ASSUME

Latest revision as of 12:53, 17 April 2024

Agent-based Simulation for Studying and Understanding Market Evolution

Authors:
Florian Maurer, Nick Harder, Kim K. Miskiw, Johanna Adams, Manish Khanra, Parag Pratil

Contact:
Nick Harder

ASSUME is an open-source toolbox for agent-based simulations of European electricity markets, with a primary focus on the German market setup and Reinforcement Learning. Developed as an open-source model, its primary objectives are to ensure usability and customizability for a wide range of users and use cases in the energy system modeling community.

Based on Python, Pyomo. Using PostgreSQL for data processing.

Website / Documentation
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Open Source
Affero General Public License v3 (AGPL-3.0)

Directly downloadable

Input data shipped

Model Scope

Model type and solution approach

Model class	German and European Electricity Market, Network-constrained Unit Commitment and Economic Dispatch, Agent-based electricity market model
Sectors	All / Electricity
Technologies	Renewables, Conventional Generation, CHP
Decisions	dispatch
Regions	depending on input data
Geographic Resolution	NUTS0 - NUTS3, for DE
Time resolution	15 Minute
Network coverage	transmission, distribution

Model type	Simulation, Agent-based
	depending on parameterization bidding behavior and market behavior can be defined. bidding behavior: bid marginal cost complex bids market behavior: pay as bid pay as clear redispatch nodal pricing
Variables
Computation time	minutes
Objective	Minimize cost, optimize dispatch per agent
Uncertainty modeling	Deterministic
Suited for many scenarios / monte-carlo	No

References

Scientific references

Zenodo
https://dx.doi.org/https://doi.org/10.5281/zenodo.8088760

Reports produced using the model

https://doi.org/10.1007/978-3-031-48652-4_10

https://doi.org/10.1016/j.egyai.2023.100295

Example research questions

What influence does the availability of different order types on a market have?

How can deep reinforcement learning for multiple markets be implemented in software?

What is the best way for demand-side management to be implemented in bidding agents?

How can different energy market designs be modelled in energy market simulations?

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@@ Line 9: / Line 9: @@
 |source_download=https://codeload.github.com/assume-framework/assume/zip/refs/heads/main
 |logo=assume-project.png
-|text_description=ASSUME is an open-source toolbox for agent-based simulations of European electricity markets, with a primary focus on the German market setup. Developed as an open-source model, its primary objectives are to ensure usability and customizability for a wide range of users and use cases in the energy system modeling community.
+|text_description=ASSUME is an open-source toolbox for agent-based simulations of European electricity markets, with a primary focus on the German market setup and Reinforcement Learning. Developed as an open-source model, its primary objectives are to ensure usability and customizability for a wide range of users and use cases in the energy system modeling community.
 |Primary outputs=electricity prices, power plant dispatch, cost and income
 |Support=OpenMod Forum, GitHub Issues
@@ Line 35: / Line 35: @@
 |Energy carriers (Solid)=Biomass, Coal, Lignite, Uranium
 |Energy carriers (Renewable)=Geothermal heat, Hydro, Sun, Wind
-|Transfer (Electricity)=Distribution, Transmission
+|Transfer (Electricity)=Transmission
 |Storage (Electricity)=Battery, CAES, Chemical, Kinetic, PHS
 |Storage (Gas)=No
@@ Line 53: / Line 53: @@
 |Additional dimensions (Other)=grid congestion
 |math_modeltype=Simulation, Agent-based
-|math_modeltype_shortdesc=depending on parameterization bidding behavior and market behavior can be defined,
+|math_modeltype_shortdesc=depending on parameterization bidding behavior and market behavior can be defined.
-bidding behavior,
+bidding behavior:
-bid marginal cost, complex bids
-market behavior,
+* bid marginal cost
-pay as bid, pay as clear, redispatch, nodal pricing
+* complex bids
+market behavior:
+* pay as bid
+* pay as clear
+* redispatch
+* nodal pricing
 |math_objective=Minimize cost, optimize dispatch per agent
 |deterministic=Deterministic
@@ Line 67: / Line 73: @@
 |citation_doi=https://doi.org/10.5281/zenodo.8088760
 |report_references=https://doi.org/10.1007/978-3-031-48652-4_10
 https://doi.org/10.1016/j.egyai.2023.100295
 |example_research_questions=What influence does the availability of different order types on a market have?
 How can deep reinforcement learning for multiple markets be implemented in software?
 What is the best way for demand-side management to be implemented in bidding agents?
 How can different energy market designs be modelled in energy market simulations?
 |Model validation=benchmark to entsoe, comparison of real dispatch

Author institution	INATECH Freiburg +
Authors	Florian Maurer, Nick Harder, Kim K. Miskiw, Johanna Adams, Manish Khanra, Parag Pratil +
Citation doi	https://doi.org/10.5281/zenodo.8088760 +
Citation references	Zenodo
Contact email	contact@assume-project.de +
Contact persons	Nick Harder +
Data availability	all +
Decisions	dispatch +
Deterministic	Deterministic +
Example research questions	What influence does the availability of di … What influence does the availability of different order types on a market have? How can deep reinforcement learning for multiple markets be implemented in software? What is the best way for demand-side management to be implemented in bidding agents? How can different energy market designs be modelled in energy market simulations? be modelled in energy market simulations?
Full Model Name	Agent-based Simulation for Studying and Understanding Market Evolution +
Georegions	Depending on input data +
Georesolution	NUTS0 - NUTS3, for DE +
Is suited for many scenarios	false +
License	Affero General Public License v3 (AGPL-3.0) +
Math modeltype	Simulation + and Agent-based +
Math modeltype shortdesc	depending on parameterization bidding behavior and market behavior can be defined. bidding behavior: bid marginal cost complex bids market behavior: pay as bid pay as clear redispatch nodal pricing +
Math objective	Minimize cost, optimize dispatch per agent +
Model class	German and European Electricity Market +, Network-constrained Unit Commitment and Economic Dispatch + and Agent-based electricity market model +
Model source public	true +
Modelling software	Python, Pyomo +
Network coverage	transmission + and distribution +
Open future	false +
Open source licensed	true +
Processing software	PostgreSQL +
Report references	https://doi.org/10.1007/978-3-031-48652-4_10 https://doi.org/10.1016/j.egyai.2023.100295
Sectors	All / Electricity +
Source download	https://codeload.github.com/assume-framework/assume/zip/refs/heads/main +
Technologies	Renewables +, Conventional Generation + and CHP +
Text description	ASSUME is an open-source toolbox for agent … ASSUME is an open-source toolbox for agent-based simulations of European electricity markets, with a primary focus on the German market setup and Reinforcement Learning. Developed as an open-source model, its primary objectives are to ensure usability and customizability for a wide range of users and use cases in the energy system modeling community.s in the energy system modeling community.
Timeresolution	15 Minute +
Website	https://assume-project.de/ +

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ASSUME

Latest revision as of 12:53, 17 April 2024

References

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Example research questions

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About

Help

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Search

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Toolbox

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ASSUME

Latest revision as of 12:53, 17 April 2024

References

Scientific references

Reports produced using the model

Example research questions