Three resistors (R1 = 6 Ω, R2 = 20 Ω and R3 = 8 Ω) are connected in a circuit as shown in the figure. What is the magnitude of the current in the R3 in the middle branch of the circuit if ε1 = 8 V and ε2 = 20 V? Hint: Use Kirchhoff's rules.
Three resistors R1-81.3 Ω, R2-20.5 Ω, R3 = 70.0 Ω, and two batteries ε1-40.0 V, and ε2-360 v are connected as shown in the diagram below. Ri R2 R3 E2 (a) What current flows through R1, R2, and R3? 11 = (No Response). A 12 (No Response). A I3No Response) A (b) What is the absolute value of the potential difference across R1, R2, and R3? AVRiNo Response) V IAVRzl = (No Response) V AVR3(No Response) V
Consider the circuit below with three resistors Two resistors, R2 (10 Ω) and R3 (10 Ω) are connected in parallel to another resistor R1 (5 Ω). And the circuit is connected to a 20 V power supply 9. Find the equivalent resistance (R) of the circuit shown above. (3 pts) Answer 10. Find the current that goes through R1. (4 pts) Answer 11. Find the potential difference through resistors in parallel (R2 and R3). (4 pts) Answer
14) Three resistors (R1 = 9.0 Ω, R2 = 18 Ω and R3 = 28 Ω are connected to a 12-V battery in a circuit as shown below. Calculate the voltage across R2. Use the combination method to solve the problem. (Answer in Volts) RI R3 R2 AV
Consider the circuit shown in (Figure 1). The batteries have emfs of ε1 = 9.0 V and ε2 = 12.0 V and the resistors have values of R1 = 27Ω, R2 = 60 Ω, and R3 = 33 Ω. Determine the magnitudes of the currents in each resistor shown in the figure. Ignore internal resistance of the batteries. Determine the directions of the currents in each resistor. Ignore internal resistance of the batteries.
Consider the following circuit of three resistors (R1, R2, and R3), with batteries that have emfs ε1 = 11 V and ε2 = 44.5 V, and internal resistances r1 and r2.Part (a) Find the current I1, in amps.Part (b) Find the current I0, in amps.Part (c) Find the current I3 in amps.
QUESTION 6 In the circuit shown in the figure below R1 . 3.8 Ω R2·6 Ω R3 2.8 Ω 11 . 3.1 A 12 5.4 Aand -1 9 A Calculate the po er produced or consumed y the emf2 (Give your answer in algebraic decimal: (+) if the emf produces electrical power and () of the emf consumes electrical power. Use "W" as unit) e1 e2 Ry QUESTION 7 In the circuit shown in the figure below ε1-8 V and...
The circuit shown in the figure below contains three resistors (R1, R2, and R3) and three batteries (VA, Vs, and V). The resistor values are: R1=2 Ohms, R2=R3=8 Ohms, and the battery voltages are Va=25 V. V8-15 V, and Vc=20 V. When the circuit is connected, what will be the power dissipated by R3? Vc R1 VA V: R₂ } R3 0.75 W 1.25 W 2.67 W 104.2 W 5.5 W
Three resistors, R1 2.0 Ω, R2:4.0 Ω, and R3:6.0 Ω are connected as shown in the figure below. For Circuit 1 (left), (a) Find the equivalent resistance of the combination; .e. [Req1] in Ohms. (b) Find the current that passes through the combination if a potential of 8.0 V is applied to the terminals: L.e. [Itot1] in A (c) Find the voltage across and the current through each resistor; L.e R1: Voltage: [VR11] V and Current: [IR11] A R2: Voltage:...
The circuit shown in the figure below contains three resistors (R1, R2, and R3) and three batteries (VA. VB, and Vc). The resistor values are: R1=2 Ohms, R=R3-8 Ohms, and the battery voltages are VA=25 V, V3=15 V, and Vc=20 V. When the circuit is connected, what will be the power dissipated by R3? Vc R₂3 VA HE R2 R₃ 0.75 W 1.25 W 2.67 W 4.2 W 5.5 W
The circuit shown in the figure below contains three resistors (R1, R2, and R3) and three batteries (VA, VB, and Vc). The resistor values are: R1=2 Ohms, R2=R3=6 Ohms, and the battery voltages are VA=25 V, V8=15 V, and Vc=20 V. When the circuit is connected, what will be the power dissipated by R2? VC HA R VA ++ VB R2 R3 1.0 W 2.0W 5.0 W 6.0 W 7.5 W