Conics: Parabolas: Introduction To form a parabola according to ancient Greek definitions, you would start with a line and a point off to one side. The line is called the "directrix"; the point is called the "focus". The parabola is the curve formed from all the points (x, y) that are equidistant from the directrix and the focus. The line perpendicular to the directrix and passing through the focus (that is, the line that splits the parabola up the middle) is called the "axis of symmetry". The point on this axis which is exactly midway between the focus and the directrix is the "vertex"; the vertex is the point where the parabola changes direction. "regular", or vertical, parabola (in blue), with the focus (in green) "inside" the parabola, the directrix (in purple) below the graph, the axis of symmetry (in red) passing through the focus and perpendicular to the directrix, and the vertex (in orange) on the graph "sideways", or horizontal, parabola (in blue), with the focus (in green) "inside" the parabola, the directrix (in purple) to the left of the graph, the axis of symmetry (in red) passing through the focus and perpendicular to the directrix, and the vertex (in orange) on the graph
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Conics: Parabolas: IntroductionTo form a parabola according to ancient Greek definitions, you would start with a line and a point off to one side. The line is called the "directrix"; the point is called the "focus". The parabola is the curve formed from all the points (x, y) that are equidistant from the directrix and the focus. The line perpendicular to the directrix and passing through the focus (that is, the line that splits the parabola up the middle) is called the "axis of symmetry". The point on this axis which is exactly midway between the focus and the directrix is the "vertex"; the vertex is the point where the parabola changes direction.
"regular", or vertical, parabola (in blue), with the focus (in green) "inside" the parabola, the directrix (in purple) below the graph, the axis of symmetry (in red) passing through the focus and perpendicular to the directrix, and the vertex (in orange) on the graph
"sideways", or horizontal, parabola (in blue), with the focus (in green) "inside" the parabola, the directrix (in purple) to the left of the graph, the axis of symmetry (in red) passing through the focus and perpendicular to the directrix, and the vertex (in orange) on the graph
The name "parabola" is derived from a New Latin term that means something similar to "compare" or "balance", and refers to the fact that the distance from the parabola to the focus is always equal to (that is, is always in balance with) the distance from the parabola to the directrix. In practical terms, you'll probably only need to know that the vertex is exactly midway between the directrix and the focus.In previous contexts, your parabolas have either been "right side up" or "upside down" graph, depending on whether the leading coefficient was positive or negative, respectively. In the context of conics, however, you will also be working with "sideways" parabolas, parabolas whose axes of symmetry parallel the x-axis and which open to the right or to the left.
(–3))2, and the vertex is at (–3, 1). The coefficient of the unsquared part is –20, and this is also the value of 4p, so p = –5. Since the x part is squared and p is negative, then this is regular parabola that opens downward. This means that the directrix, being on the outside of the parabola, is five units above the vertex.vertex: (–3, 1); directrix: y = 6 Graph x2 = 4y and state the vertex, focus, axis of symmetry, and directrix.This is the same graphing that I've done in the past: y = (1/4)x2. So I'll do the graph as usual:
