In Fig. 31-33, a generator with an adjustable frequency of

An oscillating LC circuit consists of a 75.0 mH inductor and a 3.60 mF capacitor. If the maximum charge on the capacitor is 2.90 mC, what are (a) the total energy in the circuit and (b) the maximum current?

The frequency of oscillation of a certain LC circuit is 200 kHz.At time t ! 0, plate A of the capacitor has maximum positive charge. At what earliest time t - 0 will (a) plate A again have maximum positive charge, (b) the other plate of the capacitor have maximum positive charge,and (c) the inductor have maximum magnetic field?

In a certain oscillating LC circuit, the total energy is converted from electrical energy in the capacitor to magnetic energy in the inductor in 1.50 ms. What are (a) the period of oscillation and (b) the frequency of oscillation? (c) How long after the magnetic energy is a maximum will it be a maximum again?

What is the capacitance of an oscillating LC circuit if the maximum charge on the capacitor is 1.60 mC and the total energy is 140 mJ?

n an oscillating LC circuit, L ! 1.10 mH and C ! 4.00 mF. The maximum charge on the capacitor is 3.00 mC. Find the maximum current.

A 0.50 kg body oscillates in SHM on a spring that, when extended 2.0 mm from its equilibrium position, has an 8.0 N restoring force. What are (a) the angular frequency of oscillation, (b) the period of oscillation, and (c) the capacitance of an LC circuit with the same period if L is 5.0 H?

The energy in an oscillating LC circuit containing a 1.25 H inductor is 5.70 mJ.The maximum charge on the capacitor is 175 mC. For a mechanical system with the same period, find the (a) mass, (b) spring constant, (c) maximum displacement, and (d) maximum speed

A single loop consists of inductors (L1, L2, . . .), capacitors (C1, C2, . . .), and resistors (R1, R2, . . .) connected in series as shown, for example, in Fig. 31-27a. Show that regardless of the sequence of these circuit elements in the loop, the behavior of this circuit is identical to that of the simple LC circuit shown in Fig. 31-27b. (Hint: Consider the loop rule and see Problem 47 in Chapter 30.)

In an oscillating LC circuit with L ! 50 mH and C ! 4.0 mF, the current is initially a maximum. How long will it take before the capacitor is fully charged for the first time?

LC oscillators have been used in circuits connected to loudspeakers to create some of the sounds of electronic music. What inductance must be used with a 6.7 mF capacitor to produce a frequency of 10 kHz, which is near the middle of the audible range of frequencies?

A variable capacitor with a range from 10 to 365 pF is used with a coil to form a variable-frequency LC circuit to tune the input to a radio. (a) What is the ratio of maximum frequency to minimum frequency that can be obtained with such a capacitor? If this circuit is to obtain frequencies from 0.54 MHz to 1.60 MHz, the ratio computed in (a) is too large. By adding a capacitor in parallel to the variable capacitor, this range can be adjusted. To obtain the desired frequency range, (b) what capacitance should be added and (c) what inductance should the coil have?

In an oscillating LC circuit, when 75.0% of the total energy is stored in the inductors magnetic field, (a) what multiple of the maximum charge is on the capacitor and (b) what multiple of the maximum current is in the inductor?

In an oscillating LC circuit, L ! 3.00 mH and C ! 2.70 mF. At t ! 0 the charge on the capacitor is zero and the current is 2.00 A. (a) What is the maximum charge that will appear on the capacitor? (b) At what earliest time t - 0 is the rate at which energy is stored in the capacitor greatest, and (c) what is that greatest rate?

To construct an oscillating LC system, you can choose from a 10 mH inductor, a 5.0 mF capacitor, and a 2.0 mF capacitor. What are the (a) smallest, (b) second smallest, (c) second largest, and (d) largest oscillation frequency that can be set up by these elements in various combinations?

An oscillating LC circuit consisting of a 1.0 nF capacitor and a 3.0 mH coil has a maximum voltage of 3.0 V.What are (a) the maximum charge on the capacitor, (b) the maximum current through the circuit, and (c) the maximum energy stored in the magnetic field of the coil?

