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JEE Main · MCQ · Coordinate Geometry · Parabola · Locus
MCQ · Mathematics · Parabola · Locus
Q. Let $y^2 = 12x$ be the parabola with its vertex at $O$. Let $P$ be a point on the parabola and $A$ be a point on the $x$-axis such that $\angle OPA = 90°$. Then the locus of the centroid of such triangles $OPA$ is:
A$y^2 – 4x + 8 = 0$
B$y^2 – 2x + 8 = 0$ ✓
C$y^2 – 9x + 6 = 0$
D$y^2 – 6x + 4 = 0$
✅ Correct Answer: (B) $y^2 – 2x + 8 = 0$
Step-by-Step Solution
1
Set up coordinates using parametric form of $y^2 = 12x$
Compare $y^2=12x$ with $y^2=4ax$:
$$4a = 12 \implies a = 3$$
Parametric point on parabola: $(at^2, 2at) = (3t^2,\, 6t)$
$O = (0,\,0)$ (vertex)
$P = (3t^2,\,6t)$
$A = (\lambda,\,0)$ on x-axis
2
Apply $\angle OPA = 90°$ — vectors from $P$ must be perpendicular
Vectors from $P$:
$$\vec{PO} = O – P = (0-3t^2,\; 0-6t) = (-3t^2,\; -6t)$$
$$\vec{PA} = A – P = (\lambda – 3t^2,\; 0-6t) = (\lambda-3t^2,\; -6t)$$
For $\angle OPA = 90°$: $\vec{PO} \cdot \vec{PA} = 0$:
$$(-3t^2)(\lambda – 3t^2) + (-6t)(-6t) = 0$$
$$-3t^2(\lambda – 3t^2) + 36t^2 = 0$$
$$-3t^2\lambda + 9t^4 + 36t^2 = 0$$
Divide throughout by $t^2$ (assuming $t \neq 0$, i.e., $P \neq O$):
$$-3\lambda + 9t^2 + 36 = 0$$
$$\lambda = 3t^2 + 12$$
$A = (3t^2 + 12,\; 0)$
3
All three vertices of triangle $OPA$
$O = (0,\;0)$
$P = (3t^2,\;6t)$
$A = (3t^2+12,\;0)$
4
Find centroid $G(h,k)$
$$h = \frac{x_O + x_P + x_A}{3} = \frac{0 + 3t^2 + (3t^2+12)}{3} = \frac{6t^2 + 12}{3} = 2t^2 + 4$$
$$k = \frac{y_O + y_P + y_A}{3} = \frac{0 + 6t + 0}{3} = 2t$$
5
Eliminate parameter $t$ to get locus
From $k = 2t$:
$$t = \frac{k}{2}$$
Substitute into $h = 2t^2 + 4$:
$$h = 2\left(\frac{k}{2}\right)^2 + 4 = 2 \cdot \frac{k^2}{4} + 4 = \frac{k^2}{2} + 4$$
Rearranging:
$$k^2 = 2(h – 4) = 2h – 8$$
$$k^2 – 2h + 8 = 0$$
Replace $h \to x$, $k \to y$:
$$\boxed{y^2 – 2x + 8 = 0}$$
Option (B) ✓
Related Theory
📌 Locus Problems — Standard Method
A locus is the set of all points satisfying a given geometric condition. The standard method for locus problems:
Step 1: Take a general point using parametric form (e.g., $(at^2, 2at)$ for parabola).
Step 2: Apply the given geometric condition to find relationships between coordinates and parameter.
Step 3: Express the coordinates of the required point (here centroid) in terms of parameter $t$.
Step 4: Eliminate $t$ between the coordinate expressions to get the locus equation.
This 4-step method works for all locus problems in JEE — centroid, circumcenter, midpoint, etc.
Step 1: Take a general point using parametric form (e.g., $(at^2, 2at)$ for parabola).
Step 2: Apply the given geometric condition to find relationships between coordinates and parameter.
Step 3: Express the coordinates of the required point (here centroid) in terms of parameter $t$.
Step 4: Eliminate $t$ between the coordinate expressions to get the locus equation.
This 4-step method works for all locus problems in JEE — centroid, circumcenter, midpoint, etc.