The vertex is obviously at the origin, but I need to "show" this "algebraically" by rearranging the given equation into the conics form: x2 = 4y (x – 0)2 = 4(y – 0) This rearrangement "shows" that the vertex is at (h, k) = (0, 0). The axis of symmetry is the vertical line right through the vertex: x = 0. (I can always check my graph, if I'm not sure about this.) The focus is "p" units from the vertex. Since the focus is "inside" the parabola and since this is a "right side up" graph, the focus has to be above the vertex.From the conics form of the equation, shown above, I look at what's multiplied on the unsquared part and see that 4p = 4, so p = 1. Then the focus is one unit above the vertex, at (0, 1), and the directrix is the horizontal line y = –1, one unit below the vertex.vertex: (0, 0); focus: (0, 1); axis of symmetry: x = 0; directrix: y = –1 Graph y2 + 10y + x + 25 = 0, and state the vertex, focus, axis of symmetry, and directrix.Since the y is squared in this equation, rather than the x, then this is a "sideways" parabola. To graph, I'll do my T-chart backwards, picking y-values first and then finding the corresponding x-values for x = –y2 – 10y – 25:
To convert the equation into conics form and find the exact vertex, etc, I'll need to convert the equation to perfect-square form. In this case, the squared side is already a perfect square, so: y2 + 10y + 25 = –x (y + 5)2 = –1(x – 0) This tells me that 4p = –1, so p = –1/4. Since the parabola opens to the left, then the focus is 1/4 units to the left of the vertex. I can see from the equation above that the vertex is at (h, k) = (0, –5), so then the focus must be at (–1/4, –5). The parabola is sideways, so the axis of symmetry is, too. The directrix, being perpendicular to the axis of symmetry, is then vertical, and is 1/4 units to the right of the vertex. Putting this all together, I get:vertex: (0, –5); focus: (–1/4, –5); axis of symmetry: y = –5; directrix: x = 1/4 Find the vertex and focus of y2 + 6y + 12x – 15 = 0The y part is squared, so this is a sideways parabola. I'll get the y stuff by itself on one side of the equation, and then complete the square to convert this to conics form.y2 + 6y – 15 = –12x y2 + 6y + 9 – 15 = –12x + 9 (y + 3)2 – 15 = –12x + 9 (y + 3)2 = –12x + 9 + 15 = –12x + 24 (y + 3)2 = –12(x – 2) (y – (–3))2 = 4(–3)(x – 2) Then the vertex is at (h, k) = (2, –3) and the value of p is –3. Since y is squared and p is negative, then this is a sideways parabola that opens to the left. This puts the focus 3 units to the left of the vertex. vertex: (2, –3); focus: (–1, –3) Write an equation for the parabola with focus at (0, –2) and directrix x = 2.The vertex is always halfway between the focus and the directrix, and the parabola always curves away from the directrix, so I'll do a quick graph showing the focus, the directrix, and a rough idea of where the parabola will go:
If you need to graph a sideways parabola in your graphing calculator (to check your work, for instance), you'll need to solve the equation for its two halves, and then graph the two halves as two separate functions. For instance, to view the graph of (y + 2)2 = –4(x – 1), you'd solve and graph as:
Don't expect the two halves of the graph to "meet in the middle" on your calculator screen; that's a higher degree of accuracy than the calculator can handle.In my experience, it is easier to remember the relationships between the vertex, focus, axis of symmetry, directrix, and the value of p, than to try to memorize the (often very long) list of formulas they give you. Do enough practice exercises that you have a good grasp of how these elements are related, and you should be successful with parabolas.
Conics: Ellipse: IntroductionAn ellipse, informally, is an oval or a "squished" circle. In "primitive" geometrical terms, an ellipse is the figure you can draw in the sand by the following process: Push two sticks into the sand. Take a piece of string and form a loop that is big enough to go around the two sticks and still have some slack. Take a third stick, hook it inside the string loop, pull the loop taut by pulling the stick away from the first two sticks, and drag that third stick through the sand at the furthest distance the loop will allow. The resulting shape drawn in the sand is an ellipse.Each of the two sticks you first pushed into the sand is a "focus" of the ellipse; the two together are called "foci" (FOH-siy). If you draw a line in the sand "through" these two sticks, from one end of the ellipse to the other, this will mark the "major" axis of the ellipse. The points where the major axis touches the ellipse are the "vertices" of the ellipse. The point midway between the two sticks is the "center" of the ellipse.
