A resistor is in the left gap and a (NTC) semiconductor is in the right gap of a meter bridge. Balancing length is noted `(l)`. Both are heated so that charge of resistance in them is the same. Now balancing length is

Two resistances of 4 Omega are connected in the 2 gaps of a metre bridge. Balancing length is noted. Another equal resistance is connected in parallel with 4 Omega in the left gap. Change in balancing length is approximately

With a resistance P Omega in the left gap and another resistance Q Omega in the right gap of a meter bridge, the balance point is obtained at 40 cm. When a resistance of 6 Omega is connected across Q, the balance point shifts to 50 cm. The value of resistance P is

In metre bridge experiment, with a standard resistance in the right gap and a resistance coil dipped in water (in a beaker) in the left gap, the balancing length obtained is .t.. If the temperature of water is increased, the new balancing length is

An unknown resistance R_1 is connected in series with a resistance of 10 ohm . This combination is connected to one gap of meter bridge while a resistance R_2 is connected in other gap. The balance point is at 50 cm . Now, when the 10 ohm resistance is removed balance point shifts to 40 cm . The value of R_1 is (in ohm)

In a metre bridge a copper coil is connected in the right gap and a resistance of 10 Omega in the left gap. The balance point is obtained at 0.2 m. The resistance of the coil is

If 10 Omega is unplugged from a standard resistance box and 33 1/3 cm is the balancing length obtained in the metre bridge, then calculate the resistance of the wire.

Two resistances are connected in two gaps of a metre bridge. The balance point is 20 cm from the zero end. A resistance of 15 ohm is connected in series with the smaller of the two. The null point shifts to 40 cm. The value of the smaller resistance, in ohm is