Microsoft Math Solver

Konstantinos Michailidis May 26, 2016 We have that \displaystyle\sqrt{{{2}{x}^{{2}}+{3}{x}}}-{4}{x}={\left(\sqrt{{{2}{x}^{{2}}+{3}{x}}}-{4}{x}\right)}\cdot\frac{{\sqrt{{{2}{x}^{{2}}+{3}{x}}}+{4}{x}}}{{\sqrt{{{2}{x}^{{2}}+{3}{x}}}+{4}{x}}}=\frac{{{\left(\sqrt{{{2}{x}^{{2}}+{3}{x}}}\right)}^{{2}}-{\left({4}{x}\right)}^{{2}}}}{{{\left(\sqrt{{{2}{x}^{{2}}+{3}{x}}}+{4}{x}\right)}}}=\frac{{{2}{x}^{{2}}+{3}{x}-{16}{x}^{{2}}}}{{{\left(\sqrt{{{2}{x}^{{2}}+{3}{x}}}+{4}{x}\right)}}}=\frac{{{3}{x}-{14}{x}^{{2}}}}{{{x}{\left(\sqrt{{{2}+\frac{{3}}{{x}}}}+{4}\right)}}}={x}^{{2}}\frac{{\frac{{3}}{{x}}-{14}}}{{{x}{\left(\sqrt{{{2}+\frac{{3}}{{x}}}}+{4}\right)}}}={x}\frac{{\frac{{3}}{{x}}-{14}}}{{\sqrt{{{2}+\frac{{3}}{{x}}}}+{4}}} ...

\displaystyle{\left[-\sqrt{{{6}}},\sqrt{{{6}}}\right]} Explanation: To find the domain of a function, we find all possible values of its input which give a defined function. Here, we have \displaystyle\sqrt{{{12}-{2}{x}^{{2}}}} ...

The maximum of 2x+5y under the constraint x^2+y^2=1 can be easily found by Lagrange multipliers or just the Cauchy-Schwarz inequality : \left|2x+5y\right| \leq \sqrt{2^2+5^2}\sqrt{x^2+y^2} = \color{red}{\sqrt{29}} ...

I guessed that f is of the form \sqrt{ax^2+b}. Then, f^2 is \sqrt{a^2x^2 + \frac{a^2-1}{a-1}b}. From here on in, it is algebra: a^2 =-1 \implies a = i ~~~~\text{and}~~~~\frac{a^2-1}{a-1}b = 1 \implies b = \frac{1-i}{2} ...

\displaystyle{f}'{\left({x}\right)}=\frac{{{1}-{2}{x}^{{2}}}}{\sqrt{{{1}-{x}^{{2}}}}} Explanation: The product rule: \displaystyle\frac{{d}}{{\left.{d}{x}\right.}}{\left[{g{{\left({x}\right)}}}{h}{\left({x}\right)}\right]}={g}'{\left({x}\right)}{h}{\left({x}\right)}+{g{{\left({x}\right)}}}{h}'{\left({x}\right)} ...

Hints: \sin u:= x\implies du\cos u=dx\implies \int\sqrt{1-x^2}\,dx=\int \cos^2u\,du=\frac{u+\sin u\cos u}2\;\ldots