If you draw a line through this center, perpendicular to the major axis and from one side of the ellipse to the other, this will mark the "minor" axis. The points where the minor axis touches the ellipse are the "co-vertices". A half-axis, from the center out to the
ellipse, is called a "semi-major" or a "semi-minor" axis, depending on which axis you're taking half of.The distance from the center to either focus is the fixed value c. The distance from the center to a vertex is the fixed value a. The values of a and c will vary from one ellipse to another, but they are fixed for any given ellipse. I keep the meaning of these two letters straight by mispronouncing the phrase "foci for c" as "FOH-ciy foh SEE", to remind me that c relates to the focus. Then the other letter (a) is for the other type of point (the vertex).The length of the semi-major axis is a and the length of the whole major axis is 2a, and the distance between the foci is 2c. Okay, so now we've got relationships for a and c, which leads one to wonder, "What happened to b?" The three letters are related by the equation b2 = a2 – c2 or, alternatively (depending on your book or instructor), by the equation b2 + c2 = a2.(Proving the relationship requires pages and pages of algebraic computations, so just trust me that the equation is true. It can also be shown — painfully — that b is also the length of the semi-minor axis, so the distance across the ellipse in the "shorter" direction is 2b. Yes, the Pythagorean Theorem is involved in proving this stuff. Yes, these are the same letters used in the Pythagorean Theorem. No, this is not the same as the Pythagorean Theorem. Yes, this is very confusing. Accept it, make sure to memorize the relationship before the next test, and move on.)For a wider-than-tall ellipse with center at (h, k), having vertices a units to either side of the center and foci c units to either side of the center, the ellipse equation is:
For a taller-than-wide ellipse with center at (h, k), having vertices a units above and below the center and foci c units above and below the center, the ellipse equation is:
An ellipse equation, in conics form, is always "=1". Note that, in both equations above, the h always stayed with the x and the k always stayed with the y. The only thing that changed between the two equations was the placement of the a2 and the b2. The a2
always goes with the variable whose axis parallels the wider direction of the ellipse; the b2 always goes with the variable whose axis parallels the narrower direction. Looking at
the equations the other way, the larger denominator always gives you the value of a2, the smaller denominator always gives you the value of b2, and the two denominators together allow you to find the value of c2 and the orientation of the ellipse.
Ellipses are, by their nature, not "perfectly round" in the technical sense that circles are round. The measure of the amount by which an ellipse is "squished" away from being perfectly round is called the ellipse's "eccentricity", and the value of an ellipse's eccentricity is denoted as e = c/a. Since the foci are closer to the center than are the vertices, then c < a, so the value of e will always be less than 1. If an ellipse's foci are pulled inward toward the center, the ellipse will get progressively closer to being a circle. Continuing that process, if we let c = 0 (so the foci are actually at the center), this would correspond to e = 0, with the ellipse really being a circle. This tells us that the value of e for a true (non-circle) ellipse will always be more than 0. Putting this together, we see that 0 < e < 1 for any ellipse.When scientists refer to something (such as Pluto) as having an "eccentric" orbit, they don't mean that the orbit is "weird"; they mean that it's "far from being circular". In Pluto's case, its orbit actually crosses inside that of Neptune from time to time. The larger the value of e, the more "squished" the ellipse.A physical property of ellipses is that sound or light rays emanating from one focus will reflect back to the other focus. This property can be used, for instance, in medicine. A patient suffering from, say, gall stones can be placed next to a machine that emits shock waves away from the patient and into an elliptical bowl. The patient is carefully positioned so that the gall stones are at one focus of the ellipse, with a water-filled cushion between the machine and the patient allowing for efficient transmission of the shock waves. The machine emits waves from the other focus of the ellipse; these waves scatter harmlessly from the emitter into the elliptical bowl, bounce back from the bowl, and finally reconcentrate at the other focus (inside the patient). The shock waves reach full power only at the patient's focus, where they smash the stone into small enough pieces that the patient's body will be able to get rid of them on its own. The patient can go home the same day, having required no invasive surgeryYour first task will usually be to demonstrate that you can extract information about an ellipse from its equation, and also to graph a few ellipses. State the center, vertices, foci and eccentricity of the ellipse with general equation 16x2 + 25y2 = 400, and sketch the ellipse.To be able to read any information from this equation, I'll need to rearrange it to get "=1", so I'll divide through by 400. This gives me:
Since x2 = (x – 0)2 and y2 = (y – 0)2, the equation above is really:
To sketch the ellipse, I first draw the dots for the center and the endpoints of each axis:
Then I rough in a curvy line, rotating my paper as I go and eye-balling my curve for smoothness...
...and then I draw my "answer" as a heavier solid line.
