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Conic Sections
Conic Sections We continue with the graphs of Ax2 + By2 + Cx + Dy = E, where A, B, C, D, and E are numbers (A or B β‰  0).
Conic Sections We continue with the graphs of Ax2 + By2 + Cx + Dy = E, where A, B, C, D, and E are numbers (A or B β‰  0). Their graphs are the conic sections as shown below.
Conic Sections We continue with the graphs of Ax2 + By2 + Cx + Dy = E, where A, B, C, D, and E are numbers (A or B β‰  0). Their graphs are the conic sections as shown below. Circles and ellipses are enclosed.
Conic Sections We continue with the graphs of Ax2 + By2 + Cx + Dy = E, where A, B, C, D, and E are numbers (A or B β‰  0). Their graphs are the conic sections as shown below. Circles and ellipses are enclosed.
Conic Sections We continue with the graphs of Ax2 + By2 + Cx + Dy = E, where A, B, C, D, and E are numbers (A or B β‰  0). Their graphs are the conic sections as shown below. If the equation Ax2 + By2 + Cx + Dy = E has A = B so it’s of the form Ax2 + Ay2 + Cx + Dy = E, Circles and ellipses are enclosed.
Conic Sections We continue with the graphs of Ax2 + By2 + Cx + Dy = E, where A, B, C, D, and E are numbers (A or B β‰  0). Their graphs are the conic sections as shown below. If the equation Ax2 + By2 + Cx + Dy = E has A = B so it’s of the form Ax2 + Ay2 + Cx + Dy = E, dividing by A, we obtain 1x2 + 1y2 + #x + #y = #, Circles and ellipses are enclosed.
Conic Sections We continue with the graphs of Ax2 + By2 + Cx + Dy = E, where A, B, C, D, and E are numbers (A or B β‰  0). Their graphs are the conic sections as shown below. If the equation Ax2 + By2 + Cx + Dy = E has A = B so it’s of the form Ax2 + Ay2 + Cx + Dy = E, dividing by A, we obtain 1x2 + 1y2 + #x + #y = #, and its graph is a circle. Circles and ellipses are enclosed.
Conic Sections We continue with the graphs of Ax2 + By2 + Cx + Dy = E, where A, B, C, D, and E are numbers (A or B β‰  0). Their graphs are the conic sections as shown below. If the equation Ax2 + By2 + Cx + Dy = E has A = B so it’s of the form Ax2 + Ay2 + Cx + Dy = E, dividing by A, we obtain 1x2 + 1y2 + #x + #y = #, and its graph is a circle. Circles and ellipses are enclosed. Circles: 1x2 + 1y2 + #x + #y = #
Conic Sections If an equation Ax2 + By2 + Cx + Dy = E has A β‰  B, but A and B having the same sign, Circles and ellipses are enclosed. Circles: 1x2 + 1y2 + #x + #y = #
Conic Sections If an equation Ax2 + By2 + Cx + Dy = E has A β‰  B, but A and B having the same sign, after dividing by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. Circles and ellipses are enclosed. Circles: 1x2 + 1y2 + #x + #y = #
Conic Sections If an equation Ax2 + By2 + Cx + Dy = E has A β‰  B, but A and B having the same sign, after dividing by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. This is an ellipse. Circles and ellipses are enclosed. Circles: 1x2 + 1y2 + #x + #y = #
Conic Sections If an equation Ax2 + By2 + Cx + Dy = E has A β‰  B, but A and B having the same sign, after dividing by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. This is an ellipse. Circles and ellipses are enclosed. Circles: 1x2 + 1y2 + #x + #y = # Ellipses: 1x2 + ry2 + #x + #y = # (r > 0)
Conic Sections If an equation Ax2 + By2 + Cx + Dy = E has A β‰  B, but A and B having the same sign, after dividing by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. This is an ellipse. Geometrically, the ellipses are β€œsquashed” circles and the r controls the compression or extension factor along the vertical or the y-direction of the circles. Circles and ellipses are enclosed. Circles: 1x2 + 1y2 + #x + #y = # Ellipses: 1x2 + ry2 + #x + #y = # (r > 0)
Conic Sections If an equation Ax2 + By2 + Cx + Dy = E has A β‰  B, but A and B having the same sign, after dividing by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. This is an ellipse. Geometrically, the ellipses are β€œsquashed” circles and the r controls the compression or extension factor along the vertical or the y-direction of the circles. Circles and ellipses are enclosed. Circles: 1x2 + 1y2 + #x + #y = # Ellipses: 1x2 + ry2 + #x + #y = # Ellipses also are horizontally stretched or compressed circles. (r > 0)
Conic Sections If an equation Ax2 + By2 + Cx + Dy = E has A β‰  B, but A and B having the same sign, after dividing by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. This is an ellipse. Geometrically, the ellipses are β€œsquashed” circles and the r controls the compression or extension factor along the vertical or the y-direction of the circles. Let's look at ellipses. Circles and ellipses are enclosed. Circles: 1x2 + 1y2 + #x + #y = # Ellipses: 1x2 + ry2 + #x + #y = # Ellipses also are horizontally stretched or compressed circles. (r > 0)
Ellipses
Ellipses Given two fixed points (called foci), F2 F1
Ellipses Given two fixed points (called foci), an ellipse is the set of points whose sum of the distances to the foci is a constant. F2 F1
F2 F1 Ellipses Given two fixed points (called foci), an ellipse is the set of points whose sum of the distances to the foci is a constant.
F2 F1 P Q R ( If P, Q, and R are any points on an ellipse, Ellipses Given two fixed points (called foci), an ellipse is the set of points whose sum of the distances to the foci is a constant.
