Journal Vol – 14 No -6, December 2019

DEFENSE AGAINST LOAD REDISTRIBUTION ATTACKS CONSIDERING LOAD CURTAILMENT

Authors:

Kommoju C Sravanthi, Kotapuri Mercy Rosalina

DOI NO:

https://doi.org/10.26782/jmcms.2019.12.00046

Abstract:

In the present scenario of cyber-physical power grid, DC State Estimation (SE) plays a key role in the secure and reliable operation of power systems. Advanced communication and information technological devices like Remote Terminal Units’/Phasor Measurement Units’ measurement values are more prone to false/bad attack vectors. Those typical attacks that target SE are called False Data Injection Attacks (FDIAs) which can bypass classical detection methods. Load Redistribution Attacks (LRAs) are practical FDIAs that aim active bus power injections and active line power flows. Immediate LRAs lead to severe load shedding whereas delayed ones lead to load shedding and line outages too. To find the most damaging LRA vector, a bi-level mathematical optimization problem is framed, which represents attacker and defender. An optimal defense strategy is found by obtaining the Nash equilibrium on solving a two-player (attacker and defender) static zero-sum game considering load shedding as the utility function. The approach is analyzed on IEEE-30 bus test system, and attack and defense probabilities at Nash equilibrium are obtained.

Keywords:

Load Redistribution Attacks,Bi-level Programming Problem,Probabilistic static game theory,

Refference:

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injection attacks on power system state estimation.” IEEE Transactions
on Smart Grid 5.3 (2014): 1216-1227.
II. Ding, Zhilu, Yingmeng Xiang, and Lingfeng Wang. “Quantifying the
influence of local load redistribution attack on power supply adequacy.” 2016
IEEE Power and Energy Society General Meeting (PESGM). IEEE, 2016.
III. Liu, Xuan, and Zuyi Li. “Local load redistribution attacks in power systems
with incomplete network information.” IEEE Transactions on Smart Grid 5.4
(2014): 1665-1676.
IV. Liu, Xuan, and Zuyi Li. “Local topology attacks in smart grids.” IEEE
Transactions on Smart Grid 8.6 (2016): 2617-2626.
V. Liu, Xuan, et al. “Cyber attacks against the economic operation of power
systems: A fast solution.” IEEE Transactions on Smart Grid 8.2 (2016):
1023-1025.
VI. Liu, Yao, Peng Ning, and Michael K. Reiter. “False data injection attacks
against state estimation in electric power grids.” ACM Transactions on
Information and System Security (TISSEC) 14.1 (2011): 13.
VII. Sharma, Neelam. “Analysis of Lactate Dehydrogenase & ATPase activity in
fish, Gambusia affinis at different period of exposureto chlorpyrifos.”
International Journal 4.1 (2014): 98-100.
VIII. Shen, Yubin, Minrui Fei, and Dajun Du. “Cyber security study for power
systems under denial of service attacks.” Transactions of the Institute of
Measurement and Control 41.6 (2019): 1600-1614.
IX. Xiang, Yingmeng, and Lingfeng Wang. “A game-theoretic study of load
redistribution attack and defense in power systems.” Electric Power Systems
Research 151 (2017): 12-25.
X. Xiang, Yingmeng, et al. “Coordinated attacks against power grids: Load
redistribution attack coordinating with generator and line attacks.” 2015 IEEE
Power & Energy Society General Meeting. IEEE, 2015.

XI. Xiang, Yingmeng, et al. “Power system reliability evaluation considering
load redistribution attacks.” IEEE Transactions on Smart Grid 8.2 (2016):
889-901.
XII. Xiang, Yingmeng, Lingfeng Wang, and Nian Liu. “A framework for
modeling load redistribution attacks coordinating with switching attacks.”
2017 IEEE Power & Energy Society General Meeting. IEEE, 2017.
XIII. Yang, Yingpeng, et al. “Man-in-the-middle attack test-bed investigating
cyber-security vulnerabilities in smart grid SCADA systems.” (2012): 138-
138.
XIV. Yuan, Yanling, Zuyi Li, and Kui Ren. “Modeling load redistribution attacks
in power systems.” IEEE Transactions on Smart Grid 2.2 (2011): 382-390.
XV. Yuan, Yanling, Zuyi Li, and Kui Ren. “Quantitative analysis of load
redistribution attacks in power systems.” IEEE Transactions on Parallel and
Distributed Systems 23.9 (2012): 1731-1738.

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NATURAL VENTILATION OF BUILDING USING CFD ANALYSIS

Authors:

VENKATESH P M, KANNAN M, BHARATH KUMAR N, RAO D S N M

DOI NO:

https://doi.org/10.26782/jmcms.2019.12.00047

Abstract:

The natural ventilation is flow through a closed surfaces. The internal air quality is good when the process of flow is continuous state of inlet and exhaust. By these way this paper described the room with close surfaces and flow direction comparison. Two open window with similar dimension are taken with top and bottom. The velocity of the flow inside are measured and determined a per measurements. By estimating the natural flow inside building the computational fluid dynamics process taken placed by using both concepts such as RANS method and LES method such as capturing the large eddy and by following governing Navier stokes equations

Keywords:

natural ventilation,fluid dynamics process,RANS method,Navier stokes equations,

Refference:

A.R.VijayBabu, Ch. Umamaheswara Rao, L. Tirupathaiah, Energy
Conservation, Green House Gas Emission Reduction and Management
Strategies of VFSTR University: A Case Study, Journal of Applied Research
in Dynamical & Control Systems, Volume 9, Issue 4, PP. 21-27, 2017.
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natural ventilation,”Energy and Buildings, vol. 31, pp. 65-73, 1// 2000.
III. J. Morrissey, T. Moore, and R. E. Horne, “Affordable passive solar design in
a temperate climate : An experiment in residential building
orientation,”Renewable Energy, vol. 36, pp. 568-577, 2// 2011.
IV. Kavitha, M., et al. “Evaluation of Antimitotic Activity of
Mukiamaderaspatana L. Leaf Extract in Allium cepa Root Model.”
International Journal 4.1 (2014): 65-68.
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cross ventilated rooms by varying the width of the window opening using
CFD,”Solar Energy, vol. 83, pp. 2-5, 1// 2009.
VI. M. M. Eftekhari, L. D. Marjanovic, and D. J. Pinnock, “Air flow distribution
in and around a single-sided naturally ventilated room,”Building and
Environment, vol. 38, pp. 389397, 3// 2003.
VII. P. F. Linden, “The fluid mechanics of natural ventilation,” -Annual Review
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VIII. Q. Chen and L. Glicksman. Application of computational fluid dynamics for
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overview and recent applications,”Building and Environment, vol. 44, pp.
848-858, 4// 2009.
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wind pressure and temperature difference,”Energy and Buildings, vol. 40, pp.
1031-1040, // 2008.
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XII. Y. Wei, Z. Guo-qiang, W. Xiao, L. Jing, and X. San-xian, “Potential model
for single-sided naturally ventilated buildings in China,” Solar Energy, vol.
84, pp. 1595-1600, 9// 2010.
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“Development of turbulence models for shear flows by a double expansion
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DESIGN AND IMPLEMENTATION OF A LOW-COST OBSTACLE AVOIDING UAV

Authors:

Venkata Subba Rao. P, G. Srinivasa Rao

DOI NO:

https://doi.org/10.26782/jmcms.2019.12.00048

Abstract:

The quadcopter is a device which works like a four-rotor helicopter with fixed rotor blades. It comes under the category of a drone. This paper explains how the quadcopter avoids the obstacle autonomously. For this, the ultrasonic sensors are used around the drone which senses the objects from distance and gives the signal to the Arduino controller board. It generates the signal which controls the quadcopter autonomously.

