Center ( - 2, 1 ), a = 4, b = 2,
Foci = 
Vertices = ( - 2, 1 ± 4 ) = ( - 2, 5 ) and ( - 2, - 3 )
The distance from the center to a vertex is 1, so a = 1.
The distance from the center to a focus is 2, so c = 2.
Since the square of c equals the sums of the squares of a
and b, b must equal the square root of 3.
Since a focus lies below the center, this is a vertical hyperbola.
The distance from the center to a vertex is 3, so a = 3.
The distance from the center to a focus is 5, so c = 5.
Since the square of c equals the sums of the squares of a
and b, b = 4.
Since the center, vertices and foci lie on the same horizontal line,
this is a horizontal hyperbola.
The distance from V1 to F1
equals the distance from V2 to to F2.
The distance from V1 to F2
equals 2a plus the distance from V2
to F2,
which is the same as 2a plus the distance form V1
to F1.
So the distance from V1 to F2
minus the distance from V1 to F1
equals 2a.
Likewise, the distance from V2 to F1 minus the distance from V2 to F2 equals 2a.
Center ( 1, -1 ), vertices ( 1, -1 ± 5 ), ( 1 ± 3, -1
), or ( 1, 4 ), ( 1, - 6 ), ( 4, - 1 ), ( - 2, -1 )
Since this is a vertical ellipse, the foci are ( 1, - 1 ± 4 ) = ( 1, 3 ) and ( 1, - 5 ).
A major vertex lies 3 units below the center, so a = 3. A minor vertex lies 1 unit to the right of the center, so b = 1, and the ellipse is vertical. Thus
The focus is two units above the center, so c = 2 and the ellipse is vertical. A major vertex is four units below the center, so a = 4. Since the square of c equals the difference between the squares of a and b, it follows that b equals the square root of 12, or twice the square root of 3. In any event, the square of b is 12. Thus the equation is
The distance from the center to the focus is 1, so c = 1.
The distance from the center to a major vertex is 7, so a =
7.
The square of c equals the square of a minus the square
of b, so the square of b equals 48. So b equals four
times the square root of three.
The distance from the center to a focus is 3, so c = 3.
The distance from the center to a minor vertex is 4, so b =
4.
The square of c equals the square of a minus the square
of b, so the square of a is 25. So a equals five.
Since a minor axis lies above the center, the ellipse is horizontal.
Since the sum of the distances from V3 to F1 and V3 to F2 is 2a and since the distance from V3 to F1 equals the distance from V3 to F2, the distance from V3 to F2 equals a. Since a is the hypotenuse of a right triangle with sides b and c, then the realtionship between a, b and c is determined by the Pythagorean Theorem.
a2 = b2 + c2
The distance from V1 to F1 equals the distance from F2 to V2, so the sum of the distance of V1 to F1 plus the distance from V1 to F2 equals the sum of the distances from V1 to F2 plus the distance from V2 to F2, which is just the distance from V1 to V2, which is a.
The distance from F1 to V3 and from F1 to V4 is the same as the distance from the center to V1, which equals a.
y2 + 4 y = 12 x - 40
y2 + 4 y + 4 = 12 x - 36
( y + 2 )2 = 12 ( x - 3 )
The vertex is ( 3, - 2 ). Since 4 p = 12, p = 3. So the focus is 3 units to the right of the vertex at the point ( 6, - 2 ). The endpoints of the focal chord lie 2 p = 6 units above and below the focus, so the endpoints are at ( 6, 4 ) and ( 6, - 8 ). The directrix is the vertical line three units to the left of the vertex, so itís equations is x = 0. The directrix is the y-axis.
The focus lies 2 units below the vertex, so p = - 2 and the parabola is vertical. The endpoints of the focal chord lie | 2 p | units from the focus at right angles to the axis of the parabola, so they are at points ( - 4, - 2 ) and ( 4, - 2 ).
x2 = - 8 y
The focus lies two units to the right of the vertex, so p = 2
and the parabola is horizontal. The endpoints of the focal chord lie a
distance | 2 p | above and below the focus at points ( 1, 7 ) and
( 1, - 1 ).
( y - 3 )2 = 8 ( x + 1 )
The focus lies 2 units above the vertex, so the parabola is vertical and p = 2. The endpoints of the focal chord lie | 2 p | to the left and right of the focus at points ( - 4, 2 ) and ( 4, 2 ).
x2 = 8 y
Exercise 9.1.1
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