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== Continuous functions  ==
 
== Continuous functions  ==
Let's consider the the following three functions along with their graphs (in blue). The red dots in each correspond to <math>x=0</math>, e.g. for <math>f</math>, the red dot is the point <math>(0,f(0))=(0,0)</math>.
+
Let's consider the the following three functions along with their graphs (in blue). The red dots in each correspond to <math>x=0</math>, e.g. for <math>f</math>, the red dot is the point <math>(0,f(0))=(0,0)</math>. Ignore the red dashed lines for now; we will explain them later.
  
 
:<math>\displaystyle f(x)=x^3</math>
 
:<math>\displaystyle f(x)=x^3</math>
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Let's make these observations more precise. First, we will try to estimate <math>f(0)</math> with error at most <math>0.25</math>, say. In the graph of <math>f</math>, we have marked off a band of width <math>0.5</math> about <math>f(0)</math>. So, any point in the band will provide a good approximation here. As a first try, we might think that if <math>x</math> is close enough to <math>0</math>, then <math>f(x)</math> will be a good estimate of <math>f(0)</math>. Indeed, we see from the graph that for ''any'' <math>x</math> in the interval <math>(-\sqrt[3]{0.25},\sqrt[3]{0.25})</math>, <math>f(x)</math> lies in the band (or if we wish to be more pedantic, we would say that <math>(x,f(x))</math> lies in the band). So, "close enough to <math>0</math>" here means in the interval <math>(-\sqrt[3]{0.25},\sqrt[3]{0.25})</math>; note that ''any'' point which is close enough to <math>0</math> provides a good approximation of <math>f(0)</math>.
 
Let's make these observations more precise. First, we will try to estimate <math>f(0)</math> with error at most <math>0.25</math>, say. In the graph of <math>f</math>, we have marked off a band of width <math>0.5</math> about <math>f(0)</math>. So, any point in the band will provide a good approximation here. As a first try, we might think that if <math>x</math> is close enough to <math>0</math>, then <math>f(x)</math> will be a good estimate of <math>f(0)</math>. Indeed, we see from the graph that for ''any'' <math>x</math> in the interval <math>(-\sqrt[3]{0.25},\sqrt[3]{0.25})</math>, <math>f(x)</math> lies in the band (or if we wish to be more pedantic, we would say that <math>(x,f(x))</math> lies in the band). So, "close enough to <math>0</math>" here means in the interval <math>(-\sqrt[3]{0.25},\sqrt[3]{0.25})</math>; note that ''any'' point which is close enough to <math>0</math> provides a good approximation of <math>f(0)</math>.
  
Can we do the same for <math>g</math>?
+
Can we do the same for <math>g</math>? That is, if <math>x</math> is close enough to <math>0</math>, then will <math>g(x)</math> be a good estimate of <math>g(0)</math>? Well, we see from the graph that <math>g(0.25)</math> provides a good approximation to <math>g(0)</math>. But if <math>0.25</math> is close enough to <math>0</math>, then certainly <math>-0.25</math> should be too; however, the graph shows that <math>g(-0.25)</math> is ''not'' a good estimate of <math>g(0)</math>.
  
 
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Revision as of 14:20, 11 May 2014


Limits of Functions

by: Michael Yeh, proud Member of the Math Squad.

 keyword: tutorial, limit, function, sequence 

INTRODUCTION

Provided here is a brief introduction to the concept of "limit," which features prominently in calculus. We first discuss the limit of a function at a point; to help motivate the definition, we first consider continuous functions. Unless otherwise mentioned, all functions here will have domain and range $ \mathbb{R} $, the real numbers. Words such as "all," "every," "each," "some," and "there are" are quite important here; read carefully!

Continuous functions

Let's consider the the following three functions along with their graphs (in blue). The red dots in each correspond to $ x=0 $, e.g. for $ f $, the red dot is the point $ (0,f(0))=(0,0) $. Ignore the red dashed lines for now; we will explain them later.

$ \displaystyle f(x)=x^3 $

Limits of functions f.png

$ g(x)=\begin{cases}-x^2-\frac{1}{2} &\text{if}~x<0\\ x^2+\frac{1}{2} &\text{if}~x\geq 0\end{cases} $

Limits of functions g.png

$ h(x)=\begin{cases} \sin\left(\frac{1}{x}\right) &\text{if}~x\neq 0\\ 0 &\text{if}~x=0\end{cases} $

Limits of functions h.png

We can see from the graphs that $ f $ is "continuous" at $ 0 $, and that $ g $ and $ h $ are "discontinuous" at 0. But, what exactly do we mean? Intuitively, $ f $ seems to be continuous at $ 0 $ because $ f(x) $ is close to $ f(0) $ whenever $ x $ is close to $ 0 $. On the other hand, $ g $ appears to be discontinuous at $ 0 $ because there are points $ x $ which are close to $ 0 $ but such that $ g(x) $ is far away from $ g(0) $. The same observation applies to $ h $.

Let's make these observations more precise. First, we will try to estimate $ f(0) $ with error at most $ 0.25 $, say. In the graph of $ f $, we have marked off a band of width $ 0.5 $ about $ f(0) $. So, any point in the band will provide a good approximation here. As a first try, we might think that if $ x $ is close enough to $ 0 $, then $ f(x) $ will be a good estimate of $ f(0) $. Indeed, we see from the graph that for any $ x $ in the interval $ (-\sqrt[3]{0.25},\sqrt[3]{0.25}) $, $ f(x) $ lies in the band (or if we wish to be more pedantic, we would say that $ (x,f(x)) $ lies in the band). So, "close enough to $ 0 $" here means in the interval $ (-\sqrt[3]{0.25},\sqrt[3]{0.25}) $; note that any point which is close enough to $ 0 $ provides a good approximation of $ f(0) $.

Can we do the same for $ g $? That is, if $ x $ is close enough to $ 0 $, then will $ g(x) $ be a good estimate of $ g(0) $? Well, we see from the graph that $ g(0.25) $ provides a good approximation to $ g(0) $. But if $ 0.25 $ is close enough to $ 0 $, then certainly $ -0.25 $ should be too; however, the graph shows that $ g(-0.25) $ is not a good estimate of $ g(0) $.


TOPIC 3

Lorem Ipsum [1] is simply dummy text of the printing and typesetting industry. Lorem Ipsum has been the industry's standard dummy text ever since the 1500s, when an unknown printer took a galley of type and scrambled it to make a type specimen book. It has survived not only five centuries, but also the leap into electronic typesetting, remaining essentially unchanged. It was popularised in the 1960s with the release of Letraset sheets containing Lorem Ipsum passages, and more recently with desktop publishing software like Aldus PageMaker including versions of Lorem Ipsum.


TOPIC 2

Lorem Ipsum [1] is simply dummy text of the printing and typesetting industry. Lorem Ipsum has been the industry's standard dummy text ever since the 1500s, when an unknown printer took a galley of type and scrambled it to make a type specimen book. It has survived not only five centuries, but also the leap into electronic typesetting, remaining essentially unchanged. It was popularised in the 1960s with the release of Letraset sheets containing Lorem Ipsum passages, and more recently with desktop publishing software like Aldus PageMaker including versions of Lorem Ipsum.


REFERENCES

[1] "Loream Ipsum" <http://www.lipsum.com/>.


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