Keywords:

Drone,Quadcopter,Unmanned Aerial Vehicle,Obstacle Avoidance,Electronic Speed Controller(ESC),

Refference:

I. C. Woods, H. M. Lay and Q. P. Ha, “A novel extended potential field
controller for use on aerial robots,” 2016 IEEE International Conference on
Automation Science and Engineering (CASE), Fort Worth, TX, 2016, pp.
286-291.
II. Fu, A. Sarabakha, E. Kayacan, C. Wagner, R. John and J. M. Garibaldi, “A
comparative study on the control of quadcopter UAVs by using singleton and
non-singleton fuzzy logic controllers,” 2016 IEEE International Conference
on Fuzzy Systems (FUZZ-IEEE), Vancouver, BC, 2016, pp. 1023-1030.
III. Gheorghiţă, I. Vîntu, L. Mirea and C. Brăescu, “Quadcopter control system,”
2015 19th International Conference on System Theory, Control and
Computing (ICSTCC), Cheile Gradistei, 2015, pp. 421-426.
IV. Paiva, J. Soto, J. Salinas and W. Ipanaqué, “Modeling, simulation and
implementation of a modified PID controller for stabilizing a quadcopter,”
2016 IEEE International Conference on Automatica (ICA-ACCA), Curico,
2016, pp. 1-6.
V. Paredes, C. Jacinto, R. Ramírez, I. Vargas and L. Trujillano, “Fuzzy-PD
Controller for behavior mixing and improved performance in quadcopter
attitude control systems,” 2016 IEEE Latin American Conference on
Computational Intelligence (LA-CCI), Cartagena, Colombia, 2016, pp. 1-6.

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NPC INVERTER FED DTC OF INDUCTION MOTOR

Authors:

A. Naveen Reddy, K. Bala Krishna, A. Sriharibabu, Ch.Umamaheswararao

DOI NO:

https://doi.org/10.26782/jmcms.2019.12.00049

Abstract:

The paper emphasis the importance of DTC for an induction motor with multi level inverter in order to reduce the frequency of switching for the IGBT’S for same hysteresis bands of torque and flux. The simulations were completed in SIMULINK software. Simulation results from conventional NPC-DTC and modified NPC- DTC are presented and compared. Results shows that torque, flux linkage and stator current ripples are decreased with proposed NPC-DTC strategy. Evaluation was made based on the motor performance, which are like reduction of switching cycles and improvement in flux responses.

Keywords:

Direct Torque Control (DTC),Multi-level Inverter (MLI),

Refference:

I. A.Naveen Reddy.; “Performance and improvement of induction motor by
using multi level inverter” IJCTA, 9(10), 2016, pp. 4211-4219© International
Science Press
II. Maheswararao, Ch Uma, YS Kishore Babu, and K. Amaresh. “Sliding mode
speed control of a DC motor.” 2011 International Conference on
Communication Systems and Network Technologies. IEEE, 2011.
III. Mohan Reddy K.; Naveen Reddy A.; “Solar PV Array Fed Four Switch
Buck-Boost Converter for LHB Coach” IJCTA, 9(29), 2016, pp. 249-255©
International Science Press

IV. NEETHU, J., et al. “A PROSPECTIVE STUDY ON RESPIRATORY
DISTRESS SYNDROME AMONG NEONATES IN NICU &
ASSESSMENT OF KNOWLEDGE, ATTITUDE & PRACTICE ON
NEONATAL CARE AMONG POSTNATAL MOTHERS–A PILOT
STUDY.” International Journal 5.1 (2017)
V. P. Satya Prakash.; Srikanth Gollapudi.; Alla Naveen Reddy.; K Bala
Krishna.; “Design And Implementation Of Modified Sepic Convertor For
Battery Charging Application” Journal of Advanced Research in Dynamical
and Control SystemsVol. 9. (2017).PP.100-109
VI. Sriharibabu.;A. Naveen Reddy.; “A Novel Hybrid Wind Solar Power System
with Open Winding Permanent Magnetic Machine” International Journal of
Control Theory and Applications ISSN : 0974-5572„ Volume 10,
2017,PP.149-156© International Science Press
VII. Sukumar, Durga, JayachandranathJithendranath, and Suman Saranu. “Threelevel
inverter-fed induction motor drive performance improvement with
neuro-fuzzy space vector modulation.” Electric Power Components and
Systems 42.15 (2014): 1633-1646.
VIII. Toh, C.L.; Idris, N.R.N.; Yatim, A.H.M., “Torque ripple reduction in direct
torque control of induction motor drives,” Power Engineering Conference,
2003. PECon 2003. Proceedings. National 15-16 Dec. 2003.
IX. Yadlapalli, Ravindranath Tagore, and Anuradha Kotapati. “A fast-response
sliding-mode controller for quadratic buck converter.” International Journal
of Power Electronics 6.2 (2014): 103-130.

 

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HIGH VOLTAGE GAIN INTERLEAVED BOOST CONVERTER FOR PV SYSTEM APPLICATIONS WITH A NEURAL COMPENSATOR

Authors:

A. Sriharibabu, A. Naveen Reddy, P.V.S. Sobhan, M. Subba Rao

DOI NO:

https://doi.org/10.26782/jmcms.2019.12.00050

Abstract:

In the present scenario the utilization of renewable energy sources arehappening to be more popular due to more vigorous regulations in fuel economy and carbon. This paper deals with the high voltage gain interleaved boost converter for a Photo Voltaic (PV) system with a neural network based Maximum Power Point Tracking (MPPT) controller. So as to nourish the high power electrical appliances it is necessary to design high voltage gain converters. In order to meet this requirement, a three phase interleaved boost converter (IBC) which can provide high voltage gain is proposed and designed for a PV system is proposed in this paper. The interleaving technique is adapted for the proposed converter as it is able to maintain less ripple content at the converter input current there by improves the life time of PV array. It also results less voltage stresses on the power semiconductor devices which are employed for high rated PV system. Unlike conventional modelling of PV array procedure, modelling of PV array using neural network does not require involvement of any scientific definitions. Consequently they can possibly give an unrivalled strategy for inferring non-linear models than the officially settled regular procedures. In this paper a radial basis neural network trained model is employed to simulate and anticipate the MPP of a Photo Voltaic arrayutilizing an arbitrary arrangement of information gathered from a genuine photovoltaic array. In this paper Simulinkplat form of MATLAB software is employed to break down the performance of the prosed system by carrying simulation. Furthermore, it is additionally demonstrated that the MPPT from the solar PV array with the reduced harmonics is achieved through the proposed model.

