Complete both the nodal analysis and mesh analysis sections of Table 3.0. Include all calculations and steps. Ignore the MultiSIM input sections when completing Table 3.0. Thank you very much!

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E R₁ = 2.2 k Va (Volts) Vb (Volts) Ve (Volts) IA (mA) IB (mA) Ic (mA) Ix (mA) Figure 3.0a: Circuit for Nodal Analysis Vx (Volts) I₁ (mA) I2 (mA) R3 = 1.0 kn M 13 (mA) R4 = 3.3 ΚΩ b R₂ = 5.1 kn lx Theoretical value MultiSIM value Theoretical value MultiSIM value Theoretical value MultiSIM value Theoretical value MultiSIM derived Theoretical value MultiSIM derived Theoretical value MultiSIM derived Theoretical value MultiSIM value Theoretical value MultiSIM value Theoretical value MultiSIM value Theoretical value MultiSIM value Theoretical value MultiSIM value <= => => => => => => => => => => => => => => => => => => => с => www Rς = 1.0 ΚΩ Nodal Analysis 13 → R₁ = 2.2 kn www 4₁ → R₂ = 1.0 kn IA IB: | = 3.3 ΚΩ lx R2 = 5.1 ΚΩ 1₂ → Ic Figure 3.0b: Circuit for Mesh Analysis Mesh Analysis C Table 3.0: Theoretical and MultiSIM results of the Figure 3.0 circuits Rς = 1.0 ΚΩ

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(b) Nodal and Mesh Analysis Consider the circuits in Figure 3.0, and assume input power supply, E = 15V. (i) Nodal Analysis: Select node "d" as a ground reference node as shown in Figure 3.0a. Using the nodal analysis technique, calculate the node voltages Va, V₁ and Vc. Using theses calculated node voltages, determine the value of the branch current, Ix and the branch voltage, Vx. Record all your results in Table 3.0. (ii) Mesh Analysis: Using the mesh analysis technique on the circuit shown in Figure 3.0b, calculate the mesh currents IA, IB and Ic; and determine the branch currents, I₁, I2, I3 and Ix; and the branch voltage, Vx. Record all your results in Table 3.0.