• Congratulations to the Class of 2024 on your results!
    Let us know how you went here
    Got a question about your uni preferences? Ask us here

Conics Question (1 Viewer)

kev-kun

Member
Joined
Mar 24, 2011
Messages
157
Location
Sydney, Australia
Gender
Male
HSC
2014
P is a point on the ellipse x^2/a^2 + y^2/b^2 =1 with centre O. line drawn from O, parallel to the tangent to the ellipse at P, meets the ellipse at Q. Prove that the area of the triangle OPQ is independent of the position P.

Found this question quite tough :/ Any help is appreciated ^^
 

Trebla

Administrator
Administrator
Joined
Feb 16, 2005
Messages
8,401
Gender
Male
HSC
2006
P is a point on the ellipse x^2/a^2 + y^2/b^2 =1 with centre O. line drawn from O, parallel to the tangent to the ellipse at P, meets the ellipse at Q. Prove that the area of the triangle OPQ is independent of the position P.

Found this question quite tough :/ Any help is appreciated ^^
Let the points have the parametric coordinates and .

I will use the perpendicular distance approach. The length of OP is given by



The equation of OP is given by



Hence the perpendicular distance (denoted as d) between Q and OP is given by



The area of the triangle (denoted as A) is therefore given by



BUT we haven't yet used the fact that OQ is parallel to the tangent at P. This gives the condition that



Therefore



which is independent of the positions of P (and Q)
 
Last edited:

kev-kun

Member
Joined
Mar 24, 2011
Messages
157
Location
Sydney, Australia
Gender
Male
HSC
2014
Ohh thanks for the help ^^ But just one question what did you mean in:
BUT we haven't yet used the fact that OQ is parallel to the tangent at P. This gives the condition that
Not sure what you did there.
 

Trebla

Administrator
Administrator
Joined
Feb 16, 2005
Messages
8,401
Gender
Male
HSC
2006
Ohh thanks for the help ^^ But just one question what did you mean in:
BUT we haven't yet used the fact that OQ is parallel to the tangent at P. This gives the condition that
Not sure what you did there.
I just equated the gradients of the tangent and the line OQ
 

Users Who Are Viewing This Thread (Users: 0, Guests: 1)

Top