The values for the components of the circuit shown in the figure are V = 15 V, C = 3.5 μF, and L = 150 mH. When the capacitor is fully charged, you simultaneously open switch S₁ and close switch S₂.

f = 219.65 Hz

q_max = 5.25 * 10^-5 C

i_o = 0.07245 A

What is the electromagnetic energy of the oscillating circuit, in joules? 

Transcribed Image Text:

The diagram is a schematic representation of an electrical circuit featuring the following components: 1. **Voltage Source (V):** Located on the right side of the circuit, it provides the necessary energy to the circuit. 2. **Switches (S₁ and S₂):** - **S₁:** Positioned at the top of the circuit. - **S₂:** Located at the bottom left. - These switches control the flow of current within different sections of the circuit. 3. **Capacitor (C):** Located in the middle, horizontally aligned. It stores electrical energy in an electric field. 4. **Inductor (L):** Positioned at the bottom, it is depicted with a coil symbol. This component stores energy in a magnetic field. **Circuit Operation:** - When switch S₁ is closed, the circuit is connected to the voltage source, allowing the capacitor to charge. - When switch S₂ is closed while S₁ is open, the charge stored in the capacitor can flow through the inductor, creating an oscillating LC circuit. This demonstrates electrical resonance and energy transfer between the capacitor and the inductor. This circuit configuration is often used to study the principles of oscillation in LC circuits, showcasing the interchange of energy between the capacitor and inductor.