Your search keyword '"Pashami, Sepideh"' showing total 300 results

1. CoxSE: Exploring the Potential of Self-Explaining Neural Networks with Cox Proportional Hazards Model for Survival Analysis

Author

Alabdallah, Abdallah, Hamed, Omar, Ohlsson, Mattias, Rögnvaldsson, Thorsteinn, and Pashami, Sepideh

Subjects

Computer Science - Machine Learning, Statistics - Machine Learning, I.2.6

Abstract

The Cox Proportional Hazards (CPH) model has long been the preferred survival model for its explainability. However, to increase its predictive power beyond its linear log-risk, it was extended to utilize deep neural networks sacrificing its explainability. In this work, we explore the potential of self-explaining neural networks (SENN) for survival analysis. we propose a new locally explainable Cox proportional hazards model, named CoxSE, by estimating a locally-linear log-hazard function using the SENN. We also propose a modification to the Neural additive (NAM) models hybrid with SENN, named CoxSENAM, which enables the control of the stability and consistency of the generated explanations. Several experiments using synthetic and real datasets have been performed comparing with a NAM-based model, DeepSurv model explained with SHAP, and a linear CPH model. The results show that, unlike the NAM-based model, the SENN-based model can provide more stable and consistent explanations while maintaining the same expressiveness power of the black-box model. The results also show that, due to their structural design, NAM-based models demonstrated better robustness to non-informative features. Among these models, the hybrid model exhibited the best robustness.

Published

2024

2. Artificial Intelligence Approaches for Predictive Maintenance in the Steel Industry: A Survey

Author

Jakubowski, Jakub, Wojak-Strzelecka, Natalia, Ribeiro, Rita P., Pashami, Sepideh, Bobek, Szymon, Gama, Joao, and Nalepa, Grzegorz J

Subjects

Computer Science - Artificial Intelligence

Abstract

Predictive Maintenance (PdM) emerged as one of the pillars of Industry 4.0, and became crucial for enhancing operational efficiency, allowing to minimize downtime, extend lifespan of equipment, and prevent failures. A wide range of PdM tasks can be performed using Artificial Intelligence (AI) methods, which often use data generated from industrial sensors. The steel industry, which is an important branch of the global economy, is one of the potential beneficiaries of this trend, given its large environmental footprint, the globalized nature of the market, and the demanding working conditions. This survey synthesizes the current state of knowledge in the field of AI-based PdM within the steel industry and is addressed to researchers and practitioners. We identified 219 articles related to this topic and formulated five research questions, allowing us to gain a global perspective on current trends and the main research gaps. We examined equipment and facilities subjected to PdM, determined common PdM approaches, and identified trends in the AI methods used to develop these solutions. We explored the characteristics of the data used in the surveyed articles and assessed the practical implications of the research presented there. Most of the research focuses on the blast furnace or hot rolling, using data from industrial sensors. Current trends show increasing interest in the domain, especially in the use of deep learning. The main challenges include implementing the proposed methods in a production environment, incorporating them into maintenance plans, and enhancing the accessibility and reproducibility of the research., Comment: Preprint submitted to Engineering Applications of Artificial Intelligence

Published

2024

3. Fast Genetic Algorithm for feature selection -- A qualitative approximation approach

Author

Altarabichi, Mohammed Ghaith, Nowaczyk, Sławomir, Pashami, Sepideh, and Mashhadi, Peyman Sheikholharam

Subjects

Computer Science - Neural and Evolutionary Computing, Computer Science - Artificial Intelligence, Computer Science - Machine Learning

Abstract

Evolutionary Algorithms (EAs) are often challenging to apply in real-world settings since evolutionary computations involve a large number of evaluations of a typically expensive fitness function. For example, an evaluation could involve training a new machine learning model. An approximation (also known as meta-model or a surrogate) of the true function can be used in such applications to alleviate the computation cost. In this paper, we propose a two-stage surrogate-assisted evolutionary approach to address the computational issues arising from using Genetic Algorithm (GA) for feature selection in a wrapper setting for large datasets. We define 'Approximation Usefulness' to capture the necessary conditions to ensure correctness of the EA computations when an approximation is used. Based on this definition, we propose a procedure to construct a lightweight qualitative meta-model by the active selection of data instances. We then use a meta-model to carry out the feature selection task. We apply this procedure to the GA-based algorithm CHC (Cross generational elitist selection, Heterogeneous recombination and Cataclysmic mutation) to create a Qualitative approXimations variant, CHCQX. We show that CHCQX converges faster to feature subset solutions of significantly higher accuracy (as compared to CHC), particularly for large datasets with over 100K instances. We also demonstrate the applicability of the thinking behind our approach more broadly to Swarm Intelligence (SI), another branch of the Evolutionary Computation (EC) paradigm with results of PSOQX, a qualitative approximation adaptation of the Particle Swarm Optimization (PSO) method. A GitHub repository with the complete implementation is available.

Published

2024

4. Rolling the dice for better deep learning performance: A study of randomness techniques in deep neural networks

Author

Altarabichi, Mohammed Ghaith, Nowaczyk, Sławomir, Pashami, Sepideh, Mashhadi, Peyman Sheikholharam, and Handl, Julia

Subjects

Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Computer Science - Computer Vision and Pattern Recognition, Computer Science - Neural and Evolutionary Computing

Abstract

This paper investigates how various randomization techniques impact Deep Neural Networks (DNNs). Randomization, like weight noise and dropout, aids in reducing overfitting and enhancing generalization, but their interactions are poorly understood. The study categorizes randomness techniques into four types and proposes new methods: adding noise to the loss function and random masking of gradient updates. Using Particle Swarm Optimizer (PSO) for hyperparameter optimization, it explores optimal configurations across MNIST, FASHION-MNIST, CIFAR10, and CIFAR100 datasets. Over 30,000 configurations are evaluated, revealing data augmentation and weight initialization randomness as main performance contributors. Correlation analysis shows different optimizers prefer distinct randomization types. The complete implementation and dataset are available on GitHub.

