A long straight wire having uniform resistance per uni length `lamda` (ohms/metre) is bent into `V`-shape as shown (angle `DAC=alpha`). A uniform and constant magnetic field `B` (tesla) exists in space which is perpendicular to the plane of `V`- shaped wired. Another straight wire `EF` of same uniform resistance per unit length `lamda` (ohms/metre) is pulled with constant velocity `u` (m/s) such that the wire `EF` is always perpendicular to side `AD` of `V` -shape (the wire `EF` is always in conducitng contact with the `V`- shaped wire at two points).At `t=0` (`t` is the time is seconds) the value of `x=0` (`x=` distance of wire `EF` from end `A` in metres)
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A long straight wire having uniform resistance per uni length lamda (ohms/metre) is bent into V -shape as shown (angle DAC=alpha ). A uniform and constant magnetic field B (tesla) exists in space which is perpendicular to the plane of V - shaped wired. Another straight wire EF of same uniform resistance per unit length lamda (ohms/metre) is pulled with constant velocity u (m/s) such that the wire EF is always perpendicular to side AD of V -shape (the wire EF is always in conducitng contact with the V - shaped wire at two points).At t=0 ( t is the time is seconds) the value of x=0 ( x= distance of wire EF from end A in metres) The magnetic force acting on the wire EF due to uniform magnetic field B at any time t (in N ) is

A straight wire of length 0.5 metre and carrying a current of 1.2 ampere is placed in a uniform magnetic field of induction 2 tesla. If the magnetic field is perpendicular to the length of the wire , the force acting on the wire is

A straight wire of length L is bent into a semicircle. It is moved in a uniform magnetic field with speed v with diameter perpendicular to the field. The induced emf between the ends of the wire is

A conducting wire MN carrying a current I is bent into the shape as shown and placed in xy plane. A uniform magnetic field vecB=-Bhatk is existing in the region. The net magnetic force experenced by the conducting wire MN is

A V-shaped conducting wire is moved inside a magnetic field as shown in figure. Magnetic fiel d is perpendicular to paper inwards. Then

Figure shows a wire sliding on two parallel, conducting rails placed at a separation L . A magnetic field B exists in a direction perpendicular to the plane of the rails. What force is necessary to keep the wire moving at a constant velocity V ?

A copper wire bent in the shape of a semicircle of radius r translates in its plane with a constant velocity v. A uniform magnetic field B exists in the direction perpendicular to the plane of the wire. Find the emf induced between the ends of the wire if (a) the velocity is perpendicular ot the diameter joining free ends, (b) the velocity is parallel to this diameter.

A straight wire of length 1 m, and carrying a current of 1.8 A, is placed in a uniform magnetic field of induction 2T. If the magntic field is perpendicular to the length of the wire, then the force acting on the wire is

A straight wire of length 0.5 m carrying a current of 1.6 ampere is placed in a uniform magnetic field of induction 2 T. If the magnetic field is perendicular to the length of the wire, then force on the wire is

A wire KMN moves along the bisector of the angle theta with a constant velocity v in a uniform magnetic field B perpendicular to the plane of the paper and directed inward. Which of the following is correct?