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==<span id="sec 3.1"></span>The Circle.== | |||
We looked at a circle in Chapter 1 and have a definition from a first course in | |||
plane geometry. This is still the definition: A '''circle''' is the locus of points in a plane at a given distance from a fixed point. The given distance is called the '''radius''' and the fixed point is called the '''center'''. | |||
If the center of the circle is at <math>(h, k)</math>, the distance from the center to a variable point <math>(x,y)</math> is, by the distance formula, <math>\sqrt{(x-h)^2 + (y-k)^2}</math>. If the radius is <math>r</math>, we have an equation of the circle given by | |||
<span id{{=}}"eq3.1.1"/> | |||
<math display="block"> | |||
\begin{equation} | |||
\sqrt{(x-h)^2 + (y-k)^2} = r. | |||
\label{eq3.1.1} | |||
\end{equation} | |||
</math> | |||
An equivalent equation which is more commonly used is | |||
<span id{{=}}"eq3.1.2"/> | |||
<math display="block"> | |||
\begin{equation} | |||
(x-h)^2 + (y-k)^2 = r^2. | |||
\label{eq3.1.2} | |||
\end{equation} | |||
</math> | |||
It is easy to see that, not only do all points at a distance <math>r</math> from <math>(h, k)</math> lie on the graph of (2), but also all points on the graph of (2) are at a distance r from <math>(h, k)</math>. | |||
\medskip | |||
'''Example''' | |||
(a) Write an equation of the circle with center at the origin and radius 3. (b) | |||
Write an equation of the circle with center at <math>(-1, 2)</math> and radius 5. | |||
\item[a]] By the distance formula, the first circle has equation | |||
<math display="block"> | |||
\sqrt{(x-0)^2 + (y-0)^2} = 3, \;\;\; \mbox{or} \;\;\; x^2 + y^2 = 9. | |||
</math> | |||
\item[(b)] By the distance formula, an equation for the second circle is\linebreak | |||
<math>\sqrt{[x-(-1)]^2 + (y-2)^2} = 5</math>. Equivalent equations are | |||
<math display="block"> | |||
\begin{eqnarray*} | |||
(x + 1)^2 + (y - 2)^2 &=& 25, \\ | |||
x^2 + y^2 + 2x - 4y &=& 20. | |||
\end{eqnarray*} | |||
</math> | |||
As the following examples will show, any equation of the form <math>ax^2 + ay^2 + bx + cy + d = 0</math> is, loosely speaking, an equation of a circle. The words “loosely speaking” are inserted to cover possible degenerate cases. For example, if <math>a = 0</math> and <math>b</math> and <math>c</math> are not both zero, the equation becomes an equation of a line. In another degenerate case “the circle” may be just a point (if its radius is zero), and in another there may be no locus at all. | |||
\medskip | |||
'''Example''' | |||
Describe the graph of each of the following equations: | |||
\item[(a) <math>x^2 + y^2 - 6x + 8y - 75 = 0</math>, | |||
\item[b] <math>x^2 + y^2 + 12x - 2y + 37 = 0</math>, | |||
\item[c] <math>x^2+y^2 - 4x- 5y+ 12 = 0</math>, | |||
\item[d] <math>3x^2 + 3y^2 - 9x + 10y - \frac{71}{12} = 0</math>. | |||
The technique of completing the square is useful in problems of this type. In (a), we write equations equivalent to the given equation until we recognize the form. | |||
<math display="block"> | |||
\begin{eqnarray*} | |||
x^2 - 6x + y^2 + 8y &=& 75, \\ | |||
x^2 - 6x + 9 + y^2 + 8y + 16 &=& 75 + 9 + 16, \\ | |||
(x - 3)^2 + (y + 4)^2 &=& 100. | |||
\end{eqnarray*} | |||
</math> | |||
The graph is a circle with center at <math>(3, - 4)</math> and radius 10. | |||
Applying the same technique to (b), we have | |||
<math display="block"> | |||
\begin{eqnarray*} | |||
x^2 + 12x + y^2 - 2y &=& -37, \\ | |||
x^2 + 12x + 36 + y^2 - 2y + 1 &=& -37 + 36 + 1, \\ | |||
