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Limits At Infinity, Part II | Calculus - Mathematics PDF Download

In the previous section we looked at limits at infinity of polynomials and/or rational expression involving polynomials. In this section we want to take a look at some other types of functions that often show up in limits at infinity. The functions we’ll be looking at here are exponentials, natural logarithms and inverse tangents.

Let’s start by taking a look at a some of very basic examples involving exponential functions.

Example 1 Evaluate each of the following limits.

Limits At Infinity, Part II | Calculus - Mathematics

There are really just restatements of facts given in the basic exponential section of the review so we’ll leave it to you to go back and verify these.

Limits At Infinity, Part II | Calculus - Mathematics

The main point of this example was to point out that if the exponent of an exponential goes to infinity in the limit then the exponential function will also go to infinity in the limit. Likewise, if the exponent goes to minus infinity in the limit then the exponential will go to zero in the limit.

Note as well, that in the last section the value of the limit did not depend on whether we went to plus or minus infinity. We’ve already seen in the above example that changing the sign on the infinity can change the answer so do not get locked into any assumptions you may have made from the work in the last section!

Here’s a quick set of examples to illustrate these ideas.

Example 2 Evaluate each of the following limits.

Limits At Infinity, Part II | Calculus - Mathematics

Solution:

Limits At Infinity, Part II | Calculus - Mathematics
In this part what we need to note (using Fact 2 above) is that in the limit the exponent of the exponential does the following,

Limits At Infinity, Part II | Calculus - Mathematics

So, the exponent goes to minus infinity in the limit and so the exponential must go to zero in the limit using the ideas from the previous set of examples. So, the answer here is,

Limits At Infinity, Part II | Calculus - Mathematics

Limits At Infinity, Part II | Calculus - Mathematics
Here let’s first note that,

Limits At Infinity, Part II | Calculus - Mathematics

The exponent goes to infinity in the limit and so the exponential will also need to go to infinity in the limit. Or,

Limits At Infinity, Part II | Calculus - Mathematics

Limits At Infinity, Part II | Calculus - Mathematics
On the surface this part doesn’t appear to belong in this section since it isn’t a limit at infinity. However, it does fit into the ideas we’re examining in this set of examples.

So, let’s first note that using the idea from the previous section we have,

Limits At Infinity, Part II | Calculus - Mathematics

Remember that in order to do this limit here we do need to do a right-hand limit.
So, the exponent goes to infinity in the limit and so the exponential must also go to infinity.
Here’s the answer to this part.

Limits At Infinity, Part II | Calculus - Mathematics

Let’s work some more complicated examples involving exponentials. In the following set of examples it won’t be that the exponents are more complicated, but instead that there will be more than one exponential function to deal with.

Example 3 Evaluate each of the following limits.

Limits At Infinity, Part II | Calculus - Mathematics

Solution:
So, the only difference between these two limits is the fact that in the first we’re taking the limit as we go to plus infinity and in the second we’re going to minus infinity. To this point we’ve been able to “reuse” work from the first limit in the at least a portion of the second limit. With exponentials that will often not be the case, we’re going to treat each of these as separate problems.

Limits At Infinity, Part II | Calculus - Mathematics

Let’s start by just taking the limit of each of the pieces and see what we get.

Limits At Infinity, Part II | Calculus - Mathematics

The last two terms aren’t any problem (they will be in the next part however; do you see that?). The first three are a problem however as they present us with another indeterminate form.

When dealing with polynomials we factored out the term with the largest exponent in it. Let’s do the same thing here. However, we now have to deal with both positive and negative exponents and just what do we mean by the “largest” exponent. When dealing with these here we look at the terms that are causing the problems and ask “what is the largest exponent in those terms?”. So, since only the first three terms are causing us problems (i.e. they all evaluate to an infinity in the limit) we’ll look only at those.

So, since 10x is the largest of the three exponents there we’ll “factor” an

e10x

out of the whole thing. Just as with polynomials we do the factoring by, in essence, dividing each term by

e10x

and remembering that to simply the division all we need to do is subtract the exponents. For example, let’s just take a look at the last term,

Limits At Infinity, Part II | Calculus - Mathematics

Doing factoring on all terms then gives,

Limits At Infinity, Part II | Calculus - Mathematics

Notice that in doing this factoring all the remaining exponentials now have negative exponents and we know that for this limit (i.e. going out to positive infinity) these will all be zero in the limit and so will no longer cause problems.

