Limits and Asymptotes: Understanding Infinite Discontinuities in Functions - Prof. Bellom, Study notes of Mathematics

An excerpt from a mathematics textbook discussing the concepts of limits and asymptotes in functions. It covers identifying infinite discontinuities, vertical and horizontal asymptotes, and finding horizontal asymptotes for rational functions. Students are encouraged to extend the function to find the limit as x tends to plus and minus infinity.

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Pre 2010

Uploaded on 02/24/2010

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Chapter 1. Section 6
Page 1 of 3
C. Bellomo, revised 16-Aug-08
Section 1.6 – Limits at Infinity
Recall:
You have already studied , that is ()
() ()
p
x
fx qx
=.
You should already be able to identify the domain of this function, in other words, the values of x
that are/are not allowed for inputs of f.
Q: How do we find any undefined points in the domain?
A: .
These points, if they are not , are called , and the limit
of the function there would tend to plus or minus infinity.
These types of infinite discontinuities are also called .
Example. For 1
() 2
fx x
= What is the limit as x tends to 2 from the right? From the left?
Horizontal Asymptotes:
Think of an asymptote in general being an invisible line that a function ‘tends’ to if you were to keep
drawing. You never quite get there.
For example, in the above function, the graph (as x tends to 2) gets closer and closer to the vertical
line at x = 2 but never quite reaches it. And it will not cross over, either.
The above example function has another asymptote that is horizontal… If you were to let x get larger
and larger (
x
→±) the function would get closer and closer to an ‘invisible’ horizontal line.
Q: What value does the function tend to as
x
→±? What is the equation of this line?
A: .
pf3

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Page 1 of 3

Section 1.6 – Limits at Infinity

Recall:

  • You have already studied , that is

p x f x q x

  • You should already be able to identify the domain of this function, in other words, the values of x

that are/are not allowed for inputs of f.

  • Q: How do we find any undefined points in the domain?

A:.

  • These points, if they are not , are called , and the limit

of the function there would tend to plus or minus infinity.

  • These types of infinite discontinuities are also called.

Example. For

f x x

What is the limit as x tends to 2 from the right? From the left?

Horizontal Asymptotes:

  • Think of an asymptote in general being an invisible line that a function ‘tends’ to if you were to keep

drawing. You never quite get there.

  • For example, in the above function, the graph (as x tends to 2) gets closer and closer to the vertical

line at x = 2 but never quite reaches it. And it will not cross over, either.

  • The above example function has another asymptote that is horizontal… If you were to let x get larger

and larger ( x → ±∞ ) the function would get closer and closer to an ‘invisible’ horizontal line.

  • Q: What value does the function tend to as x → ±∞? What is the equation of this line?

A:.

Page 2 of 3

Finding Horizontal Asymptotes:

  • As we ‘extend’ the function to the left and right as far as we want, we are essentially taking the limit

as x tends to plus and minus infinity.

  • To find the horizontal asymptote, if it exists, take the limit as x tends to plus and minus infinity.
  • HOW TO find horizontal asymptotes for rational functions

p x f x q x

  1. Find the leading term of the numerator, p ( x ) and denominator, q ( x ).
  2. Write as a quotient and simplify.
  3. If the reduction is
    • a constant, then this is the value of your horizontal asymptote.

positive value

constant x

, then the horizontal asymptote is zero

positive value constant (⋅ x ), then there is no horizontal asymptote

It will tend to plus or minus infinity (plug in to see which).

  • Example. Find

2

2

lim x 4

x x

→∞ x

  • Example. Find

2 3

2 4

lim x 2 4

x x

→∞ x x