If z=frac12-2i$z=\frac{1}{2}-2i$, is such that |z+1|=alpha z+beta(1+i)$|z+1|=\alpha z+\beta(1+i)$, i=sqrt-1$i=\sqrt{-1}$ and alpha,betain R$\alpha,\beta\in R$, then alpha+beta$\alpha+\beta$ is equal to
A.-4$-4$
B.3$3$
C.2$2$
D.-1$-1$
Solution & Explanation
### Related Formula
|x + iy| = sqrtx^2 + y^2$|x + iy| = \sqrt{x^2 + y^2}$
Two complex numbers are equal if and only if their real and imaginary parts are respectively equal.
### Core Logic
Given z = frac12 - 2i$z = \frac{1}{2} - 2i$.
Calculate |z + 1|$|z + 1|$:
|z + 1| = left| left(frac12 - 2iright) + 1 right|$|z + 1| = \left| \left(\frac{1}{2} - 2i\right) + 1 \right|$= left| frac32 - 2i right|$= \left| \frac{3}{2} - 2i \right|$= sqrtleft(frac32right)^2 + (-2)^2 = sqrtfrac94 + 4 = sqrtfrac254 = frac52$= \sqrt{\left(\frac{3}{2}\right)^2 + (-2)^2} = \sqrt{\frac{9}{4} + 4} = \sqrt{\frac{25}{4}} = \frac{5}{2}$
Now substitute z$z$ and |z + 1|$|z + 1|$ into the original equation:
frac52 = alphaleft(frac12 - 2iright) + beta(1 + i)$\frac{5}{2} = \alpha\left(\frac{1}{2} - 2i\right) + \beta(1 + i)$
Expand and group real and imaginary components on the RHS:
frac52 = left(fracalpha2 - 2alpha iright) + (beta + beta i)$\frac{5}{2} = \left(\frac{\alpha}{2} - 2\alpha i\right) + (\beta + \beta i)$frac52 = left(fracalpha2 + betaright) + i(beta - 2alpha)$\frac{5}{2} = \left(\frac{\alpha}{2} + \beta\right) + i(\beta - 2\alpha)$
### Step 1: Equate Parts
By equating the real and imaginary parts from both sides, we get a system of linear equations:
Imaginary part:
0 = beta - 2alpha Rightarrow beta = 2alpha$0 = \beta - 2\alpha \Rightarrow \beta = 2\alpha$
Real part:
frac52 = fracalpha2 + beta$\frac{5}{2} = \frac{\alpha}{2} + \beta$
Substitute beta = 2alpha$\beta = 2\alpha$ into the real part equation:
frac52 = fracalpha2 + 2alpha$\frac{5}{2} = \frac{\alpha}{2} + 2\alpha$frac52 = frac5alpha2$\frac{5}{2} = \frac{5\alpha}{2}$alpha = 1$\alpha = 1$
Using alpha = 1$\alpha = 1$, find beta$\beta$:
beta = 2(1) = 2$\beta = 2(1) = 2$
### Step 2: Final Calculation
Calculate the final requested value:
alpha + beta = 1 + 2 = 3$\alpha + \beta = 1 + 2 = 3$
### Pattern Recognition
Equating complex parts reduces single complex equations into two simultaneous linear equations. Treat |z+1|$|z+1|$ strictly as a scalar magnitude and parse directly into algebraic components.
