Your search keyword '"graphical user interface software"' showing total 7 results

1. Industry Experience of Developing Day-Ahead Photovoltaic Plant Forecasting System Based on Machine Learning

Author

Alexandra I. Khalyasmaa, Stanislav A. Eroshenko, Valeriy A. Tashchilin, Hariprakash Ramachandran, Teja Piepur Chakravarthi, and Denis N. Butusov

Subjects

feature engineering, forecasting, graphical user interface software, machine learning, photovoltaic power plant, Science

Abstract

This article highlights the industry experience of the development and practical implementation of a short-term photovoltaic forecasting system based on machine learning methods for a real industry-scale photovoltaic power plant implemented in a Russian power system using remote data acquisition. One of the goals of the study is to improve photovoltaic power plants generation forecasting accuracy based on open-source meteorological data, which is provided in regular weather forecasts. In order to improve the robustness of the system in terms of the forecasting accuracy, we apply newly derived feature introduction, a factor obtained as a result of feature engineering procedure, characterizing the relationship between photovoltaic power plant energy production and solar irradiation on a horizontal surface, thus taking into account the impacts of atmospheric and electrical nature. The article scrutinizes the application of different machine learning algorithms, including Random Forest regressor, Gradient Boosting Regressor, Linear Regression and Decision Trees regression, to the remotely obtained data. As a result of the application of the aforementioned approaches together with hyperparameters, tuning and pipelining of the algorithms, the optimal structure, parameters and the application sphere of different regressors were identified for various testing samples. The mathematical model developed within the framework of the study gave us the opportunity to provide robust photovoltaic energy forecasting results with mean accuracy over 92% for mostly-sunny sample days and over 83% for mostly cloudy days with different types of precipitation.

Published

2020

2. Wheatstone Bridge - The Basic Circuit for Strain Gauge Force Transducers

Author

Ştefănescu, Dan Mihai and Ştefănescu, Dan Mihai

Published

2011

3. Assessment of Renewable Energy Resources with Remote Sensing.

Author

Martins, Fernando Ramos and Martins, Fernando Ramos

Subjects

Research & information: general, Baltic area, CSP plants, GES-CAL software, Hazaki Oceanographical Research Station, artificial neural networks, climate, cloud, cloud coverage, cloud detection, coastal wind measurements, coastline, computational design method, convection, data processing, digitized image processing, electrical resistivity tomography, extreme value analysis, feature engineering, feature importance, forecasting, geophysical prospecting, geothermal energy, global radiation, graphical user interface software, hydropower reservoir, image processing, lake breeze influence, light gradient boosting machine, machine learning, machine learning techniques, metaheuristic, multistep-ahead prediction, parameter extraction, passive design strategy, photovoltaic power plant, plan position indicator, point cloud data, potential well field location, remote sensing, remote sensing data acquisition, renewable energy resource assessment and forecasting, satellite, scanning LiDAR, scatterometer, shading envelopes, sky camera, smart island, solar energy, solar energy resource, solar irradiance enhancement, solar irradiance estimation, solar irradiance forecasting, solar photovoltaic, solar radiation forecasting, statistical analysis, surface solar radiation, time domain electromagnetic method, total sky imagery, velocity volume processing, voxel-design approach, whale optimization algorithm, wind speed

Abstract

Summary: The book "Assessment of Renewable Energy Resources with Remote Sensing" focuses on disseminating scientific knowledge and technological developments for the assessment and forecasting of renewable energy resources using remote sensing techniques. The eleven papers inside the book provide an overview of remote sensing applications on hydro, solar, wind and geothermal energy resources and their major goal is to provide state of art knowledge to contribute with the renewable energy resource deployment, especially in regions where energy demand is rapidly expanding. Renewable energy resources have an intrinsic relationship with local environmental features and the regional climate. Even small and fast environment and/or climate changes can cause significant variability in power generation at different time and space scales. Methodologies based on remote sensing are the primary source of information for the development of numerical models that aim to support the planning and operation of an electric system with a substantial contribution of intermittent energy sources. In addition, reliable data and knowledge on renewable energy resource assessment are fundamental to ensure sustainable expansion considering environmental, financial and energetic security.