F2 F1 P Q R p1 p2 ( If P, Q, and R are any points on an ellipse, then p1 + p2 Ellipses Given two fixed points (called foci), an ellipse is the set of points whose sum of the distances to the foci is a constant.
F2 F1 P Q R p1 p2 ( If P, Q, and R are any points on an ellipse, then p1 + p2 = q1 + q2 q1 q2 Ellipses Given two fixed points (called foci), an ellipse is the set of points whose sum of the distances to the foci is a constant.
F2 F1 P Q R p1 p2 ( If P, Q, and R are any points on an ellipse, then p1 + p2 = q1 + q2 = r1 + r2 q1 q2 r2 r1 Ellipses Given two fixed points (called foci), an ellipse is the set of points whose sum of the distances to the foci is a constant.
F2 F1 P Q R p1 p2 ( If P, Q, and R are any points on an ellipse, then p1 + p2 = q1 + q2 = r1 + r2 = a constant ) q1 q2 r2 r1 Ellipses Given two fixed points (called foci), an ellipse is the set of points whose sum of the distances to the foci is a constant.
F2 F1 P Q R p1 p2 ( If P, Q, and R are any points on an ellipse, then p1 + p2 = q1 + q2 = r1 + r2 = a constant ) q1 q2 r2 r1 Ellipses An ellipse also has a center (h, k ); (h, k) (h, k) Given two fixed points (called foci), an ellipse is the set of points whose sum of the distances to the foci is a constant.
F2 F1 P Q R p1 p2 ( If P, Q, and R are any points on an ellipse, then p1 + p2 = q1 + q2 = r1 + r2 = a constant ) q1 q2 r2 r1 Ellipses An ellipse also has a center (h, k ); it has two axes, the semi-major (long) (h, k) Semi Major axis (h, k) Given two fixed points (called foci), an ellipse is the set of points whose sum of the distances to the foci is a constant. Semi Major axis
F2 F1 P Q R p1 p2 ( If P, Q, and R are any points on an ellipse, then p1 + p2 = q1 + q2 = r1 + r2 = a constant ) q1 q2 r2 r1 Ellipses An ellipse also has a center (h, k ); it has two axes, the semi-major (long) and the semi-minor (short) axes. (h, k) Semi Major axis (h, k) Semi Minor axis Given two fixed points (called foci), an ellipse is the set of points whose sum of the distances to the foci is a constant. Semi Major axis Semi Minor axis
These semi-axes correspond to the important radii of the ellipse. Ellipses
These semi-axes correspond to the important radii of the ellipse. From the center, the horizontal length is called the x- radius Ellipses x-radius x-radius
y-radius These semi-axes correspond to the important radii of the ellipse. From the center, the horizontal length is called the x- radius and the vertical length the y-radius. Ellipses x-radius x-radius y-radius
These semi-axes correspond to the important radii of the ellipse. From the center, the horizontal length is called the x- radius and the vertical length the y-radius. Ellipses x-radius The general equation for ellipses is Ax2 + By2 + Cx + Dy = E where A and B are the same sign but different numbers. x-radius y-radius y-radius
These semi-axes correspond to the important radii of the ellipse. From the center, the horizontal length is called the x- radius and the vertical length the y-radius. Ellipses x-radius The general equation for ellipses is Ax2 + By2 + Cx + Dy = E where A and B are the same sign but different numbers. Using completing the square, such equations may be transformed into the standard form of ellipses below. x-radius y-radius y-radius
(x – h)2 (y – k)2 a2 b2 Ellipses + = 1 The Standard Form (of Ellipses)
(x – h)2 (y – k)2 a2 b2 Ellipses + = 1 This has to be 1. The Standard Form (of Ellipses)
(x – h)2 (y – k)2 a2 b2 (h, k) is the center. Ellipses + = 1 This has to be 1. The Standard Form (of Ellipses)
(x – h)2 (y – k)2 a2 b2 x-radius = a (h, k) is the center. Ellipses + = 1 This has to be 1. The Standard Form (of Ellipses)
(x – h)2 (y – k)2 a2 b2 x-radius = a y-radius = b (h, k) is the center. Ellipses + = 1 This has to be 1. The Standard Form (of Ellipses)
(x – h)2 (y – k)2 a2 b2 x-radius = a y-radius = b (h, k) is the center. Ellipses + = 1 This has to be 1. Example A. Find the center, major and minor axes. Draw and label the top, bottom, right and left most points. (x – 3)2 (y + 1)2 42 22 + = 1 The Standard Form (of Ellipses)
(x – h)2 (y – k)2 a2 b2 x-radius = a y-radius = b (h, k) is the center. Ellipses + = 1 This has to be 1. Example A. Find the center, major and minor axes. Draw and label the top, bottom, right and left most points. (x – 3)2 (y + 1)2 42 22 + = 1 The center is (3, –1). The Standard Form (of Ellipses)
(x – h)2 (y – k)2 a2 b2 x-radius = a y-radius = b (h, k) is the center. Ellipses + = 1 This has to be 1. Example A. Find the center, major and minor axes. Draw and label the top, bottom, right and left most points. (x – 3)2 (y + 1)2 42 22 + = 1 The center is (3, –1). The x-radius is 4. The Standard Form (of Ellipses)
(x – h)2 (y – k)2 a2 b2 x-radius = a y-radius = b (h, k) is the center. Ellipses + = 1 This has to be 1. Example A. Find the center, major and minor axes. Draw and label the top, bottom, right and left most points. (x – 3)2 (y + 1)2 42 22 + = 1 The center is (3, –1). The x-radius is 4. The y-radius is 2. The Standard Form (of Ellipses)
(x – h)2 (y – k)2 a2 b2 x-radius = a y-radius = b (h, k) is the center. Ellipses + = 1 This has to be 1. (3, -1) Example A. Find the center, major and minor axes. Draw and label the top, bottom, right and left most points. (x – 3)2 (y + 1)2 42 22 + = 1 The center is (3, –1). The x-radius is 4. The y-radius is 2. The Standard Form (of Ellipses)
(x – h)2 (y – k)2 a2 b2 x-radius = a y-radius = b (h, k) is the center. Ellipses + = 1 This has to be 1. (3, -1) (7, -1) Example A. Find the center, major and minor axes. Draw and label the top, bottom, right and left most points. (x – 3)2 (y + 1)2 42 22 + = 1 The center is (3, –1). The x-radius is 4. The y-radius is 2. So the right point is (7, –1), The Standard Form (of Ellipses)
(x – h)2 (y – k)2 a2 b2 x-radius = a y-radius = b (h, k) is the center. Ellipses + = 1 This has to be 1. (3, -1) (7, -1) (3, 1) Example A. Find the center, major and minor axes. Draw and label the top, bottom, right and left most points. (x – 3)2 (y + 1)2 42 22 + = 1 The center is (3, –1). The x-radius is 4. The y-radius is 2. So the right point is (7, –1), the top point is (3, 1), The Standard Form (of Ellipses)
(x – h)2 (y – k)2 a2 b2 x-radius = a y-radius = b (h, k) is the center. Ellipses + = 1 This has to be 1. (3, -1) (7, -1) (-1, -1) (3, -3) (3, 1) Example A. Find the center, major and minor axes. Draw and label the top, bottom, right and left most points. (x – 3)2 (y + 1)2 42 22 + = 1 The center is (3, –1). The x-radius is 4. The y-radius is 2. So the right point is (7, –1), the top point is (3, 1), the left and bottom points are (–1, –1) and (3, –3). The Standard Form (of Ellipses)
(x – h)2 (y – k)2 a2 b2 x-radius = a y-radius = b (h, k) is the center. Ellipses + = 1 This has to be 1. (3, -1) (7, -1) (-1, -1) (3, -3) (3, 1) Example A. Find the center, major and minor axes. Draw and label the top, bottom, right and left most points. (x – 3)2 (y + 1)2 42 22 + = 1 The center is (3, –1). The x-radius is 4. The y-radius is 2. So the right point is (7, –1), the top point is (3, 1), the left and bottom points are (–1, –1) and (3, –3). The Standard Form (of Ellipses)
Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Ellipses
Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: Ellipses
Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 Ellipses
Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 Ellipses
Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square Ellipses
Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square 9(x2 – 2x + 1 ) + 4(y2 – 4y + 4 ) = 11 Ellipses
Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square 9(x2 – 2x + 1 ) + 4(y2 – 4y + 4 ) = 11 +9 Ellipses
Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square 9(x2 – 2x + 1 ) + 4(y2 – 4y + 4 ) = 11 +9 +16 Ellipses
Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square 9(x2 – 2x + 1 ) + 4(y2 – 4y + 4 ) = 11 + 9 + 16 +9 +16 Ellipses
Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square 9(x2 – 2x + 1 ) + 4(y2 – 4y + 4 ) = 11 + 9 + 16 +9 +16 Ellipses 9(x – 1)2 + 4(y – 2)2 = 36
9(x – 1)2 4(y – 2)2 36 36 Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square 9(x2 – 2x + 1 ) + 4(y2 – 4y + 4 ) = 11 + 9 + 16 +9 +16 + = 1 Ellipses 9(x – 1)2 + 4(y – 2)2 = 36 divide by 36 to get 1
9(x – 1)2 4(y – 2)2 36 4 36 9 Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square 9(x2 – 2x + 1 ) + 4(y2 – 4y + 4 ) = 11 + 9 + 16 +9 +16 + = 1 Ellipses 9(x – 1)2 + 4(y – 2)2 = 36 divide by 36 to get 1
9(x – 1)2 4(y – 2)2 36 4 36 9 Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square 9(x2 – 2x + 1 ) + 4(y2 – 4y + 4 ) = 11 + 9 + 16 +9 +16 + = 1 (x – 1)2 (y – 2)2 22 32 + = 1 Ellipses 9(x – 1)2 + 4(y – 2)2 = 36 divide by 36 to get 1
9(x – 1)2 4(y – 2)2 36 4 36 9 Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square 9(x2 – 2x + 1 ) + 4(y2 – 4y + 4 ) = 11 + 9 + 16 +9 +16 + = 1 (x – 1)2 (y – 2)2 22 32 + = 1 Ellipses 9(x – 1)2 + 4(y – 2)2 = 36 divide by 36 to get 1 Hence, Center: (1, 2), x-radius is 2, y-radius is 3.
9(x – 1)2 4(y – 2)2 36 4 36 9 Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square 9(x2 – 2x + 1 ) + 4(y2 – 4y + 4 ) = 11 + 9 + 16 +9 +16 + = 1 (x – 1)2 (y – 2)2 22 32 + = 1 Ellipses 9(x – 1)2 + 4(y – 2)2 = 36 divide by 36 to get 1 Hence, Center: (1, 2), x-radius is 2, y-radius is 3. (-1, 2) (3, 2) (1, 5) (1, -1) (1, 2)
Conic Sections Recall that after dividing the equations of ellipses Ax2 + By2 + Cx + Dy = E by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0.
Conic Sections Recall that after dividing the equations of ellipses Ax2 + By2 + Cx + Dy = E by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. The number r controls the compression or extension factor along the vertical or the y-direction of the circles.
Conic Sections Recall that after dividing the equations of ellipses Ax2 + By2 + Cx + Dy = E by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. The number r controls the compression or extension factor along the vertical or the y-direction of the circles. Let’s use 1x2 + ry2 = 1, ellipses centered at (0,0) as an example.
