\displaystyle{x}\in{\left[-\frac{{1}}{{5}},{2}\right)} Explanation: Given \displaystyle{\left(\text{XXX}\right)}\frac{{{5}{x}+{1}}}{{{x}-{2}}}\le{0} Consider the two cases (note this ...

[-1/2, 5) Explanation: \displaystyle{f{{\left({x}\right)}}}=\frac{{{2}{x}+{1}}}{{{x}-{5}}}\le{0} Solve this inequality by creating a sign charge (sign table) that shows the variation of of the ...

the interval is \displaystyle{\left[{3},\infty\right)} Explanation: the given inequlity is \displaystyle\frac{{{x}+{1}}}{{{x}-{1}}}\le{2} \displaystyle\Rightarrow{\left({x}+{1}\right)}\le{2}{\left({x}-{1}\right)}\Rightarrow{\left({x}+{1}\right)}\le{2}{x}-{2} ...

\displaystyle{x}\in{\left(-\infty,\frac{{2}}{{3}}\right)}\cup{\left[{2},\infty\right)} Explanation: Given inequality \displaystyle\frac{{{x}+{10}}}{{{3}{x}-{2}}}\le{3} \displaystyle\frac{{{x}+{10}}}{{{3}{x}-{2}}}-{3}\le{0} ...

Answer is \displaystyle{x} lies in the interval \displaystyle-{3}\le{x}{<}{7} or \displaystyle{\left[-{3},{7}\right)} . Explanation: First let us work for equality. As \displaystyle\frac{{{x}+{3}}}{{{x}-{7}}}={0} ...

The solution is \displaystyle{x}\in{]}-\infty,-{4}{]}\cup{]}{3},+\infty{[} Explanation: We solve this inequality with a sign chart Let \displaystyle{f{{\left({x}\right)}}}=\frac{{{x}+{4}}}{{{x}-{3}}} ...