Keywords:

Photovoltaic array modelling,Maximum power point tracker,Neural network,MPPT,Inter leaved connection,

Refference:

I. A. R.VijayBabu, V. Rajyalakshmi, K. Suresh, Renewable Energy Integrated
High Gain DC-DC Converter with Multilevel Inverter for Water Pumping
Applications, Journal of Advanced Research in Dynamical and Control
Systems, Volume 9, Issue 1, PP. 172-190, 2017.
II. Avvaru Sriharibabu, GorantlasrinivasaRao “MPPT Design for Photo Voltaic
Energy System Using Back-stepping Control with a Neural Compensator”,
Int. Jour. of Eng. Tech., vol.7, PP. 129-132, Iss. 4.24, 2018.
III. D Y Jung, Y-HyokJi, S-Hoon Park, Y-Chae Jung, and Ch-Yuen Won,
“Interleaved Soft-Switching Boost Converter for Photovoltaic Power-
Generation System” in IEEE trans. on power electron. vol. 26, no. 4, April
2011
IV. Maheswararao, Ch Uma, YS Kishore Babu, and K. Amaresh. “Sliding mode
speed control of a DC motor.” 2011 International Conference on
Communication Systems and Network Technologies. IEEE, 2011.
V. Martin A.D., Vazquez J. R. “MPPT algorithms comparison in PV systems:
P&O, PI, neuro-fuzzy and backstepping controls”, IEEE International
Conference on Indust. Tech. (ICIT), 2015.
VI. Niraj Rana, Mukesh Kumar, Arnab Ghosh and S. Banerjee, “A Novel
Interleaved Tri-State Boost Converter with Lower Ripple and Improved
Dynamic Response,” in IEEE Tran. on Indust. Electronics, vol. 65, no. 7, pp.
54565465, July 2018.
VII. SHAH, ASHISH P., et al. “INSILICO DRUG DESIGN AND MOLECULAR
DOCKING STUDIES OF SOME NATURAL PRODUCTS AS TYROSINE
KINASE INHIBITORS.” International Journal 5.1 (2017): 5.
VIII. Sukumar, Durga, JayachandranathJithendranath, and Suman Saranu. “Threelevel
inverter-fed induction motor drive performance improvement with
neuro-fuzzy space vector modulation.” Electric Power Components and
Systems 42.15 (2014): 1633-1646.
IX. Yadlapalli, Ravindranath Tagore, and Anuradha Kotapati. “A fast-response
sliding-mode controller for quadratic buck converter.” International Journal
of Power Electronics 6.2 (2014): 103-130.

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PERFORMANCE EVALUATION OF SPWM TECHNIQUES FOR SINGLE-PHASE FIVE-LEVEL INVERTER

Authors:

D. Manikanta Swamy, M. Venkatesan

DOI NO:

https://doi.org/10.26782/jmcms.2019.12.00051

Abstract:

In this, present a single-phase five-level inverter for high power applications. Whenever grid-connected system mainly focuses on maintaining less THD and less switching losses. The projected topology has a minimum number of switches as associated with existing topologies. In case, the inverter has a number of switches it produces high THD and switching loses similar more driving circuits are required. So in this proposed topology consider less number switches. Similarly, SPWM control technique is utilized to control the inverter. In SPWM techniques, level shifter modulation is implemented for proposed topology. With the help of Matlab software, the proposed topology is simulated and get results.

Keywords:

DC-DC converter,SPWM,Five-level inverter,single-phase inverter.,

Refference:

I. E. Babaei, S. Laali, and Z. Bayat, “A single-phase cascaded fivelevel inverter
based on a new basic unit with reduced number of power switches,” IEEE
Transactions on Industrial Electronics, vol. 62, no. 2, pp. 922–929, 2015.
II. E. Najafi, and A. H. M. Yatim, “Design and Implementation of a New
Fivelevel Inverter Topology,” IEEE Trans. Ind. Electron., vol. 59, no. 11, pp.
4148-4154, Nov. 2012.
III. E.Sambath1, S.P. Natarajan, C.R.Balamurugan, “Performance Evaluation of
Five Carrier Based PWM Techniques for Single Phase Five Level H-Bridge
Type FCMLI”, IOSR Journal of Engineering (IOSRJEN) ISSN: 2250-3021
Volume 2, Issue 7(July 2012), PP 82-90.
IV. Kennedy A. Aganah, Benozir Ahmed, and Aleck W. Leedy, “Single-Phase
Fivelevel Inverter Topology for Distributed DC Sources”, 978-1-5090-1496-
5/16/$31.00 c 2016 IEEE.

V. Krishna Kumar Gupta and Shailendra Jain, “A Novel Fivelevel Inverter
Based on Switched DC Sources”, IEEE TRANSACTIONS ON
INDUSTRIAL ELECTRONICS, VOL. 61, NO. 7, pp. 3269-3278, JULY
2014.
VI. Krishna Kumar Gupta, AlekhRanjan, Pallavee Bhatnagar, Lalit Kumar
SahuSailendraJain, “Fivelevel inverter topologies with reduceddevicecount:
A review,” Power Electronics, IEEE Transaction on, vol. III, pp. 135-150,
Jan. 2015.
VII. M. Venkatesan, et al., “Comparative Study of Three Phase Grid Connected
Photovoltaic Inverter Using PI and Fuzzy Logic Controller with Switching
Losses Calculation,” International Journal of Power Electronics Drives
Systems, vol.7, pp. 543-550, 2016.
VIII. M. Venkatesan, etc al., “Transient and Steady State Analysis of Modified
Three Phase Fivelevel Inverter for Photovoltaic System,” International
Journal of Power Electronics and Drive System (IJPEDS) Vol. 8, No. 1, pp.
31~39, March 2017
IX. Maha G. Elsheikh, Mahrous E. Ahmed, Emad Abdelkarem, Mohamed Orabi,
“Single-phase Five-level inverter with less number of power elements,” 33rd
International Telecommunications Energy Conference, IEEE transaction on,
pp. 1-8, Oct 2011.
X. R. Naderi and A. Rahmati, “Phase-shifted carrier pwm technique for general
cascaded inverters,” IEEE Transactions on Power Electronics, vol. 23, no. 3,
pp. 1257–1269, 2008.
XI. Sharma, Neelam. “Analysis of Lactate Dehydrogenase & ATPase activity in
fish, Gambusia affinis at different period of exposureto chlorpyrifos.”
International Journal 4.1 (2014): 98-100.
XII. Sung-Jun Park, Feel-Soon Kang, Man Hyung Lee, Cheul-U Kim, “A new
single-phase five-level PWM inverter employing a deadbeat control scheme,”
power electronics, IEEE transaction, vol. 18, no. 3, pp. 831-843, May 2003.
XIII. V.G. Agelidis, D.M. Baker, W.B. Lawrance, C. V. Nayar, “A Fivelevel PWM
Inverter Topology for Photovoltaic Application,” Industrial Electronics, IEEE
transaction symposium on, vol. II, pp. 589-594. 1997.

