Correlated synthetic time series generation for energy system simulations using Fourier and ARMA signal processing

Talbot, Paul; Rabiti, Cristian; Alfonsi, Andrea; Krome, Cameron; Kunz, M. Ross; Epiney, Aaron; Wang, Congjian; Mandelli, Diego

doi:10.1002/er.5115

Cited by 30 publications

(17 citation statements)

References 6 publications

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“…Most of the work in this respect is focused on reduction of the necessary number of samples to ensure a reliable convergence of the stochastic optimization under probabilistic constraints. For further details on the simulation framework see references (Rabiti et al 2017;Epiney et al 2018;Talbot et al 2018).…”

Section: Analysis Approach and Toolsmentioning

confidence: 99%

Integrated Energy Systems: 2020 Roadmap

Bragg‐Sitton

Rabiti

O’Brien

et al. 2020

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Many cities, states, utilities, and public commissions are setting energy standards that aim to reduce carbon emissions. In order to realize a clean and resilient energy future, new methods of energy production, distribution, and use will be required. Renewable energy technologies are currently being deployed in significant numbers around the world in response to the desire to reduce emissions, coupled with decreasing costs for these technologies. However, despite this growth, data reported in the International Energy Agency (IEA) Future of Nuclear report that was released in May 2019 indicate that the fraction of clean energy contributions to electricity generation has not changed over the last 20 years. This unexpected trend results from the increasing penetration of variable sources driving nuclear energy out of the market in some regions, resulting in the shutdown of some large-scale, non-emitting plants when non-emitting renewable resources are added to the grid. The advent of historically low-cost renewable generation sources, alongside low cost and high availability of natural gas, has driven down the price of electricity, decreasing the minimum baseload generation required to meet load at certain times of the day or year. These factors serve to diminish the role of traditionally baseload nuclear generation. Many nuclear plants have responded to increasing volatility in net demand by operating flexibly, reducing power output to reduce the financial impact to the plant from very low or negative market prices. This practice preserves the contribution of nuclear energy to grid stability and reduces economic losses associated with negatively-priced electricity sales, but it does not reduce the plant operating costs. Nuclear energy is a proven low-emission option that can provide consistent, dispatchable power to meet electricity demands while also providing high quality heat that can meet energy demands beyond the electricity sector-energy system design should seek to maximize these assets. This roadmap defines proposed integrated nuclear-renewable energy systems and identifies key technology gaps to realizing deployment of commercial scale systems for the production of a variety of electric and non-electric products. Integrated energy systems (IES) under consideration could incorporate multiple energy generation resources and energy use paths, with a focus on low-emission technologies such as nuclear and renewable generators. Together these technologies provide affordable, reliable, and resilient energy while simultaneously reducing environmental emission of CO2 and greenhouse gases (GHGs). IES are cooperatively-controlled systems that dynamically apportion thermal and/or electrical energy to provide responsive generation to the power grid. They are composed of multiple subsystems, which may or may not be geographically co-located, including a thermal energy generation source (e.g., nuclear), a turbine that converts thermal energy to electricity, additional electricity generation source(s) (e.g., renewable ge...

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Section: Analysis Approach and Toolsmentioning

confidence: 99%

Integrated Energy Systems: 2020 Roadmap

Bragg‐Sitton

Rabiti

O’Brien

et al. 2020

Self Cite

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“…Each synthetic history generation represents a multiyear scenario with the same statistical characteristics as the data on which it is trained, but with distinct signals [23]. This enables a set of components with fixed capacities to be tested under a variety of realistic circumstances and determine the system's statistical economic viability.…”

Section: Synthetic History Scenariosmentioning

confidence: 99%

Evaluation of Hybrid FPOG Applications in Regulated and Deregulated Markets Using HERON

Talbot

McDowell

Richards

et al. 2020

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“…] to construct an analysis framework using RAVEN for systems of energy producers and consumers in a method that allows statistically-meaningful decisions to be made with regards to the economic viability of energy grid portfolios and configurations. The results of this effort have shown value both in a theoretical sense [1,2,4,5,7,[9][10][11][12] as well as for specific applications when paired with industrial partners in the energy space [3,16]. However, the development and maintenance of these RAVEN workflows has been burdensome, and often involves complicated copy-and-modify operations that significantly slow the user experience.…”

Section: Tablesmentioning

confidence: 99%

“…The price of electricity sold at the Grid is given by a synthetic history [9,10,11] and changes for each time step. For this example, we consider on the resolution of the first time step as an example.…”

Section: Example Dispatchmentioning

confidence: 99%

HERON as a Tool for LWR Market Interaction in a Deregulated Market

Talbot

Gairola

Prateek

et al. 2019

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This document reports the development of HERON (Holistic Energy Resource Optimization Network), a newly-developed RAVEN (Risk Analysis Virtual ENvironment) plugin for grid and capacity optimization, to technoeconomic analysis in a deregulated market. A short description of the HERON plugin is provided, and the release process is described. HERON as a plugin enables RAVEN to perform stochastic technoeconomic analysis of grid-energy systems in a generic approach. The primary function of HERON is to generate the complex RAVEN workflows necessary to optimize component capacities under stochastic systems. HERON is capable of analyzing systems with complex components transferring a variety of commodities, including production components and varied markets. HERON is capable of optimizing highresolution dispatch for such systems and guiding stochastic optimization algorithms in RAVEN for finding optimal component capacities. In particular, this document demonstrates the application of HERON to systems with deregulated markets.

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Correlated synthetic time series generation for energy system simulations using Fourier and ARMA signal processing

Cited by 30 publications

References 6 publications

Integrated Energy Systems: 2020 Roadmap

Integrated Energy Systems: 2020 Roadmap

Evaluation of Hybrid FPOG Applications in Regulated and Deregulated Markets Using HERON

HERON as a Tool for LWR Market Interaction in a Deregulated Market

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