1.04 Discriminant of a quadratic
Quadratic equations and parabolas
We have seen when solving quadratic equations that there can be two, one or no real solutions. Let's think about the graphs of quadratics:
 |
 |
 |
| No solutions | One solution | Two solutions |
As shown above there are only three possibilities, with respect to $x$x intercepts, when graphing quadratics. These possibilities are as follows:
- No real solutions. This means there are no $x$x-intercepts or real zeros.
- One real solution. This is where the two zeros are actually equal, and the parabola has one $x$x-intercept where it just touches the $x$x-axis at the turning point.
- Two real solutions. These are the two distinct zeros or $x$x-intercepts, where the quadratic passes through the $x$x-axis.
The solutions to a quadratic equation correspond to the $x$x values that occur when $y=0$y=0 in a quadratic function, and these are the places where a function crosses the $x$x-axis.
The discriminant
We have revised a range of algebraic techniques to solve quadratic equations, and obviously, if we are able to find these actual solutions, we can answer the question of how many solutions or roots a quadratic has. But there is a faster way!
Let's look again at the quadratic formula:
$x=\frac{-b\pm\sqrt{b^2-4ac}}{2a}$x=−b±√b2−4ac2a
Specifically, let's look at what happens if the square root part $\sqrt{b^2-4ac}$√b2−4ac takes on different values...
$b^2-4ac<0$b2−4ac<0 or $b^2-4ac=0$b2−4ac=0 or $b^2-4ac>0$b2−4ac>0
- If $b^2-4ac<0$b2−4ac<0, then the square root is negative, and we know that we cannot take the square root of a negative number and get real solutions. This is the case where we have zero real roots.
- If $b^2-4ac=0$b2−4ac=0, then the square root is $0$0 and then the quadratic equation becomes just $x=\frac{-b}{2a}$x=−b2a. and we have a single root. This is actually the equation for the axis of symmetry.
- If $b^2-4ac>0$b2−4ac>0, then the square root will have two values, one for $+\sqrt{b^2-4ac}$+√b2−4ac and one for $-\sqrt{b^2-4ac}$−√b2−4ac. The quadratic formula will then generate for us two distinct real roots. If this value is a square number, we will have two rational roots, seeing as the square root of a square number will lead us with a rational result. For any other positive number, we will end up with two roots with surds in them.
This expression $b^2-4ac$b2−4ac within the quadratic formula is called the discriminant, and it determines the number of real solutions a quadratic function will have. The symbol $\Delta$Δ is used as a shortcut for$b^2-4ac$b2−4ac .
$b^2-4ac<0$b2−4ac<0, $0$0 real solutions, $2$2 complex roots, the parabola has no $x$x-intercepts
$b^2-4ac=0$b2−4ac=0, $1$1 real solution, $2$2 equal real roots, the parabola just touches the $x$x-axis
$b^2-4ac>0$b2−4ac>0, $2$2 real solutions, $2$2 distinct real roots, the parabola passes through two different points on the $x$x-axis that may be rational or irrational
Remember that every quadratic function can be sketched, even if it has no real roots. Every quadratic function is a parabola and has a vertex, which means that it has either a maximum or minimum value which can be found. Knowing the value of the discriminant, and the value of $a$a in $y=ax^2+bx+c$y=ax2+bx+c which determines its concavity, can give us enough information for a rough sketch of the parabola.
Practice questions
Question 1
Consider the equation $4x^2-6x+7=0$4x2−6x+7=0.
Find the value of the discriminant.
Using your answer from the previous part, determine the number of real solutions the equation has.
2
A0
B1
C
Question 2
Consider the equation $x^2+22x+121=0$x2+22x+121=0.
Find the value of the discriminant.
Using your answer from the previous part, determine whether the solutions to the equation are rational or irrational.
Irrational
ARational
B
Question 3
Consider the equation $x^2+18x+k+7=0$x2+18x+k+7=0.
Find the values of $k$k for which the equation has no real solutions.
If the equation has no real solutions, what is the smallest integer value that $k$k can have?
Question 4
Identify the graph of the quadratic $f\left(x\right)=ax^2+bx+c$f(x)=ax2+bx+c, where $a>0$a>0 and $b^2-4ac=0$b2−4ac=0.
- Loading Graph...ALoading Graph...BLoading Graph...CLoading Graph...D