Difference between revisions of "Limit"
(New page: A limit is the behavior of ==Intuitive Definition== We know that a function assigns values to outputs with respect to inputs. As given inputs get closer and closer to a specific value, ...) 

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−  +  {{HelperPage1=Sierpinski's Triangle2=Differentiability3=Harmonic Warping4=Taylor Series}}  
−  +  A limit is the behavior of a function as its inputs approach arbitrarily close to a given value.  
−  
−  +  Limits are written in the following form:  
−  +  <math> \lim_{x \to a}f(x) = L </math>  
−  +  The expression above states that when <math>x\,</math> approaches arbitrarily close to <math>a\,</math>, the function <math>f(x)\,</math> becomes arbitrarily close to the value <math>L\,</math>, which is called the ''limit''.  
−  <math>  
−  +  ==Informal Definition==  
+  We can consider the idea of limits using a simple continuous function, <math> f(x)=x^2 \,</math>.  
−  +  We want to examine the limit of x= 0 for this function. Since this graph is a simple unbroken line, we realize that  
−  <math>  +  <math> \lim_{x \to 0}f(x) = 0 </math> 
+  Indeed for this function, <math> \lim_{x \to a}f(x) = f(a) \,</math>. But this is a special case, in the majority of limits cannot be solved in this manner.  
+  For a very different example; given  
−  The limit of <math>f(x)\,</math>  +  <math>f(x)=\left\{\begin{matrix} {x}^2, & \mbox{if }x\ne 0 \\ \\ 1, & \mbox{if }x=0. \end{matrix}\right.</math> (as pictured below) 
+  
+  [[Image:SimpleParabola.png400px]]  
+  
+  The limit of <math>f(x)\,</math> because ''x'' approaches 0 is 0 (just as in <math>f(x)\,</math>), but <math>\lim_{x\to 0}f(x)\neq f(0)</math>; <math>f(x)</math> is not continuous at <math>x = 0</math> (as shown on the right).  
+  
+  In other cases a limit can fail to exist, as approaching the limit from different sides produces conflicting values.  
+  
+  Here we look at one such case:  
+  
+  [[Image:EvaluatingLimitsDiff1.PNG350px]]  
+  
+  <math>f(x)=\left\{\begin{matrix} {x}^2, & \mbox{if }x\ne 0 \\ \\ 1, & \mbox{if }x=0. \end{matrix}\right.</math> (as pictured above)  
+  
+  ==Rigorous Definition of Limit==  
+  This definition is more appropriate for 2nd year calculus students and higher.  
+  
+  {{hide1=The original statement <math>\lim_{x \to a}f(x) = L </math> now means that given any <math>\varepsilon > 0 </math>, a <math> \delta > 0 \,</math> exists such that if <math>0 < xa < \delta \,</math>, then <math>f(x)L< \varepsilon </math>.  
+  
+  Suppose the limit as x > a of f(x) = L. This means that if you give me any positive value for <math>\varepsilon</math>, no matter how small, I can reply with a value of <math>\delta</math> that guarantees that if a value for x is within <math>\delta</math> units of b, then f(x) will be within <math>\varepsilon</math> units of L.  
+  
+  For instance, suppose f(x) = 2x, given an <math>\varepsilon</math> on .1 and x=1, we can find a corresponding delta that satisfies the formal definition.  
+  
+  We know <math> \lim_{x \to 1}f(x) = 2 </math> and thus we have  
+  
+  <math>2x  2 < 0.1</math>  
+  
+  Solving for x we get  
+  
+  <math>x < 1.05</math>  
+  
+  and we can substitute in to find  
+  
+  <math>x  1 < .05</math>  
+  
+  We now get a <math>\delta = .05</math>.  
+  
+  As this example show, if you are faced with a very small <math>\varepsilon</math>, you may be required to respond with a very small <math>\delta</math>, but no matter how small epsilon is, there is *some* value of <math>\delta</math> that will work.  
