Let O be the origin and the position vector of A and B be 2hati+2hatj+hatk$2\hat{i}+2\hat{j}+\hat{k}$ and 2hati+4hatj+4hatk$2\hat{i}+4\hat{j}+4\hat{k}$ respectively. If the internal bisector of angle AOB$\angle AOB$ meets the line AB at C, then the length of OC is
A.frac23sqrt31$\frac{2}{3}\sqrt{31}$
B.frac23sqrt34$\frac{2}{3}\sqrt{34}$
C.frac34sqrt34$\frac{3}{4}\sqrt{34}$
D.frac32sqrt31$\frac{3}{2}\sqrt{31}$
Solution & Explanation
### Related Formula
textInternal Angle Bisector Theorem: fracACCB = frac|vecOA||vecOB|$\text{Internal Angle Bisector Theorem: } \frac{AC}{CB} = \frac{|\vec{OA}|}{|\vec{OB}|}$textSection Formula: vecOC = fracmvecOB + nvecOAm+n$\text{Section Formula: } \vec{OC} = \frac{m\vec{OB} + n\vec{OA}}{m+n}$
### Core Logic
Find the magnitudes of the position vectors vecOA$\vec{OA}$ and vecOB$\vec{OB}$:
|vecOA| = sqrt2^2 + 2^2 + 1^2 = sqrt4+4+1 = sqrt9 = 3$|\vec{OA}| = \sqrt{2^2 + 2^2 + 1^2} = \sqrt{4+4+1} = \sqrt{9} = 3$|vecOB| = sqrt2^2 + 4^2 + 4^2 = sqrt4+16+16 = sqrt36 = 6$|\vec{OB}| = \sqrt{2^2 + 4^2 + 4^2} = \sqrt{4+16+16} = \sqrt{36} = 6$
According to the internal angle bisector theorem in Delta AOB$\Delta AOB$, the point C divides the segment AB in the ratio of the adjacent sides:
fracACCB = frac|vecOA||vecOB| = frac36 = frac12$\frac{AC}{CB} = \frac{|\vec{OA}|}{|\vec{OB}|} = \frac{3}{6} = \frac{1}{2}$Vector Angle Bisector
### Step 1: Apply Section Formula
Using the section formula to find the position vector of C, dividing AB internally in ratio m:n = 1:2$m:n = 1:2$:
vecOC = frac1(vecOB) + 2(vecOA)1 + 2$\vec{OC} = \frac{1(\vec{OB}) + 2(\vec{OA})}{1 + 2}$vecOC = frac1(2hati+4hatj+4hatk) + 2(2hati+2hatj+hatk)3$\vec{OC} = \frac{1(2\hat{i}+4\hat{j}+4\hat{k}) + 2(2\hat{i}+2\hat{j}+\hat{k})}{3}$vecOC = frac(2+4)hati + (4+4)hatj + (4+2)hatk3$\vec{OC} = \frac{(2+4)\hat{i} + (4+4)\hat{j} + (4+2)\hat{k}}{3}$vecOC = frac6hati + 8hatj + 6hatk3 = 2hati + frac83hatj + 2hatk$\vec{OC} = \frac{6\hat{i} + 8\hat{j} + 6\hat{k}}{3} = 2\hat{i} + \frac{8}{3}\hat{j} + 2\hat{k}$
### Step 2: Compute Length of OC
Now, find the magnitude (length) of the vector vecOC$\vec{OC}$:
|vecOC| = sqrt2^2 + left(frac83right)^2 + 2^2$|\vec{OC}| = \sqrt{2^2 + \left(\frac{8}{3}\right)^2 + 2^2}$= sqrt4 + frac649 + 4 = sqrt8 + frac649$= \sqrt{4 + \frac{64}{9} + 4} = \sqrt{8 + \frac{64}{9}}$= sqrtfrac72 + 649 = sqrtfrac1369$= \sqrt{\frac{72 + 64}{9}} = \sqrt{\frac{136}{9}}$= fracsqrt4 times 343 = frac2sqrt343$= \frac{\sqrt{4 \times 34}}{3} = \frac{2\sqrt{34}}{3}$
### Pattern Recognition
Vector angle bisector questions invariably test the geometric property that the bisector divides the opposite side in the ratio of the side lengths. Combine this directly with the 3D coordinate section formula.
