Electricity, natural gas, water, and dis trict heating/cooling systems are predominantly planned and operated independently. However, it is increasingly recognized that integrated optimization and control of such systems at multiple spatiotemporal scales can bring significant socioeconomic, operational efficiency, and environmental benefits. Accordingly, the concept of the multi-energy system is gaining considerable attention, with the overarching objectives of 1) uncovering fundamental gains (and potential drawbacks) that emerge from the integrated operation of multiple systems and 2) developing holistic yet computationally affordable optimization and control methods that maximize operational benefits, while 3) acknowledging intrinsic interdependencies and quality-of-service requirements for each provider.
[1]
G. Andersson,et al.
Energy hubs for the future
,
2007,
IEEE Power and Energy Magazine.
[2]
Pierluigi Mancarella,et al.
Real-Time Demand Response From Energy Shifting in Distributed Multi-Generation
,
2013,
IEEE Transactions on Smart Grid.
[3]
Rita Streblow,et al.
Demand side management for city districts
,
2015
.
[4]
Andrea Simonetto,et al.
Optimal Power Flow Pursuit
,
2018,
IEEE Transactions on Smart Grid.
[5]
Pierluigi Mancarella,et al.
Integrated electrical and gas network flexibility assessment in low-carbon multi-energy systems
,
2016,
2016 IEEE Power and Energy Society General Meeting (PESGM).