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Certain circuits include sources of alternating electromotive forces of the sinusoidal form V = V0 cos(ωt) or V = V0 sin(ωt). The sine and cosine functions have values that vary between +1 and −1; either of the equations for the voltage represents a potential that varies with respect to time and has values from +V0 to −V0. The voltage varies with time at a rate given by the numerical value of ω; ω, which is called the angular frequency, is expressed in radians per second. Figure shows an example with V0 = 170 volts and ω = 377 radians per second, so that V = 170 cos(377t). The time interval required for the pattern to be repeated is called the period T, given by T = 2π/ω. In Figure, the pattern is repeated every 16.7 milliseconds, which is the period. The frequency of the voltage is symbolized by f and given by f = 1/T. In terms of ω, f = ω/2π, in hertz.

Alternating - Current Circuits | Additional Documents & Tests for IIT JAM

Figure: A sinusoidal voltage (see text).

The root-mean-square (rms) voltage of a sinusoidal source of electromotive force (Vrms) is used to characterize the source. It is the square root of the time average of the voltage squared. The value of Vrms is V0/Square root of2, or, equivalently, 0.707V0. Thus, the 60-hertz, 120-volt alternating current, which is available from most electric outlets in U.S. homes and which is illustrated in Figure, has V0 = 120/0.707 = 170 volts. The potential difference at the outlet varies from +170 volts to −170 volts and back to +170 volts 60 times each second. The rms values of voltage and currentare especially useful in calculating average power in AC circuits.
A sinusoidal electromotive force can be generated using the principles described in Faraday’s law of electromagnetic induction (see\ electromagnetism: Faraday’s law of induction). Briefly, an alternating electromotive force can be induced in a loop of conducting wire by rotating the loop of wire in a uniform magnetic field.
In AC circuits, it is often necessary to find the currents as a function of time in the various parts of the circuit for a given source of sinusoidal electromotive force. While the problems can become quite complex, the solutions are based on Kirchhoff’s two laws discussed above (see Kirchhoff’s laws of electric circuits). The solution for the current in a given loop takes the form i = i0 cos(ωt − ϕ). The current has the same frequency as the applied voltage but is not necessarily “in phase” with that voltage. When the phase angle ϕ does not equal zero, the maximum of the current does not occur when the driving voltage is at its maximum.

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FAQs on Alternating - Current Circuits - Additional Documents & Tests for IIT JAM

1. What is an alternating current circuit?
Ans. An alternating current (AC) circuit is a type of electrical circuit in which the current periodically changes direction. It is commonly used in power distribution systems and household electrical wiring. Unlike direct current (DC), which flows in only one direction, AC circuits alternate the flow of current back and forth, typically at a frequency of 50 or 60 hertz.
2. How does an alternating current circuit differ from a direct current circuit?
Ans. The main difference between an alternating current (AC) circuit and a direct current (DC) circuit is the direction of current flow. In an AC circuit, the current periodically changes direction, whereas in a DC circuit, the current flows in only one direction. Additionally, AC circuits often require transformers to change the voltage levels, while DC circuits may use voltage regulators.
3. What are the advantages of using alternating current circuits?
Ans. There are several advantages of using alternating current (AC) circuits. AC can be easily transformed to different voltage levels using transformers, making it suitable for long-distance power transmission. AC circuits also allow for more efficient power distribution and can support high-power loads. Furthermore, AC circuits are safer to work with due to the lower risk of electrocution compared to DC circuits.
4. What are some common applications of alternating current circuits?
Ans. Alternating current (AC) circuits find extensive use in various applications. They are primarily used in power distribution systems, transmitting electricity from power plants to homes and businesses. AC circuits are also used in appliances, such as refrigerators, air conditioners, and televisions. Furthermore, AC circuits are essential in industrial machinery, electric motors, and lighting systems.
5. How is power calculated in an alternating current circuit?
Ans. The power in an alternating current (AC) circuit can be calculated using the formula P = Vrms * Irms * cos(θ), where P is the power, Vrms is the root mean square (RMS) voltage, Irms is the RMS current, and cos(θ) is the power factor. The power factor represents the phase difference between the voltage and current waveforms and determines the efficiency of power transfer in AC circuits.
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