### Evaluation Rubric / Model Answer
null
### Chapter Mix
Class 12 Mathematics: Vector Algebra
Keywords:#internal bisector of angle#JEE Main 2024 Morning Q13#Vector Algebra JEE Main 2024#Vector Angle Bisector JEE Main 2024
More Vector Algebra Previous-Year Questions — Page 2
Q69jee_main_2025_29_jan_eveningVector Products and Angles
Let hatmathbfa$\hat{\mathbf{a}}$ be a unit vector perpendicular to the vectors vecmathsfb = hatmathsfi -2hatmathsfj +3hatmathsfk$\vec{\mathsf{b}} = \hat{\mathsf{i}} -2\hat{\mathsf{j}} +3\hat{\mathsf{k}}$ and vecmathbfc = 2hatmathbfi +3hatmathbfj -hatmathbfk$\vec{\mathbf{c}} = 2\hat{\mathbf{i}} +3\hat{\mathbf{j}} -\hat{\mathbf{k}}$, and makes an angle of cos^-1left(-frac13right)$\cos^{-1}\left(-\frac{1}{3}\right)$ with the vector hatmathrmi +hatmathrmj +hatmathrmk$\hat{\mathrm{i}} +\hat{\mathrm{j}} +\hat{\mathrm{k}}$. If hatmathbfa$\hat{\mathbf{a}}$ makes an angle of fracpi3$\frac{\pi}{3}$ with the vector hatmathrmi +alpha hatmathrmj +hatmathrmk$\hat{\mathrm{i}} +\alpha \hat{\mathrm{j}} +\hat{\mathrm{k}}$, then the value of alpha$\alpha$ is :
A.-sqrt3$-\sqrt{3}$
B.sqrt6$\sqrt{6}$
C.-sqrt6$-\sqrt{6}$
D.sqrt3$\sqrt{3}$
Solution
### Related Formula
Cross product for vector perpendicular direction alignment:
vecu = vecb times vecc$\vec{u} = \vec{b} \times \vec{c}$
Angle projection formula:
costheta = fracveca cdot vecv|veca||vecv|$\cos\theta = \frac{\vec{a} \cdot \vec{v}}{|\vec{a}||\vec{v}|}$
### Core Logic
Compute cross product of vecb$\vec{b}$ and vecc$\vec{c}$:
vecb times vecc = beginvmatrix hati & hatj & hatk \\ 1 & -2 & 3 \\ 2 & 3 & -1 endvmatrix = -7hati + 7hatj + 7hatk = -7(hati - hatj - hatk)$\vec{b} \times \vec{c} = \begin{vmatrix} \hat{i} & \hat{j} & \hat{k} \\ 1 & -2 & 3 \\ 2 & 3 & -1 \end{vmatrix} = -7\hat{i} + 7\hat{j} + 7\hat{k} = -7(\hat{i} - \hat{j} - \hat{k})$
Hence, unit vector hata$\hat{a}$ matches form:
hata = pm frachati - hatj - hatksqrt3$\hat{a} = \pm \frac{\hat{i} - \hat{j} - \hat{k}}{\sqrt{3}}$
### Step 1: Isolate Core Angle Direction
Check conditions against vector vecv = hati + hatj + hatk$\vec{v} = \hat{i} + \hat{j} + \hat{k}$:
Using hata = frachati - hatj - hatksqrt3$\hat{a} = \frac{\hat{i} - \hat{j} - \hat{k}}{\sqrt{3}}$:
costheta = frac1 - 1 - 1sqrt3sqrt3 = -frac13$\cos\theta = \frac{1 - 1 - 1}{\sqrt{3}\sqrt{3}} = -\frac{1}{3}$
This confirms the direction for hata$\hat{a}$.