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OPERATION AND CONTROL OF DUAL ACTIVE HBRIDGE BASED ISOLATED DC-DC CONVERTER

Authors:

N. HarshaVardhan Reddy, Y. Srinivasa Rao, K. Rahul Wilson, D. Manikanta Swamy, P. Devi Mani Deepika

DOI NO:

https://doi.org/10.26782/jmcms.2019.12.00052

Abstract:

For the energy management application of a hybrid electric vehicle(HEV), an isolated DC-DC converter is used and its operation, design and control are discussed. With the help of phase-shift angle and the loading conditions, the different modes of operation and boundary conditions are acclaimed. The absolute as well as relative voltage ripple of output has been derived. The effect of dead-band and area of safe operation are found further. The output power and frequency of switching and leakage inductance relations are also disclosed.

Keywords:

energy management,DC-DC converter,voltage ripple,output power,frequency of switching,leakage inductance,

Refference:

I. BHATNAGAR M., BALIGA B.J.: ‘Comparison of 6H-SiC, 3C-SiC, and Si
for power devices’, IEEE Trans. Electron Devices, 1993, 40, (3), pp. 645–655
II. CHIU H.J., LIN L.W.: ‘A bidirectional DC-DC converter for fuel cell electric
vehicle driving system’, IEEE Trans. Power Electron., 2006, 21, (4), pp. 950–
958
III. INOUE S., AKAGI H.: ‘A bi-directional isolated DC/DC converter as a core
circuit of the next-generation medium voltage power conversion system’,
IEEE Trans. Power Electron., 2007, 22, (2), pp. 535–542

IV. LI H., PENG F.Z., LAWLER J.S.: ‘A natural ZVS medium-power
bidirectional dc-dc converter with minimum number of device’, IEEE Trans.
Ind. Appl., 2003, 39, pp. 525–535
V. Mitra, Indranil, Gopa Roy Biswas, and Sutapa Biswas Majee. “Effect of
Filler Hydrophilicity on Superdisintegrant Performance and Release Kinetics
From Solid Dispersion Tablets of A Model BCS Class II Drug.” International
Journal 4.1 (2014): 87-92.
VI. PENG F.Z., LI H., SU G.J.: ‘A new ZVS bidirectional DC-DC converter for
fuel cell and battery application’, IEEE Trans. Power Electron., 2004, 19, (1),
pp. 54–65
VII. SU G.J., PENG F.Z.: ‘A low cost, triple-voltage bus DC/DC converter for
automotive applications’. APEC 2002, 17thAnnual IEEE Conf. Applied
Power Electronics, 2002, vol. 1, pp. 10–14
VIII. SU G.-J., TANG L.: ‘A bidirectional, triple-voltage DC-DC converter for
hybrid and fuel cell vehicle power systems’. APEC 2007, February 25–March
1 2007, pp. 1043–1049
IX. WALTER J., DE DONCKER R.W.: ‘High-power galvanicallyisolated dc-dc
converter topology for future automobiles’. PESC, 2003, June 2003, vol. 1,
pp. 27–32
X. WANG K., LIN C.Y., ZHU L., QU D., LEE F.C., LAI J.S.: ‘Bi-directional dc
to dc converters for fuel cell systems’, IEEE Trans. Power Electron., 1998,
13, pp. 47–51
XI. ZHU L.: ‘A novel soft-commutating isolated boost fullbridgeZVS-PWM DCDC
converter for bidirectional highpower application’, IEEE Trans. Power
Electron., 2006, 21, pp. 422–429

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PERFORMANCE ANALYSISOF MOD2N -1 ADDERS AT SCHEMATIC AND RTL LEVEL USING CADENCE VIRTUOSO & ENCOUNTER TOOLS

Authors:

Gonuguntla Sailakshmi, Ashish Kumar Thakur, Sarada Musala

DOI NO:

https://doi.org/10.26782/jmcms.2019.12.00053

Abstract:

RNS has the ability toperform subtraction, addition independently with carryfree propagation. The structure of RNS requires two types of conversion: Forward Conversion and Reverse Conversion. To convert binary to residues, forward conversion is used whereas to convert residues to binary reverse conversion is used. Special moduli set and arbitrary moduli set are the two types of forward conversions. (2n-1) mod adder is one the important block used to get the special moduli set type of forward conversion. This paper consists of mod (2n-1) adders for the forward conversion technique and comparison of designs at both Schematic level and RTL level. The schematic level designs provides low power than RTL design whereas the delay is reduced in RTL than Schematic design. The designs have been simulated for RTL using NC Launch - Encounter tool standard 90nm Technology.The designs have been simulated using CMOS 90nm virtuoso tool in cadence for schematic designs.

Keywords:

Residue Number System,Forward Conversion,Reverse Conversion,Modular adder,Multiplexer,

Refference:

I. A.Omondi, B. PremKumar, “Residue Number System: Theory and
Implementation”, Imperial College Press 2007, ISBN 978-1-86094-866-4.
II. B.Cao, C.H.Chang, T.Srikanthan, “A Residue-to-Binary Converter for a New
Five-Moduli Set”, IEEE Trans. on Circuits and Systems-I: Regular Papers,
2007, Vol. 54, pp.1041-1049. doi:10.1109/TCSI.2007.890623.
III. Hamed Naseri and Somayeh Timarchi, “low-power and fast full adder by
exploring New XOR and XNOR gates”,IEEE Transactions on very large
scale integration systems,Aug. 2018, Vol. 26, no. 8, pp.1481-1493.
doi:10.1109/TVLSI.2018.2820999.

IV. N. S. Szabo, R.I. Tanaka, “Residue Arithmetic and its applications to
computer technology”, New York: Mc-Graw Hill, 1967.
V. R. Zimmermann,“Efficient VLSI implementation of modulo addition and
multiplication”, in proc. of IEEE Symposium on Computer Arithmetic, Apr.
1999, pp. 158-167. doi:10.1109/ARITH.1999.762841.
VI. Sharma, Neelam. “Analysis of Lactate Dehydrogenase & ATPase activity in
fish, Gambusia affinis at different period of exposureto chlorpyrifos.”
International Journal 4.1 (2014): 98-100.
VII. S. Akhter, R. Gaurav, S. Khan “Analysis and Design of Residue Number
System Based Building Blocks”, in proc. of 5th International Conference on
signal processing and Integrated Networks, 2018, pp.441-
445.doi:10.1109/SPIN.2018.8474204.
VIII. S. J. Piestrak, “A High speed Realization of a residue to binary number
system converter”, IEEE Transactions on Circuits and Systems-II: Analog
and Digital Signal Processing, 1995, Vol. 42, pp. 661-663.
doi:10.1109/82.471401.
IX. T. U. Narendra and et.al, “FPGA based efficient Architecture for conversion
of binary to residue number system”,inproc.of Information Technology,
Electronics and Mobile Communication conference, Oct 2017.
doi:10.1109/IEMCON.2017.8117238.

