Resistance R,2R,4R,8R ...... `oo` are connected in parallel. What is their resutlant resistance will be

The resistance 4R,16R,64R.... oo are connected in series. Find their equivalent resistance.

Two batteries of E_(1) internal resistance r_(1) & emf E_(2) internal resistance r_(2) are connected in parallel and makes a battery system. An external resistance R is connected across this system as shown in the figure.

Resistance n , each of r ohm , when connected in parallel give an equivalent resistance of R ohm . If these resistances were connected series, the combination would have a resistance in ohm, equal to

Two ideal batteries of emf V_1 and V_2 and three resistances R_1, R_2 and R_3 are connected as shown in the figure. The current in resistance R_2 would be zero if

Two resistors of resistance R_(1) and R_(2) having R_(1) gt R_(2) are connected in parallel. For equivalent resistance R, the correct statement is

Two resistors of resistance R_(1) and R_(2) having R_(1) gt R_(2) are connected in parallel. For equivalent resistance R, the correct statement is

Three resistors R_1, R_2 and R_3 are to be combined to form an electrical circuit as shown in the figure. It is found that when R_1 R_2 and R_3 are put respectively in positions A, B and C, the effective resistance of the circuit is 70 Omega When R_2, R_3 and R_1 are put respectively in position A, B and C the effective resistance is 35 Omega and when R_3, R_1 and R_2 are respectively put in the position A, B and C, the effective resistance is 42 Omega If R_(1), R_(2 )and R_(3) are all connected in parallel, the effective resistance will be

For two resistors R_1 and R_2 , connected in parallel, find the relative error in their equivalent resistance. if R_1=(50 pm2)Omega and R_2=(100 pm 3) Omega .

The resistance of a heater coil is 110 Omega . A resistance R is connected in parallel with it and the combination is joined in series with a resistance of 11 Omega to a 220 V main line. The heater operates with a power of 110 W . The value of R in Omega is

Let there be n resistors R_(1) . . . R_(n) with R_(max)=max(R_(1) . . . . R_(n)) and R_("min")=min{R_(1) . . . R_(n)} . Show that when they are connected in parallel the resultant resistance R_(p)=R_("min") and when they are connected in series, the resultant resistance R_(S) gt R_(max) . Interpret the result physically.