Your search keyword '"Lazaro Alvarado-Barrios"' showing total 29 results

1. Two-Level Optimisation and Control Strategy for Unbalanced Active Distribution Systems Management

Author

Lazaro Alvarado-Barrios, Cesar Alvarez-Arroyo, Juan Manuel Escano, Francisco M. Gonzalez-Longatt, and Jose Luis Martinez-Ramos

Subjects

Distributed generation, active distribution systems, active distribution systems management, economic dispatch, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This article proposes a new approach to the operation of unbalanced Active Distribution Systems (ADS) using an economic dispatch optimisation model for Active Distribution Systems Management (ADSM). The model proposes a two-level control strategy. The first one poses an optimisation problem with the objective of minimising total active power losses in the ADS and the second one proposes an algorithm that controls the position of the taps of three-phase on-load tap-changer (OLTC) transformers to ensure compliance with the technical constraints imposed by the Distribution System Operator (DSO). The optimisation problem is solved by MATLABR and DIgSILENT PowerFactoryR for power systems static simulations. This paper includes a novel peer to peer communication framework between MATLABR/DIgSILENTR. The control and optimisation strategy is validated on the IEEE 34-Node Distribution Test Feeder. This network incorporates balanced and unbalanced three-phase loads, single-phase loads in the different phases, and two-phase loads. In this scientific paper, photovoltaic (PV) and wind power generation (WT) have been integrated to test feeder operation, with the support of battery energy storage systems (BESS). The correct operation of the proposed ADSM is demonstrated using numerical simulation on five scenarios considering several configurations of the renewable generation units and the batteries. The strategy has also been validated in a more extensive distribution network, proving its good performance.

Published

2020

2. Heuristic Methodology for Planning AC Rural Medium-Voltage Distribution Grids

Author

Oscar Danilo Montoya, Federico Martin Serra, Cristian Hernan De Angelo, Harold R. Chamorro, and Lazaro Alvarado-Barrios

Subjects

distribution system planning, tabu search algorithm, minimum spanning tree, heuristic optimization methodology, rural distribution networks, Technology

Abstract

The optimal expansion of AC medium-voltage distribution grids for rural applications is addressed in this study from a heuristic perspective. The optimal routes of a distribution feeder are selected by applying the concept of a minimum spanning tree by limiting the number of branches that are connected to a substation (mixed-integer linear programming formulation). In order to choose the caliber of the conductors for the selected feeder routes, the maximum expected current that is absorbed by the loads is calculated, thereby defining the minimum thermal bound of the conductor caliber. With the topology and the initial selection of the conductors, a tabu search algorithm (TSA) is implemented to refine the solution with the help of a three-phase power flow simulation in MATLAB for three different load conditions, i.e., maximum, medium, and minimum consumption with values of 100%, 60%, and 30%, respectively. This helps in calculating the annual costs of the energy losses that will be summed with the investment cost in conductors for determining the final costs of the planning project. Numerical simulations in two test feeders comprising 9 and 25 nodes with one substation show the effectiveness of the proposed methodology regarding the final grid planning cost; in addition, the heuristic selection of the calibers using the minimum expected current absorbed by the loads provides at least 70% of the calibers that are contained in the final solution of the problem. This demonstrates the importance of using adequate starting points to potentiate metaheuristic optimizers such as the TSA.

Published

2021

3. Accurate and Efficient Derivative-Free Three-Phase Power Flow Method for Unbalanced Distribution Networks

Author

Oscar Danilo Montoya, Juan S. Giraldo, Luis Fernando Grisales-Noreña, Harold R. Chamorro, and Lazaro Alvarado-Barrios

Subjects

banach fixed-point theorem, three-phase power flow formulation, upper-triangular representation, recursive formulation, genetic algorithm, phase-balancing, Electronic computers. Computer science, QA75.5-76.95

Abstract

The power flow problem in three-phase unbalanced distribution networks is addressed in this research using a derivative-free numerical method based on the upper-triangular matrix. The upper-triangular matrix is obtained from the topological connection among nodes of the network (i.e., through a graph-based method). The main advantage of the proposed three-phase power flow method is the possibility of working with single-, two-, and three-phase loads, including Δ- and Y-connections. The Banach fixed-point theorem for loads with Y-connection helps ensure the convergence of the upper-triangular power flow method based an impedance-like equivalent matrix. Numerical results in three-phase systems with 8, 25, and 37 nodes demonstrate the effectiveness and computational efficiency of the proposed three-phase power flow formulation compared to the classical three-phase backward/forward method and the implementation of the power flow problem in the DigSILENT software. Comparisons with the backward/forward method demonstrate that the proposed approach is 47.01%, 47.98%, and 36.96% faster in terms of processing times by employing the same number of iterations as when evaluated in the 8-, 25-, and 37-bus systems, respectively. An application of the Chu-Beasley genetic algorithm using a leader–follower optimization approach is applied to the phase-balancing problem utilizing the proposed power flow in the follower stage. Numerical results present optimal solutions with processing times lower than 5 s, which confirms its applicability in large-scale optimization problems employing embedding master–slave optimization structures.

Published

2021

4. Genetic-Convex Model for Dynamic Reactive Power Compensation in Distribution Networks Using D-STATCOMs

Author

Oscar Danilo Montoya, Harold R. Chamorro, Lazaro Alvarado-Barrios, Walter Gil-González, and César Orozco-Henao

Subjects

annual operational cost minimization, Chu and Beasley genetic algorithm (CBGA), daily active and reactive demand curves, distribution static compensators (D-STATCOMs), radial distribution networks, reactive power compensation, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

This paper proposes a new hybrid master–slave optimization approach to address the problem of the optimal placement and sizing of distribution static compensators (D-STATCOMs) in electrical distribution grids. The optimal location of the D-STATCOMs is identified by implementing the classical and well-known Chu and Beasley genetic algorithm, which employs an integer codification to select the nodes where these will be installed. To determine the optimal sizes of the D-STATCOMs, a second-order cone programming reformulation of the optimal power flow problem is employed with the aim of minimizing the total costs of the daily energy losses. The objective function considered in this study is the minimization of the annual operative costs associated with energy losses and installation investments in D-STATCOMs. This objective function is subject to classical power balance constraints and device capabilities, which generates a mixed-integer nonlinear programming model that is solved with the proposed genetic-convex strategy. Numerical validations in the 33-node test feeder with radial configuration show the proposed genetic-convex model’s effectiveness to minimize the annual operative costs of the grid when compared with the optimization solvers available in GAMS software.

