CONTENTS: Line Coding | Manchester encoding

• What is line coding ?
• Types of line coding
• Properties of line coding
• Manchester encoding
• Manchester encoding advantages and disadvantages.
• Uses of line coding in digital communication

What is Line Coding?

“Line coding is a type of code which is used in transmitting data of any specific digital signal over a specific transmission line or path”.

The main purpose of this type of coding is to avoid overlapping & distortions of any signals (Ex- inter-symbol interference).

In Line coding, standard logic levels are also converted to a form which is more suitable for line transmission.

What are the properties of line coding?

Important features of Line Coding:

The following are the desirable properties of a line code:

• Self-synchronization i.e. timing or clock signal can be usually extracted from the code.
• Low probability of bit-error
• It should have a spectrum that is suitable for the channel
• The transmission bandwidth should be as small as possible
• Line codes must have error detection capability
• The code ought to be transparent

What are the types of Line Coding?

Different Types of Line Coding:

 Line Coding can be classified into ‘four’ important divisions; they are:

1. Unipolar Line Coding
2. Polar Line Coding
3. Bipolar Line Coding
4. Manchester Line Coding

Again, Unipolar has an important division, which is ‘NRZ’.

Polar has two important divisions; they are ‘NRZ’ & ‘RZ’.

Bipolar is divided into AMI.

Explain each of the Line Coding and their respective divisions:

• UNIPOLAR – In this type of line code method, the signal levels lie above the axis or below the axis.

Diagram:

In positive logic, unipolar signalling the binary 1 is represented by a high level and a binary 0 by a zero-voltage level. This type of signalling is also called on-off signalling.

NON return to zero (NRZ):

NRZ is a special type of Unipolar coding where the positive voltages denote bit 1 and the zero voltage defines bit 0. Here, the signal does not return to zero hence the name is NRZ.

POLAR

In a polar type of coding, the signal levels lie on the both sides of the axis.

Here, binary 1’s and 0’s are denoted by equal +ve and -ve level. E.g., binary 1 is +A volts and binary 0 is a -A volts.

Non return to zero (NRZ) – This NRZ is also kind of similar to the unipolar NRZ, but in case of Polar, NRZ is divided into two divisions i.e. NRZ-L & NRZ-I level.

In NRZ-L level, the bit values are determined by the voltage level. Here, binary 0 refers to logic-level low & bit 1 refers to logic-level high.

In NRZ-I level, when the logic refers to bit 1, two level transition takes place at the boundary & when the logic level refers to 0, no transition occurs at the boundary.

Return to zero (RZ)

– unlike NRZ, here the signal value returns to zero. Hence, to Solve some NRZ problems, RZ scheme is applied. RZ uses three values which are a. positive b. negative & c. zero.

A major drawback of RZ is it requires greater bandwidths. Also, since it uses three levels of voltages, this scheme is considered to be a bit complex.

• BIPOLAR – In this type of coding, three different levels of voltages exist; they are positive, negative & zero. In which, one of them lies at zero and the other voltage levels stay at positive and negative.

Diagram:

This coding is also called pseudo-ternary signalling or alternative mark inversion (AMI) signalling. In this case, binary 1’s are represented by alternatively positive or negative values. The binary 0 is represented by a zero level.

The term pseudo-ternary means three encoded signal levels (+A, -A and zero volt) are used to represent two level binary data 1 & 0.

Alternative Mark Inversion (AMI) – In this scheme, when the voltage is neutral, it refers to binary 0 and when the voltage is positive or negative the binary becomes 1.

Pseudo-ternary –  In this coding scheme, bit 1 refers to zero voltage & bit 0 refers to any of positive or negative voltage alternatively.

Manchester coding

– Here, in this type of coding, symbol 1 is characterized by transmit a +ve pulse (say +A volts) for one-half of the signal length followed by a -ve pulse (say -A volts) for the other half of the signal length.

Correspondingly, symbol ‘0’ is characterized by a -ve half-bit pulse following the +ve half-bit pulse in Manchester encoding techniques.

Diagram:

Manchester encoding is also called split-phase encoding.

Unlike NRZ or RZ, Manchester Encoding overcomes several issues in between the signals. In this Manchester encoding, there is no baseline wandering; neither there is any DC components as they are consisted with both of positive and negative voltage.

The only drawback of Manchester encoding scheme is its minimum bandwidth requirements.

What is Differential Encoding?

At what time serial-data is carrying through circuits along a communication channel a problem arises. The waveform is likely to be inverted i.e. data complementation takes place. This means 1 may become 0 or 0 may become 1. This may occur in a twisted pair communication channels if a line code like polar signalling is utilized.

To overcome this problem in polar signalling, differential encoding is often used.

In a differential encoder, the encoded differential data are generated by a modulo 2 addition using XOR gate. Thus

 e_n = d_n ⊕ e_n-1

In a differential encoding system, the decoded sequence remains same irrespective of the channel polarity.Let us consider the input sequence d_n = 1 1 0 1 0 0 1. The encoded sequence due to differential encoding will be e_{n =} 1 0 1 1 0 0 0 1.

What are the advantages and disadvantages of Unipolar Line Coding?

Advantages:

• Unipolar is the simplest type of technique.
• Always requires less bandwidth.
• The spectral line can be used here in unipolar RZ as clock

Disadvantages:

• No clock is present at unipolar NRZ.
• Signal droop occurs due to low frequency components.
• Unipolar RZ requires more bandwidth i.e. twice than unipolar NRX.

What are the advantages and disadvantages of Polar Line Coding?

Advantages:

• This technique is also a simple one.
• No low frequency components are present

Disadvantages:

• No presence of clock
• No checking of errors
• Polar RZ signal’s bandwidth is twice than the NRZ

What are the advantages of Bipolar Coding?

