SATHEE: alternating-current

alternating-current

7.1 INTRODUCTION

We have so far considered direct current (dc) sources and circuits with dc sources. These currents do not change direction with time. But voltages and currents that vary with time are very common. The electric mains supply in our homes and offices is a voltage that varies like a sine function with time. Such a voltage is called alternating voltage (ac voltage) and the current driven by it in a circuit is called the alternating current (ac current)*. Today, most of the electrical devices we use require ac voltage. This is mainly because most of the electrical energy sold by power companies is transmitted and distributed as alternating current. The main reason for preferring use of ac voltage over dc voltage is that ac voltages can be easily and efficiently converted from one voltage to the other by means of transformers. Further, electrical energy can also be transmitted economically over long distances. AC circuits exhibit characteristics which are exploited in many devices of daily use. For example, whenever we tune our radio to a favourite station, we are taking advantage of a special property of ac circuits – one of many that you will study in this chapter.

7.2 AC VOLTAGE APPLIED TO A RESISTOR

Figure 7.1 shows a resistor connected to a source ε of ac voltage. The symbol for an ac source in a circuit diagram is . We consider a source which produces sinusoidally varying potential difference across its terminals. Let this potential difference, also called ac voltage, be given by

sin v v t = m ω (7.1)

where v m is the amplitude of the oscillating potential difference and ω is its angular frequency.

To find the value of current through the resistor, we apply Kirchhoff’s loop rule ∑ ε( ) t = 0 (refer to Section 3.13), to the circuit shown in Fig. 7.1 to get sin = v t i R m ω or i vm sin t R = ω

Since R is a constant, we can write this equation as

sin i i t = m ω (7.2)

where the current amplitude im is given by

m m v i R = (7.3)

Equation (7.3) is Ohm’s law, which for resistors, works equally well for both ac and dc voltages. The voltage across a pure resistor and the current through it, given by Eqs. (7.1) and (7.2) are plotted as a function of time in Fig. 7.2. Note, in particular that both v and i reach zero, minimum and maximum values at the same time. Clearly, the voltage and current are in phase with each other.

We see that, like the applied voltage, the current varies sinusoidally and has corresponding positive and negative values during each cycle. Thus, the sum of the instantaneous current values over one complete cycle is zero, and the average current is zero. The fact that the average current is zero, however, does not mean that the average power consumed is zero and that there is no dissipation of electrical energy. As you know, Joule heating is given by i2R and depends on i2 (which is always positive whether i is positive or negative) and not on i. Thus, there is Joule heating and dissipation of electrical energy when an ac current passes through a resistor.

The instantaneous power dissipated in the resistor is

2 2 2 sin p i R i R t = = m ω (7.4)

The average value of p over a cycle is* 2 2 2 sin p i R i R t = < > = < m ω > [7.5(a)]

where the bar over a letter (here, p) denotes its average value and <……> denotes taking average of the quantity inside the bracket. Since, i2 mand R are constants, 2 2 sin p i R t = < > m ω [7.5(b)]

Using the trigonometric identity, sin2 ωt = 1/2 (1– cos 2ωt), we have < sin2 ωt > = (1/2) (1– < cos 2ωt >) and since < cos2ωt > = 0**, we have,

2 1 sin 2 < > = ωt Thus, 1 2 p i R = 2 m [7.5(c)]

To express ac power in the same form as dc power (P = I2R), a special value of current is defined and used. It is called, root mean square (rms) or effective current (Fig. 7.3) and is denoted by Irms or I.

It is defined by 2 1 2 2 2 m m i I i i = = = = 0.707 i m (7.6) In terms of I, the average power, denoted by P is 1 2 2 2 m P i R I R = = = p (7.7) Similarly, we define the rms voltage or effective voltage by V = m 2 v = 0.707 v m (7.8) From Eq. (7.3), we have v m = i Rm or, 2 2 v i m m = R or, V = IR (7.9)

Equation (7.9) gives the relation between ac current and ac voltage and is similar to that in the dc case. This shows the advantage of introducing the concept of rms values. In terms of rms values, the equation for power [Eq. (7.7)] and relation between current and voltage in ac circuits are essentially the same as those for the dc case. It is customary to measure and specify rms values for ac quantities. For example, the household line voltage of 220 V is an rms value with a peak voltage of

v m = 2 V = (1.414)(220 V) = 311 V

In fact, the I or rms current is the equivalent dc current that would produce the same average power loss as the alternating current. Equation (7.7) can also be written as P = V2 / R = I V (since V = I R)

7.3 REPRESENTATION OF AC CURRENT AND VOLTAGE BY ROTATING VECTORS — PHASORS

In the previous section, we learnt that the current through a resistor is in phase with the ac voltage. But this is not so in the case of an inductor, a capacitor or a combination of these circuit elements. In order to show phase relationship between voltage and current in an ac circuit, we use the notion of phasors. The analysis of an ac circuit is facilitated by the use of a phasor diagram. A phasor* is a vector which rotates about the origin with angular speed ω, as shown in Fig. 7.4. The vertical components of phasors V and I represent the sinusoidally varying quantities v and i. The magnitudes of phasors V and I represent the amplitudes or the peak values vm and im of these oscillating quantities. Figure 7.4(a) shows the voltage and current phasors and their relationship at time t1 for the case of an ac source connected to a resistor i.e., corresponding to the circuit shown in Fig. 7.1. The projection of voltage and current phasors on vertical axis, i.e., vm sinω t and im sinω t, respectively represent the value of voltage and current at that instant. As they rotate with frequency ω, curves in Fig. 7.4(b) are generated. From Fig. 7.4(a) we see that phasors V and I for the case of a resistor are in the same direction. This is so for all times. This means that the phase angle between the voltage and the current is zero.

