Simulation Projects using Matlab/Simulink for BTech/MTech

Simulation Projects using Matlab/Simulink for BTech/MTech

A simulation is an imitation of the operation of a real-world process or system.The act of simulating something first requires that a model be developed; this model represents the key characteristics, behaviors and functions of the selected physical or abstract system or process. The model represents the system itself, whereas the simulation represents the operation of the system over time.

Simulation Projects List

Simulation is used in many contexts, such as simulation of technology for performance optimization, safety engineering, testing, training, education, and video games. Often, computer experiments are used to study simulation models. Simulation is also used with scientific modelling of natural systems or human systems to gain insight into their functioning, as in economics. Simulation can be used to show the eventual real effects of alternative conditions and courses of action. Simulation is also used when the real system cannot be engaged, because it may not be accessible, or it may be dangerous or unacceptable to engage, or it is being designed but not yet built, or it may simply not exist.

Simulation Projects

Matlab Projects for BTech/MTech Final Year

MATLAB PROJECTS

MATLAB Projects ASOKA TECHNOLOGIES

B.TECH/M.TECH ELECTRICAL PROJECTS USING MATLAB/SIMULINK

WE OFFER ACADEMIC Matlab Projects for BTech/MTech Final Year in different areas such as Power electronics, power systems, renewable energy, FACTS, etc

We will develop your OWN IDEAS and your IEEE Papers with extension if necessary and also we give guidance for publishing papers…

Please go through the

projects list

A large number of specialists and researchers overall utilize MATLAB to dissect and plan the frameworks and items changing our reality. Such enormous use prompts some exceptionally intriguing prospects in outlining. This rundown of 20 MATLAB ventures thoughts go over a portion of the arrangements that utilization or can utilize MATLAB. All things considered, the rundown of utilizations of such a product is interminable.

MATLAB is the short frame for Matrix Laboratory. It is a fourth era programming dialect and multi-worldview numerical figuring condition. MATLAB permits grid controls, capacities and information plotting, calculations usage, UI creation, interfacing with programs written in different dialects which incorporate C, C++, Java, Fortran and so forth. Matlab ventures are effective at picture preparing and additionally advanced flag handling framework outline.

projects is among the pioneers doing research in the field of MATLAB based tasks. We give most recent MATLAB tasks to understudies, specialists and scientists. Get MATLAB ventures with source code for your learning and research. We have extraordinary assortment of MATLAB based tasks for learning and direction. Our rundown of inventive MATLAB ventures list is an aggregation of MATLAB based undertakings that are worked to satisfy different modern and in addition residential applications and computerize different manual errands. We always give assortment of matlab venture thoughts on picture handling and additionally computerized flag preparing ventures. Our MATLAB based self learning units incorporate all framework subtle elements with circuit chart clarification and source code improvement clarification alongside instructional exercises of how the whole venture pack is worked for your comprehension of the framework advancement. In this way, here we have rattled off a portion of the best ventures thoughts in view of MATLAB which can be helpful for building understudies in finishing their Graduation effectively.

MATLAB is generally utilized in picture, flag preparing, scholarly and examine establishments and mechanical ventures. MATLAB was first received by scientists and professionals in control building, Little’s forte, however rapidly spread to numerous different areas. It is currently likewise utilized in training, specifically the instructing of straight variable based math, numerical examination, and is prominent among researchers engaged with picture preparing. In 2004, MATLAB had around one million clients in industry and in addition the scholarly community. MATLAB clients originate from different foundations of designing, science, and financial aspects

