Quiz:Limit: Difference between revisions

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Definition for finite limit for finite function of one variable

Two-sided limit

Left hand limit and right hand limit

Definition of finite limit for function of one variable in terms of a game

In the usual $\varepsilon -\delta$ definition of limit for a given limit $\lim _{x\to c}f(x)=L$ , if a given value $\delta >0$ works for a given value $\varepsilon >0$ , then which of the following is true?

	Every smaller positive value of $\delta$ works for the same $\varepsilon$ . Also, the given value of $\delta$ works for every smaller positive value of $\varepsilon$ .
	Every smaller positive value of $\delta$ works for the same $\varepsilon$ . Also, the given value of $\delta$ works for every larger value of $\varepsilon$ .
	Every larger value of $\delta$ works for the same $\varepsilon$ . Also, the given value of $\delta$ works for every smaller positive value of $\varepsilon$ .
	Every larger value of $\delta$ works for the same $\varepsilon$ . Also, the given value of $\delta$ works for every larger value of $\varepsilon$ .
	None of the above statements need always be true.

@@ Line 54: / Line 54: @@
 - Every smaller positive value of <math>\delta</math> works for the same <math>\varepsilon</math>. Also, the given value of <math>\delta</math> works for every smaller positive value of <math>\varepsilon</math>.
 + Every smaller positive value of <math>\delta</math> works for the same <math>\varepsilon</math>. Also, the given value of <math>\delta</math> works for every larger value of <math>\varepsilon</math>.
+|| See from the definition or the game description.
 - Every larger value of <math>\delta</math> works for the same <math>\varepsilon</math>. Also, the given value of $\delta$ works for every smaller positive value of <math>\varepsilon</math>.
 - Every larger value of <math>\delta</math> works for the same <math>\varepsilon</math>. Also, the given value of <math>\delta</math> works for every larger value of <math>\varepsilon</math>.

	For every $\alpha >0$ , there exists $\beta >0$ such that if $0<\|x-c\|<\alpha$ , then $\|f(x)-L\|<\beta$ .
	There exists $\alpha >0$ such that for every $\beta >0$ , and $0<\|x-c\|<\alpha$ , we have $\|f(x)-L\|<\beta$ .
	For every $\alpha >0$ , there exists $\beta >0$ such that if $0<\|x-c\|<\beta$ , then $\|f(x)-L\|<\alpha$ .
	There exists $\alpha >0$ such that for every $\beta >0$ and $0<\|x-c\|<\beta$ , we have $\|f(x)-L\|<\alpha$ .
	None of the above

	$f(c)$ exists and is equal to $L$ .
	$f(c)$ does not exist.
	$f(c)$ may or may not exist, but if it exists, it must equal $L$ .
	$f(c)$ must exist, but it need not be equal to $L$ .
	$f(c)$ may or may not exist, and even if it does exist, it may or may not be equal to $L$ .

	For every $\varepsilon >0$ , there exists $\delta >0$ such that for all $x\in \mathbb {R}$ satisfying $0<c-x<\delta$ , we have $0<L-f(x)<\varepsilon$ .
	For every $\varepsilon >0$ , there exists $\delta >0$ such that for all $x\in \mathbb {R}$ satisfying $0<x-c<\delta$ , we have $0<f(x)-L<\varepsilon$ .
	For every $\varepsilon >0$ , there exists $\delta >0$ such that for all $x\in \mathbb {R}$ satisfying $0<x-c<\delta$ , we have $0<L-f(x)<\varepsilon$ .
	For every $\varepsilon >0$ , there exists $\delta >0$ such that for all $x\in \mathbb {R}$ satisfying $0<\|x-c\|<\delta$ , we have $0<L-f(x)<\varepsilon$ .
	For every $\varepsilon >0$ , there exists $\delta >0$ such that for all $x\in \mathbb {R}$ satisfying $0<c-x<\delta$ , we have $\|f(x)-L\|<\varepsilon$ .

	The left hand limit at the left endpoint and the right hand limit at the right endpoint.
	The left hand limit at the right endpoint and the right hand limit at the left endpoint.
	The left hand limit and the right hand limit at any interior point.
	The two-sided limit at any interior point.
	The left hand limit at any point other than the left endpoint and the right hand limit at any point other than the right endpoint.