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DESIGN AND IMPLEMENTATION OF HIGH PERFORMANCE AC-DC CONVERTER

Authors:

D. Dharani Lakshmi, K. Jithendra Gowd

DOI NO:

https://doi.org/10.26782/jmcms.2019.12.00054

Abstract:

This paper is mainly focus on the power quality issues that occur in the power system and how this can be reduced by using the more outputs from the SMPS. The theme of the paper is usage of different power electronics converter methods in the supply side and constant converter by using the transformer with high frequency(HFT). In order to improvement of the PQ and for the best monitoring purpose different control strategies like NN is used in the SISO and MOSMPS. Here we mainly focus on the SISO System to obtain best output under standards conditions. Isolated and non-isolated configuration for Boost converter and various models are proposed. These entire configurations are simulated and modelled by using the MATLAB under certain loaded conditions.

Keywords:

Power Factor Correction,PFC Converters,Power Factor,Total Harmonic Distortion,Switched Mode Power Supply SMPS,

Refference:

I. A.R.VijayBabu, Manoj Kumar.P, G.Srinivasa Rao, Design and Modelling of
Fuel cell powered Quadratic Boost Converter based Multilevel Inverter,
Proceeding of the IEEE International Conference on Innovations in Power
and Advanced Computing Technologies (i-PACT-2017), VIT University,
pp.1-6, April, 2017. DOI: 10.1109/IPACT.2017.8244962
II. B. Singh, B. N. Singh, A. Chandra, K. Al-Haddad, A. Pandey and D. P.
Kothari, ―A review of single-phase improved power quality AC-DC
converters‖, IEEE Transactions on Industrial Electronics, October 2003, Vol.
50, No. 5, pp. 962–981.
III. B. Singh, Sanjeev Singh, A. Chandra and K. Al-Haddad, ―Comprehensive
study of single-phase AC-DC power factor corrected converters with high
frequency isolation‖, IEEE Transactions on Industrial Informatics, November
2011, Vol. 7, No. 7, pp. 540–556.
IV. J. B. Williams, ―Design of feedback loop in unity power factor AC to DC
converter‖, in Proc. IEEE Power Electronics Specialists Conference, 1989,
pp. 959-967.
V. J. P. Noon, ―Designing high-power factor off-line power supplies‖, Unitrode
Design Seminar Manual, SEM-1500, Texas Instruments, 2003.
VI. Kavitha, M., et al. “Evaluation of Antimitotic Activity of
Mukiamaderaspatana L. Leaf Extract in Allium cepa Root Model.”
International Journal 4.1 (2014): 65-68.
VII. L. H. Dixon, ―Average current mode control of switching power supplies‖,
Unitrode Power Supply Design Seminar Manual, SEM-700, 1990.
VIII. L. H. Dixon, ―High power factor switching preregulator design
optimization‖, Unitrode Power Supply Design Seminar Manual, SEM-700,
1990.

IX. Limits for Harmonic Current Emissions (Equipment Input Current ≤ 16 A per
Phase), International Electro Technical Commission Standard, 61000-3-2,
2004.
X. M. J. Kosher and R. L. Steigerwald, ―An AC to DC converter with high
quality input waveforms‖, in Proc. IEEE Power Electronics Specialists
Conference, 1982, pp. 63- 75.k, 1987.
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controller for a unity-power-factor PWM rectifier‖, IEEE Transactions on
Power Electronics, January 1996, Vol. 11, pp. 1-6.
XII. S. Buso, P. Mattavelli, L. Rossetto and G. Spiazzi, ―Simple digital control
improving dynamic performance of power factor preregulators‖, IEEE
Transactions on Power Electronics, September 1998, Vol. 13, pp. 814-823.

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UNMANNED FLYING VEHICLES FOR VARIOUS APPLICATIONS AND THEIR FUTURE SCOPE IN INDIA

Authors:

Ch N Narasimha Rao, Bala Krishna K, Rachananjali K, Sravani.V

DOI NO:

https://doi.org/10.26782/jmcms.2019.12.00055

Abstract:

Now a day’s people are becoming very smarter and trying to do any task in a simple way. To make the life simple and convenient many devices are available at present in the market. For example, in earlier days people can work hard for the things like getting water from a well but now whenever we switch ON the motor the water comes out of the well and we can store it where ever we want. Likewise there exist many technologies like vehicles, computers, smart phones etc… Among recent improved technologies, Unmanned Aerial Vehicle (UAV) also known as drones in some applications has becoming very popular because of its use in aerial photography, surveillance purposes etc… Its features like easy accessibility and simple construction made them more popular. This paper discusses about the complete idea behind UFV (Unmanned Flying Vehicles) and its origin; construction, different parts, their selection and it’s working. It also discuss about various applications of UFV and their future scope in INDIA.

Keywords:

Unmanned Aerial Vehicle (UAV),Unmanned Flying Vehicles (UFV),DRONES,

Refference:

I. A “hand book of unmanned aerial vehicles” byKimon P. Valavanis.
II. Drones and Robots: On the Changing Practice of Warfare” by Daniel Statman
in The Oxford Handbook of Ethics and War @http://uavcoach.com/how-tofly-
a-quadcopter-guide/.
III. Hovering Over Opportunities, Managing risk with drones, and managing
drone risk. @http://www.zurichcanada.com/
IV. https://en.wikipedia.org/wiki/Unmanned_aerial_vehicle
V. http://timesofindia.indiatimes.com/city/mumbai/Been-there-drone-that-Pizzaair-
delivery-in-Mumbai/articleshow/35445623.cms
VI. http://www.ibtimes.co.uk/faa-approves-first-drone-delivery-service-amazonprime-
air-loses-race-medical-supply-firm-flirtey-1511175
VII. https://www.linkedin.com/pulse/drones-history- where-did-name-dronecome-
from-when-fly-p%C3%A9rez-garc%C3%ADa
VIII. https://www.priv.gc.ca/information/researchrecherche/2013/drones_201303
IX. India’s Armed Drone Fleet” by SauravJha in The Diplomat.
@http://thediplomat.com
X. Julian Tan Kok Ping, Ang Eng Ling, Tan Jun Quan, Chua Yea Dat “Generic
Unmanned Aerial Vehicle (UAV) for Civilian Application” in 2012 IEEE
Conference on Sustainable Utilization and Development in Engineering and
Technology, Kuala Lumpur.
XI. Kavitha, M., et al. “Evaluation of Antimitotic Activity of Mukia
maderaspatana L. Leaf Extract in Allium cepa Root Model.” International
Journal 4.1 (2014): 65-68.
XII. R. Swaminathan, “Drones & India Exploring Policy and Regulatory
Challenges Posed by Civilian Unmanned Aerial Vehicle”. An ORF
occasional paper #58, Feb 2015.
XIII. RCMP Mini-Helicopter: “Manitoba Joins Growing List Of RC Chopper
Adopters” By Steve Lambert, The Canadian Pres
XIV. Sanjeev Miglani “India turns to Israel for armed drones as Pakistan, China
build fleets” in REUTERS on 22nd sep 2015.@ http://in.reuters.com