### Step 2: Solve for Unknown Scalar Variable
Now compute angle with vector hati + alphahatj + hatk$\hat{i} + \alpha\hat{j} + \hat{k}$ for theta = fracpi3$\theta = \frac{\pi}{3}$:
cosfracpi3 = frac1sqrt3 cdot frac1 - alpha - 1sqrt2 + alpha^2$\cos\frac{\pi}{3} = \frac{1}{\sqrt{3}} \cdot \frac{1 - \alpha - 1}{\sqrt{2 + \alpha^2}}$frac12 = frac-alphasqrt3sqrtalpha^2 + 2$\frac{1}{2} = \frac{-\alpha}{\sqrt{3}\sqrt{\alpha^2 + 2}}$
Since left hand side is positive, alpha$\alpha$ must be strictly negative. Squaring both sides:
frac14 = fracalpha^23(alpha^2 + 2) implies 3alpha^2 + 6 = 4alpha^2 implies alpha^2 = 6$\frac{1}{4} = \frac{\alpha^2}{3(\alpha^2 + 2)} \implies 3\alpha^2 + 6 = 4\alpha^2 \implies \alpha^2 = 6$
Since alpha < 0$\alpha < 0$, alpha = -sqrt6$\alpha = -\sqrt{6}$.
### Pattern Recognition
Keep strict track of signs when dealing with algebra containing square roots. Checking value constraints early on allows you to drop phantom positive/negative branches seamlessly.
### Evaluation Rubric / Model Answer
null
### Chapter Mix
Class 12 Mathematics: Vector Algebra
Q73jee_main_2025_28_jan_morningVector Dot and Cross Products
Let veca = hati +hatj +hatk,quad vecb = 2hati +2hatj +hatk$\vec{a} = \hat{i} +\hat{j} +\hat{k},\quad \vec{b} = 2\hat{i} +2\hat{j} +\hat{k}$ and vecd = vecatimes vecb$\vec{d} = \vec{a}\times \vec{b}$. If vecc$\vec{c}$ is a vector such that veca.vecc = |vecc |,$\vec{a}.\vec{c} = |\vec{c} |,$|vecc -2veca|^2 = 8$|\vec{c} -2\vec{a}|^2 = 8$ and the angle between vecd$\vec{d}$ and vecc$vec{c}$ is fracpi4,$\frac{\pi}{4},$ then |10 - 3vecb.vecc| + |vecdtimes vecc|^2$|10 - 3\vec{b}.\vec{c}| + |vec{d}\times vec{c}|^2$ is equal to ....
Q75jee_main_2025_04_april_eveningProperties of Vectors in Triangles
Let the three sides of a triangle ABC be given by the vectors 2hatmathbfi - hatmathbfj + hatmathbfk$2\hat{\mathbf{i}} - \hat{\mathbf{j}} + \hat{\mathbf{k}}$ , hatmathbfi - 3hatmathbfj - 5hatmathbfk$\hat{\mathbf{i}} - 3\hat{\mathbf{j}} - 5\hat{\mathbf{k}}$ and 3hatmathbfi - mathbf4hatmathbfj - mathbf4hatmathbfk$3\hat{\mathbf{i}} - \mathbf{4}\hat{\mathbf{j}} - \mathbf{4}\hat{\mathbf{k}}$ . Let G be the centroid of the triangle ABC. Then 6leftleft|overlineAGright|^2 + left|overlineBGright|^2 + left|overlineCGright|^2right)$6\left\left|\overline{AG}\right|^2 + \left|\overline{BG}\right|^2 + \left|\overline{CG}\right|^2\right)$ is equal to
Q64jee_main_2025_04_april_morningComponents of Vectors