### Evaluation Rubric / Model Answer
null
### Chapter Mix
Class 11 Mathematics: Complex Numbers and Quadratic Equations
Keywords:#equality of complex numbers#JEE Main 2024 Morning Q5#Complex Numbers and Quadratic Equations JEE Main 2024#Modulus and Equality of Complex Numbers JEE Main 2024
More Complex Numbers and Quadratic Equations Previous-Year Questions — Page 4
Q69jee_main_2025_29_jan_morningGeometry of Complex Numbers
Let left|z_1 - 8 - 2iright| leq 1$\left|z_1 - 8 - 2i\right| \leq 1$ and left|z_2 - 2 + 6iright| leq 2$\left|z_2 - 2 + 6i\right| \leq 2$ , z_1, z_2 in C$z_1, z_2 \in C$ . Then the minimum value of left|z_1 - z_2
ight|$\left|z_1 - z_2
ight|$ is:
A. 3
B. 7
C. 13
D. 10
Solution
### Related Formula
textMinimum distance between two circles: d_textmin = C_1C_2 - r_1 - r_2$\text{Minimum distance between two circles: } d_{\text{\min}} = C_1C_2 - r_1 - r_2$
### Core Logic
The expressions define two circular disc fields in the complex plane:
Circle 1: Center C_1(8, 2)$C_1(8, 2)$, radius r_1 = 1$r_1 = 1$
Circle 2: Center C_2(2, -6)$C_2(2, -6)$, radius r_2 = 2$r_2 = 2$Geometry of Complex Numbers diagram for Q69 - JEE Main 2025 Morning
### Step 1: Calculate Center Distance
Using coordinate distance formulation:
C_1C_2 = sqrt(8 - 2)^2 + (2 - (-6))^2 = sqrt6^2 + 8^2 = 10$C_1C_2 = \sqrt{(8 - 2)^2 + (2 - (-6))^2} = \sqrt{6^2 + 8^2} = 10$
### Step 2: Find Minimum Separation
|z_1 - z_2|_textmin = C_1C_2 - r_1 - r_2 = 10 - 1 - 2 = 7$|z_1 - z_2|_{\text{\min}} = C_1C_2 - r_1 - r_2 = 10 - 1 - 2 = 7$
### Pattern Recognition
Always interpret modulus circle properties geometrically rather than algebraically. Disconnecting complex plane variables into simple 2D analytical geometry centers avoids calculation mistakes entirely.
### Evaluation Rubric / Model Answer
null
### Chapter Mix
Class 11 Mathematics: Complex Numbers
Class 11 Mathematics: Coordinate Geometry
Q6jee_main_2024_01_february_morningGeometry of Complex Numbers
Let S=\zin C:|z-1|=1 text and (sqrt2-1)(z+overlinez)-i(z-overlinez)=2sqrt2\$S=\{z\in C:|z-1|=1 \text{ and } (\sqrt{2}-1)(z+\overline{z})-i(z-\overline{z})=2\sqrt{2}\}$. Let z_1, z_2in S$z_{1}, z_{2}\in S$ be such that |z_1|=max_zin S|z|$|z_{1}|=\max_{z\in S}|z|$ and |z_2|=min_zin S|z|$|z_{2}|=\min_{z\in S}|z|$. Then |sqrt2z_1-z_2|^2$|\sqrt{2}z_{1}-z_{2}|^{2}$ equals:
A.1$1$
B.4$4$
C.3$3$
D.2$2$
Solution
### Related Formula
For a complex number z = x + iy$z = x + iy$:
1. |z| = sqrtx^2 + y^2$|z| = \sqrt{x^2 + y^2}$
2. z + overlinez = 2x$z + \overline{z} = 2x$
3. z - overlinez = 2iy$z - \overline{z} = 2iy$
### Core Logic
Let z = x + iy$z = x + iy$.
The first condition |z - 1| = 1$|z - 1| = 1$ describes a circle:
(x-1)^2 + y^2 = 1 quad implies (1) $(x-1)^{2} + y^{2} = 1 \quad \implies (1) $
The second condition gives a straight line:
(sqrt2-1)(2x) - i(2iy) = 2sqrt2$(\sqrt{2}-1)(2x) - i(2iy) = 2\sqrt{2}$2(sqrt2-1)x + 2y = 2sqrt2$2(\sqrt{2}-1)x + 2y = 2\sqrt{2}$(sqrt2-1)x + y = sqrt2 quad implies (2) $(\sqrt{2}-1)x + y = \sqrt{2} \quad \implies (2) $
The set S$S$ contains the intersection points of this circle and line.
### Step 1: Solve for Intersection Points
From (2), y = sqrt2 - (sqrt2-1)x$y = \sqrt{2} - (\sqrt{2}-1)x$. Substitute this into (1):
(x-1)^2 + [sqrt2 - (sqrt2-1)x]^2 = 1$(x-1)^2 + [\sqrt{2} - (\sqrt{2}-1)x]^2 = 1$
Solving this quadratic equation gives two values of x$x$:
x = 1 quad textor quad x = frac12-sqrt2 $x = 1 \quad \text{or} \quad x = \frac{1}{2-\sqrt{2}} $
- **Case A**: x = 1 implies y = sqrt2 - (sqrt2-1)(1) = 1$x = 1 \implies y = \sqrt{2} - (\sqrt{2}-1)(1) = 1$.
So, one point is z_A = 1 + i$z_A = 1 + i$.
Its magnitude is |z_A| = sqrt1^2 + 1^2 = sqrt2$|z_A| = \sqrt{1^2 + 1^2} = \sqrt{2}$.
