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Energy model | ==Energy model== | ||
Shipping model | The default North Sea and Baltic Sea editions of MSP Challenge have an energy simulation running in the background. | ||
Ecosystem model | |||
The core energy simulation software is generic (meaning it doesn't depend on a specific region) and was developed by Breda University of Applied Sciences' Kevin Hutchinson, based on collaborations with several colleagues (notably Carlos Santos and Wilco Boode) and external advisors (notably Lodewijk Abspoel and Thomas Aksan). As a separate application, it takes input data from the MSP Challenge server on the different energy grids implemented within the edition at hand, calculates how much of the maximum capacity generated can actually reach the applicable country or countries given the energy infrastructure, and feeds back that output data to the server again. This is again done each simulated month, making this another discrete-event simulation. The application that handles this energy input, throughput and output is called CEL. | |||
This system relies on energy grids implemented in the edition at hand through the MSP Challenge client software. This means that if there are no energy grids at the start of an MSP Challenge session (so no offshore wind farms, for example), then CEL will have nothing to calculate. This is why the default North Sea and Baltic Sea editions of MSP Challenge have so-called starting plans in place that implement a large set of energy grids (country-specific offshore wind farms complete with cables connecting them to landing stations) before the session starts. | |||
*Read more about CEL's design and implementation [https://pure.buas.nl/en/publications/an-offshore-energy-simulation-through-flow-networks-cel-within-th in this paper] written for and presented at the ESM 2018 conference in Ghent, Belgium. | |||
==Shipping model== | |||
The default North Sea, Baltic Sea and Clyde marine region editions of MSP Challenge each have their own bespoke shipping model and simulation running in the background. | |||
The core shipping simulation is generic (meaning it doesn't depend on a specific region) and was developed by Breda University of Applied Sciences' Phil de Groot, based on collaboration with several colleagues (notably Carlos Santos and Wilco Boode). As a separate application, it takes input data from the MSP Challenge server on the different shipping routes and port within each edition to calculate the (future) impact of MSP decisions on shipping routes. This is dynamically shown in key performance indicators (e.g. route efficiencies) and visualised in heat maps of ship traffic. | |||
*Read more about SEL's design and implementation [https://pure.buas.nl/en/publications/a-shipping-simulation-through-pathfinding-sel-within-the-msp-chal in this paper] written for and presented at the Game-On 2019 conference in Breda, the Netherlands. | |||
==Ecosystem model== | |||
The default North Sea, Baltic Sea and Clyde marine region editions of MSP Challenge each have their own bespoke ecosystem model and simulation running in the background. | |||
In each case the ecosystem model was developed with the well-established free and open source software Ecopath-with-Ecosim (EwE) (<nowiki>http://www.ecopath.org</nowiki>) The MSP Challenge server feeds input data into the EwE model, after which the EwE model runs one simulated month, in order to feed back relevant output data to the MSP Challenge server again. This process turns the EwE model into a discrete-event ecosystem simulation. The software component that does this is called MEL, standing for MSP Challenge - EwE - Link. The overall ecosystem simulation thus depends on the combination of MEL, the EwE platform itself, and the specific EwE ecosystem model made with that platform. | |||
*Read more about the technical design and implementation of MEL [https://pure.buas.nl/en/publications/msp-challenge-2050-ecopath-link-design-document in this design document]. | |||
*Read more about the overall design and implementation of the North Sea and Clyde marine region EwE models, as well as their integration within the MSP Challenge simulation platform [https://doi.org/10.5751/ES-11580-250221 in this paper]. | |||
*Read more about the overall design and implementation of the Baltic Sea EwE model, as well as it's integration within the MSP Challenge simulation platform [https://www.researchgate.net/publication/335992534_Food-web_modeling_in_the_Maritime_Spatial_Planning_Challenge_Simulation_Platform_Results_from_the_Baltic_Sea_Region in this paper]. |
Latest revision as of 13:30, 27 July 2020
Energy model
The default North Sea and Baltic Sea editions of MSP Challenge have an energy simulation running in the background.
The core energy simulation software is generic (meaning it doesn't depend on a specific region) and was developed by Breda University of Applied Sciences' Kevin Hutchinson, based on collaborations with several colleagues (notably Carlos Santos and Wilco Boode) and external advisors (notably Lodewijk Abspoel and Thomas Aksan). As a separate application, it takes input data from the MSP Challenge server on the different energy grids implemented within the edition at hand, calculates how much of the maximum capacity generated can actually reach the applicable country or countries given the energy infrastructure, and feeds back that output data to the server again. This is again done each simulated month, making this another discrete-event simulation. The application that handles this energy input, throughput and output is called CEL.
This system relies on energy grids implemented in the edition at hand through the MSP Challenge client software. This means that if there are no energy grids at the start of an MSP Challenge session (so no offshore wind farms, for example), then CEL will have nothing to calculate. This is why the default North Sea and Baltic Sea editions of MSP Challenge have so-called starting plans in place that implement a large set of energy grids (country-specific offshore wind farms complete with cables connecting them to landing stations) before the session starts.
- Read more about CEL's design and implementation in this paper written for and presented at the ESM 2018 conference in Ghent, Belgium.
Shipping model
The default North Sea, Baltic Sea and Clyde marine region editions of MSP Challenge each have their own bespoke shipping model and simulation running in the background.
The core shipping simulation is generic (meaning it doesn't depend on a specific region) and was developed by Breda University of Applied Sciences' Phil de Groot, based on collaboration with several colleagues (notably Carlos Santos and Wilco Boode). As a separate application, it takes input data from the MSP Challenge server on the different shipping routes and port within each edition to calculate the (future) impact of MSP decisions on shipping routes. This is dynamically shown in key performance indicators (e.g. route efficiencies) and visualised in heat maps of ship traffic.
- Read more about SEL's design and implementation in this paper written for and presented at the Game-On 2019 conference in Breda, the Netherlands.
Ecosystem model
The default North Sea, Baltic Sea and Clyde marine region editions of MSP Challenge each have their own bespoke ecosystem model and simulation running in the background.
In each case the ecosystem model was developed with the well-established free and open source software Ecopath-with-Ecosim (EwE) (http://www.ecopath.org) The MSP Challenge server feeds input data into the EwE model, after which the EwE model runs one simulated month, in order to feed back relevant output data to the MSP Challenge server again. This process turns the EwE model into a discrete-event ecosystem simulation. The software component that does this is called MEL, standing for MSP Challenge - EwE - Link. The overall ecosystem simulation thus depends on the combination of MEL, the EwE platform itself, and the specific EwE ecosystem model made with that platform.
- Read more about the technical design and implementation of MEL in this design document.
- Read more about the overall design and implementation of the North Sea and Clyde marine region EwE models, as well as their integration within the MSP Challenge simulation platform in this paper.
- Read more about the overall design and implementation of the Baltic Sea EwE model, as well as it's integration within the MSP Challenge simulation platform in this paper.