+  
+  This definition is more useful in higher mathematics work because it eliminates the phrases "arbitrarily small" and "sufficiently small" from our intuitive definition. These phrases cannot be readily defined in mathematics language.  
+  
+  [[Image:Limit.pngrightthumb300px]]  
+  
+  
+  We use the definition as follows to prove for the function <math>f(x) = 3x1 \,</math>, <math>\lim_{x \to 2}f(x) = 5 </math>  
+  
+  Given any <math>\delta\,</math>, we choose a <math>\varepsilon\,</math> such that <math>\delta \leq \varepsilon/3</math>  
+  
+  If <math>x2<\delta\,</math>, we can derive <math>f(x)5<3\delta\,</math>.  
+  
+  <math>3x2<3\delta\,</math>  
+  
+  <math>3x6<3\delta\,</math>  
+  
+  <math>f(x)5<3\delta\,</math>  
+  
+  <math>3\delta \leq 3*\varepsilon/3 = \varepsilon\,</math>  
+  
+  Thus <math>\lim_{x \to 2}f(x) = 5 </math>  
+  }}  
+  
+  ==Properties of Limits==  
+  {{hide1=The limit of a sum of two functions is equal to the sum of the limits of the functions.  
+  
+  <math> \lim_{x \to a} (f(x)+g(x)) = \lim_{x \to a} f(x) + \lim_{x \to a} g(x) </math>  
+  
+  The limit of a difference between two functions is equal to the difference between the limits of the functions.  
+  
+  <math> \lim_{x \to a} (f(x)g(x)) = \lim_{x \to a} f(x)  \lim_{x \to a} g(x) </math>  
+  
+  The limit of a product of two functions is equal to the product of the limits of the functions.  
+  
+  <math> \lim_{x \to a} (f(x)*g(x)) = \lim_{x \to a} f(x) * \lim_{x \to a} g(x) </math>  
+  
+  The limit of a quotient of two functions is equal to the quotient of the limits of the functions (assuming a nonzero denominator).  
+  
+  <math> \lim_{x \to a} (\frac{f(x)}{g(x)}) = \frac{\lim_{x \to a} f(x)}{\lim_{x \to a} g(x)} </math>  
+  }}  
+  
+  ==Ideas for the Future==  
+   an interactive diagram in which changing the size of epsilon shows a corresponding delta, or something.  
+  
+  
+  
+  ==For More Information==  
+  
+  More examples  http://archives.math.utk.edu/visual.calculus/1/definition.6/index.html  
+  http://mathworld.wolfram.com/Limit.html  
+  Even more mathematical description  
Latest revision as of 12:34, 28 June 2012
This is a Helper Page for:


Sierpinski's Triangle 
Differentiability 
Harmonic Warping 
Taylor Series 
A limit is the behavior of a function as its inputs approach arbitrarily close to a given value.
Limits are written in the following form:
The expression above states that when approaches arbitrarily close to , the function becomes arbitrarily close to the value , which is called the limit.
Contents
Informal Definition
We can consider the idea of limits using a simple continuous function, .
We want to examine the limit of x= 0 for this function. Since this graph is a simple unbroken line, we realize that
Indeed for this function, . But this is a special case, in the majority of limits cannot be solved in this manner.
For a very different example; given
(as pictured below)
The limit of because x approaches 0 is 0 (just as in ), but ; is not continuous at (as shown on the right).
In other cases a limit can fail to exist, as approaching the limit from different sides produces conflicting values.
Here we look at one such case:
(as pictured above)
Rigorous Definition of Limit
This definition is more appropriate for 2nd year calculus students and higher.
Properties of Limits
Ideas for the Future
 an interactive diagram in which changing the size of epsilon shows a corresponding delta, or something.
For More Information
More examples  http://archives.math.utk.edu/visual.calculus/1/definition.6/index.html
http://mathworld.wolfram.com/Limit.html
Even more mathematical description 