center (0, 0), vertices (–5, 0) and (5, 0), foci (–3, 0) and (3, 0), and eccentricity 3/5You may find it helpful to do the roughing in with pencil, rotating the paper as you go around, and then draw your final graph in pen, carefully erasing your "rough draft" before you hand in your work. And always make sure your graph is neat and is large enough to be clear. State the center, foci, vertices, and co-vertices of the ellipse with equation 25x2 + 4y2 + 100x – 40y + 100 = 0. Also state the lengths of the two axes.I first have to rearrange this equation into conics form by completing the square and dividing through to get "=1". Once I've done that, I can read off the information I need from the equation.25x2 + 4y2 + 100x – 40y = –100 25x2 + 100x + 4y2 – 40y = –100 25(x2 + 4x ) + 4(y2 – 10y ) = –100 + 25( ) + 4( ) 25(x2 + 4x + 4) + 4(y2 – 10y + 25) = –100 + 25( 4 ) + 4( 25 ) 25(x + 2)2 + 4(y – 5)2 = –100 + 100 + 100 = 100
The larger demoninator is a2, and the y part of the equation has the larger denominator, so this ellipse will be taller than wide (to parallel the y-axis). Also, a2 = 25 and b2 = 4, so the equation b2 + c2 = a2 gives me 4 + c2 = 25, and c2 must equal 21. The center is clearly at the point (h, k) = (–2, 5). The vertices are a = 5 units above and below the center, at (–2, 0) and (–2, 10). The co-vertices are b = 2 units to either side of the center, at (–4, 5) and (0, 5). The major axis has length 2a = 10, and the minor axis has length 2b = 4. The foci are messy: they're sqrt[21] units above and below the center.
center (–2, 5), vertices (–2, 0) and (–2, 10), co-vertices (–4, 5) and (0, 5), foci
and , major axis length 10, minor axis length 4You'll also need to work the other way, finding the equation for an ellipse from a list of its properties.
Write an equation for the ellipse having one focus at (0, 3), a vertex at (0, 4), and its center at (0, 0).Since the focus and vertex are above and below each other, rather than side by side, I know that this ellipse must be taller than it is wide. Then a2 will go with the y part of the equation. Also, since the focus is 3 units above the center, then c = 3; since the vertex is 4 units above, then a = 4. The equation b2 = a2 – c2 gives me 16 – 9 = 7 = b2. (Since I wasn't asked for the length of the minor axis or the location of the co-vertices, I don't
equation: Write an equation for the ellipse centered at the origin, having a vertex at (0, –5) and containing the point (–2, 4).Since the vertex is 5 units below the center, then this vertex is taller than it is wide, and the a2 will go with the y part of the equation. Also, a = 5, so a2 = 25. I know that b2 = a2 – c2, but I don't know the values of b or c. However, I do have the values of h, k, and a, and also a set of values for x and y, those values being the point they gave me on the ellipse. So I'll set up the equation with everything I've got so far, and solve for b.
16b2 + 100 = 25b2 100 = 9b2 100/9 = b2 Then my equation is:
Write an equation for the ellipse having foci at (–2, 0) and (2, 0) and eccentricity e = 3/4.The center is between the two foci, so (h, k) = (0, 0). Since the foci are 2 units to either side of the center, then c = 2, this ellipse is wider than it is tall, and a2 will go with the x
part of the equation. I know that e = c/a, so 3/4 = 2/a. Solving the proportion, I get a = 8/3, so a2 = 64/9. The equation b2 = a2 – c2 gives me 64/9 – 4 = 64/9 – 36/9 = 28/9 = b2.
Now that I have values for a2 and b2, I can create my equation: A "whispering room" is one with an elliptically-arched ceiling. If someone stands at one focus of the ellipse and whispers something to his friend, the dispersed sound waves are reflected by the ceiling and concentrated at the other focus, allowing people across the room to clearly hear what he said. Suppose such gallery has a ceiling reaching twenty feet above the five-foot-high vertical walls at its tallest point (so the cross-section is half an ellipse topping two vertical lines at either end), and suppose the foci of the ellipse are thirty feet apart. What is the height of the ceiling above each "whispering point"?Since the ceiling is half of an ellipse (the top half, specifically), and since the foci will be on a line between the tops of the "straight" parts of the side walls, the foci will be five feet above the floor, which sounds about right for people talking and listening: five feet high is close to face-high on most adults. I'll center my ellipse above the origin, so (h, k) = (0, 5). The foci are thirty feet apart, so they're 15 units to either side of the center. In particular, c = 15. Since the elliptical part of the room's cross-section is twenty feet high above the center, and since this "shorter" direction is the semi-minor axis, then b = 20. The equation b2 = a2 – c2 gives me 400 = a2 – 225, so a2 = 625. Then the
equation for the elliptical ceiling is: I need to find the height of the ceiling above the foci. I prefer positive numbers, so I'll look at the focus to the right of the center. The height (from the ellipse's central line through its foci, up to the ceiling) will be the y-value of the ellipse when x = 15:
Then c = 188. If I set the center of my ellipse at the origin and make this a wider-than-tall ellipse, then I can put the Earth's center at the point (188, 0).(This means, by the way, that there isn't much difference between the circumference of the Earth and the path of the satellite. The center of the elliptical orbit is actually inside the Earth, and the ellipse, having an eccentricity of e = 188 / 4420, or about 0.04, is pretty close to being a circle.)The vertex closer to the end of the ellipse containing the Earth's center will be at 4420 units from the ellipse's center, or 4420 – 188 = 4232 units from the center of the Earth. Since the Earth's radius is 3960 units, then the altitude is 4232 – 3960 = 272. The other vertex is 4420 + 188 = 4608 units from the Earth's center, giving me an altitude of 4608 – 3960 = 648 units.The minimum altitude is 272 miles above the Earth; the maximum altitude is 648 miles above the Earth.
