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aira:start [2024/03/19 07:01] – [2024-03-14] sbk | aira:start [2024/04/26 07:32] – [Schedule Summer 2024] sbk | ||
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===== Schedule Summer 2024 ===== | ===== Schedule Summer 2024 ===== | ||
- | * **[DOCTORAL TRACK] 2024.03.21**: Maciej Szelążek | + | * **[DOCTORAL TRACK] 2024.04.25**: Bortłomiej Małkus |
- | * Meeting link: [[|MS Teams]] | + | * Meeting link: [[https:// |
+ | * Recording: [[https:// | ||
+ | * Presentation slides: {{ |Download}} | ||
+ | * **[DOCTORAL TRACK] 2024.04.18** | ||
+ | * Farnoud Ghasemi [[# | ||
+ | * Michał Bujak [[# | ||
+ | * Meeting link: [[https:// | ||
+ | * Recording: [[https:// | ||
+ | * Presentation slides: {{: | ||
+ | * **[RESEARCH TRACK] 2024.04.04**: | ||
+ | * Meeting link: [[https:// | ||
+ | * Recording: [[https:// | ||
+ | * Presentation slides: {{ : | ||
+ | * **[RESEARCH TRACK] 2024.03.28**: | ||
+ | * Meeting link: [[https:// | ||
* Recording: [[|View]] (if you are not UJ employee, ask Szymon Bobek for access) | * Recording: [[|View]] (if you are not UJ employee, ask Szymon Bobek for access) | ||
- | * Presentation slides: {{ |Download}} | + | * Presentation slides: {{|Download}} |
+ | * **[DOCTORAL TRACK] 2024.03.21**: | ||
+ | * Meeting link: [[https:// | ||
+ | * Recording: [[https:// | ||
+ | * Presentation slides: {{ : | ||
* **[RESEARCH TRACK] 2024.03.14**: | * **[RESEARCH TRACK] 2024.03.14**: | ||
* Meeting link: [[https:// | * Meeting link: [[https:// | ||
- | * Recording: [[|View]] (if you are not UJ employee, ask Szymon Bobek for access) | + | * Recording: [[https:// |
- | * Presentation slides: {{ |Download}} | + | * Presentation slides: {{ : |
===== Schedule Winter 2023 ===== | ===== Schedule Winter 2023 ===== | ||
* **[RESEARCH TRACK] 2024.02.01**: | * **[RESEARCH TRACK] 2024.02.01**: | ||
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===== Presentation details ===== | ===== Presentation details ===== | ||
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+ | ==== 2024-04-25 ==== | ||
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+ | {{ : | ||
+ | </ | ||
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+ | **Speaker**: | ||
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+ | **Title**: Interpretable Time Series Classification With Prototypical Parts | ||
+ | |||
+ | **Abstract**: | ||
+ | Time series data is one of the most popular data modality in critical domains such as industry and medicine. The demand for algorithms that not only exhibit high accuracy but also offer interpretability is crucial in such fields, as decisions made there bear significant consequences. Prototypical parts network, like ProtoPNet gained significant interest in the field of image analysis. Although they offer competitive accuracy and ante-hoc explainability, | ||
+ | |||
+ | **Biogram**: | ||
+ | Bartłomiej Małkus is a PhD candidate at the Jagiellonian University in Technical Computer Science since 2021. He received BSc and MSc degrees in Computer Science on AGH University of Science and Technology. His field of interests are interpretable AI techniques applied to time series analysis and neurosymbolic AI. Commercially, | ||
+ | </ | ||
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+ | ==== 2024-04-18 ==== | ||
+ | <WRAP column 15%> | ||
+ | {{ : | ||
+ | </ | ||
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+ | <WRAP column 75%> | ||
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+ | **Speaker**: | ||
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+ | **Title:** Performance Optimization of the Platforms in Two-sided Mobility Market | ||
+ | |||
+ | **Abstract: | ||
+ | The presentation will focus on analyzing two-sided mobility markets involving platforms such as Uber and Lyft with agent-based modeling. The MoMaS framework will be introduced, which models two-sided mobility markets as complex systems with intricate, non-linear interactions among the involved parties (including travelers, drivers, and platforms). Eventually, the integration of Reinforcement Learning into the proposed framework will be discussed explaining how RL-based platform strategies can improve platform performance. | ||
+ | |||
+ | **Biogram: | ||
+ | Farnoud is currently a PhD student within the Faculty of Mathematics and Computer Science at the Jagiellonian University. His PhD research under the supervision of Dr. Rafal Kucharski, focuses on studying behavioural dynamics of two-sided mobility using agent-based microsimulation. He received his Bachelor’s degree in Civil Engineering at the University of Tabriz and he completed his MSc degree in Transport Systems at the Sapienza University of Rome. | ||
+ | </ | ||
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+ | {{ : | ||
+ | </ | ||
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+ | <WRAP column 75%> | ||
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+ | **Speaker**: | ||
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+ | **Title:** Optimising network efficiency in the epidemic scenario | ||
+ | |||
+ | **Abstract: | ||
+ | We consider the problem of reducing virus spreading in the system network (graph) while keeping the utility of the whole system at the maximal level. To balance the above two opposite goals, we propose Deep Epidemic Efficiency Network (DEEN), an unsupervised clustering method, which optimises graph efficiency in an epidemic scenario using Graph Convolutional Neural Networks and a novel loss function. Given the desired virus transmission, | ||
+ | In particular, by dividing 150 New York taxi travellers into four groups our method increases epidemic threshold more than twofold at the cost of reducing utility only by 13%, significantly outperforming benchmark methods. The model can be instrumental in future pandemic outbreaks when we need to balance between maintaining efficiency and preventing the spread of the virus. | ||
+ | |||
+ | **Biogram: | ||
+ | A third-year phd student of technical computer science at the Jagiellonian University. He has a background in applied mathematics with a focus on the probability theory. Currently, he is a part of a team working on transportation problems in the theoretical framework. His main research area is network science (both analytical and AI-based approaches). Out of the academia, he has experience in quantitative analysis for the major global investment banks. | ||
+ | </ | ||
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+ | ==== 2024-04-04 ==== | ||
+ | <WRAP column 15%> | ||
+ | {{ : | ||
+ | </ | ||
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+ | <WRAP column 75%> | ||
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+ | **Speaker**: | ||
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+ | **Title**: Evolutionary methods in automatic | ||
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+ | **Abstract**: | ||
+ | The problem of floor layout design involves the automatic generation of space arrangements within a predefined geometric area. This presentation will provide an overview of the research carried out in the Department of Design and Computer Graphics in recent years. In particular, it will cover different representations of designs, appropriate specialized evolutionary operators, and fitness evaluation methods. | ||
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+ | **Biogram**: | ||
+ | Barbara Strug received her PhD in Computer Science from the Institute of Fundamental Technological Research of the Polish Academy of Sciences (IPPT PAN) in Warsaw in 2002 and DSc (habilitation) in Computer Science from AGH in 2014. She is an associated professor at the Institute of Applied Computer Science, Jagiellonian University. Her research interest include computer aided design | ||
+ | </ | ||
+ | <WRAP clear></ | ||
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+ | ==== 2024-03-28 ==== | ||
+ | <WRAP column 15%> | ||
+ | {{ : | ||
+ | </ | ||
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+ | <WRAP column 75%> | ||
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+ | **Speaker**: | ||
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+ | **Title**: Complex Collective Systems | ||
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+ | **Abstract**: | ||
+ | The topic of the presentation will be collective aspects of | ||
+ | complex systems. | ||
+ | presented such as: crowds, skiers, vehicle traffic in an urban | ||
+ | environment and autonomous vehicle traffic. These models are applied and | ||
+ | developed within our international projects and cover practical aspects | ||
+ | of collective intelligence. The projects used methods such as: agent | ||
+ | technologies, | ||
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+ | **Biogram**: | ||
+ | Professor of technical sciences in the discipline of computer | ||
+ | science - specialization: | ||
+ | intelligence. He's working at the Applied Computer Science department of | ||
+ | AGH. He is interested in modeling and simulation of complex systems. In | ||
+ | particular, his area of interest is data-driven modeling and the use of | ||
+ | the agent-based modeling paradigm. He is interested in the applications | ||
+ | of advanced algorithms and artificial intelligence in engineering, | ||
+ | well as in areas such as IoT, ambient intelligence and computational | ||
+ | intelligence. To date, he has supervised 5 PhDs in Computer Science and | ||
+ | AI. | ||
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+ | </ | ||
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==== 2024-03-21 ==== | ==== 2024-03-21 ==== | ||
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**Speaker**: | **Speaker**: | ||
- | **Title**: | + | **Title**: |
**Abstract**: | **Abstract**: |