Advantages:

• No low frequency components.
• Single error detection cam be done.
• It demands lower bandwidth than both of Polar and Unipolar.

Disadvantages:

• No clock is present
• Provides less synchronization\\

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Image Credit: Iñigo Gonzalez from Guadalajara, Spain, Lamp @Ibiza (624601058), CC BY-SA 2.0

Points of Discussion

• Introduction to Maximum Power transfer Theorem
• Theory of Maximum Power Transfer Theorem
• Real World Applications of Maximum Power Transfer Theorem
• Steps to solving problems regarding Maximum Power Transfer Theorem
• Explanations of the theory
• Problems on Maximum Power Transfer Theory

Introduction to Maximum Power Transfer Theory

In the previous articles related to circuit analysis, we have come across several methods and theories regarding solving problems of a complex network. The maximum power transfer theorem is one of the efficient theories needed to analyze and study advanced circuits. It is one of the primary methods yet important one.

We will discuss the theories, the problem-solving steps, real-world applications, the explanation of the theory. A mathematical problem is solved at last for a better understanding.

Know about: Thevenin’s Theorem! Click Here!

Theory of Maximum Power Transfer Theorem

Maximum power Transfer Theory:

It states that a DC Circuit’s load resistance receives the maximum power if the magnitude of the load resistance is the same as the Thevenin’s equivalent resistance.

The theory is used to calculate the value of load resistance, which causes the maximum power transferred from the source to the load. The theorem is valid for both AC and DC circuits (Point to be noted: For AC circuits, the resistances are replaced by impedance).

Real world Applications of Maximum power transfer theorem

The maximum power transfer theorem is one of the efficient theorems. That is why there are several real-world applications for this theory. The communication sector is one of its fields. The theory is used for low strength signals. Also, for loud speakers to drain the maximum power from the amplifier.

Know about: Norton’s Theorem! Click Here!

Steps for solving problems regarding Maximum Power Transfer Theorem

In general, the below mentioned steps are followed for solving power transfer theory problems. There are other ways, but following these steps will lead to a more efficient path.

• Step 1: Find out the load resistance of the circuit. Now remove it from the circuit.
• Step 2: Calculate the Thevenin’s equivalent resistance of the circuit from the open circuited load resistance branch’s view point.
• Step 3: Now, as the theory says, the new load resistance will be the Thevenin’s equivalent resistance. This is the resistance that is responsible for Maximum power transfer.
• Step 4: The maximum power is derived then. It comes as follows.

P_MAX = V_TH² / 4R_TH

Know about: Superposition Theorem! Click Here!

Explanations of the Maximum Power Transfer Theory

To explain the theorem, let us take a complex network as below.

In this circuit, we have to calculate the value of load resistance for which the maximum power will be drained from the source to the load.

As we can see in the above images, the variable load resistance is attached to the DC circuit. In the second image, the Thevenin’s equivalent circuit is already represented (both the Thevenin’s equivalent circuit and Thevenin’s equivalent resistance).  

From the second image, we can say current (I) through the circuit is:

I = V_TH / (R_TH + R_L)

The power of the circuit is given by P = VI.

Or, P = I² R_L

Substituting the value of I from the Thevenin’s equivalent circuit,

P_L = [V_TH / (R_TH + R_L)]² R_L

We can observe that the value of P_L can be increased or preferably varied by changing R_L‘s value. According to the rule of calculus, the maximum power is achieved when the derivative of the power with respect to the load resistance is equal to zero.

 dP_L / dR_L = 0.

Differentiating P_L, we get,

dP_L / dR_L = {1 / [(R_TH + R_L)²]²} * [{(R_TH + R_L)² d/dR_L (V_TH² R_L)} – {(V_TH² R_L) d/dR_L (R_TH + R_L)²}]

Or, dP_L / dR_L = {1 / (R_TH + R_L)⁴} * [{(R_TH + R_L)² V_TH²} – {V_TH² R_L * 2 (R_TH + R_L)

Or, dP_L / dR_L = [V_TH² * (R_TH + R_L – 2R_L)] / [(R_TH + R_L)³]

Or, dP_L / dR_L = [V_TH² * (R_TH – R_L)] / [(R_TH + R_L)²]

For the maximum value, dP_L / dR_L = 0.

So, [V_TH² * (R_TH – R_L)] / [(R_TH + R_L)²] = 0

From which, we get,

(R_TH – R_L) = 0 or, R_TH = R_L

It is now proved that the maximum power will be drawn when the load resistance and internal equivalent resistance are the same.

So, the maximum power which can be drawn by any circuit,

P_MAX = [V_TH / (R_TH + R_L)]² R_L

Now, R_L = R_TH

OR, P_MAX = [V_TH / (R_TH + R_TH)]² R_TH

OR, P_MAX = [V_TH² / 4R_TH²] R_TH

OR, P_MAX= V_TH² / 4R_TH

This is the power drawn by the load. The power received by the load is the same power send by the load.

So, the total supplied power is:

P = 2 * V_TH² / 4R_TH

Or, P = V_TH² / 2R_TH

The efficiency of the power transfer is calculated as follows.

η = (P_MAX / P) * 100 % = 50 %

This theory aims to gain the maximum power from the source by making the load resistance equal to the source resistances. This idea has different and several applications in the field of communication technology, especially the signal analysis part. The source and load resistances are matched previously and decided before the circuit operation started to attain the maximum power transfer condition. The efficiency comes down to 50%, and the flow of power started from source to load.

Now, for electrical power transmission systems, where the load resistances have higher values than the sources, the condition of maximum power transfer is not achieved easily. Also, the efficiency of the transfer is just 50%, which has no good economical values. That is why the power transfer theorem is rarely used in the power transmission system.

Know about: KCL, KVL Theorems! Click Here!

