let R2= 65 Ω

and calculate by hand please do if you only know thank you

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**Circuit Diagram Explanation** This diagram illustrates a simple electrical circuit featuring a voltage source, a resistor, a switch, an inductor, and a resistor in parallel with the inductor. Here’s a detailed breakdown of each component and its role within the circuit: 1. **Voltage Source (V2)**: - The diagram shows a voltage source labeled as V2 providing a constant voltage supply of 5 volts. It is grounded, indicating a common reference point for the circuit, typically zero volts. 2. **Resistor (R2)**: - R2 is located immediately after the voltage source. Its resistance value is not specified in the diagram. The resistor is used to limit the current flow within this part of the circuit. 3. **Switch (SW1)**: - The switch, labeled SW1, is placed in series after the resistor R2. It can be opened or closed to control the flow of current further in the circuit. When closed, it allows current to pass through, whereas when opened, it stops the current flow. 4. **Inductor (L1)**: - Labeled L1, this inductor has an inductance of 10 microhenries (μH). It is connected in series with the output node Vo. Inductors store energy in the form of a magnetic field when current flows through them, opposing changes in current. 5. **Resistor (R1)**: - R1 is a 50-ohm resistor connected in parallel with the inductor L1. The voltage across this resistor is the same as across the inductor when the circuit is closed. 6. **Output Node (Vo)**: - The output voltage is labeled Vo, which can be measured across the parallel combination of the inductor and resistor R1. This represents the point in the circuit where the output can be accessed and analyzed. **Operation of the Circuit**: - When switch SW1 is closed, the circuit is complete, allowing the current to flow from the voltage source through R2, into the Vo node, and then through both the inductor L1 and resistor R1. - The inductor L1 resists changes in current and works with R1 to form a parallel LC circuit. - Analysis of this circuit can help understand concepts such as transient response, time constants, and resonant frequency in RLC circuits. The behavior of this circuitry is fundamental in applications like filters and