Published

2024

5. Heterogeneous Federated Learning via Personalized Generative Networks

Author

Taghiyarrenani, Zahra, Alabdallah, Abdallah, Nowaczyk, Slawomir, and Pashami, Sepideh

Subjects

Computer Science - Machine Learning

Abstract

Federated Learning (FL) allows several clients to construct a common global machine-learning model without having to share their data. FL, however, faces the challenge of statistical heterogeneity between the client's data, which degrades performance and slows down the convergence toward the global model. In this paper, we provide theoretical proof that minimizing heterogeneity between clients facilitates the convergence of a global model for every single client. This becomes particularly important under empirical concept shifts among clients, rather than merely considering imbalanced classes, which have been studied until now. Therefore, we propose a method for knowledge transfer between clients where the server trains client-specific generators. Each generator generates samples for the corresponding client to remove the conflict with other clients' models. Experiments conducted on synthetic and real data, along with a theoretical study, support the effectiveness of our method in constructing a well-generalizable global model by reducing the conflict between local models.

Published

2023

6. Component attention network for multimodal dance improvisation recognition

Author

Fu, Jia, Tan, Jiarui, Yin, Wenjie, Pashami, Sepideh, and Björkman, Mårten

Subjects

Computer Science - Computer Vision and Pattern Recognition, Computer Science - Artificial Intelligence, Computer Science - Sound, Electrical Engineering and Systems Science - Audio and Speech Processing, I.2, I.5.4

Abstract

Dance improvisation is an active research topic in the arts. Motion analysis of improvised dance can be challenging due to its unique dynamics. Data-driven dance motion analysis, including recognition and generation, is often limited to skeletal data. However, data of other modalities, such as audio, can be recorded and benefit downstream tasks. This paper explores the application and performance of multimodal fusion methods for human motion recognition in the context of dance improvisation. We propose an attention-based model, component attention network (CANet), for multimodal fusion on three levels: 1) feature fusion with CANet, 2) model fusion with CANet and graph convolutional network (GCN), and 3) late fusion with a voting strategy. We conduct thorough experiments to analyze the impact of each modality in different fusion methods and distinguish critical temporal or component features. We show that our proposed model outperforms the two baseline methods, demonstrating its potential for analyzing improvisation in dance., Comment: Accepted to 25th ACM International Conference on Multimodal Interaction (ICMI 2023)

Published

2023

7. Explainable Predictive Maintenance

Author

Pashami, Sepideh, Nowaczyk, Slawomir, Fan, Yuantao, Jakubowski, Jakub, Paiva, Nuno, Davari, Narjes, Bobek, Szymon, Jamshidi, Samaneh, Sarmadi, Hamid, Alabdallah, Abdallah, Ribeiro, Rita P., Veloso, Bruno, Sayed-Mouchaweh, Moamar, Rajaoarisoa, Lala, Nalepa, Grzegorz J., and Gama, João

Subjects

Computer Science - Artificial Intelligence, I.2.1

Abstract

Explainable Artificial Intelligence (XAI) fills the role of a critical interface fostering interactions between sophisticated intelligent systems and diverse individuals, including data scientists, domain experts, end-users, and more. It aids in deciphering the intricate internal mechanisms of ``black box'' Machine Learning (ML), rendering the reasons behind their decisions more understandable. However, current research in XAI primarily focuses on two aspects; ways to facilitate user trust, or to debug and refine the ML model. The majority of it falls short of recognising the diverse types of explanations needed in broader contexts, as different users and varied application areas necessitate solutions tailored to their specific needs. One such domain is Predictive Maintenance (PdM), an exploding area of research under the Industry 4.0 \& 5.0 umbrella. This position paper highlights the gap between existing XAI methodologies and the specific requirements for explanations within industrial applications, particularly the Predictive Maintenance field. Despite explainability's crucial role, this subject remains a relatively under-explored area, making this paper a pioneering attempt to bring relevant challenges to the research community's attention. We provide an overview of predictive maintenance tasks and accentuate the need and varying purposes for corresponding explanations. We then list and describe XAI techniques commonly employed in the literature, discussing their suitability for PdM tasks. Finally, to make the ideas and claims more concrete, we demonstrate XAI applied in four specific industrial use cases: commercial vehicles, metro trains, steel plants, and wind farms, spotlighting areas requiring further research., Comment: 51 pages, 9 figures

Published

2023

8. The Concordance Index decomposition: A measure for a deeper understanding of survival prediction models

Author

Alabdallah, Abdallah, Ohlsson, Mattias, Pashami, Sepideh, and Rögnvaldsson, Thorsteinn

Subjects

Computer Science - Machine Learning, Statistics - Methodology, Statistics - Machine Learning

Abstract

The Concordance Index (C-index) is a commonly used metric in Survival Analysis for evaluating the performance of a prediction model. In this paper, we propose a decomposition of the C-index into a weighted harmonic mean of two quantities: one for ranking observed events versus other observed events, and the other for ranking observed events versus censored cases. This decomposition enables a finer-grained analysis of the relative strengths and weaknesses between different survival prediction methods. The usefulness of this decomposition is demonstrated through benchmark comparisons against classical models and state-of-the-art methods, together with the new variational generative neural-network-based method (SurVED) proposed in this paper. The performance of the models is assessed using four publicly available datasets with varying levels of censoring. Using the C-index decomposition and synthetic censoring, the analysis shows that deep learning models utilize the observed events more effectively than other models. This allows them to keep a stable C-index in different censoring levels. In contrast to such deep learning methods, classical machine learning models deteriorate when the censoring level decreases due to their inability to improve on ranking the events versus other events.