Parametric → Condition → Coordinates → Eliminate $t$
📌 Parabola $y^2 = 4ax$ — Complete Reference
For parabola $y^2 = 4ax$ with $a > 0$:
For $y^2=12x$: $a=3$, focus=$(3,0)$, directrix $x=-3$, LR length $=12$.
| Property | Value |
|---|---|
| Vertex | $(0,0)$ |
| Focus | $(a,0)$ |
| Directrix | $x = -a$ |
| Axis | $x$-axis ($y=0$) |
| Latus Rectum length | $4a$ |
| Parametric point | $(at^2, 2at)$ |
| Tangent at $(at^2,2at)$ | $ty = x + at^2$ |
| Normal at $(at^2,2at)$ | $y + tx = 2at+at^3$ |
📌 Perpendicularity Condition — Dot Product
Two vectors $\vec{u} = (u_1,u_2)$ and $\vec{v} = (v_1,v_2)$ are perpendicular if and only if:
$$\vec{u}\cdot\vec{v} = u_1v_1 + u_2v_2 = 0$$
In this problem, $\angle OPA = 90°$ means the angle at vertex $P$ is $90°$. So vectors from P to O and from P to A must be perpendicular.
Important: The right angle is at $P$, so vectors $\vec{PO}$ and $\vec{PA}$ (both starting at $P$) must have zero dot product — not $\vec{OP}$ and $\vec{OA}$.
Equivalently, using slopes: if $m_1$ = slope of $PO$ and $m_2$ = slope of $PA$, then $m_1 \cdot m_2 = -1$.
Important: The right angle is at $P$, so vectors $\vec{PO}$ and $\vec{PA}$ (both starting at $P$) must have zero dot product — not $\vec{OP}$ and $\vec{OA}$.
Equivalently, using slopes: if $m_1$ = slope of $PO$ and $m_2$ = slope of $PA$, then $m_1 \cdot m_2 = -1$.
$\vec{PO}\cdot\vec{PA}=0$ for $\angle OPA=90°$
$m_1\cdot m_2=-1$ for perpendicular lines
📌 Centroid of a Triangle
The centroid $G$ of triangle with vertices $(x_1,y_1)$, $(x_2,y_2)$, $(x_3,y_3)$:
$$G = \left(\frac{x_1+x_2+x_3}{3},\; \frac{y_1+y_2+y_3}{3}\right)$$
Key properties of centroid:
• Divides each median in ratio $2:1$ from vertex
• Always lies inside the triangle
• Centroid of $\triangle OPA$: since $O=(0,0)$ and $A$ is on x-axis, the $y$-coordinate of centroid is simply $y_P/3$
• In this problem: $k = 6t/3 = 2t$ (only $P$ contributes to y-coordinate)
• Divides each median in ratio $2:1$ from vertex
• Always lies inside the triangle
• Centroid of $\triangle OPA$: since $O=(0,0)$ and $A$ is on x-axis, the $y$-coordinate of centroid is simply $y_P/3$
• In this problem: $k = 6t/3 = 2t$ (only $P$ contributes to y-coordinate)
$G = \left(\dfrac{\sum x_i}{3}, \dfrac{\sum y_i}{3}\right)$
Median ratio: $2:1$ from vertex
📌 Locus Equation Analysis — $y^2 – 2x + 8 = 0$
The locus $y^2 = 2x – 8 = 2(x-4)$ is a parabola:
Compare with $Y^2 = 4aX$ where $Y=y$, $X=x-4$:
$4a = 2 \implies a = 1/2$
Properties of locus parabola:
• Vertex: $(4,0)$ (shifted 4 units right from origin)
• Axis: $y=0$ (x-axis), opens rightward
• Focus: $(4+\frac{1}{2}, 0) = (4.5, 0)$
• Directrix: $x = 4 – \frac{1}{2} = 3.5$
• LR length: $4a = 2$
This means as $P$ moves along $y^2=12x$, the centroid traces a smaller parabola with vertex at $(4,0)$.
Compare with $Y^2 = 4aX$ where $Y=y$, $X=x-4$:
$4a = 2 \implies a = 1/2$
Properties of locus parabola:
• Vertex: $(4,0)$ (shifted 4 units right from origin)
• Axis: $y=0$ (x-axis), opens rightward
• Focus: $(4+\frac{1}{2}, 0) = (4.5, 0)$
• Directrix: $x = 4 – \frac{1}{2} = 3.5$
• LR length: $4a = 2$
This means as $P$ moves along $y^2=12x$, the centroid traces a smaller parabola with vertex at $(4,0)$.