(x + 6)^2 + (y - 1)^2 &=& 0. | |||
\end{eqnarray*} | |||
</math> | |||
The graph is a circle with center at <math>(- 6, 1)</math> and radius 0; i.e., it is just the point <math>(- 6, 1)</math>. We may say that the graph consists of the single point, although we sometimes describe it as a point circle. | |||
The equation of (c) gives different results: | |||
<math display="block"> | |||
\begin{eqnarray*} | |||
x^2 - 4x + y^2 - 5y &=& - 12, \\ | |||
x^2 - 4x + 4 + y^2 - 5y + \frac{25}{4} &=& - 12 + 4 + \frac{25}{4}, \\ | |||
(x-2)^2 + (y - \frac{5}{2})^2 &=& -\frac{7}{4}. | |||
\end{eqnarray*} | |||
</math> | |||
For any two real numbers <math>x</math> and <math>y</math>, the numbers <math>(x-2)^2</math> and <math>(y-\frac{5}{2})^2</math> must both be nonnegative, while <math>-\frac{4}{7}</math> is certainly negative. Hence there are no points in the plane satisfying this equation. However, the form of the last of the three equivalent equations is that of the equation of a circle, and we sometimes say that the graph is an imaginary circle with center at <math>(2, \frac{5}{2})</math> and radius <math>\frac{1}{2}\sqrt{-7}</math>. | |||
Equation (d) requires a bit more manipulation: | |||
<math display="block"> | |||
\begin{eqnarray*} | |||
3x^2 - 9x + 3y^2 + 10y &=& \frac{71}{12},\\ | |||
x^2 - 3x + y^2 + \frac{10}{3}y &=& \frac{71}{36},\\ | |||
x^2 - 3x + \frac{9}{4} + y^2 + \frac{10}{3}y + \frac{29}{5} &=& \frac{71}{36} + \frac{9}{4} + \frac{25}{9}, \\ | |||
(x - \frac{3}{2})^2 + (y + \frac{5}{3})^2 &=& 7. | |||
\end{eqnarray*} | |||
</math> | |||
The graph is a circle with center at <math>(\frac{3}{2}, -\frac{5}{3})</math> and radius <math>\sqrt7</math>. | |||
\medskip | |||
By completing the square, as in the above examples, one can show that any equation of the form | |||
<math display="block"> | |||
ax^2 + ay^2 + bx + cy + d = 0 | |||
</math> | |||
is an equation of a circle of positive radius if and only if <math>a \neq 0</math> and <math>b^2 + c^2 > 4ad</math>. | |||
The circle is also the intersection of a right circular cone with a plane perpendicular to the axis of the cone. If the plane passes through the vertex of the cone, the intersection is a point. | |||
We can use the techniques of the calculus, as well as our knowledge of Euclidean geometry, to write an equation for a circle or for a line tangent to a circle, from given geometric conditions. | |||
'''Example''' | |||
Write an equation of the line which is tangent to the graph of <math>(x + 3)^2 + (y - 4)^2 | |||
= 25</math> at (1, 7). We may find the slope by use of the derivative, differentiating implicitly and remembering that one interpretation of the derivative is the slope of the tangent: <math>2(x + 3) + 2(y - 4)y' = 0</math>; hence <math>y' = - \frac{x + 3}{y - 4}</math>. The slope Or the tangent is <math>-\frac{1 + 3}{7 - 4} = - \frac{4}{3}</math>. We | |||
may also find the slope of the tangent by noting first that the radius to (1, 7) has slope <math>\frac{7-4}{1- (-3)}= \frac{3}{4}</math> and then by remembering that the tangent is perpendicular to the radius and hence has slope <math>-\frac{4}{3}</math>. Thus the tangent line has equation <math>y-7 = - \frac{4}{3}(x-1)</math> or <math>4x + 3y = 25</math>. | |||
\end{exercise} | |||
==General references== | |||
{{cite web |title=Crowell and Slesnick’s Calculus with Analytic Geometry|url=https://math.dartmouth.edu/~doyle/docs/calc/calc.pdf |last=Doyle |first=Peter G.|date=2008 |access-date=Oct 29, 2024}} |
Revision as of 00:07, 3 November 2024
The Circle.