Problems Related to Maximum Power Transfer Theorem

Observe the circuit carefully and calculate the resistance value to receive the maximum power. Apply maximum power transfer theorem to find out the amount of power transferred.

Solution: The problem is solved by following the given steps.

In the first step, the load resistance is disconnected from the circuit. After disconnecting the load, we mark it as AB. In the next step, we will calculate the Thevenin’s equivalent voltage.

So, V_AB = V_A – V_B

V_A comes as: V_A = V * R₂ / (R₁ + R₂)

Or, V_A = 60 * 40 / (30 + 40)

Or, V_A = 34.28 v

V_B comes as:

V_B = V * R₄ / (R₃ + R₄)

Or, V_B = 60 * 10 / (10 + 20)

Or, V_B = 20 v

So, V_AB = V_A – V_B

Or, V_AB = 34.28 – 20 = 14.28 v

Now, it is time to find out the Thevenin’s equivalent resistance for the circuit.

For that, we short circuit the voltage source and the resistance values are calculated through the open terminal of the load.

R_TH = R_AB = [{R₁R₂ / (R₁ + R₂)} + {R₃R₄ / (R₃ + R₄)}]

OR, R_TH = [{30 × 40 / (30 + 40)} + {20 × 10 / (20 + 10)}]

OR, R_TH = 23.809 ohms

Now the circuit is redrawn using the equivalent values. The maximum power transfer theorem says that to obtain the maximum power, the load resistance = Thevenin’s equivalent resistance. So as per the theory, load resistance R_L = R_TH = 23.809 ohms.

Formula for the maximum power transfer is P_MAX = V_TH² / 4 R_TH.

Or, P_MAX = 14.282 / (4 × 23.809)

Or, P_MAX = 203.9184 / 95.236

Or, P_MAX = 2.14 Watts

So, the maximum amount of transferred power is 2.14 watts.

Know about: Circuit Analysis! Click Here!

2. Observe the circuit carefully and calculate the resistance value to receive the maximum power. Apply maximum power transfer theorem to find out the amount of power transferred.

Solution: The problem is solved by following the given steps.

In the first step, the load resistance is disconnected from the circuit. After disconnecting the load, we mark it as AB. In the next step, we will calculate the Thevenin’s equivalent voltage. V_TH = V * R₂ / (R₁ + R₂)

V_TH = V * R₂ / (R₁ + R₂)

Or, V_TH = 100 * 20 / (20 +30)

Or, V_TH = 4 V

Now, it is time to find out the Thevenin’s equivalent resistance for the circuit. The resistances are in parallel with each other.

So, R_TH = R₁ || R₂

Or, R_TH = 20 || 30

Or, R_TH = 20 * 30 / (20 + 30)

Or, R_TH = 12 Ohms

Now the circuit is redrawn using the equivalent values. The maximum power transfer theorem says that to obtain the maximum power, the load resistance = Thevenin’s equivalent resistance. So as per the theory, load resistance R_L = R_TH = 12 ohms.

Formula for the maximum power transfer is P_MAX = V_TH² / 4 R_TH.

Or, P_MAX = 1002 / (4 × 12)

Or, P_MAX = 10000 / 48

Or, P_MAX = 208.33 Watts

So, the maximum amount of transferred power is 208.33 watts.

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Points of Discussion: Electrical Circuit Analysis

• Introduction to advanced Electrical Circuit Analysis
• Thevenin’s Theorem
• Norton’s Theorem
• Superposition Theorem

Introduction to Advanced Electrical Circuit Analysis

We came to know the primary circuit structure and some essential terminologies in the previous circuit analysis article. In the DC Circuit analysis, we have studied KCL, KVL. In this article, we are going to learn about some advanced methods for circuit analysis. They are – Superposition theorem, Thevenin’s theorem, Norton’s theorem. There are many more methods for circuit analysis like – maximum power transfer theory, Millman’s theory, etc.

We will learn about the theory of the methods, the detailed explanation of the theory and steps for solving circuit problems.

Basic Terminologies Related to Circuit Analysis : Click Here!

Advanced Electrical Circuit Analysis: Thevenin’s Theorem

Thevenin’s theorem (Helmholtz – Thevenin theorem) is one of the most crucial theories needed for analysing and studying complex circuits. It is one of the simplest methods to solve complex network problems. Also, it is one of the most widely used methods for circuit analysis.

Thevenin’s Theorem: It states that all complex networks can be replaced by a voltage source and a resistance in series connection.

In simpler words, if a circuit has energy sources like dependent or independent voltage sources, and has a complex structure of resistances, then the whole circuit is representable as a circuit consisting the equivalent voltage source, the load resistance, and the equivalent resistance of the circuit, all in series connection.

Steps for solving problems regarding Thevenin’s theorem

• Step 1: Remove the Load Resistance and redraw the circuit. (Note: The load resistance will be the referenced resistance through which you have to calculate the current).
• Step 2: Find out the open circuit voltage or Thevenin’s equivalent voltage for the circuit.
• Step 3: Now short circuit all the voltage sources, and open circuit all the current sources. Also, substitute all the elements with their equivalent resistances and redraw the circuit (Note: Keep the load resistance is unattached).
• Step 4: Find out the equivalent resistance of the circuit.
• Step 5: Draw a fresh circuit with a voltage source and two resistance in series with it. The magnitude of the voltage source will be the same as the derived equivalent Thevenin’s voltage. One of the resistances will be the pre-calculated equivalent resistance, and the other is the load resistance.
• Step 6: Calculate the current through the circuit. That is the final answer.

Explanation

To explain the theorem, let us take a complex circuit as below.

In this circuit, we have to find out the current I, through the resistance RL using the Thevenin’s theorem.