7.4 AC VOLTAGE APPLIED TO AN INDUCTOR

Figure 7.5 shows an ac source connected to an inductor. Usually, inductors have appreciable resistance in their windings, but we shall assume that this inductor has negligible resistance. Thus, the circuit is a purely inductive ac circuit. Let the voltage across the source be v = vm sinω t. Using the Kirchhoff’s loop rule, ∑ ε ( ) t = 0 , and since there is no resistor in the circuit,

d 0 d i v L t − = (7.10)

where the second term is the self-induced Faraday emf in the inductor; and L is the self-inductance of the inductor. The negative sign follows from Lenz’s law (Chapter 6). Combining Eqs. (7.1) and (7.10), we have

d sin d i v vm t t L L = = ω (7.11)

Equation (7.11) implies that the equation for i(t), the current as a function of time, must be such that its slope di/dt is a sinusoidally varying quantity, with the same phase as the source voltage and an amplitude given by vm/L. To obtain the current, we integrate di/dt with respect to time:

d d i d d t t v L ∫ ∫ = m sin( ) ωt t and get, i vm cos( ) constant t L = − ω + ω

The integration constant has the dimension of current and is timeindependent. Since the source has an emf which oscillates symmetrically about zero, the current it sustains also oscillates symmetrically about zero, so that no constant or time-independent component of the current exists. Therefore, the integration constant is zero. Using

− = −   cos( ) sin ω ω t t π 2 , we have i i t = − m   sin ω π 2 (7.12) where im vm L = ω

is the amplitude of the current. The quantity ω L is analogous to the resistance and is called inductive reactance, denoted by XL: XL = ω L (7.13)

The amplitude of the current is, then m m L v i X = (7.14)

The dimension of inductive reactance is the same as that of resistance and its SI unit is ohm (Ω). The inductive reactance limits the current in a purely inductive circuit in the same way as the resistance limits the current in a purely resistive circuit. The inductive reactance is directly proportional to the inductance and to the frequency of the current. A comparison of Eqs. (7.1) and (7.12) for the source voltage and the current in an inductor shows that the current lags the voltage by π/2 or one-quarter (1/4) cycle. Figure 7.6 (a) shows the voltage and the current phasors in the present case at instant t1. The current phasor I is π/2 behind the voltage phasor V. When rotated with frequency ω counterclockwise, they generate the voltage and current given by Eqs. (7.1) and (7.12), respectively and as shown in Fig. 7.6(b)

We see that the current reaches its maximum value later than the voltage by one-fourth of a period T 4 2 =   π/ ω . You have seen that an inductor has reactance that limits current similar to resistance in a dc circuit. Does it also consume power like a resistance? Let us try to find out. The instantaneous power supplied to the inductor is

p i v i t v t L = = m  − m sin  ω 2π   × sin(ω ) = −i v t t m m cos sin (ω ω ) ( ) sin 2 ( ) 2 i v m m = − ωt

So, the average power over a complete cycle is L sin 2 ( ) 2 i v m m P = − ω t sin 2 ( ) 2 i v m m = − ω t = 0,

since the average of sin (2ωt) over a complete cycle is zero. Thus, the average power supplied to an inductor over one complete cycle is zero. Figure 7.7 explains it in detail.

0-1 Current i through the coil entering at A increase from zero to a maximum value. Flux lines are set up i.e., the core gets magnetised. With the polarity shown voltage and current are both positive. So their product p is positive. ENERGY IS ABSORBED FROM THE SOURCE.

1-2 Current in the coil is still positive but is decreasing. The core gets demagnetised and the net flux becomes zero at the end of a half cycle. The voltage v is negative (since di/dt is negative). The product of voltage and current is negative, and ENERGY IS BEING RETURNED TO SOURCE.

One complete cycle of voltage/current. Note that the current lags the voltage. 2-3 Current i becomes negative i.e., it enters at B and comes out of A. Since the direction of current has changed, the polarity of the magnet changes. The current and voltage are both negative. So their product p is positive. ENERGY IS ABSORBED.

3-4 Current i decreases and reaches its zero value at 4 when core is demagnetised and flux is zero. The voltage is positive but the current is negative. The power is, therefore, negative. ENERGY ABSORBED DURING THE CYCLE 2-3 IS RETURNED TO THE SOURCE.

7.5 AC VOLTAGE APPLIED TO A CAPACITOR

Figure 7.8 shows an ac source ε generating ac voltage v = vm sin ωt connected to a capacitor only, a purely capacitive ac circuit. When a capacitor is connected to a voltage source in a dc circuit, current will flow for the short time required to charge the capacitor. As charge accumulates on the capacitor plates, the voltage across them increases, opposing the current. That is, a capacitor in a dc circuit will limit or oppose the current as it charges. When the capacitor is fully charged, the current in the circuit falls to zero.

When the capacitor is connected to an ac source, as in Fig. 7.8, it limits or regulates the current, but does not completely prevent the flow of charge. The capacitor is alternately charged and discharged as the current reverses each half cycle. Let q be the charge on the capacitor at any time t. The instantaneous voltage v across the capacitor is

q v C = (7.15)

From the Kirchhoff’s loop rule, the voltage across the source and the capacitor are equal,

sin m q v t C ω =

To find the current, we use the relation d q d i t = d ( ) d i v C t C v t m sin m cos( ) t = ω ω ω = Using the relation, cos( ) sin ω ω t t = +    2π   , we have i i t = m +   sin ω π 2 (7.16)

where the amplitude of the oscillating current is im = ωCvm. We can rewrite it as (1/ ) m m v i ωC = Comparing it to im= vm/R for a purely resistive circuit, we find that (1/ωC) plays the role of resistance. It is called capacitive reactance and is denoted by Xc, Xc = 1/ωC (7.17)

so that the amplitude of the current is m m C v i X = (7.18)

The dimension of capacitive reactance is the same as that of resistance and its SI unit is ohm (Ω). The capacitive reactance limits the amplitude of the current in a purely capacitive circuit in the same way as the resistance limits the current in a purely resistive circuit. But it is inversely proportional to the frequency and the capacitance.

