In electronic and electrical circuits, we have a responsibility to provide the components required for the circuit's operation. For this purpose, we utilized voltage and current energy sources. The dynamic circuit components are the energy sources since they can supply power or gain power in the circuit. We will discuss the different kinds of voltage sources and what they are in this article.
In this article, we will be going through What is Voltage Source, We will go through types of Voltage Sources that are Independent and Dependent Voltage Sources, Further Independent Sources are Categorized as Direct and Alternating Sources and on the basis of Internal Resistance they are Categorized in Ideal Voltage Source and Practical Voltage Source, Dependent Sources are Categorized as Voltage Controlled Voltage Sources (VCVS) and Current Controlled Voltage Source (CCVS), At last, we will conclude our Article with Some FAQs.
Voltage Source
An element of a circuit that serves to create a potential difference between two points in a circuit is called a voltage source. It is essentially an active circuit element that provides the circuit with the potential energy required to pass electrical current through it. A voltage source is a device that is connected to a two-terminal circuit and maintains a constant pressure to allow electrons (electric current) to move through the circuit. Cells, batteries, generators, and other devices that can generate voltage are common practical examples of voltage sources.
Types of Voltage Sources
Voltage sources are typically divided into two categories, They are:
- Independent Voltage Sources.
- Dependent Voltage Sources.
Independent Voltage Sources
An independent voltage source is again divided into two types, They are.
- Direct Voltage Sources
- Alternating Voltage Sources
Direct Voltage Sources
Devices or components in electrical circuits that produce a constant voltage output and maintain a constant potential difference across their terminals are referred to as direct voltage sources or direct current (DC) sources. In contrast to Alternating Current (AC) sources, which ceaselessly differ in extremity and greatness, DC sources give a steady and unidirectional progression of electric charge. Some important aspects of direct voltage sources are as follows:
Output at a Constant Voltage
- Characteristic: The essential element of an immediate voltage source is its capacity to supply a consistent voltage level over the long run.
- Stability: This security is significant in applications where a steady electrical potential is required.
Unidirectional Current Flow
- Flow of Charge: Electric charge (current) flows in a single direction in a direct voltage source. The negative terminal is replaced by the positive terminal by electrons.
- Straightforward Circuitry: This effortlessness of the current stream makes DC sources appropriate for direct circuit plans.
Independent Voltage SourcesAlternating Voltage Sources
Alternating Voltage Sources, regularly referred to as Alternating Current (AC) sources, are gadgets or components in electrical circuits that produce a consistently changing voltage yield. AC sources, in contrast to Direct Current (DC) sources, produce a sinusoidal voltage that changes over time. Alternating Voltage Sources' most important features are as follows:
Sinusoidal Voltage Variation
- Characteristic: The characterizing element of AC sources is the sinusoidal variety of voltage over the long run. This indicates that the voltage fluctuates between positive and negative values regularly.
- Representation: The voltage waveform is frequently represented mathematically by a sine or cosine function.
Polarity Reversal
- Polarity Change: The electric current in AC sources occasionally reverses direction. Electrons move to and froth, making a substituting stream.
- Frequency: Hertz (Hz) is the unit of measurement for the rate at which the polarity shifts.
Common Types of Alternating Voltage Sources
- Generators: Electromagnetic induction results in the production of alternating voltage by AC generators, such as those found in power plants.
- Power Outlets: AC voltage is typically provided by household power outlets. AC at 60 Hz is the norm in many places.
Dependent Voltage Sources
A dependent voltage source is a type of voltage source whose output voltage is dependent on any other voltage or current in the circuit. Controlled voltage sources are two other names for dependent voltage sources.
There are two types of controlled voltage sources:
- Voltage Controlled Voltage Source (VCVS)
- Current Controlled Voltage Source (CCVS)
A voltage-dependent voltage source (VDVS) or voltage-controlled voltage source (VCVS) is a voltage source whose output voltage is dependent on the voltage in any other part of the electric circuit. In contrast, a voltage source is referred to as a current-dependent voltage source (CDVS) or a current-controlled voltage source (CCVS) when its output voltage is dependent on the current in any other part of the circuit.
.png)
Dependent Voltage Sources The figure depicts a diamond-shaped symbol with polarity marks that are used to represent dependent voltage sources. The reliant sources are utilized to show electronic circuits.
Voltage Controlled Voltage Source (VCVS)
An active device with two terminals that generates an output voltage proportional to an input voltage is known as a voltage-controlled voltage source (VCVS). Simply put, the input voltage controls the output voltage. The connection between the info and result voltages is regularly communicated by a voltage gain, meant by a boundary image, for example, "A" or "Av." The output voltage (V out) can be represented mathematically as:
VOUT = A x Vin
- Gain in voltage (A): The amplification factor in a VCVS is determined by the voltage gain (A). Higher upsides of An outcome in the more prominent intensification of the info voltage, making VCVS ideal for applications where signal strength needs an upgrade.
- Implementation of Op-Amps: VCVS qualities are many times mimicked or accomplished utilizing functional speakers (operation amps). When set up right, op-amps can behave like a good VCVS with low input impedance and high output impedance.
