We've updated our
Privacy Policy effective December 15. Please read our updated Privacy Policy and tap

Study Guides > College Algebra

Solving Polynomial Inequalities

One application of our ability to find intercepts and sketch a graph of polynomials is the ability to solve polynomial inequalities. It is a very common question to ask when a function will be positive and negative. We can solve polynomial inequalities by either utilizing the graph, or by using test values.  

Example: Solving Polynomial Inequalities in Factored From

Solve [latex]\left(x+3\right){\left(x+1\right)}^{2}\left(x-4\right)> 0\\[/latex]

Solution

As with all inequalities, we start by solving the equality [latex]\left(x+3\right){\left(x+1\right)}^{2}\left(x-4\right)= 0\\[/latex], which has solutions at x = -3, -1, and 4. We know the function can only change from positive to negative at these values, so these divide the inputs into 4 intervals. We could choose a test value in each interval and evaluate the function [latex]f\left(x\right) = \left(x+3\right){\left(x+1\right)}^{2}\left(x-4\right)\\[/latex] at each test value to determine if the function is positive or negative in that interval
Interval Test x in interval f(test value) > 0 or < 0
x < -3 -4 72 > 0
-3 < x < -1 -2 -6 < 0
-1 <  x < 4 0 -12 < 0
x > 4 5 288  > 0
On a number line this would look like: Number line with values from -6 to 6 double headed arrows from -6 to -3 read positive, from -3 to -1 read negative, from -1 to positive 4 read negative and from 4 to 6 read positive. From our test values, we can determine this function is positive when x < -3 or x > 4, or in interval notation, [latex]\left(-\infty, -3\right)\cup\left(4,\infty\right)\\[/latex]. We could have also determined on which intervals the function was positive by sketching a graph of the function. We illustrate that technique in the next example.

Example: Solving Polynomial Inequalities in Factored From

Find the domain of the function [latex]v\left(t\right)=\sqrt{6-5t-{t}^{2}}\\[/latex]

Solution

A square root is only defined when the quantity we are taking the square root of, the quantity inside the square root, is zero or greater. Thus, the domain of this function will be when [latex]6 - 5t - {t}^{2}\ge 0\\[/latex]. Again we start by solving the equality [latex]6 - 5t - {t}^{2}= 0\\[/latex]. While we could use the quadratic formula, this equation factors nicely to [latex]\left(6 + t\right)\left(1-t\right)=0\\[/latex], giving horizontal intercepts t = 1 and t = -6. Sketching a graph of this quadratic will allow us to determine when it is positive. Graph of upside down parabola on cartesian coordinate axes passing through (-6,0) and (1,0) From the graph we can see this function is positive for inputs between the intercepts. So [latex]6 - 5t - {t}^{2}\ge 0\\[/latex] is positive for [latex]-6 \le t\le 1\\[/latex], and this will be the domain of the v(t) function.

Example: Solving a Polynomial Inequality Not in Factored Form

Solve the inequality [latex]{x}^{4} - 2{x}^{3} - 3{x}^{2} \gt 0\\[/latex]

Solution

In our other examples, we were given polynomials that were already in factored form, here we have an additional step to finding the intervals on which solutions to the given inequality lie. Again, we will start by solving the equality [latex]{x}^{4} - 2{x}^{3} - 3{x}^{2} = 0\\[/latex]   Notice that there is a common factor of [latex]{x}^{2}\\[/latex] in each term of this polynomial. We can use factoring to simplify in the following way: [latex-display]\begin{array}{ccc}\hfill{x}^{4} - 2{x}^{3} - 3{x}^{2} &\hfill= 0&\hfill\text{ }\\ \hfill{x}^{2}\left({x}^{2} - 2{x} - 3\right) &\hfill = 0 &\hfill\text{ }\\ \hfill{x}^{2}\left({x}^{2} - 2{x} - 3\right) &\hfill = 0 &\hfill\text{ we can also factor the inner polynomial}\\ \hfill{x}^{2}\left({x}^{2} - 3{x} + x - 3\right) &\hfill = 0 &\hfill\text{ }\\\hfill{x}^{2}\left({x}\left(x - 3\right) + 1 \left(x - 3\right)\right) &\hfill = 0 &\hfill\text{ }\\ \hfill{x}^{2}\left(x - 3\right)\left(x + 1 \right)&\hfill = 0&\hfill\text{ }\end{array}\\[/latex-display] Now we can set each factor equal to zero to find the solution to the equality. [latex]\begin{array}{ccc} \hfill{x}^{2} = \hfill0 & \left(x - 3\right) = \hfill 0 &\left(x+1\right) = \hfill 0\\ \hfill {x} = \hfill 0 & x = \hfill 3 & x = \hfill -1\\ \end{array}[/latex]. Note that x = 0 has multiplicity of two, but since our inequality is strictly greater than, we don't need to include it in our solutions. We can choose a test value in each interval and evaluate the function [latex-display]{x}^{4} - 2{x}^{3} - 3{x}^{2} = 0\\[/latex-display] at each test value to determine if the function is positive or negative in that interval
Interval Test x in interval > 0,  < 0
x < -1 -2 x > 0
-1 < x < 0 -1/2  x <  0
0 < x < 3 1 x < 0
x > 3 5 x > 0
We want to have the set of x values that will give us the intervals where the polynomial is greater than zero. Our answer will be [latex]\left(-\infty, -1\right]\cup\left[3,\infty\right)\\[/latex].   The graph of the function gives us additional confirmation of our solution. Screen Shot 2015-11-30 at 4.05.30 PM

