Your search keyword '"Gregor Papa"' showing total 2 results

1. δ-perturbation of bilevel optimization problems: An error bound analysis

Author

Margarita Antoniou, Ankur Sinha, and Gregor Papa

Subjects

Bilevel optimization, Optimistic bilevel problem, Pessimistic bilevel problem, Perturbation method, Error bound, Iterative heuristics, Mathematics, QA1-939

Abstract

In this paper, we analyze a perturbed formulation of bilevel optimization problems, which we refer to as δ-perturbed formulation. The δ-perturbed formulation allows to handle the lower level optimization problem efficiently when there are multiple lower level optimal solutions. By using an appropriate perturbation strategy for the optimistic or pessimistic formulation, one can ensure that the optimization problem at the lower level contains only a single (approximate) optimal solution for any given decision at the upper level. The optimistic or the pessimistic bilevel optimal solution can then be efficiently searched for by algorithms that rely on solving the lower level optimization problem multiple times during the solution search procedure. The δ-perturbed formulation is arrived at by adding the upper level objective function to the lower level objective function after multiplying the upper level objective by a small positive/negative δ. We provide a proof that the δ-perturbed formulation is approximately equivalent to the original optimistic or pessimistic formulation and give an error bound for the approximation. We apply this scheme to a class of algorithms that attempts to solve optimistic and pessimistic variants of bilevel optimization problems by repeatedly solving the lower level optimization problem.

Published

2024

2. A comparison of models for forecasting the residential natural gas demand of an urban area

Author

Gregor Papa, Primož Potočnik, Rok Hribar, and Jurij Šilc

Subjects

napovedovanje odjema, 020209 energy, media_common.quotation_subject, forecast accuracy, 02 engineering and technology, Urban area, Industrial and Manufacturing Engineering, 020401 chemical engineering, Natural gas, energetsko modeliranje, Linear regression, 0202 electrical engineering, electronic engineering, information engineering, Econometrics, udc:004.9:620.9(045), 0204 chemical engineering, Electrical and Electronic Engineering, Civil and Structural Engineering, media_common, natančnost napovedi, geography, geography.geographical_feature_category, Artificial neural network, zgradbe, business.industry, Mechanical Engineering, Empirical modelling, Building and Construction, Pollution, buildings, strojno učenje, demand forecasting, General Energy, Kernel method, Recurrent neural network, machine learning, Service (economics), energy modeling, Environmental science, business

Abstract

Forecasting the residential natural gas demand for large groups of buildings is extremely important for efficient logistics in the energy sector. In this paper different forecast models for residential natural gas demand of an urban area were implemented and compared. The models forecast gas demand with hourly resolution up to 60 h into the future. The model forecasts are based on past temperatures, forecasted temperatures and time variables, which include markers for holidays and other occasional events. The models were trained and tested on gas-consumption data gathered in the city of Ljubljana, Slovenia. Machine-learning models were considered, such as linear regression, kernel machine and artificial neural network. Additionally, empirical models were developed based on data analysis. Two most accurate models were found to be recurrent neural network and linear regression model. In realistic setting such trained models can be used in conjunction with a weather-forecasting service to generate forecasts for future gas demand.

Published

2019