An infinite sequence of resistance is shown in the figure. The resultant between `A` and `B` will be, when `R_(1) = ohm` and `R_(2) = 2 ohm`

Six resistors of each 2 ohm are connected as shown in the figure. The resultant resistance between A and B is.

Four identical resistances are joined as shown in the figure. The equivalent resistance between points A and B is R_(1) and that between A anc C is R_(2) then ratio R_(1)//R_(2) is

An infinite network of resistances has been made as shown in the figure. Each resistance is R. find the equivalent resistance between A and B.

For the network of resistance shown in the figure the equivalent resistance of the network between the points A and B is 18 ohm. The value of unknown resistance R is :

For the network of resistance shown in the figure the equivalent resistance of the network between the points A and B is 18 ohm. The value of unknown resistance R is :

For the network of resistance shown in the figure the equivalent resistance of the network between the points A and B is 18 ohm. The value of unknown resistance R is :

For infinite ladder network containing identical resistance of R Omega each, are combined as shown in figure. The equivalent resistance between A and B is R_(AB) and between A and C is R_(AC) . Then the value (R_(AB))/(R_(AC)) is :

For infinite ladder network containing identical resistance of R Omega each, are combined as shown in figure. The equivalent resistance between A and B is R_(AB) and between A and C is R_(AC) . Then the value (R_(AB))/(R_(AC)) is :

For infinite ladder network containing identical resistance of R Omega each, are combined as shown in figure. The equivalent resistance between A and B is R_(AB) and between A and C is R_(AC) . Then the value (R_(AB))/(R_(AC)) is :