A comparison of Eq. (7.16) with the equation of source voltage, Eq. (7.1) shows that the current is π/2 ahead of voltage. Figure 7.9(a) shows the phasor diagram at an instant t1. Here the current phasor I is π/2 ahead of the voltage phasor V as they rotate counterclockwise. Figure 7.9(b) shows the variation of voltage and current with time. We see that the current reaches its maximum value earlier than the voltage by one-fourth of a period.

The instantaneous power supplied to the capacitor is pc = i v = im cos(ωt)vm sin(ωt) = i m v m cos(ωt) sin(ωt) sin(2 ) 2 i v m m = ωt (7.19)

So, as in the case of an inductor, the average power sin(2 ) sin(2 ) 0 2 2 m m m m C i v i v P = ωt = ωt =

since <sin (2ωt)> = 0 over a complete cycle. Figure 7.10 explains it in detail. Thus, we see that in the case of an inductor, the current lags the voltage by π/2 and in the case of a capacitor, the current leads the voltage by π/2.

Example 7.3 A lamp is connected in series with a capacitor. Predict your observations for dc and ac connections. What happens in each case if the capacitance of the capacitor is reduced?

Solution When a dc source is connected to a capacitor, the capacitor gets charged and after charging no current flows in the circuit and the lamp will not glow. There will be no change even if C is reduced. With ac source, the capacitor offers capacitative reactance (1/ωC) and the current flows in the circuit. Consequently, the lamp will shine. Reducing C will increase reactance and the lamp will shine less brightly than before.

Example 7.4 A 15.0 µF capacitor is connected to a 220 V, 50 Hz source. Find the capacitive reactance and the current (rms and peak) in the circuit. If the frequency is doubled, what happens to the capacitive reactance and the current?

Solution The capacitive reactance is 6 F 1 1 212 X C = = 2 2 (50Hz)(15.0 10 ) π π ν C × − = Ω The rms current is I X = = = Ω The peak current is i I m = = 2 (1.41)(1.04 ) 1.47 A A = This current oscillates between +1.47A and –1.47 A, and is ahead of the voltage by π/2. If the frequency is doubled, the capacitive reactance is halved and consequently, the current is doubled.

0-1 The current i flows as shown and from the maximum at 0, reaches a zero value at 1. The plate A is charged to positive polarity while negative charge q builds up in B reaching a maximum at 1 until the current becomes zero. The voltage vc = q/C is in phase with q and reaches maximum value at 1. Current and voltage are both positive. So p = vci is positive. ENERGY IS ABSORBED FROM THE SOURCE DURING THIS QUAR TER CYCLE AS THE CAPACITOR IS CHARGED.

1-2 The current i reverses its direction. The accumulated charge is depleted i.e., the capacitor is discharged during this quarter cycle.The voltage gets reduced but is still positive. The current is negative. Their product, the power is negative. THE ENERGY ABSORBED DURING THE 1/4 CYCLE 0-1 IS RETURNED DURING THIS QUARTER.

2-3 As i continues to flow from A to B, the capacitor is charged to reversed polarity i.e., the plate B acquires positive and A acquires negative charge. Both the current and the voltage are negative. Their product p is positive. The capacitor ABSORBS ENERGY during this 1/4 cycle.

3-4 The current i reverses its direction at 3 and flows from B to A. The accumulated charge is depleted and the magnitude of the voltage vc is reduced. vc becomes zero at 4 when the capacitor is fully discharged. The power is negative.ENERGY ABSORBED DURING 2-3 IS RETURNED TO THE SOURCE. NET ENERGY ABSORBED IS ZERO.

7.6 AC VOLTAGE APPLIED TO A SERIES LCR CIRCUIT

Figure 7.12 shows a series LCR circuit connected to an ac source ε. As usual, we take the voltage of the source to be v = vm sin ωt. If q is the charge on the capacitor and i the current, at time t, we have, from Kirchhoff’s loop rule:

d d i q L i R v t C + + = (7.20)

We want to determine the instantaneous current i and its phase relationship to the applied alternating voltage v. We shall solve this problem by two methods. First, we use the technique of phasors and in the second method, we solve Eq. (7.20) analytically to obtain the time– dependence of i.

7.6.1 Phasor-diagram solution

From the circuit shown in Fig. 7.12, we see that the resistor, inductor and capacitor are in series. Therefore, the ac current in each element is the same at any time, having the same amplitude and phase. Let it be i = i m sin(ωt+φ) (7.21)

where φ is the phase difference between the voltage across the source and the current in the circuit. On the basis of what we have learnt in the previous sections, we shall construct a phasor diagram for the present case.

Let I be the phasor representing the current in the circuit as given by Eq. (7.21). Further, let VL, VR, VC, and V represent the voltage across the inductor, resistor, capacitor and the source, respectively. From previous section, we know that V R is parallel to I, VC is π/2 behind I and V L is π/2 ahead of I. VL, VR, VC and I are shown in Fig. 7.13(a) with apppropriate phaserelations.

