The complexity of cyber-physical systems is rising in line with the everyday advancements in technology and industry. Smart power grids, autonomous cars, distributed sensor networks, advanced robotic systems, district heating networks, and traffic platoons are only a few examples of such systems. Their primary features are high complexity, operation in complex time-varying environments, and safety-critical issues. Utilizing measurement data, one may develop model-based or model-free techniques for controlling them. One may employ purely physics-based models built from available information in the model-based strategy. To produce a model representing reality precisely, we need a comprehensive grasp of the system's nature and a method for generating detailed models from the first principles. Due to the information limitations, this is not feasible in many applications. Also, this framework results in estimating an immense amount of parameters via non-convex large-scale optimizations formulated based on limited, heterogeneous, and noisy data, which further decreases their performance. One may utilize a reasonably simple physics-based model with few parameters to address these concerns. Though the built model may show meaningful behaviors, it may not fairly represent reality due to its excessive simplicity and inadequate inclusion of the first principles. Thus, the resulting decision-making is vulnerable to substantial bias and error.

Recent machine and reinforcement learning advances have delivered promising directions for developing black-box models, particularly when complexity prevents direct physics-based description. When a massive amount of informative data is provided, advanced ML methods may identify features and structures, so that the model is interpretable. Modern ML algorithms can capture complicated spatio-temporal patterns; however, they require extensive data, which is seldom accessible in most real-world settings. Moreover, ML models may not be capable of extending to out-of-sample contexts as they only identify links in the training data. Since naïve application of ML techniques to the data results in a blind interpretation of reality, the critical underlying traits are disregarded. Thus, inconsistent results may be obtained. Hence, if there is significant uncertainty or the model structures are relatively complicated, the generated models will not correctly represent reality. Therefore, we have high inaccuracies in the models, and decision-making is vulnerable to risks. Though the inclusion of model uncertainty may address safety issues, it results in over-conservativism according to model mismatches leaked into the ambiguity envelopes. Thus, the decision-making policy will be sub-optimal. Analogous arguments exist for model-free approaches when certain aspects of reality are ignored.

The ML methods can be modified to become applicable for autonomous and large-scale complex systems by including readily available side-information on the underlying reality. This allows the rejection of inconsistent models and decisions. Subsequently, we obtain more interpretable models and decisions. Additionally, imposing specific attributes can promote more effective control mechanisms. Motivated by the above discussion, we need to derive trustworthy and tractable data-driven and learning-based control schemes incorporating side-information systematically and correctly. As the side-information can originate from various sources and no standardized procedure exists for its inclusion, the emphasis will be more on standard structures. To achieve this objective, we need to leverage advanced mathematical frameworks like the theory of reproducing kernel Hilbert spaces, Gaussian processes, and Koopman operator theory. The results should be delivered as a user-friendly numerical toolbox validated in real-world settings like energy systems, district heating networks, buildings, and greenhouses.

• You have obtained an MSc degree, or will receive it before the starting date of the position, in one of the following science and engineering fields: Electrical Engineering, Systems & Control, Mathematics, Mechanical Engineering, or similar disciplines.
• The candidate should have a solid mathematical background and has willing to learn further and get skilled in advanced mathematical topics such as functional analysis, PDE, optimization, and probability theory.
• You have a good command of the English language.

Doing a PhD at TU Delft requires English proficiency at a certain level to ensure that the candidate is able to communicate and interact well, participate in English-taught Doctoral Education courses, and write scientific articles and a final thesis. For more details please check the Graduate Schools Admission Requirements.

Doctoral candidates will be offered a 4-year period of employment in principle, but in the form of 2 employment contracts. An initial 1,5 year contract with an official go/no go progress assessment within 15 months. Followed by an additional contract for the remaining 2,5 years assuming everything goes well and performance requirements are met.

Salary and benefits are in accordance with the Collective Labour Agreement for Dutch Universities, increasing from € 2541 per month in the first year to € 3247 in the fourth year. As a PhD candidate you will be enrolled in the TU Delft Graduate School. The TU Delft Graduate School provides an inspiring research environment with an excellent team of supervisors, academic staff and a mentor. The Doctoral Education Programme is aimed at developing your transferable, discipline-related and research skills.

The TU Delft offers a customisable compensation package, discounts on health insurance and sport memberships, and a monthly work costs contribution. Flexible work schedules can be arranged. 

For international applicants, TU Delft has the Coming to Delft Service. This service provides information for new international employees to help you prepare the relocation and to settle in the Netherlands. The Coming to Delft Service offers a Dual Career Programme for partners and they organise events to expand your (social) network.

Delft University of Technology

Delft University of Technology is built on strong foundations. As creators of the world-famous Dutch waterworks and pioneers in biotech, TU Delft is a top international university combining science, engineering and design. It delivers world class results in education, research and innovation to address challenges in the areas of energy, climate, mobility, health and digital society. For generations, our engineers have proven to be entrepreneurial problem-solvers, both in business and in a social context.

At TU Delft we embrace diversity as one of our core values and we actively engage to be a university where you feel at home and can flourish. We value different perspectives and qualities. We believe this makes our work more innovative, the TU Delft community more vibrant and the world more just. Together, we imagine, invent and create solutions using technology to have a positive impact on a global scale. That is why we invite you to apply. Your application will receive fair consideration.

Challenge. Change. Impact!

Faculty Mechanical, Maritime and Materials Engineering

From chip to ship. From machine to human being. From idea to solution. Driven by a deep-rooted desire to understand our environment and discover its underlying mechanisms, research and education at the 3mE faculty focusses on fundamental understanding, design, production including application and product improvement, materials, processes and (mechanical) systems.

3mE is a dynamic and innovative faculty with high-tech lab facilities and international reach. It’s a large faculty but also versatile, so we can often make unique connections by combining different disciplines. This is reflected in 3mE’s outstanding, state-of-the-art education, which trains students to become responsible and socially engaged engineers and scientists. We translate our knowledge and insights into solutions to societal issues, contributing to a sustainable society and to the development of prosperity and well-being. That is what unites us in pioneering research, inspiring education and (inter)national cooperation.

Click here to go to the website of the Faculty of Mechanical, Maritime and Materials Engineering. Do you want to experience working at our faculty? These videos will introduce you to some of our researchers and their work.