- **Case B**: x = frac12-sqrt2 = frac2+sqrt22 = 1 + frac1sqrt2$x = \frac{1}{2-\sqrt{2}} = \frac{2+\sqrt{2}}{2} = 1 + \frac{1}{\sqrt{2}}$.
Then y = sqrt2 - (sqrt2-1)left(1+frac1sqrt2right) = sqrt2 - left(sqrt2 + 1 - 1 - frac1sqrt2right) = frac1sqrt2$y = \sqrt{2} - (\sqrt{2}-1)\left(1+\frac{1}{\sqrt{2}}\right) = \sqrt{2} - \left(\sqrt{2} + 1 - 1 - \frac{1}{\sqrt{2}}\right) = \frac{1}{\sqrt{2}}$.
So, the other point is z_B = left(1 + frac1sqrt2right) + fracisqrt2$z_B = \left(1 + \frac{1}{\sqrt{2}}\right) + \frac{i}{\sqrt{2}}$.
Its magnitude is |z_B| = sqrtleft(1+frac1sqrt2right)^2 + left(frac1sqrt2right)^2 = sqrt1 + sqrt2 + frac12 + frac12 = sqrt2 + sqrt2$|z_B| = \sqrt{\left(1+\frac{1}{\sqrt{2}}\right)^2 + \left(\frac{1}{\sqrt{2}}\right)^2} = \sqrt{1 + \sqrt{2} + \frac{1}{2} + \frac{1}{2}} = \sqrt{2 + \sqrt{2}}$.
### Step 2: Evaluate Min and Max Magnitude Expressions
Comparing magnitudes, |z_B| > |z_A|$|z_B| > |z_A|$, so:
z_1 = z_B = left(1 + frac1sqrt2right) + fracisqrt2 $z_1 = z_B = \left(1 + \frac{1}{\sqrt{2}}\right) + \frac{i}{\sqrt{2}} $z_2 = z_A = 1 + i $z_2 = z_A = 1 + i $
Now, calculate |sqrt2z_1-z_2|^2$|\sqrt{2}z_{1}-z_{2}|^{2}$:
sqrt2z_1 = sqrt2left(1 + frac1sqrt2right) + sqrt2left(fracisqrt2right) = (sqrt2 + 1) + i$\sqrt{2}z_1 = \sqrt{2}\left(1 + \frac{1}{\sqrt{2}}\right) + \sqrt{2}\left(\frac{i}{\sqrt{2}}\right) = (\sqrt{2} + 1) + i$sqrt2z_1 - z_2 = (sqrt2 + 1 + i) - (1 + i) = sqrt2 $\sqrt{2}z_1 - z_2 = (\sqrt{2} + 1 + i) - (1 + i) = \sqrt{2} $|sqrt2z_1 - z_2|^2 = |sqrt2|^2 = 2 $|\sqrt{2}z_1 - z_2|^2 = |\sqrt{2}|^2 = 2 $
### Pattern Recognition
Sees: Geometric constraint mapping to a circle and line intersection in the complex plane.
Shortcut: Rationalizing terms like frac12-sqrt2$\frac{1}{2-\sqrt{2}}$ immediately into standard form 1+frac1sqrt2$1+\frac{1}{\sqrt{2}}$ saves you from handling layered fraction algebra down the line.
### Evaluation Rubric / Model Answer
null
### Chapter Mix
Class 11 Complex Numbers: Geometry
Class 10 Coordinate Geometry: Lines and Circles
Q27jee_main_2024_01_february_morningGeometry of Complex Numbers
Let P=\zinmathbbC:|z+2-3i|le1\$P=\{z\in\mathbb{C}:|z+2-3i|\le1\}$ and Q=\zinmathbbC:z(1+i)+overlinez(1-i)le-8\$Q=\{z\in\mathbb{C}:z(1+i)+\overline{z}(1-i)\le-8\}$. Let in P cap Q, |z-3+2i|$P \cap Q, |z-3+2i|$ be maximum and minimum at z_1$z_{1}$ and z_2$z_{2}$ respectively. If |z_1|^2+2|z_2|^2=alpha+betasqrt2$|z_{1}|^{2}+2|z_{2}|^{2}=\alpha+\beta\sqrt{2}$, where alpha, beta$\alpha, \beta$ are integers, then alpha+beta$\alpha+\beta$ equals
Numerical Answer.Answer: 36 to 36
Solution
### Related Formula
For a complex coordinate transformation, substituting z = x + iy$z = x + iy$ and its conjugate overlinez = x - iy$\overline{z} = x - iy$ maps a complex condition directly into rectangular Cartesian coordinates.