The length of these phasors or the amplitude of V R, VC and VL are: v Rm = im R, vCm = im XC, vLm = im XL (7.22) The voltage Equation (7.20) for the circuit can be written as vL + v R + vC = v (7.23)

The phasor relation whose vertical component gives the above equation is V L + VR + VC = V (7.24)

This relation is represented in Fig. 7.13(b). Since V C and VL are always along the same line and in opposite directions, they can be combined into a single phasor (VC + VL) which has a magnitude vCm – vLm. Since V is represented as the hypotenuse of a right-triangle whose sides are VR and (VC + VL), the pythagorean theorem gives: v v v v m Rm Cm Lm 2 2 = + − ( )2

Substituting the values of vRm, vCm, and vLm from Eq. (7.22) into the above equation, we have

v i R i X i X m m 2 = + − ( ) ( 2 m C m L )2 = + − i R X X m2 2   ( ) C L 2   or, 2 2 ( ) m m C L v i R X X = + − [7.25(a)]

By analogy to the resistance in a circuit, we introduce the impedance Z in an ac circuit:

m m v i Z = [7.25(b)]

where Z R X X = + − 2 ( ) C L 2 (7.26) Since phasor I is always parallel to phasor VR, the phase angle φ is the angle between VR and V and can be determined from Fig. 7.14:

tan Cm Lm Rm v v v φ = −

Using Eq. (7.22), we have tan X X C L R φ = − (7.27)

Equations (7.26) and (7.27) are graphically shown in Fig. (7.14). This is called Impedance diagram which is a right-triangle with Z as its hypotenuse.

Equation 7.25(a) gives the amplitude of the current and Eq. (7.27) gives the phase angle. With these, Eq. (7.21) is completely specified. If X C > XL, φ is positive and the circuit is predominantly capacitive. Consequently, the current in the circuit leads the source voltage. If XC < X

L, φ is negative and the circuit is predominantly inductive. Consequently, the current in the circuit lags the source voltage. Figure 7.15 shows the phasor diagram and variation of v and i with ωt for the case X C > XL.

Thus, we have obtained the amplitude and phase of current for an LCR series circuit using the technique of phasors. But this method of analysing ac circuits suffers from certain disadvantages. First, the phasor diagram say nothing about the initial condition. One can take any arbitrary value of t (say, t1, as done throughout this chapter) and draw different phasors which show the relative angle between different phasors. The solution so obtained is called the steady-state solution. This is not a general solution. Additionally, we do have a transient solution which exists even for v = 0. The general solution is the sum of the transient solution and the steady-state solution. After a sufficiently long time, the effects of the transient solution die out and the behaviour of the circuit is described by the steady-state solution.

7.6.2 Analytical solution

The voltage equation for the circuit is

d d i q L R i v t C + + = = v m sin ωt

We know that i = dq/dt. Therefore, di/dt = d2q/dt2. Thus, in terms of q, the voltage equation becomes L R v t t t C + + = ω (7.28)

This is like the equation for a forced, damped oscillator, [see Eq. {14.37(b)} in Class XI Physics Textbook]. Let us assume a solution

q = qm sin (ω t + θ) [7.29(a)]

so that d cos( ) d m q q t t = ω ω θ + [7.29(b)] and 2 2 2 d sin( ) d m q q t t = − ω ω θ + [7.29(c)]

Substituting these values in Eq. (7.28), we get

q R t X X t mω ω θ [ cos( ) ( )sin( ) + + − C L ω θ + ] = v t m sin ω (7.30)

where we have used the relation X c= 1/ωC, XL = ω L. Multiplying and dividing Eq. (7.30) by Z R X X = + − 2 ( ) c L 2 , we have

q Z R Z t X X Z t m ω ω θ  cos( ) + + ( ) C L − sin( ) ω θ +   

sin = v t m ω (7.31) Now, let cos R Z = φ and ( ) X X C L sin Z − = φ so that tan 1 X X C L R φ = − − (7.32)

Substituting this in Eq. (7.31) and simplifying, we get: q Z t v t mω ω θ φ ω cos( ) sin + − = m (7.33) Comparing the two sides of this equation, we see that v q Z i Z m m = = ω m

where i q m m = ω [7.33(a)] and 2 θ φ − = −π or 2 θ φ = − + π [7.33(b)]

Therefore, the current in the circuit is d d i q t q m cos( ) t = = ω ω θ + = i m cos(ωt + θ) or i = i msin(ωt + φ) (7.34) where 2 ( )2 m m m C L v v i Z R X X = = + − [7.34(a)]

and tan 1 X X C L R φ = Thus, the analytical solution for the amplitude and phase of the current in the circuit agrees with that obtained by the technique of phasors.

7.6.3 Resonance

An interesting characteristic of the series RLC circuit is the phenomenon of resonance. The phenomenon of resonance is common among systems that have a tendency to oscillate at a particular frequency. This frequency is called the system’s natural frequency. If such a system is driven by an energy source at a frequency that is near the natural frequency, the amplitude of oscillation is found to be large. A familiar example of this phenomenon is a child on a swing. The swing has a natural frequency for swinging back and forth like a pendulum. If the child pulls on the rope at regular intervals and the frequency of the pulls is almost the same as the frequency of swinging, the amplitude of the swinging will be large (Chapter 14, Class XI).

For an RLC circuit driven with voltage of amplitude vm and frequency ω, we found that the current amplitude is given by

2 ( )2 m m m C L v v i Z R X X = = + − with X

c = 1/ωC and XL = ωL. So if ω is varied, then at a particular frequency ω

0, Xc = XL, and the impedance is minimum (Z R R = + = 2 2 0 ). This frequency is called the resonant frequency:

0 1 0 or X X c L L C ω ω = = or 0 1 LC ω = (7.35)

At resonant frequency, the current amplitude is maximum; im = vm/R. Figure 7.16 shows the variation of im with ω in a RLC series circuit with L = 1.00 mH, C = 1.00 nF for two values of R: (i) R = 100 Ω and (ii) R = 200 Ω. For the source applied vm = 100 V. ω 0 for this case is 1 LC = 1.00×106 rad/s.

We see that the current amplitude is maximum at the resonant frequency. Since im = vm / R at resonance, the current amplitude for case (i) is twice to that for case (ii).

Resonant circuits have a variety of applications, for example, in the tuning mechanism of a radio or a TV set. The antenna of a radio accepts signals from many broadcasting stations. The signals picked up in the antenna acts as a source in the tuning circuit of the radio, so the circuit can be driven at many frequencies.

But to hear one particular radio station, we tune the radio. In tuning, we vary the capacitance of a capacitor in the tuning circuit such that the resonant frequency of the circuit becomes nearly equal to the frequency of the radio signal received. When this happens, the amplitude of the current with the frequency of the signal of the particular radio station in the circuit is maximum.

It is important to note that resonance phenomenon is exhibited by a circuit only if both L and C are present in the circuit. Only then do the voltages across L and C cancel each other (both being out of phase) and the current amplitude is vm/R, the total source voltage appearing across R. This means that we cannot have resonance in a RL or RC circuit.

Sharpness of resonance

The amplitude of the current in the series LCR circuit is given by

i v R L C m m = + −   2 2 1 ω ω

and is maximum when ω ω = = 0 1/ . L C The maximum value is i v R m m max = / .

For values of ω other than ω 0, the amplitude of the current is less than the maximum value. Suppose we choose a value of ω for which the current amplitude is 1/ 2 times its maximum value. At this value, the power dissipated by the circuit becomes half. From the curve in Fig. (7.16), we see that there are two such values of ω, say, ω1 and ω2, one greater and the other smaller than ω0 and symmetrical about ω0. We may write

ω 1 = ω0 + ∆ω ω 2 = ω0 – ∆ω The difference ω

1 – ω2 = 2∆ω is often called the bandwidth of the circuit. The quantity (ω0 / 2∆ω) is regarded as a measure of the sharpness of resonance. The smaller the ∆ω, the sharper or narrower is the resonance. To get an expression for ∆ω, we note that the current amplitude im is (1/ 2)i mmax for ω1 = ω0 + ∆ω. Therefore,

at ω 1 2 1 1 2 1 , i v R L C m m = + −   ω ω max 2 2 i v m m R

or R L C 2 R 1 1 2 1 + − 2  

ω = ω or R L C 2 R 1 1 2 1 2 + − 2  

ω = ω 1 1 1 L R C ω ω − =

which may be written as, 0 0 1 ( ) ( ) L R C ω ω ω ω + ∆ − = + ∆ ω ω ω ω ω ω 0 0 0 0 1 1 1 L C + R  

− +   = ∆ ∆ Using 02 1 L C ω = in the second term on the left hand side, we get ω ω ω ω ω ω 0 0 0 0 1 1 L L + R   − +  

= ∆ ∆ We can approximate 1 0 1 +   − ∆ω ω as 1 0 −  

∆ω ω since ω 0 ω ∆ «1. Therefore, ω ω ω ω ω ω 0 0 0 0 L 1 + L 1 R  

− −   = ∆ ∆ or 0 0 2 ω L R ω ∆ ω = R 2L ∆ = ω [7.36(a)]

The sharpness of resonance is given by, 0 0 2 L R ω ω ω = ∆ [7.36(b)]

The ratio 0L R ω is also called the quality factor, Q of the circuit. 0L Q R ω = [7.36(c)]

From Eqs. [7.36 (b)] and [7.36 (c)], we see that 2 0 ω Q ∆ = ω . So, larger the

value of Q, the smaller is the value of 2∆ω or the bandwidth and sharper is the resonance. Using ω02 = 1/L C , Eq. [7.36(c)] can be equivalently expressed as Q = 1/ω0CR.

We see from Fig. 7.15, that if the resonance is less sharp, not only is the maximum current less, the circuit is close to resonance for a larger range ∆ω of frequencies and the tuning of the circuit will not be good. So, less sharp the resonance, less is the selectivity of the circuit or vice versa. From Eq. (7.36), we see that if quality factor is large, i.e., R is low or L is large, the circuit is more selective.

7.7 POWER IN AC CIRCUIT: THE POWER FACTOR

We have seen that a voltage v = vm sinωt applied to a series RLC circuit drives a current in the circuit given by i = im sin(ωt + φ) where

m m v i Z = and φ =  − tan−1   X X C L R   

Therefore, the instantaneous power p supplied by the source is p v i v t i t = = ( m sin sin( ) ω ) × + [ m ω φ ] [cos cos(2 )] 2 v i m m = φ ω φ − + t (7.37)

The average power over a cycle is given by the average of the two terms in R.H.S. of Eq. (7.37). It is only the second term which is time-dependent. Its average is zero (the positive half of the cosine cancels the negative half). Therefore,

cos 2 v i m m P = φ cos 2 2 v i m m = φ = V I cosφ [7.38(a)]

This can also be written as, 2 P I Z = cosφ [7.38(b)]

So, the average power dissipated depends not only on the voltage and current but also on the cosine of the phase angle φ between them. The quantity cosφ is called the power factor. Let us discuss the following cases:

Case (i) Resistive circuit: If the circuit contains only pure R, it is called resistive. In that case φ= 0, cos φ =1.Thereis maximum power dissipation.

Case (ii) Purely inductive or capacitive circuit: If the circuit contains only an inductor or capacitor, we know that the phase difference between voltage and current is π/2. Therefore, cos φ = 0, and no power is dissipated even though a current is flowing in the circuit. This current is sometimes referred to as wattless current.

