Difference between revisions of "Real Function Limits:Sequential Criterion"

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<h1 id="toc0"><span>The Sequential Criterion for a Limit of a Function</span></h1>
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<p>We will now look at a very important theorem known as The Sequential Criterion for a Limit which merges the concept of the limit of a function <span class="math-inline">$f$</span> at a cluster point <span class="math-inline">$c$</span> from <span class="math-inline">$A$</span> with regards to sequences <span class="math-inline">$(a_n)$</span> from <span class="math-inline">$A$</span> that converge to <span class="math-inline">$c$</span>.</p>
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<td><strong>Theorem 1 (The Sequential Criterion for a Limit of a Function):</strong> Let <span class="math-inline">$f : A \to \mathbb{R}$</span> be a function and let <span class="math-inline">$c$</span> be a cluster point of <span class="math-inline">$A$</span>. Then <span class="math-inline">$\lim_{x \to c} f(x) = L$</span> if and only if for all sequences <span class="math-inline">$(a_n)$</span> from the domain <span class="math-inline">$A$</span> where <span class="math-inline">$a_n \neq c$</span> <span class="math-inline">$\forall n \in \mathbb{N}$</span> and <span class="math-inline">$\lim_{n \to \infty} a_n = c$</span> then <span class="math-inline">$\lim_{n \to \infty} f(a_n) = L$</span>.</td>
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<p>Consider a function <span class="math-inline">$f$</span> that has a limit <span class="math-inline">$L$</span> when <span class="math-inline">$x$</span> is close to <span class="math-inline">$c$</span>. Now consider all sequences <span class="math-inline">$(a_n)$</span> from the domain <span class="math-inline">$A$</span> where these sequences converge to <span class="math-inline">$c$</span>, that is <span class="math-inline">$\lim_{n \to \infty} a_n = c$</span>. The Sequential Criterion for a Limit of a Function says that then that as <span class="math-inline">$n$</span> goes to infinity, the function <span class="math-inline">$f$</span> evaluated at these <span class="math-inline">$a_n$</span> will have its limit go to <span class="math-inline">$L$</span>.</p>
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<p>For example, consider the function <span class="math-inline">$f: \mathbb{R} \to \mathbb{R}$</span> defined by the equation <span class="math-inline">$f(x) = x$</span>, and suppose we wanted to compute <span class="math-inline">$\lim_{x \to 0} x$</span>. We should already know that this limit is zero, that is <span class="math-inline">$\lim_{x \to 0} x = 0$</span>. Now consider the sequence <span class="math-inline">$(a_n) = \left ( \frac{1}{n} \right)$</span>. This sequence <span class="math-inline">$(a_n)$</span> is clearly contained in the domain of <span class="math-inline">$f$</span>. Furthermore, this sequence converges to 0, that is <span class="math-inline">$\lim_{n \to \infty} \frac{1}{n} = 0$</span>. If all such sequences <span class="math-inline">$(a_n)$</span> that converge to <span class="math-inline">$0$</span> have the property that <span class="math-inline">$(f(a_n))$</span> converges to <span class="math-inline">$f(0) = 0$</span>, then we can say that <span class="math-inline">$\lim_{n \to 0} f(x) = 0$</span>.</p>
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<p>We will now look at the proof of The Sequential Criterion for a Limit of a Function.</p>
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<ul>