Consider two vectors vecu = 3hati - hatj$\vec{u} = 3\hat{i} - \hat{j}$ and vecv = 2hati + hatj - lambda hatk$\vec{v} = 2\hat{i} + \hat{j} - \lambda \hat{k}$, where lambda > 0$\lambda > 0$. The angle between them is given by cos^-1left(fracsqrt52sqrt7right)$\cos^{-1}\left(\frac{\sqrt{5}}{2sqrt{7}}\right)$. Let vecv = vecv_1 + vecv_2$\vec{v} = \vec{v}_1 + \vec{v}_2$, where vecv_1$\vec{v}_1$ is parallel to vecu$\vec{u}$ and vecv_2$\vec{v}_2$ is perpendicular to vecu$\vec{u}$. Then the value |vecv_1|^2 + |vecv_2|^2$|\vec{v}_1|^2 + |\vec{v}_2|^2$ is equal to
A.frac232$\frac{23}{2}$
B. 14
C.frac252$\frac{25}{2}$
D. 10
Solution
### Related Formula
By orthogonal vector decomposition (Pythagorean property):
|vecv|^2 = |vecv_1|^2 + |vecv_2|^2 quad textwhen vecv_1 cdot vecv_2 = 0$|\vec{v}|^2 = |\vec{v}_1|^2 + |\vec{v}_2|^2 \quad \text{when } \vec{v}_1 \cdot \vec{v}_2 = 0$
### Core Logic
Compute lambda$\lambda$ using dot product formula:
costheta = fracvecu cdot vecv|vecu||vecv| implies fracsqrt52sqrt7 = frac3(2) + (-1)(1)sqrt3^2 + (-1)^2 sqrt2^2 + 1^2 + (-lambda)^2$\cos\theta = \frac{\vec{u} \cdot \vec{v}}{|\vec{u}||\vec{v}|} \implies \frac{\sqrt{5}}{2\sqrt{7}} = \frac{3(2) + (-1)(1)}{\sqrt{3^2 + (-1)^2} \sqrt{2^2 + 1^2 + (-\lambda)^2}}$fracsqrt52sqrt7 = frac5sqrt10sqrt5 + lambda^2 implies frac12sqrt7 = fracsqrt5sqrt10sqrt5 + lambda^2 = frac1sqrt2sqrt5 + lambda^2$\frac{\sqrt{5}}{2\sqrt{7}} = \frac{5}{\sqrt{10}\sqrt{5 + \lambda^2}} \implies \frac{1}{2\sqrt{7}} = \frac{\sqrt{5}}{\sqrt{10}\sqrt{5 + \lambda^2}} = \frac{1}{\sqrt{2}\sqrt{5 + \lambda^2}}$
### Step 1: Solve for lambda
Square both sides of equation:
frac128 = frac12(5 + lambda^2) implies 2(5 + lambda^2) = 28 implies 5 + lambda^2 = 14 implies lambda^2 = 9 implies lambda = 3$\frac{1}{28} = \frac{1}{2(5 + \lambda^2)} \implies 2(5 + \lambda^2) = 28 \implies 5 + \lambda^2 = 14 \implies \lambda^2 = 9 \implies \lambda = 3$
Since vecv = 2hati + hatj - 3hatk$\vec{v} = 2\hat{i} + \hat{j} - 3\hat{k}$.
### Step 2: Apply Identity
Since components are orthogonal, direct magnitude squared holds:
|vecv_1|^2 + |vecv_2|^2 = |vecv|^2 = 2^2 + 1^2 + (-3)^2 = 4 + 1 + 9 = 14$|\vec{v}_1|^2 + |\vec{v}_2|^2 = |\vec{v}|^2 = 2^2 + 1^2 + (-3)^2 = 4 + 1 + 9 = 14$
### Pattern Recognition
Do not waste time explicitly projecting components vecv_1$\vec{v}_1$ and vecv_2$\vec{v}_2$ if only the sum of their squared magnitudes is requested. The scalar length matches the total vector length invariant under any orthogonal basis change.
### Evaluation Rubric / Model Answer
null
### Chapter Mix
Class 12 Mathematics: Vector Algebra
More Vector Algebra Questions — jee_main_2024_29_jan_morning
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