- Linear Relationship: If it operates within its linear range, VCVS has a linear relationship between the input and output voltages. For accurate signal processing and reproduction, linearity is essential.
Current Controlled Voltage Source (CCVS)
A device that produces an output voltage proportional to an input current is called a Current Controlled Voltage Source (CCVS), also known as a voltage-controlled voltage source. A transconductance parameter, often denoted by the symbols "Gm" or "A," describes the relationship between the input current and the output voltage in this instance. Mathematically, the output voltage (V out) can be expressed as:
VOUT = Gm x Iin
- Transconductance (Gm): The transconductance (Gm) in a CCVS addresses the connection between the information current and the resulting voltage. It is the increase factor for the CCVS. A higher transconductance brings about a bigger change in yield voltage for a given change in input current.
- Amplifiers for Operation: Operational amplifiers can be used to mimic CCVS characteristics, which are similar to those of VCVS. A CCVS with particular transconductance characteristics can be produced with the right op-amp configurations.
- Ideal CCVS: Ideally, a CCVS would have zero output impedance and infinite input impedance, ensuring that the connected circuit has no effect on the input current or voltage, nor does the load.
Types of Independent Voltage Sources
Depending on their internal resistance, independent voltage sources can also be divided into the following two categories:
- Ideal Voltage Source
- Practical Voltage Source
Ideal Voltage Source
An ideal voltage source can supply a constant voltage to the circuit it is connected to and has no internal resistance (or impedance). Since an ideal voltage source has zero Internal Resistance, the voltage across its terminal is equivalent to the source voltage (or emf). This is because there is no voltage drop due to internal resistance when the current is drawn from an ideal voltage source. The fact that the ideal voltage source is 100 percent efficient—that is, there is no power loss in its internal circuit—is another important feature.
Ideal Voltage Source Practical Voltage Source
A voltage source that has a limited inside obstruction and whose terminal voltage drops with the expansion in current drawn from it, is known as a pragmatic (or genuine) voltage source. In below Figure depicts a practical voltage source's circuit symbol and current/voltage graph.
Practical Voltage SourceIt is evident from the real voltage source's current/voltage graph that the voltage across its terminals decreases when the source draws more current. It is because the expanded current builds the voltage drop across the inner opposition. All of the voltage sources that we use in actual, working circuits have a certain amount of internal resistance.
Characteristics of Voltage Sources
Given Below are the following Characteristics of Voltage Sources
- Electromotive Force (EMF): The maximum potential difference that a source can provide is represented by the voltage it produces, which is frequently referred to as EMF.
- Open Circuit Voltage: The voltage that exists when no current is drawn across the terminals of a voltage source.
- Internal Resistance: The ability of a voltage source to deliver current to a load may be affected by internal resistance.
Applications of Voltage Sources
Given Below are the following Applications of Voltage Sources
- Power Electronic Devices: Batteries and power supplies act as voltage hotspots for gadgets going from cell phones to workstations.
- Machines used in industry: In industrial settings, voltage sources power motors, control systems, and other components.
- Systems for Renewable Energy: Sunlight-based chargers and wind turbines produce voltage to bridle environmentally friendly power.
- Communication Techniques: Voltage sources power speakers and transmitters in correspondence frameworks.
- Medical supplies: Diagnostic and therapeutic devices must be powered by voltage sources in the healthcare industry.
Conclusion
In conclusion, We have Gone through in brief About Voltage Source and Seen its Different Types which are Independent and Dependent Voltage Sources. The Voltage Source is the Component Which Provides Energy Supply Required for the operation of the Circuit. The Voltage Sources can be Further Classified as Dc, Ac and other Types based on there Requirements. The most Common examples of Voltage Sources are Battery, Cell, Generator, Etc.
