Florentin Hildebrandt

Research Associate

M.Sc. Florentin Hildebrandt

Fakultät für Wirtschaftswissenschaft (FWW)
Lehrstuhl BWL, insb. Management Science
Universitätsplatz 2, 39106, Magdeburg, G22-A358
Curriculum Vitae
 

03/2023 - 06/2023

Visiting researcher, Dipartimento di Ingegneria dell'Informazione, Università di Padova
 

Since 10/2021

Research associate, Chair of Management Science, Otto-von-Guericke-Universität Magdeburg
 

03/2020 - 10/2021

Research associate, Decision Support group, Technische Universität Braunschweig

 

10/2017 - 02/2020

Master of Science in Mathematics, Georg-August-Universität Göttingen

 

03/2019 - 03/2020

Student worker, BESSY II, Helmholtz-Zentrum Berlin

 

10/2018 - 03/2019

Intern, 4flow Management, 4flow

 

10/2017 - 10/2018

Student worker, AG Optimierung, Georg-August-Universität Göttingen

 

10/2013 - 07/2017

Bachelor of Science in Mathematics, Georg-August-Universität Göttingen

Publications

2024

Book chapter

Tourenplanung

Ackva, Charlotte; Fassnacht, Lukas; Henninger, Steffen; Hildebrandt, Florentin; Spühler, Felix

In: Radlogistik - Grundlagen zu Logistik und Wirtschaftsverkehr mit Lasten- und Transporträdern - Wiesbaden : Springer Fachmedien Wiesbaden ; Assmann, Tom *1989-* . - 2024, S. 197-212

Standortplanung

Ackva, Charlotte; Fassnacht, Lukas; Hildebrandt, Florentin; Spühler, Felix

In: Radlogistik - Grundlagen zu Logistik und Wirtschaftsverkehr mit Lasten- und Transporträdern - Wiesbaden : Springer Fachmedien Wiesbaden ; Assmann, Tom *1989-* . - 2024, S. 177-195

2023

Peer-reviewed journal article

Opportunities for reinforcement learning in stochastic dynamic vehicle routing

Hildebrandt, Florentin D.; Thomas, Barrett W.; Ulmer, Marlin Wolf

In: Computers & operations research - Amsterdam [u.a.] : Elsevier, Bd. 150 (2023), Artikel 106071

Non-peer-reviewed journal article

Reinforcement learning variants for stochastic dynamic combinatorial optimization problems in transportation

Hildebrandt, Florentin D.; Bode, Alexander; Ulmer, Marlin Wolf; Mattfeld, Dirk C.

In: Magdeburg: Otto-von-Guericke-Universität Magdeburg: Fakultät für Wirtschaftswissenschaft, 2023, 1 Online-Ressource (38 Seiten, 0,82 MB) - (Working paper series; Otto von Guericke Universität Magdeburg, Faculty of Economics and Management; 2023, no. 06)

2021

Peer-reviewed journal article

Supervised learning for arrival time estimations in restaurant meal delivery

Hildebrandt, Florentin; Ulmer, Marlin W.

In: Transportation science - Hanover, Md. : INFORMS . - 2021 [Online first]

Projects

Current projects

Meal-Delivery Operations
Duration: 01.01.2023 bis 31.10.2025

We analyze planning and operations in restaurant meal-delivery, We consider the design of different delivery systems. We further optimize demand and fleet control in an integrated manner, and use machine learning for delivery time predictions.

View project in the research portal

Completed projects

Integrating machine learning in combinatorial dynamic optimization for urban transportation services
Duration: 01.09.2022 bis 31.08.2024

The goal of this project is to provide effective decision support for stochastic dynamic pickup and delivery problems by combining the strengths of mixed-integer linear programming (MILP) and reinforcement learning (RL).Stochastic dynamic pickup-and-delivery problems play an increasingly important role in urban logistics. They are characterized by the often time-critical transport of wares or passengers in the city. Common examples are same-day delivery, ridesharing, and restaurant meal delivery. The mentioned problems have in common that a sequence of decision problems with future uncertainty must be solved in every decision step where the full value of a decision reveals only later in the service horizon. Searching the combinatorial decision space of the subproblems for efficient and feasible tours is a complex task of solving a MILP. This complexity is now multiplied by the challenge of evaluating such decision with respect to their effectiveness given future dynamism and uncertainty; an ideal case for RL. Both are crucial to fully meet operational requirements. Therefore, a direct combination of both methods is needed. Yet, a seamless integration has not been established due to different reasons and is the aim of this research project. We suggest using RL to manipulate the MILP itself to derive not only efficient but also effective decisions. This manipulation may change the objective function or the constraints. Incentive or penalty terms can be added to the objective function to enforce or prohibit the selection of certain decisions. Alternatively, the constraints may be adapted to reserve fleet-resources.The challenge is to decide where and how the manipulation takes place. SDPDPs have constraints with respect to routing, vehicle capacities, or time windows. Some constraints may be irrelevant for the fleet’s flexibility while others might be binding. The first part of the research project focuses on identifying the "interesting” parts of the MILP via (un-)supervised learning. Once the "interesting” parts are identified, the second challenge is to find the right parametrization. Here, we will apply RL methods to learn the state-dependent manipulation of the MILP components.

View project in the research portal

Opportunities for Machine Learning in Urban Logistics
Duration: 01.03.2020 bis 31.08.2024

There has been a paradigm-shift in urban logistic services in the last years; global interconnectedness, urbanization, ubiquitous information streams, and increased service-orientation raise the need for anticipatory real-time decision making. A striking example are logistic service providers: Service promises, like same-day or restaurant meal delivery, dial-a-ride, and emergency repair, force logistic service providers to anticipate future demand, adjust to real-time traffic information, or even incorporate unknown crowdsourced drivers to fulfill customer expectations. Data-driven, anticipatory approaches are required to overcome the challenges of such services. They promise to improve customer satisfaction through accurate predictions (e.g., via supervised learning), enhanced fleet control (e.g., via reinforcement learning), and identification of demand patterns and delivery scenarios (e.g., via unsupervised learning). Within this research project, we combine recent advances in machine learning with established methods from operations research to tackle present-day challenges in urban logistics.

View project in the research portal

Awards and Grants
  • Transportation Science Meritorious Service Award 2024
  • Transportation Science Meritorious Service Award 2023
  • Transportation Science Meritorious Service Award 2022

Last Modification: 29.11.2024 - Contact Person: