Two circular rings of identical radii and resistance of `36Omega` each are placed in such a way that they cross each others centre `C_1` and `C_2` as shown in figure. Conducting joints are made at intersection point A and B of the rings. An ideal cell of emf 20 volts is connected across AB. The power delivered by cell is:

A tetrahedral is consisting of 6 identical wires as shown in figure. Each wire is having a resistance of 2Omega . When an ideal cell of emf 2V is connected across AB, as shown then the current through CD is

Five resistance, each of 5Omega are connected as shown in figure. Find the equivalent resistance between points (1) A and B , (2) A and C .

Two cells having emf's of 10 V and 8 V, and internal resistance of 1Omega (each) are connected as shown with an external resistance of 8Omega Find the current flowing through the circuit.

Four identical cells each having emf E and internal resistance r are connected in series to form a loop ABCD as shown in figure . Find potential difference across AB and AC .

A conducting circular ring is rotated with angular velocity omega about point A as shown in figure. Radius of ring is a find a. potential difference between points A and C b. potential difference between the points A and D .

Two circular rings each of radius a are joined together such that their planes are perpendicular to each other as shown in the figure. The resistance of each half part of the ring is indicated. A very small loop of mass m and radius r carrying a current I_(0) is placed in the plane of the paper at the common centre of each ring. The loop can freely rotate about any of its diametric axes. If the loop is slightly dispalced, find the time period of its oscillations. (Given ma=(2pimu_(0)I_(0))/(pi^(2))

Four idential cells each having e.m.f. E, internal resistance r are connected as shown in figure. Find the potential difference between: (i) A and B (ii) A and C

Six resistors, each of value 3Omega are connected as shown in the figure. A cell of emf 3V is connected across AB. The effective resistance across AB and the current through the arm AB will be :

A resistance of 4 Omega and a wire of length 5 meters and resistance 5 Omega are joined in series and connected to a cell of e.m.f. 10 V and internal resistance 1 Omega . A parallel combination of two identical cells is balanced across 300 cm of wire. The e.m.f. E of each cell is

As shown in figure a cell is connected across two points A and B of a uniform circular conductor of radius r. Prove that the magnetic field induction at its centre O will be zero.