Now, to do so, first remove the load resistance and make that branch open circuited. Find out the open circuit voltage or Thevenin’s equivalent across that branch. The open circuited voltage comes as: V_OC = I R₃ = (V_S / R₁ + R₃) R₃

For calculation of the equivalent resistance, the voltage source is short circuited (deactivated). Now, find out the resistance. The equivalent resistance comes out as: R_TH = R₂ + [(R₁ R₃) / (R₁ + R₃)]

At the last step, make a circuit using the derived equivalent voltage and equivalent resistance. Connect the load resistance in series with the equivalent resistance. 

The current comes as: I_L = V_TH / (R_TH + R_L)

Electrical Circuit Analysis: Norton’s Theorem

Norton’s theorem (Mayer – Norton Theorem) is another crucial theory needed to analyses and study complex circuits. It is one of the simplest methods to solve complex network problems. Also, it is one of the most widely used methods for circuit analysis.

Norton’s Theorem: It states that all complex networks can be replaced by a current source and a resistance in parallel connection.

In simpler words, if a circuit has energy sources like dependent or independent current sources, and has a complex structure of resistances, then the whole circuit is representable as a circuit consisting the equivalent current source, the load resistance, and the equivalent resistance of the circuit, all in parallel connection.

Steps for solving problems regarding Norton’s theorem

• Step 1: Short circuit the Load Resistance and redraw the circuit. (Note: The load resistance will be the referenced resistance through which you have to calculate the current).
• Step 2: Find out the short circuit current or Norton’s current of the circuit.
• Step 3: Now, short circuit all the independent sources. Also, substitute all the elements with their equivalent resistances and redraw the circuit (Note: Make the load resistance unattached).
• Step 4: Find out the equivalent resistance of the circuit.
• Step 5: Draw a fresh circuit with a current source and two resistance in parallel with it. The magnitude of the current source will be the same as the derived equivalent short-circuit current. One of the resistances will be the pre-calculated equivalent resistance, and the other is the load resistance.
• Step 6: Calculate the current through the circuit. That is the final answer.

Explanation

To explain the theorem, let us take a complex circuit as below.

In this circuit, we have to find out the current I, through the resistance RL using Norton’s theorem.

To do so, first, remove the load resistance (R_L) and make that branch short circuited. The current in the closed loop is calculated first.

I = V_S / [ R₁ + {R₂R₃/ (R₂ + R₃)}]

The short circuit current comes as I_SC = I R₃ / (R₃ + R₂)

The voltage source is short circuited (deactivated) and the load resistance branch is short circuited for calculation of the equivalent resistance. Now, find out the resistance. The equivalent resistance comes out as: R_NT = R₂ + [(R₁ R₃) / (R₁ + R₃)]

At the last step, make a circuit using the derived equivalent current source and equivalent resistance. Connect the load resistance in parallel with the equivalent resistance and the current source in parallel with them. 

The current comes as: I_L = I_SC R_NT / (R_NT + R_L)

Electrical Circuit Analysis: Superposition Theorem

Superposition theorem is another crucial theory needed for analysing and studying of complex circuits. It is another easy method to solve complex network problems. Also, it is one of the most widely used methods for circuit analysis. Superposition theory is only applicable for linear circuits and circuits which obey Ohm’s law.

Superposition Theorem: It states that for all active, linear circuits, which have multiple sources, the response across any circuit element, is the aggregate sum of the responses obtained from each source considered separately and every source are substituted by their internal resistances.

In a more general way, the theorem states that the aggregate current in each branch can be expressed as the sum of all currents produced for a linear network. At the same time, all the source acted separately, and their internal resistances substitute independent sources.

Steps for solving problems regarding superposition theorem

• Step 1: Consider one independent source at a time and deactivate (short-circuit) all the other sources.
• Step 2:  Replace that other source with the equivalence of the resistors of the circuits. (Note: By default, if the resistance is not given, make it short-circuit).
• Step 3: Now, short circuit all the other (leave the selected source) voltage source and open circuit all the other current source. 
• Step 4: Find the current for every branch of the circuit.
• Step 5: Now choose another voltage source and follow step 1-4. Please do it for every independent source.
• Step 6: At last, calculate the current for each branch by superposition theorem (addition). To do so, add up currents of the same branch calculated for different voltage sources. Add the direction of the currents wise (if the same direction – add up, else minus).

Explanation

To explain the method, let us take a complex circuit as below.

In this circuit, we have to find out the current through each branch. The circuit has two voltage sources.

At first, we choose the V₁ source. So, we short circuit (as the source’s internal resistance is not given) the other voltage source – V₂.

Now, calculate all the current for every branch. Let the current through the branches are – I₁`, I<sub>2</sub>`, I₃`. They are represented as follow.

I₁` = V₁ / [ R₁ + {R₂R₃/ (R₂ + R₃)}]

I₂` = I<sub>1</sub>` R₃ / (R₃ + R₂)

Now, I₃` = I<sub>1</sub>` – I₂`

The V₂ voltage source is activated in the next step while the V₁ source is deactivated or short circuited (internal resistance is not given).

As the previous step, here we need to calculate the current for every branch again. The current through the branches comes as follow.

I₂“ = V₂ / [ R₂ + {R₁R₃/ (R₁ + R₃)}]

I₁“ = I₂“ R₃ / (R₃ + R₁)

Now, I₃“ = I₂“ – I₁“

All the source calculation is now covered. Now, we have to apply superposition theorem and find out the net currents for the branches. The direction rule is considered while calculating. The I₁, I₂, I₃ magnitudes are given below.

I₃ = I₃` + I₃“

I₂ = I₂` – I₂“

I₁ = I₁` – I₁“

For mathematical problems, check out the next article.