Conic Sections Recall that after dividing the equations of ellipses Ax2 + By2 + Cx + Dy = E by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. The number r controls the compression or extension factor along the vertical or the y-direction of the circles. Let’s use 1x2 + ry2 = 1, ellipses centered at (0,0) as an example. r = 1 1x2 + 1y2 = 1 1 1
Conic Sections Recall that after dividing the equations of ellipses Ax2 + By2 + Cx + Dy = E by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. The number r controls the compression or extension factor along the vertical or the y-direction of the circles. Let’s use 1x2 + ry2 = 1, ellipses centered at (0,0) as an example. r = 1 1x2 + 1y2 = 1 1x2 + y2 = 1 1 4 r = 1/4 1 1 2 1
Conic Sections Recall that after dividing the equations of ellipses Ax2 + By2 + Cx + Dy = E by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. The number r controls the compression or extension factor along the vertical or the y-direction of the circles. Let’s use 1x2 + ry2 = 1, ellipses centered at (0,0) as an example. r = 1 1x2 + 1y2 = 1 1x2 + y2 = 1 1 4 1x2 + y2 = 1 1 9 r = 1/9 r = 1/4 1 1 1 3 2 1
Conic Sections Recall that after dividing the equations of ellipses Ax2 + By2 + Cx + Dy = E by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. The number r controls the compression or extension factor along the vertical or the y-direction of the circles. Let’s use 1x2 + ry2 = 1, ellipses centered at (0,0) as an example. r = 1 1x2 + 1y2 = 1 1x2 + y2 = 1 1 4 1x2 + y2 = 1 1 9 1x2 + 4y2 = 1 1x2 + 9y2 = 1 r = 4 r = 1/9 r = 1/4 r = 9 1 1 1 1 1 3 2 1/2 1 1/3
Conic Sections Recall that after dividing the equations of ellipses Ax2 + By2 + Cx + Dy = E by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. The number r controls the compression or extension factor along the vertical or the y-direction of the circles. Let’s use 1x2 + ry2 = 1, ellipses centered at (0,0) as an example. r = 1 1x2 + 1y2 = 1 1x2 + y2 = 1 1 4 1x2 + y2 = 1 1 9 1x2 + 4y2 = 1 1x2 + 9y2 = 1 r = 4 r = 1/9 r = 1/4 r = 9 1 1 1 1 1 3 2 1/2 1 1/3 Ex. Verify that for 1x2 + ry2 = 1 the y-radius is 1/√r, i.e. the vertical rescale-factor is 1/√r (from the circle).
Ellipses
Ellipses B. Complete the square of the following equations. Find the center and the radii of the ellipses. Draw and label the 4 cardinal points. 1. x2 + 4y2 = 1 2. 9x2 + 4y2 = 1 3. 4x2 + y2/9 = 1 4. x2/4 + y2/9 = 1 5. 0.04x2 + 0.09y2 = 1 6. 2.25x2 + 0.25y2 = 1 7. x2 + 4y2 = 100 8. x2 + 49y2 = 36 9. 4x2 + y2/9 = 9 10. x2/4 + 9y2 = 100 11. x2 + 4y2 + 8y = –3 12. y2 – 8x + 4x2 + 24y = 21 13. 4x2 – 8x + 25y2 + 16x = 71 14. 9y2 – 18y + 25x2 + 100x = 116
(Answers to odd problems) Exercise A. 1. + = 1 x2 y2 4 9 (2,0) (0,3) (0,-3) (-2,0) 3. + = 1 (x + 1)2 (y + 3)2 4 16 (3,-3) (-5,-3) (-1,-5) (-1,-1) Ellipses 5. + = 1 (x + 4)2 (y + 2)2 16 1 (-3,-2) (-5,-2) (-4,-6) (-4,2) 7. + = 1 (x + 1)2 (y – 2)2 3 2 (-1, 0.27) (0.41, 2) (-1,3.73) (-2.47, 2)
9. + = 1 (x – 3.1)2 (y + 2.3)2 0.09 1.44 Ellipses (3.1, -2.6) (3.1, -2) (4.3, -2.3) (1.9, -2.3) Exercise B. 1. Center: (0,0) x radius: 1 y radius: 0.5 3. Center: (0,0) x radius: 0.5 y radius: 3 (0, -0.5) (0, 0.5) (-1, 0) (0, -3) (0, 3) (0.5, 0) (-0.5, 0) (1, 0)
Ellipses 5. Center: (0,0) x radius: 5 y radius: 10/3 (-5, 0) (0, 3.33) (0, -3.33) (5, 0) (0, 5) (0, -5) (-10, 0) (10, 0) 7. Center: (0,0) x radius: 10 y radius: 5 (1.5, 0) (-1.5, 0) (0, 9) (0, -9) (1, -1) (-1, -1) (0, 0.5) (0, -1.5) 9. Center: (0,0) x radius: 1.5 y radius: 9 11. Center: (0,-1) x radius: 1 y radius: 0.5 13. Center: (–1,0) x radius: οƒ–18.75 y radius: οƒ–3 (–1,0) (–1,–3) (–1,οƒ–3) (–1+ οƒ–18.75,0) (–1–18.75,0)

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18 ellipses x

  • 2. Conic Sections We continue with the graphs of Ax2 + By2 + Cx + Dy = E, where A, B, C, D, and E are numbers (A or B β‰  0).
  • 3. Conic Sections We continue with the graphs of Ax2 + By2 + Cx + Dy = E, where A, B, C, D, and E are numbers (A or B β‰  0). Their graphs are the conic sections as shown below.
  • 4. Conic Sections We continue with the graphs of Ax2 + By2 + Cx + Dy = E, where A, B, C, D, and E are numbers (A or B β‰  0). Their graphs are the conic sections as shown below. Circles and ellipses are enclosed.
