In my RC Circuits lab, the goal was to predict the time constant of each circuit using the theoretical model, and calculate the time constant of each circuit. The results from each IOLab measure are as follows: For measurement 1, The experimental value of τ is 1.0351 s and the theoretical value is 1 s. The percentage error is about 3.5 %. The absolute error is calculated by subtracting the theoretical value from the experimental value. In this case, the experimental value of τ is 1.0351 s and the theoretical value is 1 s. So, the absolute error is 1.0351 s - 1 s = 0.0351 s. The percentage error is calculated by dividing the absolute error by the theoretical value and then multiplying by 100. In this case, the absolute error is 0.0351 s and the theoretical value is 1 s. So, the percentage error is (0.0351 s / 1 s) * 100 = 3.51 %. For measurement 2, The experimental value of τ is 0.5920 s and the theoretical value is 0.56 s. The percentage error is about 3.2 %. The absolute error is calculated by subtracting the theoretical value from the experimental value. In this case, the experimental value of τ is 0.5920 s and the theoretical value is 0.56 s. So, the absolute error is 0.5920 s – 0.56 s = 0.032 s. The percentage error is calculated by dividing the absolute error by the theoretical value and then multiplying by 100. In this case, the absolute error is 0.0351 s and the theoretical value is 1 s. So, the percentage error is (0.032 s / 0.56 s) * 100 = 3.2 %. What can we conclude from the entire lab?
In my RC Circuits lab, the goal was to predict the time constant of each circuit using the theoretical model, and calculate the time constant of each circuit. The results from each IOLab measure are as follows:
For measurement 1, The experimental value of τ is 1.0351 s and the theoretical value is 1 s. The percentage error is about 3.5 %. The absolute error is calculated by subtracting the theoretical value from the experimental value. In this case, the experimental value of τ is 1.0351 s and the theoretical value is 1 s. So, the absolute error is 1.0351 s - 1 s = 0.0351 s. The percentage error is calculated by dividing the absolute error by the theoretical value and then multiplying by 100. In this case, the absolute error is 0.0351 s and the theoretical value is 1 s. So, the percentage error is (0.0351 s / 1 s) * 100 = 3.51 %.
For measurement 2, The experimental value of τ is 0.5920 s and the theoretical value is 0.56 s. The percentage error is about 3.2 %. The absolute error is calculated by subtracting the theoretical value from the experimental value. In this case, the experimental value of τ is 0.5920 s and the theoretical value is 0.56 s. So, the absolute error is 0.5920 s – 0.56 s = 0.032 s. The percentage error is calculated by dividing the absolute error by the theoretical value and then multiplying by 100. In this case, the absolute error is 0.0351 s and the theoretical value is 1 s. So, the percentage error is (0.032 s / 0.56 s) * 100 = 3.2 %.
What can we conclude from the entire lab?
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