MATLAB projects

List of Electrical Engineering Projects

AT01 An Integrated Boost Resonant Converter for Photovoltaic Applications 2013-14 IEEE
AT02 Bridgeless SEPIC Converter With a Ripple-Free Input Current 2013-14 IEEE
AT03 An Advanced Power Electronics Interface for Electric Vehicles Applications 2013-14 IEEE
AT04 A High-Efficiency Solar Array Simulator Implemented by an LLC Resonant DC–DC Converter 2013-14 IEEE
AT05 A Novel Reduced Switching Loss Bidirectional AC/DC Converter PWM Strategy with Feed-Forward Control for Grid-Tied Micro Grid Systems 2013-14 IEEE
AT06 Coordinated Control and Energy Management of Distributed Generation Inverters in a Microgrid 2013-14 IEEE
AT07 A New ZVS DC/DC Converter With Three APWM Circuits 2013-14 IEEE
AT08 Analysis and Implementation of a Single Stage Flyback PV-Micro Inverter with Soft Switching 2013-14 IEEE
AT09 A Bridgeless Boost Rectifier for Low-Voltage Energy Harvesting Applications 2013-14 IEEE

Electrical engineering is a field of engineering that generally deals with the study and application of electricity, electronics, and electro magnetism. This field first became an identifiable occupation in the later half of the 19th century after commercialization of the electric telegraph, the telephone, and electric power distribution and use. Subsequently, broad casting and recording media made electronics part of daily life. The invention of the transistor, and later the integrated circuit, brought down the cost of electronics to the point they can be used in almost any household object.

Electrical engineering has now subdivided into a wide range of sub fields including electronics, digital computers, power engineering, tele communications, control systems, radio-frequency engineering, signal processing, instrumentation, and microelectronics. Many of these sub disciplines overlap and also overlap with other engineering branches, spanning a huge number of specializations such as hardware engineering, power electronics, electro magnetics & waves, microwave engineering, nanotechnology, electro chemistry, renewable energies, mechatronics, electrical materials science, and many more.

Electrical engineers typically hold a degree in electrical engineering or electronic engineering. Practicing engineers may have professional certification and be members of a professional body. Such bodies include the Institute of Electrical and Electronics Engineers (IEEE) and the Institution of Engineering and Technology (professional society) (IET).

Electrical engineers work in a very wide range of industries and the skills required are likewise variable. These range from basic circuit theory to the management skills required of a project manager. The tools and equipment that an individual engineer may need are similarly variable, ranging from a simple voltmeter to a top end analyzer to sophisticated design and manufacturing software.

 

Final Year Electrical Projects

AT_B01 An Integrated Boost Resonant Converter for Photovoltaic Applications IEEE 2013-14
AT_B02 Coordinated control and energy management of distributed generation inverters in a micro grid IEEE 2013-14
AT_B03 Statcom control at wind farms with fixed speed induction generators under asymmetrical grid faults IEEE 2013-14
AT_B04 Control of the Dynamic Voltage Restorer to Improve Voltage Quality

 

IEEE 2014-15
AT_B05 Research on Three-phase Voltage Type PWM Rectifier System Based on SVPWM control RJASET 2013-14
AT_B06 Dynamic Modeling of Microgrid for Grid Connected and Intentional Islanding Operation IEEE 2012-13
AT_B07 High-Step-Up and High-Efficiency Fuel-Cell Power Generation System with Active-Clamp Flyback-Forward Converter

 

IEEE 2012-13
AT_B08 Direct Power Control of Series Converter of Unified Power-Flow Controller With Three-Level Neutral Point Clamped Converter

 

IEEE 2012-13
AT_B09 Analysis of Discrete and Space Vector PWM Controlled Hybrid Active Filters For Power Quality Enhancement

 

IEEE 2012-13

and so on…….

Electrical engineering is a field of engineering that generally deals with the study and application of electricity, electronics, and electro magnetism. This field first became an identifiable occupation in the later half of the 19th century after commercialization of the electric telegraph, the telephone, and electric power distribution and use. Subsequently, broad casting and recording media made electronics part of daily life. The invention of the transistor, and later the integrated circuit, brought down the cost of electronics to the point they can be used in almost any household object.

