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Set of instances used in article "Optimal management of collective Photovoltaic Systems in Spanish Multi-dwelling buildings"

「スペイン集合住宅における共同太陽光発電システムの最適管理」で使用したインスタンスデータセット (AI 翻訳)

Alonso-Ayuso, Antonio, Benito-Orea, Silvia, Martin-Campo, F. Javier, MOLINA, ELISENDA, Terán-Viadero, Paula

Zenodoプレプリント2026-07-02#再生可能エネルギーOrigin: EU経営インパクト: コスト削減対象セクター: real_estate
DOI: 10.5281/zenodo.21106781
原典: https://zenodo.org/records/21106781

🤖 gxceed AI 要約

日本語

本データセットは、スペインの集合住宅における太陽光発電の共同最適管理モデルを再現するための入力データと最適化結果を提供する。6つの住宅コミュニティ、5都市の日射量、時間別需要・料金データを含む。

English

This dataset provides input data and optimization results to reproduce a deterministic optimization model for collective photovoltaic energy allocation in Spanish multi-dwelling buildings. It includes hourly demand, generation, and tariff data for six communities across five Spanish cities.

Unofficial AI-generated summary based on the public title and abstract. Not an official translation.

📝 gxceed 編集解説 — Why this matters

日本のGX文脈において

スペイン特有の規制に基づくが、日本のマンションにおける共同太陽光発電の最適配分にも応用可能。マンションの共用部・個別住戸の需要を考慮したモデルは、日本のFIT/FIP制度下でのコミュニティソーラーにも示唆を与える。

In the global GX context

While specific to Spanish regulations, this optimization model for collective PV sharing in multi-dwelling buildings is relevant to the global trend of energy communities and prosumer models. The dataset enables benchmarking and adaptation to other regulatory contexts.

👥 読者別の含意

🔬研究者:PV sharing optimization researchers can use this dataset for benchmarking and validating their own models.

🏢実務担当者:Energy managers and property developers may gain insights into cost-effective PV sharing strategies for multi-dwelling buildings.

🏛政策担当者:Policymakers designing energy sharing regulations can examine the impact of different time-based allocation policies (hourly, daily, monthly) on self-consumption and savings.

📄 Abstract(原文)

The dataset presented is used in the article "Optimal management of collective Photovoltaic Systems in Spanish Multi-dwelling buildings" by Antonio Alonso-Ayuso, Silvia Benito-Orea, F. Javier Martín-Campo, Elisenda Molina and Paula Terán-Viadero, submitted for publication (2026). This paper proposes a deterministic mathematical optimization model for the allocation of photovoltaic energy in multi-dwelling residential buildings, developed in accordance with the regulatory framework governing the Spanish energy market. The model considers the electricity consumption profiles of individual users, as well as the demand associated with communal facilities such as entrance halls, elevators, garages, and swimming pools, among others.  The dataset contains the input data and optimization results required to reproduce the computational experiments presented in the paper. Six residential communities are considered: I20a, I20b, I40a, I40b, I60a, and I60b. For each community, three CSV files are provided: <community>_demand.csv : Hourly electricity demand for the entire study year. The file contains the electricity consumption of all community supply points and individual supply points in the corresponding residential community. <community>_weight.csv : Participation coefficients of the individual supply points (households and commercial units) in each community supply point. Rows correspond to individual supply points, while columns correspond to community supply points. The coefficients of each community supply point sum to 1. <community>_tariff.csv : Hourly electricity purchase prices and surplus energy compensation prices for the entire study year. The file ProduccionFotovoltaica.csv contains the hourly photovoltaic generation profiles for the five cities considered in the study: Barcelona, Bilbao, Huelva, Madrid, and Ourense. The file Results.zip contains the optimization results, Pareto front points, and payoff matrices. The archive is organized into two main folders: PV50 : Results assuming that the photovoltaic installation is sized to cover 50% of the annual electricity demand of the residential community. PV100 : Results assuming that the photovoltaic installation is sized to cover 100% of the annual electricity demand. Each of these folders contains five subfolders corresponding to the analyzed cities (Barcelona, Bilbao, Huelva, Madrid, and Ourense). Within each city folder, there are six subfolders corresponding to the six residential communities (I20a, I20b, I40a, I40b, I60a, and I60b). Each community folder contains six Excel workbooks, corresponding to the six energy-sharing policies considered in the study (hourly, daily, weekly, monthly, bimonthly, and four-monthly), together with two additional folders: ParetoValues and PayoffMatrices . Each Excel workbook contains four worksheets: Input_data : Summary of the case study, including the residential community, total number of supply points, number of community and individual supply points, time horizon, city, minimum percentage of photovoltaic generation allocated to community supply points, and other model parameters. Energy_summary : Summary of the energy-sharing results, including photovoltaic generation, self-consumption, electricity demand, community demand, electricity imported from the grid, exported surplus energy, monetary savings, and surplus compensation. Distribution : Hourly values for every supply point throughout the entire study horizon. The reported variables include photovoltaic generation, electricity demand, grid imports, photovoltaic energy allocation, surplus energy, and the energy-sharing coefficient (beta). Although all data are reported at hourly resolution, the sharing policy determines the time intervals over which the beta coefficient remains constant. For example, under the daily policy, the beta values are identical for all 24 hours of the same day. Model_performance : Optimization model statistics, including the objective function value, solution time, solver status, and the number of variables and constraints. The ParetoValues folder contains one Excel workbook with two worksheets: Self-Consuming : Pareto front points obtained using the self-consumption objective. Savings : Pareto front points obtained using the monetary savings objective. The PayoffMatrices folder contains six Excel workbooks, one for each energy-sharing policy, reporting the payoff matrices for the self-consumption and monetary savings objectives.  

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