Locus vertex: $(4,0)$
$a=1/2$, opens right
Locus: $y^2=2(x-4)$
📌 Alternative: Slope Method for $\angle OPA = 90°$
Slope of $PO$: $m_1 = \dfrac{0-6t}{0-3t^2} = \dfrac{-6t}{-3t^2} = \dfrac{2}{t}$
Slope of $PA$: $m_2 = \dfrac{0-6t}{\lambda-3t^2} = \dfrac{-6t}{\lambda-3t^2}$
For perpendicularity: $m_1 \cdot m_2 = -1$: $$\frac{2}{t} \cdot \frac{-6t}{\lambda-3t^2} = -1$$ $$\frac{-12}{\lambda-3t^2} = -1$$ $$\lambda – 3t^2 = 12 \implies \lambda = 3t^2+12$$ Same result as dot product method ✓
Slope of $PA$: $m_2 = \dfrac{0-6t}{\lambda-3t^2} = \dfrac{-6t}{\lambda-3t^2}$
For perpendicularity: $m_1 \cdot m_2 = -1$: $$\frac{2}{t} \cdot \frac{-6t}{\lambda-3t^2} = -1$$ $$\frac{-12}{\lambda-3t^2} = -1$$ $$\lambda – 3t^2 = 12 \implies \lambda = 3t^2+12$$ Same result as dot product method ✓
📌 Common Mistakes to Avoid
❌ Mistake 1: Taking angle at wrong vertex. $\angle OPA = 90°$ is the angle at $P$, not at $O$ or $A$. Always identify which vertex has the right angle before forming the perpendicularity condition.
❌ Mistake 2: Forgetting to divide by $t^2$ after applying dot product. This is valid only when $t \neq 0$ (i.e., $P \neq O$).
❌ Mistake 3: Using centroid formula incorrectly — it’s $(\sum x_i)/3$, not $(\sum x_i)/2$ (that’s midpoint for two points).
❌ Mistake 4: Writing final locus as $y^2 = 2x – 8$ without rearranging to match the options format $y^2 – 2x + 8 = 0$.
❌ Mistake 5: Computing $h$ as $(0+3t^2)/2$ — centroid involves all three vertices including $A$.
❌ Mistake 2: Forgetting to divide by $t^2$ after applying dot product. This is valid only when $t \neq 0$ (i.e., $P \neq O$).
❌ Mistake 3: Using centroid formula incorrectly — it’s $(\sum x_i)/3$, not $(\sum x_i)/2$ (that’s midpoint for two points).
❌ Mistake 4: Writing final locus as $y^2 = 2x – 8$ without rearranging to match the options format $y^2 – 2x + 8 = 0$.
❌ Mistake 5: Computing $h$ as $(0+3t^2)/2$ — centroid involves all three vertices including $A$.
📌 Key Results Summary
$y^2=12x$: $a=3$, parametric $(3t^2,6t)$
$\angle OPA=90°$: $\vec{PO}\cdot\vec{PA}=0$
$A=(3t^2+12,0)$
Centroid: $h=2t^2+4$, $k=2t$
$t=k/2$, eliminate: $k^2=2h-8$
Locus: $y^2-2x+8=0$
Frequently Asked Questions
1. What is the parametric form of $y^2=12x$?
$(3t^2, 6t)$ since $a=3$.
2. Where is vertex $O$?
$(0,0)$ — the vertex of the parabola.
3. How is $\angle OPA=90°$ used?
$\vec{PO}\cdot\vec{PA}=0$, giving $\lambda=3t^2+12$.
4. What is the $x$-coordinate of $A$?
$\lambda = 3t^2+12$.
5. What is centroid $h$?
$h=(0+3t^2+3t^2+12)/3=2t^2+4$.
6. What is centroid $k$?
$k=(0+6t+0)/3=2t$.
7. How is $t$ eliminated?
$t=k/2$. Substitute into $h=2t^2+4$: $h=k^2/2+4$.
8. What is the locus equation?
$y^2-2x+8=0$.
9. What type of curve is the locus?
A parabola with vertex $(4,0)$, opening rightward, $a=1/2$.
10. Why divide by $t^2$ in step 2?
$t\neq0$ since $P\neq O$. Dividing simplifies the equation cleanly.
11. Can slope method be used instead?
Yes. $m_{PO}\cdot m_{PA}=-1$ gives same result: $\lambda=3t^2+12$.
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