Four 20 Ω resistors are connecting in series with a 6 V battery. a) Draw a...

A circuit consists of two resistors, 1.80 Ω and 9.79 Ω, connected in series. The combination...

A circuit consists of two resistors, 1.80 Ω and 9.79 Ω, connected in series. The combination of resistors is connected to a 12.0 V battery. Calculate a) the equivalent resistance of the circuit, b) the current in the circuit, and c) the total power usage of the circuit.

A 24-V battery is connected to two resistors, 56.0 Ω and 82.0 Ω, which are joined...

A 24-V battery is connected to two resistors, 56.0 Ω and 82.0 Ω, which are joined together in series. (a) What is the current and power for each resistor? (b) What is the current and power for each resistor if you join them in parallel instead?

​Two resistors, each with a resistance of 200 M​Ω are connected in parallel. Two capacitors, each...

​Two resistors, each with a resistance of 200 M​Ω are connected in parallel. Two capacitors, each with a capacitance of 10 ​μ​F are connected in series. The combination of resistors and the combination of capacitors are then connected in series with a battery supplying an emf of 12 V. The electrical circuit is completed. The capacitors are uncharged at the beginning. (a) Illustrate the circuit. (b) Calculate the capacitive time constant of the circuit. (c) What fraction of the final...

Draw your own circuit with four resistors (50 Ω, 100 Ω, 120 Ω, ,140 Ω).  Try to...

Draw your own circuit with four resistors (50 Ω, 100 Ω, 120 Ω, ,140 Ω).  Try to make some resistors in parallel with each other, and others in series with each other. Find the equivalent resistance of your circuit. If you want extra practice, attach a 3V battery to your circuit and find the current through each resistor and the electric potential across each resistor.

A 10.7-V battery, a 4.91-Ω resistor, and a 10.7-H inductor are connected in series. After the...

A 10.7-V battery, a 4.91-Ω resistor, and a 10.7-H inductor are connected in series. After the current in the circuit has reached its maximum value, calculate the following. (a) the power being supplied by the battery (b) the power being delivered to the resistor (c) the power being delivered to the inductor (d) the energy stored in the magnetic field of the inductor

You are supplied with three resistors, with R_1=10 Ω, R_2=20 Ω and R_3=30 Ω, a 40.0...

You are supplied with three resistors, with R_1=10 Ω, R_2=20 Ω and R_3=30 Ω, a 40.0 mH inductor and a 10.0 V battery, and a switch. (a) Draw a circuit with all of these components which has 2nd lowest characteristic time. In your diagram, connect the inductor in series with the battery and leave the switch close. (b) In the circuit from (a), suppose the switch is now open. Find the current in the circuit after one characteristic time. (c)...

A 11.0-V battery, a 5.08-Ω resistor, and a 10.2-H inductor are connected in series. After the...

A 11.0-V battery, a 5.08-Ω resistor, and a 10.2-H inductor are connected in series. After the current in the circuit has reached its maximum value, calculate the following. (a) the power being supplied by the battery _______W (b) the power being delivered to the resistor _______W (c) the power being delivered to the inductor _______W (d) the energy stored in the magnetic field of the inductor _______J

Three resistors of 12 Ω , 12 Ω , and 6.0 Ω are connected in parallel....

Three resistors of 12 Ω , 12 Ω , and 6.0 Ω are connected in parallel. A 12-V battery is connected to the combination. What is the current through the 6.0 Ω resistor? Three capacitors of 12 μF, 12 μF, and 6.0 μF are connected in series. A 12-V battery is connected to the combination. What is the charge on the 6.0 μF capacitor?

4, 8, and 12 Ω resistors are connected series with 24 V battery. Find current through...

4, 8, and 12 Ω resistors are connected series with 24 V battery. Find current through each resistor and potential difference across individual resistors.

1.Two 60.0 Ω resistors are connected in parallel and this parallel arrangement is then connected in...

1.Two 60.0 Ω resistors are connected in parallel and this parallel arrangement is then connected in series with a 30.0 Ω resistor. The combination is placed across a 120V potential difference. Can you design the circuit diagram using above data? According to your observation show that total voltage is equal to the sum of the individual voltage and also show that total power dissipated is equal to the sum of the power dissipated by individual resistor. Also suggest what will...