Line 26: Line 26:
 
and that this limit is <math> L \, </math>.  
 
and that this limit is <math> L \, </math>.  
  
Indeed, let us select <math> \varepsilon >0 </math>. Since (*) is true, then   
+
Indeed, let us select <math> \varepsilon >0 \ </math>. Since (*) is true, then   
<math>\exists \delta(\varepsilon)>0 </math> such that  
+
<math>\exists \delta(\varepsilon)>0 \,</math> such that  
 
<math> 0 < |z-c| < \delta \, </math> implies <math> |f(z)-L|< \varepsilon  </math>.  
 
<math> 0 < |z-c| < \delta \, </math> implies <math> |f(z)-L|< \varepsilon  </math>.  
  
Consider <math> |h(x)-L| \, </math> when <math>x\to 0 </math>.
+
Consider <math> |h(x)-L| \, </math> when <math>x\to 0 \, </math>.
Notice that if <math> |x-0|<\delta </math>. If <math> z=x+c </math> then  
+
Notice that if <math> |x-0|<\delta \, </math>. If <math> z=x+c \, </math> then  
  
 
<math>  
 
<math>  
|x-0|=|(x+c) - c|= |z-c|<\delta  
+
|x-0|=|(x+c) - c|= |z-c|<\delta \,
 
</math>
 
</math>
  
Line 50: Line 50:
  
 
In other words, <math> |h(x)-L|<\varepsilon </math>
 
In other words, <math> |h(x)-L|<\varepsilon </math>
as long as <math> |x-0|<\delta </math>. Because <math> \varepsilon>0 </math> was  
+
as long as <math> |x-0|<\delta\, </math>. Because <math> \varepsilon>0 </math> was  
 
arbitrary, we conclude that  
 
arbitrary, we conclude that  
  

Revision as of 09:25, 7 April 2010

To ask a new question, add a line and type in your question. You can use LaTeX to type math. Here is a link to a short LaTeX tutorial.

To answer a question, open the page for editing and start typing below the question...

go back to the Discussion Page


Could someone formulate 4.1.4? It's easy but I'm not sure my answer is correct. Thanks


prof. Alekseenko: In problem 4 we need to prove the "if and only if" statement. It has to parts. The first part is that

if $ \lim_{x\to c} f(x) = L $ then $ \lim_{x\to 0} f(x+c) = L $.

The second part goes in the opposite direction. Namely, we need to prove that

if $ \lim_{x\to 0} f(x+c) = L $ then $ \lim_{x\to c} f(x) = L $.

Let me work out the first part and may be somebody can do the second. We assume that

(*) $ \lim_{z\to c} f(z) = L $

Notice that we used letter $ z\, $ instead of the variable $ x\, $. The reason for this will be clear soon. However, using a different letter to denote the variable is not a problem.

Let us show that $ h(x):=f(x+c)\, $ also has limit at $ x=0\, $ and that this limit is $ L \, $.

Indeed, let us select $ \varepsilon >0 \ $. Since (*) is true, then $ \exists \delta(\varepsilon)>0 \, $ such that $ 0 < |z-c| < \delta \, $ implies $ |f(z)-L|< \varepsilon $.

Consider $ |h(x)-L| \, $ when $ x\to 0 \, $. Notice that if $ |x-0|<\delta \, $. If $ z=x+c \, $ then

$ |x-0|=|(x+c) - c|= |z-c|<\delta \, $

Then, of course,

$ |f(z)-L|<\varepsilon $

However, $ z=x+c \, $, therefore,

$ |f(x+c)-L|=|h(x)-L|<\varepsilon $

In other words, $ |h(x)-L|<\varepsilon $ as long as $ |x-0|<\delta\, $. Because $ \varepsilon>0 $ was arbitrary, we conclude that

(**) $ \lim_{x\to 0} h(x) = \lim_{x\to 0} f(x+c) = L $


Alumni Liaison

Ph.D. 2007, working on developing cool imaging technologies for digital cameras, camera phones, and video surveillance cameras.

Buyue Zhang