Case (iii) LCR series circuit: In an LCR series circuit, power dissipated is given by Eq. (7.38) where φ = tan–1 (Xc – XL )/ R. So, φ may be non-zero in a RL or RC or RCL circuit. Even in such cases, power is dissipated only in the resistor.

Case (iv) Power dissipated at resonance in LCR circuit: At resonance Xc – X L= 0, and φ = 0. Therefore, cosφ = 1 and P = I 2Z = I 2 R. That is, maximum power is dissipated in a circuit (through R) at resonance.

7.8 LC OSCILLATIONS

We know that a capacitor and an inductor can store electrical and magnetic energy, respectively. When a capacitor (initially charged) is connected to an inductor, the charge on the capacitor and the current in the circuit exhibit the phenomenon of electrical oscillations similar to oscillations in mechanical systems (Chapter 14, Class XI).

Let a capacitor be charged qm (at t = 0) and connected to an inductor as shown in Fig. 7.18.

The moment the circuit is completed, the charge on the capacitor starts decreasing, giving rise to current in the circuit. Let q and i be the charge and current in the circuit at time t. Since di/dt is positive, the induced emf in L will have polarity as shown, i.e., vb< va. According to Kirchhoff’s loop rule,

d 0 d q i L C t − = (7.39)

i = – (dq/dt) in the present case (as q decreases, i increases). Therefore, Eq. (7.39) becomes:

2 2 d 1 0 d q q t LC + = (7.40)

This equation has the form 2 20 2 d 0 d x x t + = ω for a simple harmonic

oscillator. The charge on the capacitor, therefore, oscillates with a natural frequency 0 1 LC ω = (7.41)

and varies sinusoidally with time as q q t = m cos(ω φ 0 + ) (7.42)

where qm is the maximum value of q and φ is a phase constant. Since q = qm at t = 0, we have cos φ =1 or φ = 0. Therefore, in the present case,

q q t = m cos( ) ω0 (7.43)

The current i q t = −   d d is given by i i t = m sin( ) ω0 (7.44) where i q m m = ω0

Let us now try to visualise how this oscillation takes place in the circuit.

Figure 7.19(a) shows a capacitor with initial charge qm connected to an ideal inductor. The electrical energy stored in the charged capacitor is 2 1 2 m E q U C = . Since, there is no current in the circuit, energy in the inductor is zero. Thus, the total energy of LC circuit is, 2 1 2 m E q U U C

At t = 0, the switch is closed and the capacitor starts to discharge [Fig. 7.19(b)]. As the current increases, it sets up a magnetic field in the inductor and thereby, some energy gets stored in the inductor in the form of magnetic energy: UB = (1/2) Li2. As the current reaches its maximum value i m , (at t = T/4) as in Fig. 7.19(c), all the energy is stored in the magnetic field: UB = (1/2) Li2m. You can easily check that the maximum electrical energy equals the maximum magnetic energy. The capacitor now has no charge and hence no energy. The current now starts charging the capacitor, as in Fig. 7.19(d). This process continues till the capacitor is fully charged (at t = T/2) [Fig. 7.19(e)]. But it is charged with a polarity opposite to its initial state in Fig. 7.19(a). The whole process just described will now repeat itself till the system reverts to its original state. Thus, the energy in the system oscillates between the capacitor and the inductor.

The LC oscillation is similar to the mechanical oscillation of a block attached to a spring. The lower part of each figure in Fig. 7.19 depicts the corresponding stage of a mechanical system (a block attached to a spring). As noted earlier, for a block of a mass m oscillating with frequency ω

0, the equation is 2 2 2 0 d 0 d x x t + = ω

Here,

ω0 = k m / , and k is the spring constant. So, x corresponds to q. In case of a mechanical system F = ma = m (dv/dt) = m (d2x/dt2). For an electrical system, ε = –L (di/dt) = –L (d2q/dt 2). Comparing these two equations, we see that L is analogous to mass m: L is a measure of resistance to change in current. In case of LC circuit, ω0 = 1/ LC and for mass on a spring, ω0 = k m / . So, 1/C is analogous to k. The constant k (=F/x) tells us the (external) force required to produce a unit displacement whereas 1/C (=V/q) tells us the potential difference required to store a unit charge. Table 7.1 gives the analogy between mechanical and electrical quantities.

Note that the above discussion of LC oscillations is not realistic for two reasons:

(i) Every inductor has some resistance. The effect of this resistance is to introduce a damping effect on the charge and current in the circuit and the oscillations finally die away.

(ii) Even if the resistance were zero, the total energy of the system would not remain constant. It is radiated away from the system in the form of electromagnetic waves (discussed in the next chapter). In fact, radio and TV transmitters depend on this radiation.

7.9 TRANSFORMERS

For many purposes, it is necessary to change (or transform) an alternating voltage from one to another of greater or smaller value. This is done with a device called transformer using the principle of mutual induction. A transformer consists of two sets of coils, insulated from each other. They are wound on a soft-iron core, either one on top of the other as in Fig. 7.20(a) or on separate limbs of the core as in Fig. 7.20(b). One of the coils called the primary coil has N p turns. The other coil is called the secondary coil; it has Ns turns. Often the primary coil is the input coil and the secondary coil is the output coil of the transformer.

When an alternating voltage is applied to the primary, the resulting current produces an alternating magnetic flux which links the secondary and induces an emf in it. The value of this emf depends on the number of turns in the secondary. We consider an ideal transformer in which the primary has negligible resistance and all the flux in the core links both primary and secondary windings. Let φ be the flux in each turn in the core at time t due to current in the primary when a voltage v p is applied to it.