### Core Logic
Let's translate the complex set properties into Cartesian geometry:
- Set P$P$: |z - (-2 + 3i)| le 1 implies$|z - (-2 + 3i)| \le 1 \implies$ Interior and boundary of a circle with center C(-2, 3)$C(-2, 3)$ and radius r = 1$r = 1$.
- Set Q$Q$: (x+iy)(1+i) + (x-iy)(1-i) le -8 implies (x - y + ix + iy) + (x - y - ix - iy) le -8$(x+iy)(1+i) + (x-iy)(1-i) \le -8 \implies (x - y + ix + iy) + (x - y - ix - iy) \le -8$2(x - y) le -8 implies x - y + 4 le 0$2(x - y) \le -8 \implies x - y + 4 \le 0$
This defines a half-plane below or to the left of the boundary line L_2: x - y + 4 = 0$L_2: x - y + 4 = 0$.
### Step 1: Identify Extreme Points for Distance from Point A
We want to find points in the region P cap Q$P \cap Q$ that minimize and maximize the distance to the external point A(3, -2)$A(3, -2)$, corresponding to |z - (3 - 2i)|$|z - (3 - 2i)|$.
The line L_1$L_1$ connecting center C(-2, 3)$C(-2, 3)$ and point A(3, -2)$A(3, -2)$ has slope:
m = frac-2 - 33 - (-2) = frac-55 = -1$m = \frac{-2 - 3}{3 - (-2)} = \frac{-5}{5} = -1$
Equation of line L_1$L_1$: y - 3 = -1(x + 2) implies x + y - 1 = 0$y - 3 = -1(x + 2) \implies x + y - 1 = 0$.
The graphic details the intersection region bounded by the circular locus and the line inequality, showing points z1 and z2 relative to external reference point P.
### Step 2: Calculate Coordinates for z1 and z2
- **Minimum Distance Point (z_2$z_2$):** By geometric observation, the minimum distance from A$A$ to the bounded region is the intersection point of lines L_1$L_1$ and L_2$L_2$:
x - y + 4 = 0 quad textand quad x + y - 1 = 0 implies 2x + 3 = 0 implies x = -frac32, \, y = frac52$x - y + 4 = 0 \quad \text{and} \quad x + y - 1 = 0 \implies 2x + 3 = 0 \implies x = -\frac{3}{2}, \, y = \frac{5}{2}$
So, z_2 = left(-frac32, frac52
ight)$z_2 = \left(-\frac{3}{2}, \frac{5}{2}
ight)$.
- **Maximum Distance Point (z_1$z_1$):** The maximum distance is at the far boundary edge of the circle along line L_1$L_1$. The vector path from C(-2, 3)$C(-2, 3)$ opposite to A$A$ has unit direction left(-frac1sqrt2, frac1sqrt2right)$\left(-\frac{1}{\sqrt{2}}, \frac{1}{\sqrt{2}}\right)$:
z_1 = left(-2 - frac1sqrt2, \, 3 + frac1sqrt2right)$z_1 = \left(-2 - \frac{1}{\sqrt{2}}, \, 3 + \frac{1}{\sqrt{2}}\right)$
### Step 3: Evaluate Magnitudes and Sum Parameters
Calculate the squares of the moduli:
|z_1|^2 = left(-2 - frac1sqrt2right)^2 + left(3 + frac1sqrt2right)^2 = 4 + 2sqrt2 + frac12 + 9 + 3sqrt2 + frac12 = 14 + 5sqrt2$|z_1|^2 = \left(-2 - \frac{1}{\sqrt{2}}\right)^2 + \left(3 + \frac{1}{\sqrt{2}}\right)^2 = 4 + 2\sqrt{2} + \frac{1}{2} + 9 + 3\sqrt{2} + \frac{1}{2} = 14 + 5\sqrt{2}$|z_2|^2 = left(-frac32right)^2 + left(frac52
ight)^2 = frac94 + frac254 = frac344 = frac172$|z_2|^2 = \left(-\frac{3}{2}\right)^2 + \left(\frac{5}{2}
ight)^2 = \frac{9}{4} + \frac{25}{4} = \frac{34}{4} = \frac{17}{2}$
Now compute the total requested term:
|z_1|^2 + 2|z_2|^2 = (14 + 5sqrt2) + 2left(frac172right) = 14 + 5sqrt2 + 17 = 31 + 5sqrt2$|z_1|^2 + 2|z_2|^2 = (14 + 5\sqrt{2}) + 2\left(\frac{17}{2}\right) = 14 + 5\sqrt{2} + 17 = 31 + 5\sqrt{2}$
Matching with alpha + betasqrt2$\alpha + \beta\sqrt{2}$ gives alpha = 31$\alpha = 31$ and beta = 5$\beta = 5$. Thus:
alpha + beta = 31 + 5 = 36$\alpha + \beta = 31 + 5 = 36$
### Pattern Recognition
Sees: Locus intersection involving geometric complex inequalities.
