1. Connect the network shown in Figure 6.7 after measuring and recording the actual value of each resistor used. Figure 6.7. Experimental series-parallel circuit. R, = 470 2 216 E = 470 2 463 220 2 B...

Extracted text: 1. Connect the network shown in Figure 6.7 after measuring and recording the actual value of each resistor used. Figure 6.7. Experimental series-parallel circuit. R, = 470 2 216 E = 470 2 463 220 2 B R4 = 330 n R5 = 100 2 Power supply 324 .101 2. Set the power supply voltage to 10 V. Then measure and record in Table 6.2 the current through and the voltage across each component, including the power supply. Be certain that you insert the ammeter in the correct locations for measuring the actual current in each component (observe polarity!) and always turn the power off before connecting the ammeter in a new location. Table 6.2 Measured resistance () Current Voltage (v) Component (A) power supply 10 R1 8.4744h -3.02 8.97-438).02 -8-8-4.31 1246 R2 463 R3 .463 .321 -1,29 82 Experiment 6


Extracted text: Note: Use the actual (measured) values of resistance in all calculations. 1. Solve the network of Figure 6.7 and compare your results with the measured values recorded in Table 6.2. Using the measured values recorded in Table 6.2, verify Kirchhoff's current law at junctions A, B, and C in Figure 6.7. Also verify Kirchhoff's voltage law around each closed loop in Figure 6.7. (There are four such loops in this figure.) 2. 3. Repeat steps 2 and 3 for the circuit of Figure 6.8 and Table 6.3.