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(A) Statement-$1$: False. The function $f$ must be continuous at $x = c$ for the first derivative test to guarantee a local maximum. For example,consi

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$FFTF$

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(A) Statement-$1$: False. The function $f$ must be continuous at $x = c$ for the first derivative test to guarantee a local maximum. For example,consider a function that is increasing on $(c-\delta, c)$ and decreasing on $(c, c+\delta)$ but has a vertical asymptote or a jump discontinuity at $c$ such that $f(c)$ is not the maximum value.Statement-$2$: False. $A$ function can have a local maximum at $x=c$ and also be an inflection point if the concavity changes at $c$ (e.g.,$f(x) = -x^4$ has a local maximum at $x=0$ and $f''(x) = -12x^2$,which changes sign at $x=0$,making it an inflection point).Statement-$3$: True. $f(x) = x^2 |x| = x^3$ for $x \geq 0$ and $-x^3$ for $x Statement-$4$: False. If $f'(c) = 0$,the inverse function $f^{-1}$ is not differentiable at $f(c)$. For example,$f(x) = x^3$ at $x=0$ is differentiable,but $f^{-1}(x) = x^{1/3}$ is not differentiable at $x=0$.

Column $I$	Column $II$
$A$. $x\|x\|$	$I$. Strictly increasing and continuous in $(-1,1)$
$B$. $\sqrt{\|x\|}$	$II$. Continuous but not differentiable in $(-1,1)$
$C$. $x+[x]$	$III$. Differentiable in $(-1,1)$
$D$. $\|x-1\|+\|x+1\|+\|x\|$	$IV$. Differentiable in $(-1,0) \cup (0,1)$
	$V$. Strictly increasing and not differentiable in $(-1,1)$

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