Electrical engineering has now subdivided into a wide range of sub fields including electronics, digital computers, power engineering, tele communications, control systems, radio-frequency engineering, signal processing, instrumentation, and microelectronics. Many of these sub disciplines overlap and also overlap with other engineering branches, spanning a huge number of specializations such as hardware engineering, power electronics, electro magnetics & waves, microwave engineering, nanotechnology, electro chemistry, renewable energies, mechatronics, electrical materials science, and many more.

Electrical engineers typically hold a degree in electrical engineering or electronic engineering. Practicing engineers may have professional certification and be members of a professional body. Such bodies include the Institute of Electrical and Electronics Engineers (IEEE) and the Institution of Engineering and Technology (professional society) (IET).

Electrical engineers work in a very wide range of industries and the skills required are likewise variable. These range from basic circuit theory to the management skills required of a project manager. The tools and equipment that an individual engineer may need are similarly variable, ranging from a simple voltmeter to a top end analyzer to sophisticated design and manufacturing software.

 

Matlab Simulink projects in Hyderabad

Matlab Simulink projects in Hyderabad

Matlab Simulink projects in Hyderabad

1. Cascaded Dual Model Predictive Control of an Active Front-End Rectifier
2. Simple Time Averaging Current Quality Evaluation of a Single-Phase Multilevel PWM Inverter
3. Nonlinear Control of Single-Phase PWM Rectifiers With Inherent Current-Limiting Capability
4. Impact of SFCL on the Four Types of HVDC Circuit Breakers by Simulation
5. An Adaptive SPWM Technique for Cascaded Multilevel Converters with Time-Variant DC Sources
6. Model-Based Control for a Three-Phase Shunt Active Power Filter
7. Design of a multi level inverter with reactive power control ability for connecting pv cells to the grid
8. DSTATCOM supported induction generator for improving power quality
9. Improved equal current approach for reference current generation in shunt applications under unbalanced and distorted source and load conditions
10. A Hybrid-STATCOM With Wide Compensation Range and Low DC-Link Voltage

Matlab Simulink projects in Hyderabad

ELECTRICAL ENGINEERING is a field of engineering that generally deals with the study and application of electricity, electronics, and electro magnetism. This field first became an identifiable occupation in the later half of the 19th century after commercialization of the electric telegraph, the telephone, and electric power distribution and use. Subsequently, broad casting and recording media made electronics part of daily life. The invention of the transistor, and later the integrated circuit, brought down the cost of electronics to the point they can be used in almost any household object.

Electrical engineering has now subdivided into a wide range of sub fields including electronics, digital computers, power engineering, tele communications, control systems, radio-frequency engineering, signal processing, instrumentation, and microelectronics. Many of these sub disciplines overlap and also overlap with other engineering branches, spanning a huge number of specializations such as hardware engineering, power electronics, electro magnetics & waves, microwave engineering, nanotechnology, electro chemistry, renewable energies, mechatronics, electrical materials science, and many more.

POWER ELECTRONICS is the application of solid-state electronics to the control and conversion of electric power. The first high power electronic devices were mercury-arc valves. In modern systems the conversion is performed with semiconductor switching devices such as diodes, thyristors and transistors, pioneered by R. D. Middlebrook and others beginning in the 1950s. In contrast to electronic systems concerned with transmission and processing of signals and data, in power electronics substantial amounts of electrical energy are processed. An AC/DC converter (rectifier) is the most typical power electronics device found in many consumer electronic devices, e.g. television sets, personal computers, battery chargers, etc. The power range is typically from tens of watts to several hundred watts. In industry a common application is the variable speed drive (VSD) that is used to control an induction motor. The power range of VSDs start from a few hundred watts and end at tens of megawatts.

