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| | |Acronym=Mosaik | | |Acronym=Mosaik |
| | |author_institution=OFFIS | | |author_institution=OFFIS |
| | + | |contact_email=mosaik@offis.de |
| | |website=http://mosaik.offis.de/ | | |website=http://mosaik.offis.de/ |
| | |source_download=https://gitlab.com/mosaik | | |source_download=https://gitlab.com/mosaik |
| − | |text_description= | + | |logo=Mosaik logo.png |
| − | Mosaik is a flexible Smart Grid co-simulation framework. | + | |text_description=Mosaik is a flexible Smart Grid co-simulation framework. |
| | | | |
| | Mosaik allows you to reuse and combine existing simulation models and simulators to create large-scale Smart Grid scenarios – and by large-scale we mean thousands of simulated entities distributed over multiple simulator processes. These scenarios can then serve as test bed for various types of control strategies (e.g., multi-agent systems (MAS) or centralized control). | | Mosaik allows you to reuse and combine existing simulation models and simulators to create large-scale Smart Grid scenarios – and by large-scale we mean thousands of simulated entities distributed over multiple simulator processes. These scenarios can then serve as test bed for various types of control strategies (e.g., multi-agent systems (MAS) or centralized control). |
| | | | |
| − | Mosaik is written in Python and completely open source (LGPL), including some simple simulators, a binding to PYPOWER and a demonstration scenario. | + | Mosaik is written in Python and completely open source (LGPL), including some simple simulators, a binding to pandapower and PYPOWER and a demonstration scenario. |
| − | | + | |User documentation=mosaik.readthedocs.io |
| − | |Primary purpose=Cosimulation | + | |
| | |Code documentation=mosaik.readthedocs.io | | |Code documentation=mosaik.readthedocs.io |
| | |open_source_licensed=Yes | | |open_source_licensed=Yes |
| | |license=GNU Library or "Lesser" General Public License version 2.1 (LGPL-2.1) | | |license=GNU Library or "Lesser" General Public License version 2.1 (LGPL-2.1) |
| − | |model_source_public=No | + | |model_source_public=Yes |
| | |Link to source=https://gitlab.com/mosaik | | |Link to source=https://gitlab.com/mosaik |
| | + | |data_availability=some |
| | |open_future=No | | |open_future=No |
| | |modelling_software=Python | | |modelling_software=Python |
| − | |Primary purpose=Cosimulation | + | |processing_software=HDF5, InfluxDB, Grafana |
| − | |GUI=No | + | |GUI=Yes |
| | + | |model_class=distributed energy systems, smart grid simulation |
| | + | |sectors=electricity, heat, mobility, household |
| | + | |technologies=Renewables, CHP |
| | + | |Demand sectors=Households |
| | + | |Energy carriers (Renewable)=Sun, Wind |
| | + | |Transfer (Electricity)=Distribution, Transmission |
| | + | |Storage (Electricity)=Battery |
| | |Storage (Gas)=No | | |Storage (Gas)=No |
| | |Storage (Heat)=No | | |Storage (Heat)=No |
| | + | |timeresolution=Second |
| | + | |network_coverage=transmission, distribution |
| | + | |Observation period=Less than one month, Less than one year, More than one year |
| | |math_modeltype=Optimization, Simulation, Agent-based | | |math_modeltype=Optimization, Simulation, Agent-based |
| | |is_suited_for_many_scenarios=Yes | | |is_suited_for_many_scenarios=Yes |
| | |montecarlo=No | | |montecarlo=No |
| | + | |citation_references=A. Ofenloch et al., "MOSAIK 3.0: Combining Time-Stepped and Discrete Event Simulation," 2022 Open Source Modelling and Simulation of Energy Systems (OSMSES), 2022, pp. 1-5 |
| | + | |citation_doi=10.1109/OSMSES54027.2022.9769116. |
| | + | |Integrated models=demod, pandapower |
| | + | |Interfaces=Python, Java, C#, Matlab, FMI |
| | |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 |
| | }} | | }} |
A. Ofenloch et al., "MOSAIK 3.0: Combining Time-Stepped and Discrete Event Simulation," 2022 Open Source Modelling and Simulation of Energy Systems (OSMSES), 2022, pp. 1-5
https://dx.doi.org/10.1109/OSMSES54027.2022.9769116.
