Difference between revisions of "Limits of Vector Functions"
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+ | <blockquote style="background: white; border: 1px solid black; padding: 1em;"> | ||
+ | '''Definition:''' If <span class="math-inline"><math>\vec{r}(t) = (x(t), y(t), z(t))</math></span> is a vector-valued function, then <span class="math-inline"><math>\lim_{t \to a} \vec{r}(t) = \left ( \lim_{t \to a} x(t), \lim_{t \to a} y(t), \lim_{t \to a} z(t) \right )</math></span> provided that the limits of the components exist. | ||
+ | </blockquote> | ||
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+ | //Limits of vector-valued functions in <math>\mathbb{R}^n</math> are defined similarly as the limit of each component. // | ||
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+ | Let's look at some examples of evaluating limits of vector-valued functions. Consider the vector-valued function <math>\vec{r}(t) = (t^2 - 1, t + 1, e^t)</math> and suppose that we wanted to compute <math>\lim_{t \to 2} \vec{r}(t)</math>. To compute this limit, all we need to do is compute the limits of the components. | ||
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+ | <div style="text-align: center;"> <math>\begin{align} \quad \lim_{t \to 2} \vec{r}(t) = \left ( \lim_{t \to 2} t^2 - 1, \lim_{t \to 2} t + 1, \lim_{t \to 2} e^t \right ) = (3, 3, e^2) \end{align}</math></div> | ||
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+ | For another example, consider the vector-valued function <math>\vec{r}(t) = \left ( \frac{e^t - 1}{t}, \frac{t - 1}{t+1}, t^2 + 3 \right )</math> and suppose that we wanted to compute <math>\lim_{t \to 0} \vec{r}(t)</math>. To compute this limit, we will compute all of the limits of the components again, however, this time the limits are a little trickier to compute. Fortunately, we have already learned about various rules to evaluate limits. | ||
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+ | <div style="text-align: center;"><math>\begin{align} \quad \lim_{t \to 0} \vec{r}(t) = \left ( \lim_{t \to 0} \frac{e^t - 1}{t}, \lim_{t \to 0} \frac{t - 1}{t + 1}, \lim_{t \to 0} t^2 + 3 \right ) \end{align}</math></div> | ||
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+ | For <math>\lim_{t \to 0} \frac{e^t - 1}{t}</math> we will use L'Hospital's Rule, and so <math>\lim_{t \to 0} \frac{e^t - 1}{t} \overset{H} = \lim_{t \to 0} \frac{e^t}{1} = 1</math>. | ||
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+ | For <math>\lim_{t \to 0} \frac{t - 1}{t+1}</math>, we can use direct substitution and so <math>\lim_{t \to 0} \frac{t-1}{t+1} = -1</math>. | ||
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+ | Now <math>\lim_{t \to 0} t^2 + 3</math> is also easy to compute by direct substitution and so <math>\lim_{t \to 0} t^2 + 3 = 3</math>. | ||
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+ | Thus we have that <math>\lim_{t \to 0} \vec{r}(t) = (1, -1, 3)</math>. | ||
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+ | The following theorem gives us a formal definition to say a vector-valued function <math>\vec{r}(t)</math> has limit <math>\vec{b}</math> at <math>t = a</math>, which is analogous to that of limits of real-valued functions. | ||
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+ | <blockquote style="background: white; border: 1px solid black; padding: 1em;"> | ||
+ | :'''Theorem 1:''' Let <math>\vec{r}(t) = (x(t), y(t), z(t))</math> be a vector-valued function and let <math>\vec{b} = (b_1, b_2, b_3) \in \mathbb{R}^3</math>. Then <math>\lim_{t \to a} \vec{r}(t) = \vec{b}</math> if and only if <math>\forall \epsilon > 0</math> <math>\exists \delta > 0</math> such that if <math>0 < \mid t - a \mid < \delta</math> then <math>\| \vec{r}(t) - \vec{b} \| < \epsilon</math>. | ||
+ | </blockquote> | ||
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+ | * '''Proof:''' <math>\Rightarrow</math> Suppose that <math>\lim_{t \to a} \vec{r}(t) = \vec{b}</math>. Then we have that:</li> | ||
+ | <div style="text-align: center;"><math>\begin{align} \left ( \lim_{t \to a} x(t), \lim_{t \to a} y(t), \lim_{t \to a} z(t) \right ) = (b_1, b_2, b_3) \end{align}</math></div> | ||
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+ | * Now recall that two vectors are equal if and only if their components are equal, and so the equation above implies that <math>\lim_{t \to a} x(t) = b_1</math>, <math>\lim_{t \to a} y(t) = b_2</math>, and <math>\lim_{t \to a} z(t) = b_3</math>. Now notice that these three limits are limits of real-valued functions. | ||
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+ | * Since <math>\lim_{t \to a} x(t) = b_1</math> then <math>\forall \epsilon > 0</math> <math>\exists \delta_1 > 0</math> such that if <math>0 < \mid t - a \mid < \delta_1</math> then <math>\mid x(t) - b_1 \mid < \frac{\epsilon}{3}</math>. | ||
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+ | * Since <math>\lim_{t \to a} y(t) = b_2</math> then <math>\forall \epsilon > 0</math> <math>\exists \delta_2 > 0</math> such that if <math>0 < \mid t - a \mid < \delta_2</math> then <math>\mid y(t) - b_2 \mid < \frac{\epsilon}{3}</math>. | ||