Points of Discussions: AC Circuit Analysis

• Introduction to Advanced AC Circuit Analysis
• RC Series Circuit
  • Circuit Diagram
  • Phasor Diagram
  • Power of the circuit
• RL Series Circuit
  • Circuit Diagram
  • Phasor Diagram
  • Power of the circuit
• LC series Circuit
  • Circuit Diagram
  • Resonance in series LC Circuit

Introduction to Advanced AC Circuit Analysis

In the previous article of the AC circuit, we have discussed some of the basic ac circuit analysis. We have studied about the circuit, the phasor diagrams, power calculations, and some essential terminologies. In this article, we will learn some advanced AC circuit analysis like – RC Series circuit, RL series circuit, RLC series circuit, etc. These advanced circuits are essential and have more applications in electrical analysis. All of these circuits can be said another level of primary ac circuit as the more complex circuit can be built using these. Please check out the introductory circuit article before studying this advanced ac circuit analysis.

Basic AC Circuit Analysis: Read Here!

RC Series Circuit

If a pure resistor is placed in a series with a pure capacitor in an AC circuit, then the ac circuit will be called RC AC Series Circuit. An ac voltage source produces sinusoidal voltages and the current passes through the resistor and the capacitor of the circuit.

• Circuit diagram of RC series circuit

VR gives the voltage across the resistance, and – VC gives the voltage across the capacitor. The current through the circuit is I. R is the resistance and C is the capacitance value. XC denotes the capacitive reactance of the capacitor.

• Phasor diagram of RC series circuit

The process to draw the phasor diagram of RC Circuit.

The phasor diagram is an essential analytical tool which helps to study the behaviour of the circuit. Let us learn the steps to draw the phasor.

Step 1. Find out the r.m.s value of the current. Mark that as the reference vector.

Step 2. As we know that for a purely resistive circuit, voltage and current remains in the same phase, here as well voltage drop across the resistor stays in phase with the current value. It is given as V = IR.

Step 3. Now for the capacitive circuit, we know that voltage lags by 90 degrees and current leads. That is why voltage drop across the capacitor in this circuit, stays 90 degrees behind than the current vector.

Step 4. The applied voltage thus comes as the vector sum of the voltage drops of capacitor and resistances. So, it can be written as:

V² = VR² + V_C²

Or, V² = (I_R)² + (IX_C)²

Or, V = I √ (R² + X_C²)

Or, I = V / √ (R² + X_C²)

Or, I = V / Z

Z is the aggregate impedance of the RC circuit. The following equation represents the mathematical form.

Z = √ (R² + X_C²)

Now from the phasor diagram, we can observe there is an angle as – ϕ.

So, tan ϕ will be equal to IX_C / I_R.

So, ϕ = tan^-1 (IX_C / I_R)

This angle ϕ is known as phase angle.

• RC Series Circuit Power calculation

The power of the circuit is calculated by P = VI formula. Here we will calculate the instantaneous value of power.

So, P = VI

Or, P = (V_m Sinωt) * [I_m Sin (ωt+ ϕ)]

Or, P = (V_m I_m / 2) [ 2Sinωt * Sin (ωt+ ϕ)]

Or, P = (V_m I_m / 2) [ cos {ωt – (ωt+ ϕ)} – cos {ωt – (ωt+ ϕ)}]

Or, P = (V_m I_m / 2) [ cos (- ϕ) – cos (2ωt+ ϕ)]

Or, P = (V_m I_m / 2) [ cos (ϕ) – cos (2ωt+ ϕ)]

Or, P = (V_m I_m / 2) cos (ϕ) – (V_m I_m / 2) cos (2ωt+ ϕ)

We can observe that the power equation has two sections. One is a constant part another is the variable section. The mean of the variable part comes to be zero over a full cycle.

So, the average power for an RC series circuit, over a full cycle is given as :

P = (V_m I_m / 2) cos (ϕ)

Or, P = (V_m / √2) * (I_m / √2) * cos (ϕ)

Or, P = VI cos (ϕ)

Here, V and I are considered as RMS values.

The power factor of RC Series Circuit

The RC series circuit’s power factor is given by the ratio of active power to the apparent power. It is represented by cosϕ and expressed as below given expression.

cos ϕ = P / S = R / √ (R² + X_C²)

RL Series Circuit

If a pure resistor is placed in a series with a pure inductor in an AC circuit, then the ac circuit will be called RL AC Series Circuit. An ac voltage source produces sinusoidal voltages and the current passes through the resistor and the inductor of the circuit.

• Circuit Diagram of RL circuit

VR gives the voltage across the resistance, and – VL gives the voltage across the inductor. The current through the circuit is I. R is the resistance and L is the inductance value. XL denotes the inductive reactance of the inductor.

• Phasor Diagram of RL circuit

The process to draw the phasor diagram of RL Circuit.

Step 1. Find out the r.m.s value of the current. Mark that as the reference vector.

Step 2. As we know, for a purely resistive circuit, voltage and current remain in the same phase, here as well voltage drop across the resistor stays in phase with the current value. It is given as V = IR.

Step 3. Now for the inductive circuit, we know that voltage leads by 90 degrees and the current lags. That is why voltage drop across the inductor in this circuit, stays 90 degrees ahead than the current vector.

Step 4. The applied voltage comes as the vector sum of the voltage drops of inductor and resistances. So, it can be written as:

V² = V_R² + V_L²

Or, V² = (I_R)² + (IX_L)²

Or, V = I √ (R² + X_L²)

Or, I = V / √ (R² + X_L²)

Or, I = V / Z

Z is the aggregate impedance of the RL circuit. The following equation represents the mathematical form.

Z = √ (R² + X_L²)

Now from the phasor diagram, we can observe there is an angle as – ϕ.

So, tan ϕ will be equal to IX_L / I_R.

So, ϕ = tan^-1 (X_L / R)

This angle ϕ is known as phase angle.

