H.W 1.2: The switch in the circuit in figure 1.17 has been in the left position for a long time. At t = 0 it moves to the right position and stays there. a) Write the expression for the capacitor voltage, v(t) for t>0 b) Write the expression for the current through the 40k resistor, i(t) for t>0, 5 kN 40 kN 1 = 0 120 V 10 kN : 160 nF 25 kN §10 kN Figure 1.17

H.W 1.2: The switch in the circuit in figure 1.17 has been in the left position for a long time. At t = 0 it moves to the right position and stays there. a) Write the expression for the capacitor voltage, v(t) for t>0 b) Write the expression for the current through the 40k resistor, i(t) for t>0, 5 kN 40 kN 1 = 0 120 V 10 kN : 160 nF 25 kN §10 kN Figure 1.17

Introductory Circuit Analysis (13th Edition)

13th Edition

ISBN:9780133923605

Author:Robert L. Boylestad

Publisher:Robert L. Boylestad

Chapter1: Introduction

Section: Chapter Questions

Problem 1P: Visit your local library (at school or home) and describe the extent to which it provides literature...

See similar textbooks

Related questions

Q: ng period of witch is set t W1

A: The transient occurs in an electric circuit because of energy storing elements of opposite kind…

Q: When the switch has been in position-a for a long time, what is the initial current carried by the…

A: When the switch has been in position-a for a long time, what is the initial current carried by the…

Q: In the circuit shown in figure, & = 10.0 V, R₁ = 5.00 S2, R₂ = 10.0 2, and L = 5.00 H. a) Switch S…

A: For the given R-L circuit, the circuit parameters are as follows:ϵ=10 V, R1=5 Ω, R2=10 Ω, L=5 H.

Q: A 130-µF capacitance is initially charged to 1160 V . At t = 0, it is connected to a 1-k2…

A: Energy stored in capacitor=12×CV2. We will write expression for for general Expression for voltage…

Q: 20 Ω 20 N 60 N 60 Ω 80 μF 21 V 40 μF 40 µF [40 µF Switch

Q: A circuit having a resistance of 20 ohms and an inductance of 0.5 H is connected across a 200 V dc…

Q: Fort<0, isi = isz = 0. isı (t) = 30[mA]e® Isz(t) = 50[mA]e¬² Find the energy delivered by the source…

Q: a) What is the coupling constant between the two coils? b) Using the dot notation, determine if the…

A: "Since you have posted a question with multiple sub parts, we will provide the solution only to the…

Q: The values of the components in the circuit are L = 163 mH, R, = 410 N, R, = 340 N, and E = 10.0 V.…

A: Current through indicator when switch is opened is calculated as shown below

Q: What type of response (natural/step) is the circuit undergoing? Explain briefly with reasons.

Q: *Chapter 32, Problem 018 GO The circuit in the figure consists of switch S, a 4.60 V ideal battery,…

A: Given data, V=4.60 VR=25.0 MΩl=4.00 mmt=260 μs

Q: In the attached image, find the current i at time t=0.0062265 seconds. (The energy stored in the the…

A: In given circuit, V1=58 V R3=26 ohm L=0.44 H C=0.14 F It is given that there is no energy stored in…

Q: B) C) Consider a series connection of R=2 Ohms, C=3F, a switch, and a voltage source, E=12 Volts.…

Q: For the circuit below with switch U1 closing at time t=0 and the initial current in inductor L1…

Q: Option 2: Electrical Engineering Application. You are analyzing an AC circuit like one that you…

A: Write the given values in the question. itmax=30 Aitmin=0 Af=80 cylces/second

Q: Q2. Find the equivalent inductance Leg and capacitance CEQ for the partial circuits shown. .01 μF 50…

Q: 6 A R₁ L₁ m L2 R₂3 L3 ell R3 i2

Q: When the switch is in position-b, what is the final value of current?

Q: A 500 ohm resistor, an 1.5 F uncharged capacitor, and a 6.16-V emf are connected in series. (a) What…

A: Hello. Since your question has multiple sub-parts, we will solve first three sub-parts for you. If…

Q: Assume that switch SW1 has been in position 1 long enough to completely charge C1. Then, at t = 0,…

Q: The following circuit has R1 = 750 2, R2 = 1400 2. Note, the current source Is is defined by the…

A: To find the values of the capacitor $ C $ and inductor $ L $, we need to analyze the given…

Q: 2. Refer to figure 1.B. The capacitor in initially uncharged. The switch S is elosed at t=0. Since…

A: Since you have posted a question with multiple sub-parts, we will solve the three sub-parts (d, e…

Q: C T-l. Figure A Figure B Figure C U() U, U .--. Figure D Figure E Figure F U..-. U, - Which plot…

Q: An inductor has inductance of 2 H. The voltage v(t) across the inductor is plotted versus time as…

A: Given: The plot of voltage across inductor of 2H. To do: Derive the current i(t) , power p(t) and…

Q: Consider the circuit shown in the figure (Click "Link to Figure" to access the figure), where L =…

Q: igure ows thể čircular wave fronts emitted by two sources, the wavelength for both idential waves is…

A: Note: Since you have not specified any question to be answered, as per our honor code, we are…

Q: For the circuit shown below, find an expression for the voltage drop across the inductor after the…

A: Find the current through the inductor for t < 0.

