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Resistors in an ac circuit

Just as a reminder, consider [link] , which shows an AC voltage applied to a resistor and a graph of voltage and current versus time. The voltage and current are exactly in phase in a resistor. There is no frequency dependence to the behavior of plain resistance in a circuit:

Part a of the diagram shows a resistor R connected across an A C voltage source V. The voltage drop across the resistor R is given by V R.Part b of the diagram shows a graph showing the variation of voltage V R and current I R with time t. the V R and current I R are plotted along Y axis and time t is along the X axis. Both I and V are progressive cosine waves. The amplitude of I wave is more than V wave.
(a) An AC voltage source in series with a resistor. (b) Graph of current and voltage across the resistor as functions of time, showing them to be exactly in phase.

Ac voltage in a resistor

When a sinusoidal voltage is applied to a resistor, the voltage is exactly in phase with the current—they have a phase angle.

Section summary

  • For inductors in AC circuits, we find that when a sinusoidal voltage is applied to an inductor, the voltage leads the current by one-fourth of a cycle, or by a 90º phase angle.
  • The opposition of an inductor to a change in current is expressed as a type of AC resistance.
  • Ohm’s law for an inductor is
    I = V X L , size 12{I= { {V} over {X rSub { size 8{L} } } } } {}
    where V size 12{V} {} is the rms voltage across the inductor.
  • X L size 12{X rSub { size 8{L} } } {} is defined to be the inductive reactance, given by
    X L = fL , size 12{X rSub { size 8{L} } =2π ital "fL"} {}
    with f size 12{f} {} the frequency of the AC voltage source in hertz.
  • Inductive reactance X L size 12{X rSub { size 8{L} } } {} has units of ohms and is greatest at high frequencies.
  • For capacitors, we find that when a sinusoidal voltage is applied to a capacitor, the voltage follows the current by one-fourth of a cycle, or by a 90º phase angle.
  • Since a capacitor can stop current when fully charged, it limits current and offers another form of AC resistance; Ohm’s law for a capacitor is
    I = V X C , size 12{I= { {V} over {X rSub { size 8{C} } } } } {}
    where V size 12{V} {} is the rms voltage across the capacitor.
  • X C size 12{X rSub { size 8{C} } } {} is defined to be the capacitive reactance, given by
    X C = 1 fC . size 12{X rSub { size 8{C} } = { {1} over {2π ital "fC"} } } {}
  • X C size 12{X rSub { size 8{C} } } {} has units of ohms and is greatest at low frequencies.

Conceptual questions

Presbycusis is a hearing loss due to age that progressively affects higher frequencies. A hearing aid amplifier is designed to amplify all frequencies equally. To adjust its output for presbycusis, would you put a capacitor in series or parallel with the hearing aid’s speaker? Explain.

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Would you use a large inductance or a large capacitance in series with a system to filter out low frequencies, such as the 100 Hz hum in a sound system? Explain.

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High-frequency noise in AC power can damage computers. Does the plug-in unit designed to prevent this damage use a large inductance or a large capacitance (in series with the computer) to filter out such high frequencies? Explain.

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Does inductance depend on current, frequency, or both? What about inductive reactance?

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Explain why the capacitor in [link] (a) acts as a low-frequency filter between the two circuits, whereas that in [link] (b) acts as a high-frequency filter.

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The figure describes two circuits with two different connections. The first part of the diagram shows circuit one and circuit two connected in series and a capacitor C is connected between them. Both the circuits are shown as grounded. The second part of the diagram shows two circuits circuit one and circuit two connected to each other. At the point of connection one end of the capacitor is connected and the other end of the capacitor is grounded. Both the circuits are shown as grounded.
Capacitors and inductors. Capacitor with high frequency and low frequency.

If the capacitors in [link] are replaced by inductors, which acts as a low-frequency filter and which as a high-frequency filter?

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Problems&Exercises

At what frequency will a 30.0 mH inductor have a reactance of 100 Ω ?

531 Hz

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What value of inductance should be used if a 20.0 kΩ reactance is needed at a frequency of 500 Hz?

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What capacitance should be used to produce a 2.00 MΩ reactance at 60.0 Hz?

1.33 nF

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At what frequency will an 80.0 mF capacitor have a reactance of 0.250 Ω ?

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(a) Find the current through a 0.500 H inductor connected to a 60.0 Hz, 480 V AC source. (b) What would the current be at 100 kHz?

(a) 2.55 A

(b) 1.53 mA

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(a) What current flows when a 60.0 Hz, 480 V AC source is connected to a 0.250 μF capacitor? (b) What would the current be at 25.0 kHz?

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A 20.0 kHz, 16.0 V source connected to an inductor produces a 2.00 A current. What is the inductance?

63.7 µH

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A 20.0 Hz, 16.0 V source produces a 2.00 mA current when connected to a capacitor. What is the capacitance?

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(a) An inductor designed to filter high-frequency noise from power supplied to a personal computer is placed in series with the computer. What minimum inductance should it have to produce a 2.00 kΩ reactance for 15.0 kHz noise? (b) What is its reactance at 60.0 Hz?

(a) 21.2 mH

(b) 8.00 Ω

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The capacitor in [link] (a) is designed to filter low-frequency signals, impeding their transmission between circuits. (a) What capacitance is needed to produce a 100 kΩ reactance at a frequency of 120 Hz? (b) What would its reactance be at 1.00 MHz? (c) Discuss the implications of your answers to (a) and (b).

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The capacitor in [link] (b) will filter high-frequency signals by shorting them to earth/ground. (a) What capacitance is needed to produce a reactance of 10.0 mΩ for a 5.00 kHz signal? (b) What would its reactance be at 3.00 Hz? (c) Discuss the implications of your answers to (a) and (b).

(a) 3.18 mF

(b) 16.7 Ω

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Unreasonable Results

In a recording of voltages due to brain activity (an EEG), a 10.0 mV signal with a 0.500 Hz frequency is applied to a capacitor, producing a current of 100 mA. Resistance is negligible. (a) What is the capacitance? (b) What is unreasonable about this result? (c) Which assumption or premise is responsible?

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Construct Your Own Problem

Consider the use of an inductor in series with a computer operating on 60 Hz electricity. Construct a problem in which you calculate the relative reduction in voltage of incoming high frequency noise compared to 60 Hz voltage. Among the things to consider are the acceptable series reactance of the inductor for 60 Hz power and the likely frequencies of noise coming through the power lines.

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Practice Key Terms 2

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Source:  OpenStax, College physics for ap® courses. OpenStax CNX. Nov 04, 2016 Download for free at https://legacy.cnx.org/content/col11844/1.14
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