15.4 Power in an ac circuit

University physics volume 2 Page 1 / 4

By the end of the section, you will be able to:

Describe how average power from an ac circuit can be written in terms of peak current and voltage and of rms current and voltage
Determine the relationship between the phase angle of the current and voltage and the average power, known as the power factor

A circuit element dissipates or produces power according to $P = I V,$ where I is the current through the element and V is the voltage across it. Since the current and the voltage both depend on time in an ac circuit, the instantaneous power $p (t) = i (t) v (t)$ is also time dependent. A plot of p ( t ) for various circuit elements is shown in [link] . For a resistor, i ( t ) and v ( t ) are in phase and therefore always have the same sign (see [link] ). For a capacitor or inductor, the relative signs of i ( t ) and v ( t ) vary over a cycle due to their phase differences (see [link] and [link] ). Consequently, p ( t ) is positive at some times and negative at others, indicating that capacitive and inductive elements produce power at some instants and absorb it at others.

Figures a through d show sine waves on graphs of P versus t. All have the same amplitude and frequency. Figure a is labeled resistor. P bar is equal to half I0 V0. The sine wave is above the x axis, with the minimum y value being 0. It starts from a trough. Figure b is labeled capacitor. P bar is equal to 0. The equilibrium position of the sine wave is along the x axis. It starts at equilibrium with a positive slope. Figure c is labeled inductor. P bar is equal to 0. The equilibrium position of the sine wave is along the x axis. It starts at equilibrium with a negative slope. Figure d is labeled AC source. P bar is equal to half I0 V0 cos phi. The equilibrium position of the sine wave is above the x axis, with the minimum y-value of the wave being negative. — Graph of instantaneous power for various circuit elements. (a) For the resistor, $P_{ave} = I_{0} V_{0} / 2,$ whereas for (b) the capacitor and (c) the inductor, $P_{ave} = 0 .$ (d) For the source, $P_{ave} = I_{0} V_{0} (cos ϕ) / 2,$ which may be positive, negative, or zero, depending on $ϕ .$

Because instantaneous power varies in both magnitude and sign over a cycle, it seldom has any practical importance. What we’re almost always concerned with is the power averaged over time, which we refer to as the average power . It is defined by the time average of the instantaneous power over one cycle:

P_{ave} = \frac{1}{T} \int_{0}^{T} p (t) d t,

where $T = 2 π / ω$ is the period of the oscillations. With the substitutions $v (t) = V_{0} sin ω t$ and $i (t) = I_{0} sin (ω t - ϕ),$ this integral becomes

P_{ave} = \frac{I_{0} V_{0}}{T} \int_{0}^{T} sin (ω t - ϕ) sin ω t d t .

Using the trigonometric relation $sin (A - B) = sin A cos B - sin B cos A,$ we obtain

P_{ave} = \frac{I_{0} V_{0} cos ϕ}{T} \int_{0}^{T} sin ω t d t - \frac{I_{0} V_{0} sin ϕ}{T} \int_{0}^{T} {sin}^{2} ω t cos ω t d t .

Evaluation of these two integrals yields

\frac{1}{T} \int_{0}^{T} {sin}^{2} ω t d t = \frac{1}{2}

and

\frac{1}{T} \int_{0}^{T} sin ω t cos ω t d t = 0 .

Hence, the average power associated with a circuit element is given by

P_{ave} = \frac{1}{2} I_{0} V_{0} cos ϕ .

In engineering applications, $cos ϕ$ is known as the power factor , which is the amount by which the power delivered in the circuit is less than the theoretical maximum of the circuit due to voltage and current being out of phase. For a resistor, $ϕ = 0,$ so the average power dissipated is

P_{ave} = \frac{1}{2} I_{0} V_{0} .

A comparison of p ( t ) and $P_{ave}$ is shown in [link] (d). To make $P_{ave} = (1 / 2) I_{0} V_{0}$ look like its dc counterpart, we use the rms values $I_{rms} and V_{rms}$ of the current and the voltage. By definition, these are

I_{rms} = \sqrt{i_{ave}^{2}} and V_{rms} = \sqrt{v_{ave}^{2}},

where

i_{ave}^{2} = \frac{1}{T} \int_{0}^{T} i^{2} (t) d t and v_{ave}^{2} = \frac{1}{T} \int_{0}^{T} v^{2} (t) d t .

With $i (t) = I_{0} sin (ω t - ϕ) and v (t) = V_{0} sin ω t,$ we obtain

I_{rms} = \frac{1}{\sqrt{2}} I_{0} and V_{rms} = \frac{1}{\sqrt{2}} V_{0} .

We may then write for the average power dissipated by a resistor,

P_{ave} = \frac{1}{2} I_{0} V_{0} = I_{rms} V_{rms} = I_{rms}^{2} R .

This equation further emphasizes why the rms value is chosen in discussion rather than peak values. Both equations for average power are correct for [link] , but the rms values in the formula give a cleaner representation, so the extra factor of 1/2 is not necessary.

Questions & Answers

A golfer on a fairway is 70 m away from the green, which sits below the level of the fairway by 20 m. If the golfer hits the ball at an angle of 40° with an initial speed of 20 m/s, how close to the green does she come?

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Samuel Reply

can someone explain to me, an ignorant high school student, why the trend of the graph doesn't follow the fact that the higher frequency a sound wave is, the more power it is, hence, making me think the phons output would follow this general trend?

Joseph Reply

Nevermind i just realied that the graph is the phons output for a person with normal hearing and not just the phons output of the sound waves power, I should read the entire thing next time

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Follow up question, does anyone know where I can find a graph that accuretly depicts the actual relative "power" output of sound over its frequency instead of just humans hearing

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A string is 3.00 m long with a mass of 5.00 g. The string is held taut with a tension of 500.00 N applied to the string. A pulse is sent down the string. How long does it take the pulse to travel the 3.00 m of the string?

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Source: OpenStax, University physics volume 2. OpenStax CNX. Oct 06, 2016 Download for free at http://cnx.org/content/col12074/1.3

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