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<li><strong>Proof:</strong> <span class="math-inline">$\Rightarrow$</span> Suppose that <span class="math-inline">$\lim_{x \to c} f(x) = L$</span>, and let <span class="math-inline">$(a_n)$</span> be a sequence in <span class="math-inline">$A$</span> such that <span class="math-inline">$a_n \neq c$</span> <span class="math-inline">$\forall n \in \mathbb{N}$</span> such that <span class="math-inline">$\lim_{n \to \infty} a_n = c$</span>. We thus want to show that <span class="math-inline">$\lim_{n \to \infty} f(a_n) = L$</span>.</li>
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<li>Let <span class="math-inline">$\epsilon &gt; 0$</span>. We are given that <span class="math-inline">$\lim_{x \to c} f(x) = L$</span> and so for <span class="math-inline">$\epsilon &gt; 0$</span> there exists a <span class="math-inline">$\delta &gt; 0$</span> such that if <span class="math-inline">$x \in A$</span> and <span class="math-inline">$0 &lt; \mid x - c \mid &lt; \delta$</span> then we have that <span class="math-inline">$\mid f(x) - L \mid &lt; \epsilon$</span>. Now since <span class="math-inline">$\delta &gt; 0$</span>, since we have that <span class="math-inline">$\lim_{n \to \infty} a_n = c$</span> then there exists an <span class="math-inline">$N \in \mathbb{N}$</span> such that if <span class="math-inline">$n ≥ N$</span> then <span class="math-inline">$\mid a_n - c \mid &lt; \delta$</span>. Therefore <span class="math-inline">$a_n \in V_{\delta} (c) \cap A$</span>.</li>
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<li>Therefore it must be that <span class="math-inline">$\mid f(a_n) - L \mid &lt; \epsilon$</span>, in other words, <span class="math-inline">$\forall n ≥ N$</span> we have that <span class="math-inline">$\mid f(a_n) - L \mid &lt; \epsilon$</span> and so <span class="math-inline">$\lim_{n \to \infty} f(a_n) = L$</span>.</li>
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<li><span class="math-inline">$\Leftarrow$</span> Suppose that for all <span class="math-inline">$(a_n)$</span> in <span class="math-inline">$A$</span> such that <span class="math-inline">$a_n \neq c$</span> <span class="math-inline">$\forall n \in \mathbb{N}$</span> and <span class="math-inline">$\lim_{n \to \infty} a_n = c$</span>, we have that <span class="math-inline">$\lim_{n \to \infty} f(a_n) = L$</span>. We want to show that <span class="math-inline">$\lim_{x \to c} f(x) = L$</span>.</li>
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<li>Suppose not, in other words, suppose that <span class="math-inline">$\exists \epsilon_0 &gt; 0$</span> such that <span class="math-inline">$\forall \delta &gt; 0$</span> then <span class="math-inline">$\exists x_{\delta} \in A \cap V_{\delta} (c) \setminus \{ c \}$</span> such that <span class="math-inline">$\mid f(x_{\delta}) - L \mid ≥ \epsilon_0$</span>. Let <span class="math-inline">$\delta_n = \frac{1}{n}$</span>. Then there exists <span class="math-inline">$x_{\delta_n} = a_n \in A \cap V_{\delta_n} (c) \setminus \{ c \}$</span>, in other words, <span class="math-inline">$0 &lt; \mid a_n - c \mid &lt; \frac{1}{n}$</span> and <span class="math-inline">$\lim_{n \to \infty} a_n = c$</span>. However, <span class="math-inline">$\mid f(a_n) - L \mid ≥ \epsilon_0$</span> so <span class="math-inline">$\lim_{n \to \infty} f(a_n) \neq L$</span>, a contradiction. Therefore <span class="math-inline">$\lim_{x \to c} f(x) = L$</span>. <span class="math-inline">$\blacksquare$</span></li>
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==Resources==
 
