Pietro Rando Mazzarino scite author profile

Pietro Rando Mazzarino

5Publications

13Citation Statements Received

98Citation Statements Given

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How they cite others

131

Affiliations

Polytechnic University of Turin

Publications

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IoT-Enabled Real-Time Management of Smart Grids With Demand Response Aggregators

Estebsari

Mazzarino

Bottaccioli

et al. 2022

IEEE Trans. on Ind. Applicat.

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Integration of widely distributed small-scale Renewable Energy Sources like rooftop Photovoltaic panels and emerging loads like plug-in Electric Vehicles would cause more volatility in total net demand of distribution networks. Utility-owned storage units and control devices like tap changers and capacitors may not be sufficient to manage the system in real-time. Exploitation of available flexibility in demand side through aggregators is a new measure that distribution system operators are interested in. In this paper, we present a developed real-time management schema based on Internet of Things solutions which facilitate interactions between system operators and aggregators for ancillary services like power balance at primary substation or voltage regulation at secondary substations. Two algorithms for power balance and voltage regulation are developed based on modified Optimal Power Flow and voltage sensitivity matrix, respectively. To demonstrate the applicability of the schema, we set-up a real-time simulationbased test bed and realised the performance of this approach in a real-like environment using real data of a network with residential buildings.

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An agent-based framework for smart grid balancing exploiting thermal flexibility of residential buildings

Mazzarino

Vizia

Macii

et al. 2021

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A Multi-Agent Framework for Smart Grid Simulations: Strategies for power-to-heat flexibility management in residential context

Mazzarino

Macii

Bottaccioli

et al. 2023

Sustainable Energy, Grids and Networks

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A comparison study of co-simulation frameworks for multi-energy systems: the scalability problem

et al. 2022

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The transition to a low-carbon society will completely change the structure of energy systems from a standalone hierarchical centralised vision to cooperative and distributed Multi-Energy Systems. The analysis of these complex systems requires the collaboration of researchers from different disciplines in the energy, ICT, social, economic, and political sectors. Combining such disparate disciplines into a single tool for modeling and analyzing such a complex environment as a Multi-Energy System requires tremendous effort. Researchers have overcome this effort by using co-simulation techniques that give the possibility of integrating existing domain-specific simulators in a single environment. Co-simulation frameworks, such as Mosaik and HELICS, have been developed to ease such integration. In this context, an additional challenge is the different temporal and spatial scales that are involved in the real world and that must be addressed during co-simulation. In particular, the huge number of heterogeneous actors populating the system makes it difficult to represent the system as a whole. In this paper, we propose a comparison of the scalability performance of two major co-simulation frameworks (i.e. HELICS and Mosaik) and a particular implementation of a well-known multi-agent systems library (i.e. AIOMAS). After describing a generic co-simulation framework infrastructure and its related challenges in managing a distributed co-simulation environment, the three selected frameworks are introduced and compared with each other to highlight their principal structure. Then, the scalability problem of co-simulation frameworks is introduced presenting four benchmark configurations to test their ability to scale in terms of a number of running instances. To carry out this comparison, a simplified multi-model energy scenario was used as a common testing environment. This work helps to understand which of the three frameworks and four configurations to select depending on the scenario to analyse. Experimental results show that a Multi-processing configuration of HELICS reaches the best performance in terms of KPIs defined to assess the scalability among the co-simulation frameworks.

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A Multi-Agent framework to evaluate energy flexibility in District Heating networks

Mazzarino

Capone

Guelpa

et al. 2022

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