(b) Series Resistors Circuit - KVL = (i) For the circuit of Figure 2.1a, assume the source-voltage, E = 15V, R₁ = 3.3 k2, R₂ 2.2 ΚΩ and R3 = 1.0 kn. Determine the expected current, I and the voltages across resistors R₁ (=Vab), R₂ (= Vbc) and R3 (=Vcd) for the respective values of resistors shown. Record your theoretical results in Table 2.1. Determine the sum EV = (Vab + Vbe + Ved) to verify the KVL law.

Please use the values provided for Figure 2.1a to calculate the expected current and voltages across the resistors. Include all calculations and steps, and record the results in Table 2.1. Ignore the MultiSIM input sections of the table. Verify KVL law as well. Thank you very much!

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(b) Series Resistors Circuit - KVL (i) For the circuit of Figure 2.1a, assume the source-voltage, E = 15V, R₁ = 3.3 kN, R₂= 2.2 k and R3 = 1.0 kn. Determine the expected current, I and the voltages across resistors R₁ (=Vab), R₂ (= Vbc) and R3 (=Vcd) for the respective values of resistors shown. Record your theoretical results in Table 2.1. Determine the sum EV = (Vab + Vbc + Ved) to verify the KVL law.

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E 15V E a I (mA) Theory MultiSIM result result R₁ b R₂ с R3 Figure 2.1a: KVL Series Circuit ab (Volts) Theory MultiSIM result result E A Vbc (Volts) Theory MultiSIM result result a + VE I R₁ cd (Volts) Theory MultiSIM result result b R₂ C R3 Figure 2.1b: KVL Series Circuit showing Voltmeter & Ammeter connections Vbc EV = (Vab + Vbc+ Ved) Theory result Table 2.1: Theoretical and MultiSIM results of the Series Circuit in Figure 2.1 MultiSIM result