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COMPARISON ANALYSIS OF CIRCUIT BREAKERS WITH RESISTIVE TYPE SFCL IN MICROGRID PROTECTION

Authors:

Mercy Rosalina K, M Uma Maheswara Rao

DOI NO:

https://doi.org/10.26782/jmcms.2019.12.00056

Abstract:

Microgrid protection is one of the challenging tasks, now a day microgrids placed an important role. In general, some conventional protective devices (Circuit breaker and relays, etc.) are there for the protection of microgrids. These conventional protective devices having some drawbacks, they are during abnormal conditions continuity of supply is not possible and it permits up to three cycles of error currents into the network. To overcome that disadvantages Superconducting Fault Current Limiter (Resistive type) is used. Under standard conditions R-SFCL offers small resistance then it acted as a superconductor, under fault circumstances it offers more resistance then error currents are minimized. It allows only one cycle of fault current into the system and continuity of supply is possible.

Keywords:

Distributed generation (DG),Superconducting fault current limiters Resistive type (R-SFCL),Circuit breaker (CB),Phase locked loop (PLL),

Refference:

I. A. S. Emhemed, Singh R. N. K, and McDonald J. R, “Analysis of transient
stability enhancement of LVconnected induction microgenerators by using
resistive-type fault current limiters,” IEEE Trans. Power Syst., vol. 25, no. 2,
pp. 885–893, May 2010.
II. B.W.Lee, Park. K. B and Oh. I. S,“Practical application issues of
superconducting fault current limiters for electric power systems,” IEEE
Trans. Sppl. Superconduct., vol. 18, p. 620, June. 2008.
III. Babu, T. Vandana, T. Satyanarayana Murthy, and B. Sivaiah. “Detecting
unusual customer consumption profiles in power distribution systems—
APSPDCL.” 2013 IEEE International Conference on Computational
Intelligence and Computing Research. IEEE, 2013.
IV. M. Noe and Steurer. M, “High temperature superconductor fault current
limiters: concepts, applications and development status,” Supercond. Sci.
Technol., vol. 20, no. 3, pp. R15–R29, Mar. 2007.
V. M. Uma Maheshwara Rao, Mercy Rosalina. K, “Microgrid protection by
using resistive type superconducting fault current limiter,” Modelling,
Measurement, and Control A, Vol. 91, no.2, June 2018,pp.89-93, June 2018.
VI. M. Uma Maheshwara Rao, Mercy Rosalina. K, “Modeling of a Micro-grid
Connected Hybrid System using Solar, Wind and Fuel cell”, Jour of Adv
Research in Dynamical & Control Systems, vol.10, pp.1908-1915, July 2018.

VII. M. Uma Maheshwara Rao, Mercy Rosalina. K, “Transient stability
improvement of Microgrid using Series Active Power Filters, ” IEEE Conf.
On Fifth International Conference on Electrical Energy Systems (ICEES), pp.
1- 4, 2019.
VIII. Mitra, Indranil, Gopa Roy Biswas, and Sutapa Biswas Majee. “Effect of
Filler Hydrophilicity on Superdisintegrant Performance and Release Kinetics
From Solid Dispersion Tablets of A Model BCS Class II Drug.” International
Journal 4.1 (2014): 87-92.
IX. M. Uma Maheshwara Rao, Mercy Rosalina. K, “Transient stability
improvement of Microgrids by using Resistive type SFCL and Series active
power filters,” European Journal of Electrical Engineering, Vol. 19, no.3-4,
June 2018,pp.181-195, 2017.
X. Pei and Smith. A. C, “Experimental Testing and Development of Improved
Modelling for Multistrand Resistive SFCL,” IEEE Transactions on Applied
Superconductivity, vol. 26, issue 4, 2016.
XI. Z. Kai-Hui and Ming-Chao. X, “Impacts of Microgrid on Protection of
Distribution Networks and Protection Strategy of Microgrid,” IEEE Conf. on
Advanced Power Sys. Automation and Protection, Vol. 1, pp.356-359, 2011.

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REALIZING SOFT SWITCHING IN FLYBACK CONVERTER BY APPROPRIATE TRANSFORMER DESIGN AND COMPARISON WITH HARD SWITCHED SIMILAR CONVERTER

Authors:

Rayudu Mannam, Srinivasa Rao Gorantla, Nagesh Vangala

DOI NO:

https://doi.org/10.26782/jmcms.2019.12.00057

Abstract:

AC- DC or DC-DC converters are today entirely dominated by switched-mode power converters, SMPCs. The industry today, in the race of meeting customers’ demands, is looking at packaging more and more power in lesser and lesser volumes. Hence the power supply designers are always engaged in devising new topologies and techniques to achieve power densities efficiently. Soft switching is one such technique which aids the designers in finding a solution to increase power densities by raising the switching frequency. The present paper proposes the least complicated soft-switching technique in low power flyback converters. Flyback converter in the power range of 150W is taken as a study piece, and soft switching is demonstrated without adding any extra hardware and control overhead. The obtained results are compared with a hard switched CCM flyback converter. Practical working models are built, tested, and evaluated to display the efficacy of the proposed scheme.

Keywords:

Soft Switching,Flyback Converters,DCM,Hard Switching,low power,DC-DC Converter,

Refference:

I. Christophe Basso. “The Dark Side of Flyback converters ON
semiconductors” APEC seminar, 2011.
II. Guichao Hua and Fred C. Lee. “Soft-Switching Techniques in PWM
Converters” IEEE Transactions on Industrial Electronics, Vol. 42, Issue 6,
pp. 595-603, December 1995.
III. KeithBillings, TaylorMorey. “Switching Power supply Design Handbook
Third edition ” Mc Graw Hill, 2009.
IV. Nagesh Vangala, Rayudu Mannam. “Transformer Design to Achieve Soft
Switching In Low Power Flyback Converters” IEEE 1st International
Conference on Power Electronics 2016, pp. 1-5, June 2016.
V. Ned Mohan, Tore M. Undeland and William P. Robbins. “Power Electronics
Converters, Applications, And Design THIRD EDITION” JOHN WILEY &
SONS, INC., 2003.
VI. SHAH, ASHISH P., et al. “INSILICO DRUG DESIGN AND
MOLECULAR DOCKING STUDIES OF SOME NATURAL PRODUCTS
AS TYROSINE KINASE INHIBITORS.” International Journal 5.1 (2017):
5.
VII. Shijie Chen et al. “A transformer assisted ZVS scheme for flyback
converter” Twentieth Annual IEEE Applied Power Electronics Conference
and Exposition APEC 2005 V2, pp. 678-682, March 2005.

