12 M R1 120 VAC 13.2 H L1 1k2 MW R2 60 Hz

5. The voltage drop across R1 is _______. Vhttps://blackboard.fvtc.edu/courses/1/83026/content/_12803272_1/5021316190/media/1033/10234.gif 111.3v 48.8 V 22.4 V 12 V

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### Series R-L-R Circuit Analysis **Diagram Description:** The diagram represents a series R-L-R (Resistor-Inductor-Resistor) circuit connected to an AC power source. Below is a detailed explanation of the components and their values: - **R1 (Resistor 1):** 1 kΩ (kilo-ohms) - **L1 (Inductor):** 13.2 H (henries) - **R2 (Resistor 2):** 1 kΩ (kilo-ohms) **Power Source:** - **Voltage:** 120 VAC (Volts Alternating Current) - **Frequency:** 60 Hz (Hertz) **Explanation:** This circuit configuration consists of two resistors and one inductor arranged in series. Each component is denoted by its labeled symbol and value on the schematic. - The resistors, R1 and R2, each have a resistance of 1 kΩ, which contributes to the total resistive impedance of the circuit. - The inductor, L1, has an inductance of 13.2 H, influencing the circuit's reactance and overall impedance, depending on the frequency of the AC supply. The AC power source provides a sine wave input with a voltage of 120 volts and a frequency of 60 Hz. The interaction of resistive and inductive elements in this circuit will result in a phase shift between voltage and current, characteristic of R-L circuits. This setup is a fundamental example used to study the behavior of AC circuits with reactive components, demonstrating the principles of impedance, reactance, and resonance.