In Fig. 27-37, the ideal batteries have emfs `epsi_(1)= 12.0 V and = epsi_(2)=0.500 epsi_(1)` and the resistances are each `4.00 Omega`. What is the current in (a) resistance 2 and (b) resistance 3?

In Fig 27-56, the ideal batteries have emf emf_(1)2=200V and epsi_(2)=50V and the resistances are R_(1)=3.0 Omega and R_(2)=2.0 Omega . If the potential at P is 100 V, what is at at Q?

In Fig. 27-63, R_1=100 Omega, R_2= 50 Omega, and the ideal batteries have emfs, epsi_(1)=6.0 V, epsi_(2)= 10 V, and epsi_(3) =4.0 V. Find (a) the current in resistor 1, (b) the current in resistor 2, and (c) the potential difference between points a and b.

Two batteries of emf epsi_(1) and epsi_(2)(epsi_(2) gt epsi_(1)) and internal resistance r_(1) and r_(2) respectively are connected in parallel as shown in figure.

In Fig. 27-51. battery 1 has emf epsi_(1)= 12.0 V and internal resistance r_1= 0.025 Omega and battery 2 has emf_(2)= 12.0 V and internal resistance r_2= 0.012Omega . The batteries are connected in series with an external resistance R. (a) What R value makes the terminal-to-terminal potential difference of one of the batteries zero? (b) Which battery is that?

The emf and resistances in the circuit of Fig 27-8a have the following values: epsi_(1)=4.4 V. epsi_(2)=2.1V , r_(1)=2.3 Omega, r_(2)=1.8 Omega, R=5.5 Omega (a) What is the current I in the circuit? (b) What is the potential difference between the terminals of battery 1 in Fig. 27 8a?