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Limit of a f(x,y) function

Posted 10 years ago


Firstly: Why doesn't this work:

In[88]:= f[x_, y_] = (1/(4*Pi))*Log[(x - 20)^2 + y^2]

Out[88]= Log[(-20 + x)^2]/(4 [Pi])

Secondly: How do I calculate the Limit of a function with two varibales. For example x->20 and y->0

Thirdly, a bit off topic question. Is it really necessary to limit myself to numerical data? For example, instead of number 20 in my expression for f(x,y) I would like to have a constant a. And than calculate Limit x->a and y->0 and also plot the function. Is that possible?

Thank you!

POSTED BY: Mitja Jan?i?
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I think you are asking why your expression for f[x,y] returns an immediate result. This is because you used Set (=) rather than SetDelayed (:=).

So you want

In[1]:= f[x_, y_] := (1/(4*Pi))*Log[(x - 20)^2 + y^2]

For your question about limits, you need to take the limit of the limit. Remember that limits do not necessarily commute, depending on the nature of the function at the point in question. So, one example you may execute is, in your particular example,

In[2]:= Limit[Limit[f[x, y], x -> 20], y -> 0]

Out[2]= -\[Infinity]

Which of course is not unexpected ;-)

As for your off topic question, you don't have to limit yourself to numerical data. However be aware that by using a symbolic value for the limiting value of your parameter you may not capture behaviors in particular cases and that you need to analyze the function to see if there are any issues for particular values of that parameter.

In[3]:= Limit[Limit[f[x, y], x -> a], y -> 0]

Out[3]= Log[(-20 + a)^2]/(4 \[Pi])
POSTED BY: David Reiss

Thanks for your answers, the first two work perfectly, about the third one:

Looks like there was a misunderstanding. Let's say that my function is f(x):=(x-a)^2 where a is an arbitrary constant. Now I want to plot f(x). Is that possible?

POSTED BY: Mitja Jan?i?

Well of course you cannot plot (x-a)^2 directly without specifying a value for a since it is not numerical with an arbitrary value of a. You can plot a two-dimensional plot varying both x and a line this:

Plot3D[(x - a)^2, {x, -2, 2}, {a, -1, 1}]

Or you could look at how a plot of (x-a)^2 varies as you change a dynamically using Manipulate, for example:

Manipulate[Plot[(x - a)^2, {x, -2, 2}], {a, -1, 1}]

And, of course, there are many other possibilities...

POSTED BY: David Reiss

In addition to David Reiss' excellent analysis of the issues I will note that, prior to In[88], there was almost certainly something like y=0 executed.

POSTED BY: Daniel Lichtblau

Right! I should never answer these questions before my morning coffee...

POSTED BY: David Reiss
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