We can now take the limit of the two factors. The first is clearly infinity and the second is clearly a finite number (one in this case) and so the Facts from the Infinite Limits section gives us the following limit,

Limits At Infinity, Part II | Calculus - Mathematics

To simplify the work here a little all we really needed to do was factor the

e10x

out of the “problem” terms (the first three in this case) as follows,

Limits At Infinity, Part II | Calculus - Mathematics

We factored the

e10x

out of all terms for the practice of doing the factoring and to avoid any issues with having the extra terms at the end. Note as well that while we wrote (∞)(1) for the limit of the first term we are really using the Facts from the Infinite Limit section to do that limit.

Limits At Infinity, Part II | Calculus - Mathematics
Let’s start this one off in the same manner as the first part. Let’s take the limit of each of the pieces. This time note that because our limit is going to negative infinity the first three exponentials will in fact go to zero (because their exponents go to minus infinity in the limit). The final two exponentials will go to infinity in the limit (because their exponents go to plus infinity in the limit).

Taking the limits gives,

Limits At Infinity, Part II | Calculus - Mathematics

So, the last two terms are the problem here as they once again leave us with an indeterminate form. As with the first example we’re going to factor out the “largest” exponent in the last two terms. This time however, “largest” doesn’t refer to the bigger of the two numbers (-2 is bigger than -15). Instead we’re going to use “largest” to refer to the exponent that is farther away from zero. Using this definition of “largest” means that we’re going to factor an

e-15out.

Again, remember that to factor this out all we really are doing is dividing each term by

e-15x 

and then subtracting exponents. Here’s the work for the first term as an example,

Limits At Infinity, Part II | Calculus - Mathematics

As with the first part we can either factor it out of only the “problem” terms (i.e. the last two terms), or all the terms. For the practice we’ll factor it out of all the terms. Here is the factoring work for this limit,

Limits At Infinity, Part II | Calculus - Mathematics

Finally, after taking the limit of the two terms (the first is infinity and the second is a negative, finite number) and recalling the Facts from the Infinite Limit section we see that the limit is,

Limits At Infinity, Part II | Calculus - Mathematics

So, when dealing with sums and/or differences of exponential functions we look for the exponential with the “largest” exponent and remember here that “largest” means the exponent farthest from zero. Also remember that if we’re looking at a limit at plus infinity only the exponentials with positive exponents are going to cause problems so those are the only terms we look at in determining the largest exponent. Likewise, if we are looking at a limit at minus infinity then only exponentials with negative exponents are going to cause problems and so only those are looked at in determining the largest exponent.

Finally, as you might have been able to guess from the previous example when dealing with a sum and/or difference of exponentials all we need to do is look at the largest exponent to determine the behavior of the whole expression. Again, remembering that if the limit is at plus infinity we only look at exponentials with positive exponents and if we’re looking at a limit at minus infinity we only look at exponentials with negative exponents.

Let’s next take a look at some rational functions involving exponentials.

Example 4 Evaluate each of the following limits.

Limits At Infinity, Part II | Calculus - Mathematics

Solution:
As with the previous example, the only difference between the first two parts is that one of the limits is going to plus infinity and the other is going to minus infinity and just as with the previous example each will need to be worked differently.

Limits At Infinity, Part II | Calculus - Mathematics
The basic concept involved in working this problem is the same as with rational expressions in the previous section. We look at the denominator and determine the exponential function with the “largest” exponent which we will then factor out from both numerator and denominator. We will use the same reasoning as we did with the previous example to determine the “largest” exponent. In the case since we are looking at a limit at plus infinity we only look at exponentials with positive exponents.

So, we’ll factor an

e4x

out of both then numerator and denominator. Once that is done we can cancel the

e4x

and then take the limit of the remaining terms. Here is the work for this limit,

Limits At Infinity, Part II | Calculus - Mathematics

Limits At Infinity, Part II | Calculus - Mathematics
In this case we’re going to minus infinity in the limit and so we’ll look at exponentials in the denominator with negative exponents in determining the “largest” exponent. There’s only one however in this problem so that is what we’ll use.

Again, remember to only look at the denominator. Do NOT use the exponential from the numerator, even though that one is “larger” than the exponential in the denominator. We always look only at the denominator when determining what term to factor out regardless of what is going on in the numerator.

Here is the work for this part.

Limits At Infinity, Part II | Calculus - Mathematics

Limits At Infinity, Part II | Calculus - Mathematics
We’ll do the work on this part with much less detail.

Limits At Infinity, Part II | Calculus - Mathematics

Next, let’s take a quick look at some basic limits involving logarithms.

Example 5 Evaluate each of the following limits.

Limits At Infinity, Part II | Calculus - Mathematics

Solution:

As with the last example I’ll leave it to you to verify these restatements from the basic logarithm section.

