Explore topic-wise InterviewSolutions in Current Affairs.

If $ABCD$ is a rhombus whose diagonals are represented by $\overrightarrow{AC}=\hat{i}+(1+\lambda )\hat{j}+(\lambda -2)\hat{k}$ and $\overrightarrow{BD}=(2\lambda -1)\hat{i}+\hat{j}-\hat{k},$ then $\lambda$ equals to

Two springs A and B ($k_A$ = 2$k_B$) are stretched by applying forces of equal magnitudes at the four ends. If the energy stored in A is E, that in B is

A $2\text{kg}$ ball is swinging in a vertical circle at the end of an inextensible string $2\text{m}$ long. The angular speed of the ball if the string can sustain a maximum tension of $119.6\text{N}$ is (Take $g=9.8{\text{m/s}}^2$)

The variation of the intensity of magnetisation $\left(I\right)$ with respect to the magnetising field $\left(H\right)$ in a diamagnetic substance is described by the graph.

Which one of the following is the bending moment diagram for the vertical cantilever beam loaded as shown in figure?

The Bat Life: Batman is undercover, and to prevent anyone from recognizing his voice (or Bruce Wayne's) he inhales a very dilute Helium gas (search YouTube for "voice after helium” to see the effects). The helium is stored ina cylindrical chamber as shown.

During a fight one of the steel balls gets dislodged. What will happen to the piston?

A man of mass m stands on a create of mass M. He pulls on a light rope passing over a smooth light pulley. The other end of the rope is attached to the crate. For the system to be in equilibrium, the force exerted by the men on the rope will be

Figure shows a capillary tube of radius $r$ dipped into water. The atmospheric pressure is $P_0$ and the capillary rise of water is $h$. $s$ is the surface tension for water-glass.





Which of the following graphs may represent the relation between the capillary rise $h$ and the radius $r$ of the capillary?

Find the amplitude of vibration of the particles of air through which a sound wave of intensity $2.0\times {10}^{-6}W{m}^{-2}$ and frequency 1.0 kHz is passing. Density of air =$1.2kg{m}^{-3}$and speed of sound in air =$330m{s}^{-1}$

When ultraviolet rays are incident on metal plate, then photoelectric effect does not occurs. It occurs by the incidence of

Two wave with same frequency and wave number are propagating in the same direction. The ratio of their amplitude is $5:1$ . If interference occurs, the ratio of maximum and minimum intensity should be

Four charge particles $H{e}^{++}$, proton, deutron and $L{i}^{++}$ enters a region of uniform magnetic field and moves in a circular path of different radius. List I gives above four particles while list II gives magnitude of some quantity.



$\begin{array}{cc}\text{List I}& \text{List II}\\ \text{I -}H{e}^{++}& \text{P)}1\\ \text{II -}\text{Proton}& \text{Q)}2\\ \text{III -}\text{deutron}& \text{R)}\frac{1}{\sqrt{2}}\\ \text{IV)}L{i}^{++}& \text{S)}\sqrt{2}\\ & \text{T)}\frac{\sqrt{7}}{2}\\ & \text{U)}\frac{1}{2}\end{array}$

If kinetic energy of all four particles is same than correct match for radius of four particles in units of radius of proton is

The acceleration of a particle is increasing linearly with time $t$ as $bt$. The particle starts from rest from the origin. The velocity will be proportional to

Two blocks of masses $3\text{kg}$and $6\text{kg}$ respectively are placed on a smooth horizontal surface. They are connected by a light spring of force constant $k=200\text{N/m}$. Initially the spring is unstretched. The indicated velocities are imparted to the blocks. Find the maximum extension of the spring.

For a series LCR circuit, $L=2\text{H},C=32\mu \text{F}$ and $R=10\Omega$. What will be the magnitude of Q-factor at resonance?

The longest wavelength in Lyman series of hydrogen atom spectrum corresponding to $H_{\alpha }$ line is approximately.

Figure shows , three spherical and equipotential surfaces (marked $1,2$ and $3$ in the figure) around a point charge $q$. If the potential difference $V_1-V_2=V_2-V_3$ and $t_1$ and $t_2$ be the distances between them, then which of the following is true?

Find the fundamental, first overtone and second overtone frequencies of an open organ pipe of length 20 cm. Speed of sound in air is 340$m{s}^{-1}$.

Acceleration of the particle in a rectilinear motion is given as $a=2t-2$ in $\left(m/s^2\right)$. The final position of the particle as a function of time $t$ is

(Given that at $t=0,u=2m/s,x=4m$)

A block of mass $2\text{kg}$ rests on a rough inclined plane making an angle of ${30}^{\circ }$ with the horizontal. The coefficient of static friction between the block and the plane is $0.7$. The frictional force on the block is

A particle of mass $m$ and charge $Q$ is placed in an electric field of intensity $E,$ which varies with time $t$ as $E=E_0\sin \omega t.$ It will undergo simple harmonic motion of amplitude

Truth table for the given circuit is

Two bodies of mass $1\text{Kg}$ and $3\text{Kg}$ have position vectors $\hat{i}+2\hat{j}+\hat{k}$ and $-3\hat{i}-2\hat{j}+\hat{k}$ respectively. The centre of mass of this system has a position vector