Published

2021

5. The Equivalence between Successive Approximations and Matricial Load Flow Formulations

Author

María Camila Herrera-Briñez, Oscar Danilo Montoya, Lazaro Alvarado-Barrios, and Harold R. Chamorro

Subjects

successive approximations method, matricial backward/forward method, load flow analysis, electrical distribution networks, equivalent formulations, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

This paper shows the equivalence of the matricial form of the classical backward/forward load flow formulation for distribution networks with the recently developed successive approximations (SA) load flow approach. Both formulations allow solving the load flow problem in meshed and radial distribution grids even if these are operated with alternating current (AC) or direct current (DC) technologies. Both load flow methods are completely described in this research to make a fair comparison between them and demonstrate their equivalence. Numerical comparisons in the 33- and 69-bus test feeder with radial topology show that both methods have the same number of iterations to find the solution with a convergence error defined as 1×10−10.

Published

2021

6. A Mixed-Integer Quadratic Formulation of the Phase-Balancing Problem in Residential Microgrids

Author

Alejandro Garces, Walter Gil-González, Oscar Danilo Montoya, Harold R. Chamorro, and Lazaro Alvarado-Barrios

Subjects

phase-balancing, convex approximations, heuristic algorithm, unbalanced power distribution grids, microgrids, combinatorial optimization, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Phase balancing is a classical optimization problem in power distribution grids that involve phase swapping of the loads and generators to reduce power loss. The problem is a non-linear integer and, hence, it is usually solved using heuristic algorithms. This paper proposes a mathematical reformulation that transforms the phase-balancing problem in low-voltage distribution networks into a mixed-integer convex quadratic optimization model. To consider both conventional secondary feeders and microgrids, renewable energies and their subsequent stochastic nature are included in the model. The power flow equations are linearized, and the combinatorial part is represented using a Birkhoff polytope B3 that allows the selection of phase swapping in each node. The numerical experiments on the CIGRE low-voltage test system demonstrate the use of the proposed formulation.

Published

2021

7. Application of the Vortex Search Algorithm to the Phase-Balancing Problem in Distribution Systems

Author

Brandon Cortés-Caicedo, Laura Sofía Avellaneda-Gómez, Oscar Danilo Montoya, Lazaro Alvarado-Barrios, and Harold R. Chamorro

Subjects

load connection, phase-balancing, power loss, three-phase power flow, unbalanced distribution systems, vortex search algorithm, Technology

Abstract

This article discusses the problem of minimizing power loss in unbalanced distribution systems through phase-balancing. This problem is represented by a mixed-integer nonlinear-programming mathematical model, which is solved by applying a discretely encoded Vortex Search Algorithm (DVSA). The numerical results of simulations performed in IEEE 8-, 25-, and 37-node test systems demonstrate the applicability of the proposed methodology when compared with the classical Cuh & Beasley genetic algorithm. In addition, the computation times required by the algorithm to find the optimal solution are in the order of seconds, which makes the proposed DVSA a robust, reliable, and efficient tool. All computational implementations have been developed in the MATLAB® programming environment, and all the results have been evaluated in DigSILENT© software to verify the effectiveness and the proposed three-phase unbalanced power-flow method.

Published

2021

8. Grid Code-Dependent Frequency Control Optimization in Multi-Terminal DC Networks

Author

Melanie Hoffmann, Harold R. Chamorro, Marc René Lotz, José M. Maestre, Kumars Rouzbehi, Francisco Gonzalez-Longatt, Michael Kurrat, Lazaro Alvarado-Barrios, and Vijay K. Sood

Subjects

MTDC, frequency control, fast frequency control, low-inertia, wind power, grid code, Technology

Abstract

The increasing deployment of wind power is reducing inertia in power systems. High-voltage direct current (HVDC) technology can help to improve the stability of AC areas in which a frequency response is required. Moreover, multi-terminal DC (MTDC) networks can be optimized to distribute active power to several AC areas by droop control setting schemes that adjust converter control parameters. To this end, in this paper, particle swarm optimization (PSO) is used to improve the primary frequency response in AC areas considering several grid limitations and constraints. The frequency control uses an optimization process that minimizes the frequency nadir and the settling time in the primary frequency response. Secondly, another layer is proposed for the redistribution of active power among several AC areas, if required, without reserving wind power capacity. This method takes advantage of the MTDC topology and considers the grid code limitations at the same time. Two scenarios are defined to provide grid code-compliant frequency control.

Published

2020

9. Stochastic unit commitment in microgrids: Influence of the load forecasting error and the availability of energy storage

Author

Álvaro Rodríguez del Nozal, Ignacio García Vera, Lazaro Alvarado-Barrios, Juan Boza Valerino, and Jose L. Martinez-Ramos

Subjects

Mathematical optimization, 060102 archaeology, Renewable Energy, Sustainability and the Environment, Computer science, Stochastic modelling, business.industry, 020209 energy, 06 humanities and the arts, 02 engineering and technology, Demand forecasting, 7. Clean energy, Energy storage, Power system simulation, Distributed generation, 0202 electrical engineering, electronic engineering, information engineering, 0601 history and archaeology, Microgrid, Diesel generator, Dispatchable generation, business

Abstract

A Stochastic Model for the Unit Commitment (SUC) problem of a hybrid microgrid for a short period of 24 h is presented. The microgrid considered in the problem is composed of a wind turbine (WT), a photovoltaic plant (PV), a diesel generator (DE), a microturbine (MT) and a Battery Energy Storage System (BESS). The problem is addressed in three stages. First, based on the historical data of the demanded power in the microgrid, an ARMA model is used to obtain the demand prediction. Second, the 24-h-ahead SUC problem is solved, based on generators’ constraints, renewable generation and demand forecast and the statistical distribution of the error in the demand estimation. In this problem, a spinning reserve of the dispatchable units is considered, able to cover the uncertainties in the demand estimation. In the third stage, once the SUC problem has been solved, a case study is established in real time, in which the demand estimation error in every moment is known. Therefore, the objective of this stage is to select the spinning reserve of the units in an optimal way to minimize the cost in the microgrid operation.