Published

2022

9. Surrogate-Assisted Genetic Algorithm for Wrapper Feature Selection

Author

Altarabichi, Mohammed Ghaith, Nowaczyk, Sławomir, Pashami, Sepideh, and Mashhad, Peyman Sheikholharam

Subjects

Computer Science - Machine Learning, Computer Science - Neural and Evolutionary Computing

Abstract

Feature selection is an intractable problem, therefore practical algorithms often trade off the solution accuracy against the computation time. In this paper, we propose a novel multi-stage feature selection framework utilizing multiple levels of approximations, or surrogates. Such a framework allows for using wrapper approaches in a much more computationally efficient way, significantly increasing the quality of feature selection solutions achievable, especially on large datasets. We design and evaluate a Surrogate-Assisted Genetic Algorithm (SAGA) which utilizes this concept to guide the evolutionary search during the early phase of exploration. SAGA only switches to evaluating the original function at the final exploitation phase. We prove that the run-time upper bound of SAGA surrogate-assisted stage is at worse equal to the wrapper GA, and it scales better for induction algorithms of high order of complexity in number of instances. We demonstrate, using 14 datasets from the UCI ML repository, that in practice SAGA significantly reduces the computation time compared to a baseline wrapper Genetic Algorithm (GA), while converging to solutions of significantly higher accuracy. Our experiments show that SAGA can arrive at near-optimal solutions three times faster than a wrapper GA, on average. We also showcase the importance of evolution control approach designed to prevent surrogates from misleading the evolutionary search towards false optima.

Published

2021

10. AI perspectives in Smart Cities and Communities to enable road vehicle automation and smart traffic control

Author

Englund, Cristofer, Aksoy, Eren Erdal, Alonso-Fernandez, Fernando, Cooney, Martin Daniel, Pashami, Sepideh, and Astrand, Bjorn

Subjects

Computer Science - Artificial Intelligence, Computer Science - Computers and Society

Abstract

Smart Cities and Communities (SCC) constitute a new paradigm in urban development. SCC ideates on a data-centered society aiming at improving efficiency by automating and optimizing activities and utilities. Information and communication technology along with internet of things enables data collection and with the help of artificial intelligence (AI) situation awareness can be obtained to feed the SCC actors with enriched knowledge. This paper describes AI perspectives in SCC and gives an overview of AI-based technologies used in traffic to enable road vehicle automation and smart traffic control. Perception, Smart Traffic Control and Driver Modelling are described along with open research challenges and standardization to help introduce advanced driver assistance systems and automated vehicle functionality in traffic. To fully realize the potential of SCC, to create a holistic view on a city level, the availability of data from different stakeholders is need. Further, though AI technologies provide accurate predictions and classifications there is an ambiguity regarding the correctness of their outputs. This can make it difficult for the human operator to trust the system. Today there are no methods that can be used to match function requirements with the level of detail in data annotation in order to train an accurate model. Another challenge related to trust is explainability, while the models have difficulties explaining how they come to a certain conclusion it is difficult for humans to trust it.

Published

2021

11. Pitfalls of Assessing Extracted Hierarchies for Multi-Class Classification

Author

del Moral, Pablo, Nowaczyk, Slawomir, Sant'Anna, Anita, and Pashami, Sepideh

Subjects

Computer Science - Machine Learning, Statistics - Machine Learning

Abstract

Using hierarchies of classes is one of the standard methods to solve multi-class classification problems. In the literature, selecting the right hierarchy is considered to play a key role in improving classification performance. Although different methods have been proposed, there is still a lack of understanding of what makes one method to extract hierarchies perform better or worse. To this effect, we analyze and compare some of the most popular approaches to extracting hierarchies. We identify some common pitfalls that may lead practitioners to make misleading conclusions about their methods. In addition, to address some of these problems, we demonstrate that using random hierarchies is an appropriate benchmark to assess how the hierarchy's quality affects the classification performance. In particular, we show how the hierarchy's quality can become irrelevant depending on the experimental setup: when using powerful enough classifiers, the final performance is not affected by the quality of the hierarchy. We also show how comparing the effect of the hierarchies against non-hierarchical approaches might incorrectly indicate their superiority. Our results confirm that datasets with a high number of classes generally present complex structures in how these classes relate to each other. In these datasets, the right hierarchy can dramatically improve classification performance.

Published

2021

12. The Concordance Index decomposition: A measure for a deeper understanding of survival prediction models

Author

Alabdallah, Abdallah, Ohlsson, Mattias, Pashami, Sepideh, and Rögnvaldsson, Thorsteinn

Published

2024

13. Avoiding Improper Treatment of Persons with Dementia by Care Robots

Author

Cooney, Martin, Pashami, Sepideh, Järpe, Eric, and Ashfaq, Awais

Subjects

Computer Science - Computers and Society, Computer Science - Robotics

Abstract

The phrase "most cruel and revolting crimes" has been used to describe some poor historical treatment of vulnerable impaired persons by precisely those who should have had the responsibility of protecting and helping them. We believe we might be poised to see history repeat itself, as increasingly human-like aware robots become capable of engaging in behavior which we would consider immoral in a human--either unknowingly or deliberately. In the current paper we focus in particular on exploring some potential dangers affecting persons with dementia (PWD), which could arise from insufficient software or external factors, and describe a proposed solution involving rich causal models and accountability measures: Specifically, the Consequences of Needs-driven Dementia-compromised Behaviour model (C-NDB) could be adapted to be used with conversation topic detection, causal networks and multi-criteria decision making, alongside reports, audits, and deterrents. Our aim is that the considerations raised could help inform the design of care robots intended to support well-being in PWD., Comment: 4 pages. Published. (Submitted: Jan. 22, 2019; Accepted: Jan. 30, 2019; Camera-ready submitted: Feb. 6, 2019.)

