Given `R_(1) = 5.0 +- 0.2 Omega, and R_(2) = 10.0 +- 0.1 Omega`. What is the total resistance in parallel with possible `%` error?

Two resistances R_(1) = 100 +- 3 Omega and R_(2) = 200 +- 4 Omega are connected in series . Find the equivalent resistance of the series combination.

Two resistances R_(1) = 100 +- 3 Omega and R_(2) = 200 +- 4 Omega are connected in series . Find the equivalent resistance of the series combination.

Two resistor R_(1) = (24 +- 0.5)Omega and R_(2) = (8 +- 0.3)Omega are joined in series, The equivalent resistence is

You are given two resistance R_(1)=(4.0+-0.1)Omega and R_(2)=(9.1+-0.2)Omega . Calculate their effective resistance when they are connected (i) in series and (ii) in parallel. Also calculate the percentage error in each case.

Two resistor of resistance R_(1)=(6+-0.09)Omega and R_(2)=(3+-0.09)Omega are connected in parallel the equivalent resistance R with error (in Omega)

In the circuit shown in Fig. the emf of the sources is equal to xi = 5.0 V and the resistances are equal to R_(1) = 4.0 Omega and R_(2) = 6.0 Omega . The internal resistance of the source equals R = 1.10 Omega . Find the currents flowing through the resistances R_(1) and R_(2) .

The values of two resistors are R_(1)=(6+-0.3)kOmega and R_(2)=(10+-0.2)kOmega . The percentage error in the equivalent resistance when they are connected in parallel is

The figure shows an infinite circuit formed by the repetiton of the same link , consisting of resistance R_(1) = 4.0 Omega and R_(2) = 3.0 Omega . Find the resisance of this circuit between points A and B.

The resistance R = V//i , where V = 100 +- 5 V and I = 10+- 0.2 A . What is the total error in R ?

Two resistors of resistance R_1 = 2 Omega and R_2= 1 Omega are connected in parallel with a current source of 3 A. Draw the arrangement and deduce the current I_1" in "R_1 and I_2" in "R_2.