1. Limits and Continuity
Introduction to Limits
4:14 minutesProblem 2.7.45
Textbook Question
Use the precise definition of infinite limits to prove the following limits.
Verified step by step guidance1
Step 1: Understand the definition of an infinite limit. The statement \( \lim_{{x \to 4}} \frac{1}{{(x-4)^2}} = \infty \) means that for every positive number \( M \), there exists a \( \delta > 0 \) such that if \( 0 < |x - 4| < \delta \), then \( \frac{1}{{(x-4)^2}} > M \).
Step 2: Start by manipulating the inequality \( \frac{1}{{(x-4)^2}} > M \). This can be rewritten as \( (x-4)^2 < \frac{1}{M} \).
Step 3: Solve the inequality \( (x-4)^2 < \frac{1}{M} \) for \( x \). This gives \( |x-4| < \frac{1}{\sqrt{M}} \).
Step 4: Choose \( \delta = \frac{1}{\sqrt{M}} \). This choice of \( \delta \) ensures that whenever \( 0 < |x - 4| < \delta \), the inequality \( \frac{1}{{(x-4)^2}} > M \) holds true.
Step 5: Conclude that since for every \( M > 0 \), there exists a \( \delta = \frac{1}{\sqrt{M}} \) such that \( 0 < |x - 4| < \delta \) implies \( \frac{1}{{(x-4)^2}} > M \), the limit \( \lim_{{x \to 4}} \frac{1}{{(x-4)^2}} = \infty \) is proven.
Verified video answer for a similar problem:This video solution was recommended by our tutors as helpful for the problem above
Video duration:
4mWas this helpful?
Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Infinite Limits
Infinite limits describe the behavior of a function as the input approaches a certain value, where the output grows without bound. Specifically, if the limit of a function as x approaches a value c is infinity, it indicates that the function's values increase indefinitely as x gets closer to c. This concept is crucial for understanding how functions behave near points of discontinuity or vertical asymptotes.
Recommended video:
05:50
One-Sided Limits
Limit Definition
The formal definition of a limit involves the epsilon-delta criterion, which provides a rigorous way to describe the behavior of functions as they approach a specific point. For a limit to exist, for every small positive number (epsilon), there must be a corresponding small distance (delta) such that if the input is within that distance of the point, the output is within the specified range. This definition is foundational for proving limits, especially in cases involving infinity.
Recommended video:
05:43Definition of the Definite Integral
Continuity and Discontinuity
Continuity at a point means that a function is defined at that point, the limit exists, and the limit equals the function's value. Discontinuity occurs when any of these conditions fail, often leading to infinite limits. Understanding the types of discontinuities, such as removable or essential, is essential for analyzing limits, particularly when approaching points where the function may not be defined or behaves erratically.
Recommended video:
05:34Intro to Continuity
6:47mWatch next
Master Finding Limits Numerically and Graphically with a bite sized video explanation from Callie
Start learning
