The Domain is the set of all values of \displaystyle{x} fro which the function is defined; in this case the domain is \displaystyle{\left[-{4},+{4}\right]} Explanation: Given \displaystyle{\left(\text{XX}\right)}{y}={\left\lbrace{\left(\sqrt{{-{x}}}\ \text{ for }\ -{4}\le{x}\le{0}\right)},{\left(\sqrt{{{x}}}\ \text{ for }\ {0}{<}{x}\le{4}\right)}\right\rbrace} ...

Note that: b\leq(a^{n}+b^{n})^n=b((\frac{a}{b})^n+1)^\frac{1}{n}\leq b2^{\frac{1}{n}}

I_a = (x,y) \cdot (z,x+a) and (x,y) + (z,x+a) =(x,y,z,x+a) = (1), since it contains a \in k \setminus \{0\}. By the Chinese remainder theorem k[x,y,z]/I_a \cong k[x,y,z]/(x,y) \times k[x,y,z]/(z,x+a) \cong k[z] \times k[y] ...

You have derived that F_Y(y) = \Pr\{Y \leq y\} = \Pr\{X \leq \sqrt{y}\} - \Pr\{X \leq -\sqrt{y}\} Differentiating both sides with respect to y, f_Y(y) = \frac {1} {2\sqrt{y}}f_X(\sqrt{y}) + \frac {1} {2\sqrt{y}}f_X(-\sqrt{y}) ...

Hint: The situation for p>0 or p<0 is symmetric with respect to the origin. ( see the figure) The point A is the point where the tangent to the parabola forms an angle of \pi/4 with the x- ...

The problem comes in the second to the last equality. Your equality was: lim_{h→0^-}\frac{\sqrt{|x−h|}}{h}=lim_{h→0^-}\frac{\sqrt{h}}{h} However, as h is negative, |x−h|=-h when x is 0. Thus ...