Concept explainers

Digital Integrated Circuit Design

Digital IC design is a procedural interaction that involves converting determinations and highlights into computerized blocks, which are then further transformed into basic circuits. A significant number of the imperatives related with advanced IC plan come from the foundry cycle and innovative restrictions.

Question

100%

H.W 1.2: The switch in the circuit in figure 1.17 has been in the left position for
a long time. Att = 0 it moves to the right position and stays there.
a) Write the expression for the capacitor voltage, v(t) for t>0
b) Write the expression for the current through the 40 k resistor, i(t) for t>0,
5 kN
40 k2
t = 0
120 V
10 kN
160 nF
$25 k
10 kN
Figure 1.17
Ans:
v(t) = (80e-375t) V,
t > 0,
i(t) = (1.6e-375t) mA,
t > 0

Expert Solution

This question has been solved!

Explore an expertly crafted, step-by-step solution for a thorough understanding of key concepts.

This is a popular solution!

SEE SOLUTION Check out a sample Q&A here

Step 1

VIEW

Step 2

VIEW

Step 3

VIEW

Trending now

This is a popular solution!

Step by step

Solved in 3 steps with 7 images

SEE SOLUTION Check out a sample Q&A here

Knowledge Booster

P-channel Metal-Oxide Semiconductor (PMOS), N-channel Metal-Oxide Semiconductor (NMOS), and Complementary Metal-Oxide Semiconductor (CMOS)

Learn more about

Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, electrical-engineering and related others by exploring similar questions and additional content below.

Similar questions

Switch S1 has been closed and S2 has open for a long time until the capacitors are fully charged. At t=0, S1 is opened and S2 is closed. If =12V, C₁=4mF and C₂=8mF, R₁=2.18kQ and R₂-4.02 KQ; what is the voltage on R₂ at t=0? Please express your answer using one decimal place. E R₁ Answer: S₁ C₂ C₁ a b I S R₂ 2
Below is a circuit diagram. Each of the L; are different inductors(each having and induction of 1 henry), while the R1 is a resistor( with a resistance of 4 ohms). We will make the following assumption: the input voltage V(t) = 0 when t > 0. Below is the circuit diagram: ell L2 1H Loop 2 R1 Loop 1 L2 1H ell L3 1H 2 Calculations For the circuit above, find the following: Set up the system of differential equations. • Find the general solution for a given time t. • Find the exact solution if you are given that Io = L ell
For the circuit shown in Figure 3: A +1 V1 9V S1 B R1 1kQ2 C1 470μF The circuit in Figure 3 shows the circuit set up to charge and discharge a capacitor. a) Calculate the time constant (T) for the circuit. b) Draw the detailed current waveform through the circuit and voltage waveform across capacitor for the Capacitor charge cycle when the switch is at position A. (Consider the initial capacitor voltage to be OV). c) Draw the detailed current waveform through the circuit and voltage waveform across capacitor for the Capacitor discharge cycle when the switch position is changed to position B. (Consider the capacitor to be fully charged just before the switch position is changed). The waveforms should be labelled, showing the capacitor voltage, currents and time constant. The figures should show as much details as possible, including the time constant and voltage levels. Also write a brief description, explaining the behaviour of the capacitor under the two mentioned cycles.
A circuit is constructed with a resistor, two inductors, one capacitor, one battery and a switch as shown. The value of the resistance is R1 = 231 0. The values for L, R, the inductances are: L1 = 307 mH and L2 = 114 mH. The capacitance is C = 190 uF and the battery voltage is V = 12 V. The positive terminal of the battery is indicated with a + sign. L2 4) What is Q(t1), the charge on the capacitor at time t = t = 4.83 ms. Qt1) is defined to be positive if V(a) - V(b) is positive. uC Submit 5) What is t2, the first time after the switch is opened that the energy stored in the capacitor is a maximum? ms| Submit 6) What is the total energy stored in the inductors plus the capacitor at time t = t2? Submit
continued on f and g.
How many milliseconds after the switch has been moved does the inductor voltage equal 45V?
a) Write the expression for the voltage vC after the switch is closed b) Write the expression for the current iC after the switch is closed. Plot the results of parts (a) and (b).