Published

2020

10. Heuristic Methodology for Planning AC Rural Medium-Voltage Distribution Grids

Author

Cristian H. De Angelo, Harold R. Chamorro, Oscar Danilo Montoya, Federico Martin Serra, and Lazaro Alvarado-Barrios

Subjects

Technology, Mathematical optimization, Control and Optimization, Heuristic (computer science), Computer science, Energy Engineering and Power Technology, Topology (electrical circuits), Minimum spanning tree, Electrical and Electronic Engineering, MATLAB, Engineering (miscellaneous), Metaheuristic, computer.programming_language, distribution system planning, tabu search algorithm, minimum spanning tree, heuristic optimization methodology, rural distribution networks, LEMB, Renewable Energy, Sustainability and the Environment, Grid, Tabu search, Tabu search algorithm, Heuristic optimization methodology, computer, Distribution system planning, Energy (miscellaneous), Voltage, Rural distribution networks

Abstract

The optimal expansion of AC medium-voltage distribution grids for rural applications is addressed in this study from a heuristic perspective. The optimal routes of a distribution feeder are selected by applying the concept of a minimum spanning tree by limiting the number of branches that are connected to a substation (mixed-integer linear programming formulation). In order to choose the caliber of the conductors for the selected feeder routes, the maximum expected current that is absorbed by the loads is calculated, thereby defining the minimum thermal bound of the conductor caliber. With the topology and the initial selection of the conductors, a tabu search algorithm (TSA) is implemented to refine the solution with the help of a three-phase power flow simulation in MATLAB for three different load conditions, i.e., maximum, medium, and minimum consumption with values of 100%, 60%, and 30%, respectively. This helps in calculating the annual costs of the energy losses that will be summed with the investment cost in conductors for determining the final costs of the planning project. Numerical simulations in two test feeders comprising 9 and 25 nodes with one substation show the effectiveness of the proposed methodology regarding the final grid planning cost; in addition, the heuristic selection of the calibers using the minimum expected current absorbed by the loads provides at least 70% of the calibers that are contained in the final solution of the problem. This demonstrates the importance of using adequate starting points to potentiate metaheuristic optimizers such as the TSA.

Published

2021

11. An improved crow search algorithm applied to the phase swapping problem in asymmetric distribution systems

Author

Oscar Danilo Montoya, Brandon Cortés-Caicedo, Laura Sofía Avellaneda-Gómez, Cesar Alvarez-Arroyo, Lazaro Alvarado-Barrios, and Universidad de Sevilla. Departamento de Ingeniería Eléctrica

Subjects

phase swapping problem, Physics and Astronomy (miscellaneous), Computer science, 020209 energy, General Mathematics, Gaussian, 02 engineering and technology, Nonlinear programming, Electric power system, symbols.namesake, Search algorithm, Genetic algorithm, power losses, asymmetric distribution grids, QA1-939, 0202 electrical engineering, electronic engineering, information engineering, Computer Science (miscellaneous), improved crow search algorithm, normal Gaussian distribution, vortex search algorithm, MATLAB, computer.programming_language, Normal Gaussian distribution, LEMB, Vortex search algorithm, Phase swapping problem, Improved crow search algorithm, Power (physics), Chemistry (miscellaneous), symbols, Probability distribution, 020201 artificial intelligence & image processing, Asymmetric distribution grids, Power losses, computer, Algorithm, Mathematics

Abstract

Article number 1329 This paper discusses the power loss minimization problem in asymmetric distribution systems (ADS) based on phase swapping. This problem is presented using a mixed-integer nonlinear programming model, which is resolved by applying a master-slave methodology. The master stage consists of an improved version of the crow search algorithm. This stage is based on the generation of candidate solutions using a normal Gaussian probability distribution. The master stage is responsible for providing the connection settings for the system loads using integer coding. The slave stage uses a power flow for ADSs based on the three-phase version of the iterative sweep method, which is used to determine the network power losses for each load connection supplied by the master stage. Numerical results on the 8-, 25-, and 37-node test systems show the efficiency of the proposed approach when compared to the classical version of the crow search algorithm, the Chu and Beasley genetic algorithm, and the vortex search algorithm. All simulations were obtained using MATLAB and validated in the DigSILENT power system analysis software. Centro de Investigación y Desarrollo Científico de la Universidad Distrital Francisco José de Caldas 1643-12-2020 Dirección de Investigaciones de la Universidad Tecnológica de Bolívar PS2020002

Published

2021

12. Accurate and Efficient Derivative-Free Three-Phase Power Flow Method for Unbalanced Distribution Networks

Author

Luis Fernando Grisales-Noreña, Oscar Danilo Montoya, Juan S. Giraldo, Lazaro Alvarado-Barrios, Harold R. Chamorro, and Mathematics of Operations Research

Subjects

Optimization problem, General Computer Science, Computer science, 020209 energy, phase balancing, 02 engineering and technology, Topology, three-phase power flow formulation, Theoretical Computer Science, three-phase power flow, Matrix (mathematics), upper-triangular representation, Banach fixed-point theorem, Convergence (routing), Genetic algorithm, 0202 electrical engineering, electronic engineering, information engineering, phase-balancing, Upper-triangular representation, LEMB, Applied Mathematics, Numerical analysis, 020208 electrical & electronic engineering, Phase-balancing, upper triangular representation, QA75.5-76.95, Three-phase, Three-phase power flow formulation, Modeling and Simulation, Electronic computers. Computer science, Embedding, recursive formulation, Recursive formulation