Limits At Infinity, Part II | Calculus - Mathematics

Note that we had to do a right-handed limit for the first one since we can’t plug negative x’s into a logarithm. This means that the normal limit won’t exist since we must look at x’s from both sides of the point in question and x’s to the left of zero are negative.

From the previous example we can see that if the argument of a log (the stuff we’re taking the log of) goes to zero from the right (i.e. always positive) then the log goes to negative infinity in the limit while if the argument goes to infinity then the log also goes to infinity in the limit.

Note as well that we can’t look at a limit of a logarithm as x approaches minus infinity since we can’t plug negative numbers into the logarithm.

Let’s take a quick look at some logarithm examples.

Example 6 Evaluate each of the following limits.

Limits At Infinity, Part II | Calculus - Mathematics

Solution:

Limits At Infinity, Part II | Calculus - Mathematics
So, let’s first look to see what the argument of the log is doing,

Limits At Infinity, Part II | Calculus - Mathematics

The argument of the log is going to infinity and so the log must also be going to infinity in the limit. The answer to this part is then,

Limits At Infinity, Part II | Calculus - Mathematics

Limits At Infinity, Part II | Calculus - Mathematics

First, note that the limit going to negative infinity here isn’t a violation (necessarily) of the fact that we can’t plug negative numbers into the logarithm. The real issue is whether or not the argument of the log will be negative or not.

Using the techniques from earlier in this section we can see that,

Limits At Infinity, Part II | Calculus - Mathematics

and let’s also note that for negative numbers (which we can assume we’ve got since we’re going to minus infinity in the limit) the denominator will always be positive and so the quotient will also always be positive. Therefore, not only does the argument go to zero, it goes to zero from the right. This is exactly what we need to do this limit.

So, the answer here is,

Limits At Infinity, Part II | Calculus - Mathematics

As a final set of examples let’s take a look at some limits involving inverse tangents.

Example 7 Evaluate each of the following limits.

Limits At Infinity, Part II | Calculus - Mathematics

Solution:

The first two parts here are really just the basic limits involving inverse tangents and can easily be found by examining the following sketch of inverse tangents. The remaining two parts are more involved but as with the exponential and logarithm limits really just refer back to the first two parts as we’ll see.

Limits At Infinity, Part II | Calculus - Mathematics

Limits At Infinity, Part II | Calculus - Mathematics
As noted above all we really need to do here is look at the graph of the inverse tangent. Doing this shows us that we have the following value of the limit.

Limits At Infinity, Part II | Calculus - Mathematics

Limits At Infinity, Part II | Calculus - Mathematics
Again, not much to do here other than examine the graph of the inverse tangent.

Limits At Infinity, Part II | Calculus - Mathematics

Limits At Infinity, Part II | Calculus - Mathematics
Okay, in part (a) above we saw that if the argument of the inverse tangent function (the stuff inside the parenthesis) goes to plus infinity then we know the value of the limit. In this case (using the techniques from the previous section) we have,

Limits At Infinity, Part II | Calculus - Mathematics

So, this limit is,

Limits At Infinity, Part II | Calculus - Mathematics

Limits At Infinity, Part II | Calculus - Mathematics

Even though this limit is not a limit at infinity we’re still looking at the same basic idea here. We’ll use part (b) from above as a guide for this limit. We know from the Infinite Limits section that we have the following limit for the argument of this inverse tangent,

Limits At Infinity, Part II | Calculus - Mathematics

So, since the argument goes to minus infinity in the limit we know that this limit must be,

Limits At Infinity, Part II | Calculus - Mathematics

Practice problems: Limits At Infinity, Part II

For problems 1 – 6 evaluate (a)Limits At Infinity, Part II | Calculus - Mathematics1. For (x)=e8+2x−x3  evaluate each of the following limits.
Limits At Infinity, Part II | Calculus - Mathematics

Solution:
Limits At Infinity, Part II | Calculus - Mathematics
First notice that,

Limits At Infinity, Part II | Calculus - Mathematics
If you aren’t sure about this limit you should go back to the previous section and work some of the examples there to make sure that you can do these kinds of limits.

Now, recalling Example 1 from this section, we know that because the exponent goes to infinity in the limit the answer is,

Limits At Infinity, Part II | Calculus - Mathematics

Limits At Infinity, Part II | Calculus - Mathematics
First notice that,
Limits At Infinity, Part II | Calculus - Mathematics
If you aren’t sure about this limit you should go back to the previous section and work some of the examples there to make sure that you can do these kinds of limits.