  • 5. Conic Sections We continue with the graphs of Ax2 + By2 + Cx + Dy = E, where A, B, C, D, and E are numbers (A or B β‰  0). Their graphs are the conic sections as shown below. Circles and ellipses are enclosed.
  • 6. Conic Sections We continue with the graphs of Ax2 + By2 + Cx + Dy = E, where A, B, C, D, and E are numbers (A or B β‰  0). Their graphs are the conic sections as shown below. If the equation Ax2 + By2 + Cx + Dy = E has A = B so it’s of the form Ax2 + Ay2 + Cx + Dy = E, Circles and ellipses are enclosed.
  • 7. Conic Sections We continue with the graphs of Ax2 + By2 + Cx + Dy = E, where A, B, C, D, and E are numbers (A or B β‰  0). Their graphs are the conic sections as shown below. If the equation Ax2 + By2 + Cx + Dy = E has A = B so it’s of the form Ax2 + Ay2 + Cx + Dy = E, dividing by A, we obtain 1x2 + 1y2 + #x + #y = #, Circles and ellipses are enclosed.
  • 8. Conic Sections We continue with the graphs of Ax2 + By2 + Cx + Dy = E, where A, B, C, D, and E are numbers (A or B β‰  0). Their graphs are the conic sections as shown below. If the equation Ax2 + By2 + Cx + Dy = E has A = B so it’s of the form Ax2 + Ay2 + Cx + Dy = E, dividing by A, we obtain 1x2 + 1y2 + #x + #y = #, and its graph is a circle. Circles and ellipses are enclosed.
  • 9. Conic Sections We continue with the graphs of Ax2 + By2 + Cx + Dy = E, where A, B, C, D, and E are numbers (A or B β‰  0). Their graphs are the conic sections as shown below. If the equation Ax2 + By2 + Cx + Dy = E has A = B so it’s of the form Ax2 + Ay2 + Cx + Dy = E, dividing by A, we obtain 1x2 + 1y2 + #x + #y = #, and its graph is a circle. Circles and ellipses are enclosed. Circles: 1x2 + 1y2 + #x + #y = #
  • 10. Conic Sections If an equation Ax2 + By2 + Cx + Dy = E has A β‰  B, but A and B having the same sign, Circles and ellipses are enclosed. Circles: 1x2 + 1y2 + #x + #y = #
  • 11. Conic Sections If an equation Ax2 + By2 + Cx + Dy = E has A β‰  B, but A and B having the same sign, after dividing by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. Circles and ellipses are enclosed. Circles: 1x2 + 1y2 + #x + #y = #
  • 12. Conic Sections If an equation Ax2 + By2 + Cx + Dy = E has A β‰  B, but A and B having the same sign, after dividing by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. This is an ellipse. Circles and ellipses are enclosed. Circles: 1x2 + 1y2 + #x + #y = #
  • 13. Conic Sections If an equation Ax2 + By2 + Cx + Dy = E has A β‰  B, but A and B having the same sign, after dividing by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. This is an ellipse. Circles and ellipses are enclosed. Circles: 1x2 + 1y2 + #x + #y = # Ellipses: 1x2 + ry2 + #x + #y = # (r > 0)
  • 14. Conic Sections If an equation Ax2 + By2 + Cx + Dy = E has A β‰  B, but A and B having the same sign, after dividing by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. This is an ellipse. Geometrically, the ellipses are β€œsquashed” circles and the r controls the compression or extension factor along the vertical or the y-direction of the circles. Circles and ellipses are enclosed. Circles: 1x2 + 1y2 + #x + #y = # Ellipses: 1x2 + ry2 + #x + #y = # (r > 0)
  • 15. Conic Sections If an equation Ax2 + By2 + Cx + Dy = E has A β‰  B, but A and B having the same sign, after dividing by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. This is an ellipse. Geometrically, the ellipses are β€œsquashed” circles and the r controls the compression or extension factor along the vertical or the y-direction of the circles. Circles and ellipses are enclosed. Circles: 1x2 + 1y2 + #x + #y = # Ellipses: 1x2 + ry2 + #x + #y = # Ellipses also are horizontally stretched or compressed circles. (r > 0)
  • 16. Conic Sections If an equation Ax2 + By2 + Cx + Dy = E has A β‰  B, but A and B having the same sign, after dividing by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. This is an ellipse. Geometrically, the ellipses are β€œsquashed” circles and the r controls the compression or extension factor along the vertical or the y-direction of the circles. Let's look at ellipses. Circles and ellipses are enclosed. Circles: 1x2 + 1y2 + #x + #y = # Ellipses: 1x2 + ry2 + #x + #y = # Ellipses also are horizontally stretched or compressed circles. (r > 0)
  • 18. Ellipses Given two fixed points (called foci), F2 F1
  • 19. Ellipses Given two fixed points (called foci), an ellipse is the set of points whose sum of the distances to the foci is a constant. F2 F1
  • 20. F2 F1 Ellipses Given two fixed points (called foci), an ellipse is the set of points whose sum of the distances to the foci is a constant.
  • 21. F2 F1 P Q R ( If P, Q, and R are any points on an ellipse, Ellipses Given two fixed points (called foci), an ellipse is the set of points whose sum of the distances to the foci is a constant.
  • 22. F2 F1 P Q R p1 p2 ( If P, Q, and R are any points on an ellipse, then p1 + p2 Ellipses Given two fixed points (called foci), an ellipse is the set of points whose sum of the distances to the foci is a constant.
  • 23. F2 F1 P Q R p1 p2 ( If P, Q, and R are any points on an ellipse, then p1 + p2 = q1 + q2 q1 q2 Ellipses Given two fixed points (called foci), an ellipse is the set of points whose sum of the distances to the foci is a constant.
