Zeros of \displaystyle{x}^{{4}}+{2}{x}^{{3}}+{22}{x}^{{2}}+{50}{x}-{75} are \displaystyle-{3} and \displaystyle{1} Explanation: To find all the zeros of \displaystyle{P}{\left({X}\right)}={x}^{{4}}+{2}{x}^{{3}}+{22}{x}^{{2}}+{50}{x}-{75} ...

\displaystyle{f{{\left({x}\right)}}} has zeros \displaystyle-{1},-{5},\pm{3}{i} Explanation: \displaystyle{f{{\left({x}\right)}}}={x}^{{4}}+{6}{x}^{{3}}+{14}{x}^{{2}}+{54}{x}+{45} ...

Zeros of \displaystyle{f{{\left({x}\right)}}} are \displaystyle{\left\lbrace{0},{2},\frac{{3}}{{2}},-\frac{{1}}{{5}}\right\rbrace} Explanation: \displaystyle{f{{\left({x}\right)}}}={x}^{{4}}-{3.3}{x}^{{3}}+{2.3}{x}^{{2}}+{0.6}{x} ...

h(x)=4x4+15x3+12x2+60x-16  No solutions found Rearrange: Rearrange the equation by subtracting what is to the right of the equal sign from both sides of the equation : ...

The FTOA tells us that there are four zeros counting multiplicity. Other methods help us find them: \displaystyle-{2} , \displaystyle-{3} , \displaystyle{2}{i} , \displaystyle-{2}{i} ...

HINT: Every polynomial of odd degree has at least one root in \mathbb{R} This is true by IVT as \lim_{x \to -\infty} f(x) = -\infty and \lim_{x \to \infty} f(x) = \infty. Another way to see why ...