An ELECTRIC POWER SYSTEM is a network of electrical components deployed to supply, transfer, and use electric power. An example of an electric power system is the the grid that provides power to an extended area. An electrical grid power system can be broadly divided into the generators that supply the power, the transmission system that carries the power from the generating centres to the load centres, and the distribution system that feeds the power to nearby homes and industries. Smaller power systems are also found in industry, hospitals, commercial buildings and homes. The majority of these systems rely upon three-phase AC power—the standard for large-scale power transmission and distribution across the modern world. Specialised power systems that do not always rely upon three-phase AC power are found in aircraft, electric rail systems, ocean liners and automobiles.

MATLAB (matrix laboratory) is a multi-paradigm numerical computing environment and fourth-generation programming language. A proprietary programming language developed by MathWorks, MATLAB allows matrix manipulations, plotting of functions and data, implementation of algorithms, creation of user interfaces, and interfacing with programs written in other languages, including C, C++, C#, Java, Fortran and Python.

SIMULINK, developed by MathWorks, is a graphical programming environment for modeling, simulating and analyzing multidomain dynamic systems. Its primary interface is a graphical block diagramming tool and a customizable set of block libraries. It offers tight integration with the rest of the MATLAB environment and can either drive MATLAB or be scripted from it. Simulink is widely used in automatic control and digital signal processing for multidomain simulation and Model-Based Design.Matlab Simulink projects in Hyderabad

Matlab Simulink projects in Hyderabad

BTech and MTech electrical projects

BTech and MTech Electrical Project List

Electrical engineering is a field of engineering that generally deals with the study and application of electricity, electronics, and electro magnetism. This field first became an identifiable occupation in the later half of the 19th century after commercialization of the electric telegraph, the telephone, and electric power distribution and use. Subsequently, broad casting and recording media made electronics part of daily life. The invention of the transistor, and later the integrated circuit, brought down the cost of electronics to the point they can be used in almost any household object.

Electrical engineering has now subdivided into a wide range of sub fields including electronics, digital computers, power engineering, tele communications, control systems, radio frequency engineering, signal processing, instrumentation, and micro electronics. Many of these sub disciplines overlap and also overlap with other engineering branches, spanning a huge number of specializations such as hardware engineering, power electronics, electro magnetics & waves, microwave engineering, nano technology, electro chemistry, renewable energies, mechatronics, electrical materials science, and many more.

Electrical engineers typically hold a degree in electrical engineering or electronic engineering. Practicing engineers may have professional certification and be members of a professional body. Such bodies include the Institute of Electrical and Electronics Engineers (IEEE) and the Institution of Engineering and Technology (professional society) (IET).

Electrical engineers work in a very wide range of industries and the skills required are likewise variable. These range from basic circuit theory to the management skills required of a project manager. The tools and equipment that an individual engineer may need are similarly variable, ranging from a simple voltmeter to a top end analyzer to sophisticated design and manufacturing software.

 

A Novel Control Method for Transformerless H-Bridge Cascaded STATCOM with Star Configuration

ABSTRACT

This paper presents a transformerless static synchronous compensator (STATCOM) system based on multilevel H-bridge converter with star configuration. This proposed control methods devote themselves not only to the current loop control but also to the dc capacitor voltage control. With regards to the current loop control, a nonlinear controller based on the passivity-based control (PBC) theory is used in this cascaded structure STATCOM for the first time. As to the dc capacitor voltage control, overall voltage control is realized by adopting a proportional resonant controller. Clustered balancing control is obtained by using an active disturbances rejection controller. Individual balancing control is achieved by shifting the modulation wave vertically which can be easily implemented in a field-programmable gate array. Two actual H-bridge cascaded STATCOMs rated at 10 kV 2 MVA are constructed and a series of verification tests are executed. The experimental results prove that H-bridge cascaded STATCOM with the proposed control methods has excellent dynamic performance and strong robustness. The dc capacitor voltage can be maintained at the given value effectively.

 

KEYWORDS:

Active disturbances rejection controller (ADRC), H-bridge cascaded, passivity-based control (PBC), proportional resonant (PR) controller, shifting modulation wave, static synchronous compensator (STATCOM).

