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- AIMMS
- AIMMS Control.py (Rolling Horizon AIMMS)
- AIMMS Control Rolling Horizon.py (Rolling Horizon AIMMS)
- Abdollahi and Maratizaman, 2011 - Multi-objective appraoc in thermoenvironomic optimization of a small-scale distributed CCHP system with risk analysis
- Abdollahi and Maratizaman, 2011 - Multi-objective approach in thermoenvironomic optimization of a small-scale distributed CCHP system with risk analysis
- Abdulah et al, 2015 - Sustainable energy system design with distribued renewable resources considering economic, environmental and uncertainty aspects
- Abdulah et al, 2015 - Sustainable energy system design with distributed renewable resources considering economic, environmental and uncertainty aspects
- Abdullah et al, 2015 - Sustainable energy system design with distributed renewable resources considering economic, environmental and uncertainty aspects
- Accessibility of modules
- Acuri et al, 2007 - A mixed integer programming model for optimal design of trigeneration in a hospital complex
- AddingAModuleTest
- Aggregate occupancy data.m (Stochastic building energy demand generator)
- Ahmadi et al, 2015 - Evaluating the effectiveness of normal boundary intersection method for short-term environmental/economic hydrothermal self-scheduling
- Aimms
- Air source heat pump 1
- Air source heat pump 10
- Air source heat pump 11
- Air source heat pump 12
- Air source heat pump 13
- Air source heat pump 14
- Air source heat pump 15
- Air source heat pump 16
- Air source heat pump 17
- Air source heat pump 18
- Air source heat pump 19
- Air source heat pump 2
- Air source heat pump 20
- Air source heat pump 21
- Air source heat pump 22
- Air source heat pump 23
- Air source heat pump 24
- Air source heat pump 25
- Air source heat pump 26
- Air source heat pump 27
- Air source heat pump 28
- Air source heat pump 29
- Air source heat pump 3
- Air source heat pump 30
- Air source heat pump 31
- Air source heat pump 32
- Air source heat pump 33
- Air source heat pump 34
- Air source heat pump 35
- Air source heat pump 36
- Air source heat pump 37
- Air source heat pump 38
- Air source heat pump 39
- Air source heat pump 4
- Air source heat pump 40
- Air source heat pump 41
- Air source heat pump 5
- Air source heat pump 6
- Air source heat pump 7
- Air source heat pump 8
- Air source heat pump 9
- Akbari et al, 2014 - Optinal investment and unit sizing of distributed energy systems under uncertainty: A robust optimization approach
- Akomeno Omu
- Andrew Bollinger
- Ashouri et al, 2013 - Optimal design and operation of building services using mixed-integer linear programming techniques
- Aste et al, 2013 - Cost optimal analysis of heat pump technology adoption in residential reference buildings
- Aste et al, 2013 - Cost optimal analysis of heat pump technology adoption in residential regerence buildings
- Bidirectional massflow LTN (IDA ICE)
- Biomass air turbine 1
- Biomass boiler 1
- Biomass boiler 10
- Biomass boiler 11
- Biomass boiler 12
- Biomass boiler 13
- Biomass boiler 14
- Biomass boiler 15
- Biomass boiler 16
- Biomass boiler 17
- Biomass boiler 18
- Biomass boiler 19
- Biomass boiler 2
- Biomass boiler 20
- Biomass boiler 21
- Biomass boiler 22
- Biomass boiler 23
- Biomass boiler 24
- Biomass boiler 25
- Biomass boiler 26
- Biomass boiler 27
- Biomass boiler 28
- Biomass boiler 29
- Biomass boiler 3
- Biomass boiler 30
- Biomass boiler 31
- Biomass boiler 32
- Biomass boiler 33
- Biomass boiler 34
- Biomass boiler 35
- Biomass boiler 36
- Biomass boiler 37
- Biomass boiler 38
- Biomass boiler 39
- Biomass boiler 4
- Biomass boiler 40
- Biomass boiler 41
- Biomass boiler 42
- Biomass boiler 43
- Biomass boiler 44
- Biomass boiler 45
- Biomass boiler 46
- Biomass boiler 47
- Biomass boiler 48
- Biomass boiler 49
- Biomass boiler 5
- Biomass boiler 50
- Biomass boiler 51
- Biomass boiler 52
- Biomass boiler 53
- Biomass boiler 54
- Biomass boiler 6
- Biomass boiler 7
- Biomass boiler 8
- Biomass boiler 9
- Biomass steam turbine 1
- Biomass steam turbine 2
- Bischi et al, 2014 - A detailed MILP optimization model for combined cooling, heat, and power system operation planning
- Blarke and Dotzauer, 2011 - Intermittency-friendly and high-efficiency cogeneration: Operational optimisation of cogeneration with compression heat pump, flue gas heat recovery, and intermediate cold storage
- Boran Morvaj
- Bosman et al, 2012 - Planning the production of a fleet of domestic combined heat and power generators
