Don't use chatgpt will upvote and provide solution in Handwritten form neat and clean and please be quick as soon as possible

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Collect the same data, VD and averages at voltage settings 0V, IV, 2V, 4V, 6V, and 8V in Table 4-2 below. Table 4-2 Vpower(V) 0 1 2 6 8 Vo( .966 1.947 3.900 5.850 7.805 love 0 ,009 .019 .039 .058 .078 Graph the data and fit it the same way. 5. Slope 6. 99.x Intercept 0348 Take a screen-shot for your report. Compute your experimental resistance value's % error from the nominal value. Part C: Both Resistors in Series Treated as One Item Move the yellow wire (and red voltmeter lead) to the socket below the 33 resis- tor, so the indicated current (after being measured by ammeter A) will travel "up" through the 332 then down through the 1000 (to be measured again, by ammeter B). Notice how the voltage probe in D will be measuring the total voltage across both resistors (which should be almost the same as the set V). Collect the same data, V and at voltage settings 0V, 1V, 2V, 4V, 6V, and 8V in Table 4-31 below. Table 4-3 0 1 2 power 6 8 V₂M 0 972 1.958 3.921 5.883 7.848 4 .007 .014 029 .044 .059 Graph the data and fit it the same way as for the individual resistors. Slope 132.6 Intercept Take a screen-shot for your report. 0489 Now we should see how the power supply's voltage is divided among the devices. Move voltmeter D's black lead (but not the blue/green wire that connects the 10 to ammeter B) to the socket between the resistors, so it will measure the 33's voltage. Plug another voltmeter probe into port C and connect its tips across the 10. Set the 850 to output 8V, and record data here: V5.9 V V₁ 1.94 (V100 + V33) 7.84 V 39