Then the induced emf or voltage εs, in the secondary with Ns turns is d d s s N φ t ε = − (7.45)

The alternating flux φ also induces an emf, called back emf in the primary. This is

d d p p N φ t ε = − (7.46) But ε p = v p

. If this were not so, the primary current would be infinite since the primary has zero resistance (as assumed). If the secondary is an open circuit or the current taken from it is small, then to a good approximation

ε s = v s where v

s is the voltage across the secondary. Therefore, Eqs. (7.45) and (7.46) can be written as

s s d v N d t φ = − [7.45(a)] p p d v N d t φ = − [7.46(a)]

From Eqs. [7.45 (a)] and [7.46 (a)], we have s s p p

Note that the above relation has been obtained using three assumptions: (i) the primary resistance and current are small; (ii) the same flux links both the primary and the secondary as very little flux escapes from the core, and (iii) the secondary current is small. If the transformer is assumed to be 100% efficient (no energy losses), the power input is equal to the power output, and since p = i v,

ip vp = i svs (7.48)

Although some energy is always lost, this is a good approximation, since a well designed transformer may have an efficiency of more than 95%. Combining Eqs. (7.47) and (7.48), we have

p s s s p p i v N i v N = = (7.49)

Since i and v both oscillate with the same frequency as the ac source, Eq. (7.49) also gives the ratio of the amplitudes or rms values of corresponding quantities. Now, we can see how a transformer affects the voltage and current. We have:

V N N V s s p = p   and I N N I s p s = p   (7.50)

That is, if the secondary coil has a greater number of turns than the primary (Ns > Np), the voltage is stepped up (Vs > Vp). This type of arrangement is called a step-up transformer. However, in this arrangement, there is less current in the secondary than in the primary (N p /N s < 1 and I s < I

p). For example, if the primary coil of a transformer has 100 turns and the secondary has 200 turns, Ns/Np = 2 and Np/Ns=1/2. Thus, a 220V input at 10A will step-up to 440 V output at 5.0 A. If the secondary coil has less turns than the primary (Ns < Np), we have a step-down transformer. In this case, Vs < Vp and Is > Ip. That is, the voltage is stepped down, or reduced, and the current is increased. The equations obtained above apply to ideal transformers (without any energy losses). But in actual transformers, small energy losses do occur due to the following reasons:

(i) Flux Leakage: There is always some flux leakage; that is, not all of the flux due to primary passes through the secondary due to poor design of the core or the air gaps in the core. It can be reduced by winding the primary and secondary coils one over the other.

(ii) Resistance of the windings: The wire used for the windings has some resistance and so, energy is lost due to heat produced in the wire (I 2R). In high current, low voltage windings, these are minimised by using thick wire.

(iii) Eddy currents: The alternating magnetic flux induces eddy currents in the iron core and causes heating. The effect is reduced by using a laminated core.

(iv) Hysteresis: The magnetisation of the core is repeatedly reversed by the alternating magnetic field. The resulting expenditure of energy in the core appears as heat and is kept to a minimum by using a magnetic material which has a low hysteresis loss

The large scale transmission and distribution of electrical energy over long distances is done with the use of transformers. The voltage output of the generator is stepped-up (so that current is reduced and consequently, the I 2R loss is cut down). It is then transmitted over long distances to an area sub-station near the consumers. There the voltage is stepped down. It is further stepped down at distributing sub-stations and utility poles before a power supply of 240 V reaches our homes.

SUMMARY

An alternating voltage v v t = ω m sin applied to a resistor R drives a current i = i m sinωt in the resistor, im = vRm . The current is in phase with the applied voltage.
For an alternating current i = im sin ωt passing through a resistor R, the average power loss P (averaged over a cycle) due to joule heating is ( 1/2 )i 2 mR. To express it in the same form as the dc power (P = I 2R), a special value of current is used. It is called root mean square (rms) current and is donoted by I: 0.707 m 2 m i I = = i

Similarly, the rms voltage is defined by

0.707 m 2 m v V = = v We have P = IV = I 2R

An ac voltage v = vm sin ωt applied to a pure inductor L, drives a current in the inductor i = i m sin (ωt – π/2), where im = vm/XL. XL = ωL is called inductive reactance. The current in the inductor lags the voltage by π/2. The average power supplied to an inductor over one complete cycle is zero.
An ac voltage v = vm sinωt applied to a capacitor drives a current in the capacitor: i = im sin (ωt + π/2). Here, 1 , m m C C v i X X C ω = = is called capacitive reactance. The current through the capacitor is π/2 ahead of the applied voltage. As in the case of inductor, the average power supplied to a capacitor over one complete cycle is zero.
For a series RLC circuit driven by voltage v = vm sin ωt, the current is given by i = im sin (ωt + φ) where 2 ( )2 m m C L v i R X X = + − and tan 1 X X C L R φ = − − Z R X X = + − 2 ( ) C L 2 is called the impedance of the circuit.

The average power loss over a complete cycle is given by

P = V I cosφ

The term cosφ is called the power factor.