Now, recalling Example 1 from this section, we know that because the exponent goes to negative infinity in the limit the answer is,

Limits At Infinity, Part II | Calculus - Mathematics

2. For Limits At Infinity, Part II | Calculus - Mathematics evaluate each of the following limits.

Limits At Infinity, Part II | Calculus - Mathematics

Solution:

First notice that,

Limits At Infinity, Part II | Calculus - Mathematics
If you aren’t sure about this limit you should go back to the previous section and work some of the examples there to make sure that you can do these kinds of limits.

Now, recalling Example 1 from this section, we know that because the exponent goes to negative infinity in the limit the answer is,

Limits At Infinity, Part II | Calculus - Mathematics

Limits At Infinity, Part II | Calculus - Mathematics

First notice that,

Limits At Infinity, Part II | Calculus - Mathematics

If you aren’t sure about this limit you should go back to the previous section and work some of the examples there to make sure that you can do these kinds of limits.

Now, recalling Example 1 from this section, we know that because the exponent goes to infinity in the limit the answer is,
Limits At Infinity, Part II | Calculus - Mathematics

3. for Limits At Infinity, Part II | Calculus - Mathematics evaluate each of the following limits.

Limits At Infinity, Part II | Calculus - Mathematics

Solution:

Limits At Infinity, Part II | Calculus - Mathematics
For this limit the exponentials with positive exponents will simply go to zero and there is only one exponential with a negative exponent (which will go to infinity) and so there isn’t much to do with this limit.

Limits At Infinity, Part II | Calculus - Mathematics

Limits At Infinity, Part II | Calculus - Mathematics
Here we have two exponents with positive exponents and so both will go to infinity in the limit. However, each term has opposite signs and so each term seems to be suggesting different answers for the limit.

In order to determine which “wins out” so to speak all we need to do is factor out the term with the largest exponent and then use basic limit properties.

Limits At Infinity, Part II | Calculus - Mathematics

4. For f(x)=3ex8e5xe10x  evaluate each of the following limits.

Limits At Infinity, Part II | Calculus - Mathematics

Solution:

Limits At Infinity, Part II | Calculus - Mathematics

Here we have two exponents with negative exponents and so both will go to infinity in the limit. However, each term has opposite signs and so each term seems to be suggesting different answers for the limit.

In order to determine which “wins out” so to speak all we need to do is factor out the term with the most negative exponent and then use basic limit properties.

Limits At Infinity, Part II | Calculus - Mathematics

Limits At Infinity, Part II | Calculus - Mathematics
For this limit the exponentials with negative exponents will simply go to zero and there is only one exponential with a positive exponent (which will go to infinity) and so there isn’t much to do with this limit.

Limits At Infinity, Part II | Calculus - Mathematics

5. For Limits At Infinity, Part II | Calculus - Mathematicsevaluate each of the following limits.

Limits At Infinity, Part II | Calculus - Mathematics

Solution:

Limits At Infinity, Part II | Calculus - Mathematics
The exponential with the negative exponent is the only term in the denominator going to infinity for this limit and so we’ll need to factor the exponential with the negative exponent in the denominator from both the numerator and denominator to evaluate this limit.

Limits At Infinity, Part II | Calculus - Mathematics

Limits At Infinity, Part II | Calculus - Mathematics
The exponential with the positive exponent is the only term in the denominator going to infinity for this limit and so we’ll need to factor the exponential with the positive exponent in the denominator from both the numerator and denominator to evaluate this limit.

Limits At Infinity, Part II | Calculus - Mathematics

6. For Limits At Infinity, Part II | Calculus - Mathematicsevaluate each of the following limits.

Limits At Infinity, Part II | Calculus - Mathematics

Solution:

Limits At Infinity, Part II | Calculus - Mathematics
The exponentials with the negative exponents are the only terms in the denominator going to infinity for this limit and so we’ll need to factor the exponential with the most negative exponent in the denominator (because it will be going to infinity fastest) from both the numerator and denominator to evaluate this limit.

Limits At Infinity, Part II | Calculus - Mathematics

Limits At Infinity, Part II | Calculus - Mathematics
The exponentials with the positive exponents are the only terms in the denominator going to infinity for this limit and so we’ll need to factor the exponential with the most positive exponent in the denominator (because it will be going to infinity fastest) from both the numerator and denominator to evaluate this limit.

Limits At Infinity, Part II | Calculus - Mathematics

For problems 7 – 12 evaluate the given limit.

7. Evaluate  Limits At Infinity, Part II | Calculus - Mathematics

Solution:

First notice that,

Limits At Infinity, Part II | Calculus - Mathematics

If you aren’t sure about this limit you should go back to the previous section and work some of the examples there to make sure that you can do these kinds of limits.

