THE Y'S THE LIMIT |

__THE Y'S THE LIMIT__:

Those of you studying differential Calculus will have already met up with **limits**, and you've probably scratched a furrow or two into your scalp while battling to understand just what a limit means. Well, the title says it all.

When we evaluate a limit such as the **limit as x approaches a for f(x),** we are looking for a

Since division by 0 is undefined in our number system, and

when *x*** = -2** , the value –2 is **not an element in the domain** set of ** f**.

__This is why we take a limit__ -- from the left and the right -- investigating the *y*** values** associated

with *x*** values** ** close** to –2. For the current function, we would have to split the limit into two separate limits.

We would find and

In a case like this, the **left limit goes to** and the **right limit goes to **, so ** there is no limit**, since the limit from the left must equal the limit from the right for a limit to exist and, infinity doesn't put any limits on the curve -- now does it? If you get , there is no limit. (See

Let's look at a more interesting function.

Consider: .

We can rewrite the function as

It is obvious that ** x** = 3 is not an element of this function's domain so let's find the limit at 3.

As you probably learned in your first limits lesson, generally with a fraction such as this, we **factor, cancel and substitute** -- but we have **a value of ***x*** that makes both numerator and denomiator equal to zero** here. This is known as an **indeterminate form** since could satisfy 3 different situations in our number system. It is a fraction with numerator = 0 so it should = 0. It is also a fraction with a denominator of 0, so it should = . We could also assign the value 1 to this fraction by claiming that it has numerator = to denominator. Now do you understand why we call it **indeterminate**? Because of the nature of zero, we have to find sneaky ways to evaluate such a fraction. The other problem child from this family you'll meet is the **indeterminate form** of , which could also be explained to be **1, 0** or ** **. A French fellow named l'Hopital appropriately enough will take care of both indeterminate forms later in this course or early in the next. Until then, use algebraic techniques to find their limits.

When ** x** = –3, only the denominator = 0 here and so

When we factor, cancel and substitute 3 for ** x**, we get 1/6, thus the

This hole is known as a **removable discontinuity** or a **removable jump** since there is only a single point missing. Thus, we could make this function continuous at *x*** = 3** by stipulating that *f***(3) = 1/6**. The discontinuity that occurs at *x*** = – 3** however is an **infinite discontinuity** otherwise known as a **vertical asymptote**. There is no way to fill the gap created here.

When we investigate **limits at infinity**, we are looking at the **behavior** of the *y***-values** at the **extremes of the **** x**-axis, in other words -- how does the graph behave when

For example: if ** **, we divide everything by *x*** ^{2}**.

As you can probably see, the result, once we make *x*** = **, is **3/ – 5**. Thus, when we graph this function, it will have a **horizontal** **asymptote** at *y*** = – 3/5. **The *y***-value** will approach **– 3/5 **as ** x** gets extremely large (approaches ) or extremely small (approaches ), and since

Once you begin studying derivatives, you will encounter a special limit known as **Newton's Quotient** (which should really be known as **Descartes' Quotient**) that will enable you to evaluate **the slope of the tangent** at any point along a given curve. I will discuss this topic in my next article.

P.S. If you're wondering why we call fractions **rational numbers** you need only look at the first 5 letters of the word **rational** to comprehend the logic.

**images of asymptotes and limits at **

**TtT**

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