VIII. Sung-Soo Hong, Sang-Keun Ji et al. “Analysis and design of a high voltage
flyback converter with resonant elements” Journal of Power Electronics,
Vol. 10, Issue 2, pp. 107-114, March 2010.
IX. T.W. Ching and K.U. Chan. “Review of Soft-Switching Techniques for
High- Frequency Switched-Mode Power Converters” IEEE Vehicle Power
and Propulsion Conference (VPPC), Harbin, China, pp. 1-6, September
2008.
X. Tesla N. “Electrical Igniter for Gas Engines” US Patent No: 609250, Aug
1898.
XI. West Coast Magnetics. “Switchmode Power Supply Transformer Design”
www.wcmagnetics.com Downloaded, April 2019.
XII. Xiaoyang Zhang. “Zero Voltage Switching in Flyback Converters with
Variable Input Voltages” US Patent No: 2013/0148385, June 2013.

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POSITIVE SEQUENCEPOWER FLOW ANALYSIS OF IEEE 57 BUS POWER SYSTEMUSING MATLAB-LOAD FLOW TOOL

Authors:

Veera Bhadra Chary.Gade, K.Mercy Rosalina

DOI NO:

https://doi.org/10.26782/jmcms.2019.12.00058

Abstract:

The approach of symmetrical components of power flow analysis is the very salient technique to inspect the bus power flows in a 3-phase unbalanced and balanced power system network during the healthy or unhealthy case operation. There are various traditional programs available in the literature,which solve the single-phase equivalent power system models for power flow analysis. The main aim of this paper is to conduct a positive sequence power flow analysis on a balanced 3- phase IEEE 57 bus test case matlab Simulink model by using the Load Flow Tool. The present power system model consists of 7 thermal energy systems, each system configured with IEEE type-1 Excitation, Steam turbine, and Governor. The simulation study is useful for finding the bus voltages, active power losses and reactive power losses in the lines. However, there is an empirical analysis conducted with present results with the test case. There is a voltage improvement is observed at the buses with the present model. The efficiency of the model and convergence criteria perceive with the simulation results report. The simulink model is also useful for the steadystate analysis of power system network as well as the power flow analysis of the network with various grid connected renewable energy sources.

Keywords:

IEEE 57 bus,Load Flow tool,Power Flow,positive sequence,Simulink model,thermal energy systems,

Refference:

I. ARTURO LOSI, AND MARIO RUSSO, “OBJECT-ORIENTED LOAD FLOW FOR
RADIAL AND WEAKLY MESHED DISTRIBUTION NETWORKS,” IEEE
TRANSACTIONS ON POWER SYSTEMS, VOL. 18, NO. 4, PP 1265 – 1274, NOV.
2003.
II. FAISAL MUMTAZ, M. H. SYED, MOHAMED AL HOSANI, AND H. H.
ZEINELDIN, “A NOVEL APPROACH TO SOLVE POWER FLOW FOR
ISLANDED MICROGRIDS USING MODIFIED NEWTON RAPHSON
WITH DROOP CONTROL OF DG,” IEEE TRANSACTIONS ON
SUSTAINABLE ENERGY, VOL. 7, NO. 2, PP 493 – 503, APRIL. 2016.
III. FEDERICO MILANO, “CONTINUOUS NEWTON’S METHOD FOR POWER FLOW
ANALYSIS,” IEEE TRANSACTIONS ON POWER SYSTEMS, VOL. 24, NO. 1, PP.
50–57, FEB. 2009.
IV. J. E. TATE AND T. J. OVERBYE, “A COMPARISON OF THE OPTIMAL
MULTIPLIER IN POLAR AND RECTANGULAR COORDINATES,” IEEE
TRANSACTIONS ON POWER SYSTEMS, VOL. 20, NO. 4, PP. 1667–1674, NOV.
2005.
V. J. FLUECK AND H. D. CHIANG, “SOLVING THE NONLINEAR POWER FLOW
EQUATIONS WITH AN INEXACT NEWTON METHOD USING GMRES,” IEEE
TRANSACTIONS ON POWER SYSTEMS, VOL. 13, NO. 2, PP. 267–273, MAY
1998.
VI. K. A. BIRT, J. J. GRAFFY, J. D. MCDONALD, AND A. H. EL-ABIAD, “THREE
PHASE LOAD FLOW PROGRAM,” IEEE TRANSACTIONS ON POWER APPARATUS
AND SYSTEMS, VOL. 95, NO. 1, PP 59 – 65, FEB. 1976.
VII. L. M. C. BRAZ, C. A. CASTRO, AND C. A. F. MURARI, “A CRITICAL
EVALUATION OF STEP SIZE OPTIMIZATION BASED LOAD FLOW METHODS,”
IEEE TRANSACTIONS ON POWER SYSTEMS, VOL. 15, NO. 1, PP. 202–207, FEB.
2000.

VIII. P. R. BIJWE AND S. M. KELAPURE, “NONDIVERGENT FAST POWER FLOW
METHODS,” IEEE TRANSACTIONS ON POWER SYSTEMS VOL. 18, NO. 2, PP.
633–638, MAY 2003.
IX. SEMLYEN, “FUNDAMENTAL CONCEPTS OF A KRYLOV SUBSPACE POWER
FLOW METHODOLOGY,” IEEE TRANSACTIONS ON POWER SYSTEMS, VOL. 11,
NO. 3, PP. 1528–1537, AUG. 1995.
X. SHARMA, NEELAM. “ANALYSIS OF LACTATE DEHYDROGENASE & ATPASE
ACTIVITY IN FISH, GAMBUSIA AFFINIS AT DIFFERENT PERIOD OF EXPOSURETO
CHLORPYRIFOS.” INTERNATIONAL JOURNAL 4.1 (2014): 98-100.
XI. T. J. OVERBYE AND R. P. KLUMP, “EFFECTIVE CALCULATION OF POWER
SYSTEM LOW-VOLTAGE SOLUTIONS,” IEEE TRANSACTIONS ON POWER
SYSTEMS, VOL. 11, NO. 1, PP. 75–82, FEB. 1996.
XII. T. J. OVERBYE, “COMPUTATION OF A PRACTICAL METHOD TO RESTORE
POWER FLOW SOLVABILITY,” IEEE TRANSACTIONS ON POWER SYSTEMS,
VOL. 10, NO. 1, PP. 280–287, FEB. 1995.
XIII. Y. CHEN AND C. SHEN, “A JACOBIAN-FREE NEWTON-GMRES(M) METHOD
WITH ADAPTIVE PRECONDITIONER AND ITS APPLICATION FOR POWER FLOW
CALCULATIONS,” IEEE TRANSACTIONS ON POWER SYSTEMS, VOL. 21, NO. 3,
PP. 1096–1103, AUG.2006.