• RL Series Circuit Power calculation

The power of the circuit is calculated by P = VI formula. Here we will calculate the instantaneous value of power.

So, P = VI

Or, P = (V_m Sinωt) * [I_m Sin (ωt- ϕ)]

Or, P = (V_m I_m / 2) [ 2Sinωt * Sin (ωt – ϕ)]

Or, P = (V_m I_m / 2) [ cos {ωt – (ωt – ϕ)} – cos {ωt – (ωt – ϕ)}]

Or, P = (V_m I_m / 2) [ cos (ϕ) – cos (2ωt – ϕ)]

Or, P = (V_m I_m / 2) cos (ϕ) – (V_m I_m / 2) cos (2ωt – ϕ)

We can observe that the power equation has two sections. One is a constant part another is the variable section. The mean of the variable part comes to be zero over a full cycle.

So, the average power for an RL series circuit, over a full cycle is given as :

P = (V_m I_m / 2) cos (ϕ)

Or, P = (Vm / √2) * (Im / √2) * cos (ϕ)

Or, P = VI cos (ϕ)

Here, V and I are considered as RMS values.

LC Series Circuit

An LC series circuit is an AC circuit consisting of inductor and capacitor, placed in a series connection. An LC circuit has several applications. It is also known as a resonant circuit, tuned circuit, LC filters. As there is no resistor in the circuit, ideally this circuit doesn’t suffer any losses.  

LC Circuit as Tuned Circuit: The flow of current means flows of charges. Now in an LC circuit, charges keep flowing behind and ahead of the capacitor plates and through the inductor. Thus, a type of oscillation gets created. That is why these circuits are known as tuned or tank circuit. However, the internal resistance of the circuit prevents the oscillation in real.

• Circuit diagram of LC Series Circuit

In a series circuit, the current value is the same across the whole circuit. So we can write that, I = I_L = I_C.

The voltage can be written as V = V_C + V_L.

• Resonance in series LC Circuit

Resonance is refereed to as a particular condition of this LC circuit. If the frequency of the current increases, the value of inductive reactance also gets increased, and the value of capacitive reactance gets decreased.

X_L = ωL = 2πfL

X_C = 1 / ωC = 2πfC

At the resonance condition, the magnitude of capacitive reactance and inductive reactance is equal. So, we can write that XL = XC

Or, ωL = 1 / ωC

Or, ω²C = 1 / LC

Or, ω = ω₀ = 1 / √LC

Or, 2πf = ω₀ = 1 / √LC

Or, f₀ = ω₀ / 2π = (1/2π) (1 / √LC)

f₀ is the resonant frequency.

• The impedance of the circuit

Z = Z_L + Z_C

Or, Z = jωL + 1 / jωC

Or, Z = jωL + j / j2ωC

Or, Z = jωL – j / ωC

Topic of Discussion: Digital Communication

• Introduction to Digital Communication
• It’s advantages over Analog communication
• What is Encoding
• Types of Encoding
• Companding in Encoding
• Sampling Theorem

To know about encoding and other features, first, we have to recall what digital communication is and some of its advantages.

What is Digital Communication?

Definition & the advantages of Digital communication:

“It is the type of communication system, in which the signals which are used to transmit data or information, should be discrete in time & amplitude. They are also called digital signals“

Some of the important advantages are:

• Digital communications provide increased immunity to noise and external interference.
• It offers better flexibility and compatibility.
• Digital communication gives improved reliability due to channel coding.
• Digital Communication system is comparatively simpler and cheaper than an analog communication system.
• Computers can be used directly for digital signal processing.
• It makes communication more secured using data encryption.
• Wideband channels are available for digital communications.

What is Encoding?

Introduction to encoding in digital communication:

“Encoding is a special type of process in which various patterns or voltages or current levels are used to represent 1s and 0s of the digital signals on a particular transmission link or channel.“

What are the different types of encoding?

There are four types of encoding; they are-

• Unipolar
• Polar
• Bipolar
• Manchester

What is Companding?

Why is Companding needed in encoding?

Quantization is of two types

• Uniform Quantization,
• Non-Uniform Quantization.

Non-Uniform quantization is achieved through companding. This is a process in which compression of the input signal is done in the transmitter, whereas the expansion of the signal is done at the receiver. The combination of compressing and expanding is companding.

The process of Companding:

In a linear or uniform quantization, the small amplitude signals would have a poor SNR than the large-amplitude signals. This is a drawback of linear quantization. To remove this problem, non-uniform quantization is utilized in which the step size differs with the amplitude of the i/p. The step size variation is achieved by distorting the input signal before the quantization process. This process of distorting the input signal before quantization is known as compression, in which the signal is amplified at low signal level and attenuated at high signal level.

After compression, uniform quantization is applied. Here the signal is companding, which is to make the overall transmission distortion less.

Input Output characteristics of a Compander:

What is Aliasing?

Define the Aliasing Effect:

• Aliasing is an important term in encoding & digital communication itself.
• If signal is sampled at a rate lesser than the Nyquist Rate, the side band overlap, producing an interference-effect. This is called the Aliasing Effect.
• If aliasing takes place, it is not possible to recover the original analog signal.

Anti-Aliasing Filter:

To remove the problem of the aliasing from the signals, a special type of filter is used, which is known as the Anti- Aliasing Filter.

An anti-aliasing filter is usually at the input of a PAM generator to avoid the effect of aliasing. PAM signal is generated by sampling the input analog signal in a sampler circuit.

The sampling is thru in accord with the Sampling Theorem , i.e., the sampling frequency fs is kept equal to or higher than twice the maximum frequency W present in the input analog signal. If, however, fs<2W, then aliasing occurs, and recovery of the original analog signal will not be possible. Since fs is usually kept unchanged, the input analog signal is passed through a low pass filter before sampling to band limit the analog signal in conformity with the sampling theorem.

