Network Theory - Passive Elements | Network Theory (Electric Circuits) - Electrical Engineering (EE) PDF Download

Passive elements in electrical and electronic circuits are components that do not generate energy but can store or dissipate it. They typically do not require an external power source to operate and can only absorb energy. The most common passive elements include resistors, capacitors, and inductors.

Some Passive Elements

Hence, some of the common passive elements are:

  1. Resistor
  2. Inductor
  3. Capacitor
  4. Coil

Resistor

  • The main functionality of Resistor is either opposes or restricts the flow of electric current. Hence, the resistors are used in order to limit the amount of current flow and / or dividing (sharing) voltage.
  • Let the current flowing through the resistor is I amperes and the voltage across it is V volts. The symbol of resistor along with current, I and voltage, V are shown in the following figure.
    R in the given circuit is resistor
    R in the given circuit is resistor

According to Ohm’s law, the voltage across resistor is the product of current flowing through it and the resistance of that resistor. Mathematically, it can be represented as:

⇒ V= IR     Equation 1
⇒ I= V/R  Equation 2

Where, R is the resistance of a resistor.

From Equation 2, we can conclude that the current flowing through the resistor is directly proportional to the applied voltage across resistor and inversely proportional to the resistance of resistor.
Power in an electric circuit element can be represented as

P = VI      Equation 3

Substitute, Equation 1 in Equation 3.

⇒ P = (IR)*I
⇒ P = I2R      Equation 4

Substitute, Equation 2 in Equation 3.

Network Theory - Passive Elements | Network Theory (Electric Circuits) - Electrical Engineering (EE)
Network Theory - Passive Elements | Network Theory (Electric Circuits) - Electrical Engineering (EE)   Equation 5

So, we can calculate the amount of power dissipated in the resistor by using one of the formulae mentioned in Equations 3 to 5.

Question for Network Theory - Passive Elements
Try yourself:Which of the following is the correct formula to calculate power dissipated in a resistor?
View Solution

Inductor

In general, inductors will have number of turns. Hence, they produce magnetic flux when current flows through it. So, the amount of total magnetic flux produced by an inductor depends on the current, I flowing through it and they have linear relationship.
Mathematically, it can be written as:

⇒ Ψ α I
⇒ Ψ = LI

Where,

  • Ψ is the total magnetic flux
  • L is the inductance of an inductor

Let the current flowing through the inductor is I amperes and the voltage across it is V volts. The symbol of inductor along with current I and voltage V are shown in the following figure.
L is the inductor in the circuitL is the inductor in the circuitAccording to Faraday’s law, the voltage across the inductor can be written as
Network Theory - Passive Elements | Network Theory (Electric Circuits) - Electrical Engineering (EE)
Substitute Ψ = LI in the above equation.
Network Theory - Passive Elements | Network Theory (Electric Circuits) - Electrical Engineering (EE)
Network Theory - Passive Elements | Network Theory (Electric Circuits) - Electrical Engineering (EE)
Network Theory - Passive Elements | Network Theory (Electric Circuits) - Electrical Engineering (EE)
From the above equations, we can conclude that there exists a linear relationship between voltage across inductor and current flowing through it.
We know that power in an electric circuit element can be represented as
P = VI
Substitute Network Theory - Passive Elements | Network Theory (Electric Circuits) - Electrical Engineering (EE) in the above equation.
Network Theory - Passive Elements | Network Theory (Electric Circuits) - Electrical Engineering (EE)
Network Theory - Passive Elements | Network Theory (Electric Circuits) - Electrical Engineering (EE)
By integrating the above equation, we will get the energy stored in an inductor as
Network Theory - Passive Elements | Network Theory (Electric Circuits) - Electrical Engineering (EE)
So, the inductor stores the energy in the form of magnetic field.

Question for Network Theory - Passive Elements
Try yourself:Which of the following equations represents the relationship between the total magnetic flux (Φ), and the current I flowing through an inductor?
View Solution

Capacitor

  • In general, a capacitor has two conducting plates, separated by a dielectric medium. If positive voltage is applied across the capacitor, then it stores positive charge. 
  • Similarly, if negative voltage is applied across the capacitor, then it stores negative charge.
    So, the amount of charge stored in the capacitor depends on the applied voltage V across it and they have linear relationship. 

Mathematically, it can be written as:

⇒ Q  α  V
⇒ Q = CV

Where,

  • Q is the charge stored in the capacitor.
  • C is the capacitance of a capacitor.

Let the current flowing through the capacitor is I amperes and the voltage across it is V volts. The symbol of capacitor along with current I and voltage V are shown in the following figure.
Network Theory - Passive Elements | Network Theory (Electric Circuits) - Electrical Engineering (EE)
We know that the current is nothing but the time rate of flow of charge. Mathematically, it can be represented as
I = dQ/dt
Substitute Q = CV in the above equation.
Network Theory - Passive Elements | Network Theory (Electric Circuits) - Electrical Engineering (EE)
Network Theory - Passive Elements | Network Theory (Electric Circuits) - Electrical Engineering (EE)
Network Theory - Passive Elements | Network Theory (Electric Circuits) - Electrical Engineering (EE)
From the above equations, we can conclude that there exists a linear relationship between voltage across capacitor and current flowing through it.
We know that power in an electric circuit element can be represented as
P = VI
Substitute Network Theory - Passive Elements | Network Theory (Electric Circuits) - Electrical Engineering (EE) in the above equation.
Network Theory - Passive Elements | Network Theory (Electric Circuits) - Electrical Engineering (EE)
Network Theory - Passive Elements | Network Theory (Electric Circuits) - Electrical Engineering (EE)

By integrating the above equation, we will get the energy stored in the capacitor as
Network Theory - Passive Elements | Network Theory (Electric Circuits) - Electrical Engineering (EE)
So, the capacitor stores the energy in the form of electric field.

The document Network Theory - Passive Elements | Network Theory (Electric Circuits) - Electrical Engineering (EE) is a part of the Electrical Engineering (EE) Course Network Theory (Electric Circuits).
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FAQs on Network Theory - Passive Elements - Network Theory (Electric Circuits) - Electrical Engineering (EE)

1. What are passive elements in electrical engineering?
Ans. Passive elements in electrical engineering are components that do not generate energy but instead store or dissipate it. Examples include resistors, inductors, and capacitors.
2. What is the function of a resistor in a circuit?
Ans. A resistor limits the flow of electrical current in a circuit, controlling the amount of current that passes through it.
3. How does an inductor work in a circuit?
Ans. An inductor stores energy in the form of a magnetic field when current flows through it, resisting changes in current.
4. What is the role of a capacitor in an electrical circuit?
Ans. A capacitor stores electrical energy in an electric field, releasing it when needed to smooth out voltage variations in a circuit.
5. Can passive elements be used in combination to create more complex circuits?
Ans. Yes, passive elements like resistors, inductors, and capacitors can be combined in various ways to create filters, oscillators, and other complex circuits in electrical engineering.
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