In the circuit given E = 6.0 V, R1 = 100 ohms, R2 = R3 = 50 ohms, R4 = 75 ohms. The equivalent resistance of the circuit, in ohms, is
(1) 11.875
(2) 26.31
(3) 118.75
(4) None of these
By using only two resistance coils-singly, in series, or in parallel one should be able to obtain resistances of 3, 4, 12, and 16 ohms. The separate resistances of the coil are :
(1) 3 and 4
(2) 4 and 12
(3) 12 and 16
(4) 16 and 3
In the adjoining circuit, the battery E1 has an e.m.f. of 12 volts and zero internal resistance while the battery E has an e.m.f. of 2 volts. If the galvanometer G reads zero, then the value of the resistance X in ohm is
(1) 10
(2) 100
(3) 500
(4) 200
The magnitude and direction of the current in the circuit shown will be
(1) A from a to b through e
(2) A from b to a through e
(3) 1A from b to a through e
(4) 1A from a to b through e
The e.m.f. of a cell is E volts and internal resistance is r ohm. The resistance in external circuit is also r ohm. The p.d. across the cell will be
(1) E/2
(2) 2E
(3) 4E
(4) E/4
Kirchhoff's first law i.e. at a junction is based on the law of conservation of :
(1) Charge
(2) Energy
(3) Momentum
(4) Angular momentum
The figure below shows currents in a part of electric circuit. The current i is
(1) 1.7 amp
(2) 3.7 amp
(3) 1.3 amp
(4) 1 amp
In the circuit shown, A and V are ideal ammeter and voltmeter respectively. Reading of the voltmeter will be
(1) 2 V
(2) 1 V
(3) 0.5 V
(4) Zero
The terminal potential difference of a cell when short-circuited is (E = E.M.F. of the cell)
(1) E
(2) E/2
(3) Zero
(4) E/3
The potential difference in open circuit for a cell is 2.2 volts. When a 4-ohm resistor is connected between its two electrodes the potential difference becomes 2 volts. The internal resistance of the cell will be :
(1) 1 ohm
(2) 0.2 ohm
(3) 2.5 ohm
(4) 0.4 ohm