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JEE Main · MCQ · Complex Numbers · Geometry
MCQ · Mathematics · Complex Numbers
Q. Let $z$ be the complex number satisfying $|z – 5| \leq 3$ and having maximum positive principal argument. Then $34\left|\dfrac{5z-12}{5iz+16}\right|^2$ is equal to:
A$20$ ✓
B$26$
C$12$
D$16$
✅ Correct Answer: (A) $20$
Step-by-Step Solution
1
Geometric interpretation of $|z-5| \leq 3$
This represents a closed disk:
Centre $C = (5,\,0)$, Radius $r = 3$
$z$ lies on or inside this circle in the complex plane.
2
Find $z$ with maximum positive principal argument
The principal argument $\theta = \arg(z)$ is maximised when $z$ is the point on the circle (boundary) from which the line $OP$ (O = origin) makes maximum angle with positive x-axis.
🔵 Geometrically: Draw tangent lines from origin $O(0,0)$ to the circle with centre $C(5,0)$ and radius $3$.
The tangent in the upper half plane touches the circle at the point $z$ with maximum argument.
The tangent in the upper half plane touches the circle at the point $z$ with maximum argument.
3
Compute tangent geometry
Distance from origin to centre: $|OC| = 5$
$\sin\theta = \dfrac{r}{|OC|} = \dfrac{3}{5}, \quad \cos\theta = \dfrac{4}{5}$
\text{(using } \sin^2\theta + \cos^2\theta = 1\text{, tangent length} = \sqrt{5^2-3^2} = 4\text{)}
Maximum argument $\theta = \sin^{-1}(3/5)$
\text{(using } \sin^2\theta + \cos^2\theta = 1\text{, tangent length} = \sqrt{5^2-3^2} = 4\text{)}
4
Find the tangent point $z$
The foot of perpendicular from $C(5,0)$ to the tangent line gives the tangent point. Using the geometry:
$z = |OT|\cdot e^{i\theta}$ where $|OT| = 4$ (tangent length)
$z = 4\!\left(\cos\theta + i\sin\theta\right) = 4\!\left(\dfrac{4}{5} + i\cdot\dfrac{3}{5}\right)$
$= \dfrac{16}{5} + \dfrac{12i}{5}$
$z = 4\!\left(\cos\theta + i\sin\theta\right) = 4\!\left(\dfrac{4}{5} + i\cdot\dfrac{3}{5}\right)$
$= \dfrac{16}{5} + \dfrac{12i}{5}$
$z = \dfrac{16 + 12i}{5}$
5
Compute $5z – 12$
$5z = 5 \cdot \dfrac{16+12i}{5} = 16 + 12i$
$5z – 12 = (16-12) + 12i = 4 + 12i$
$|5z-12|^2 = 4^2 + 12^2 = 16 + 144 = 160$
$5z – 12 = (16-12) + 12i = 4 + 12i$
$|5z-12|^2 = 4^2 + 12^2 = 16 + 144 = 160$
6
Compute $5iz + 16$
$5iz = i \cdot (16+12i) = 16i + 12i^2 = -12 + 16i$
$5iz + 16 = (-12+16) + 16i = 4 + 16i$
$|5iz+16|^2 = 4^2 + 16^2 = 16 + 256 = 272$
$5iz + 16 = (-12+16) + 16i = 4 + 16i$
$|5iz+16|^2 = 4^2 + 16^2 = 16 + 256 = 272$
7
Compute the final expression
$34\left|\dfrac{5z-12}{5iz+16}\right|^2 = 34 \times \dfrac{|5z-12|^2}{|5iz+16|^2}$
$= 34 \times \dfrac{160}{272} = 34 \times \dfrac{10}{17} = 2 \times 10 = 20$
$= 34 \times \dfrac{160}{272} = 34 \times \dfrac{10}{17} = 2 \times 10 = 20$
$= 20$ → Option (A) ✓
Related Theory
📌 Complex Number as a Point in Argand Plane
Every complex number $z = x + iy$ corresponds to the point $(x,y)$ in the Argand plane (complex plane). This geometric representation is fundamental to solving complex number problems in JEE.
Modulus: $|z| = \sqrt{x^2+y^2}$ = distance from origin to point $(x,y)$
Argument: $\arg(z) = \tan^{-1}(y/x)$ = angle made with positive x-axis
Principal Argument: The argument in the range $(-\pi, \pi]$. Positive principal argument means the point is in the upper half plane ($y > 0$) or on positive x-axis.
Modulus: $|z| = \sqrt{x^2+y^2}$ = distance from origin to point $(x,y)$
Argument: $\arg(z) = \tan^{-1}(y/x)$ = angle made with positive x-axis
Principal Argument: The argument in the range $(-\pi, \pi]$. Positive principal argument means the point is in the upper half plane ($y > 0$) or on positive x-axis.
