You calculated a value of 0.45 s ± 0.04 s for the time constant from your graph. If you used a 1MΩ resistor with a tolerance of 10%, what is the equivalent capacitance of your circuit (including the uncertainty)?
[Answer +/- Answer] F (MUST BE IN FARADS)
You calculated a value of 0.45 s ± 0.04 s for the time constant from your...
You calculated a value of 0.54 s ± 0.06 s for the time constant from your graph. If you used a 1MΩ resistor with a tolerance of 10%, what is the equivalent capacitance of your circuit (including the uncertainty)?
1) You calculated a equivalent capacitance of 0.42 μF ± 0.08 μF. If the manufacturer has labeled the capacitor as 0.5 μF ± 10%, is this consistent with your result? yes, no, or cannot be determined? 2) You calculated a value of 0.53 s ± 0.06 s for the time constant from your graph. If you used a 1MΩ resistor with a tolerance of 10%, what is the equivalent capacitance of your circuit (including the uncertainty)?
The time constant of a resistive/capacitive circuit is defined as: The product tC (time x capacitance) Time divided by RC (time/(resistance x capacitance)) The product VI (voltage x current) The product RC (resistance x capacitance) The function generator will be used to generate a square wave which will: Create a force on the resistor Charge and discharge the capacitor through the resistor Allow a graph to be produced on the computer Be converted to a sine wave through inductance There...
The time constant of a resistive/capacitive circuit is defined as: The product tC (time x capacitance) Time divided by RC (time/(resistance x capacitance)) The product VI (voltage x current) The product RC (resistance x capacitance) The function generator will be used to generate a square wave which will: Create a force on the resistor Charge and discharge the capacitor through the resistor Allow a graph to be produced on the computer Be converted to a sine wave through inductance There...
We calculated the capacticance of our capacitior in farads and we have to compare it to the listed capacitance of the capacitor as shown in the picture. When we do percent difference we get 200%... where did I mess up? That can't be right. The resistance of our resistor is 12970 ohms. Please explain this like you were talking to a child. Amicon 26936KO (M) 2000 F25V 81-POLAR NPS wire leads of the resistor to the table the body of...
tor is charged to an initial voltage of 1OV micro- discharge through a 40 kQ resistor. You take 10 is then tsof voltage versus time and record a vol 10 It is rements o and a voltage reading of.47 volts after 60 after 50 seco What is your percent of .47 volts after 60 seconds. ent error against the theoretical value of the voltage reading after three time constants? 6% -6% c.60% d. -60% What is the equation for the...
You are charging a 11895 μF capacitor that is in an R-C circuit with a resistor that has a nominal value of 7910 Ω. What is the charging time constant? τ= 94.08945s A typical 1/4 W resistor has a tolerance of 10% (shown by a silver fourth color band). If the capacitor has an uncertainty of ±7%, what is the uncertainty of the time constant? δτ= ____ s
3.4 Preliminary Assignment 1) The following table contains current/voltage pairs of points as determined from an experiment to verify Ohm's Law. A) Use graph paper and plot these points as voltage vs. current B) Does this device follow Ohm's Law? How do you know? C) Determine the value of the resistor used in this circuit. Current (Amps) -0.227 -0.180 -0.070 -0.022 +0.054 +0.126 +0.185 +0.258 Voltage (Volts) -2.320 -1.847 -0.721 -0.203 +0.586 +1.329 +1.937 +2.680 resistor. The 2) A (20.10.2),...
2. The time constant for any given RC circuit is the value of the effective resistance of the circuit multiplied by the effec- tive capacitance of the circuit. What is the value of the time constant for the circuit below? 20 ko 500 F 2000 5 500 2000 3. For the circuit below, the switch is closed and steady-state conditions have been reached, meaning the capacitor is full charged 10Ω А B с 12 V 3Ω 422 20 6 F...
(a) A capacitor has a value of 5 μF. Explain in terms of electric charge what this means. (b) The 5 uF capacitor shown in the circuit below is initially uncharged. The circuit is connected to a computer and switch S is closed. The monitor of the computer displays a graph of current against time as the capacitor charges monitoT charging current/uA 30 20 10 0 . 2,3 4 time s computer The battery has negligible internal resistance. (i) Calculate...