 

SOFTWARE: MATLAB/SIMULINK

 

CONTROL BLOCK DIAGRAM:

image001

Fig. 1. Control block diagram for the 10 kV 2 MVA H-bridge cascaded STATCOM.

 image002

Fig. 2. Block diagram of PBC.

 

EXPERIMENTAL RESULTS:

image003 image004

Fig. 3. Experimental results verify the effect of PBC in steady-state process. (a) Ch1: reactive current; Ch2: compensating current; Ch3: residual current of grid. (b) Ch1: reactive current; Ch2: compensating current; Ch3: residual current of grid.

 image005

Fig. 4. Experimental results show the dynamic performance of STATCOM in the dynamic process. Ch1: reactive current; Ch2: compensating current; Ch3: residual current of grid.

image006 image007

Fig. 5. Experimental results in the startup process and stopping process. (a) Ch1: reactive current; Ch2: compensating current; Ch3: residual current of grid. (b) Ch1: reactive current; Ch2: compensating current; Ch3: residual current of grid.

 

CONCLUSION

This paper has analyzed the fundamentals of STATCOM based on multilevel H-bridge converter with star configuration. And then, the actual H-bridge cascaded STATCOM rated at 10 kV 2 MVA is constructed and the novel control methods are also proposed in detail. The proposed method has the following characteristics.

1) A PBC theory-based nonlinear controller is first used in STATCOM with this cascaded structure for the current loop control, and the viability is verified by the experimental results.

2) The PR controller is designed for overall voltage control and the experimental result proves that it has better performance in terms of response time and damping profile compared with the PI controller.

3) The ADRC is first used in H-bridge cascaded STATCOM for clustered balancing control and the experimental results verify that it can realize excellent dynamic compensation for the outside disturbance.

4) The individual balancing control method which is realized by shifting the modulation wave vertically can be easily implemented in the FPGA.

The experimental results have confirmed that the proposed methods are feasible and effective. In addition, the findings of this study can be extended to the control of any multilevel voltage source converter, especially those with H-bridge cascaded structure.

 

REFERENCES

[1] B. Gultekin and M. Ermis, “Cascaded multilevel converter-based transmission STATCOM: System design methodology and development of a 12 kV ±12 MVAr power stage,” IEEE Trans. Power Electron., vol. 28, no. 11, pp. 4930–4950, Nov. 2013.

[2] B. Gultekin, C. O. Gerc¸ek, T. Atalik, M. Deniz, N. Bic¸er, M. Ermis, K. Kose, C. Ermis, E. Koc¸, I. C¸ adirci, A. Ac¸ik, Y. Akkaya, H. Toygar, and S. Bideci, “Design and implementation of a 154-kV±50-Mvar transmission STATCOM based on 21-level cascaded multilevel converter,” IEEE Trans. Ind. Appl., vol. 48, no. 3, pp. 1030–1045, May/Jun. 2012.

[3] S. Kouro, M. Malinowski, K. Gopakumar, L. G. Franquelo, J. Pou, J. Rodriguez, B.Wu,M. A. Perez, and J. I. Leon, “Recent advances and industrial applications of multilevel converters,” IEEE Trans. Ind. Electron., vol. 57, no. 8, pp. 2553–2580, Aug. 2010.

[4] F. Z. Peng, J.-S. Lai, J. W. McKeever, and J. VanCoevering, “A multilevel voltage-source inverter with separateDCsources for static var generation,” IEEE Trans. Ind. Appl., vol. 32, no. 5, pp. 1130–1138, Sep./Oct. 1996.

[5] Y. S. Lai and F. S. Shyu, “Topology for hybrid multilevel inverter,” Proc. Inst. Elect. Eng.—Elect. Power Appl., vol. 149, no. 6, pp. 449–458, Nov. 2002.