Abstract

The power flow problem in three-phase unbalanced distribution networks is addressed in this research using a derivative-free numerical method based on the upper-triangular matrix. The upper-triangular matrix is obtained from the topological connection among nodes of the network (i.e., through a graph-based method). The main advantage of the proposed three-phase power flow method is the possibility of working with single-, two-, and three-phase loads, including Δ- and Y-connections. The Banach fixed-point theorem for loads with Y-connection helps ensure the convergence of the upper-triangular power flow method based an impedance-like equivalent matrix. Numerical results in three-phase systems with 8, 25, and 37 nodes demonstrate the effectiveness and computational efficiency of the proposed three-phase power flow formulation compared to the classical three-phase backward/forward method and the implementation of the power flow problem in the DigSILENT software. Comparisons with the backward/forward method demonstrate that the proposed approach is 47.01%, 47.98%, and 36.96% faster in terms of processing times by employing the same number of iterations as when evaluated in the 8-, 25-, and 37-bus systems, respectively. An application of the Chu-Beasley genetic algorithm using a leader–follower optimization approach is applied to the phase-balancing problem utilizing the proposed power flow in the follower stage. Numerical results present optimal solutions with processing times lower than 5 s, which confirms its applicability in large-scale optimization problems employing embedding master–slave optimization structures.

Published

2021

13. Reduction of Losses and Operating Costs in Distribution Networks Using a Genetic Algorithm and Mathematical Optimization

Author

Fabio Edison Riaño, Harold R. Chamorro, Oscar Danilo Montoya, Jonathan Felipe Cruz, and Lazaro Alvarado-Barrios

Subjects

Mathematical optimization, Optimization problem, Combinatorial optimization, Computer Networks and Communications, Computer science, 020209 energy, lcsh:TK7800-8360, 02 engineering and technology, fixed-step capacitor banks, Reduction (complexity), Genetic algorithm, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Algebraic number, Metaheuristic, Chu and Beasley genetic algorithm, Operative costs minimization, operative costs minimization, LEMB, 020208 electrical & electronic engineering, lcsh:Electronics, Nonlinear system, Hardware and Architecture, Control and Systems Engineering, Signal Processing, Discrete codification, Fixed-step capacitor banks, combinatorial optimization, discrete codification

Abstract

This study deals with the minimization of the operational and investment cost in the distribution and operation of the power flow considering the installation of fixed-step capacitor banks. This issue is represented by a nonlinear mixed-integer programming mathematical model which is solved by applying the Chu and Beasley genetic algorithm (CBGA). While this algorithm is a classical method for resolving this type of optimization problem, the solutions found using this approach are better than those reported in the literature using metaheuristic techniques and the General Algebraic Modeling System (GAMS). In addition, the time required for the CBGA to get results was reduced to a few seconds to make it a more robust, efficient, and capable tool for distribution system analysis. Finally, the computational sources used in this study were developed in the MATLAB programming environment by implementing test feeders composed of 10, 33, and 69 nodes with radial and meshed configurations. Universidad Tecnológica de Bolívar

Published

2021

14. Application of the Vortex Search Algorithm to the Phase-Balancing Problem in Distribution Systems

Author

Lazaro Alvarado-Barrios, Laura Sofía Avellaneda-Gómez, Oscar Danilo Montoya, Harold R. Chamorro, and Brandon Cortés-Caicedo

Subjects

Control and Optimization, Computer science, 020209 energy, Computation, Energy Engineering and Power Technology, 02 engineering and technology, lcsh:Technology, Distribution system, three-phase power flow, Search algorithm, Genetic algorithm, 0202 electrical engineering, electronic engineering, information engineering, phase-balancing, Unbalanced distribution systems, Electrical and Electronic Engineering, Power loss, Engineering (miscellaneous), unbalanced distribution systems, LEMB, Renewable Energy, Sustainability and the Environment, Phase balancing, lcsh:T, 020208 electrical & electronic engineering, Phase-balancing, Vortex search algorithm, Load connection, Vortex, power loss, load connection, vortex search algorithm, Three-phase power flow, Algorithm, Energy (miscellaneous)

Abstract

This article discusses the problem of minimizing power loss in unbalanced distribution systems through phase-balancing. This problem is represented by a mixed-integer nonlinear-programming mathematical model, which is solved by applying a discretely encoded Vortex Search Algorithm (DVSA). The numerical results of simulations performed in IEEE 8-, 25-, and 37-node test systems demonstrate the applicability of the proposed methodology when compared with the classical Cuh & Beasley genetic algorithm. In addition, the computation times required by the algorithm to find the optimal solution are in the order of seconds, which makes the proposed DVSA a robust, reliable, and efficient tool. All computational implementations have been developed in the MATLAB® programming environment, and all the results have been evaluated in DigSILENT© software to verify the effectiveness and the proposed three-phase unbalanced power-flow method. View Full-Text Universidad Tecnológica de Bolívar

Published

2021

15. Data-Driven Trajectory Prediction of Grid Power Frequency Based on Neural Models

Author

Vijay K. Sood, Wilmar Martinez, Alvaro D. Orjuela-Cañón, David Ganger, Harold R. Chamorro, Lazaro Alvarado-Barrios, Francisco Gonzalez-Longatt, and Mattias Persson

Subjects

Frequency response, Computer Networks and Communications, Computer science, 020209 energy, non-synchronous generation, lcsh:TK7800-8360, 02 engineering and technology, primary frequency control, nadir estimation, Electric power system, Robustness (computer science), Control theory, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Wind power, business.industry, 020208 electrical & electronic engineering, lcsh:Electronics, deep learning, wind power, Phasor measurement unit, low-inertia power systems, machine learning, Hardware and Architecture, Control and Systems Engineering, Signal Processing, frequency response, business

Abstract

Frequency in power systems is a real-time information that shows the balance between generation and demand. Good system frequency observation is vital for system security and protection. This paper analyses the system frequency response following disturbances and proposes a data-driven approach for predicting it by using machine learning techniques like Nonlinear Auto-regressive (NAR) Neural Networks (NN) and Long Short Term Memory (LSTM) networks from simulated and measured Phasor Measurement Unit (PMU) data. The proposed method uses a horizon-window that reconstructs the frequency input time-series data in order to predict the frequency features such as Nadir. Simulated scenarios are based on the gradual inertia reduction by including non-synchronous generation into the Nordic 32 test system, whereas the PMU collected data is taken from different locations in the Nordic Power System (NPS). Several horizon-windows are experimented in order to observe an adequate margin of prediction. Scenarios considering noisy signals are also evaluated in order to provide a robustness index of predictability. Results show the proper performance of the method and the adequate level of prediction based on the Root Mean Squared Error (RMSE) index. article-number: 151 ispartof: Electronics vol:10 issue:2 status: Published online