Shortcut: Translating complex equations into standard 2D graphs reveals the geometry instantly, mapping extreme distances to line intersections or boundary nodes cleanly.
### Evaluation Rubric / Model Answer
null
### Chapter Mix
Class 11 Complex Numbers: Geometry
Class 11 Coordinate Geometry: Straight Lines
Q6jee_main_2024_29_january_eveningModulus and Argument of a Complex Number
Let r$r$ and theta$\theta$ respectively be the modulus and amplitude of the complex number z = 2 - i left(2 tan frac5 pi8right)$z = 2 - i \left(2 \tan \frac{5 \pi}{8}\right)$, then (r, theta)$(r, \theta)$ is equal to
### Related Formula
For z = x + iy$z = x + iy$, modulus r = sqrtx^2 + y^2$r = \sqrt{x^2 + y^2}$ and argument theta$\theta$ depends on the quadrant location.
### Core Logic
Given z = 2 - ileft(2 tan frac5pi8right)$z = 2 - i\left(2 \tan \frac{5\pi}{8}\right)$.
Note that frac5pi8$\frac{5\pi}{8}$ lies in the second quadrant, so tan frac5pi8 < 0$\tan \frac{5\pi}{8} < 0$.
Let's write r$r$:
r = sqrt2^2 + left(-2 tan frac5pi8right)^2 = 2 sqrt1 + tan^2 frac5pi8 = 2 left| sec frac5pi8 right|$r = \sqrt{2^2 + \left(-2 \tan \frac{5\pi}{8}\right)^2} = 2 \sqrt{1 + \tan^2 \frac{5\pi}{8}} = 2 \left| \sec \frac{5\pi}{8} \right|$
Since sec frac5pi8$\sec \frac{5\pi}{8}$ is negative:
r = -2 sec frac5pi8 = -2 sec left(pi - frac3pi8right) = 2 sec frac3pi8$r = -2 \sec \frac{5\pi}{8} = -2 \sec \left(\pi - \frac{3\pi}{8}\right) = 2 \sec \frac{3\pi}{8}$
### Step 1: Finding the Amplitude
Since x = 2 > 0$x = 2 > 0$ and y = -2 tan frac5pi8 > 0$y = -2 \tan \frac{5\pi}{8} > 0$, the complex number lies in the first quadrant.
theta = tan^-1 left( fracyx right) = tan^-1 left( frac-2 tan frac5pi82 right) = tan^-1 left( -tan frac5pi8 right)$\theta = \tan^{-1} \left( \frac{y}{x} \right) = \tan^{-1} \left( \frac{-2 \tan \frac{5\pi}{8}}{2} \right) = \tan^{-1} \left( -\tan \frac{5\pi}{8} \right)$-tan frac5pi8 = -tan left(pi - frac3pi8right) = tan frac3pi8$-\tan \frac{5\pi}{8} = -\tan \left(\pi - \frac{3\pi}{8}\right) = \tan \frac{3\pi}{8}$theta = tan^-1 left( tan frac3pi8 right) = frac3pi8$\theta = \tan^{-1} \left( \tan \frac{3\pi}{8} \right) = \frac{3\pi}{8}$
### Pattern Recognition
Always absolute-value trigonometric terms coming out of square roots (e.g., sqrtsec^2 phi = |sec phi|$\sqrt{\sec^2 \phi} = |\sec \phi|$). Knowing the precise quadrant prevents incorrect signs.