4. Industry experience of developing day-ahead photovoltaic plant forecasting system based on machine learning

Author

Khalyasmaa, A. I., Eroshenko, S. A., Tashchilin, V. A., Ramachandran, H., Chakravarthi, T. P., Butusov, D. N., Khalyasmaa, A. I., Eroshenko, S. A., Tashchilin, V. A., Ramachandran, H., Chakravarthi, T. P., and Butusov, D. N.

Abstract

This article highlights the industry experience of the development and practical implementation of a short-term photovoltaic forecasting system based on machine learning methods for a real industry-scale photovoltaic power plant implemented in a Russian power system using remote data acquisition. One of the goals of the study is to improve photovoltaic power plants generation forecasting accuracy based on open-source meteorological data, which is provided in regular weather forecasts. In order to improve the robustness of the system in terms of the forecasting accuracy, we apply newly derived feature introduction, a factor obtained as a result of feature engineering procedure, characterizing the relationship between photovoltaic power plant energy production and solar irradiation on a horizontal surface, thus taking into account the impacts of atmospheric and electrical nature. The article scrutinizes the application of different machine learning algorithms, including Random Forest regressor, Gradient Boosting Regressor, Linear Regression and Decision Trees regression, to the remotely obtained data. As a result of the application of the aforementioned approaches together with hyperparameters, tuning and pipelining of the algorithms, the optimal structure, parameters and the application sphere of different regressors were identified for various testing samples. The mathematical model developed within the framework of the study gave us the opportunity to provide robust photovoltaic energy forecasting results with mean accuracy over 92% for mostly-sunny sample days and over 83% for mostly cloudy days with different types of precipitation. © 2020 by the authors. Licensee MDPI, Basel, Switzerland.

Published

2020

5. Industry Experience of Developing Day-Ahead Photovoltaic Plant Forecasting System Based on Machine Learning

Author

Valeriy Tashchilin, Stanislav Eroshenko, Denis N. Butusov, Teja Piepur Chakravarthi, Alexandra I. Khalyasmaa, and Hariprakash Ramachandran

Subjects

Feature engineering, photovoltaic power plant, WEATHER FORECASTING, Computer science, 02 engineering and technology, FORECASTING ACCURACY, computer.software_genre, STRUCTURAL OPTIMIZATION, 0202 electrical engineering, electronic engineering, information engineering, lcsh:Science, PHOTOVOLTAIC CELLS, Photovoltaic system, Random forest, PHOTOVOLTAIC POWER PLANT, REMOTE DATA ACQUISITION, machine learning, MACHINE LEARNING, INDUSTRY EXPERIENCE, 020209 energy, Decision tree, METEOROLOGY, Sample (statistics), forecasting, ELECTRIC POWER PLANTS, Machine learning, Electric power system, graphical user interface software, Robustness (computer science), FORECASTING, HORIZONTAL SURFACES, SOLAR POWER GENERATION, DECISION TREES, PROFESSIONAL ASPECTS, business.industry, 020208 electrical & electronic engineering, GRAPHICAL USER INTERFACE SOFTWARE, ADAPTIVE BOOSTING, METEOROLOGICAL DATA, feature engineering, PHOTOVOLTAIC ENERGY, SOLAR POWER PLANTS, DATA ACQUISITION, General Earth and Planetary Sciences, lcsh:Q, Artificial intelligence, Gradient boosting, FEATURE ENGINEERINGS, business, FEATURE ENGINEERING, computer