Published

2021

16. On the Optimal Selection and Integration of Batteries in DC Grids through a Mixed-Integer Quadratic Convex Formulation

Author

Lazaro Alvarado-Barrios, Harold R. Chamorro, Oscar Danilo Montoya, Federico Martin Serra, Cesar Alvarez-Arroyo, Universidad de Sevilla. Departamento de Ingeniería Eléctrica, and Universidad Tecnológica de Bolívar

Subjects

Battery energy storage systems, Mathematical optimization, TK7800-8360, Computer Networks and Communications, Computer science, MathematicsofComputing_NUMERICALANALYSIS, Global optimum finding, Power flow approximation, Quadratic equation, mixed-integer quadratic programming, Exact mathematical optimization, Quadratic programming, Electrical and Electronic Engineering, Mixed-integer quadratic programming, LEMB, power flow approximation, exact mathematical optimization, global optimum finding, Distribution (mathematics), Hyperplane, Hardware and Architecture, Control and Systems Engineering, Signal Processing, Convex optimization, Node (circuits), Minification, Electronics, battery energy storage systems, Integer (computer science)

Abstract

This paper deals with the problem of the optimal selection and location of batteries in DC distribution grids by proposing a new mixed-integer convex model. The exact mixed-integer nonlinear model is transformed into a mixed-integer quadratic convex model (MIQC) by approximating the product among voltages in the power balance equations as a hyperplane. The most important characteristic of our proposal is that the MIQC formulations ensure the global optimum reaching via branch &amp, bound methods and quadratic programming since each combination of the binary variables generates a node with a convex optimization subproblem. The formulation of the objective function is associated with the minimization of the energy losses for a daily operation scenario considering high renewable energy penetration. Numerical simulations show the effectiveness of the proposed MIQC model to reach the global optimum of the optimization model when compared with the exact optimization model in a 21-node test feeder. All the validations are carried out in the GAMS optimization software.

Published

2021

17. A hybrid approach based on socp and the discrete version of the sca for optimal placement and sizing dgs in ac distribution networks

Author

Oscar Danilo Montoya, Alexander Molina-Cabrera, Edwin Rivas-Trujillo, Lazaro Alvarado-Barrios, and Harold R. Chamorro

Subjects

Mathematical optimization, Discrete-sine cosine algorithm, Computer Networks and Communications, Computer science, 020209 energy, lcsh:TK7800-8360, 02 engineering and technology, Power factor, Nonlinear programming, Mixed-integer nonlinear programming, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, LEMB, business.industry, lcsh:Electronics, 020208 electrical & electronic engineering, Sizing, Second-cone programming, Variable (computer science), Global optimum, Hardware and Architecture, Control and Systems Engineering, Distributed generation, Signal Processing, Convex optimization, business, Metaheuristic optimization, Optimal power flow, Integer (computer science)

Abstract

This paper deals with the problem of the optimal placement and sizing of distributed generators (DGs) in alternating current (AC) distribution networks by proposing a hybrid master&ndash, slave optimization procedure. In the master stage, the discrete version of the sine&ndash, cosine algorithm (SCA) determines the optimal location of the DGs, i.e., the nodes where these must be located, by using an integer codification. In the slave stage, the problem of the optimal sizing of the DGs is solved through the implementation of the second-order cone programming (SOCP) equivalent model to obtain solutions for the resulting optimal power flow problem. As the main advantage, the proposed approach allows converting the original mixed-integer nonlinear programming formulation into a mixed-integer SOCP equivalent. That is, each combination of nodes provided by the master level SCA algorithm to locate distributed generators brings an optimal solution in terms of its sizing, since SOCP is a convex optimization model that ensures the global optimum finding. Numerical validations of the proposed hybrid SCA-SOCP to optimal placement and sizing of DGs in AC distribution networks show its capacity to find global optimal solutions. Some classical distribution networks (33 and 69 nodes) were tested, and some comparisons were made using reported results from literature. In addition, simulation cases with unity and variable power factor are made, including the possibility of locating photovoltaic sources considering daily load and generation curves. All the simulations were carried out in the MATLAB software using the CVX optimization tool.

Published

2020

18. Grid Code-Dependent Frequency Control Optimization in Multi-Terminal DC Networks

Author

Kumars Rouzbehi, José M. Maestre, Lazaro Alvarado-Barrios, Vijay K. Sood, Melanie Hoffmann, Marc Rene Lotz, Francisco Gonzalez-Longatt, Harold R. Chamorro, Michael Kurrat, Universidad de Sevilla. Departamento de Ingeniería de Sistemas y Automática, Australian Education International, Australian Government, and Ministerio de Economía y Competitividad (MINECO). España

Subjects

Frequency response, Control and Optimization, Settling time, Computer science, 020209 energy, Automatic frequency control, Grid code, Energy Engineering and Power Technology, 02 engineering and technology, Non-synchronous generation, lcsh:Technology, low-inertia, Electric power system, frequency control, Control theory, 0202 electrical engineering, electronic engineering, information engineering, grid code, Voltage droop, MTDC, Electrical and Electronic Engineering, Engineering (miscellaneous), fast frequency control, wind power, non-synchronous generation, python-PSCAD-interface, particle swarm optimization, Wind power, Renewable Energy, Sustainability and the Environment, business.industry, lcsh:T, Particle swarm optimization, 020208 electrical & electronic engineering, Direct current, AC power, Grid, Frequency control, Low-inertia, business, Energy (miscellaneous)