Published

2020

14. Material handling machine activity recognition by context ensemble with gated recurrent units

Author

Chen, Kunru, Rögnvaldsson, Thorsteinn, Nowaczyk, Sławomir, Pashami, Sepideh, Klang, Jonas, and Sternelöv, Gustav

Published

2023

15. Multi-domain adaptation for regression under conditional distribution shift

Author

Taghiyarrenani, Zahra, Nowaczyk, Sławomir, Pashami, Sepideh, and Bouguelia, Mohamed-Rafik

Published

2023

16. Fast Genetic Algorithm for feature selection — A qualitative approximation approach

Author

Altarabichi, Mohammed Ghaith, Nowaczyk, Sławomir, Pashami, Sepideh, and Mashhadi, Peyman Sheikholharam

Published

2023

17. Exploring home robot capabilities by medium fidelity prototyping

Author

Cooney, Martin, Pashami, Sepideh, Fan, Yuantao, Sant'Anna, Anita, Ma, Yinrong, Zhang, Tianyi, Zhao, Yuwei, Hotze, Wolfgang, Heyne, Jeremy, Englund, Cristofer, Lilienthal, Achim J., and Ziemke, Tom

Subjects

Computer Science - Robotics, Computer Science - Human-Computer Interaction

Abstract

In order for autonomous robots to be able to support people's well-being in homes and everyday environments, new interactive capabilities will be required, as exemplified by the soft design used for Disney's recent robot character Baymax in popular fiction. Home robots will be required to be easy to interact with and intelligent--adaptive, fun, unobtrusive and involving little effort to power and maintain--and capable of carrying out useful tasks both on an everyday level and during emergencies. The current article adopts an exploratory medium fidelity prototyping approach for testing some new robotic capabilities in regard to recognizing people's activities and intentions and behaving in a way which is transparent to people. Results are discussed with the aim of informing next designs., Comment: 28 pages, 11 figures

Published

2017

18. Towards Explainable Deep Domain Adaptation

Author

Bobek, Szymon, Nowaczyk, Sławomir, Pashami, Sepideh, Taghiyarrenani, Zahra, Nalepa, Grzegorz J., Bobek, Szymon, Nowaczyk, Sławomir, Pashami, Sepideh, Taghiyarrenani, Zahra, and Nalepa, Grzegorz J.

Abstract

In many practical applications data used for training a machine learning model and the deployment data does not always preserve the same distribution. Transfer learning and, in particular, domain adaptation allows to overcome this issue, by adapting the source model to a new target data distribution and therefore generalizing the knowledge from source to target domain. In this work, we present a method that makes the adaptation process more transparent by providing two complementary explanation mechanisms. The first mechanism explains how the source and target distributions are aligned in the latent space of the domain adaptation model. The second mechanism provides descriptive explanations on how the decision boundary changes in the adapted model with respect to the source model. Along with a description of a method, we also provide initial results obtained on publicly available, real-life dataset. © The Author(s) 2024., Funding: The paper is funded from the XPM project funded by the National Science Centre, Poland under the CHIST-ERA programme (NCN UMO2020/02/Y/ST6/00070) and the Swedish Research Council under grant CHIST-ERA19-XAI-012 and by a grant from the Priority Research Area (DigiWorld) under the Strategic Programme Excellence Initiative at Jagiellonian University.

Published

2024

19. Improving Concordance Index in Regression-based Survival Analysis : Discovery of Loss Function for Neural Networks

Author

Altarabichi, Mohammed Ghaith, Alabdallah, Abdallah, Pashami, Sepideh, Ohlsson, Mattias, Rögnvaldsson, Thorsteinn, Nowaczyk, Sławomir, Altarabichi, Mohammed Ghaith, Alabdallah, Abdallah, Pashami, Sepideh, Ohlsson, Mattias, Rögnvaldsson, Thorsteinn, and Nowaczyk, Sławomir

Abstract

In this work, we use an Evolutionary Algorithm (EA) to discover a novel Neural Network (NN) regression-based survival loss function with the aim of improving the C-index performance. Our contribution is threefold; firstly, we propose an evolutionary meta-learning algorithm SAGA$_{loss}$ for optimizing a neural-network regression-based loss function that maximizes the C-index; our algorithm consistently discovers specialized loss functions that outperform MSCE. Secondly, based on our analysis of the evolutionary search results, we highlight a non-intuitive insight that signifies the importance of the non-zero gradient for the censored cases part of the loss function, a property that is shown to be useful in improving concordance. Finally, based on this insight, we propose MSCE$_{Sp}$, a novel survival regression loss function that can be used off-the-shelf and generally performs better than the Mean Squared Error for censored cases. We performed extensive experiments on 19 benchmark datasets to validate our findings., As manuscript in thesis.

Published

2024

20. Mind the Data, Measuring the Performance Gap Between Tree Ensembles and Deep Learning on Tabular Data

Author

Karlsson, Axel, Wang, Tianze, Nowaczyk, Sławomir, Pashami, Sepideh, Asadi, Sahar, Karlsson, Axel, Wang, Tianze, Nowaczyk, Sławomir, Pashami, Sepideh, and Asadi, Sahar

Abstract

Recent machine learning studies on tabular data show that ensembles of decision tree models are more efficient and performant than deep learning models such as Tabular Transformer models. However, as we demonstrate, these studies are limited in scope and do not paint the full picture. In this work, we focus on how two dataset properties, namely dataset size and feature complexity, affect the empirical performance comparison between tree ensembles and Tabular Transformer models. Specifically, we employ a hypothesis-driven approach and identify situations where Tabular Transformer models are expected to outperform tree ensemble models. Through empirical evaluation, we demonstrate that given large enough datasets, deep learning models perform better than tree models. This gets more pronounced when complex feature interactions exist in the given task and dataset, suggesting that one must pay careful attention to dataset properties when selecting a model for tabular data in machine learning – especially in an industrial setting, where larger and larger datasets with less and less carefully engineered features are becoming routinely available. © The Author(s)