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+ | * Since <math>\lim_{t \to a} z(t) = b_3</math> then <math>\forall \epsilon > 0</math> <math>\exists \delta_3 > 0</math> such that if <math>0 < \mid t - a \mid < \delta_3</math> then <math>\mid z(t) - b_3 \mid < \frac{\epsilon}{3}</math>. | ||
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+ | * Let <math>\delta = \mathrm{min} \{ \delta_1, \delta_2, \delta_3 \}</math>. Then if <math>0 < \mid t - a \mid < \delta</math> we have that: | ||
+ | <div style="text-align: center;"><math>\begin{align} \quad \quad \| \vec{r}(t) - \vec{b} \| = \| (x(t) - b_1, y(t) - b_2, z(t) - b_3)) \| = \sqrt{(x(t) - b_1)^2 + (y(t) - b_2)^2 + (z(t) - b_3)^2} \\ \quad \quad \leq \sqrt{(x(t) - b_1)^2} + \sqrt{(y(t) - b_2)^2} + \sqrt{(z(t) - b_3)^2} = \mid x(t) - b_1 \mid + \mid y(t) - b_2 \mid + \mid z(t) - b_3 \mid < \frac{\epsilon}{3} + \frac{\epsilon}{3} + \frac{\epsilon}{3} = \epsilon \end{align}</math></div> | ||
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+ | * <math>\Leftarrow</math> Suppose that <math>\forall \epsilon > 0</math> <math>\exists \delta > 0</math> such that if <math>0 < \mid t - a \mid < \delta</math> then <math>\| \vec{r}(t) - \vec{b} \| < \epsilon</math>. Therefore we have that | ||
+ | :<math>\| \vec{r}(t) - \vec{b} \| = \| (x(t) - b_1, y(t) - b_2, z(t) - b_3) \| < \epsilon</math>, which implies that: | ||
+ | <div style="text-align: center;"><math>\begin{align} \sqrt{(x(t) - b_1)^2 + (y(t) - b_2)^2 + (z(t) - b_3)^2} < \epsilon \\ (x(t) - b_1)^2 + (y(t) - b_2)^2 + (z(t) - b_3)^2 < \epsilon^2 \\ \end{align}</math></div> | ||
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+ | * Now since all terms of the lefthand side of this equation are positive, we must have that for <math>0 < \mid t - a \mid < \delta</math> then <math>(x(t) - b_1)^2 < \epsilon^2</math>, <math>(y(t) - b_2)^2 < \epsilon^2</math>, and <math>(z(t) - b_3)^2 < \epsilon^2</math>, and so <math>\mid x(t) - b_1 \mid < \epsilon</math>, <math>\mid y(t) - b_2 \mid < \epsilon</math> and <math>\mid z(t) - b_3 \mid < \epsilon</math>. Therefore by the definition of real-valued function limits we have that <math>\lim_{t \to a} x(t) = b_1</math>, <math>\lim_{t \to a} y(t) = b_2</math>, and <math>\lim_{t \to a} z(t) = b_3</math>. | ||
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+ | * Thus <math>\lim_{t \to a} \vec{r}(t) = \left ( \lim_{t \to a} x(t), \lim_{t \to a} y(t), \lim_{t \to a} z(t) \right ) = (b_1, b_2, b_3) = \vec{b}</math>. <math>\blacksquare</math></li> | ||
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== Licensing == | == Licensing == | ||
Content obtained and/or adapted from: | Content obtained and/or adapted from: | ||
* [http://mathonline.wikidot.com/limits-of-vector-valued-functions Limits of Vector-Valued Functions, mathonline.wikidot.com] under a CC BY-SA license | * [http://mathonline.wikidot.com/limits-of-vector-valued-functions Limits of Vector-Valued Functions, mathonline.wikidot.com] under a CC BY-SA license |
Latest revision as of 16:56, 29 October 2021
Definition: If is a vector-valued function, then provided that the limits of the components exist.
//Limits of vector-valued functions in are defined similarly as the limit of each component. //
Let's look at some examples of evaluating limits of vector-valued functions. Consider the vector-valued function and suppose that we wanted to compute . To compute this limit, all we need to do is compute the limits of the components.
For another example, consider the vector-valued function and suppose that we wanted to compute . To compute this limit, we will compute all of the limits of the components again, however, this time the limits are a little trickier to compute. Fortunately, we have already learned about various rules to evaluate limits.
For we will use L'Hospital's Rule, and so .
For , we can use direct substitution and so .
Now is also easy to compute by direct substitution and so .
Thus we have that .
The following theorem gives us a formal definition to say a vector-valued function has limit at , which is analogous to that of limits of real-valued functions.
- Theorem 1: Let be a vector-valued function and let . Then if and only if such that if then .
- Proof: Suppose that . Then we have that:
- Now recall that two vectors are equal if and only if their components are equal, and so the equation above implies that , , and . Now notice that these three limits are limits of real-valued functions.
- Since then such that if then .
- Since then such that if then .
- Since then such that if then .
- Let . Then if we have that:
- Suppose that such that if then . Therefore we have that
- , which implies that:
- Now since all terms of the lefthand side of this equation are positive, we must have that for then , , and , and so , and . Therefore by the definition of real-valued function limits we have that , , and .
- Thus .
Licensing
Content obtained and/or adapted from:
- Limits of Vector-Valued Functions, mathonline.wikidot.com under a CC BY-SA license