\displaystyle{x}={5}\sqrt{{3}}{\quad\text{and}\quad}{x}=-{3}\sqrt{{3}} Explanation: \displaystyle{x}^{{2}}-{\left({2}\sqrt{{3}}\right)}{x}-{45}={0}{\quad\text{or}\quad}{x}^{{2}}-{\left({2}\sqrt{{3}}\right)}{x}+{\left(\sqrt{{3}}\right)}^{{2}}-{3}-{45}={0}{\quad\text{or}\quad}{\left({x}-\sqrt{{3}}\right)}^{{2}}={48}{\quad\text{or}\quad}{\left({x}-\sqrt{{3}}\right)}=\pm\sqrt{{48}}{\quad\text{or}\quad}{\left({x}-\sqrt{{3}}\right)}=\pm{4}\sqrt{{3}}{\quad\text{or}\quad}{x}=\sqrt{{3}}+{4}\sqrt{{3}}={5}\sqrt{{3}} ...

It is clear from the equation that to complete square, something of the type (a-b)^2 on the left hand side. 4x^2 is already in square form to look like a^2 . Thus a = 2x . To find b^2 ...

\displaystyle{8}{x}^{{2}}+{8}\sqrt{{2}}{x}+{4}={8}{\left({x}+\frac{{1}}{\sqrt{{2}}}\right)}^{{2}}={0} and solution is \displaystyle\pm\frac{{1}}{\sqrt{{2}}} Explanation: \displaystyle{8}{x}^{{2}}+{8}\sqrt{{2}}{x}+{4}={0} ...

Rewrite this equation as a quadratic and solve for \displaystyle{x} . Explanation: The first thing you need to do in order to solve this equation is isolate the radical on one side of the ...

A rather messy completing the square: -5x^2-4\sqrt{5}x+2 -5\left(x^2+\frac{4\sqrt{5}x}{5}\right)+2 2-5\left(x+\frac{2\sqrt{5}}{5} \right)^2+4 (\sqrt{6})^2-\left(\sqrt{5}\left(x+\frac{2\sqrt{5}}{5} \right)\right)^2

I am not sure if I understood well your question. So forgive me if the following answer does not satisfy you. Anyway, if you have an equation like x^2-6x+10=0 not having real solutions, you can ...