- Bracco et al, 2013 - Economic and environmental optimization model for the design and the operation of a combined heat and power distributed generation system in an urban area
- Bracco et al, 2014 - A mathematical model for the optimal operation of the University of Genoa Smart Polygeneration Microgrid: Evaluation of technical, economic and environmental performance indicators
- Brahman et al, 2015 - Optimal electrical and thermal energy management of a residential energy hub, integrating demand response and energy storage system
- Build eplus multizone combined.m (Stochastic building energy demand generator)
- Build eplus v2.m (Simple building energy model Rheinfelden)
- Building energy model
- Building energy modules
- Building occupancy
- Building occupancy modules
- Building simulation
- Buoro et al, 2011 - Optimization of Distributed Trigeneration Systems Integrated with Heating and Cooling Microgrids
- Buoro et al, 2013 - Multicriteria optimization of a distributed energy supply system for an industrial area
- Buoro et al, 2014 - Optimization of Distributed Cogeneration System with solar district heating
- CCGT 1
- CCGT 10
- CCGT 11
- CCGT 2
- CCGT 3
- CCGT 4
- CCGT 5
- CCGT 6
- CCGT 7
- CCGT 8
- CCGT 9
- CC BY-NC-SA
- CC BY-NC 3.0
- Calliope
- Cano et al, 2014 - A strategic optimization model for energy systems planning
- Capuder and Mancarella, 2014 - Techno-economic and environmental modelling and optimization of flexible distributed multi-generation options
- Capuler and Mancarella, 2014 - Techno-economic and environmental modelling and optimization of flexible distributed multi-generation options
- Cardoso et al, 2013 - Microgrid reliability modeling and battery scheduling using stochastic linear programming
- Carrier.m (YALMIP EHUBV1 0)
- Carvalho et al, 2011 - Optimal systhesis of trigeneration systems subject to environmental constraints
- Case study data:test
- Casisi et al, 2009 - Optimal lay-out and operation of combined heat and power (CHP) distribtued generation systems
- Casisi et al, 2015 - Effect of different economic support policies on the optimal systhesis and operation of a distribued energy supply system with renewable energy sources for an industrial area
- Chinese, 2008 - Optimal size and layout planning for district heating and cooling networks with distributed generation options
- Christoph Waibel
- Code repository
- Collazos et al, 2009 - Predictive optimal management method for the control of polygeneration systems
- Collections
- Comments:Feedback and suggestions
- Component.m (YALMIP EHUBV1 0)
- ComponentF.m (YALMIP EHUBV1 0)
- ComponentFS.m (YALMIP EHUBV1 0)
- ComponentS.m (YALMIP EHUBV1 0)
- ComponentSC.m (YALMIP EHUBV1 0)
- ComponentSCL.m (YALMIP EHUBV1 0)
- Computational time
- Contact information
- Contribute - add models, code or data
- Costa and Fichera, 2014 - A mixed-integer linear programming (MILP) model for the evaluation of CHP system in the context of hospital structures
- Create matfile.m (Stochastic building energy demand generator)
- Crossover.m (NSGA-II)
- Crowding.m (NSGA-II)
- DG.aimms (Bilevel GA+MILP combined with MATPOWER for electrical grid power flow calculations)
- DHWDemandData 525600.xlsx (Energy hub batch run with minute resolution)
- Data class:Building cooling demand time series, hourly
- Data class:Building electricity demand time series, hourly
- Data class:Building heating demand time series, hourly
- Data class:Building occupancy time series, hourly
- Data class:Building temperature setpoints time series, hourly
- Data class:Cooling demand time series, hourly
- Data class:Electricity demand time series, hourly
- Data class:Electricity generation time series, hourly
- Data class:Heat generation time series, hourly
- Data class:Heating demand time series, hourly
- Data class:Network description (links)
- Data class:Network description (nodes)
- Data class:Solar radiation data, hourly
- Data class:Storage state of charge time series, hourly
- Data class:test
- Data classes
- DeForest et al, 2014 - Optimal deployment of thermal energy storage under diverse economic and climate conditions
- Development pages
- Directions for submitting modules
- District heating network routing
- Dominance matrix.m (NSGA-II)
- Download the technology database
- Dvorak and Havel, 2012 - Combined heat and power production planning under liberalized market conditions
- Effects of district size on optimal energy hub configuration considering demand variability
- Electric heater 1
- Electric heater 10
- Electric heater 11
- Electric heater 12