  • 24. F2 F1 P Q R p1 p2 ( If P, Q, and R are any points on an ellipse, then p1 + p2 = q1 + q2 = r1 + r2 q1 q2 r2 r1 Ellipses Given two fixed points (called foci), an ellipse is the set of points whose sum of the distances to the foci is a constant.
  • 25. F2 F1 P Q R p1 p2 ( If P, Q, and R are any points on an ellipse, then p1 + p2 = q1 + q2 = r1 + r2 = a constant ) q1 q2 r2 r1 Ellipses Given two fixed points (called foci), an ellipse is the set of points whose sum of the distances to the foci is a constant.
  • 26. F2 F1 P Q R p1 p2 ( If P, Q, and R are any points on an ellipse, then p1 + p2 = q1 + q2 = r1 + r2 = a constant ) q1 q2 r2 r1 Ellipses An ellipse also has a center (h, k ); (h, k) (h, k) Given two fixed points (called foci), an ellipse is the set of points whose sum of the distances to the foci is a constant.
  • 27. F2 F1 P Q R p1 p2 ( If P, Q, and R are any points on an ellipse, then p1 + p2 = q1 + q2 = r1 + r2 = a constant ) q1 q2 r2 r1 Ellipses An ellipse also has a center (h, k ); it has two axes, the semi-major (long) (h, k) Semi Major axis (h, k) Given two fixed points (called foci), an ellipse is the set of points whose sum of the distances to the foci is a constant. Semi Major axis
  • 28. F2 F1 P Q R p1 p2 ( If P, Q, and R are any points on an ellipse, then p1 + p2 = q1 + q2 = r1 + r2 = a constant ) q1 q2 r2 r1 Ellipses An ellipse also has a center (h, k ); it has two axes, the semi-major (long) and the semi-minor (short) axes. (h, k) Semi Major axis (h, k) Semi Minor axis Given two fixed points (called foci), an ellipse is the set of points whose sum of the distances to the foci is a constant. Semi Major axis Semi Minor axis
  • 29. These semi-axes correspond to the important radii of the ellipse. Ellipses
  • 30. These semi-axes correspond to the important radii of the ellipse. From the center, the horizontal length is called the x- radius Ellipses x-radius x-radius
  • 31. y-radius These semi-axes correspond to the important radii of the ellipse. From the center, the horizontal length is called the x- radius and the vertical length the y-radius. Ellipses x-radius x-radius y-radius
  • 32. These semi-axes correspond to the important radii of the ellipse. From the center, the horizontal length is called the x- radius and the vertical length the y-radius. Ellipses x-radius The general equation for ellipses is Ax2 + By2 + Cx + Dy = E where A and B are the same sign but different numbers. x-radius y-radius y-radius
  • 33. These semi-axes correspond to the important radii of the ellipse. From the center, the horizontal length is called the x- radius and the vertical length the y-radius. Ellipses x-radius The general equation for ellipses is Ax2 + By2 + Cx + Dy = E where A and B are the same sign but different numbers. Using completing the square, such equations may be transformed into the standard form of ellipses below. x-radius y-radius y-radius
  • 34. (x – h)2 (y – k)2 a2 b2 Ellipses + = 1 The Standard Form (of Ellipses)
  • 35. (x – h)2 (y – k)2 a2 b2 Ellipses + = 1 This has to be 1. The Standard Form (of Ellipses)
  • 36. (x – h)2 (y – k)2 a2 b2 (h, k) is the center. Ellipses + = 1 This has to be 1. The Standard Form (of Ellipses)
  • 37. (x – h)2 (y – k)2 a2 b2 x-radius = a (h, k) is the center. Ellipses + = 1 This has to be 1. The Standard Form (of Ellipses)
  • 38. (x – h)2 (y – k)2 a2 b2 x-radius = a y-radius = b (h, k) is the center. Ellipses + = 1 This has to be 1. The Standard Form (of Ellipses)
  • 39. (x – h)2 (y – k)2 a2 b2 x-radius = a y-radius = b (h, k) is the center. Ellipses + = 1 This has to be 1. Example A. Find the center, major and minor axes. Draw and label the top, bottom, right and left most points. (x – 3)2 (y + 1)2 42 22 + = 1 The Standard Form (of Ellipses)
  • 40. (x – h)2 (y – k)2 a2 b2 x-radius = a y-radius = b (h, k) is the center. Ellipses + = 1 This has to be 1. Example A. Find the center, major and minor axes. Draw and label the top, bottom, right and left most points. (x – 3)2 (y + 1)2 42 22 + = 1 The center is (3, –1). The Standard Form (of Ellipses)
  • 41. (x – h)2 (y – k)2 a2 b2 x-radius = a y-radius = b (h, k) is the center. Ellipses + = 1 This has to be 1. Example A. Find the center, major and minor axes. Draw and label the top, bottom, right and left most points. (x – 3)2 (y + 1)2 42 22 + = 1 The center is (3, –1). The x-radius is 4. The Standard Form (of Ellipses)
  • 42. (x – h)2 (y – k)2 a2 b2 x-radius = a y-radius = b (h, k) is the center. Ellipses + = 1 This has to be 1. Example A. Find the center, major and minor axes. Draw and label the top, bottom, right and left most points. (x – 3)2 (y + 1)2 42 22 + = 1 The center is (3, –1). The x-radius is 4. The y-radius is 2. The Standard Form (of Ellipses)
