RC Challenge Problem You have an RC Circuit hooked up to a battery that you are testing for your company. This consists of a battery, resistor and capacitor all in series. You can assume the battery is ideal (no internal resistance). You need to know how long it takes (time) in order for the capacitor to store 69.1% of the maximum possible energy for this circuit. The values for the battery, resistor and capacitor are below. Battery = 11.88 V %3D Capacitor = 117.00 micro Farads (UF) %3D Resistor = 106.00 kilo Ohms (kS2) %3D rahwer. Make sure to include units with your al Hint: This is NOT the same question as asking how long it takes to have 69.1 % of the maximum voltage across the capacitor. Think about how the capacitor energy and voltage relate to solve this. Your Answer: Answer units

RC Challenge Problem You have an RC Circuit hooked up to a battery that you are testing for your company. This consists of a battery, resistor and capacitor all in series. You can assume the battery is ideal (no internal resistance). You need to know how long it takes (time) in order for the capacitor to store 69.1% of the maximum possible energy for this circuit. The values for the battery, resistor and capacitor are below. Battery = 11.88 V %3D Capacitor = 117.00 micro Farads (UF) %3D Resistor = 106.00 kilo Ohms (kS2) %3D rahwer. Make sure to include units with your al Hint: This is NOT the same question as asking how long it takes to have 69.1 % of the maximum voltage across the capacitor. Think about how the capacitor energy and voltage relate to solve this. Your Answer: Answer units

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

See similar textbooks

Similar questions

In the series RC circuit shown below, the current through the resistor is decreasing with time. If that is true, what is happening to the charge on the capacitor as time goes on? a) The charge is increasing b) the charge remains constant c) the charge is decreasing d) need more information
Two RC circuits are shown. In 4 x 10-6 F 2 x 10-6 F each circuit, the capacitor is fully charged and the switch is open. Then, the switch in each circuit closes at the exact same time 25 0 250 N and the capacitors begin to discharge. Circuit A Circuit B i) How long does it take the capacitor in Circuit A to reach 37% of its maximum value? 1.0 x 10-4 s 5.0 x 10-4 s 2000 s 10,000 s Cannot be determined ii) Which capacitor retains its charge the longest? Capacitor A Capacitor B They discharge at the Cannot be same rate determined ww
RC Circuits 6. The charge on a C = 0.4F capacitor is measured as a function of time in a physics lab and produces the following graph. The capacitor is part of a simple circuit having only a battery, a capacitor, and a resistor in series. The capacitor starts uncharged and at t=0s, the battery is plugged in and the capacitor charges. In general, the charge of a charging capacitor is given by: q(t) = Qmax(1 – e-t/RC) тах Charge vs. Time 20 18 16 14 ū 12 10 8 4 2 1 3 4 7 8. 9 10 Time (s) а. Use the graph to estimate the time constant for this circuit, T. b. Estimate the resistance of the resistor R in this circuit. с. Estimate the battery's voltage AV in this circuit. Charge (C)
The circuit shown has two resistors, with R1 > R2 .Which resistor dissipates the larger amount of power? Explain.
v Question Completion Status: A Moving to another question will save this response. Question 1 A series parallel combination of resistor is shown in the figure below. If R1 =26 Q, R2= 23 Q, R3 = 40 Q and V=6.8 Volt ,what current the ammeter will read? 3 R: R3 V R2 A Moving to another question will save this response.
For the circuit shown, determine the steady- state voltage across each capacitor and the energy stored in the 124 F capacitor. 6uF 40V + 4MF 8 MFT - F12 MF
Q9
Q2 Consider the circuit shown in Figure P26.23, where Ci - 6.00 μΕ, C,-3.00 μF, and ΔV= 20.0 V Capacitor C¡ is first charged by the closing of switch S1. Switch S¡ is then opened, and the charged capacitor is connected to the uncharged capacitor by the closing of S2. Calculate the initial charge acquired by C, and the final charge on each capacitor. AV |C2 S2 Figure P26.23
*Chapter 32, Problem 018 GO Your answer is partially correct. Try again. The circuit in the figure consists of switch S, a 4.60 V ideal battery, a 25.0 MS2 resistor, and an airfilled capacitor. The capacitor has parallel circular plates of radius 5.30 cm, separated by 4.00 mm. At time t = 0, switch S is closed to begin charging the capacitor. The electric field between the plates is uniform. At t = 260 ps, what is the magnitude of the magnetic fleld within the capacitor, at radial distance 2.50 cm? R Number [0.000000000000029578 Units h
27. * (a) Write two loop rule equations and one junction rule equation for the circuit in Figure P19.27. (b) Use these equations to determine the current in each branch of the circuit for the case in which R₁ =50, R₂ =30, R3 =15 N, and ε = 120 V. Figure P19.27 R₁ E R₂ ww R3 -ww
35. * Determine (a) the equivalent resistance of resistors R₁, R₂, and R3 in Figure P19.35 = 28 Ω , R, - 30 Ω, and R3 = 20 Ω for R₁ -= and (b) the current through the battery if ε = 10 V. Figure P19.35 E R₂ www www R₂ www R₁
*Chapter 32, Problem 018 GO Your answer is partially correct. Try again. The circuit in the figure consists of switch S, a 4.60 V ideal battery, a 25.0 MN resistor, and an airfilled capacitor. The capacitor has parallel circular plates of radius 5.30 cm, separated by 4.00 mm. At time t = 0, switch S is closed to begin charging the capacitor. The electric field between the plates is uniform. At t = 260 us, what is the magnitude of the magnetic field within the capacitor, at radial distance 2.50 cm? R Units Number [0.000000000000384