In the figure shown for given values of `R_1` and `R_2` the balance point for Jockey is at `40cm` from `A`. When `R_2` is shunted by a resistance of `10Omega`, balance shifts to `50cm`. `R_1` and `R_2` are (`AB=1m`):

In the figure shown for given values of R_1 and R_2 the balance point for Jockey is at 40cm from A . When R_2 is shunted by a resistance of 10Omega , balance shifts to 50cm . R_1 and R_2 are ( AB=1cm ):

The figure shown gives values of R_(1 ) and R_(2), the balance point for jockey is at 30 cm from A. When R_(2) is shunted by a resistance of 10 Omega, jockey has to slide 20 cm to obtain balance point. The values of R_(1) and R_(2) are

In a metre bridge, the gaps are closed by two resistance P and Q and the balance point is obtained at 40 cm . When Q is shunted by a resistance of 10 Omega , the balance point shifts to 50 cm . The values of P and Q are. .

An unknown resistance R_(1) is connected is series with a resistance of 10 Omega . This combination is connected to one gap of a meter bridge, while other gap is connected to another resistance R_(2) . The balance point is at 50 cm Now , when the 10 Omega resistance is removed, the balanced point shifts to 40 cm Then the value of R_(1) is.

Two resistances are connected in two gaps of slide wire bridge. The balance point is at 40cm from left end. A resistance X is connected in series with smaller resistance R and balance point shifts to 40cm from right end. What is the value of X if R is 4Omega ?

The resistance in the left and right gaps of a balanced meter bridge are R_(1) and R_(1) . The balanced point is 50 cm . If a resistance of 24 Omega is connected in parallel to R_(2) , the balance point is 70 cm . The value of R_(1) or R_(2) is.

In a metre bridge when the resistance in the left gap is 2Omega and an unknown resistance in the right gap, the balance point is obtained at 40 cm from the zero end. On shunting the unknown resistance with 2Omega find the shift of the balance point on the bridge wire.