10:19Inductors Explained - The basics how inductors work working principleThe Engineering Mindset421views
12:34Inductive Reactance, Impedance, & Power Factor - AC Circuits - PhysicsThe Organic Chemistry Tutor756views
10:33Inductors Have Inductance, Reactance, AND Impedance. DANG, DAWG. | Doc PhysicsDoc Schuster368views
Multiple ChoiceWill a frequency f = 60 Hz or ω = 75 s−1 produce a larger max current in an inductor connected to an AC source?322views1rank
Multiple ChoiceA certain laptop charger says that the Vrms provided to the laptop is 12 V. You know this charger is plugged into an outlet for which Vrms is 120 V, such that there must be a transformer inside the laptop charger. If the number of windings of wire on the laptop side of the transformer is 60, how many windings of wire must be on the outlet side of the transformer?349views
Multiple ChoiceThe peak current to and from an inductor is IL when the emf source has a peak voltage V and frequency f. What is the peak current to and from the inductor if the frequency and peak voltage are doubled to 2f and 2V. respectively?393views1comments
Multiple ChoiceAn AC circuit consists of an inductor and an emf source with frequency 0.25Hz. If the source is turned on at t=0s, and the first time the voltage across the inductor reaches a maximum value is at t=1.4s, when is the first time the current in the inductor is at a maximum?272views
Multiple ChoiceThe peak current to and from an inductor is i when the emf source has a peak voltage V and frequency f. What is the peak current to and from the inductor if the frequency and peak voltage are doubled to 2f and 2V2V, respectively?279views
Textbook Question(b) What is the inductance of an inductor whose reactance is 120 Ω at 80.0 Hz?341views
Textbook QuestionThe peak current through an inductor is 10 mA. What is the peak current if b. The emf peak voltage is doubled (at the original frequency)?97views
Textbook QuestionIn some experiments, very tiny distances or spaces ( ≈ nm ) can be measured by using capacitance. Consider forming an LC circuit using a parallel-plate capacitor with plate area A, and a known inductance L. (a) If charge is found to oscillate in this circuit at frequency f = ω/2π when the capacitor plates are separated by distance x, show that x = 4π² Aε₀f²L.58views
Textbook QuestionIn some experiments, very tiny distances or spaces ( ≈ nm ) can be measured by using capacitance. Consider forming an LC circuit using a parallel-plate capacitor with plate area A, and a known inductance L. (b) When the plate separation is changed by ∆x, the circuit’s oscillation frequency will change by ∆f. Show that ∆x/x ≈ 2(∆f/f).54views
Textbook QuestionIn some experiments, very tiny distances or spaces ( ≈ nm ) can be measured by using capacitance. Consider forming an LC circuit using a parallel-plate capacitor with plate area A, and a known inductance L. (c) If f is on the order of 1 MHz and can be measured to a precision of ∆f = 1 Hz, with what percent accuracy can x be determined? Assume fringing effects at the capacitor’s edges can be neglected.59views
Textbook Question(II) A 75-W incandescent lightbulb is designed to operate with an applied ac voltage of 120 V rms. The bulb is placed in series with an inductor L, and this series combination is then connected to a 60.0-Hz 240-V rms voltage source. For the bulb to operate properly, determine the required value for L. Assume the bulb has resistance R and negligible inductance.19views
Textbook QuestionAt t = 0, the current through a 60.0-mH inductor is 50.0 mA and is increasing at the rate of 78.0 mA/s. What is the initial energy stored in the inductor, and how long does it take for the energy to increase by a factor of 8.0 from the initial value?25views
Textbook Question(III) Suppose that a circular parallel-plate capacitor has radius r₀ = 3.0 cm and plate separation d = 5.0 mm. A sinusoidal potential difference V = V₀ sin (2𝝅ft) is applied across the plates, where V₀ = 180 V and f = 60 Hz. (a) In the region between the plates, show that the magnitude of the induced magnetic field is given by B = B₀(r) cos (2𝝅ft), where B₀(r) is a function of the radial distance r from the capacitor’s central axis.15views
Textbook Question(III) Suppose that a circular parallel-plate capacitor has radius r₀ = 3.0 cm and plate separation d = 5.0 mm. A sinusoidal potential difference V = V₀ sin (2𝝅ft) is applied across the plates, where V₀ = 180 V and f = 60 Hz. (b) Determine the expression for the amplitude B₀(r) of this time-dependent (sinusoidal) field when r ≤ r₀ and when r > r₀.10views
Textbook Question(III) Suppose that a circular parallel-plate capacitor has radius r₀ = 3.0 cm and plate separation d = 5.0 mm. A sinusoidal potential difference V = V₀ sin (2𝝅ft) is applied across the plates, where V₀ = 180 V and f = 60 Hz. (c) Plot B₀(r) in tesla for the range 0 ≤ r ≤ 10 cm.18views