Further Examples

Solving a polynomial inequality not in factored form - use factoring by grouping.

https://youtu.be/jmeLkQCFLHs

Solving a polynomial inequality not in factored form - use greatest common factor.

https://youtu.be/zyiad-T6-TI

Solving a polynomial inequality not in factored form - factor a trinomial

https://youtu.be/LC1bwRHcdh4

Writing Equations using Intercepts

Since a polynomial function written in factored form will have a horizontal intercept where each factor is equal to zero, we can form a function that will pass through a set of horizontal intercepts by introducing a corresponding set of factors.

Factored Form of Polynomials

If a polynomial has horizontal intercepts at [latex] x = {x}_{1},{x}_{2},\dots,{x}_{n}\\[/latex], then the polynomial can be written in the factored form [latex]f\left(x\right) = a{\left(x - {x}_{1}\right)}^{{p}_{1}}{\left(x - {x}_{2}\right)}^{{p}_{2}}\dots{\left(x - {x}_{n}\right)}^{{p}_{n}}\\[/latex] where the powers [latex]{p}^{i}\\[/latex] on each factor can be determined by the behavior of the graph at the corresponding intercept, and the stretch factor a can be determined given a value of the function other than the horizontal intercept.

Graphed Polynomial

Write a formula for the polynomial function graphed here. Graph of fourth degree polynomial with intercepts at (-3,0), (2,0) with multiplicity two and (5,0)

Solution

This graph has three horizontal intercepts: x = -3, 2, and 5. At x = -3 and 5 the graph passes through the axis, suggesting the corresponding factors of the polynomial will be linear. At x = 2 the graph bounces at the intercept, suggesting the corresponding factor of the polynomial will be 2nd degree (quadratic). Together, this gives us:[latex]f\left(x\right) = a\left(x + 3\right){\left(x - 2\right)}^{2}\left(x - 5\right)\\[/latex]. To determine hte stretch factor, a we can utilize another point on the graph. Here, the vertical intercept appears to be (0,-2), so we can plug in those values to solve for a: [latex-display]\begin{array}{cc}-2 = &\hfill a\left(0+3\right){\left(0 - 2\right)}^{2}\left(0 - 5\right)\\ -2 = &\hfill -60 a\\ a = \frac{1}{30} &\text{}\end{array}\\[/latex-display] The graphed polynomial appears to represent the function [latex]f\left(x\right) = \frac{1}{30}\left(x + 3\right){\left(x - 2\right)}^{2}\left(x - 5\right)\\[/latex]

Licenses & Attributions

CC licensed content, Original

  • Example: Solving a Polynomial Inequality Not in Factored Form. Authored by: Lumen Learning. License: CC BY: Attribution.

CC licensed content, Shared previously

  • Ex: Solve a Polynomial Inequality - Factor By Grouping (Degree 3). Authored by: Mathispower4u. License: All Rights Reserved. License terms: Standard YouTube License.
  • Ex: Solve a Polynomial Inequality - Factor Using GCF (Degree 3). Authored by: Mathispower4u. License: All Rights Reserved. License terms: Standard YouTube License.
  • Ex: Solve a Polynomial Inequality - Factor a Trinomial (Degree 4). Authored by: Mathispower4u. License: All Rights Reserved. License terms: Standard YouTube License.
  • Precalculus: An Investigation of Functions, Graphs of Polynomial Functions, Solving Polynomial Inequalities. Authored by: David Lippman, Melonie Rasmussen. Located at: http://www.opentextbookstore.com/precalc/1.5/Chapter%203e.pdf. License: CC BY: Attribution.