Published

2024

21. Mode tracking using multiple data streams

Author

Bouguelia, Mohamed-Rafik, Karlsson, Alexander, Pashami, Sepideh, Nowaczyk, Sławomir, and Holst, Anders

Published

2018

22. A Knowledge-Based AI Framework for Mobility as a Service

Author

Rajabi, Enayat, Nowaczyk, Sławomir, Pashami, Sepideh, Bergquist, Magnus, Ebby, Geethu Susan, Wajid, Summrina, Rajabi, Enayat, Nowaczyk, Sławomir, Pashami, Sepideh, Bergquist, Magnus, Ebby, Geethu Susan, and Wajid, Summrina

Abstract

Mobility as a Service (MaaS) combines various modes of transportation to present mobility services to travellers based on their transport needs. This paper proposes a knowledge-based framework based on Artificial Intelligence (AI) to integrate various mobility data types and provide travellers with customized services. The proposed framework includes a knowledge acquisition process to extract and structure data from multiple sources of information (such as mobility experts and weather data). It also adds new information to a knowledge base and improves the quality of previously acquired knowledge. We discuss how AI can help discover knowledge from various data sources and recommend sustainable and personalized mobility services with explanations. The proposed knowledge-based AI framework is implemented using a synthetic dataset as a proof of concept. Combining different information sources to generate valuable knowledge is identified as one of the challenges in this study. Finally, explanations of the proposed decisions provide a criterion for evaluating and understanding the proposed knowledge-based AI framework. © 2023 by the authors.

Published

2023

23. Safe to circulate : public report

Author

Gutkin, Renaud, Wirje, Anders, Nilsson-Lindén, Hanna, Brunklaus, Birgit, Pashami, Sepideh, Lundahl, Jenny, Essvik, Krister, Enebog, Emma, Jonasson, Christian, Andersson, Oscar, Gutkin, Renaud, Wirje, Anders, Nilsson-Lindén, Hanna, Brunklaus, Birgit, Pashami, Sepideh, Lundahl, Jenny, Essvik, Krister, Enebog, Emma, Jonasson, Christian, and Andersson, Oscar

Abstract

Project within FFI: Accelerate the transition to sustainable road transport

Published

2023

24. Analysis of Statistical Data Heterogeneity in Federated Fault Identification

Author

Taghiyarrenani, Zahra, Nowaczyk, Sławomir, Pashami, Sepideh, Taghiyarrenani, Zahra, Nowaczyk, Sławomir, and Pashami, Sepideh

Abstract

Federated Learning (FL) is a setting where different clients collaboratively train a Machine Learning model in a privacy-preserving manner, i.e., without the requirement to share data. Given the importance of security and privacy in real-world applications, FL is gaining popularity in many areas, including predictive maintenance. For example, it allows independent companies to construct a model collaboratively. However, since different companies operate in different environments, their working conditions may differ, resulting in heterogeneity among their data distributions. This paper considers the fault identification problem and simulates different scenarios of data heterogeneity. Such a setting remains challenging for popular FL algorithms, and thus we demonstrate the considerations to be taken into account when designing federated predictive maintenance solutions.

Published

2023

25. Toward Solving Domain Adaptation with Limited Source Labeled Data

Author

Chen, Kunru, Rögnvaldsson, Thorsteinn, Nowaczyk, Sławomir, Pashami, Sepideh, Klang, Jonas, Sternelov, Gustav, Chen, Kunru, Rögnvaldsson, Thorsteinn, Nowaczyk, Sławomir, Pashami, Sepideh, Klang, Jonas, and Sternelov, Gustav

Abstract

The success of domain adaptation relies on high-quality labeled data from the source domain, which is a luxury setup for applied machine learning problems. This article investigates a particular challenge: the source labeled data are neither plentiful nor sufficiently representative. We studied the challenge of limited data with an industrial application, i.e., forklift truck activity recognition. The task is to develop data-driven methods to recognize forklift usage performed in different warehouses with a large scale of signals collected from the onboard sensors. The preliminary results show that using pseudo-labeled data from the source domain can significantly improve classification performance on the target domain in some tasks. As the real-world problems are much more complex than typical research settings, it is not clearly understood in what circumstance the improvement may occur. Therefore, we provided discussions regarding this phenomenon and shared several inspirations on the difficulty of understanding and debugging domain adaptation problems in practice. © 2023 IEEE., Funding: The Knowledge Foundation, Halmstad University, and Toyota Material Handling Europe

Published

2023

26. Discovering Premature Replacements in Predictive Maintenance Time-to-Event Data

Author

Alabdallah, Abdallah, Rögnvaldsson, Thorsteinn, Fan, Yuantao, Pashami, Sepideh, Ohlsson, Mattias, Alabdallah, Abdallah, Rögnvaldsson, Thorsteinn, Fan, Yuantao, Pashami, Sepideh, and Ohlsson, Mattias

Abstract

Time-To-Event (TTE) modeling using survival analysis in industrial settings faces the challenge of premature replacements of machine components, which leads to bias and errors in survival prediction. Typically, TTE survival data contains information about components and if they had failed or not up to a certain time. For failed components, the time is noted, and a failure is referred to as an event. A component that has not failed is denoted as censored. In industrial settings, in contrast to medical settings, there can be considerable uncertainty in an event; a component can be replaced before it fails to prevent operation stops or because maintenance staff believe that the component is faulty. This shows up as “no fault found” in warranty studies, where a significant proportion of replaced components may appear fault-free when tested or inspected after replacement. In this work, we propose an expectation-maximization-like method for discovering such premature replacements in survival data. The method is a two-phase iterative algorithm employing a genetic algorithm in the maximization phase to learn better event assignments on a validation set. The learned labels through iterations are accumulated and averaged to be used to initialize the following expectation phase. The assumption is that the more often the event is selected, the more likely it is to be an actual failure and not a “no fault found”. Experiments on synthesized and simulated data show that the proposed method can correctly detect a significant percentage of premature replacement cases., Som manuscript i avhandling/As manuscript in thesis.