  • 43. (x – h)2 (y – k)2 a2 b2 x-radius = a y-radius = b (h, k) is the center. Ellipses + = 1 This has to be 1. (3, -1) Example A. Find the center, major and minor axes. Draw and label the top, bottom, right and left most points. (x – 3)2 (y + 1)2 42 22 + = 1 The center is (3, –1). The x-radius is 4. The y-radius is 2. The Standard Form (of Ellipses)
  • 44. (x – h)2 (y – k)2 a2 b2 x-radius = a y-radius = b (h, k) is the center. Ellipses + = 1 This has to be 1. (3, -1) (7, -1) Example A. Find the center, major and minor axes. Draw and label the top, bottom, right and left most points. (x – 3)2 (y + 1)2 42 22 + = 1 The center is (3, –1). The x-radius is 4. The y-radius is 2. So the right point is (7, –1), The Standard Form (of Ellipses)
  • 45. (x – h)2 (y – k)2 a2 b2 x-radius = a y-radius = b (h, k) is the center. Ellipses + = 1 This has to be 1. (3, -1) (7, -1) (3, 1) Example A. Find the center, major and minor axes. Draw and label the top, bottom, right and left most points. (x – 3)2 (y + 1)2 42 22 + = 1 The center is (3, –1). The x-radius is 4. The y-radius is 2. So the right point is (7, –1), the top point is (3, 1), The Standard Form (of Ellipses)
  • 46. (x – h)2 (y – k)2 a2 b2 x-radius = a y-radius = b (h, k) is the center. Ellipses + = 1 This has to be 1. (3, -1) (7, -1) (-1, -1) (3, -3) (3, 1) Example A. Find the center, major and minor axes. Draw and label the top, bottom, right and left most points. (x – 3)2 (y + 1)2 42 22 + = 1 The center is (3, –1). The x-radius is 4. The y-radius is 2. So the right point is (7, –1), the top point is (3, 1), the left and bottom points are (–1, –1) and (3, –3). The Standard Form (of Ellipses)
  • 47. (x – h)2 (y – k)2 a2 b2 x-radius = a y-radius = b (h, k) is the center. Ellipses + = 1 This has to be 1. (3, -1) (7, -1) (-1, -1) (3, -3) (3, 1) Example A. Find the center, major and minor axes. Draw and label the top, bottom, right and left most points. (x – 3)2 (y + 1)2 42 22 + = 1 The center is (3, –1). The x-radius is 4. The y-radius is 2. So the right point is (7, –1), the top point is (3, 1), the left and bottom points are (–1, –1) and (3, –3). The Standard Form (of Ellipses)
  • 48. Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Ellipses
  • 49. Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: Ellipses
  • 50. Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 Ellipses
  • 51. Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 Ellipses
  • 52. Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square Ellipses
  • 53. Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square 9(x2 – 2x + 1 ) + 4(y2 – 4y + 4 ) = 11 Ellipses
  • 54. Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square 9(x2 – 2x + 1 ) + 4(y2 – 4y + 4 ) = 11 +9 Ellipses
  • 55. Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square 9(x2 – 2x + 1 ) + 4(y2 – 4y + 4 ) = 11 +9 +16 Ellipses
  • 56. Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square 9(x2 – 2x + 1 ) + 4(y2 – 4y + 4 ) = 11 + 9 + 16 +9 +16 Ellipses
  • 57. Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square 9(x2 – 2x + 1 ) + 4(y2 – 4y + 4 ) = 11 + 9 + 16 +9 +16 Ellipses 9(x – 1)2 + 4(y – 2)2 = 36
  • 58. 9(x – 1)2 4(y – 2)2 36 36 Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square 9(x2 – 2x + 1 ) + 4(y2 – 4y + 4 ) = 11 + 9 + 16 +9 +16 + = 1 Ellipses 9(x – 1)2 + 4(y – 2)2 = 36 divide by 36 to get 1
  • 59. 9(x – 1)2 4(y – 2)2 36 4 36 9 Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square 9(x2 – 2x + 1 ) + 4(y2 – 4y + 4 ) = 11 + 9 + 16 +9 +16 + = 1 Ellipses 9(x – 1)2 + 4(y – 2)2 = 36 divide by 36 to get 1
  • 60. 9(x – 1)2 4(y – 2)2 36 4 36 9 Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square 9(x2 – 2x + 1 ) + 4(y2 – 4y + 4 ) = 11 + 9 + 16 +9 +16 + = 1 (x – 1)2 (y – 2)2 22 32 + = 1 Ellipses 9(x – 1)2 + 4(y – 2)2 = 36 divide by 36 to get 1
  • 61. 9(x – 1)2 4(y – 2)2 36 4 36 9 Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square 9(x2 – 2x + 1 ) + 4(y2 – 4y + 4 ) = 11 + 9 + 16 +9 +16 + = 1 (x – 1)2 (y – 2)2 22 32 + = 1 Ellipses 9(x – 1)2 + 4(y – 2)2 = 36 divide by 36 to get 1 Hence, Center: (1, 2), x-radius is 2, y-radius is 3.
  • 62. 9(x – 1)2 4(y – 2)2 36 4 36 9 Example B. Put 9x2 + 4y2 – 18x – 16y = 11 into the standard form. Find the center and the x&y radii. Draw and label the top, bottom, right, left most points. Group the x’s and the y’s: 9x2 – 18x + 4y2 – 16y = 11 factor out the square-coefficients 9(x2 – 2x ) + 4(y2 – 4y ) = 11 complete the square 9(x2 – 2x + 1 ) + 4(y2 – 4y + 4 ) = 11 + 9 + 16 +9 +16 + = 1 (x – 1)2 (y – 2)2 22 32 + = 1 Ellipses 9(x – 1)2 + 4(y – 2)2 = 36 divide by 36 to get 1 Hence, Center: (1, 2), x-radius is 2, y-radius is 3. (-1, 2) (3, 2) (1, 5) (1, -1) (1, 2)
  • 63. Conic Sections Recall that after dividing the equations of ellipses Ax2 + By2 + Cx + Dy = E by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0.
