Problem 76
Question
\(\lim _{x \rightarrow \infty}\\{x\\}\)
Step-by-Step Solution
Verified Answer
The limit as \(x\) approaches infinity of \(x\) is infinity.
1Step 1: Identify the limit
The problem is asking for the limit of a constant function \(x\), as \(x\) approaches infinity.
2Step 2: Apply the limit
Apply the limit, meaning substitute the approaching value (in this case, infinity) into the function. The limit as \(x\) approaches infinity of \(x\) is \(x\).
3Step 3: Evaluate the limit
As \(x\) approaches infinity, the function \(x\) also approaches infinity. In other words, the value of \(x\) becomes larger and larger without bound as \(x\) tends to infinity.
Key Concepts
Limit of a FunctionApproaching InfinityEvaluating Limits
Limit of a Function
Understanding the limit of a function is a foundational concept in calculus. It informs us about the behavior of a function as its input gets closer and closer to a certain value.
For example, when we write \(\lim _{x \rightarrow a}f(x)\), we're looking at what happens to the function \(f(x)\) as the variable \(x\) approaches the value \(a\). Do remember, the actual value of the function at \(a\) might not be important; what matters is the value that the function is approaching.
To understand this better, let's use a real-world analogy. Imagine you're walking towards a street performer. The closer you get, the louder the music becomes. The 'limit' is like the volume of the music you hear as you are just about to reach the performer--not the moment you are standing right next to them and experience the sound at its loudest.
For example, when we write \(\lim _{x \rightarrow a}f(x)\), we're looking at what happens to the function \(f(x)\) as the variable \(x\) approaches the value \(a\). Do remember, the actual value of the function at \(a\) might not be important; what matters is the value that the function is approaching.
To understand this better, let's use a real-world analogy. Imagine you're walking towards a street performer. The closer you get, the louder the music becomes. The 'limit' is like the volume of the music you hear as you are just about to reach the performer--not the moment you are standing right next to them and experience the sound at its loudest.
Approaching Infinity
When we say that a variable is 'approaching infinity', we speak of a journey without an end. In mathematics, infinity isn’t a real number but rather a concept of endlessness or boundlessness.
In the case of our exercise concerning \(\lim _{x \rightarrow \infty}x\), what we're saying is that as \(x\) gets larger and larger, there's no ceiling it reaches; it keeps going up without any limit. Now, keep in mind that infinity is not a destination; you cannot 'reach' infinity. Instead, it's a way to describe the behavior of \(x\) as it increases perpetually. You can visualize this like a balloon that keeps expanding as you add more air—it never stops growing.
In the case of our exercise concerning \(\lim _{x \rightarrow \infty}x\), what we're saying is that as \(x\) gets larger and larger, there's no ceiling it reaches; it keeps going up without any limit. Now, keep in mind that infinity is not a destination; you cannot 'reach' infinity. Instead, it's a way to describe the behavior of \(x\) as it increases perpetually. You can visualize this like a balloon that keeps expanding as you add more air—it never stops growing.
Evaluating Limits
Evaluating limits is about making a careful analysis to determine what value a function approaches as its input tends toward a particular point or infinity.
In our textbook problem, to evaluate \(\lim _{x \rightarrow \infty}x\), we're essentially looking at the function's behavior at the tails of its domain. Here, we see that the function simply is \(x\), and as \(x\) stretches towards infinity, so does the value of the function. It's a simple case, where the limit of the function quite naturally is \(x\) itself—increasing endlessly as \(x\) grows without bounds.
Evaluation can get more complex with more intricate functions, where we may need to use specific techniques or rules—like L'Hôpital’s rule, squeeze theorem, or algebraic simplification—to find the limit. But for now, know that evaluating limits is a crucial tool for understanding the behavior of functions near defined points or their boundless stretch to infinity.
In our textbook problem, to evaluate \(\lim _{x \rightarrow \infty}x\), we're essentially looking at the function's behavior at the tails of its domain. Here, we see that the function simply is \(x\), and as \(x\) stretches towards infinity, so does the value of the function. It's a simple case, where the limit of the function quite naturally is \(x\) itself—increasing endlessly as \(x\) grows without bounds.
Evaluation can get more complex with more intricate functions, where we may need to use specific techniques or rules—like L'Hôpital’s rule, squeeze theorem, or algebraic simplification—to find the limit. But for now, know that evaluating limits is a crucial tool for understanding the behavior of functions near defined points or their boundless stretch to infinity.
Other exercises in this chapter
Problem 74
Show that the function \(f(x)=x^{2}-x+1, \quad x \geq \frac{1}{2}\) and \(g(x)=\frac{1}{2}+\sqrt{x-\frac{3}{4}}\) are mutually inverse, and solve the equation \
View solution Problem 75
Find the domain of the function \(f(x)=\frac{1}{\lfloor x-1 \mid]+[|7-x|]-6}\) ([ ] denotes greatest integer function).
View solution Problem 77
\(\lim _{x \rightarrow 2^{-}} x+(x-[x])^{2} .\)
View solution Problem 78
\(\lim _{x \rightarrow 1} 1-x+[x-1]+[1-x] .\)
View solution