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28 results on '"Klarmann, Noah"'

1. Optimizing Job Shop Scheduling in the Furniture Industry: A Reinforcement Learning Approach Considering Machine Setup, Batch Variability, and Intralogistics

Author

Schneevogt, Malte, Binninger, Karsten, and Klarmann, Noah

Subjects
Computer Science - Artificial Intelligence, Computer Science - Machine Learning, Electrical Engineering and Systems Science - Systems and Control
Abstract

This paper explores the potential application of Deep Reinforcement Learning in the furniture industry. To offer a broad product portfolio, most furniture manufacturers are organized as a job shop, which ultimately results in the Job Shop Scheduling Problem (JSSP). The JSSP is addressed with a focus on extending traditional models to better represent the complexities of real-world production environments. Existing approaches frequently fail to consider critical factors such as machine setup times or varying batch sizes. A concept for a model is proposed that provides a higher level of information detail to enhance scheduling accuracy and efficiency. The concept introduces the integration of DRL for production planning, particularly suited to batch production industries such as the furniture industry. The model extends traditional approaches to JSSPs by including job volumes, buffer management, transportation times, and machine setup times. This enables more precise forecasting and analysis of production flows and processes, accommodating the variability and complexity inherent in real-world manufacturing processes. The RL agent learns to optimize scheduling decisions. It operates within a discrete action space, making decisions based on detailed observations. A reward function guides the agent's decision-making process, thereby promoting efficient scheduling and meeting production deadlines. Two integration strategies for implementing the RL agent are discussed: episodic planning, which is suitable for low-automation environments, and continuous planning, which is ideal for highly automated plants. While episodic planning can be employed as a standalone solution, the continuous planning approach necessitates the integration of the agent with ERP and Manufacturing Execution Systems. This integration enables real-time adjustments to production schedules based on dynamic changes., Comment: 18 pages, 8 pages

Published
2024

2. Autoencoder-Based Visual Anomaly Localization for Manufacturing Quality Control

Author

Mehta, Devang and Klarmann, Noah

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Manufacturing industries require efficient and voluminous production of high-quality finished goods. In the context of Industry 4.0, visual anomaly detection poses an optimistic solution for automatically controlled product quality with high precision. In general, automation based on computer vision is a promising solution to prevent bottlenecks at the product quality checkpoint. We considered recent advancements in machine learning to improve visual defect localization, but challenges persist in obtaining a balanced feature set and database of the wide variety of defects occurring in the production line. Hence, this paper proposes a defect localizing autoencoder with unsupervised class selection by clustering with k-means the features extracted from a pre-trained VGG16 network. Moreover, the selected classes of defects are augmented with natural wild textures to simulate artificial defects. The study demonstrates the effectiveness of the defect localizing autoencoder with unsupervised class selection for improving defect detection in manufacturing industries. The proposed methodology shows promising results with precise and accurate localization of quality defects on melamine-faced boards for the furniture industry. Incorporating artificial defects into the training data shows significant potential for practical implementation in real-world quality control scenarios.

Published
2023

3. DiAReL: Reinforcement Learning with Disturbance Awareness for Robust Sim2Real Policy Transfer in Robot Control

Author

Malmir, Mohammadhossein, Josifovski, Josip, Klarmann, Noah, and Knoll, Alois

Subjects
Computer Science - Robotics, Computer Science - Machine Learning, Electrical Engineering and Systems Science - Systems and Control
Abstract

Delayed Markov decision processes fulfill the Markov property by augmenting the state space of agents with a finite time window of recently committed actions. In reliance with these state augmentations, delay-resolved reinforcement learning algorithms train policies to learn optimal interactions with environments featured with observation or action delays. Although such methods can directly be trained on the real robots, due to sample inefficiency, limited resources or safety constraints, a common approach is to transfer models trained in simulation to the physical robot. However, robotic simulations rely on approximated models of the physical systems, which hinders the sim2real transfer. In this work, we consider various uncertainties in the modelling of the robot's dynamics as unknown intrinsic disturbances applied on the system input. We introduce a disturbance-augmented Markov decision process in delayed settings as a novel representation to incorporate disturbance estimation in training on-policy reinforcement learning algorithms. The proposed method is validated across several metrics on learning a robotic reaching task and compared with disturbance-unaware baselines. The results show that the disturbance-augmented models can achieve higher stabilization and robustness in the control response, which in turn improves the prospects of successful sim2real transfer., Comment: Submitted to the 2023 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS 2023)