We looked at a circle in Chapter 1 and have a definition from a first course in plane geometry. This is still the definition: A circle is the locus of points in a plane at a given distance from a fixed point. The given distance is called the radius and the fixed point is called the center. If the center of the circle is at [math](h, k)[/math], the distance from the center to a variable point [math](x,y)[/math] is, by the distance formula, [math]\sqrt{(x-h)^2 + (y-k)^2}[/math]. If the radius is [math]r[/math], we have an equation of the circle given by
An equivalent equation which is more commonly used is
It is easy to see that, not only do all points at a distance [math]r[/math] from [math](h, k)[/math] lie on the graph of (2), but also all points on the graph of (2) are at a distance r from [math](h, k)[/math]. \medskip Example
(a) Write an equation of the circle with center at the origin and radius 3. (b) Write an equation of the circle with center at [math](-1, 2)[/math] and radius 5.
\item[a]] By the distance formula, the first circle has equation
\item[(b)] By the distance formula, an equation for the second circle is\linebreak [math]\sqrt{[x-(-1)]^2 + (y-2)^2} = 5[/math]. Equivalent equations are
As the following examples will show, any equation of the form [math]ax^2 + ay^2 + bx + cy + d = 0[/math] is, loosely speaking, an equation of a circle. The words “loosely speaking” are inserted to cover possible degenerate cases. For example, if [math]a = 0[/math] and [math]b[/math] and [math]c[/math] are not both zero, the equation becomes an equation of a line. In another degenerate case “the circle” may be just a point (if its radius is zero), and in another there may be no locus at all.
\medskip
Example
Describe the graph of each of the following equations:
\item[(a) [math]x^2 + y^2 - 6x + 8y - 75 = 0[/math], \item[b] [math]x^2 + y^2 + 12x - 2y + 37 = 0[/math], \item[c] [math]x^2+y^2 - 4x- 5y+ 12 = 0[/math], \item[d] [math]3x^2 + 3y^2 - 9x + 10y - \frac{71}{12} = 0[/math].
The technique of completing the square is useful in problems of this type. In (a), we write equations equivalent to the given equation until we recognize the form.
The graph is a circle with center at [math](3, - 4)[/math] and radius 10. Applying the same technique to (b), we have
The graph is a circle with center at [math](- 6, 1)[/math] and radius 0; i.e., it is just the point [math](- 6, 1)[/math]. We may say that the graph consists of the single point, although we sometimes describe it as a point circle. The equation of (c) gives different results:
For any two real numbers [math]x[/math] and [math]y[/math], the numbers [math](x-2)^2[/math] and [math](y-\frac{5}{2})^2[/math] must both be nonnegative, while [math]-\frac{4}{7}[/math] is certainly negative. Hence there are no points in the plane satisfying this equation. However, the form of the last of the three equivalent equations is that of the equation of a circle, and we sometimes say that the graph is an imaginary circle with center at [math](2, \frac{5}{2})[/math] and radius [math]\frac{1}{2}\sqrt{-7}[/math].
Equation (d) requires a bit more manipulation:
The graph is a circle with center at [math](\frac{3}{2}, -\frac{5}{3})[/math] and radius [math]\sqrt7[/math].
\medskip
By completing the square, as in the above examples, one can show that any equation of the form
is an equation of a circle of positive radius if and only if [math]a \neq 0[/math] and [math]b^2 + c^2 \gt 4ad[/math]. The circle is also the intersection of a right circular cone with a plane perpendicular to the axis of the cone. If the plane passes through the vertex of the cone, the intersection is a point. We can use the techniques of the calculus, as well as our knowledge of Euclidean geometry, to write an equation for a circle or for a line tangent to a circle, from given geometric conditions. Example
Write an equation of the line which is tangent to the graph of [math](x + 3)^2 + (y - 4)^2 = 25[/math] at (1, 7). We may find the slope by use of the derivative, differentiating implicitly and remembering that one interpretation of the derivative is the slope of the tangent: [math]2(x + 3) + 2(y - 4)y' = 0[/math]; hence [math]y' = - \frac{x + 3}{y - 4}[/math]. The slope Or the tangent is [math]-\frac{1 + 3}{7 - 4} = - \frac{4}{3}[/math]. We may also find the slope of the tangent by noting first that the radius to (1, 7) has slope [math]\frac{7-4}{1- (-3)}= \frac{3}{4}[/math] and then by remembering that the tangent is perpendicular to the radius and hence has slope [math]-\frac{4}{3}[/math]. Thus the tangent line has equation [math]y-7 = - \frac{4}{3}(x-1)[/math] or [math]4x + 3y = 25[/math].
\end{exercise}
General references
Doyle, Peter G. (2008). "Crowell and Slesnick's Calculus with Analytic Geometry" (PDF). Retrieved Oct 29, 2024.