In a purely inductive or capacitive circuit, cosφ = 0 and no power is dissipated even though a current is flowing in the circuit. In such cases, current is referred to as a wattless current.
The phase relationship between current and voltage in an ac circuit can be shown conveniently by representing voltage and current by rotating vectors called phasors. A phasor is a vector which rotates about the origin with angular speed ω. The magnitude of a phasor represents the amplitude or peak value of the quantity (voltage or current) represented by the phasor. The analysis of an ac circuit is facilitated by the use of a phasor diagram.
An interesting characteristic of a series RLC circuit is the phenomenon of resonance. The circuit exhibits resonance, i.e., the amplitude of the current is maximum at the resonant frequency, 0 1 LC ω = . The quality factor Q defined by 0L Q R ω = 0 1 ω CR = is an indicator of the sharpness of the resonance, the higher value of Q indicating sharper peak in the current.
A circuit containing an inductor L and a capacitor C (initially charged) with no ac source and no resistors exhibits free oscillations. The charge q of the capacitor satisfies the equation of simple harmonic motion: 2 2 d 1 q q 0 dt LC + = and therefore, the frequency ω of free oscillation is 0 1 LC ω = . The energy in the system oscillates between the capacitor and the inductor but their sum or the total energy is constant in time.
A transformer consists of an iron core on which are bound a primary coil of N p turns and a secondary coil of Ns turns. If the primary coil is connected to an ac source, the primary and secondary voltages are related by V N N V s s p = p   and the currents are related by I N N I s p s = p   If the secondary coil has a greater number of turns than the primary, the voltage is stepped-up (Vs > Vp). This type of arrangement is called a stepup transformer. If the secondary coil has turns less than the primary, we have a step-down transformer.

POINTS TO PONDER

When a value is given for ac voltage or current, it is ordinarily the rms value. The voltage across the terminals of an outlet in your room is normally 240 V. This refers to the rms value of the voltage. The amplitude of this voltage is v V m = = = 2 2(240) 340 V
The power rating of an element used in ac circuits refers to its average power rating.
The power consumed in an ac circuit is never negative.
Both alternating current and direct current are measured in amperes. But how is the ampere defined for an alternating current? It cannot be derived from the mutual attraction of two parallel wires carrying ac currents, as the dc ampere is derived. An ac current changes direction with the source frequency and the attractive force would average to zero. Thus, the ac ampere must be defined in terms of some property that is independent of the direction of the current. Joule heating is such a property, and there is one ampere of rms value of alternating current in a circuit if the current produces the same average heating effect as one ampere of dc current would produce under the same conditions.
In an ac circuit, while adding voltages across different elements, one should take care of their phases properly. For example, if VR and VC are voltages across R and C, respectively in an RC circuit, then the total voltage across RC combination is V V V RC R C = + 2 2 and not VR + V C since VC is π/2 out of phase of VR.
Though in a phasor diagram, voltage and current are represented by vectors, these quantities are not really vectors themselves. They are scalar quantities. It so happens that the amplitudes and phases of harmonically varying scalars combine mathematically in the same way as do the projections of rotating vectors of corresponding magnitudes and directions. The ‘rotating vectors’ that represent harmonically varying scalar quantities are introduced only to provide us with a simple way of adding these quantities using a rule that we already know as the law of vector addition.
There are no power losses associated with pure capacitances and pure inductances in an ac circuit. The only element that dissipates energy in an ac circuit is the resistive element.
In a RLC circuit, resonance phenomenon occur when XL = XC or 0 1 LC ω = . For resonance to occur, the presence of both L and C elements in the circuit is a must. With only one of these (L or C ) elements, there is no possibility of voltage cancellation and hence, no resonance is possible.
The power factor in a RLC circuit is a measure of how close the circuit is to expending the maximum power.
In generators and motors, the roles of input and output are reversed. In a motor, electric energy is the input and mechanical energy is the output. In a generator, mechanical energy is the input and electric energy is the output. Both devices simply transform energy from one form to another.
A transformer (step-up) changes a low-voltage into a high-voltage. This does not violate the law of conservation of energy. The current is reduced by the same proportion.
The choice of whether the description of an oscillatory motion is by means of sines or cosines or by their linear combinations is unimportant, since changing the zero-time position transforms the one to the other.

EXERCISES

7.1 A 100 Ω resistor is connected to a 220 V, 50 Hz ac supply.

(a) What is the rms value of current in the circuit?

(b) What is the net power consumed over a full cycle?

7.2 (a) The peak voltage of an ac supply is 300 V. What is the rms voltage?

(b) The rms value of current in an ac circuit is 10 A. What is the peak current?

7.3 A 44 mH inductor is connected to 220 V, 50 Hz ac supply. Determine the rms value of the current in the circuit.

7.4 A 60 µF capacitor is connected to a 110 V, 60 Hz ac supply. Determine the rms value of the current in the circuit.

7.5 In Exercises 7.3 and 7.4, what is the net power absorbed by each circuit over a complete cycle. Explain your answer.

7.6 Obtain the resonant frequency ωr of a series LCR circuit with L = 2.0H, C = 32 µF and R = 10 Ω. What is the Q-value of this circuit?

7.7 A charged 30 µF capacitor is connected to a 27 mH inductor. What is the angular frequency of free oscillations of the circuit?

7.8 Suppose the initial charge on the capacitor in Exercise 7.7 is 6 mC. What is the total energy stored in the circuit initially? What is the total energy at later time?

7.9 A series LCR circuit with R = 20 Ω, L = 1.5 H and C = 35 µF is connected to a variable-frequency 200 V ac supply. When the frequency of the supply equals the natural frequency of the circuit, what is the average power transferred to the circuit in one complete cycle?

7.10 A radio can tune over the frequency range of a portion of MW broadcast band: (800 kHz to 1200 kHz). If its LC circuit has an effective inductance of 200 µH, what must be the range of its variable capacitor?

[Hint: For tuning, the natural frequency i.e., the frequency of free oscillations of the LC circuit should be equal to the frequency of the radiowave.]

7.11 Figure 7.21 shows a series LCR circuit connected to a variable frequency 230 V source. L = 5.0 H, C = 80µF, R = 40 Ω.

(a) Determine the source frequency which drives the circuit in resonance.

(b) Obtain the impedance of the circuit and the amplitude of current at the resonating frequency.

(c) Determine the rms potential drops across the three elements of the circuit. Show that the potential drop across the LC combination is zero at the resonating frequency.

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