NVAMediumJEE 2023Conic Sections (Parabola, Ellipse, Hyperbola)

JEE Mathematics 2023 Question with Solution

The vertices of a hyperbola HH are (±6,0)({\pm}6, 0) and its eccentricity is 52\frac{\sqrt{5}}{2}. Let NN be the normal to HH at a point in the first quadrant and parallel to the line 2x+y=22\sqrt{2}x + y = 2\sqrt{2}. If dd is the length of the line segment of NN between HH and the yy-axis, then d2d^2 is equal to _____.

Answer

Correct answer:216

Step-by-step solution

Standard Method

Given: The vertices are (±6,0)({\pm}6,0), so a=6a=6 and a2=36a^2=36. The eccentricity is e=52e=\frac{\sqrt{5}}{2}.

Find: The value of d2d^2, where dd is the length of the segment of the normal between the hyperbola and the yy-axis.

Sketch of a hyperbola opening left and right, with right branch point P in first quadrant, vertical y-axis through origin, point K on y-axis above origin, and segment KP labeled d.

For the hyperbola

x236y29=1\frac{x^2}{36}-\frac{y^2}{9}=1

we use the standard parametric point

P=(asecθ,btanθ)P=(a\sec\theta, b\tan\theta)

so here

P=(6secθ,3tanθ).P=(6\sec\theta, 3\tan\theta).

Using

e2=1+b2a2e^2=1+\frac{b^2}{a^2}

we get

54=1+b236\frac{5}{4}=1+\frac{b^2}{36} 14=b236\frac{1}{4}=\frac{b^2}{36} b2=9.b^2=9.

Hence the hyperbola is

x236y29=1.\frac{x^2}{36}-\frac{y^2}{9}=1.

The equation of the normal at parameter θ\theta is

6xcosθ+3ycotθ=45.6x\cos\theta + 3y\cot\theta = 45.

Its slope is

2sinθ.-2\sin\theta.

The given line 2x+y=22\sqrt{2}x+y=2\sqrt{2} has slope

2.-\sqrt{2}.

Since the normal is parallel to this line,

2sinθ=2.-2\sin\theta=-\sqrt{2}.

So,

sinθ=22\sin\theta=\frac{\sqrt{2}}{2}

which gives

θ=π4\theta=\frac{\pi}{4}

for the point in the first quadrant.

Substituting θ=π4\theta=\frac{\pi}{4} in the normal,

6xcosπ4+3ycotπ4=456x\cos\frac{\pi}{4}+3y\cot\frac{\pi}{4}=45 32x+3y=453\sqrt{2}x+3y=45 2x+y=15.\sqrt{2}x+y=15.

Thus the normal meets the yy-axis at

K=(0,15).K=(0,15).

Also,

P=(6secπ4,3tanπ4)=(62,3).P=(6\sec\tfrac{\pi}{4}, 3\tan\tfrac{\pi}{4})=(6\sqrt{2},3).

Therefore,

d2=PK2=(620)2+(315)2d^2=PK^2=(6\sqrt{2}-0)^2+(3-15)^2 =72+144=216.=72+144=216.

Hence, the required value is 216216.

Using eccentricity and normal slope

Given: a=6a=6 and e=52e=\frac{\sqrt{5}}{2}.

Find: The square of the segment length on the normal from the point of contact to the yy-axis.

First compute bb from eccentricity:

e2=1+b2a2e^2=1+\frac{b^2}{a^2} 54=1+b236\frac{5}{4}=1+\frac{b^2}{36} b2=9.b^2=9.

So the hyperbola is

x236y29=1.\frac{x^2}{36}-\frac{y^2}{9}=1.

For the point P=(asecθ,btanθ)P=(a\sec\theta,b\tan\theta) on the hyperbola, the normal is

axcosθ+bycotθ=a2+b2.ax\cos\theta + by\cot\theta = a^2+b^2.

With a=6,b=3a=6, b=3, this becomes

6xcosθ+3ycotθ=45.6x\cos\theta + 3y\cot\theta = 45.

The slope of this line is

m=6cosθ3cotθ=2sinθ.m=-\frac{6\cos\theta}{3\cot\theta}=-2\sin\theta.

Since the normal is parallel to 2x+y=22\sqrt{2}x+y=2\sqrt{2}, its slope is 2-\sqrt{2}. Hence

2sinθ=2-2\sin\theta=-\sqrt{2} sinθ=12.\sin\theta=\frac{1}{\sqrt{2}}.

In the first quadrant,

θ=π4.\theta=\frac{\pi}{4}.

Now

P=(6secπ4,3tanπ4)=(62,3).P=(6\sec\tfrac{\pi}{4},3\tan\tfrac{\pi}{4})=(6\sqrt{2},3).

The normal becomes

2x+y=15,\sqrt{2}x+y=15,

so on the yy-axis x=0x=0 and therefore

K=(0,15).K=(0,15).

Finally,

d2=PK2=(62)2+(315)2=72+144=216.d^2=PK^2=(6\sqrt{2})^2+(3-15)^2=72+144=216.

Therefore, the answer is 216216.

Common mistakes

  • Using the ellipse relation e=1b2a2e=\sqrt{1-\frac{b^2}{a^2}} instead of the hyperbola relation e=1+b2a2e=\sqrt{1+\frac{b^2}{a^2}} is incorrect. For a hyperbola, always use the plus sign to find b2b^2.

  • Taking the slope of the line 2x+y=22\sqrt{2}x+y=2\sqrt{2} as 2\sqrt{2} is wrong. Writing it as y=2x+22y=-\sqrt{2}x+2\sqrt{2} shows the slope is actually 2-\sqrt{2}.

  • Using the tangent point form instead of the normal equation leads to the wrong intercept on the yy-axis. The problem specifically asks for the segment on the normal, so the normal equation must be used.

Practice more Conic Sections (Parabola, Ellipse, Hyperbola) questions

Get unlimited AI-adaptive practice, mastery tracking, and an AI tutor that explains every step — free to start.

Related questions