Analyses of Photovoltaic Power Plant Performance Estimates Based on Detailed Laboratory Module Characterizations and Typical Real-World Input Data Sources

This chapter provides an ethnography of a complex scenario involving the construction of a power plant and, in so doing, tries to show the importance of a practice-based approach to the problem of technical and organizational change. The chapter reports on fieldwork conducted in a highly complex and tightly coupled environment: power plant construction. The ethnography describes work practices on three different sites and describes and analyses their interlocking dependencies, showing the difficulties encountered at each location and the way in which the delays that result cascade through the different sites. It goes on to describe some technological solutions that are associated with augmented reality and that are being designed in response to the insights gained from the fieldwork. The chapter also reflects more generally on the relationship between fieldwork and design in real-world contexts.

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Using dynamical uncertainty models for estimation of uncertainty bounds on power plant performance prediction

2007 European Control Conference (ECC) ◽

10.23919/ecc.2007.7068491 ◽

2007 ◽

Author(s):

P.F. Odgaard ◽

J. Stoustrup ◽

B. Mataji

Keyword(s):

Power Plant ◽

Performance Prediction ◽

Plant Performance ◽

Dynamical Uncertainty ◽

Uncertainty Models ◽

Estimation Of Uncertainty

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Data Driven Modelling of Nuclear Power Plant Performance Data as Finite State Machines

Modelling ◽

10.3390/modelling2010003 ◽

2021 ◽

Vol 2 (1) ◽

pp. 43-62

Author(s):

Kshirasagar Naik ◽

Mahesh D. Pandey ◽

Anannya Panda ◽

Abdurhman Albasir ◽

Kunal Taneja

Keyword(s):

Power Plant ◽

Nuclear Power Plant ◽

Nuclear Power ◽

Finite State Machine ◽

State Machine ◽

Plant Performance ◽

Series Data ◽

Cyberphysical Systems ◽

Finite State ◽

Machine Representation

Accurate modelling and simulation of a nuclear power plant are important factors in the strategic planning and maintenance of the plant. Several nonlinearities and multivariable couplings are associated with real-world plants. Therefore, it is quite challenging to model such cyberphysical systems using conventional mathematical equations. A visual analytics approach which addresses these limitations and models both short term as well as long term behaviour of the system is introduced. Principal Component Analysis (PCA) followed by Linear Discriminant Analysis (LDA) is used to extract features from the data, k-means clustering is applied to label the data instances. Finite state machine representation formulated from the clustered data is then used to model the behaviour of cyberphysical systems using system states and state transitions. In this paper, the indicated methodology is deployed over time-series data collected from a nuclear power plant for nine years. It is observed that this approach of combining the machine learning principles with the finite state machine capabilities facilitates feature exploration, visual analysis, pattern discovery, and effective modelling of nuclear power plant data. In addition, finite state machine representation supports identification of normal and abnormal operation of the plant, thereby suggesting that the given approach captures the anomalous behaviour of the plant.

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An Improved Whale Algorithm for Support Vector Machine Prediction of Photovoltaic Power Generation

Symmetry ◽

10.3390/sym13020212 ◽

2021 ◽

Vol 13 (2) ◽

pp. 212

Author(s):

Yu-Wei Liu ◽

Huan Feng ◽

Heng-Yi Li ◽

Ling-Ling Li

Keyword(s):

Support Vector Machine ◽

Prediction Model ◽

Output Power ◽

Input Data ◽

Support Vector Machine Model ◽

Weather Conditions ◽

Clean Energy ◽

Support Vector ◽

Machine Model ◽

Photovoltaic Power

Accurate prediction of photovoltaic power is conducive to the application of clean energy and sustainable development. An improved whale algorithm is proposed to optimize the Support Vector Machine model. The characteristic of the model is that it needs less training data to symmetrically adapt to the prediction conditions of different weather, and has high prediction accuracy in different weather conditions. This study aims to (1) select light intensity, ambient temperature and relative humidity, which are strictly related to photovoltaic output power as the input data; (2) apply wavelet soft threshold denoising to preprocess input data to reduce the noise contained in input data to symmetrically enhance the adaptability of the prediction model in different weather conditions; (3) improve the whale algorithm by using tent chaotic mapping, nonlinear disturbance and differential evolution algorithm; (4) apply the improved whale algorithm to optimize the Support Vector Machine model in order to improve the prediction accuracy of the prediction model. The experiment proves that the short-term prediction model of photovoltaic power based on symmetry concept achieves ideal accuracy in different weather. The systematic method for output power prediction of renewable energy is conductive to reducing the workload of predicting the output power and to promoting the application of clean energy and sustainable development.

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