In the circuit shown, the resistance are given ohms and the battery is assumed ideal with end equal to 3.0 volts. The resistance that dissipates the maximum power is

In the circuit shown, the resistances are given in ohms and the battery is assumed ideal with emf equal to 3.0 V.

In the circuit shown, the average power dissipated in the resistor is (assume diode to be ideal)

In the given circuit, the resistances are given in ohm. The current through the 10Omega resistance is 3 A while that through the resistance X is 1 A. No current passes through the galavanometer. The values of the unknown resistances X and Y are respectively (in ohm)

In the circuit shown, total power supplied by an ideal battery is 80 W. if R = 10 Omega . If the resistance R is removed from the circuit. Then

In the circuit shown in the figure , the resistance marked R can be varied by using a Rheostat. The power across the 5 Omega resistor will be maximum if the Rhoestat has resistance equal to

In the circuit shown the resistance of voltmeter is 10000 ohm and that of ammeter is 20 ohm . The ammeter reading is 0.10 amp and voltmeter reading is 12 volts. Then R is equal to

Resistors P , Q , and R in the circuit have equal resistances. If the battery is supplying a total power of 12 W , what is the power dissipated as heat in resistors R ?

In a circuit shown in figure if the internal resistances of the sources are negligible then at what value of resistance R will the thermal power generated in it will be the maximum. What is the value of maximum power?

In the circuit shown the resistance R is kept in a chamber whose temperature. is 20^(@) C which remains constant. The initial temperature and resistance of R is 50^(@)C and 15 Omega respectively. The rate of change of resistance R with temperature is (1)/(2)Omega//^(@)C and the rate of decrease of temperature of R is In (3//100) times the temperature difference from the surrounding (Assume the resistance R loses heat only in accordance with Newton's law of cooling) If K is closed at t = 0, then find the (a) value of. R for which power dissipation in it is maximum. (b) temperature of R when power dissipation is maximum (c) time after which the power dissipation will be maximum

The power dissipated in the resistance R, in the circuit as shown in the figure, is maximum if R is equal to