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Ellipse - PLEASE HELP!!! (1 Viewer)
- Thread starter Sunyata
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Mature Lamb
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The normal to the ellipse x^2/a^2 + y^2/b^2 = 1 at P(x1, y1) meets the x-axis in N and the Y-axis in G. Prove PN/NG = (1-e^2)/e^2
1. get equation of normal to the ellipse at P
- differentiate the equation of the ellipse with respect to x, then negative reciprocal of dy/dx for gradient of normal, then point gradient formula with P(x1, y1) to end up with:
a^2x / x1 - b^2y / y1 = a^2 - b^2
2. solve for x = 0 and y = 0 for points N and G
when y = 0, x = x1(a^2-b^2)/a^2
.'. N (x1(a^2-b^2)/a^2, 0)
when x = 0, y = -y1(a^2-b^2)/b^2
.'. G (0, -y1(a^2-b^2)/b^2)
3. P, N and G are on the same line, so..
using division of a line with a given ratio formula, prove that N divides line segment PG in ratio (1-e^2) : e^2 by showing the coordinates of N
NOTE:
from b^2 = a^2(1-e^2),
e^2 = (a^2 - b^2) / a^2
xn = (e^2.x1 + (1-e^2).0) / (1-e^2) - e^2
= e^2.x1
= x1(a^2-b^2) / a^2
which is the x co-ordinate of N
Do the same for the y-coordinate of N and prove that it's equal to 0.
P.S. sorry for the messy solutions.. I don't know how to work LaTeX equation editor
1. get equation of normal to the ellipse at P
- differentiate the equation of the ellipse with respect to x, then negative reciprocal of dy/dx for gradient of normal, then point gradient formula with P(x1, y1) to end up with:
a^2x / x1 - b^2y / y1 = a^2 - b^2
2. solve for x = 0 and y = 0 for points N and G
when y = 0, x = x1(a^2-b^2)/a^2
.'. N (x1(a^2-b^2)/a^2, 0)
when x = 0, y = -y1(a^2-b^2)/b^2
.'. G (0, -y1(a^2-b^2)/b^2)
3. P, N and G are on the same line, so..
using division of a line with a given ratio formula, prove that N divides line segment PG in ratio (1-e^2) : e^2 by showing the coordinates of N
NOTE:
from b^2 = a^2(1-e^2),
e^2 = (a^2 - b^2) / a^2
xn = (e^2.x1 + (1-e^2).0) / (1-e^2) - e^2
= e^2.x1
= x1(a^2-b^2) / a^2
which is the x co-ordinate of N
Do the same for the y-coordinate of N and prove that it's equal to 0.
P.S. sorry for the messy solutions.. I don't know how to work LaTeX equation editor
Last edited:
There's a faster and less messy solution.
You want to prove PN/NG = (1-e^2)/e^2
Find your coordinate G
which is (0, [-y1(a^2-b^2)]/b^2)
Let B be the foot of the perpendicular for P to the y axis
So , B is (0,y1)
Draw it out and you can see that PN/NG = BO / BG by ratio of intercepts on a parallel line.
It becomes much simpler now as you dont need to use distance formula.
BO = y1
OG = [y1 (a^2-b^2)]/b^2
BO / OG = b^2/(a^2-b^2)
= b^2/a^2e^2 <=== (e^2 = 1-b^2/a^2)
= (b^2/a^2) x (1/e^2)
= (1-e^2) / e^2
Sorry its hard to read, latex isnt working =\
You want to prove PN/NG = (1-e^2)/e^2
Find your coordinate G
which is (0, [-y1(a^2-b^2)]/b^2)
Let B be the foot of the perpendicular for P to the y axis
So , B is (0,y1)
Draw it out and you can see that PN/NG = BO / BG by ratio of intercepts on a parallel line.
It becomes much simpler now as you dont need to use distance formula.
BO = y1
OG = [y1 (a^2-b^2)]/b^2
BO / OG = b^2/(a^2-b^2)
= b^2/a^2e^2 <=== (e^2 = 1-b^2/a^2)
= (b^2/a^2) x (1/e^2)
= (1-e^2) / e^2
Sorry its hard to read, latex isnt working =\
Mature Lamb
wats goin on
- Joined
- May 14, 2009
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- 1,117
- Gender
- Male
- HSC
- 2010
- Uni Grad
- 2015
What are the triangles involved?
I'll post my solution tomorrow. It's way too late for that now...