Conics: Hyperbolas: IntroductionHyperbolas don't come up much — at least not that I've noticed — in other math classes, but if you're covering conics, you'll need to know their basics. An hyperbola looks sort of like two mirrored parabolas, with the two "halves" being called "branches". Like an ellipse, an hyperbola has two foci and two vertices; unlike an ellipse, the foci in an hyperbola are further from the hyperbola's center than are its vertices:
The hyperbola is centered on a point (h, k), which is the "center" of the hyperbola. The point on each branch closest to the center is that branch's "vertex". The vertices are some fixed distance a from the center. The line going from one vertex, through the center, and ending at the other vertex is called the "transverse" axis. The "foci" of an hyperbola are "inside" each branch, and each focus is located some fixed distance c from the center. (This means that a < c for hyperbolas.) The values of a and c will vary from one hyperbola to another, but they will be fixed values for any given hyperbola.
For any point on an ellipse, the sum of the distances from that point to each of the foci is some fixed value; for any point on an hyperbola, it's the difference of the distances from the two foci that is fixed. Looking at the graph above and letting "the point" be one of the vertices, this fixed distance must be (the distance to the further focus) less (the distance to the nearer focus), or (a + c) – (c – a) = 2a. This fixed-difference property can used for determining locations: If two beacons are placed in known and fixed positions, the difference in the times at which their signals are received by, say, a ship at sea can tell the crew where they are.As with ellipses, there is a relationship between a, b, and c, and, as with ellipses, the computations are long and painful. So trust me that, for hyperbolas (where a < c), the relationship is c2 – a2 = b2 or, which means the same thing, c2 = b2 + a2. (Yes, the Pythagorean Theorem is used to prove this relationship. Yes, these are the same letters as are used in the Pythagorean Theorem. No, this is not the same thing as the Pythagorean Theorem. Yes, this is very confusing. Just memorize it, and move on.)
When the transverse axis is horizontal (in other words, when the center, foci, and vertices line up side by side, parallel to the x-axis), then the a2 goes with the x part of the hyperbola's equation, and the y part is subtracted.
When the transverse axis is vertical (in other words, when the center, foci, and vertices line up above and below each other, parallel to the y-axis), then the a2 goes with the y part of the hyperbola's
Note that the only difference in the asymptote equations above is in the slopes of the straight lines: If a2 is the denominator for the x part of the hyperbola's equation, then a is still in the denominator in the slope of the asymptotes' equations; if a2 goes with the y part of the hyperbola's equation, then a goes in the numerator of the slope in the asymptotes' equations.Hyperbolas can be fairly "straight" or else pretty "bendy":
hyperbola with an hyperbola with an
eccentricity of about 1.05 eccentricity of about 7.6
The measure of the amount of curvature is the "eccentricity" e, where e = c/a. Since the foci are further from the center of an hyperbola than are the vertices (so c > a for hyperbolas), then e > 1. Bigger values of e correspond to the "straighter" types of hyperbolas, while values closer to 1 correspond to hyperbolas whose graphs curve quickly away from their centers. Find the center, vertices, foci, eccentricity, and asymptotes of the hyperbola
with the given equation, and sketch: Since the y part of the equation is added, then the center, foci, and will be above and below the center (on a line paralleling the y-axis), rather than side by side.Looking at the denominators, I see that a2 = 25 and b2 = 144, so a = 5 and b = 12. The equation c2 – a2 = b2 tells me that c2 = 144 + 25 = 169, so c = 13, and the eccentricity is e = 13/5. Since x2 = (x – 0)2 and y2 = (y – 0)2, then the center is at (h, k) = (0, 0). The vertices and foci are above and below the center, so the foci are at (0, –13) and (0, 13), and the vertices are at (0, 5) and (0, –5).