  • 64. Conic Sections Recall that after dividing the equations of ellipses Ax2 + By2 + Cx + Dy = E by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. The number r controls the compression or extension factor along the vertical or the y-direction of the circles.
  • 65. Conic Sections Recall that after dividing the equations of ellipses Ax2 + By2 + Cx + Dy = E by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. The number r controls the compression or extension factor along the vertical or the y-direction of the circles. Let’s use 1x2 + ry2 = 1, ellipses centered at (0,0) as an example.
  • 66. Conic Sections Recall that after dividing the equations of ellipses Ax2 + By2 + Cx + Dy = E by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. The number r controls the compression or extension factor along the vertical or the y-direction of the circles. Let’s use 1x2 + ry2 = 1, ellipses centered at (0,0) as an example. r = 1 1x2 + 1y2 = 1 1 1
  • 67. Conic Sections Recall that after dividing the equations of ellipses Ax2 + By2 + Cx + Dy = E by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. The number r controls the compression or extension factor along the vertical or the y-direction of the circles. Let’s use 1x2 + ry2 = 1, ellipses centered at (0,0) as an example. r = 1 1x2 + 1y2 = 1 1x2 + y2 = 1 1 4 r = 1/4 1 1 2 1
  • 68. Conic Sections Recall that after dividing the equations of ellipses Ax2 + By2 + Cx + Dy = E by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. The number r controls the compression or extension factor along the vertical or the y-direction of the circles. Let’s use 1x2 + ry2 = 1, ellipses centered at (0,0) as an example. r = 1 1x2 + 1y2 = 1 1x2 + y2 = 1 1 4 1x2 + y2 = 1 1 9 r = 1/9 r = 1/4 1 1 1 3 2 1
  • 69. Conic Sections Recall that after dividing the equations of ellipses Ax2 + By2 + Cx + Dy = E by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. The number r controls the compression or extension factor along the vertical or the y-direction of the circles. Let’s use 1x2 + ry2 = 1, ellipses centered at (0,0) as an example. r = 1 1x2 + 1y2 = 1 1x2 + y2 = 1 1 4 1x2 + y2 = 1 1 9 1x2 + 4y2 = 1 1x2 + 9y2 = 1 r = 4 r = 1/9 r = 1/4 r = 9 1 1 1 1 1 3 2 1/2 1 1/3
  • 70. Conic Sections Recall that after dividing the equations of ellipses Ax2 + By2 + Cx + Dy = E by A, we obtain 1x2 + ry2 + #x + #y = #, with r > 0. The number r controls the compression or extension factor along the vertical or the y-direction of the circles. Let’s use 1x2 + ry2 = 1, ellipses centered at (0,0) as an example. r = 1 1x2 + 1y2 = 1 1x2 + y2 = 1 1 4 1x2 + y2 = 1 1 9 1x2 + 4y2 = 1 1x2 + 9y2 = 1 r = 4 r = 1/9 r = 1/4 r = 9 1 1 1 1 1 3 2 1/2 1 1/3 Ex. Verify that for 1x2 + ry2 = 1 the y-radius is 1/√r, i.e. the vertical rescale-factor is 1/√r (from the circle).
  • 72. Ellipses B. Complete the square of the following equations. Find the center and the radii of the ellipses. Draw and label the 4 cardinal points. 1. x2 + 4y2 = 1 2. 9x2 + 4y2 = 1 3. 4x2 + y2/9 = 1 4. x2/4 + y2/9 = 1 5. 0.04x2 + 0.09y2 = 1 6. 2.25x2 + 0.25y2 = 1 7. x2 + 4y2 = 100 8. x2 + 49y2 = 36 9. 4x2 + y2/9 = 9 10. x2/4 + 9y2 = 100 11. x2 + 4y2 + 8y = –3 12. y2 – 8x + 4x2 + 24y = 21 13. 4x2 – 8x + 25y2 + 16x = 71 14. 9y2 – 18y + 25x2 + 100x = 116
  • 73. (Answers to odd problems) Exercise A. 1. + = 1 x2 y2 4 9 (2,0) (0,3) (0,-3) (-2,0) 3. + = 1 (x + 1)2 (y + 3)2 4 16 (3,-3) (-5,-3) (-1,-5) (-1,-1) Ellipses 5. + = 1 (x + 4)2 (y + 2)2 16 1 (-3,-2) (-5,-2) (-4,-6) (-4,2) 7. + = 1 (x + 1)2 (y – 2)2 3 2 (-1, 0.27) (0.41, 2) (-1,3.73) (-2.47, 2)
  • 74. 9. + = 1 (x – 3.1)2 (y + 2.3)2 0.09 1.44 Ellipses (3.1, -2.6) (3.1, -2) (4.3, -2.3) (1.9, -2.3) Exercise B. 1. Center: (0,0) x radius: 1 y radius: 0.5 3. Center: (0,0) x radius: 0.5 y radius: 3 (0, -0.5) (0, 0.5) (-1, 0) (0, -3) (0, 3) (0.5, 0) (-0.5, 0) (1, 0)
  • 75. Ellipses 5. Center: (0,0) x radius: 5 y radius: 10/3 (-5, 0) (0, 3.33) (0, -3.33) (5, 0) (0, 5) (0, -5) (-10, 0) (10, 0) 7. Center: (0,0) x radius: 10 y radius: 5 (1.5, 0) (-1.5, 0) (0, 9) (0, -9) (1, -1) (-1, -1) (0, 0.5) (0, -1.5) 9. Center: (0,0) x radius: 1.5 y radius: 9 11. Center: (0,-1) x radius: 1 y radius: 0.5 13. Center: (–1,0) x radius: οƒ–18.75 y radius: οƒ–3 (–1,0) (–1,–3) (–1,οƒ–3) (–1+ οƒ–18.75,0) (–1–18.75,0)