$|z| = \sqrt{x^2+y^2}$
$\arg(z) \in (-\pi,\pi]$
$|z_1/z_2| = |z_1|/|z_2|$
📌 Circle in Complex Plane — $|z – z_0| = r$
$|z – z_0| = r$ represents a circle centred at $z_0$ with radius $r$.
$|z – z_0| \leq r$ represents the closed disk (circle + interior).
Common forms to recognise:
• $|z – a| = |z – b|$: perpendicular bisector of $a$ and $b$
• $|z – a| + |z – b| = k$: ellipse with foci $a,b$
• $|z – a| / |z – b| = k$: circle (Apollonius circle) if $k \neq 1$
• $\arg(z – a) = \theta$: ray from $a$ at angle $\theta$
$|z – z_0| \leq r$ represents the closed disk (circle + interior).
Common forms to recognise:
• $|z – a| = |z – b|$: perpendicular bisector of $a$ and $b$
• $|z – a| + |z – b| = k$: ellipse with foci $a,b$
• $|z – a| / |z – b| = k$: circle (Apollonius circle) if $k \neq 1$
• $\arg(z – a) = \theta$: ray from $a$ at angle $\theta$
$|z-z_0|=r$ → circle, centre $z_0$, radius $r$
$|z-z_0|\leq r$ → closed disk
📌 Maximum Argument — Tangent from Origin
To find the complex number $z$ on/inside a circle with maximum argument:
Step 1: Draw tangent lines from the origin to the circle boundary.
Step 2: The tangent point in the upper half plane gives maximum argument.
Step 3: Use right triangle: if centre is at distance $d$ from origin and radius is $r$, then: $$\sin(\theta_{max}) = \frac{r}{d}, \quad \text{tangent length} = \sqrt{d^2 – r^2}$$
Here: $d = |OC| = 5$, $r = 3$, so tangent length $= \sqrt{25-9} = 4$.
The tangent point: $z = 4e^{i\theta} = 4(\cos\theta + i\sin\theta)$ where $\sin\theta = 3/5$.
Step 1: Draw tangent lines from the origin to the circle boundary.
Step 2: The tangent point in the upper half plane gives maximum argument.
Step 3: Use right triangle: if centre is at distance $d$ from origin and radius is $r$, then: $$\sin(\theta_{max}) = \frac{r}{d}, \quad \text{tangent length} = \sqrt{d^2 – r^2}$$
Here: $d = |OC| = 5$, $r = 3$, so tangent length $= \sqrt{25-9} = 4$.
The tangent point: $z = 4e^{i\theta} = 4(\cos\theta + i\sin\theta)$ where $\sin\theta = 3/5$.
$\sin\theta_{max} = r/d$
Tangent length $= \sqrt{d^2-r^2}$
$z = \text{tangent length} \cdot e^{i\theta_{max}}$
📌 Modulus of Quotient — $\left|\dfrac{z_1}{z_2}\right|^2$
A key property of complex modulus:
$$\left|\frac{z_1}{z_2}\right|^2 = \frac{|z_1|^2}{|z_2|^2}$$
This allows us to compute the modulus squared of a quotient by computing numerator and denominator moduli separately.
Also remember:
• $|z_1 z_2| = |z_1| \cdot |z_2|$
• $|z_1 + z_2|^2 = |z_1|^2 + |z_2|^2 + 2\text{Re}(z_1\overline{z_2})$
• $|z|^2 = z\bar{z}$
• $|iz| = |i| \cdot |z| = |z|$ (multiplying by $i$ only rotates, doesn’t change modulus)
Also remember:
• $|z_1 z_2| = |z_1| \cdot |z_2|$
• $|z_1 + z_2|^2 = |z_1|^2 + |z_2|^2 + 2\text{Re}(z_1\overline{z_2})$
• $|z|^2 = z\bar{z}$
• $|iz| = |i| \cdot |z| = |z|$ (multiplying by $i$ only rotates, doesn’t change modulus)
$|z_1/z_2|^2 = |z_1|^2/|z_2|^2$
$|z|^2 = x^2+y^2$
$|iz|=|z|$
📌 Multiplication by $i$ — Rotation by 90°
Multiplying a complex number $z$ by $i$ rotates it by $90°$ anticlockwise:
$$i \cdot z = i(x+iy) = ix + i^2y = -y + ix$$
So the point $(x,y)$ maps to $(-y, x)$.
In this problem: $5iz = i(16+12i) = 16i – 12 = -12 + 16i$. This is just a $90°$ rotation of $16+12i$.
Powers of $i$:
$i^0=1,\ i^1=i,\ i^2=-1,\ i^3=-i,\ i^4=1$ (period 4)
In this problem: $5iz = i(16+12i) = 16i – 12 = -12 + 16i$. This is just a $90°$ rotation of $16+12i$.
Powers of $i$:
$i^0=1,\ i^1=i,\ i^2=-1,\ i^3=-i,\ i^4=1$ (period 4)
$i\cdot z$ = rotate $z$ by $90°$ CCW
$i^2=-1$
$(-i)\cdot z$ = rotate by $90°$ CW
📌 Verification: Is $z = (16+12i)/5$ on the Circle?