Abstract

The increasing deployment of wind power is reducing inertia in power systems. High-voltage direct current (HVDC) technology can help to improve the stability of AC areas in which a frequency response is required. Moreover, multi-terminal DC (MTDC) networks can be optimized to distribute active power to several AC areas by droop control setting schemes that adjust converter control parameters. To this end, in this paper, particle swarm optimization (PSO) is used to improve the primary frequency response in AC areas considering several grid limitations and constraints. The frequency control uses an optimization process that minimizes the frequency nadir and the settling time in the primary frequency response. Secondly, another layer is proposed for the redistribution of active power among several AC areas, if required, without reserving wind power capacity. This method takes advantage of the MTDC topology and considers the grid code limitations at the same time. Two scenarios are defined to provide grid code-compliant frequency control. Australian Education International, Australian Government TEC2016-80242-P Ministerio de Economía y Competitividad DPI2016-75294-C2-2-R

Published

2020

19. A Multi-Platform Lab for Teaching and Research in Active Distribution Networks

Author

Antonio Gomez-Exposito, Manuel Barragán-Villarejo, Juan Jimenez, Francisco de Paula García-López, Juan Manuel Mauricio, Jose Maria Maza-Ortega, and Lazaro Alvarado-Barrios

Subjects

Engineering, Distribution networks, business.industry, 020209 energy, Control (management), GRASP, Energy Engineering and Power Technology, 02 engineering and technology, Smart grid, Distributed generation, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Systems engineering, Electricity, Power engineering, Electrical and Electronic Engineering, business, Curriculum

Abstract

Today's electricity paradigm requires that the notion of active distribution systems be introduced at both undergraduate and graduate curricula. This involves not only the customary theoretical foundations but also a suitable power engineering laboratory, where flexible enough and affordable resources allow students and researchers to carry out hands-on experiments reinforcing the concepts explained in the classroom. This paper describes the smart grid laboratory of the Power Engineering Group at the University of Seville, composed of a scaled-down distribution system, along with the required control and monitoring equipment, designed to help its users easily grasp the major influence that distributed generation and storage devices exert in the operation of medium-voltage distribution systems.

Published

2017

20. Application of Genetic Algorithms for Unit Commitment and Economic Dispatch Problems in Microgrids

Author

Lazaro Alvarado-Barrios, A. Tapia, A. Rodríguez del Nozal, and Daniel Gutiérrez Reina

Subjects

Electric power system, Mathematical optimization, Power system simulation, business.industry, Computer science, Robustness (computer science), Distributed generation, Genetic algorithm, Control variable, Economic dispatch, business, Power (physics)

Abstract

In the last decades, new types of generation technologies have emerged and have been gradually integrated into the existing power systems, moving their classical architectures to distributed systems. In spite of the positive features associated to this paradigm, new problems arise such as coordination and uncertainty. In this framework, microgrids (MGs) constitute an effective solution to deal with the coordination and operation of these distributed energy resources. This book chapter proposes a Genetic Algorithm (GA) to address the combined problem of Unit Commitment (UC) and Economic Dispatch (ED). With this end, a detailed model of a MG is introduced together with all the control variables and power restrictions. In order to optimally operate the MG, two operation modes are introduced, which attend to optimize economical factors and the robustness of the solution with respect power demand uncertainty. Therefore, it achieves a robust design that guarantees the power supply for different confidence levels. Finally, the algorithm is applied to an example scenario to illustrate its performance.

Published

2019

21. Genetic-Convex Model for Dynamic Reactive Power Compensation in Distribution Networks Using D-STATCOMs

Author

Walter Gil-González, Lazaro Alvarado-Barrios, Oscar Danilo Montoya, C. Orozco-Henao, and Harold R. Chamorro

Subjects

Mathematical optimization, reactive power compensation, Computer science, 020209 energy, Reactive power compensation, 02 engineering and technology, lcsh:Technology, Nonlinear programming, lcsh:Chemistry, daily active and reactive demand curves, Distribution static compensators (D-STATCOMs), Daily active and reactive demand curves, Chu and Beasley genetic algorithm (CBGA), Power Balance, Genetic algorithm, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Annual operational cost minimization, annual operational cost minimization, lcsh:QH301-705.5, Instrumentation, Fluid Flow and Transfer Processes, lcsh:T, Process Chemistry and Technology, Radial distribution networks, radial distribution networks, 020208 electrical & electronic engineering, General Engineering, distribution static compensators (D-STATCOMs), AC power, Grid, lcsh:QC1-999, Sizing, Computer Science Applications, lcsh:Biology (General), lcsh:QD1-999, lcsh:TA1-2040, Minification, lcsh:Engineering (General). Civil engineering (General), lcsh:Physics, Integer (computer science)

Abstract

This paper proposes a new hybrid master–slave optimization approach to address the problem of the optimal placement and sizing of distribution static compensators (D-STATCOMs) in electrical distribution grids. The optimal location of the D-STATCOMs is identified by implementing the classical and well-known Chu and Beasley genetic algorithm, which employs an integer codification to select the nodes where these will be installed. To determine the optimal sizes of the D-STATCOMs, a second-order cone programming reformulation of the optimal power flow problem is employed with the aim of minimizing the total costs of the daily energy losses. The objective function considered in this study is the minimization of the annual operative costs associated with energy losses and installation investments in D-STATCOMs. This objective function is subject to classical power balance constraints and device capabilities, which generates a mixed-integer nonlinear programming model that is solved with the proposed genetic-convex strategy. Numerical validations in the 33-node test feeder with radial configuration show the proposed genetic-convex model’s effectiveness to minimize the annual operative costs of the grid when compared with the optimization solvers available in GAMS software. Universidad Tecnológica de Bolívar

Published

2021

22. The Equivalence between Successive Approximations and Matricial Load Flow Formulations

Author

Oscar Danilo Montoya, María Camila Herrera-Briñez, Harold R. Chamorro, and Lazaro Alvarado-Barrios