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A SINGLE STAGE 1 KW ISOLATED SINGLE SWITCH ACTIVE POWER FACTOR CORRECTED SOFT SWITCHING AC-DC CONVERTER

Authors:

Nagesh Vangala, Srinivasa Rao Gorantla, Rayudu Mannam

DOI NO:

https://doi.org/10.26782/jmcms.2019.12.00059

Abstract:

Active Power factor corrected AC-DC converters in the power range of 500 watts and above are mostly accomplished in a two-stage process. The front end is non-isolated boost regulator working in CCM and the second stage is a DC-DC converter with isolation. This process is less efficient, complex and consumes more area. The front end PFC in CCM is a major source of EMI requiring heavy line filters to meet the international interface specifications. A novel single-stage AC-DC converter for the output power of 1KW is proposed here, which has many advantages such as Single active switch, completely soft switched and isolated. The new configuration is fabricated and tested for all the parameters. A near unity PF is achieved and the worst case efficiency is recorded to be 94%. All the test data are presented.

Keywords:

Power factor correction,soft switching,CCM,BCM control,Resonant reset,High power,

Refference:

I. Ching T.W. and K.U. Chan, Review of Soft-Switching Techniques for
High-Frequency Switched-Mode Power Converters, IEEE Vehicle
Power and Propulsion Conference (VPPC), Sep 2008
II. Edward L. Owen. “A History of Harmonics in Power Systems” IEEE
Industry Applications Magazine, January 1998.
III. EPSMA. “Harmonic Current Emissions: Guidelines to the standard EN
61000-3-2” EUROPEAN POWER SUPPLY MANUFACTURERS
ASSOCIATION, April 2010.
IV. Joel Turci et al. “Power Factor Correction (PFC) Handbook: Choosing
the Right Power Factor Correction Solution” ON Semiconductor HBD
853/D Rev 5, April 2014.
V. Keith Billings, Taylor Morey. “Switching Power supply Design
Handbook Third edition” Mc Graw Hill, 2009.
VI. Maheswararao, Ch Uma, YS Kishore Babu, and K. Amaresh. “Sliding
mode speed control of a DC motor.” 2011 International Conference on
Communication Systems and Network Technologies. IEEE, 2011.
VII. Miao-Miao Cheng et al. “Continuous Conduction Mode Soft-Switching
Boost Converter and its Application in Power Factor Correction” Journal
of Power Electronics, September 2016.
VIII. Milan M. Jovanovic. “Power Supply Technology – Past, Present, and
Future” Power Electronics Laboratory, Delta Products Corporation NC
27709, U.S.A., 2007.
IX. Nagesh Vangala, Rayudu Mannam. “Transformer Design to Achieve
Soft Switching In Low Power Flyback Converters” IEEE 1st
International Conference on Power Electronics 2016, June 2016.

X. Nagesh Vangala, Srinivasa Rao Gorantla, Rayudu Mannam. “Improving
power losses and thermal management in switch mode power converters
using multiple transformers” Int. J. Computer Aided Engineering and
Technology, 2019.
XI. Rayudu Mannam, Srinivasa Rao Gorantla, Nagesh Vangala. “Soft-
Switching Flyback Converter Adopting Fixed Dead Time” Journal of
Advanced Research in Dynamical and Control Systems JARDCS, 2017.
XII. Sam Abdel-Rahman, Franz Stückler, Ken Siu. “PFC boost converter
design guide: 1200 W design example” Infineon Application Note
Revision1, February 2016.
XIII. Sharma, Neelam. “Analysis of Lactate Dehydrogenase & ATPase
activity in fish, Gambusia affinis at different period of exposureto
chlorpyrifos.” International Journal 4.1 (2014): 98-100.
XIV. Sukumar, Durga, Jayachandranath Jithendranath, and Suman Saranu.
“Three-level inverter-fed induction motor drive performance
improvement with neuro-fuzzy space vector modulation.” Electric Power
Components and Systems 42.15 (2014): 1633-1646.
XV. Yadlapalli, Ravindranath Tagore, and Anuradha Kotapati. “A fastresponse
sliding-mode controller for quadratic buck
converter.” International Journal of Power Electronics 6.2 (2014): 103-
130.

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PERFORMANCE ANALYSIS OF A STANDALONE PHOTOVOLTAIC SYSTEM USING P&O MPPT ALGORITHM

Authors:

G. Sirisha, A.R.Vijaybabu, Ch. Umamaheswara Rao, K. Sai Janardhan

DOI NO:

https://doi.org/10.26782/jmcms.2019.12.00060

Abstract:

In the world, acute energy decreases so we are moving to alternative energy sources today. Solar energy is a vital source in the sultry country like India. The foremost obstacle for the entrance and reaches solar energy is their Inefficiency and high initial charge. Within this paper, we analyze the schematic to remove the most attainable solar energy from a solar panel and use it for Direct Current utilization. This paper reviews in detail the theory of MPPT which significantly improves the production from the astral system.

Keywords:

Photo voltaic system,P&O,Maximum Power Point Tracking (MPPT),

Refference:

I. D. Dondi, A. Bertacchini, D. Brunelli, L. Larcher, “Modeling and optimization of a
solar energy harvester system for self-powered wireless sensor networks”, IEEE
Trans Ind Electron, vol. 55, pp. 2759-66, 2008.
II. G. Ganesh, G Vijay Kumar, A.R.VijayBabu, G.Srinivasa Rao, Y.R.Tagore,
Performance Analysis and MPPT Control of a Standalone Hybrid Power
Generation System, Journal of Electrical Engineering, Volume 15, Edition: 1, pp.
334-343, 2015.
III. Kavitha, M., et al. “Evaluation of Antimitotic Activity of Mukiamaderaspatana L.
Leaf Extract in Allium cepa Root Model.” International Journal 4.1 (2014): 65-68.
IV. Rao, B. Venkateswara, et al. “Optimal power flow by Newton method for
reduction of operating cost with SVC models.” 2009 International Conference on
Advances in Computing, Control, and Telecommunication Technologies. IEEE,
2009.
V. S. Das, P. K. Sadhu, S. Chakraborty, N. Pal, G. Majumdar, “New Generation Solar
PV Powered Sailing Boat Using Boost Chopper”, TELKOMNIKA Indones. J.
Electr. Eng, vol. 12, no. 12, pp. 8077-8084, 2014.
VI. Y. Li, W. Huang, H. Huang, C. Hewitt, Y. Chen, G. Fang et al., “Evaluation of
methods to extract parameters from current-voltage characteristics of solar
cells”, Sol Energy, vol. 90, pp. 51-7, 2013.
VII. Zegaoui, M. Aillerie, P. Petit, J. P. Sawicki, J. P. Charles, A. W. Belarbi,
“Dynamic behaviour of PV generator trackers under irradiation and
temperature changes”, Solar Energy, vol. 85, pp. 2953-2964, 2011.

 

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