Abstract

This article highlights the industry experience of the development and practical implementation of a short-term photovoltaic forecasting system based on machine learning methods for a real industry-scale photovoltaic power plant implemented in a Russian power system using remote data acquisition. One of the goals of the study is to improve photovoltaic power plants generation forecasting accuracy based on open-source meteorological data, which is provided in regular weather forecasts. In order to improve the robustness of the system in terms of the forecasting accuracy, we apply newly derived feature introduction, a factor obtained as a result of feature engineering procedure, characterizing the relationship between photovoltaic power plant energy production and solar irradiation on a horizontal surface, thus taking into account the impacts of atmospheric and electrical nature. The article scrutinizes the application of different machine learning algorithms, including Random Forest regressor, Gradient Boosting Regressor, Linear Regression and Decision Trees regression, to the remotely obtained data. As a result of the application of the aforementioned approaches together with hyperparameters, tuning and pipelining of the algorithms, the optimal structure, parameters and the application sphere of different regressors were identified for various testing samples. The mathematical model developed within the framework of the study gave us the opportunity to provide robust photovoltaic energy forecasting results with mean accuracy over 92% for mostly-sunny sample days and over 83% for mostly cloudy days with different types of precipitation. © 2020 by the authors. Licensee MDPI, Basel, Switzerland.

Published

2020

6. Plant-scale biogas production prediction based on multiple hybrid machine learning technique.

Author

Zhang Y, Li L, Ren Z, Yu Y, Li Y, Pan J, Lu Y, Feng L, Zhang W, and Han Y

Subjects

Algorithms, Software, Biofuels, Machine Learning

Abstract

The parameters from full-scale biogas plants are highly nonlinear and imbalanced, resulting in low prediction accuracy when using traditional machine learning algorithms. In this study, a hybrid extreme learning machine (ELM) model was proposed to improve prediction accuracy by solving imbalanced data. The results showed that the best ELM model had a good prediction for validation data (R 2  = 0.972), and the model was developed into the software (prediction error of 2.15 %). Furthermore, two parameters within a certain range (feed volume (FV) = 23-45 m 3 and total volatile fatty acids of anaerobic digestion (TVFA AD ) = 1750-3000 mg/L) were identified as the most important characteristics that positively affected biogas production. This study combines machine learning with data-balancing techniques and optimization algorithms to achieve accurate predictions of plant biogas production at various loads., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2022 Elsevier Ltd. All rights reserved.)

Published

2022

7. Industry Experience of Developing Day-Ahead Photovoltaic Plant Forecasting System Based on Machine Learning.

Author

Khalyasmaa, Alexandra I., Eroshenko, Stanislav A., Tashchilin, Valeriy A., Ramachandran, Hariprakash, Piepur Chakravarthi, Teja, and Butusov, Denis N.

Subjects

*PHOTOVOLTAIC power generation, *MACHINE learning, *WORK experience (Employment), *RANDOM forest algorithms, *SOLAR energy, *BUILDING-integrated photovoltaic systems, *PHOTOVOLTAIC power systems

Abstract

This article highlights the industry experience of the development and practical implementation of a short-term photovoltaic forecasting system based on machine learning methods for a real industry-scale photovoltaic power plant implemented in a Russian power system using remote data acquisition. One of the goals of the study is to improve photovoltaic power plants generation forecasting accuracy based on open-source meteorological data, which is provided in regular weather forecasts. In order to improve the robustness of the system in terms of the forecasting accuracy, we apply newly derived feature introduction, a factor obtained as a result of feature engineering procedure, characterizing the relationship between photovoltaic power plant energy production and solar irradiation on a horizontal surface, thus taking into account the impacts of atmospheric and electrical nature. The article scrutinizes the application of different machine learning algorithms, including Random Forest regressor, Gradient Boosting Regressor, Linear Regression and Decision Trees regression, to the remotely obtained data. As a result of the application of the aforementioned approaches together with hyperparameters, tuning and pipelining of the algorithms, the optimal structure, parameters and the application sphere of different regressors were identified for various testing samples. The mathematical model developed within the framework of the study gave us the opportunity to provide robust photovoltaic energy forecasting results with mean accuracy over 92% for mostly-sunny sample days and over 83% for mostly cloudy days with different types of precipitation. [ABSTRACT FROM AUTHOR]

Published

2020