==Resources==
 
* [http://mathonline.wikidot.com/the-sequential-criterion-for-a-limit-of-a-function The Sequential Criterion for a Limit of a Function]
 
* [http://mathonline.wikidot.com/the-sequential-criterion-for-a-limit-of-a-function The Sequential Criterion for a Limit of a Function]

Revision as of 09:25, 20 October 2021

The Sequential Criterion for a Limit of a Function

We will now look at a very important theorem known as The Sequential Criterion for a Limit which merges the concept of the limit of a function $f$ at a cluster point $c$ from $A$ with regards to sequences $(a_n)$ from $A$ that converge to $c$.

Theorem 1 (The Sequential Criterion for a Limit of a Function): Let $f : A \to \mathbb{R}$ be a function and let $c$ be a cluster point of $A$. Then $\lim_{x \to c} f(x) = L$ if and only if for all sequences $(a_n)$ from the domain $A$ where $a_n \neq c$ $\forall n \in \mathbb{N}$ and $\lim_{n \to \infty} a_n = c$ then $\lim_{n \to \infty} f(a_n) = L$.

Consider a function $f$ that has a limit $L$ when $x$ is close to $c$. Now consider all sequences $(a_n)$ from the domain $A$ where these sequences converge to $c$, that is $\lim_{n \to \infty} a_n = c$. The Sequential Criterion for a Limit of a Function says that then that as $n$ goes to infinity, the function $f$ evaluated at these $a_n$ will have its limit go to $L$.

For example, consider the function $f: \mathbb{R} \to \mathbb{R}$ defined by the equation $f(x) = x$, and suppose we wanted to compute $\lim_{x \to 0} x$. We should already know that this limit is zero, that is $\lim_{x \to 0} x = 0$. Now consider the sequence $(a_n) = \left ( \frac{1}{n} \right)$. This sequence $(a_n)$ is clearly contained in the domain of $f$. Furthermore, this sequence converges to 0, that is $\lim_{n \to \infty} \frac{1}{n} = 0$. If all such sequences $(a_n)$ that converge to $0$ have the property that $(f(a_n))$ converges to $f(0) = 0$, then we can say that $\lim_{n \to 0} f(x) = 0$.

We will now look at the proof of The Sequential Criterion for a Limit of a Function.

  • Proof: $\Rightarrow$ Suppose that $\lim_{x \to c} f(x) = L$, and let $(a_n)$ be a sequence in $A$ such that $a_n \neq c$ $\forall n \in \mathbb{N}$ such that $\lim_{n \to \infty} a_n = c$. We thus want to show that $\lim_{n \to \infty} f(a_n) = L$.
  • Let $\epsilon > 0$. We are given that $\lim_{x \to c} f(x) = L$ and so for $\epsilon > 0$ there exists a $\delta > 0$ such that if $x \in A$ and $0 < \mid x - c \mid < \delta$ then we have that $\mid f(x) - L \mid < \epsilon$. Now since $\delta > 0$, since we have that $\lim_{n \to \infty} a_n = c$ then there exists an $N \in \mathbb{N}$ such that if $n ≥ N$ then $\mid a_n - c \mid < \delta$. Therefore $a_n \in V_{\delta} (c) \cap A$.
  • Therefore it must be that $\mid f(a_n) - L \mid < \epsilon$, in other words, $\forall n ≥ N$ we have that $\mid f(a_n) - L \mid < \epsilon$ and so $\lim_{n \to \infty} f(a_n) = L$.
  • $\Leftarrow$ Suppose that for all $(a_n)$ in $A$ such that $a_n \neq c$ $\forall n \in \mathbb{N}$ and $\lim_{n \to \infty} a_n = c$, we have that $\lim_{n \to \infty} f(a_n) = L$. We want to show that $\lim_{x \to c} f(x) = L$.
  • Suppose not, in other words, suppose that $\exists \epsilon_0 > 0$ such that $\forall \delta > 0$ then $\exists x_{\delta} \in A \cap V_{\delta} (c) \setminus \{ c \}$ such that $\mid f(x_{\delta}) - L \mid ≥ \epsilon_0$. Let $\delta_n = \frac{1}{n}$. Then there exists $x_{\delta_n} = a_n \in A \cap V_{\delta_n} (c) \setminus \{ c \}$, in other words, $0 < \mid a_n - c \mid < \frac{1}{n}$ and $\lim_{n \to \infty} a_n = c$. However, $\mid f(a_n) - L \mid ≥ \epsilon_0$ so $\lim_{n \to \infty} f(a_n) \neq L$, a contradiction. Therefore $\lim_{x \to c} f(x) = L$. $\blacksquare$

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