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| | |website=https://github.com/richard-weinhold/pomato | | |website=https://github.com/richard-weinhold/pomato |
| | |source_download=https://github.com/richard-weinhold/pomato | | |source_download=https://github.com/richard-weinhold/pomato |
| − | |logo=Pomato 2.png | + | |logo=Pomato.gif |
| | |text_description=POMATO stands for (POwer MArket TOol) and is an easy to use tool for the comprehensive analysis of the modern electricity market. It comprises the necessary power engineering framework to account for power flow physics, thermal transport constraints and security policies of the underlying transmission infrastructure, depending on the requirements defined by the user. POMATO was specifically designed to realistically model Flow-Based Market-Coupling (FBMC) and is therefore equipped with a fast security constrained optimal power flow algorithm and allows zonal market clearing with endogenously generated flow-based parameters, and redispatch. | | |text_description=POMATO stands for (POwer MArket TOol) and is an easy to use tool for the comprehensive analysis of the modern electricity market. It comprises the necessary power engineering framework to account for power flow physics, thermal transport constraints and security policies of the underlying transmission infrastructure, depending on the requirements defined by the user. POMATO was specifically designed to realistically model Flow-Based Market-Coupling (FBMC) and is therefore equipped with a fast security constrained optimal power flow algorithm and allows zonal market clearing with endogenously generated flow-based parameters, and redispatch. |
| | |Primary outputs=Economic dispatch subhect to various network representations | | |Primary outputs=Economic dispatch subhect to various network representations |
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| | |processing_software=Python | | |processing_software=Python |
| | |External optimizer=Clp per default, commercial solvers are compadible | | |External optimizer=Clp per default, commercial solvers are compadible |
| | + | |Additional software=No |
| | |GUI=No | | |GUI=No |
| − | |model_class=Network-constrained Unit Commitment and Economic Dispatch, | + | |model_class=Network-constrained Unit Commitment and Economic Dispatch, |
| | |sectors=Electricity Market, Heat | | |sectors=Electricity Market, Heat |
| | |technologies=Renewables, Conventional Generation, CHP | | |technologies=Renewables, Conventional Generation, CHP |
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| | |Storage (Heat)=No | | |Storage (Heat)=No |
| | |decisions=dispatch | | |decisions=dispatch |
| − | |georegions=inlcuded data for DE, CWE. all Matpower cases are compadible. | + | |georegions=User-dependent |
| | |georesolution=Nodal resolution | | |georesolution=Nodal resolution |
| | |timeresolution=Hour | | |timeresolution=Hour |
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| | |is_suited_for_many_scenarios=No | | |is_suited_for_many_scenarios=No |
| | |montecarlo=No | | |montecarlo=No |
| − | |report_references= | + | |citation_references=Weinhold, Richard, and Robert Mieth. 2021. “Power Market Tool (POMATO) for the Analysis of Zonal Electricity Markets.” SoftwareX 16 (December): 100870. |
| − | Weinhold and Mieth (2020), Fast Security-Constrained Optimal Power Flow through Low-Impact and Redundancy Screening. DOI: 0.1109/TPWRS.2020.2994764 | + | |citation_doi=10.1016/j.softx.2021.100870 |
| | + | |report_references=Schönheit, Weinhold, Dierstein (2020), The impact of different strategies for generation shift keys (GSKs) on the flow-based market coupling domain: A model-based analysis of Central Western Europe. https://doi.org/10.1016/j.apenergy.2019.114067. |
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| − | Schönheit, Weinhold, Dierstein (2020), The impact of different strategies for generation shift keys (GSKs) on the flow-based market coupling domain: A model-based analysis of Central Western Europe. DOI: 10.1016/j.apenergy.2019.114067
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| | + | Weinhold, Richard, and Robert Mieth. 2020. “Fast Security-Constrained Optimal Power Flow Through Low-Impact and Redundancy Screening.” IEEE Transactions on Power Systems 35 (6): 4574–84. https://doi.org/10.1109/TPWRS.2020.2994764. |
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| | + | Weinhold, Richard. 2021. “Evaluating Policy Implications on the Restrictiveness of Flow-Based Market Coupling with High Shares of Intermittent Generation: A Case Study for Central Western Europe.” ArXiv preprint 2109.04940v1. https://arxiv.org/abs/2109.04940. |
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| | + | Weinhold, Richard, and Robert Mieth. 2021. “Uncertainty-Aware Capacity Allocation in Flow-Based Market Coupling.” ArXiv preprint 2109.04968v2. https://arxiv.org/abs/2109.04968. |
| | |Model input file format=No | | |Model input file format=No |
| | |Model file format=No | | |Model file format=No |
| | |Model output file format=No | | |Model output file format=No |
| | }} | | }} |
Weinhold, Richard, and Robert Mieth. 2021. “Power Market Tool (POMATO) for the Analysis of Zonal Electricity Markets.” SoftwareX 16 (December): 100870.
https://dx.doi.org/10.1016/j.softx.2021.100870
Schönheit, Weinhold, Dierstein (2020), The impact of different strategies for generation shift keys (GSKs) on the flow-based market coupling domain: A model-based analysis of Central Western Europe. https://doi.org/10.1016/j.apenergy.2019.114067.
