I'm afraid your formula contains a typo. The actual derivative of f(x) = {2}^{{x}^{2}} is: f'(x) = \mathrm{ln(2)}x\,{2}^{{x}^{2}+1}. Thus the "1" is not a constant to be added to that ...

You can't do what you that, silly. The function described above is continuous and once-differentiable, but it's not twice-differentiable. It is S-shaped, but it's not a sigmoid function. You can't ...

2.249 areal units. Explanation: Let \displaystyle{G}_{{1}}:{y}={4}^{{x}}={2}^{{{2}{x}}} \displaystyle{G}_{{2}}:{y}={2}{\left({2}^{{x}}\right)} \displaystyle{G}_{{3}}:{y}={2}^{{x}}+{6} ...

You can use the points \displaystyle{\left({0},{3}\right)},{\left({1},{4}\right)},{\left({2},{6}\right)} . Also use the asymptote \displaystyle{y}={2} . Explanation: In an exponential graph, ...

graph{y=8 2^x [-10, 10, -5, 5]} Explanation: Here, \displaystyle{y}={2}^{{{x}+{3}}}={2}^{{x}}{2}^{{3}}={8}{\left({2}^{{x}}\right)} , an exponential function. As \displaystyle{x}\to-\infty,{y}\to{0} ...

\displaystyle{y} is an exponential function. Explanation: \displaystyle{y}={2}^{{x}}+{8} \displaystyle{y} is the standard exponential function \displaystyle{f{{\left({x}\right)}}}={2}^{{x}} ...