Difference between revisions of "Quadratic Inequalities"
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Since all of the non-zero terms are already on the same side we can skip the first step. Now we need to look at the | Since all of the non-zero terms are already on the same side we can skip the first step. Now we need to look at the | ||
discriminant. The discriminant is <math> (-5)^2 - 4(3)(2) = 1</math>. So there are two distinct x-intercepts(zeroes) and we can use the quadratic formula to find them. | discriminant. The discriminant is <math> (-5)^2 - 4(3)(2) = 1</math>. So there are two distinct x-intercepts(zeroes) and we can use the quadratic formula to find them. | ||
| − | By the quadratic formula the x-intercepts are <math> \frac{5 \pm\sqrt{1}}{2(3)} = \frac{5\pm 1}{6}</math>. So the two x-intercepts are <math> (1, 0), and (\frac{2}{3}, 0)</math>. | + | By the quadratic formula the x-intercepts are <math> \frac{5 \pm\sqrt{1}}{2(3)} = \frac{5\pm 1}{6}</math>. So the two x-intercepts are <math> (1, 0), \text{ and } (\frac{2}{3}, 0)</math>. |
Since the coefficient of <math>x^2</math> is positive the parabola opens up. Thus, the answer is <math> (-\infty, \frac{2}{3}]\cup [1, \infty)</math> | Since the coefficient of <math>x^2</math> is positive the parabola opens up. Thus, the answer is <math> (-\infty, \frac{2}{3}]\cup [1, \infty)</math> | ||
[[Math_5|'''Return to Topics Page]] | [[Math_5|'''Return to Topics Page]] | ||
Latest revision as of 17:41, 17 October 2015
Introduction
In this section we will solve inequalities that involve quadratic functions. The approach can be summarized as moving everything onto one side of the inequality sign, preferably so the coefficient of is positive, then find the x-intercept, and use knowledge of whether the parabola opens up or down to solve the problem.
Example
Solve the inequality
Since all of the non-zero terms are already on the same side we can skip the first step. Now we need to look at the discriminant. The discriminant is . So there are two distinct x-intercepts(zeroes) and we can use the quadratic formula to find them. By the quadratic formula the x-intercepts are . So the two x-intercepts are .
Since the coefficient of is positive the parabola opens up. Thus, the answer is
![{\displaystyle (-\infty ,{\frac {2}{3}}]\cup [1,\infty )}](https://wikimedia.org/api/rest_v1/media/math/render/svg/494b4740922af1b4c7dfd48dac92414d70f61d86)