Microsoft Math Solver

\displaystyle{{\log}_{{2}}{\left({5}\right)}}={3.223} Explanation: \displaystyle{{\log}_{{2}}{\left({5}\right)}}=\frac{{\log{{5}}}}{{\log{{2}}}} = \displaystyle\frac{{0.6990}}{{0.3010}} ...

It will depend upon your calculator and its built-in functions. (see below for two examples) \displaystyle{\log{{2.3}}}\approx{0.3617} Explanation: First Calculator from my desk drawer: Sharp ...

\begin{eqnarray} \log(2+i)&=&\log\left(\sqrt{(\Re{(2+i)})^2+(\Im{(2+i)})^2 }e^{i\tan^{-1}\left(\frac{{\Im{(2+i)}}}{{\Re{(2+i)}}}\right)}\right)\\ &=&\log\left(\sqrt{2^2+1^2 }e^{i\tan^{-1}(\frac12)}\right)\\ &=&\log\left(\sqrt{2^2+1^2 }\right)+\log\left(e^{i\tan^{-1}(\frac12)}\right)\\ &=&\log\sqrt{5}+i\tan^{-1}(1/2)\\ \end{eqnarray}

Well, there's one mistake along the way that I have spotted: \cdots=\left\{\left(1+\frac13+\frac15+\frac17\color{red}{+\cdots}\right)-\left(\frac12+\frac14+\frac16 +\frac18\color{red}{+\cdots} \right)\right\} ...

\displaystyle\frac{{3}}{{2}}\cdot{a}+\frac{{1}}{{2}}\cdot{b}+\frac{{1}}{{2}}{\log{{5}}} . Explanation: Using the Usual Rules of \displaystyle{\log} , \displaystyle{\log{{\left(\sqrt{{60}}\sqrt{{2}}\right)}}}={\log{\sqrt{{60}}}}+{\log{\sqrt{{2}}}} ...

(i) There is no mistake in your work here: x = 0 is correct. (ii) Your work up to and including this statement is correct: -x = \log2+x\log e. I think you made mistakenly canceled the x ...