Activity 2.4 1. The following values were calculated from an \( R L C \) circuit. Draw a neat phasor diagram of this circuit with labels. \( V_{L}=232,5139^{\circ} \mathrm{V} \) \( V_{C}=165-142^{\circ} \mathrm{V} \) \( V_{R}=62 \angle-52^{\circ} \mathrm{V} \) \( I_{\mathrm{T}}=5,2 \angle-52^{\circ} \mathrm{A} \) \( V_{\mathrm{T}}=20010^{\circ} \mathrm{V} \)

When you're putting together a phasor diagram for an \( RLC \) circuit, it's essential to visualize how the different voltages relate to one another. Start by plotting the voltage across the resistor (\( V_R = 62 \angle -52^\circ \mathrm{V} \)) on the real axis since it is in phase with the current. Then, draw \( V_L = 232.5 \angle 139^\circ \mathrm{V} \) 90 degrees ahead of \( V_R \) since inductive voltage leads current. Next, plot \( V_C = 165.0 \angle -142^\circ \mathrm{V} \), which will be 90 degrees behind \( V_R \). Finally, combine these to find your total voltage \( V_T = 200.0 \angle 10^\circ \mathrm{V} \), ensuring all angles are accurately represented! Now, for crafting an epic phasor diagram, be sure to highlight the direction of the vectors based on their angles. Consider using different colors for each phasor to make the diagram pop and clearly show their relationships. Label all vectors and angles, making it easy for anyone to follow the actions of your circuit! A neat tip is to keep the lengths of the phasors proportional to the magnitudes of the voltages; this visually represents the relationships effectively!