What is Sampling?

State Sampling Theorem:

The mathematical basis of the sampling process has been laid by the Nyquist sampling theorem. It also gives an idea about the recovery of the original signal completely from its samples. The statement of the sampling theorem is thus given in two parts below’;

• A band-limiting signal of finite energy that has no freq. rage of W Hz is usualy designated by agreeing the value of the signals at that time parted by ½ W sec.
• A band-limit signal of finite energy that has no freq. components outside the W Hz might be totally reformed from the information of its sample data rated @2W sample/sec.

The sampling rate 2W/sec is entitled as the “Nyquist Rate.” in the Sampling Theorem explanation.

The reciprocal 1/2W is entitled “Nyquist Interval.”

How does sampling theorem work in encoding?

In sampling theorem, the received message (baseband) signals are sampled with a typical combination of rectangular-shaped or square-shaped pulses. For the accurate reconstruction of the message signal in the receiving end, the sampling rate has to be more than double of maximum freq. component specified by ‘W’. In a practical case, an anti-aliasing filter (lpf) is utilized at the sampler device to discard the frequencies band those are greater than the W. Hence, the various utilization of sampling allows the minimization of the incessantly changeable message signal (of some determinate period) to some degree of discrete quantity per sec.

Explain the Encoding Process:

In merging the sampling theorem and quantization procedures, the order of a continuous message (baseband) signal converts limited to discrete values but not in the procedure appropriate for the transmission over a long-distanced radio telecommunication channel. To utilize the benefits of sampling and quantization to create the communicated signal stronger to noise, interference, and other channel dreadful conditions. The main requirement is an encoding process to interpret the discrete set of sample values to a proper form of signal. This distinct procedure in a code is called a code element or symbol. Specific prearrangement of symbols employed in coding to signify a single value of the distinctive set is entitled as ‘codeword’ or ‘character’.

In binary encryption, the symbol is in two distinctive values, such as a -ve pulse or a +ve pulse. The binary codes are, as a matter of course, signified as 0 and 1 combination only.

Actually, a binary code is favored over other codes such as ternary cod for the following grounds.

• The more significant advantages over the effects of noise in a transmission channel could be obtained using a binary code because of its sustainability with higher noises.
• Another reason is the binary code is comparatively simplified to produce and to regenerate again.

What is A-law and μ-law in companding?

There are two types of compression laws in use. These are, namely, ? law & A-law companding.

? law companding is used in various country A-law companding recommended by CCITT is used in asian and European countries.

? law is defined by the expression-

The A-law compression characteristic is finished up of a linear segment for low-level input and a log-segment for higher level input. The special case A=1 corresponds to uniform quantization. A applied value for A is 87.561.

A-law companding is inferior to ? law in terms of small-signal quality, i.e., ideal channel noise.

For more related topics and MCQ click here

Cover Image Credit – Santeri Viinamäki, MCB Circuit breakers for DIN rail, CC BY-SA 4.0

Points of discussion : Circuit Analysis

• Introduction to circuit analysis
• Ideal Circuit elements
• Realistic circuit elements
• Ideal Energy Sources
• Real-World Energy Sources
• Important terminologies related to Circuit analysis

Introduction to Circuit Analysis

Circuit analysis is one of the primary and essential modules for Electrical and Electronics Engineering. Before exploring out the concepts and theories of circuit analysis, let us know what a circuit is.

A circuit can be defined as a closed or open loop consists of electrical and electronic components and have interconnection between them. Circuit analysis is the method to determine the necessary current or voltage value at any point of the circuit by studying and analysing the circuit. There are numerous different methods for circuit analysis and used as per suitable conditions.

What is a DC Circuit? Learn About KCL & KVLs! Click Here!

Ideal Circuit Elements

An ideal circuit can be defined as a circuit without any losses, thus the appearance of 100% input power at the output side. An ideal circuit consists of three ideal elements. They are – Resistances, capacitor, Inductor.

• Resistors: Resistors are passive electrical components used to resist the flow of electrons in a circuit. The voltage across the resistor is expressed by a famous law, known as Ohm’s law. It states that “the voltages are directly proportional to the currents”. If V and I respectively denote the voltage value and current, then

V ∝ I

Or, V = IR

Here R represents the resistance or resistor value. The unit is given by ohm(Ω).  The following image

represents the resistor –

The following mathematical expression gives the power stored by a resistor.

P = VI

Or, P = (IR) I

Or, P = I²R

Or, P = V² / R

• Capacitor: A typical capacitor is a passive electrical equipment which stores electrical energy inside an electric field. It is a two-terminal device. Capacitance is known as the effect of the capacitor. Capacitance has a unit – Farad(F). The capacitor is represented in the circuit by the following image.

The relation between charges and capacitance is given by Q = CV, where C is the capacitance value, Q is the Charge, V is the applied voltage.

The current relationship can be derived from the above equation. Let us differentiate both side with respect to time.

dQ/dt = C dV/dt; C is a constant value

Or, I = C dV/dt; as I = dQ/dt.

Power stored in a capacitor can be described written as

P = VI

Or, P = V C dV/dt

Now, the energy is given as U = ∫ p dt

Or, U = ∫ V C (dV/dt) dt

Or, U = C ∫ V dV

If we assume that the capacitor was discharged at the beginning of the circuit, then the power comes as U = ½ CV².

• Inductor: Inductor is another passive device present in an ideal circuit. It holds energies in a magnetic field. The unit of inductance is given by Henry(H). The relation between voltage and inductance is given below.

V = L dI/dt

The reserved energies are returned back to the circuitry in current form. The following image represents the inductor in the circuit.

The power of an inductor is given as P =VI.