Subjects

Successive approximations method, 020209 energy, Equivalent formulations, Topology (electrical circuits), Electrical distribution networks, 02 engineering and technology, lcsh:Technology, load flow analysis, law.invention, lcsh:Chemistry, electrical distribution networks, law, matricial backward/forward method, Convergence (routing), 0202 electrical engineering, electronic engineering, information engineering, Applied mathematics, General Materials Science, Power-flow study, lcsh:QH301-705.5, Instrumentation, Equivalence (measure theory), Mathematics, Fluid Flow and Transfer Processes, LEMB, lcsh:T, equivalent formulations, Process Chemistry and Technology, 020208 electrical & electronic engineering, Direct current, General Engineering, Load flow analysis, successive approximations method, lcsh:QC1-999, Computer Science Applications, lcsh:Biology (General), lcsh:QD1-999, Flow (mathematics), lcsh:TA1-2040, Shaping, lcsh:Engineering (General). Civil engineering (General), Matricial backward/forward method, Alternating current, lcsh:Physics

Abstract

This paper shows the equivalence of the matricial form of the classical backward/forward load flow formulation for distribution networks with the recently developed successive approximations (SA) load flow approach. Both formulations allow solving the load flow problem in meshed and radial distribution grids even if these are operated with alternating current (AC) or direct current (DC) technologies. Both load flow methods are completely described in this research to make a fair comparison between them and demonstrate their equivalence. Numerical comparisons in the 33- and 69-bus test feeder with radial topology show that both methods have the same number of iterations to find the solution with a convergence error defined as 1×10−10.

Published

2021

23. A Mixed-Integer Quadratic Formulation of the Phase-Balancing Problem in Residential Microgrids

Author

Oscar Danilo Montoya, Alejandro Garces, Lazaro Alvarado-Barrios, Harold R. Chamorro, and Walter Gil-González

Subjects

Mathematical optimization, Optimization problem, Computer science, Heuristic (computer science), microgrids, 020209 energy, 0211 other engineering and technologies, 02 engineering and technology, lcsh:Technology, lcsh:Chemistry, Quadratic equation, 0202 electrical engineering, electronic engineering, information engineering, heuristic algorithm, phase-balancing, General Materials Science, unbalanced power distribution grids, lcsh:QH301-705.5, Instrumentation, convex approximations, Fluid Flow and Transfer Processes, 021103 operations research, Birkhoff polytope, lcsh:T, Process Chemistry and Technology, General Engineering, lcsh:QC1-999, Computer Science Applications, Power (physics), lcsh:Biology (General), lcsh:QD1-999, lcsh:TA1-2040, Combinatorial optimization, combinatorial optimization, Node (circuits), lcsh:Engineering (General). Civil engineering (General), lcsh:Physics, Integer (computer science)

Abstract

Phase balancing is a classical optimization problem in power distribution grids that involve phase swapping of the loads and generators to reduce power loss. The problem is a non-linear integer and, hence, it is usually solved using heuristic algorithms. This paper proposes a mathematical reformulation that transforms the phase-balancing problem in low-voltage distribution networks into a mixed-integer convex quadratic optimization model. To consider both conventional secondary feeders and microgrids, renewable energies and their subsequent stochastic nature are included in the model. The power flow equations are linearized, and the combinatorial part is represented using a Birkhoff polytope B3 that allows the selection of phase swapping in each node. The numerical experiments on the CIGRE low-voltage test system demonstrate the use of the proposed formulation.

Published

2021

24. Dynamic optimisation of unbalanced distribution network management by model predictive control with Markov reward processes

Author

César Álvarez-Arroyo, Salvatore Vergine, Guglielmo D'Amico, Juan Manuel Escaño, and Lázaro Alvarado-Barrios

Subjects

Model predictive control, Economic dispatch, Distributed generation, Renewable energy sources, Markov process, Uncertainty, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

In this work, a two-level control system is used to minimize the total active power losses of an active distribution system connected to the external grid and composed of a wind turbine, two photovoltaic power sources, and two batteries. At the first control level, a model-based predictive control (MPC) is run, using non-homogeneous Markov reward models for wind power prediction and homogeneous Markov reward models for photovoltaic power. At the second level, an algorithm is run for optimal management of voltage control assets, such as voltage regulating transformers, to minimize losses. Different scenarios have been considered, highlighting the advantages of using an MPC framework. This results in an optimization process that can be influenced by different time horizons depending on whether or not the MPC is applied. The predictions allow considering a long-horizon stepwise optimization process that leads to an increasing number of variables along with the decrease of total active power losses. When the MPC is not applied, a short-horizon analysis is performed with a decrease in both the number of variables and the quality of the results. Different cases are considered in which the nominal power of a photovoltaic unit and the battery capacity are modified.

Published

2024

25. A MPC Strategy for the Optimal Management of Microgrids Based on Evolutionary Optimization

Author

Lazaro Alvarado-Barrios, Álvaro Rodríguez del Nozal, Juan Manuel Escaño, A. Tapia, Daniel Gutiérrez Reina, Universidad de Sevilla. Departamento de Ingeniería Eléctrica, Universidad de Sevilla. Departamento de Ingeniería Electrónica, and Universidad de Sevilla. Departamento de Ingeniería de Sistemas y Automática

Subjects

Mathematical optimization, Optimization problem, Microgrid, model predictive control, Computer Networks and Communications, Computer science, 020209 energy, lcsh:TK7800-8360, 02 engineering and technology, Diesel engine, evolutionary optimization, Turbine, Energy storage, Genetic algorithm, genetic algorithm, 0202 electrical engineering, electronic engineering, information engineering, Model predictive control, Electrical and Electronic Engineering, lcsh:Electronics, 020208 electrical & electronic engineering, Photovoltaic system, Evolutionary optimization, microgrid, Hardware and Architecture, Control and Systems Engineering, Signal Processing, Evolution strategy

Abstract

In this paper, a novel model predictive control strategy, with a 24-h prediction horizon, is proposed to reduce the operational cost of microgrids. To overcome the complexity of the optimization problems arising from the operation of the microgrid at each step, an adaptive evolutionary strategy with a satisfactory trade-off between exploration and exploitation capabilities was added to the model predictive control. The proposed strategy was evaluated using a representative microgrid that includes a wind turbine, a photovoltaic plant, a microturbine, a diesel engine, and an energy storage system. The achieved results demonstrate the validity of the proposed approach, outperforming a global scheduling planner-based on a genetic algorithm by 14.2% in terms of operational cost. In addition, the proposed approach also better manages the use of the energy storage system. Ministerio de Economía y Competitividad DPI2016-75294-C2-2-R Unión Europea (Programa Horizonte 2020) 764090

