerical relationships, and they can be extended to complex numbers.