3.1 Vector-valued functions and space curves (Page 3/12)

Calculus volume 3 Page 3 / 12

You may notice that the graphs in parts a. and b. are identical. This happens because the function describing curve b is a so-called reparameterization of the function describing curve a. In fact, any curve has an infinite number of reparameterizations; for example, we can replace t with $2 t$ in any of the three previous curves without changing the shape of the curve. The interval over which t is defined may change, but that is all. We return to this idea later in this chapter when we study arc-length parameterization.

As mentioned, the name of the shape of the curve of the graph in [link] c. is a helix ( [link] ). The curve resembles a spring, with a circular cross-section looking down along the z -axis. It is possible for a helix to be elliptical in cross-section as well. For example, the vector-valued function $r (t) = 4 cos t i + 3 sin t j + t k$ describes an elliptical helix. The projection of this helix into the $x, y -plane$ is an ellipse. Last, the arrows in the graph of this helix indicate the orientation of the curve as t progresses from 0 to $4 π .$

Create a graph of the vector-valued function $r (t) = (t^{2} - 1) i + (2 t - 3) j,$ $0 \leq t \leq 3 .$

This figure is a graph of the function r(t) = (t^2-1)i + (2t-3)j, for the values of t from 0 to 3. The curve begins in the 3rd quadrant at the ordered pair (-1,-3) and increases up through the 1st quadrant. It is increasing and has arrows on the curve representing orientation to the right.

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At this point, you may notice a similarity between vector-valued functions and parameterized curves. Indeed, given a vector-valued function $r (t) = f (t) i + g (t) j,$ we can define $x = f (t)$ and $y = g (t) .$ If a restriction exists on the values of t (for example, t is restricted to the interval $[a, b]$ for some constants $a < b),$ then this restriction is enforced on the parameter. The graph of the parameterized function would then agree with the graph of the vector-valued function, except that the vector-valued graph would represent vectors rather than points. Since we can parameterize a curve defined by a function $y = f (x),$ it is also possible to represent an arbitrary plane curve by a vector-valued function.

Limits and continuity of a vector-valued function

We now take a look at the limit of a vector-valued function . This is important to understand to study the calculus of vector-valued functions.

Definition

A vector-valued function r approaches the limit L as t approaches a, written

lim_{t \to a} r (t) = L,

provided

lim_{t \to a} | r (t) - L | = 0 .

This is a rigorous definition of the limit of a vector-valued function. In practice, we use the following theorem:

Limit of a vector-valued function

Let f, g, and h be functions of t. Then the limit of the vector-valued function $r (t) = f (t) i + g (t) j$ as t approaches a is given by

lim_{t \to a} r (t) = [lim_{t \to a} f (t)] i + [lim_{t \to a} g (t)] j,

provided the limits $lim_{t \to a} f (t) and lim_{t \to a} g (t)$ exist. Similarly, the limit of the vector-valued function $r (t) = f (t) i + g (t) j + h (t) k$ as t approaches a is given by

lim_{t \to a} r (t) = [lim_{t \to a} f (t)] i + [lim_{t \to a} g (t)] j + [lim_{t \to a} h (t)] k,

provided the limits $lim_{t \to a} f (t), lim_{t \to a} g (t) and lim_{t \to a} h (t)$ exist.

In the following example, we show how to calculate the limit of a vector-valued function.

Evaluating the limit of a vector-valued function

For each of the following vector-valued functions, calculate $lim_{t \to 3} r (t)$ for

$r (t) = (t^{2} - 3 t + 4) i + (4 t + 3) j$
$r (t) = \frac{2 t - 4}{t + 1} i + \frac{t}{t^{2} + 1} j + (4 t - 3) k$

Use [link] and substitute the value $t = 3$ into the two component expressions:

$\begin{matrix} lim_{t \to 3} r (t) & = lim_{t \to 3} [(t^{2} - 3 t + 4) i + (4 t + 3) j] \\ = [lim_{t \to 3} (t^{2} - 3 t + 4)] i + [lim_{t \to 3} (4 t + 3)] j \\ = 4 i + 15 j . \end{matrix}$
Use [link] and substitute the value $t = 3$ into the three component expressions:

$\begin{matrix} lim_{t \to 3} r (t) & = lim_{t \to 3} (\frac{2 t - 4}{t + 1} i + \frac{t}{t^{2} + 1} j + (4 t - 3) k) \\ = [lim_{t \to 3} (\frac{2 t - 4}{t + 1})] i + [lim_{t \to 3} (\frac{t}{t^{2} + 1})] j + [lim_{t \to 3} (4 t - 3)] k \\ = \frac{1}{2} i + \frac{3}{10} j + 9 k . \end{matrix}$

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Source: OpenStax, Calculus volume 3. OpenStax CNX. Feb 05, 2016 Download for free at http://legacy.cnx.org/content/col11966/1.2

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