Now, recalling Example 5 from this section, we know that because the argument goes to infinity in the limit the answer is,

Limits At Infinity, Part II | Calculus - Mathematics

8. EvaluateLimits At Infinity, Part II | Calculus - Mathematics

Solution:

First notice that,

Limits At Infinity, Part II | Calculus - Mathematics

If you aren’t sure about this limit you should go back to the previous section and work some of the examples there to make sure that you can do these kinds of limits.

Now, recalling Example 5 from this section, we know that because the argument goes to infinity in the limit the answer is,

Limits At Infinity, Part II | Calculus - Mathematics

9. Evaluate Limits At Infinity, Part II | Calculus - Mathematics

Solution:
First notice that, 

Limits At Infinity, Part II | Calculus - Mathematics

If you aren’t sure about this limit you should go back to the previous section and work some of the examples there to make sure that you can do these kinds of limits.

Also, note that because we are evaluating the limit x→∞ it is safe to assume that x>0 and so we can further say that,

Limits At Infinity, Part II | Calculus - Mathematics

Now, recalling Example 5 from this section, we know that because the argument goes to zero from the right in the limit the answer is,

Limits At Infinity, Part II | Calculus - Mathematics

10. Evaluate Limits At Infinity, Part II | Calculus - Mathematics

Solution:

First notice that, 

Limits At Infinity, Part II | Calculus - Mathematics

If you aren’t sure about this limit you should go back to the previous section and work some of the examples there to make sure that you can do these kinds of limits.

Now, recalling Example 7 from this section, we know that because the argument goes to negative infinity in the limit the answer is,

Limits At Infinity, Part II | Calculus - Mathematics

11. Evaluate Limits At Infinity, Part II | Calculus - Mathematics

Solution:

First notice that,

Limits At Infinity, Part II | Calculus - Mathematics

If you aren’t sure about this limit you should go back to the previous section and work some of the examples there to make sure that you can do these kinds of limits.

Then answer is then,

Limits At Infinity, Part II | Calculus - Mathematics

Do not get so used the “special case” limits that we tend to usually do in the problems at the end of a section that you decide that you must have done something wrong when you run across a problem that doesn’t fall in the “special case” category.

12. Evaluate Limits At Infinity, Part II | Calculus - Mathematics

Solution:

First notice that,

Limits At Infinity, Part II | Calculus - Mathematics

If you aren’t sure about this limit you should go back to the previous section and work some of the examples there to make sure that you can do these kinds of limits.

Now, recalling Example 7 from this section, we know that because the argument goes to infinity in the limit the answer is,

Limits At Infinity, Part II | Calculus - Mathematics

The document Limits At Infinity, Part II | Calculus - Mathematics is a part of the Mathematics Course Calculus.
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FAQs on Limits At Infinity, Part II - Calculus - Mathematics

1. What is the concept of limits at infinity in mathematics?
Ans. Limits at infinity refer to the behavior of a function as the input values approach positive or negative infinity. It helps us understand the long-term trend or end behavior of a function.
2. How can I determine the limit at infinity of a rational function?
Ans. To find the limit at infinity of a rational function, we compare the degrees of the numerator and denominator. If the degree of the numerator is less than the degree of the denominator, the limit at infinity is 0. If the degree of the numerator is greater than the degree of the denominator, the limit is either positive infinity or negative infinity, depending on the leading coefficients. If the degrees are equal, the limit at infinity is the ratio of the leading coefficients.
3. Can limits at infinity be used to determine horizontal asymptotes of a function?
Ans. Yes, limits at infinity can be used to determine horizontal asymptotes. If the limit at positive infinity exists and is a finite number, it represents the horizontal asymptote of the function as x approaches positive infinity. Similarly, if the limit at negative infinity exists and is a finite number, it represents the horizontal asymptote as x approaches negative infinity.
4. Are there any specific rules or properties to simplify finding limits at infinity?
Ans. Yes, there are some rules and properties that can simplify finding limits at infinity. For rational functions, we can simplify by dividing both the numerator and denominator by the highest power of x. We can also use algebraic manipulation techniques, such as factoring or multiplying by conjugate, to simplify the expression before evaluating the limit.
5. Can limits at infinity help determine the end behavior of a function?
Ans. Yes, limits at infinity can provide insights into the end behavior of a function. By finding the limits at positive infinity and negative infinity, we can determine if the function approaches a specific value, goes to positive infinity, goes to negative infinity, or oscillates. This information helps us understand how the function behaves as x becomes extremely large or extremely small.
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