Office_Shredder said:this is just f(x*g(x)). What do you know about x*g(x) if g is continuous?
snipez90 said:Also, f is continuous, so basically you have a lot of continuous functions involved in different operations. If you've already proved that f(g(x)) is continuous at a point a if g(x) is continuous at a and f is continuous at g(a), then you could save yourself a lot of trouble.
kathrynag said:lx-al<[tex]\delta[/tex]
lg(x)-g(a)l<[tex]\epsilon[/tex]
kathrynag said:f continuous at g(a)
lx-g(a)l<[tex]\delta[/tex]
lf(x)-f(g(a)l<[tex]\epsilon[/tex]
Should it be changed to a f or are you talking about a change from x to y?snipez90 said:A few comments to point you in the right direction. We want |x-a|<[tex]\delta[/tex] to imply that lf(g(x))-f(g(a)l<[tex]\epsilon[/tex].
This is fine, except one variable should be changed. We want to somehow connect this to our second fact, which is
Ok so there is d' such that lg(x)-g(a)l<[tex]\delta[/tex]. then |f(g(x))-f(g(a)l<[tex]\epsilon[/tex]snipez90 said:Ok, obviously we want to be careful about using the same variables. Since x is used to represent elements in the domain of g, let's use y to represent the elements in the domain f. Making this change, we have
f continuous at g(a)
ly-g(a)l<[tex]\delta[/tex]
lf(y)-f(g(a)l<[tex]\epsilon[/tex]
Now note that if we replace y with g(x), which is certainly allowed, we are very close to what we need. Namely, lg(x)-g(a)l<[tex]\delta[/tex] implies that |f(g(x))-f(g(a)l<[tex]\epsilon[/tex]. But we also know that we reserved the variable delta for lx-al<[tex]\delta[/tex]. So we need to change the delta in lg(x)-g(a)l<[tex]\delta[/tex] to some other variable.
In fact, we can choose any variable that is greater than 0 (Why?). So let's choose d' (delta prime). Now how can we use the fact that d' > 0 to connect our delta in |x-a| < [tex]\delta[/tex] to our epsilon in |f(g(x))-f(g(a)l<[tex]\epsilon[/tex]?
The continuity of x^x=e^xlnx can be expressed as the limit of x approaching a particular value, where the function remains continuous. In this case, the limit of x^x as x approaches 1 is equal to the limit of e^xlnx as x approaches 1, which is 1.
The continuity of x^x=e^xlnx can be determined by evaluating the limit of the function as x approaches the particular value in question. If the limit exists and is equal to the value of the function at that point, then the function is continuous at that point.
Yes, x^x=e^xlnx can be continuous at more than one point. In fact, it is continuous for all values of x except for x=0. This can be seen by evaluating the limit of the function as x approaches 0 from the left and right sides, which both equal 1.
The continuity of x^x=e^xlnx is dependent on the continuity of its individual components, x^x and e^xlnx. Both of these components are continuous for all values of x, except for when x=0. Therefore, the overall function is also continuous for all values of x except for x=0.
Understanding the continuity of x^x=e^xlnx can be useful in various mathematical and scientific applications. For example, it can be used in optimization problems and in analyzing the behavior of functions near critical points. It can also be applied in real-world scenarios, such as modeling population growth or compound interest.