Published
2023

4. A Reinforcement Learning Approach for Scheduling Problems With Improved Generalization Through Order Swapping

Author

Vivekanandan, Deepak, Wirth, Samuel, Karlbauer, Patrick, and Klarmann, Noah

Subjects
Computer Science - Artificial Intelligence, Computer Science - Machine Learning
Abstract

The scheduling of production resources (such as associating jobs to machines) plays a vital role for the manufacturing industry not only for saving energy but also for increasing the overall efficiency. Among the different job scheduling problems, the JSSP is addressed in this work. JSSP falls into the category of NP-hard COP, in which solving the problem through exhaustive search becomes unfeasible. Simple heuristics such as FIFO, LPT and metaheuristics such as Taboo search are often adopted to solve the problem by truncating the search space. The viability of the methods becomes inefficient for large problem sizes as it is either far from the optimum or time consuming. In recent years, the research towards using DRL to solve COP has gained interest and has shown promising results in terms of solution quality and computational efficiency. In this work, we provide an novel approach to solve the JSSP examining the objectives generalization and solution effectiveness using DRL. In particular, we employ the PPO algorithm that adopts the policy-gradient paradigm that is found to perform well in the constrained dispatching of jobs. We incorporated an OSM in the environment to achieve better generalized learning of the problem. The performance of the presented approach is analyzed in depth by using a set of available benchmark instances and comparing our results with the work of other groups.

Published
2023

5. Analysis of Randomization Effects on Sim2Real Transfer in Reinforcement Learning for Robotic Manipulation Tasks

Author

Josifovski, Josip, Malmir, Mohammadhossein, Klarmann, Noah, Žagar, Bare Luka, Navarro-Guerrero, Nicolás, and Knoll, Alois

Subjects
Computer Science - Robotics, Computer Science - Artificial Intelligence
Abstract

Randomization is currently a widely used approach in Sim2Real transfer for data-driven learning algorithms in robotics. Still, most Sim2Real studies report results for a specific randomization technique and often on a highly customized robotic system, making it difficult to evaluate different randomization approaches systematically. To address this problem, we define an easy-to-reproduce experimental setup for a robotic reach-and-balance manipulator task, which can serve as a benchmark for comparison. We compare four randomization strategies with three randomized parameters both in simulation and on a real robot. Our results show that more randomization helps in Sim2Real transfer, yet it can also harm the ability of the algorithm to find a good policy in simulation. Fully randomized simulations and fine-tuning show differentiated results and translate better to the real robot than the other approaches tested., Comment: Accepted to IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS) 2022

Published
2022

6. Artificial Intelligence Narratives: An Objective Perspective on Current Developments

Author

Klarmann, Noah

Subjects
Computer Science - Artificial Intelligence
Abstract

This work provides a starting point for researchers interested in gaining a deeper understanding of the big picture of artificial intelligence (AI). To this end, a narrative is conveyed that allows the reader to develop an objective view on current developments that is free from false promises that dominate public communication. An essential takeaway for the reader is that AI must be understood as an umbrella term encompassing a plethora of different methods, schools of thought, and their respective historical movements. Consequently, a bottom-up strategy is pursued in which the field of AI is introduced by presenting various aspects that are characteristic of the subject. This paper is structured in three parts: (i) Discussion of current trends revealing false public narratives, (ii) an introduction to the history of AI focusing on recurring patterns and main characteristics, and (iii) a critical discussion on the limitations of current methods in the context of the potential emergence of a strong(er) AI. It should be noted that this work does not cover any of these aspects holistically; rather, the content addressed is a selection made by the author and subject to a didactic strategy.

Published
2021

9. Autoencoder-Based Visual Anomaly Localization for Manufacturing Quality Control.

Author

Mehta, Devang and Klarmann, Noah

Subjects
QUALITY control, MANUFACTURING defects, COMPUTER vision, ARTIFICIAL neural networks, BOTTLENECKS (Manufacturing), DATABASES, MELAMINE, VIDEO coding, ARTIFICIAL membranes
Abstract

Manufacturing industries require the efficient and voluminous production of high-quality finished goods. In the context of Industry 4.0, visual anomaly detection poses an optimistic solution for automatically controlled product quality with high precision. In general, automation based on computer vision is a promising solution to prevent bottlenecks at the product quality checkpoint. We considered recent advancements in machine learning to improve visual defect localization, but challenges persist in obtaining a balanced feature set and database of the wide variety of defects occurring in the production line. Hence, this paper proposes a defect localizing autoencoder with unsupervised class selection by clustering with k-means the features extracted from a pretrained VGG16 network. Moreover, the selected classes of defects are augmented with natural wild textures to simulate artificial defects. The study demonstrates the effectiveness of the defect localizing autoencoder with unsupervised class selection for improving defect detection in manufacturing industries. The proposed methodology shows promising results with precise and accurate localization of quality defects on melamine-faced boards for the furniture industry. Incorporating artificial defects into the training data shows significant potential for practical implementation in real-world quality control scenarios. [ABSTRACT FROM AUTHOR]