Or, P = I * L (dI/dt)

Again, the energy U = ∫ p dt

Or, U = ∫ I * L (dI/dt) dt

Or, U = L ∫ I dI

The energy comes as U = ½ LI².

Learn about different types of AC Circuits! Click here!

Realistic Circuit Elements

Ideal circuit components are for ideal circuits. They are not applicable in real circuits. However, the main characteristics remain the same for the elements. Elements suffer some loss, have some tolerance values and some abstractions while using it.

The working principles and equations get changed in real domains. Also, some other factors get added during operations. For example, capacitors work differently in high-frequency domains; resistors generate a magnetic field during operations.

• Resistors: The real-world resistors should be made to obey Ohm’s law as close as they can. The resistance offered by a resistor depends upon the material and shape of the resistor.

A real resistor maybe gets destroyed or burned out due to heat generated by itself. There is a certain tolerance level mentioned for every resistor via the color codes.

• Capacitors: The realistic capacitors should be made to obey the capacitor’s equation as close as possible. Two conducting surfaces are needed to build a capacitor. They are placed together, and air or any material is filled in between them. The capacitor value is dependent on the surface area of the conductor and the distance between them and upon the permittivity of the inside material. There are various categories of capacitors in the market. Some of them are – Electrolytic Capacitors, Tantalum Capacitors, etc.

Capacitors are connected with wire at their terminals. That causes resistance and a small amount of impedance. An increase in voltage across the capacitors sometimes damages the insulative materials between the plates.

• Inductors: The realistic or real-world inductors should be made to obey the inductor equation as close as possible. Inductors are choke of coils. They induce magnetic fields to store electrical-energies.

Inductors are made using the winding wires in a coil-like structure: the more the winding, the stronger the magnetic field. Placing a magnetic material inside the coil would increase the magnetic effect. Now, as these wires are wounded around the material, this causes the generation of resistance. Also, it is needed to be large enough to accumulate the magnetic field. That sometimes causes problems.

Ideal Energy Sources

An ideal circuit needs an ideal source of energy. There are two types of ideal energy sources. They are – ideal voltage source and ideal current source.

Ideal Voltage Source: Ideal voltage sources supply a constant amount of voltage for every instant of time. Voltage is constant throughout the source. In reality, there is no ideal source for circuits. It is an assumption to simplify the circuit analysis. The below image represents an ideal voltage source.

Ideal Current Source: Ideal current sources supply currents independent of the variation of voltage in the circuit. An ideal current source is an approximation that does not take place in reality but can be achieved. The below picture represents the ideal current source in a circuit.

Real energy sources for circuits

Real electrical or electronic circuits need natural sources of energy. There are some differences between ideal and real-world energy sources though the main principle of supplying the energy to the circuit remains the same. Real-world energy sources have several types. Some are even dependent upon other sources. Like – Voltage controlled current source, Current controlled current source, etc. We will discuss them briefly in this circuit analysis article.

• Voltage Sources: Real voltage sources come up with an internal resistance, which is consider it to be in series with the voltage source. No matter how negligible the resistance is, it affects the V-I characteristic of the circuit. The voltage source can be of two types –

1. Independent Voltage Source
2. Dependent Voltage Source

• Voltage Controlled Voltage Source
• Current Controlled Voltage Source.

• Voltage Controlled Voltage Source: If any other voltage source is controlled by any kind of voltage source, it is known as Voltage controlled voltage source. V0 = AVc gives voltage output; Here, A represents the gain, and Vc is the controlling voltage.
• Current Controlled Voltage Source: If any other voltage source is controlled by different current source in the circuit, it is known as a current-controlled current source. V0 = AIc gives the output; Here, A represents the gain, and Ic controls the current.

• Current Sources: Real current sources come up with internal resistance. The resistance may be negligible but has its effect throughout the circuit. Current Source can be of two kind.

1. Dependent Source
2. Independent Source

Independent Source: These current sources have no dependency upon any other energy sources of the circuit. It provides a small resistance, which changes the V-I characteristic plot.

Dependent Current Sources: These current sources are dependent upon any other energy sources present in the circuits. They can be classified into two categories

• Current Controlled Current Source
• Voltage Controlled Current Source.

• Current Controlled Current Source: If any other current source controls any current source, then it is known as a current-controlled current source. I0 = AIc gives the output; Here, A represents the gain, and Ic is the controlling current.
• Voltage Controlled Current Source: If any current source is controlled by any other current source in the circuit, it is known as a voltage-controlled current source. I0 = AVc gives the output; Here, A represents the gain, and Vc controls voltage.

Important terminologies related to circuit analysis

Circuit analysis is a vast field which includes years of researches by scientist and inventor. It has grown up with lots of theories and terminologies. Let us discuss some of the primaries yet important circuit theory terminologies, which will be required throughout the sections.

• Elements / Components: Any electrical device present and connected in the circuit is known as Elements or components of the circuit.
• Node / Junction: Nodes are the junctions where two or more elements get connected.
• Reference Node: Reference nodes are arbitrarily selected nodes as a reference point to start the calculation and analyse the circuit.
• Branches: Branches are the parts of the circuit that connects the nodes. A branch consists of an element like a resistor, capacitors, etc. The number of branches gives us the number of elements in the circuitry.
• Loop: Loop:  Loops are enclosed paths whose start point and finishing point are same.
• Mesh: Meshes are the minimal loop within an electrical circuit without any overlapping.
• Circuit: The word ‘circuit’ is originated from the word ‘Circle’. A typical circuit is referred to as the interconnected assemblies of different electrical and electronic equipment.

• Port: Port is referred to as the two terminals where the same current flows as the other.
• Ground: Ground is considered as one of the reference nodes and has some characteristics. It is a physical connection that connects to the earth’s surface. It is vital for the safety of the circuit. The below image represents the representation of the ground in a circuit.