Published

2019

26. Optimal management of a hybrid and isolated microgrid in a random setting

Author

Salvatore Vergine, César Álvarez-Arroyo, Guglielmo D’Amico, Juan Manuel Escaño, and Lázaro Alvarado-Barrios

Subjects

Microgrids, Economic dispatch, Unit commitment, Renewable energy sources, Uncertainty, Markov process, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Nowadays, governments and electricity companies are making efforts to increase the integration of renewable energy sources into grids and microgrids, thus reducing the carbon footprint and increasing social welfare. Therefore, one of the purposes of the microgrid is to distribute and exploit more zero emission sources. In this work, a Stochastic Unit Commitment of a hybrid and isolated microgrid is developed. The microgrid supplies power to satisfy the demand response by managing a photovoltaic plant, a wind turbine, a microturbine, a diesel generator and a battery storage system. The optimization problem aims to reduce the operating cost of the microgrid and is divided into three stages. In the first stage, the uncertainties of the wind and photovoltaic powers are modeled through Markov processes, and the demand power is predicted using an ARMA model. In the second stage, the stochastic unit commitment is solved by considering the system constraints, the renewable power production, and the predicted demand. In the last stage, the real-time operation of the microgrid is modeled, and the error in the demand forecast is calculated. At this point, the second optimization problem is solved to decide which generators must supply the demand variation to minimize the total cost. The results indicate that the stochastic models accurately simulate the production of renewable energy, which strongly influences the total cost paid by the microgrid. Wind production has a daily impact on total cost, whereas photovoltaic production has a smoother impact, shown in terms of general trend. A comparison study is also considered to emphasize the importance of correctly modeling the uncertainties of renewable power production in this context.

Published

2022

27. Control strategy for a mid-size wind energy convertion system

Author

Lazaro Alvarado-Barrios, Jose Maria Maza-Ortega, Antonio Gomez-Exposito, and Juan Manuel Mauricio

Subjects

Engineering, Wind power, Control theory, business.industry, Control system, Feedback linearization, AC power, Nonlinear control, business, DC-BUS, Machine control

Abstract

A control strategy for a mid-size Permanent Magnet Synchronous Machine (PMSM) based Wind Energy Conversion System (WECS) operating under unbalanced voltages and currents is presented in this paper. The analyzed WECS is based on a PMSM connected through a non-controlled rectifier to the DC-bus. This paper proposes a new control strategy for improving the wind energy conversion efficiency based on the DC voltage regulation. In addition, in order to eliminate over-currents risk during unbalanced conditions, a control scheme has been designed to independently control positive and negative sequence currents. The proposed controller is based on the feedback linearization technique and shows an improvement in the system performance regarding 2ω ripple elimination in the DC voltage arising during AC-side imbalances and an accurate and decoupled active and reactive power tracking.

Published

2010

28. Efficient Reduction in the Annual Investment Costs in AC Distribution Networks via Optimal Integration of Solar PV Sources Using the Newton Metaheuristic Algorithm

Author

Oscar Danilo Montoya, Luis Fernando Grisales-Noreña, Lázaro Alvarado-Barrios, Andres Arias-Londoño, and Cesar Álvarez-Arroyo

Subjects

placement and sizing of PV generation, AC distribution networks, Newton metaheuristic algorithm, radial distribution networks, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

This research addresses the problem of the optimal placement and sizing of (PV) sources in medium voltage distribution grids through the application of the recently developed Newton metaheuristic optimization algorithm (NMA). The studied problem is formulated through a mixed-integer nonlinear programming model where the binary variables regard the installation of a PV source in a particular node, and the continuous variables are associated with power generations as well as the voltage magnitudes and angles, among others. To improve the performance of the NMA, we propose the implementation of a discrete–continuous codification where the discrete component deals with the location problem and the continuous component works with the sizing problem of the PV sources. The main advantage of the NMA is that it works based on the first and second derivatives of the fitness function considering an evolution formula that contains its current solution (xit) and the best current solution (xbest), where the former one allows location exploitation and the latter allows the global exploration of the solution space. To evaluate the fitness function and its derivatives, the successive approximation power flow method was implemented, which became the proposed solution strategy in a master–slave optimizer, where the master stage is governed by the NMA and the slave stage corresponds to the power flow method. Numerical results in the IEEE 34- and IEEE 85-bus systems show the effectiveness of the proposed optimization approach to minimize the total annual operative costs of the network when compared to the classical Chu and Beasley genetic algorithm and the MINLP solvers available in the general algebraic modeling system with reductions of 26.89% and 27.60% for each test feeder with respect to the benchmark cases.

Published

2021

29. An Improved Crow Search Algorithm Applied to the Phase Swapping Problem in Asymmetric Distribution Systems

Author

Brandon Cortés-Caicedo, Laura Sofía Avellaneda-Gómez, Oscar Danilo Montoya, Lázaro Alvarado-Barrios, and César Álvarez-Arroyo

Subjects

improved crow search algorithm, normal Gaussian distribution, phase swapping problem, power losses, asymmetric distribution grids, vortex search algorithm, Mathematics, QA1-939

Abstract

This paper discusses the power loss minimization problem in asymmetric distribution systems (ADS) based on phase swapping. This problem is presented using a mixed-integer nonlinear programming model, which is resolved by applying a master–slave methodology. The master stage consists of an improved version of the crow search algorithm. This stage is based on the generation of candidate solutions using a normal Gaussian probability distribution. The master stage is responsible for providing the connection settings for the system loads using integer coding. The slave stage uses a power flow for ADSs based on the three-phase version of the iterative sweep method, which is used to determine the network power losses for each load connection supplied by the master stage. Numerical results on the 8-, 25-, and 37-node test systems show the efficiency of the proposed approach when compared to the classical version of the crow search algorithm, the Chu and Beasley genetic algorithm, and the vortex search algorithm. All simulations were obtained using MATLAB and validated in the DigSILENT power system analysis software.

Published

2021