### Evaluation Rubric / Model Answer
null
### Chapter Mix
Class 11 Mathematics: Complex Numbers and Quadratic Equations
Q21jee_main_2024_29_january_eveningRoots of Quadratic Equations
Let alpha, beta$\alpha, \beta$ be the roots of the equation x^2 - sqrt6 x + 3 = 0$x^2 - \sqrt{6} x + 3 = 0$ such that operatornameIm(alpha) > operatornameIm(beta)$\operatorname{Im}(\alpha) > \operatorname{Im}(\beta)$. Let a, b$a, b$ be integers not divisible by 3 and n$n$ be a natural number such that fracalpha^99beta + alpha^98 = 3^n (a + ib), i = sqrt-1$\frac{\alpha^{99}}{\beta} + \alpha^{98} = 3^n (a + ib), i = \sqrt{-1}$. Then n + a + b$n + a + b$ is equal to
Numerical Answer.Answer: 49 to 49
Solution
### Related Formula
Using Euler's formula:
e^itheta = costheta + isintheta$e^{i\theta} = \cos\theta + i\sin\theta$
### Core Logic
Solving the quadratic root configurations for x^2 - sqrt6x + 3 = 0$x^2 - \sqrt{6}x + 3 = 0$:
x = fracsqrt6 pm sqrt6 - 122 = fracsqrt6 pm isqrt62 = fracsqrt62(1 pm i)$x = \frac{\sqrt{6} \pm \sqrt{6 - 12}}{2} = \frac{\sqrt{6} \pm i\sqrt{6}}{2} = \frac{\sqrt{6}}{2}(1 \pm i)$
Given operatornameIm(alpha) > operatornameIm(beta)$\operatorname{Im}(\alpha) > \operatorname{Im}(\beta)$, we set:
alpha = sqrt3 left(frac1+isqrt2right) = sqrt3 e^ipi/4$\alpha = \sqrt{3} \left(\frac{1+i}{\sqrt{2}}\right) = \sqrt{3} e^{i\pi/4}$beta = sqrt3 left(frac1-isqrt2right) = sqrt3 e^-ipi/4$\beta = \sqrt{3} \left(\frac{1-i}{\sqrt{2}}\right) = \sqrt{3} e^{-i\pi/4}$
### Step 1: Simplify Target Expression
Let us factor out common variables:
fracalpha^99beta + alpha^98 = alpha^98 left( fracalphabeta + 1 right) = fracalpha^98(alpha + beta)beta$\frac{\alpha^{99}}{\beta} + \alpha^{98} = \alpha^{98} \left( \frac{\alpha}{\beta} + 1 \right) = \frac{\alpha^{98}(\alpha + \beta)}{\beta}$
Since alpha + beta = sqrt6$\alpha + \beta = \sqrt{6}$:
textValue = frac(sqrt3e^ipi/4)^98 cdot sqrt6sqrt3e^-ipi/4 = 3^49 e^i 98pi/4 cdot sqrt2 e^ipi/4 = 3^49 cdot sqrt2 e^i 99pi/4$\text{Value} = \frac{(\sqrt{3}e^{i\pi/4})^{98} \cdot \sqrt{6}}{\sqrt{3}e^{-i\pi/4}} = 3^{49} e^{i 98\pi/4} \cdot \sqrt{2} e^{i\pi/4} = 3^{49} \cdot \sqrt{2} e^{i 99\pi/4}$
Evaluate e^i 99pi/4$e^{i 99\pi/4}$:
99fracpi4 = 24pi + frac3pi4 implies e^i 99pi/4 = e^i 3pi/4 = frac-1+isqrt2$99\frac{\pi}{4} = 24\pi + \frac{3\pi}{4} \implies e^{i 99\pi/4} = e^{i 3\pi/4} = \frac{-1+i}{\sqrt{2}}$
Substituting this back:
textValue = 3^49 cdot sqrt2 left( frac-1+isqrt2 right) = 3^49(-1 + i)$\text{Value} = 3^{49} \cdot \sqrt{2} \left( \frac{-1+i}{\sqrt{2}} \right) = 3^{49}(-1 + i)$
### Step 2: Resolving Constants
Comparing with the given expression 3^n(a + ib)$3^n(a + ib)$:
n = 49, quad a = -1, quad b = 1$n = 49, \quad a = -1, \quad b = 1$
Therefore:
n + a + b = 49 - 1 + 1 = 49$n + a + b = 49 - 1 + 1 = 49$
### Pattern Recognition
Convert complex expressions into polar form r e^itheta$r e^{i\theta}$ early. Power scaling like alpha^98$\alpha^{98}$ becomes simple multiplication under Euler structures.
### Evaluation Rubric / Model Answer
null
### Chapter Mix
Class 11 Mathematics: Complex Numbers and Quadratic Equations
More Complex Numbers and Quadratic Equations Questions — jee_main_2024_29_jan_morning
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