8. For the circuit in Figure 2, determine and draw the Norton's Equivalent circuit. Also, determine the current, I, and the power dissipated in the load by change the value of the load impedance Z, when the value of the capacitor changes. It is required to record your result in table 3. Z, Table 3 calculated values I, V. P. = 1, *V,

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3. For the circuit in Figure 2, determine and draw the Norton's Equivalent circuit. Also, determine the current, I, and the power dissipated in the load by change the value of the load impedance Z, when the value of the capacitor changes. It is required to record your result in table 3. Z, Table 3 calculated values I. P. =1, *V, V. 4. Plot P, versus R, using Excel or MATLAB. It is required to figure out the maximum power transfer to the load. R R2 W 000 3300 150 n ImH E = 5V20° (N luF Figure 2

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Exercises part: 1. For the circuit in Figure 1, determine and draw the Thevenin Equivalent circuit. Also, determine the current, I, and the power dissipated in the load. The load impedance Z, is changed as shown in table 2 when Z, = R- X, where Z, = R, ±X. Table 2 calculated values R, V. I. P, = 1, *V, 1.8- X, 2 10-X, 2 22 - х, 2 100 –X, 2 330- Х, 2 560 -X, 2 1-X, kQ 2.2-X, k2 10-X, k2 56-X, k2 2. Plot P, versus R, using Excel or MATLAB. It is required to figure out the maximum power transfer to the load. R 330 0 1 mH E = 5VZ 0° 1 uF f=1000HZ Figure 1.