Published

2023

27. XAI for Predictive Maintenance

Author

Gama, Joao, Nowaczyk, Sławomir, Pashami, Sepideh, Ribeiro, Rita P., Nalepa, Grzegorz J., Veloso, Bruno, Gama, Joao, Nowaczyk, Sławomir, Pashami, Sepideh, Ribeiro, Rita P., Nalepa, Grzegorz J., and Veloso, Bruno

Abstract

The field of Explainable Predictive Maintenance (PM) is concerned with developing methods that can clarify how AI systems operate in the PM domain. One of the challenges of creating maintenance plans is integrating AI output with human decision-making processes and expertise. For AI to be helpful and trustworthy, fault predictions must be contextualized and easily comprehensible to humans. This involves providing tailored explanations to different actors depending on their roles and needs. For example, engineers can be connected to technical installation blueprints, while managers can evaluate system downtime costs, and lawyers can assess safety-threatening failures' potential liability. In many industries, black-box AI systems analyze sensor data to predict failures by detecting anomalies and deviations from typical behavior with impressive accuracy. However, PM is just one part of a broader context that aims to identify the most probable causes, develop a recovery plan, and estimate remaining useful life while providing alternative solutions. Achieving this requires complex interactions among various actors in industrial and decision-making processes. Our tutorial explores current trends, and promising research directions in Explainable AI (XAI) relevant to Explainable Predictive Maintenance (XPM), and future challenges and open issues on this topic. We will also present three case studies that highlight XPM's challenges in bus and train operations and steel factories. © 2023 Owner/Author., Funding: João Gama was financed by European Union’s Horizon Europe research and innovation programme under the Grant Agreement 101073874 (EMERITUS). Sławomir Nowaczyk and Sepideh Pashami were financed by Swedish Research Council under grant CHIST- ERA-19-XAI-012. Rita P. Ribeiro was financed by the CHIST-ERA grant CHIST-ERA- 19-XAI-012, and project CHIST-ERA/0004/2019 funded by FCT and also within project LA/P/0063/2020.

Published

2023

28. Forecasting Auxiliary Energy Consumption for Electric Heavy-Duty Vehicles

Author

Fan, Yuantao, Wang, Zhenkan, Pashami, Sepideh, Nowaczyk, Slawomir, Ydreskog, Henrik, Fan, Yuantao, Wang, Zhenkan, Pashami, Sepideh, Nowaczyk, Slawomir, and Ydreskog, Henrik

Abstract

Accurate energy consumption prediction is crucial for optimizing the operation of electric commercial heavy-duty vehicles, e.g., route planning for charging. Moreover, understanding why certain predictions are cast is paramount for such a predictive model to gain user trust and be deployed in practice. Since commercial vehicles operate differently as transportation tasks, ambient, and drivers vary, a heterogeneous population is expected when building an AI system for forecasting energy consumption. The dependencies between the input features and the target values are expected to also differ across sub-populations. One well-known example of such a statistical phenomenon is the Simpson paradox. In this paper, we illustrate that such a setting poses a challenge for existing XAI methods that produce global feature statistics, e.g. LIME or SHAP, causing them to yield misleading results. We demonstrate a potential solution by training multiple regression models on subsets of data. It not only leads to superior regression performance but also more relevant and consistent LIME explanations. Given that the employed groupings correspond to relevant sub-populations, the associations between the input features and the target values are consistent within each cluster but different across clusters. Experiments on both synthetic and real-world datasets show that such splitting of a complex problem into simpler ones yields better regression performance and interpretability.

Published

2023

29. A Knowledge-Based AI Framework for Mobility as a Service

Author

Rajabi, Enayat, primary, Nowaczyk, Sławomir, additional, Pashami, Sepideh, additional, Bergquist, Magnus, additional, Ebby, Geethu Susan, additional, and Wajid, Summrina, additional

Published

2023

30. Semi-Supervised Learning for Forklift Activity Recognition from Controller Area Network (CAN) Signals

Author

Chen, Kunru, Rögnvaldsson, Thorsteinn, Nowaczyk, Sławomir, Pashami, Sepideh, Johansson, Emilia, Sternelöv, Gustav, Chen, Kunru, Rögnvaldsson, Thorsteinn, Nowaczyk, Sławomir, Pashami, Sepideh, Johansson, Emilia, and Sternelöv, Gustav

Abstract

Machine Activity Recognition (MAR) can be used to monitor manufacturing processes and find bottlenecks and potential for improvement in production. Several interesting results on MAR techniques have been produced in the last decade, but mostly on construction equipment. Forklift trucks, which are ubiquitous and highly important industrial machines, have been missing from the MAR research. This paper presents a data-driven method for forklift activity recognition that uses Controller Area Network (CAN) signals and semi-supervised learning (SSL). The SSL enables the utilization of large quantities of unlabeled operation data to build better classifiers; after a two-step post-processing, the recognition results achieve balanced accuracy of 88% for driving activities and 95% for load-handling activities on a hold-out data set. In terms of the Matthews correlation coefficient for five activity classes, the final score is 0.82, which is equal to the recognition results of two non-domain experts who use videos of the activities. A particular success is that context can be used to capture the transport of small weight loads that are not detected by the forklift’s built-in weight sensor. © 2022 by the authors. Licensee MDPI, Basel, Switzerland.

Published

2022

31. Filtering Misleading Repair Log Labels to Improve Predictive Maintenance Models

Author

Del Moral, Pablo, Nowaczyk, Sławomir, Pashami, Sepideh, Del Moral, Pablo, Nowaczyk, Sławomir, and Pashami, Sepideh

Abstract

One of the main challenges for predictive maintenance in real applications is the quality of the data, especially the labels. In this paper, we propose a methodology to filter out the misleading labels that harm the performance of Machine Learning models. Ideally, predictive maintenance would be based on the information of when a fault has occurred in a machine and what specific type of fault it was. Then, we could train machine learning models to identify the symptoms of such fault before it leads to a breakdown. However, in many industrial applications, this information is not available. Instead, we approximate it using a log of component replacements, usually coming from the sales or maintenance departments. The repair history provides reliable labels for fault prediction models only if the replaced component was indeed faulty, with symptoms captured by collected data, and it was going to lead to a breakdown. However, very often, at least for complex equipment, this assumption does not hold. Models trained using unreliable labels will then, necessarily, fail. We demonstrate that filtering misleading labels leads to improved results. Our central claim is that the same fault, happening several times, should have similar symptoms in the data; thus, we can train a model to predict them. On the contrary, replacements of the same component that do not exhibit similar symptoms will be confusing and harm the ML models. Therefore, we aim to filter the maintenance operations, keeping only those that can be used to predict each other. Suppose we can train a successful model using the data before a component replacement to predict another component replacement. In that case, those maintenance operations must be motivated by the same, or a very similar, type of fault. We test this approach on a real scenario using data from a fleet of sterilizers deployed in hospitals. The data includes sensor readings from the machines describing their operations and the service logs indicat

Published

2022

32. Why Is Multiclass Classification Hard?

Author

Del Moral, Pablo, Nowaczyk, Sławomir, Pashami, Sepideh, Del Moral, Pablo, Nowaczyk, Sławomir, and Pashami, Sepideh

Abstract

In classification problems, as the number of classes increases, correctly classifying a new instance into one of them is assumed to be more challenging than making the same decision in the presence of fewer classes. The essence of the problem is that using the learning algorithm on each decision boundary individually is better than using the same learning algorithm on several of them simultaneously. However, why and when it happens is still not well-understood today. This work’s main contribution is to introduce the concept of heterogeneity of decision boundaries as an explanation of this phenomenon. Based on the definition of heterogeneity of decision boundaries, we analyze and explain the differences in the performance of state of the art approaches to solve multi-class classification. We demonstrate that as the heterogeneity increases, the performances of all approaches, except one-vs-one, decrease. We show that by correctly encoding the knowledge of the heterogeneity of decision boundaries in a decomposition of the multi-class problem, we can obtain better results than state of the art decompositions. The benefits can be an increase in classification performance or a decrease in the time it takes to train and evaluate the models. We first provide intuitions and illustrate the effects of the heterogeneity of decision boundaries using synthetic datasets and a simplistic classifier. Then, we demonstrate how a real dataset exhibits these same principles, also under realistic learning algorithms. In this setting, we devise a method to quantify the heterogeneity of different decision boundaries, and use it to decompose the multi-class problem. The results show significant improvements over state-of-the-art decompositions that do not take the heterogeneity of decision boundaries into account. © 2013 IEEE.

Published

2022

33. SIAMBERT : Siamese Bert-based Code Search

Author

Pena, Francisco J., Gonzalez Lopez, Angel Luis, Pashami, Sepideh, Al-Shishtawy, Ahmad, Payberah, Amir H., Pena, Francisco J., Gonzalez Lopez, Angel Luis, Pashami, Sepideh, Al-Shishtawy, Ahmad, and Payberah, Amir H.

Abstract

Code Search is a practical tool that helps developers navigate growing source code repositories by connecting natural language queries with code snippets. Platforms such as StackOverflow resolve coding questions and answers; however, they cannot perform a semantic search through the code. Moreover, poorly documented code adds more complexity to search for code snippets in repositories. To tackle this challenge, this paper presents SIAMBERT, a BERT-based model that gets the question in natural language and returns relevant code snippets. The SIAMBERT architecture consists of two stages, where the first stage, inspired by Siamese Neural Network, returns the top K relevant code snippets to the input questions, and the second stage ranks the given snippets by the first stage. The experiments show that SIAMBERT outperforms non-BERT-based models having improvements that range from 12% to 39% on the Recall@1 metric and improves the inference time performance, making it 15x faster than standard BERT models., QC 20220930Part of proceedings: ISBN 978-166547126-8

Published

2022

34. Towards Geometry-Preserving Domain Adaptation for Fault Identification

Author

Taghiyarrenani, Zahra, Nowaczyk, Sławomir, Pashami, Sepideh, Bouguelia, Mohamed-Rafik, Taghiyarrenani, Zahra, Nowaczyk, Sławomir, Pashami, Sepideh, and Bouguelia, Mohamed-Rafik

Abstract

In most industries, the working conditions of equipment vary significantly from one site to another, from one time of a year to another, and so on. This variation poses a severe challenge for data-driven fault identification methods: it introduces a change in the data distribution. This contradicts the underlying assumption of most machine learning methods, namely that training and test samples follow the same distribution. Domain Adaptation (DA) methods aim to address this problem by minimizing the distribution distance between training (source) and test (target) samples. However, in the area of predictive maintenance, this idea is complicated by the fact that different classes – fault categories – also vary across domains. Most of the state-of-the-art DA methods assume that the data in the target domain is complete, i.e., that we have access to examples from all the possible classes or faulty categories during adaptation. In reality, this is often very difficult to guarantee. Therefore, there is a need for a domain adaptation method that is able to align the source and target domains even in cases of having access to an incomplete set of test data. This paper presents our work in progress as we propose an approach for such a setting based on maintaining the geometry information of source samples during the adaptation. This way, the model can capture the relationships between different fault categories and preserve them in the constructed domain-invariant feature space, even in situations where some classes are entirely missing. This paper examines this idea using artificial data sets to demonstrate the effectiveness of geometry-preserving transformation. We have also started investigations on real-world predictive maintenance datasets, such as CWRU.

Published

2022

35. An Explainable Knowledge-based AI Framework for Mobility as a Service

Author

Rajabi, Enayat, Nowaczyk, Sławomir, Pashami, Sepideh, Bergquist, Magnus, Rajabi, Enayat, Nowaczyk, Sławomir, Pashami, Sepideh, and Bergquist, Magnus

Abstract

Mobility as a Service (MaaS) is a relatively new domain where new types of knowledge systems have recently emerged. It combines various modes of transportation and different kinds of data to present personalized services to travellers based on transport needs. A knowledge-based framework based on Artificial Intelligence (AI) is proposed in this paper to integrate, analyze, and process different types of mobility data. The framework includes a knowledge acquisition process to extract and structure data from various sources, including mobility experts and add new information to a knowledge base. The role of AI in this framework is to aid in automatically discovering knowledge from various data sets and recommend efficient and personalized mobility services with explanations. A scenario is also presented to demonstrate the interaction of the proposed framework’s modules.

Published

2022

36. A Fault Detection Framework Based on LSTM Autoencoder : A Case Study for Volvo Bus Data Set

Author

Davari, Narjes, Pashami, Sepideh, Veloso, Bruno, Nowaczyk, Sławomir, Fan, Yuantao, Mota Pereira, Pedro, Ribeiro, Rita P., Gama, João, Davari, Narjes, Pashami, Sepideh, Veloso, Bruno, Nowaczyk, Sławomir, Fan, Yuantao, Mota Pereira, Pedro, Ribeiro, Rita P., and Gama, João

Abstract

This study applies a data-driven anomaly detection framework based on a Long Short-Term Memory (LSTM) autoencoder network for several subsystems of a public transport bus. The proposed framework efficiently detects abnormal data, significantly reducing the false alarm rate compared to available alternatives. Using historical repair records, we demonstrate how detection of abnormal sequences in the signals can be used for predicting equipment failures. The deviations from normal operation patterns are detected by analysing the data collected from several on-board sensors (e.g., wet tank air pressure, engine speed, engine load) installed on the bus. The performance of LSTM autoencoder (LSTM-AE) is compared against the multi-layer autoencoder (mlAE) network in the same anomaly detection framework. The experimental results show that the performance indicators of the LSTM-AE network, in terms of F1 Score, Recall, and Precision, are better than those of the mlAE network. © 2022 The Author(s), under exclusive license to Springer Nature Switzerland AG, Funding: The CHIST-ERA grant CHIST-ERA-19-XAI-012, project CHIST-ERA/0004/2019 funded by FCT - Fundação para a Ciência e Tecnologia and project 2020-00767 funded by Swedish Research Council., CHIST-ERA XPM

Published

2022

37. SurvSHAP : A Proxy-Based Algorithm for Explaining Survival Models with SHAP

Author

Alabdallah, Abdallah, Pashami, Sepideh, Rögnvaldsson, Thorsteinn, Ohlsson, Mattias, Alabdallah, Abdallah, Pashami, Sepideh, Rögnvaldsson, Thorsteinn, and Ohlsson, Mattias

Abstract

Survival Analysis models usually output functions (survival or hazard functions) rather than point predictions like regression and classification models. This makes the explanations of such models a challenging task, especially using the Shapley values. We propose SurvSHAP, a new model-agnostic algorithm to explain survival models that predict survival curves. The algorithm is based on discovering patterns in the predicted survival curves, the output of the survival model, that would identify significantly different survival behaviors, and utilizing a proxy model and SHAP method to explain these distinct survival behaviors. Experiments on synthetic and real datasets demonstrate that the SurvSHAP is able to capture the underlying factors of the survival patterns. Moreover, SurvSHAP results on the Cox Proportional Hazard model are compared with the weights of the model to show that we provide faithful overall explanations, with more fine-grained explanations of the sub-populations. We also illustrate the wrong model and explanations learned by a Cox model when applied to heterogeneous sub-populations. We show that a non-linear machine learning survival model with SurvSHAP can better model the data and provide better explanations than linear models., Funding: This research was funded by the CHIST-ERA grant CHIST-ERA-19-XAI-012 and CAISR+ project funded by the Swedish Knowledge Foundation.Som manuscript i avhandling/As manuscript in thesis.

Published

2022

38. Adversarial Contrastive Semi-Supervised Domain Adaptation

Author

Taghiyarrenani, Zahra, Nowaczyk, Sławomir, Pashami, Sepideh, Bouguelia, Mohamed-Rafik, Taghiyarrenani, Zahra, Nowaczyk, Sławomir, Pashami, Sepideh, and Bouguelia, Mohamed-Rafik

Abstract

Domain Adaptation (DA) aims to transfer knowledge from a source to a target domain by aligning their respective data distributions. In the unsupervised setting, however, this may cause the source and target samples of different classes to align to each other, consequently leading to negative transfer. Semi-Supervised Domain Adaptation (SSDA) tries to solve such class misalignment problem by exploiting a few sample labels in the target domain. This paper proposes a new SSDA method called Adversarial Contrastive Semi-Supervised Domain Adaptation (ACSSDA) which combines two objectives, optimized for the case where very few target sample labels are available, to learn a shared feature representation for both source and target domains. ACSSDA uses a domain classifier to ensure that the resulting feature space is domain agnostic. