Table 4 AV1=5V AV2=3V R(Q) im(A) 0.010 R1 100 R2 200 0.010 R3 330 0.006 4. Using Kirchhoff's Rules, construct enough mathematically independent equations to solve for the current of each resistor. Then calculate the % error between your measured and theoretical values for the current of each resistor. You MUST use Kirchhoff's Rules and show work it(A) % Error

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**Table 4** \[ \begin{array}{|c|c|c|c|c|} \hline & R(\Omega) & i_m(A) & i_t(A) & \% \text{ Error} \\ \hline \text{R1} & 100 & 0.010 & & \\ \text{R2} & 200 & 0.010 & & \\ \text{R3} & 330 & 0.006 & & \\ \hline \end{array} \] **Conditions:** \(\Delta V1 = 5V, \Delta V2 = 3V\) 4. Using Kirchhoff’s Rules, construct enough mathematically independent equations to solve for the current of each resistor. Then calculate the % error between your measured and theoretical values for the current of each resistor. You MUST use Kirchhoff’s Rules and **show work**.

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**Setup #4: Circuit Diagram Explanation** This diagram illustrates an electrical circuit with three resistors and two voltage sources. - **R1 and R2** are connected in series at the top of the circuit. - **R3** is connected in series at the bottom of the circuit with the voltage source labeled **V1**. - The voltage source labeled **V2** is placed between R1/R2 and R3, forming a parallel connection to V1 and R3. The resistors (R1, R2, R3) limit the flow of electric current, while the voltage sources (V1, V2) provide the necessary potential difference to drive current through the circuit. Understanding the configuration of this circuit is crucial for analyzing the total resistance and voltage across different components.