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s20quiz1315_n2

If $\displaystyle \sinh y+x^3\,y^3=y$ , then find $\displaystyle \frac{dy}{dx}$ by implicit differentiation.
$\displaystyle \frac{dy}{dx} = -{{\cosh y+3\,x^3\,y^2}\over{3\,x^2\,y^3-1}}$ $\displaystyle \frac{dy}{dx} = -{{\cosh y+3\,x^3\,y^2-1}\over{3\,x^2\,y^3}}$ $\displaystyle \frac{dy}{dx} = \sinh y+x^3\,y^3$ $\displaystyle \frac{dy}{dx} = 3\,x^2\,y^3$ $\displaystyle \frac{dy}{dx} = -{{3\,x^2\,y^3}\over{\cosh y+3\,x^3\,y^2-1}}$ $\displaystyle \frac{dy}{dx} = -{{3\,x^2\,y^3-1}\over{\cosh y+3\,x^3\,y^2}}$
Find the derivative for $f(x) =\displaystyle \arctan x^2$ .
$f'(x) =\displaystyle {{1}\over{x^4+1}}$ $f'(x) =\displaystyle {{x^2}\over{x^4+1}}$ $f'(x) =\displaystyle {{2\,x}\over{\tan x^2}}$ $f'(x) =\displaystyle -{{2\,x\,\left(\sec x^2\right)^2}\over{\tan ^2x^2}}$ $f'(x) =\displaystyle {{2\,x}\over{x^4+1}}$ $f'(x) =\displaystyle {{x^2}\over{\tan x^2}}$
Find the derivative for $f(x) =\displaystyle x^{\cosh x}$ .
$f'(x) =\displaystyle \left(\ln x\right)^{\cosh x}\,\sinh x\,\ln \ln x$ $f'(x) =\displaystyle \left(\ln x\right)^{\cosh x}\,\left(\sinh x\,\ln \ln x+{{\cosh x }\over{x\,\ln x}}\right)$ $f'(x) =\displaystyle {{\cosh x\,\left(\ln x\right)^{\cosh x-1}}\over{x}}$ $f'(x) =\displaystyle x^{\cosh x-1}\,\cosh x$ $f'(x) =\displaystyle x^{\cosh x}\,\ln x\,\sinh x+x^{\cosh x-1}\,\cosh x$
If $\displaystyle \sqrt{y}+\sqrt{x}=x$ , then find $\displaystyle \frac{dy}{dx}$ by implicit differentiation.
$\displaystyle \frac{dy}{dx} = {{1}\over{2\,\sqrt{x}}}$ $\displaystyle \frac{dy}{dx} = {{\left(2\,\sqrt{x}-1\right)\,\sqrt{y}}\over{\sqrt{x}}}$ $\displaystyle \frac{dy}{dx} = {{\sqrt{x}}\over{\left(2\,\sqrt{x}-1\right)\,\sqrt{y}}}$ $\displaystyle \frac{dy}{dx} = \sqrt{y}+\sqrt{x}$ $\displaystyle \frac{dy}{dx} = {{\sqrt{y}}\over{2\,\sqrt{x}\,\sqrt{y}-\sqrt{x}}}$ $\displaystyle \frac{dy}{dx} = {{2\,\sqrt{x}\,\sqrt{y}-\sqrt{x}}\over{\sqrt{y}}}$
Find the derivative for $f(x) =\displaystyle x^{x}$ .
$f'(x) =\displaystyle \left(\ln x\right)^{x}\,\ln \ln x$ $f'(x) =\displaystyle x^{x}\,\ln x+x^{x}$ $f'(x) =\displaystyle x^{x}$ $f'(x) =\displaystyle \left(\ln x\right)^{x}\,\left(\ln \ln x+{{1}\over{\ln x}} \right)$ $f'(x) =\displaystyle \left(\ln x\right)^{x-1}$
Find the derivative for $f(x) =\displaystyle \left(\ln x\right)^{x}$ .
$f'(x) =\displaystyle x^{x}\,\left(\ln x+1\right)$ $f'(x) =\displaystyle \left(\ln x\right)^{x}\,\ln \ln x$ $f'(x) =\displaystyle \left(\ln x\right)^{x-1}$ $f'(x) =\displaystyle \left(\ln x\right)^{x}\,\ln \ln x+\left(\ln x\right)^{x-1}$ $f'(x) =\displaystyle x^{x}$
Find the derivative for $f(x) =\displaystyle \arcsin e^{2\,x}$ .
$f'(x) =\displaystyle {{1}\over{\sqrt{1-e^{4\,x}}}}$ $f'(x) =\displaystyle {{2\,e^{2\,x}}\over{\sin e^{2\,x}}}$ $f'(x) =\displaystyle {{e^{2\,x}}\over{\sin e^{2\,x}}}$ $f'(x) =\displaystyle -{{2\,e^{2\,x}\,\cos e^{2\,x}}\over{\sin ^2e^{2\,x}}}$ $f'(x) =\displaystyle {{e^{2\,x}}\over{\sqrt{1-e^{4\,x}}}}$ $f'(x) =\displaystyle {{2\,e^{2\,x}}\over{\sqrt{1-e^{4\,x}}}}$
If $\displaystyle {{1}\over{y}}+{{1}\over{x}}=1$ , then find $\displaystyle \frac{dy}{dx}$ by implicit differentiation.
$\displaystyle \frac{dy}{dx} = -{{x^2}\over{y^2}}$ $\displaystyle \frac{dy}{dx} = -{{1}\over{x^2}}$ $\displaystyle \frac{dy}{dx} = {{1}\over{y}}+{{1}\over{x}}$ $\displaystyle \frac{dy}{dx} = -{{\left(x^2+1\right)\,y^2}\over{x^2}}$ $\displaystyle \frac{dy}{dx} = -{{y^2}\over{x^2}}$ $\displaystyle \frac{dy}{dx} = -{{x^2}\over{\left(x^2+1\right)\,y^2}}$
Find the derivative for $f(x) =\displaystyle \ln \left\vert 3\,x^2+2\,x-3\right\vert$ .
$f'(x) =\displaystyle 6\,x+2$ $f'(x) =\displaystyle \left(6\,x+2\right)\,\ln \left\vert 3\,x^2+2\,x-3\right\vert$ $f'(x) =\displaystyle {{1}\over{3\,x^2+2\,x-3}}$ $f'(x) =\displaystyle {{6\,x+2}\over{3\,x^2+2\,x-3}}$
Find the derivative for $f(x) =\displaystyle \ln \left(e^{x}+e^ {- x }\right)$ .
$f'(x) =\displaystyle {{e^{x}+e^ {- x }}\over{e^{x}-e^ {- x }}}$ $f'(x) =\displaystyle \coth x$ $f'(x) =\displaystyle \tanh x$ $f'(x) =\displaystyle {{1}\over{e^{x}-e^ {- x }}}$ $f'(x) =\displaystyle {{1}\over{e^{x}+e^ {- x }}}$

Department of Mathematics
Last modified: 2025-05-04