Published
2024
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11. Optimising Trajectories in Simulations with Deep Reinforcement Learning for Industrial Robots in Automotive Manufacturing

Author

Klarmann, Noah, Malmir, Mohammadhossein, Josifovski, Josip, Plorin, Daniel, Wagner, Matthias, and Knoll, Alois

Subjects
deep reinforcement learning, offline programming, virtual learning platform, robot learning, industrial robotics, trajectory optimisation, motion planning, simulation
Abstract

This paper outlines the concept of optimising trajectories for industrial robots by applying deep reinforcement learning in simulations. An application of high technical relevance is considered in a production line of an automotive manufacturer (AUDI AG), where industrial manipulators apply sealant on a car body to prevent water intrusion and hence corrosion. A methodology is proposed that supports the human expert in the tedious task of programming the robot trajectories. A deep reinforcement learning agent generates trajectories in virtual instances where the use case is simulated. By making use of the automatically generated trajectories, the expert’s task is reduced to minor changes instead of developing the trajectory from scratch. This paper describes an appropriate way to model the agent in the context of Markov decision processes and gives an overview of the employed technologies. The use case outlined in this paper is a proof of concept to demonstrate the applicability of reinforcement learning for industrial robotics., Disclaimer: This chapter is published under Attribution-Non Commercial 4.0 International (CC BY-NC 4.0) license (https://www.riverpublishers.com/policies.php?pid=6). All River Publishers Open Access books, including Monographs and Edited Volumes, are distributed under the Creative Commons Attribution-Non Commercial 4.0 International (CC BY-NC 4.0). The full book is available at: https://www.riverpublishers.com/research_details.php?book_id=967 River Publishers Series in Communications Artificial Intelligence for Digitising Industry - Applications Editors: Ovidiu Vermesan, SINTEF, Norway Reiner John, AVL List, Austria Cristina De Luca, Infineon Technologies, Germany Marcello Coppola, STMicroelectronics, France ISBN: 9788770226646, e-ISBN: 9788770226639

Published
2022

13. AI4DI Deliverable D2.4 Report on hybrid intelligent system and sub-system level modelling and simulation for integration of AI methods

Author

Josifovski, Josip, Malmir, Mohammadhossein, Klarmann, Noah, Nica, Iulia, Wotawa, Franz, Klueck, Florian, Felbinger, Hermann, Trantidou, Tatiana, Marini, Eleftheria, Schneider, Mathias, Jokela, Tuomas, Chromý, Adam, Daskalopoulos, Ioannis, Trouva, Eleni, Poulakidas, Athanasios, Lucas, Peter, and SINTEF/IGT/NXTECH

Subjects
modelling, simulation, artificial intelligence
Abstract

The present document is a deliverable of the AI4DI project, which is co-funded by the ECSEL Joint Undertaking under grant agreement No. 826060 and ECSEL JU Member States. This report gives an overview of the simulation and modelling approaches at the system and subsystem level for the integration of AI methods across different supply chains within the AI4DI project. It starts with a short introduction regarding simulation where benefits and shortcomings are critically discussed. A high-level overview of the use-cases of each of the contributing partners is presented. The report covers four industrial sectors: Automotive Industry (Chapter 5), Machinery (Chapter 6), Food and Beverage Industry (Chapter 7) and Transportation Industry (Chapter 8) are addressed in individual chapters.

Published
2021
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20. Robust Sim2Real Transfer by Learning Inverse Dynamics of Simulated Systems

Author

Malmir, Mohammadhossein, Josifovski, Josip, Klarmann, Noah, and Knoll, Alois

Subjects
ddc:000, Informatik, Wissen, Systeme, inverse dynamics, disturbance observer, robotic manipulation, robust reinforcement learning, sim2real transfer
Abstract

This paper presents a data-driven nonlinear disturbance observer to reduce the reality gap caused by the imperfect simulation of the real-world physics. The main focus is on increasing robustness of the closed-loop control without changing the RL algorithm or simulation model to account for the uncertainty of the real world. For this purpose, a DNN representing inverse dynamics of the deterministic source-domain environment is learned by the simulation data. The proposed approach offers a systematic way to transfer the policies trained in simulation into the real world without decreasing sample efficiency of the RL agent in contrast to domain randomization or min-max robust RL methods.

Published
2019

21. Continual Learning on Incremental Simulations for Real-World Robotic Manipulation Tasks

Author

Josifovski, Josip, Malmir, Mohammadhossein, Klarmann, Noah, and Knoll, Alois

Subjects
ddc:000, Informatik, Wissen, Systeme
Abstract

Current state-of-the-art approaches for transferring deep-learning models trained in simulation either rely on highly realistic simulations or employ randomization techniques to bridge the reality gap. However, such strategies do not scale well for complex robotic tasks; highly-realistic simulations are computationally expensive and hard to implement, while randomization techniques become sample-inefficient as the complexity of the task increases. In this paper, we propose a procedure for training on incremental simulations in a continual learning setup. We analyze whether such setup can help to reduce the training time for complex tasks and improve the sim2real transfer. For the experimental analysis, we develop a simulation platform that can serve as a training environment and as a benchmark for continual and reinforcement learning sim2real approaches

Published
2019

22. Modeling Turbulent Combustion and CO Emissions in Partially-Premixed Conditions Considering Flame Stretch and Heat Loss

Author

Sattelmayer, Thomas (Prof. Dr.), Andreini, Antonio (Prof., Ph.D.), Klarmann, Noah Eugen, Sattelmayer, Thomas (Prof. Dr.), Andreini, Antonio (Prof., Ph.D.), and Klarmann, Noah Eugen

Abstract

This study investigates combustion and CO emissions in gas turbines operating at part load conditions. Combustion is described on the basis of flamelets. Important effects like flame stretch and heat loss are considered by a novel approach. CO is derived from flamelets within the turbulent flame brush. As the flamelet theory is not able to describe the burnout chemistry downstream of the turbulent flame brush, a novel model to close the post-flame source terms of CO is introduced., Diese Arbeit untersucht den Verbrennungsvorgang und die damit verbundenen CO-Emissionen in Gasturbinenbrennkammern bei Teillast. Die Verbrennung wird auf Basis von eindimensionalen Flammenrechnungen mit detaillierter Chemie unter Berücksichtigung von Flammenstreckung und Wärmeverlusten modelliert. Das Verbrennungsmodell kann zudem die CO-Verteilung innerhalb der turbulenten Flammenbürste beschreiben. Da die eindimensionalen Flammen stromab der Wärmefreisetzungszone an Gültigkeit verlieren, wird ein neues Vorgehen für die Modellierung der chemischen Quellterme im CO-Ausbrand vorgestellt.

Published
2019

28. Linearized Euler Equations for the Prediction of Linear High-Frequency Stability in Gas Turbine Combustors.

Author

Schulze, Moritz, Hummel, Tobias, Klarmann, Noah, Berger, Frederik, Sattelmayer, Thomas, and Schuermans, Bruno

Abstract

A novel methodology for linear stability analysis of high-frequency thermoacoustic oscillations in gas turbine combustors is presented. The methodology is based on the linearized Euler equations (LEEs), which yield a high-fidelity description of acoustic wave propagation and damping in complex, nonuniform, reactive mean flow environments, such as encountered in gas turbine combustion chambers. Specifically, this work introduces three novelties to the community: (1) linear stability analysis on the basis of linearized Euler equations. (2) Explicit consideration of three-dimensional, acoustic oscillations at screech level frequencies, particularly the first-transversal mode. (3) Handling of noncompact flame coupling with LEE, that is, the spatially varying coupling dynamics between perturbation and unsteady flame response due to small acoustic wavelengths. Two different configurations of an experimental model combustor in terms of thermal power and mass flow rates are subject of the analysis. Linear flame driving is modeled by prescribing the unsteady heat release source term of the linearized Euler equations by local flame transfer functions, which are retrieved from first principles. The required steady-state flow field is numerically obtained via computational fluid dynamics (CFD), which is based on an extended flamelet-generated manifold (FGM) combustion model, taking into account heat transfer to the environment. The model is therefore highly suitable for such types of combustors. The configurations are simulated, and thermoacoustically characterized in terms of eigenfrequencies and growth rates associated with the first-transversal mode. The findings are validated against experimentally observed thermoacoustic stability characteristics. On the basis of the results, new insights into the acoustic field are discussed. [ABSTRACT FROM AUTHOR]

Published
2017
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