An inductor is connected across a capacitor whose capacitance can be varied by turning a knob. We wish to make the frequency of oscillation of this LC circuit vary linearly with the angle of rotation of the knob, going from 2 & 105 to 4 & 105 Hz as the knob turns through 180. If L ! 1.0 mH, plot the required capacitance C as a function of the angle of rotation of the knob.

In Fig. 31-28, R ! 14.0 , C 6.20 mF, and L 54.0 mH, and the ideal battery has emf # ! 34.0 V. The switch is kept at a for a long time and then thrown to position b. What are the (a) frequency and (b) current amplitude of the resulting oscillations?

An oscillating LC circuit has a current amplitude of 7.50 mA, a potential amplitude of 250 mV, and a capacitance of 220 nF. What are (a) the period of oscillation, (b) the maximum energy stored in the capacitor, (c) the maximum energy stored in the inductor, (d) the maximum rate at which the current changes, and (e) the maximum rate at which the inductor gains energy?

Using the loop rule, derive the differential equation for an LC circuit (Eq. 31-11).

In an oscillating LC circuit in which C ! 4.00 mF, the maximum potential difference across the capacitor during the oscillations is 1.50 V and the maximum current through the inductor is 50.0 mA. What are (a) the inductance L and (b) the frequency of the oscillations? (c) How much time is required for the charge on the capacitor to rise from zero to its maximum value?

In an oscillating LC circuit with C ! 64.0 mF, the current is given by i (1.60) sin(2500t 0.680), where t is in seconds, i in amperes, and the phase constant in radians. (a) How soon after t ! 0 will the current reach its maximum value? What are (b) the inductance L and (c) the total energy?

A series circuit containing inductance L1 and capacitance C1 oscillates at angular frequency v. A second series circuit, containing inductance L2 and capacitance C2, oscillates at the same angular frequency. In terms of v, what is the angular frequency of oscillation of a series circuit containing all four of these elements? Neglect resistance. (Hint: Use the formulas for equivalent capacitance and equivalent inductance; see Module 25-3 and Problem 47 in Chapter 30.)

In an oscillating LC circuit, L ! 25.0 mH and C ! 7.80 mF. At time t 0 the current is 9.20 mA, the charge on the capacitor is 3.80 mC, and the capacitor is charging.What are (a) the total energy in the circuit, (b) the maximum charge on the capacitor, and (c) the maximum current? (d) If the charge on the capacitor is given by q ! Q cos(vt $ f), what is the phase angle f? (e) Suppose the data are the same, except that the capacitor is discharging at t ! 0.What then is f?

A single-loop circuit consists of a 7.20 " resistor, a 12.0 H inductor, and a 3.20 mF capacitor. Initially the capacitor has a charge of 6.20 mC and the current is zero. Calculate the charge on the capacitor N complete cycles later for (a) N ! 5, (b) N ! 10, and (c) N ! 100.

What resistance R should be connected in series with an inductance L 220 mH and capacitance C 12.0 mF for the maximum charge on the capacitor to decay to 99.0% of its initial value in 50.0 cycles? (Assume v* % v.)

In an oscillating series RLC circuit, find the time required for the maximum energy present in the capacitor during an oscillation to fall to half its initial value.Assume q ! Q at t ! 0.

In an oscillating series RLC circuit, show that )U/U, the fraction of the energy lost per cycle of oscillation, is given to a close approximation by 2pR/vL. The quantity vL/R is often called the Q of the circuit (for quality). A high-Q circuit has low resistance and a low fractional energy loss (! 2p/Q) per cycle.

A 1.50 mF capacitor is connected as in Fig. 31-10 to an ac generator with #m ! 30.0 V. What is the amplitude of the resulting alternating current if the frequency of the emf is (a) 1.00 kHz and (b) 8.00 kHz?

A 50.0 mH inductor is connected as in Fig. 31-12 to an ac generator with 30.0 V. What is the amplitude of the resulting alternating current if the frequency of the emf is (a) 1.00 kHz and (b) 8.00 kHz?

A 50.0 " resistor is connected as in Fig. 31-8 to an ac generator with 30.0 V. What is the amplitude of the resulting alternating current if the frequency of the emf is (a) 1.00 kHz and (b) 8.00 kHz?

(a) At what frequency would a 6.0 mH inductor and a 10 mF capacitor have the same reactance? (b) What would the reactance be? (c) Show that this frequency would be the natural frequency of an oscillating circuit with the same L and C.

An ac generator has emf # ! #m sin vdt, with #m ! 25.0 V and 377 rad/s. It is connected to a 12.7 H inductor. (a) What is the maximum value of the current? (b) When the current is a maximum, what is the emf of the generator? (c) When the emf of the generator is '12.5 V and increasing in magnitude, what is the current?

An ac generator has emf # ! #m sin(vdt ' p/4), where 30.0 V and 350 rad/s. The current produced in a connected circuit is i(t) I sin( t 3p/4), where I 620 mA. At what time after t 0 does (a) the generator emf first reach a maximum and (b) the current first reach a maximum? (c) The circuit contains a single element other than the generator. Is it a capacitor, an inductor, or a resistor? Justify your answer. (d) What is the value of the capacitance, inductance, or resistance, as the case may be?

An ac generator with emf # ! #m sin vdt, where #m ! 25.0 V and vd 377 rad/s, is connected to a 4.15 mF capacitor. (a) What is the maximum value of the current? (b) When the current is a maximum, what is the emf of the generator? (c) When the emf of the generator is '12.5 V and increasing in magnitude, what is the current?

A coil of inductance 88 mH and unknown resistance and a 0.94 mF capacitor are connected in series with an alternating emf of frequency 930 Hz. If the phase constant between the applied voltage and the current is 75, what is the resistance of the coil?

An alternating source with a variable frequency, a capacitor with capacitance C, and a resistor with resistance R are connected in series. Figure 31-29 gives the impedance Z of the circuit versus the driving angular frequency vd; the curve reaches an asymptote of 500 ", and the horizontal scale is set by vds ! 300 rad/s. The figure also gives the reactance XC for the capacitor versus vd. What are (a) R and (b) C?

An electric motor has an effective resistance of 32.0 " and an inductive reactance of 45.0 " when working under load. The voltage amplitude across the alternating source is 420 V. Calculate the current amplitude

The current amplitude I versus driving angular frequency vd for a driven RLC circuit is given in Fig. 31-30, where the vertical axis scale is set by Is ! 4.00 A. The inductance is 200 mH, and the emf amplitude is 8.0 V.What are (a) C and (b) R?

Remove the inductor from the circuit in Fig. 31-7 and set R ! 200 ", C ! 15.0 mF, fd ! 60.0 Hz, and #m ! 36.0 V. What are (a) Z, (b) f, and (c) I? (d) Draw a phasor diagram.

An alternating source drives a series RLC circuit with an emf amplitude of 6.00 V, at a phase angle of $30.0.When the potential difference across the capacitor reaches its maximum positive value of 5.00 V, what is the potential difference across the inductor (sign included)?

In Fig. 31-7, set R ! 200 ", C ! 70.0 mF, L ! 230 mH, fd 60.0 Hz, and 36.0 V. What are (a) Z, (b) f, and (c) I? (d) Draw a phasor diagram

An alternating source with a variable frequency, an inductor with inductance L, and a resistor with resistance R are connected in series. Figure 31-31 gives the impedance Z of the circuit versus the driving angular frequency vd, with the horizontal axis scale set by vds ! 1600 rad/s. The figure also gives the reactance XL for the inductor versus vd.What are (a) R and (b) L?

Remove the capacitor from the circuit in Fig. 31-7 and set R ! 200 ", L ! 230 mH, fd ! 60.0 Hz, and #m ! 36.0 V.What are (a) Z, (b) f, and (c) I? (d) Draw a phasor diagram.

An ac generator with emf amplitude #m ! 220 V and operating at frequency 400 Hz causes oscillations in a series RLC circuit having R 220 ", L ! 150 mH, and C ! 24.0 mF. Find (a) the capacitive reactance XC, (b) the impedance Z, and (c) the current amplitude I. A second capacitor of the same capacitance is then connected in series with the other components. Determine whether the values of (d) XC, (e) Z, and (f) I increase, decrease, or remain the same.

(a) In an RLC circuit, can the amplitude of the voltage across an inductor be greater than the amplitude of the generator emf? (b) Consider an RLC circuit with emf amplitude #m ! 10 V, resistance R ! 10 ", inductance L ! 1.0 H, and capacitance C ! 1.0 mF. Find the amplitude of the voltage across the inductor at resonance.

An alternating emf source with a variable frequency fd is connected in series with a 50.0 resistor and a 20.0 mF capacitor. The emf amplitude is 12.0 V. (a) Draw a phasor diagram for phasor VR (the potential across the resistor) and phasor VC (the potential across the capacitor). (b) At what driving frequency fd do the two phasors have the same length? At that driving frequency, what are (c) the phase angle in degrees, (d) the angular speed at which the phasors rotate, and (e) the current amplitude?

An RLC circuit such as that of Fig. 31-7 has R 5.00 , C 20.0 mF, L 1.00 H, and 30.0 V. (a) At what angular frequency vd will the current amplitude have its maximum value, as in the resonance curves of Fig. 31-16? (b) What is this maximum value? At what (c) lower angular frequency vd1 and (d) higher angular frequency vd2 will the current amplitude be half this maximum value? (e) For the resonance curve for this circuit, what is the fractional half-width (vd1 ' vd2)/v?

Figure 31-32 shows a driven RLC circuit that contains two identical capacitors and two switches. The emf amplitude is set at 12.0 V, and the driving frequency is set at 60.0 Hz. With both switches open, the current leads the emf by 30.9. With switch S1 closed and switch S2 still open, the emf leads the current by 15.0. With both switches closed, the current amplitude is 447 mA. What are (a) R, (b) C, and (c) L?

In Fig. 31-33, a generator with an adjustable frequency of oscillation is connected to resistance R 100 , inductances L1 ! 1.70 mH and L2 ! 2.30 mH, and capacitances C1 ! 4.00 mF, C2 ! 2.50 mF, and C3 ! 3.50 mF. (a) What is the resonant frequency of the circuit? (Hint: See Problem 47 in Chapter 30.) What happens to the resonant frequency if (b) R is increased, (c) L1 is increased, and (d) C3 is removed from the circuit?

An alternating emf source with a variable frequency fd is connected in series with an 80.0 " resistor and a 40.0 mH inductor.The emf amplitude is 6.00 V. (a) Draw a phasor diagram for phasor VR (the potential across the resistor) and phasor VL (the potential across the inductor). (b) At what driving frequency fd do the two phasors have the same length? At that driving frequency, what are (c) the phase angle in degrees, (d) the angular speed at which the phasors rotate, and (e) the current amplitude?

The fractional half-width )vd of a resonance curve, such as the ones in Fig. 31-16, is the width of the curve at half the maximum value of I. Show that )vd/v ! R(3C/L)1/2, where v is the angular frequency at resonance. Note that the ratio )vd/v increases with R, as Fig. 31-16 shows.

An ac voltmeter with large impedance is connected in turn across the inductor, the capacitor, and the resistor in a series circuit having an alternating emf of 100 V (rms); the meter gives the same reading in volts in each case.What is this reading?

An air conditioner connected to a 120 V rms ac line is equivalent to a 12.0 resistance and a 1.30 inductive reactance in series. Calculate (a) the impedance of the air conditioner and (b) the average rate at which energy is supplied to the appliance.

What is the maximum value of an ac voltage whose rms value is 100 V?

What is the maximum value of an ac voltage whose rms value is 100 V?

A typical light dimmer used to dim the stage lights in a theater consists of a variable inductor L (whose inductance is adjustable between zero and Lmax) connected in series with a lightbulb B, as shown in Fig. 31-34. The electrical supply is 120 V (rms) at 60.0 Hz; the lightbulb is rated at 120 V, 1000 W. (a) What Lmax is required if the rate of energy dissipation in the lightbulb is to be varied by a factor of 5 from its upper limit of 1000 W? Assume that the resistance of the lightbulb is independent of its temperature. (b) Could one use a variable resistor (adjustable between zero and Rmax) instead of an inductor? (c) If so, what Rmax is required? (d) Why isnt this done?

In an RLC circuit such as that of Fig. 31-7 assume that R ! 5.00 ", L ! 60.0 mH, fd ! 60.0 Hz, and #m ! 30.0 V. For what values of the capacitance would the average rate at which energy is dissipated in the resistance be (a) a maximum and (b) a minimum? What are (c) the maximum dissipation rate and the corresponding (d) phase angle and (e) power factor? What are (f) the minimum dissipation rate and the corresponding (g) phase angle and (h) power factor?

For Fig. 31-35, show that the average rate at which energy is dissipated in resistance R is a maximum when R is equal to the internal resistance r of the ac generator. (In the text discussion we tacitly assumed that r ! 0.)

In Fig. 31-7, R ! 15.0 ", C ! 4.70 mF, and L ! 25.0 mH. The generator provides an emf with rms voltage 75.0 V and frequency 550 Hz. (a) What is the rms current? What is the rms voltage across (b) R, (c) C, (d) L, (e) C and L together, and (f) R, C, and L together? At what average rate is energy dissipated by (g) R, (h) C, and (i) L?

In a series oscillating RLC circuit, R 16.0 ", C 5 31.2 F, L 9.20 mH, and sin vdt with 45.0 V and 3000 rad/s. For time t 0.442 ms find (a) the rate Pg at which energy is being supplied by the generator, (b) the rate PC at which the energy in the capacitor is changing, (c) the rate PL at which the energy in the inductor is changing, and (d) the rate PR at which energy is being dissipated in the resistor. (e) Is the sum of PC,PL, and PR greater than, less than, or equal to Pg?

Figure 31-36 shows an ac generator connected to a black box through a pair of terminals. The box contains an RLC circuit, possibly even a multiloop circuit, whose elements and connections we do not know. Measurements outside the box reveal that #(t) ! (75.0 V) sin vdt and i(t) ! (1.20 A) sin(vdt $ 42.0). (a) What is the power factor? (b) Does the current lead or lag the emf? (c) Is the circuit in the box largely inductive or largely capacitive? (d) Is the circuit in the box in resonance? (e) Must there be a capacitor in the box? (f) An inductor? (g) A resistor? (h) At what average rate is energy delivered to the box by the generator? (i) Why dont you need to know vd to answer all these questions?

A generator supplies 100 V to a transformers primary coil, which has 50 turns. If the secondary coil has 500 turns, what is the secondary voltage?

A transformer has 500 primary turns and 10 secondary turns. (a) If Vp is 120 V (rms), what is Vs with an open circuit? If the secondary now has a resistive load of 15 ", what is the current in the (b) primary and (c) secondary?

Figure 31-37 shows an autotransformer. It consists of a single coil (with an iron core). Three taps Ti are provided. Between taps T1 and T2 there are 200 turns, and between taps T2 and T3 there are 800 turns. Any two taps can be chosen as the primary terminals, and any two taps can be chosen as the secondary terminals. For choices producing a step-up transformer, what are the (a) smallest, (b) second smallest, and (c) largest values of the ratio Vs/Vp? For a step-down transformer, what are the (d) smallest, (e) second smallest, and (f) largest values of Vs/Vp?

An ac generator provides emf to a resistive load in a remote factory over a two-cable transmission line. At the factory a stepdown transformer reduces the voltage from its (rms) transmission value Vt to a much lower value that is safe and convenient for use in the factory. The transmission line resistance is 0.30 "/cable, and the power of the generator is 250 kW. If Vt ! 80 kV, what are (a) the voltage decrease )V along the transmission line and (b) the rate Pd at which energy is dissipated in the line as thermal energy? If Vt ! 8.0 kV, what are (c) )V and (d) Pd? If Vt ! 0.80 kV, what are (e) )V and (f) Pd?