We must verify $|z-5| = 3$:
$$z – 5 = \frac{16+12i}{5} – 5 = \frac{16+12i-25}{5} = \frac{-9+12i}{5}$$
$$|z-5| = \frac{\sqrt{81+144}}{5} = \frac{\sqrt{225}}{5} = \frac{15}{5} = 3 \ ✓$$
The point lies exactly on the boundary circle, confirming it is the tangent point.
📌 Common Mistakes to Avoid
❌ Mistake 1: Confusing $|z-5|\leq 3$ (disk) with $|z-5|=3$ (circle). The maximum argument is on the boundary circle, not the interior.
❌ Mistake 2: Thinking maximum argument occurs at the topmost point of the circle $(5, 3)$. This is not true — the maximum argument occurs at the tangent point from the origin, not the topmost point.
❌ Mistake 3: Computing $5iz$ as $5i\cdot z$ incorrectly. Remember $i^2 = -1$, so $i(12i) = 12i^2 = -12$ (real, not imaginary).
❌ Mistake 4: Forgetting that tangent length $= \sqrt{d^2-r^2}$, not $d-r$.
❌ Mistake 5: Computing $|5z-12|^2$ as $|5z|^2 – |12|^2$. Modulus does NOT distribute over subtraction like that. Always compute $|a+bi|^2 = a^2+b^2$ directly.
❌ Mistake 2: Thinking maximum argument occurs at the topmost point of the circle $(5, 3)$. This is not true — the maximum argument occurs at the tangent point from the origin, not the topmost point.
❌ Mistake 3: Computing $5iz$ as $5i\cdot z$ incorrectly. Remember $i^2 = -1$, so $i(12i) = 12i^2 = -12$ (real, not imaginary).
❌ Mistake 4: Forgetting that tangent length $= \sqrt{d^2-r^2}$, not $d-r$.
❌ Mistake 5: Computing $|5z-12|^2$ as $|5z|^2 – |12|^2$. Modulus does NOT distribute over subtraction like that. Always compute $|a+bi|^2 = a^2+b^2$ directly.
📌 Key Formulas Summary
$|z-z_0|\leq r$: disk, centre $z_0$
Max arg: tangent from origin
$\sin\theta=r/d$, tangent$=\sqrt{d^2-r^2}$
$z_{tangent}=\sqrt{d^2-r^2}\cdot e^{i\theta}$
$|a+bi|^2=a^2+b^2$
$|z_1/z_2|^2=|z_1|^2/|z_2|^2$
$i^2=-1$, $i(a+bi)=-b+ai$
📌 JEE Relevance
Complex number geometry is a high-weightage topic in JEE Main — typically 2–3 questions per session. Problems involving maximum/minimum argument, locus on Argand plane, and modulus expressions appear regularly. The key skill tested here is:
(1) Converting $|z-5|\leq3$ to a circle
(2) Finding the tangent point for maximum argument
(3) Clean computation of complex modulus squared
This 3-step approach works for all “maximum/minimum argument” problems. Time target: 3 minutes in JEE Main.
(1) Converting $|z-5|\leq3$ to a circle
(2) Finding the tangent point for maximum argument
(3) Clean computation of complex modulus squared
This 3-step approach works for all “maximum/minimum argument” problems. Time target: 3 minutes in JEE Main.
Frequently Asked Questions
1. What does $|z-5|\leq3$ represent?
A closed disk centred at $(5,0)$ with radius $3$ in the Argand plane.
2. Where is maximum argument achieved?
At the tangent point from the origin to the circle in the upper half plane.
3. What is $\sin\theta_{max}$?
$\sin\theta = r/d = 3/5$, $\cos\theta = 4/5$.
4. What is the tangent length from origin?
$\sqrt{5^2-3^2} = \sqrt{16} = 4$.
5. What is $z$ at maximum argument?
$z = 4(\cos\theta+i\sin\theta) = (16+12i)/5$.
6. What is $5z-12$?
$16+12i-12 = 4+12i$, so $|5z-12|^2 = 160$.
7. What is $5iz+16$?
$5iz = -12+16i$, so $5iz+16 = 4+16i$, $|5iz+16|^2 = 272$.
8. What is the final computation?
$34 \times 160/272 = 34 \times 10/17 = 20$.
9. How do we verify $z$ is on the circle?
$|z-5| = |(-9+12i)/5| = 15/5 = 3$ ✓
10. What does multiplying by $i$ do geometrically?
It rotates the complex number by $90°$ anticlockwise. $|iz|=|z|$ always.
11. Why is the topmost point $(5,3)$ not the answer?
The topmost point has $\arg = \tan^{-1}(3/5) \approx 31°$, but the tangent point has $\arg = \sin^{-1}(3/5) \approx 37°$ — larger. Always use tangent from origin for max argument.
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