Because the y part of the equation is dominant (being added, not subtracted), then the slope of the asymptotes has the a on top, so the slopes will be m = ± 5/12. To graph, I start with the center, and draw the asymptotes through it, using dashed lines:
Then I draw in the vertices, and rough in the graph, rotating the paper as necessary and "eye-balling" for smoothness:
Then I draw in the final graph as a neat, smooth, heavier line:
And the rest of my answer is:center (0, 0), vertices (0, –5) and (0, 5), foci (0, –13) and (0, 13),
eccentricity , and asymptotes Give the center, vertices, foci, and asymptotes for the hyperbola
center (–3, 2), vertices (–7, 2) and (1, 2), foci (–8, 2) and (2, 2),
and asymptotes Find the center, vertices, and asymptotes of the hyperbola with equation 4x2 – 5y2 + 40x – 30y – 45 = 0.To find the information I need, I'll first have to convert this equation to "conics" form by completing the square.4x2 + 40x – 5y2 – 30y = 45 4(x2 + 10x…..) – 5(y2 + 6……) = 45 + 4(…..) – 5(…..) 4(x2 + 10x + 25) – 5(y2 + 6y + 9) = 45 + 4(25) – 5(9) 4(x + 5)2 – 5(y + 3)2 = 45 + 100 – 45
Then the center is at (h, k) = (–5, –3). Since the x part of the equation is added, then the center, foci, and vertices lie on a horizontal line paralleling the x-axis; a2 = 25 and b2 = 20, so a = 5 and b = 2sqrt[5]. The equation a2 + b2 = c2 gives me c2 = 25 + 20 = 45, so c = sqrt[45] = 3sqrt[5]. The slopes of the two asymptotes will be m = ± (2/5)sqrt[5]. Then my complete answer is:center (–5, –3), vertices (–10, –3) and (0, –3),
foci and , and asymptotes If I had needed to graph this hyperbola, I'd have used a decimal approximation of ± 0.89442719... for the slope, but would have rounded the value to something reasonable like m = ± 0.9.*Find an equation for the hyperbola with center (2, 3), vertex (0, 3), and focus (5, 3).The center, focus, and vertex all lie on the horizontal line y = 3 (that is, they're side by side on a line paralleling the x-axis), so the branches must be side by side, and the x part of the equation must be added. The a2 will go with the x part of the equation, and the y part will be subtracted. The vertex is 2 units from the center, so a = 2; the focus is 3 units from the center, so c = 3. Then a2 + b2 = c2 gives me b2 = 9 – 4 = 5. I don't need to bother with the value of b itself, since they only asked me for the equation, which is:
Find an equation for the hyperbola with center (0, 0), vertex (0, 5), and asymptotes y = ± (5/3)x.The vertex and the center are both on the vertical line x = 0 (that is, on the y-axis), so the hyperbola's branches are above and below each other, not side by side. Then the y part of the equation will be added, and will get the a2 as its denominator. Also, the slopes of the two asymptotes will be of the form m = ± a/b.The vertex they gave me is 5 units above the center, so a = 5 and a2 = 25. The slope of the asymptotes (ignoring the "plus-minus" part) is a/b = 5/3 = 5/b, so b = 3 and b2 = 9.
And this is all I need in order to find my equation:
16. Then a2 + b2 = c2 tells me that b2 = 25 – 16 = 9, and my equation is: Find an equation for the hyperbola with vertices at (–2, 15) and (–2, –1), and having eccentricity e = 17/8.The vertices are above and below each other, so the center, foci, and vertices lie on a vertical line paralleling the y-axis. Then the a2 will go with the y part of the hyperbola equation, and the x part will be subtracted.The center is midway between the two vertices, so (h, k) = (–2, 7). The vertices are 8 units above and below the center, so a = 8 and a2 = 64. The eccentricity is e = c/a = 17/8 = c/8, so c = 17 and c2 = 289. The equation a2 + b2 = c2 tells me that b2 = 289 – 64 = 225. Then my equation is: