So far, we have used techniques such as graphing, factoring, and applying the Square Root Property to find exact solutions to certain quadratic equations. We have also learnt how to solve quadratic equations by completing the square.
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Jetzt kostenlos anmeldenSo far, we have used techniques such as graphing, factoring, and applying the Square Root Property to find exact solutions to certain quadratic equations. We have also learnt how to solve quadratic equations by completing the square.
While some of these methods seem to be the best option to solve any type of quadratic equation, it may turn out to be rather difficult if fractions or decimals are involved in the given quadratic equation. However, fear not! There happens to be a solution to solving any form of quadratic equation expressed as the definition above. This is known as the Quadratic Formula.
The Quadratic Formula is an important tool used to determine the solutions for any given quadratic equation. We can apply this concept when solving quadratic equations that cannot be factorized through standard factoring methods.
Note that we can indeed use the Quadratic Formula to find solutions for any form of quadratic equations, even ones that can be factorized.
Before we dive into this topic, let us first recall the standard form of a quadratic equation.
The standard form of a quadratic equation is where
With that in mind, let us now introduce the Quadratic Formula.
For a quadratic equation of the form where the solutions are given by the Quadratic Formula,
.
Notice that the Quadratic Formula has the '±' sign. This means that the formula produces two solutions, namely
.
Given that the Quadratic Formula tells us the roots of a given quadratic equation, we can easily locate these points and plot the graph more accurately.
The Quadratic Formula is derived via completing the square. This section explains its derivation step-by-step as below.
Given the general form of a quadratic equation :
Step 1: Divide the expression by a
Step 2: Subtract from each side
Step 3: Complete the square
Step 4: Factor the left-hand side and simplify the right-hand side
Step 5: Square root each side
Don't forget the '±' sign!
Step 6: Subtract from each side
Step 7: Simplify the expression
Note: this method of completing the square is explained in detail in the topic Completing the Squares. This discussion contains clearly worked examples that show how this derivation is applied to a given quadratic equation. Check it out if you'd like to explore this in greater depth!
In the following sections, we shall look at the properties of roots for given quadratic equations. We will be introduced to a new concept called the discriminant. The discriminant plays a crucial role in understanding the nature of the roots of a quadratic equation.
Before we look into the idea of a discriminant, we need to familiarise ourselves with several important terms to aid our understanding throughout this discussion. Let us begin by defining a rational and irrational root.
A rational root is a solution that can be expressed as a quotient of two integers.
They are represented in the form where p and q are integers where p is the constant of the polynomial and q is the leading coefficient.
An irrational root is a solution that cannot be expressed as a quotient of two integers. They are often represented by infinitely non-repeating decimals or surds.
Next, we shall define what it means to be a perfect square. This concept is crucial when we start using the Quadratic Formula as it determines whether the roots of our given quadratic equation are rational or irrational, as we shall soon see!
A perfect square is an integer that is the square of an integer, that is to say, the product of some integer with itself. This takes the form where p is an integer. Essentially, .
Examples include 9 (32), 16 (42), 25 (52), etc.
Now that we have our key definitions sorted, let us now move on to the concept of a discriminant and its relation to the properties of roots.
To find the number of roots in a given quadratic equation, we shall make use of the discriminant. We can also determine the type of roots the expression holds.
Notice that this is the component inside the square root in the Quadratic Formula.
The condition of a discriminant has three cases.
When the determinant is more than zero, or in other words, b2 – 4ac > 0, we obtain two real distinct roots. This can be further categorized as the following.
If b2 – 4ac is a perfect square then we have two real rational roots;
If b2 – 4ac is not a perfect square then we have two real irrational roots.
The graph for this case is shown below.
Discriminant case when D > 0, Vaia Originals
When the determinant is equal to zero, or in other words, b2 – 4ac = 0, we obtain one real root. This is also known as a repeated root. The graph for this case is shown below.
Discriminant case when D = 0, Vaia Originals
When the determinant is less than zero, or in other words, b2 – 4ac < 0, we obtain two complex conjugate roots. This means that our solution is of the form a + bi where a is the real part and b is the imaginary part. The graph for this case is shown below.
Recall that the imaginary unit is
In this section, we shall look at some worked examples that demonstrate the application of the Quadratic Formula and the discriminant to look for solutions to a given quadratic equation.
Solve the following quadratic equation.
Calculate the discriminant and identify the number and type of roots this expression holds. Then, use the Quadratic Formula to evaluate its solutions.
Solution
Step 1: Identify a, b and c
Step 2: Calculate the discriminant
As D > 0, there are two real distinct roots.
Step 3: Find the solutions
Using the Quadratic Formula we obtain
Note that the component inside the square root is D, or in other words
Here, is a perfect square so we obtain a pair of rational roots
Thus, the solutions are .
The graph for this quadratic equation is plotted below. The green dots represent the solutions to the expression.
Example 1, Vaia Originals
Solve the following quadratic equation.
Calculate the discriminant and identify the number and type of roots this expression holds. Then, use the Quadratic Formula to evaluate their solutions.
Solution
Step 1: Identify a, b and c
Step 2: Calculate the discriminant
As D > 0, there are two real distinct roots.
Step 3: Find the solutions
Using the Quadratic Formula we obtain
Here, is not a perfect square so we obtain a pair of irrational roots
Thus, the solutions are .
The graph for this quadratic equation is plotted below. The green dots represent the solutions to the expression.
Example 2, Vaia Originals
Note that you can keep the roots in the exact form and that the decimal places are an approximate answer.
Solve the following quadratic equation.
Calculate the discriminant and identify the number and type of roots this expression holds. Then, use the Quadratic Formula to evaluate their solutions.
Solution
Step 1: Identify a, b and c
Step 2: Calculate the discriminant
As D = 0, there is one real distinct root.
Step 3: Find the solutions
Using the Quadratic Formula we obtain
Noting that
Thus, the solution is .
The graph for this quadratic equation is plotted below. The green dots represent the solutions of the expression.
Example 3, Vaia Originals
Solve the following quadratic equation.
Calculate the discriminant and identify the number and type of roots this expression holds. Then, use the Quadratic Formula to evaluate their solutions.
Solution
Step 1: Identify a, b and c
Step 2: Calculate the discriminant
As D < 0, there are two complex conjugate roots.
Step 3: Find the solutions
Using the Quadratic Formula we obtain
Noting that
Simplifying this, we obtain
Thus, the solutions are .
The graph for this quadratic equation is plotted below. The green dots represent the solutions to the expression.
Example 4, Vaia Originals
Notice that there are no solutions labelled on this graph. This is because the solutions are imaginary and cannot be graphed in the standard Cartesian plane. The Cartesian plane is represented by real numbers, not imaginary numbers! In this case, we can essentially 'assume' the shape of the graph based on the coefficient of the x2 term and that the y-intercept given by the initial quadratic equation.
In this section, we shall look at the discriminant of a cubic equation and identify the types of roots the expression has, given the value of its discriminant.
For a cubic equation of the (general) form
,
where a ≠ 0, the discriminant is described by the formula
.
The formula for evaluating the discriminant of cubic equations can be quite lengthy. Questions, where this formula may be applied, are often rare in this syllabus. However, it may be helpful to know how it is done for clarity.
Just like the quadratic case, the discriminant for cubic equations has three conditions.
When the discriminant is more than zero, we obtain three (distinct) real roots.
Say we have the cubic equation .
Here, the discriminant is .
Hence, we have three distinct real roots. Factorizing this expression yields
Thus, the roots are .
The graph is shown below.
Example 5, Vaia Originals
Case 2(a): If the discriminant is equal to zero and b2 = 3ac, we obtain three repeated real roots (distinct triple root).
Say we have the cubic equation .
Here, the discriminant is .
Further, .
Hence, we have three repeated real roots. Factorizing this expression yields
Thus, the roots are .
The graph is shown below.
Example 6, Vaia Originals
Case 2(b): If the discriminant is equal to zero and b2 ≠ 3ac, we obtain two repeated real roots (distinct double root) and one real (distinct) root.
Say we have the cubic equation .
Here, the discriminant is .
Further, .
Hence, we have two repeated real roots and one real root. Factorizing this expression yields
Thus, the roots are .
The graph is shown below.
Example 7, Vaia Originals
When the discriminant is less than zero, we obtain one (distinct) real root and a pair of complex conjugate roots.
Say we have the cubic equation .
Here, the discriminant is.
Hence, we have one real root and two complex conjugate roots. Factorizing this expression yields
Thus, the roots are .
The graph is shown below.
Example 8, Vaia Originals
Value of Discriminant | Type and Number of Roots | Graph |
D > 0, D is a perfect square | 2 Real Rational Roots | |
D > 0, D is not a perfect square | 2 Real Irrational Roots | |
D = 0 | 1 Real Repeated Root | |
D < 0 | 2 Complex Conjugate Roots |
A positive discriminant means that the quadratic equation has two real roots while a negative discriminant means that the quadratic equation has two complex roots.
The discriminant is a quantity used to find the number and type of solutions a quadratic equation has.
The discriminant is described by the formula D = b2 – 4ac.
The discriminant is described by the formula D = b2 – 4ac and the quadratic formula is used to determine the solutions of a given quadratic equation.
Formula for discriminant of cubic equation is D = b2c2 + 18abcd − 4b3d − 4ac3 − 27a2d2.
What is the Quadratic Formula used for?
To find solutions of a given quadratic equation
How many solutions does the Quadratic Formula produce? What is the sign in the Quadratic Formula that gives that particular number of solutions?
Two solutions. The '±' sign indicates that there are two solutions when we apply the Quadratic Formula.
How can the Quadratic Formula help us plot the graph of a given quadratic equation?
Since the Quadratic Formula determines the roots of a quadratic equation, we can locate them and plot the graph more accurately
When can we use the Quadratic Formula to solve a given quadratic equation?
We can use this for quadratic equations that cannot be factored (however, we can indeed use it to solve any quadratic equation)
What is another term used to describe a graph with one real root?
Repeated real root
What are the components of a complex solution?
A complex solution takes the form a+bi where a is the real part and b is the imaginary part
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