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Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced PDF Download

Series L-R Circuit

  • Now consider an ac circuit consisting of a resistor of resistance R and an inductor of inductance L in series with an ac source generator.
  • Suppose in phasor diagram, current is taken along positive x-direction. The VR is also along positive x-direction and VL along positive y-direction as we know that potential difference across a resistance in ac is in phase with current and it leads in phase by 90º with current across the inductor, and as we know VR = i0R & V0 = i0XL
    i = i0 sin wt
    Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced
    VR(t) = i0 Rsin ωt
    VL(t) = i0 XL sin (ωt + p/2)
    hence we can write
    V(t) = i0R sin ωt + i0 XL sin (ωt + p/2)
    V0 = i0Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced
    where Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced is known as impedence (z) of the circuit.
    now we can write
    Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced
    where tan β= Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced
    hence β = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Example 1. When 100 volt dc is applied across a coil, a current of 1 amp flows through it; when 100 V ac of 50 Hz is applied to the same coil, only 0.5 amp flows. Calculate the resistance of inductance of the coil.

Sol. In case of a coil, i.e., L - R circuit.

i = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced with Z = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

So when dc is applied, ω = 0, so z = R

and hence i = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced i.e., R = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced = 200 ?

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advancedi.e., ω2L2 = Z2-R2

i.e., (2πfL)2 = 2002 - 1002 = 3 × 104 (as ω = 2πf)

So, L = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced = 0.55 H


Example 2. A 12 ohm resistance and an inductance of 0.05/p henry with negligible resistance are connected in series. Across the end of this circuit is connected a 130 volt alternating voltage of frequency 50 cycles/second. Calculate the alternating current in the circuit and potential difference across the resistance and that across the inductance.

Sol. The impedance of the circuit is given by

Z = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

= Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced = 13 ohm

Current in the circuit i = E/Z = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced = 10 amp

Potential difference across resistance

VR = iR = 10 × 12 = 120 volt

Inductive reactance of coil XL = ωL = 2πfL

Therefore, XL = 2π × 50 × Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced = 5 ohm

Potential difference across inductance

VL = i × XL = 10 × 5 = 50 volt

Series C-R Circuit

Now consider an ac circuit consisting of a resistor of resistance R and an capacitor of capacitance C in series with an ac source generator.

Suppose in phasor diagram current is taken along positive x-direction. Then VR is also along positive x-direction but VC is along negative y-direction as potential difference across a capacitor in ac lags in phase by 90º with the current in the circuit. So we can write,

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

VR = I0 R sin ωt Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Potential difference across capacitor

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Potential at any instant t

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

V(t) = V0 sin (ωt + b)

tan α = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Example 3. An A.C. source of angular frequency w is fed across a resistor R and a capacitor C in series. The current registered is i. If now the frequency of the source is changed to ω/3 (but maintaining the same voltage), the current in the circuit is found to be halved. Calculate the ratio of reactance to resistance at the original frequency.

Sol. At angular frequency w, the current in R-C circuit is given by

irms = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced ...(i)

When frequency is changed to ω/3, the current is halved. Thus

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced ...(ii)

From equations (i) and (ii), we have

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Solving this equation, we get Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Hence, the ratio of reactance to resistance is Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Example 4. A 50 W, 100 V lamp is to be connected to an ac mains of 200 V, 50 Hz. What capacitance is essential to be put in series with the lamp?

Sol. As resistance of the lamp R = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced = 200 ? and the maximum current i = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced ; so when the lamp is put in series with a capacitance and run at 200 V ac, from V =iZ we have,

Z = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced = 400?

Now as in case of C-R circuit, Z = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced,

i.e., R2 + Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced = 160000

or, Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced = 16 × 104 - (200)2 = 12 × 104

So, Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced × 102

or C = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

i.e., C = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced = 9.2 μF

L.C. Circuit

As shown in figure a capacitor and inductance are connected in series method and alternating voltage is applied across the circuit.

Let Xc is capacitance reactance,

XL is Inductance reactance,

i = i0 sin wt current flowing through the circuit

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

VC(t) = i0 XC sin (ωt - π/2)

VL(t) = i0 XL sin (ωt + π/2)

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

= i0 XC sin wt cos π/2 - i0 XC cos wt sin π/2 + i0 XL sin wt cos π/2 + i0 XL cos wt sin π/2

= i0 cos w t(XL - XC)

V(t) = V0sin (wt + p/2)

V0 = i0Z Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Z = (X- XC)

cos Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced= 0

VCO = i0 XC ; Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Series L-C-R Circuit

Now consider an ac circuit consisting of a resistor of resistance R, a capacitor of capacitance C and an inductor of inductance L are in series with an ac source generator.

Suppose in a phasor diagram current is taken along positive x-direction. Then VR is along positive x-direction, VL along positive y-direction and VC along negative y-direction, as potential difference across an inductor leads the current by 90° in phase while that across a capacitor, lags by 90°.

V = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

L - R - C circuit

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Impedance phasor of above circuit

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

 

& Impedance triangle

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

here B is phase angle By triangle tan β= Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Power factor cosSeries L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced= Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Let I be the current in the series circuit of any instant then

(1) Voltage V(t) = V0 sin (ωt + β) = i0 z sin (ωt + β)

here v0 = i0z & vrms = irmsz

(2) Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced here voltage VL across the inductance is ahead of current I in phase by π/2 rad

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

(3) VC(t) = VO C sin (ωt - π/2)

here voltage VC across the capacitance lags behind the current I in phase by π/2 rad

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

(4) VR(t) = i0 R sin ωt

here voltage VR across the resistor R has same phase as I

VO R = IR

Special Case :

(1) When XL > XC or VL > VC then emf is ahead of current by phase β which is given by

tan β = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced or cos f = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

The series LCR circuit is said to be inductive

(2) When XL < XC or VL < VC then current is ahead of emf by phase angle β which is given by

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced or Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

The series LCR circuit is said to be capacitive

(3) When XL = XC or VL = VC, b = 0, the emf and current will be in the same phase. The series LCR circuit is said to be purely resistive. It may also be noted that

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced or Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced or IRms = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Susceptance : The reciprocal of the reactane of an a.c. circuit is called its susceptance.

Admittance : The reciprocal of the impedance of an a.c. circuit is called its admittance.

Ex.10 Figure shows a series LCR circuit connected to a variable voltage source V = 10 sin (ωt + p/4) ;

xL = 10 ?, XC = 6 ?, R = 3 ?

Calculate Z, i0, irms, vrms, VL O, VC O, VR O, b,

VL Rms, VC Rms, VRms, i(t), VL(t), Vc(t), and VR(t)

 

Series L-R, C-R & C-R Circuit | Physics for JEE Main & AdvancedXL > XC

Sol. V = 10 sin (wt + p/4) so V0 = 10 volt

Vrms = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Therefore, Z = Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced; Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced; Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced; Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

i(t) = 20 sin (ωt + π/4 - 53°)

VL(t) = 20 sin (ωt + π/4 - 53° + π/2)

= 20 sin (ωt + Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced - 53° - Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced) = 12 sin (ωt - Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced - 53°)

Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced

Ex.11 A resistor of resistance R, an inductor of inductance L and a capacitor of capacitance C all are connected in series with an a.c. supply. The resistance of R is 16 ohm and for a given frequency the inductive reactance of L is 24 ohm and capacitive reactance of C is 12 ohm. If the current in the circuit is 5 amp., find

(a) the potential difference across R, L and C (b) the impedance of the circuit

(c) the voltage of a.c. supply (d) phase angle

Sol. (a) Potential difference across resistance

VR = iR = 5 × 16 = 80 volt

Potential difference across inductance

VL = i × (wL) = 5 × 24 = 120 volt

The document Series L-R, C-R & C-R Circuit | Physics for JEE Main & Advanced is a part of the JEE Course Physics for JEE Main & Advanced.
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FAQs on Series L-R, C-R & C-R Circuit - Physics for JEE Main & Advanced

1. What is a Series L-R circuit?
Ans. A Series L-R circuit is a type of electrical circuit that consists of an inductor (L) and a resistor (R) connected in series. In this circuit, the inductor opposes changes in current flow due to its property of storing energy in its magnetic field, while the resistor dissipates electrical energy in the form of heat.
2. What is the significance of a Series C-R circuit?
Ans. A Series C-R circuit is a circuit that includes a capacitor (C) and a resistor (R) connected in series. This type of circuit is commonly used in power factor correction applications. The capacitor in the circuit helps to improve the power factor by compensating for the reactive power in the system.
3. What is an L.C. circuit?
Ans. An L.C. circuit, also known as a tank circuit or resonant circuit, is an electrical circuit that includes an inductor (L) and a capacitor (C) connected in parallel. This type of circuit exhibits resonance, which occurs when the natural frequency of the circuit matches the frequency of an applied alternating current. L.C. circuits are commonly used in radio receivers and transmitters.
4. What is the purpose of a Series L-C-R circuit?
Ans. A Series L-C-R circuit is designed to provide a specific frequency response or filter a particular range of frequencies. By combining the elements of an inductor (L), a capacitor (C), and a resistor (R) in series, this circuit can be used to create low-pass, high-pass, or band-pass filters. The values of the components determine the cutoff frequency and the shape of the frequency response.
5. What are some applications of Series L-R, C-R, and L-C-R circuits?
Ans. Series L-R, C-R, and L-C-R circuits find applications in various areas of electrical engineering. Some common applications include audio frequency amplifiers, radio frequency filters, power factor correction in electrical distribution systems, impedance matching, and resonance control in electronic devices. These circuits are also used in communication systems, signal processing, and power electronics.
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