The resistance of metal sheet 1 between the shaded portion is `R_1` and Resistance between shaded portion for sheet 2 `R_2` the `R_1//R_2` is

The resistance of metal sheet 1 between A and B is R_1 and the resistance of sheet 2 between A' and B' is R_(2) . The value of the ratio (R_1)/(R_2) is

Find the ratio between the area of the shaded and the unshaded portions of the following figure

The circuit has resistors of equal resistance R. The equivalent resistance between A and B, when key is closed is R_1 and when key is open is R_2 . Find the ratio R_1 and R_2 .

With two resistance R_1 and R_2 (>R_1) in the two gaps of a metre bridge the balance was found to be 1/3 m from the zero end. When a 6 Omega resistance is connected in series with the smaller of the two resistance, the point is shifted to 2/3 m from the same end, then R_1 and R_2 are

For infinite ladder network containing identical resistance of R Omega each, are combined as shown in figure. The equivalent resistance between A and B is R_(AB) and between A and C is R_(AC) . Then the value (R_(AB))/(R_(AC)) is :

A galvanmeter of resistance G is converted into a voltmeter of range 0 -1V by connecting resistance R_1 in series with it. The additional resistance that should be connected in series with R_1 to increase the range of the voltmeter to 0-2 V will be :

As shown, the circuit is made of 8 different resistance. It is found that when R_(1) = 4 Omega , the resistance between A and B is 2 Omega . Now replace R_(1) by a 6 Omega resistor, what is the resistance between A and B ?

Six wires each of resistance r form a tetrahedron. The equivalent resistance between corners 1-2 and 1-3 are respectively

The circuit diagram shwon in the fig consist of a large number of elementws (each element has two resistors R_1 and R_2. The resistance of the resistors in each subsequent element differs by a factor of k= 1/2 from the resistance of the resistors in previous elements find the equivalent resistance between A and B shown in

In the circuit shown, both cells are ideal and of fixed emf, the resistance of resistance R_(1) has fixed resistance and the resistance of resistor R_(2) can be varied (but the value of R_(2) is not zero). Then: