R R3 NI A 10k2 RL. RL. IN RN. Iko L1 R L2 Iko 5V Ika R В 10k2 N2 GND GND Figure 1: The Norton equivalent circuit. Implement the circuit shown in Figure I above on the provided board. This circuit will be used to verify the Norton equivalent circuit. Experimental Steps and Procedures: Once the circuit is correctly setup on the board, please perform the following tasks: 1) Disconnect the load (RL). Replace the source (Vs) with a short circuit and measure the total resistance between A and B. RN- I1.12 Ry = 2) Reconnect the source (Vs), short-circuit the load (R), and measure the current delivered to the load, IN. O,04 mA IN %3D 3) Find theoretically the Thevenin voltage VrA. 4) Compare this value to the value of VTh found in the session 3. 5) Calculate theoretically the current I at resistor RL. 6) Measure the current I at resistor RL 7) Compare between the theoretical and measured values of IL.

Q 3,4,5,6,7 

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Experimental Setup: R R3 NI A 10kN IL RL Vs RL. IN RN. Ika L1 R L2 Iko 5V Ika R B В 10kN N2 GND GND Figure 1: The Norton equivalent circuit. Implement the circuit shown in Figure 1 above on the provided board. This circuit will be used to verify the Norton equivalent circuit. Experimental Steps and Procedures: Once the circuit is correctly setup on the board, please perform the following tasks: 1) Disconnect the load (RL), Replace the source (Vs) with a short circuit and measure the total resistance between A and B. RN- RN ...... 2) Reconnect the source (Vs), short-circuit the load (R), and measure the current delivered to the load, IN. O,04 mA IN 3) Find theoretically the Thevenin voltage VrA. 4) Compare this value to the value of VTh found in the session 3. 5) Calculate theoretically the current I at resistor RL. 6) Measure the current I at resistor RL 7) Compare between the theoretical and measured values of IL.