Four rods of side length `l` have been hinged to form a rhombus. Vertex `A` is fixed to a rigid support, vertex `C` is being moved along the `x`-axis with constant velocity `V` as shown in figure. The rate at which vertex `B` is nearing the `x`-axis at the moment the rhombus is in the form of a squarem is

Four rods of equal mass m and length L . Forms a square ABCD as shown in figure. The moment of inertia of ABCD about the axis OO' passing through the point A is

A particle of mass m moves in the XY plane with constant velocity v along the straight line PQ as shown in the figure. Its angular momentum with respect to origin O is( theta is angle between vec v and x-axis)

A uniform rod AB of mass m and length L rotates about a fixed vertical axis making a constant angle theta with it as shown in figure. The rod is rotated about this axis, so that point B the free end of the rod moves with a uniform speed V in the horizontal plane then the angular momentum of the rod about the axis is:

A uniform rod AB of mass m and length L rotates about a fixed vertical axis making a constant angle theta with it as shown in figure. The rod is rotated about this axis, so that point B the free end of the rod moves with a uniform speed V in the horizontal plane then the angular momentum of the rod about the axis is:

Two straight conducting rails form a right angle where their ends are joined. A conducting bar in contact with the rails starts at the vertex at time t = 0 and moves with constant velocity v along them as shown in Fig. A magnetic field vec(B) is directed into the page. the induced emf in the circuit at any time t is proportional to

Two straight conducting rails form a right angle where their ends are joined. A conducting bar in contact with the rails starts at the vertex at time t = 0 and moves with constant velocity v along them as shown in Fig. A magnetic field vec(B) is directed into the page. the induced emf in the circuit at any time t is proportional to

A rod of length 'l' is placed along x-axis. One of its ends is at the origin. The rod has a non-uniform charge density lambda= a, a being a positive constant. Electric potential at P as shown in the figure is -

Four identical rods each of mass m and length l are joined to form a rigid square frame. The frame lies in the xy plane, with its centre at the origin and the sides parallel to the x and y axes. Its moment of inertia about

A rigid wire loop of square shape having side of length L and resistance R is moving along the x-axis with a constant velocity v_(0) in the plane of the paper. At t=0 , the right edge of the loop enters a region of length 3L where there is a uniform magnetic field B_(0) into the plane of the paper, as shown in the figure. For sufficiently large v_(0) , the loop eventually crosses the region. Let x be the location of the right edge of the loop. Let v(x),I_(x) and F_(x) represent the velocity of the loop, current in the loop, and force on the loop, respectively, as a function of x. Counter-clockwise curren is taken as positive. Which of the following schematic plots (s) is are correct ? (Ignore gravity )

A particle of mass m and charge -q enters the region between the two charged plates initially moving along x-axis with speed v_(x) as shown in figure. The length of plate is L and a uniform electric field E is maintained between the plates. The vertical deflection of the particle at the far edge of the plate is