Similar Reads
Electrical Engineering Engineering has emerged as one of the most popular career option for majority of population. Electrical Engineering is one such branch of engineering that has emerged as a popular choice. Electrical Engineering is one of the more recent branches of engineering which is about design, study and applic
8 min read
Fundamentals & Circuit Basics
Electrical EngineeringEngineering has emerged as one of the most popular career option for majority of population. Electrical Engineering is one such branch of engineering that has emerged as a popular choice. Electrical Engineering is one of the more recent branches of engineering which is about design, study and applic
8 min read
Getting Started with Electrical CircuitsElectrical Circuits are an integral part of engineering and are used in various domains. Their usage expands from circuits in energy transformations to circuits used in designing industrial equipment. Anyone who wants to pursue a career in engineering must be aware of the basics of these circuits us
11 min read
Ohm's Law - Definition, Formula, Applications, LimitationsAccording to Ohm's law, the voltage or potential difference between two locations is proportional to the current of electricity flowing through the resistance, and the resistance of the circuit is proportional to the current or electricity travelling through the resistance. V=IR is the formula for O
5 min read
Electrical ResistanceElectrical resistance is the obstruction offered by the material in the flowing of the current or charge through the material. Thus, the higher the resistance the lower the amount of current passing through it. It is the property of a material that tells us about the flow of the current through the
9 min read
Linear Circuit ElementsIn Power Electronics, Linear circuit elements are those elements that are not changed with respect to the voltage and current. Elements that follow ohm's law are called linear circuit elements. Linear circuit elements mainly resist, store, or control the flow of electric current or voltage in a circ
8 min read
Network Analysis in Electric CircuitsIn this Article We will be going through what is Network Analysis, we will look at its components,then we will go through Electrical Elements, In this we will Know what is active and passive elements and the Different types of connections in electrical circuits, Next we will go through Different typ
9 min read
Digital & Logic Systems
Advanced Circuit Analysis
Nodal AnalysisIn this article, we will understand the nodal analysis with solved examples. We will discuss nodes and their types. We will discuss the procedure for nodal analysis along with some rules. We will also discuss the super node. Then we will see how nodal analysis is different from mesh analysis. Later
14 min read
Resistors in SeriesResistors are devices that obstruct the flow of electric current in the circuit. They provide the hindrance to the path of the current which flows in the circuit. A resistor is a two-terminal electrical component that works by reducing the flow of charge and voltage levels in the circuit. Most of th
10 min read
Total Resistance in a Parallel CircuitThe opposition to the current flowing in a circuit is called resistance. In other words, resistance is the measurement of opposition of current in a circuit. The SI unit of resistance is Ohm (Ω). Commonly it is denoted as R. According to Ohm's law, resistance is ratio of voltage applied to current f
6 min read
Representation of an Electronic CircuitElectronics and circuits go hand-in-hand, basically, every topic of electronic systems involves some explanation through basic circuits. In this article, we discuss how to represent an electronic circuit. We talk about the basic components required to make an electronic circuit, and the primary term
9 min read
Electrical FormulasElectricity is an integral part of our lives. In our daily life, we need electricity to run lights, fans, air conditioners, computers, etc. So, what is electricity? The flow of a charge through a conductor is referred to as electricity. The charge usually flows from a positive terminal (anode) to a
6 min read
Power & Power Electronics
Electrical Machines
Types of Electric MachinesElectric machines are essential devices in electric engineering that convert electric power into mechanical electricity or vice versa. These machines play a vital position in diverse programs, from powering business gadgets to propelling electric-powered vehicles. The 3 number one sorts of electric-
14 min read
Difference between AC Machine and DC MachineElectrical machines are a very important part of modern life from industries to household usage. These devices focus on transforming electrical energy into mechanical energy and vice versa. These machines are classified into two groups: alternating current (AC) machines and direct current (DC) machi
7 min read
Synchronous MotorsAn electric motor that operates at a constant speed is known as a synchronous motor as the frequency of the AC voltage that is used and the rotor rotation are synchronized. The fixed connection between the stator and rotor magnetic fields is maintained by it. Imagine a world free of electricity, whe
13 min read
Squirrel Cage Induction MotorAn electric motor is a machine that converts electrical energy into mechanical energy. The motor consists of two parts: the rotor and the stator. The rotor part is not fixed and thus it moves whereas the stator part is fixed and doesn't move. Magnet and armature are also a part of the electric motor
10 min read
Construction And Working of a DC GeneratorIn 1831, Michael Faraday, a British physicist, devised the electromagnetic generator. The primary function of this device is to convert mechanical energy to electrical energy. There are several types of mechanical energy sources available, including hand cranks, internal combustion engines, water tu
15+ min read
Power TransformersPower transformers are essential devices in the electrical system that play a critical role in transmitting electricity from power plants to distribution networks and end-users This comprehensive guide provides an in-depth overview of power transformers, covering their primary terminologies, working
6 min read
Control Systems
Control System TutorialIn this Control System tutorial, we will analyze and understand the concept and applications of a Control System with the help of detailed modules. This tutorial covers each module from the basics to advanced, including features, examples, classifications, applications, advantages, disadvantages, an
9 min read
What is Control System? Definition, Types, and ExamplesControl systems are used in a wide range of applications they are the essential parts of many modern devices and systems. In simple terms, Control systems are used to control the behavior of devices or any process. In this article, we will be discussing the topic of Control Systems. We will cover th
9 min read
Components of Control SystemsWith the advancement of technology, Human dependency on control system have increased over years and are being used everywhere, playing significant role in our daily lives. Contributing to different applications, they made the work easier by reducing human effort and involvement. They are used to co
8 min read
Types of Control SystemsEvery activity in our daily lives is affected by some form of control system. The concept of a control system also plays an important role in the working of space vehicles, satellites, guided missiles, etc. Such control systems are now an integral part of modern industrialization, industrial process
7 min read
Continuous Time and Discrete Time Control SystemsIn Electronic Engineering, Continuous-time and Discrete-time control systems are essential ideas that are vital to the design and optimization of a wide range of electronic systems and devices. Continuous-time control systems operate on signals that vary continuously over time, where both the input
7 min read
Controllability and Observability in Control SystemThe control system is the system that directs the input to another system and regulates its output. It helps in determining the system's behavior. The controllability and observability help in designing the control system more effectively. Controllability is the ability to control the state of the s
6 min read