- Electric heater 13
- Electric heater 14
- Electric heater 15
- Electric heater 16
- Electric heater 17
- Electric heater 18
- Electric heater 19
- Electric heater 2
- Electric heater 20
- Electric heater 21
- Electric heater 22
- Electric heater 23
- Electric heater 24
- Electric heater 25
- Electric heater 26
- Electric heater 27
- Electric heater 28
- Electric heater 3
- Electric heater 4
- Electric heater 5
- Electric heater 6
- Electric heater 7
- Electric heater 8
- Electric heater 9
- EmpaCase.m (YALMIP EHUBV1 0)
- EmpaCaseWrapper.m (YALMIP EHUBV1 0)
- EmpaData.mat (YALMIP EHUBV1 0)
- EmpaDataShifted.mat (YALMIP EHUBV1 0)
- EnergyHub.ams (Energy hub batch run with minute resolution)
- EnergyPlus
- EnergyPlus batch run module
- EnergyPlus batch run module (EnergyPlus batch run module)
- Energy Hub.ams (Energy hub model for design, sizing and operation of an energy system of a building or an aggregation of buildings)
- Energy Hub.ams (Energy hub model for design sizing and operation of an energy system of a building or an aggregation of buildings)
- Energy hub
- Energy hub batch run with minute resolution
- Energy hub literature portal
- Energy hub model
- Energy hub model for design, sizing and operation of an energy system of a building or an aggregation of buildings
- Energy hub model for design (Energy hub model for design sizing and operation of an energy system of a building or an aggregation of buildings)
- Energy hub modules
- Energyhub.m (YALMIP EHUBV1 0)
- Energyplus
- Eplus add.m (EnergyPlus batch run module)
- Eplus build.m (EnergyPlus batch run module)
- Eplus buildpara.m (EnergyPlus batch run module)
- Eplus edit.m (EnergyPlus batch run module)
- Eplus edit.m (NSGA-II)
- Eplus makelayout.m (EnergyPlus batch run module)
- Eplus paralist.m (EnergyPlus batch run module)
- Eplus readcsv.m (EnergyPlus batch run module)
- Eplus readcsv.m (NSGA-II)
- Eplus run.m (EnergyPlus batch run module)
- Eplus run.m (NSGA-II)
- Eplus runmulti.m (EnergyPlus batch run module)
- Erdinc, 2014 - Economic impacts of small-scale own generating and storage units, and electric vehicles under different demand response strategies for smart households
- Erdinc et al, 2015 - A new perspective for sizing of distributed generation and energy storage for smart households under demand response
- Eval pop.m (NSGA-II)
- Evins et al, 2014 - New formulations of the 'enrgy hub' model to address operational constraints
- Explanation of module ratings
- External resources
- F nsga2.m (NSGA-II)
- Fast Fluid Dynamics
- Fazlollahi and Marechal, 2013 - Multi-objective, multi-period optimization of biomass conversion technoogies using evolutionary algorithms and mixed integer linear programming (MILP)
- Fazlollahi et al, 2012 - Methods for multi-objective investment and operating optimization of complex energy systems
- Fazlollahi et al, 2014 - Multi-objectives, multi-period optimization of district energy systems: II. Daily thermal storage
- Fazlollahi et al, 2014 - Multi-objectives, multi-period optimization of district energy systems: III. Distribution networks
- Fazlollahi et al, 2015 - Multi-objective, multi-period optimization of district energy systems: IV - A case study
- Feedback and suggestions
- Ferrer-Marti et al, 2013 - A MILP model to design hybrid wind-photovoltaic isolated rural electrification projects in developing countries
- Fuel cell 1
- Fuel cell 10
- Fuel cell 11
- Fuel cell 12
- Fuel cell 13
- Fuel cell 14
- Fuel cell 15
- Fuel cell 16
- Fuel cell 17
- Fuel cell 18
- Fuel cell 19
- Fuel cell 2
- Fuel cell 20
- Fuel cell 21
- Fuel cell 22
- Fuel cell 23
- Fuel cell 24
- Fuel cell 25
- Fuel cell 26
- Fuel cell 27
- Fuel cell 28
- Fuel cell 29
- Fuel cell 3
- Fuel cell 30
- Fuel cell 31
- Fuel cell 32
- Fuel cell 33
- Fuel cell 34
- Fuel cell 35
- Fuel cell 36
- Fuel cell 37
- Fuel cell 38
- Fuel cell 39
- Fuel cell 4
- Fuel cell 40
- Fuel cell 41
- Fuel cell 42
- Fuel cell 43
- Fuel cell 44
- Fuel cell 45
- Fuel cell 46
- Fuel cell 47
- Fuel cell 5
- Fuel cell 6
- Fuel cell 7
- Fuel cell 8
- Fuel cell 9
- Fuentes-Cortes et al, 2015 - Optimal desgin of integrated CHP systems for housing complexes
- Fuentes-Cortes et al, 2015 - Optimal design of integrated CHP systems for housing complexes
- GSoC Projects
- Gas Turbine 1
- Gas engine 1
- Gas engine 2
- Gas turbine 1
- Gas turbine 10
- Gas turbine 11
- Gas turbine 12
- Gas turbine 13
- Gas turbine 14
- Gas turbine 15
- Gas turbine 16
- Gas turbine 17
- Gas turbine 18
- Gas turbine 19
- Gas turbine 2
- Gas turbine 20
- Gas turbine 21