In Fig. 31-35, let the rectangular box on the left represent the (high-impedance) output of an audio amplifier, with r ! 1000 ". Let R ! 10 " represent the (low-impedance) coil of a loudspeaker. For maximum transfer of energy to the load R we must have R ! r, and that is not true in this case. However, a transformer can be used to transform resistances, making them behave electrically as if they were larger or smaller than they actually are. (a) Sketch the primary and secondary coils of a transformer that can be introduced between the amplifier and the speaker in Fig. 31-35 to match the impedances. (b) What must be the turns ratio?

An ac generator produces emf # ! #m sin(vdt ' p/4), where m 30.0 V and vd 350 rad/s. The current in the circuit attached to the generator is i(t) ! I sin(vdt $ p/4), where I ! 620 mA. (a) At what time after t ! 0 does the generator emf first reach a maximum? (b) At what time after t ! 0 does the current first reach a maximum? (c) The circuit contains a single element other than the generator. Is it a capacitor, an inductor, or a resistor? Justify your answer. (d) What is the value of the capacitance, inductance, or resistance, as the case may be?

A series RLC circuit is driven by a generator at a frequency of 2000 Hz and an emf amplitude of 170 V. The inductance is 60.0 mH, the capacitance is 0.400 mF, and the resistance is 200 ". (a) What is the phase constant in radians? (b) What is the current amplitude?

A generator of frequency 3000 Hz drives a series RLC circuit with an emf amplitude of 120 V.The resistance is 40.0 ", the capacitance is 1.60 mF, and the inductance is 850 mH. What are (a) the phase constant in radians and (b) the current amplitude? (c) Is the circuit capacitive, inductive, or in resonance?

A 45.0 mH inductor has a reactance of 1.30 k". (a) What is its operating frequency? (b) What is the capacitance of a capacitor with the same reactance at that frequency? If the frequency is doubled, what is the new reactance of (c) the inductor and (d) the capacitor?

An RLC circuit is driven by a generator with an emf amplitude of 80.0 V and a current amplitude of 1.25 A. The current leads the emf by 0.650 rad. What are the (a) impedance and (b) resistance of the circuit? (c) Is the circuit inductive, capacitive, or in resonance?

series RLC circuit is driven in such a way that the maximum voltage across the inductor is 1.50 times the maximum voltage across the capacitor and 2.00 times the maximum voltage across the resistor. (a) What is f for the circuit? (b) Is the circuit inductive, capacitive, or in resonance? The resistance is 49.9 ", and the current amplitude is 200 mA. (c) What is the amplitude of the driving emf?

A capacitor of capacitance 158 mF and an inductor form an LC circuit that oscillates at 8.15 kHz, with a current amplitude of 4.21 mA. What are (a) the inductance, (b) the total energy in the circuit, and (c) the maximum charge on the capacitor?

An oscillating LC circuit has an inductance of 3.00 mH and a capacitance of 10.0 mF. Calculate the (a) angular frequency and (b) period of the oscillation. (c) At time t ! 0, the capacitor is charged to 200 mC and the current is zero. Roughly sketch the charge on the capacitor as a function of time

For a certain driven series RLC circuit, the maximum generator emf is 125 V and the maximum current is 3.20 A. If the current leads the generator emf by 0.982 rad, what are the (a) impedance and (b) resistance of the circuit? (c) Is the circuit predominantly capacitive or inductive?

A 1.50 mF capacitor has a capacitive reactance of 12.0 ". (a) What must be its operating frequency? (b) What will be the capacitive reactance if the frequency is doubled?

In Fig. 31-38, a three-phase generator G produces electrical power that is transmitted by means of three wires. The electric potentials (each relative to a common reference level) are V1 ! A sin vdt for wire 1, V2 ! A sin(vdt ' 120) for wire 2, and V3 ! A sin(vdt ' 240) for wire 3. Some types of industrial equipment (for example, motors) have three terminals and are designed to be connected directly to these three wires. To use a more conventional two-terminal device (for example, a lightbulb), one connects it to any two of the three wires. Show that the potential difference between any two of the wires (a) oscillates sinusoidally with angular frequency vd and (b) has an amplitude of .

An electric motor connected to a 120 V, 60.0 Hz ac outlet does mechanical work at the rate of 0.100 hp (1 hp ! 746 W). (a) If the motor draws an rms current of 0.650 A, what is its effective resistance, relative to power transfer? (b) Is this the same as the resistance of the motors coils, as measured with an ohmmeter with the motor disconnected from the outlet?

(a) In an oscillating LC circuit, in terms of the maximum charge Q on the capacitor, what is the charge there when the energy in the electric field is 50.0% of that in the magnetic field? (b) What fraction of a period must elapse following the time the capacitor is fully charged for this condition to occur?

A series RLC circuit is driven by an alternating source at a frequency of 400 Hz and an emf amplitude of 90.0 V. The resistance is 20.0 ", the capacitance is 12.1 mF, and the inductance is 24.2 mH. What is the rms potential difference across (a) the resistor, (b) the capacitor, and (c) the inductor? (d) What is the average rate at which energy is dissipated?

In a certain series RLC circuit being driven at a frequency of 60.0 Hz, the maximum voltage across the inductor is 2.00 times the maximum voltage across the resistor and 2.00 times the maximum voltage across the capacitor. (a) By what angle does the current lag the generator emf? (b) If the maximum generator emf is 30.0 V, what should be the resistance of the circuit to obtain a maximum current of 300 mA?

A 1.50 mH inductor in an oscillating LC circuit stores a maximum energy of 10.0 mJ.What is the maximum current?

A generator with an adjustable frequency of oscillation is wired in series to an inductor of L ! 2.50 mH and a capacitor of C ! 3.00 mF. At what frequency does the generator produce the largest possible current amplitude in the circuit?

A series RLC circuit has a resonant frequency of 6.00 kHz. When it is driven at 8.00 kHz, it has an impedance of 1.00 k" and a phase constant of 45.What are (a) R, (b) L, and (c) C for this circuit?

An LC circuit oscillates at a frequency of 10.4 kHz. (a) If the capacitance is 340 mF, what is the inductance? (b) If the maximum current is 7.20 mA, what is the total energy in the circuit? (c) What is the maximum charge on the capacitor?

When under load and operating at an rms voltage of 220 V, a certain electric motor draws an rms current of 3.00 A. It has a resistance of 24.0 " and no capacitive reactance.What is its inductive reactance?

The ac generator in Fig. 31-39 supplies 120 V at 60.0 Hz. With the switch open as in the diagram, the current leads the generator emf by 20.0. With the switch in position 1, the current lags the generator emf by 10.0.When the switch is in position 2, the current amplitude is 2.00 A.What are (a) R, (b) L, and (c) C?

In an oscillating LC circuit, L ! 8.00 mH and C ! 1.40 mF. At time t ! 0, the current is maximum at 12.0 mA. (a) What is the maximum charge on the capacitor during the oscillations? (b) At what earliest time t - 0 is the rate of change of energy in the capacitor maximum? (c) What is that maximum rate of change?

For a sinusoidally driven series RLC circuit, show that over one complete cycle with period T (a) the energy stored in the capacitor does not change; (b) the energy stored in the inductor does not change; (c) the driving emf device supplies energy and (d) the resistor dissipates energy . (e) Show that the quantities found in (c) and (d) are equal.

What capacitance would you connect across a 1.30 mH inductor to make the resulting oscillator resonate at 3.50 kHz?

A series circuit with resistorinductorcapacitor combination R1, L1, C1 has the same resonant frequency as a second circuit with a different combination R2, L2, C2. You now connect the two combinations in series. Show that this new circuit has the same resonant frequency as the separate circuits.

Consider the circuit shown in Fig. 31-40. With switch S1 closed and the other two switches open, the circuit has a time constant tC. With switch S2 closed and the other two switches open, the circuit has a time constant tL. With switch S3 closed and the other two switches open, the circuit oscillates with a period T.Show that T ! 2p 1tCtL.

When the generator emf in Sample Problem 31.07 is a maximum, what is the voltage across (a) the generator, (b) the resistance, (c) the capacitance, and (d) the inductance? (e) By summing these with appropriate signs, verify that the loop rule is satisfied.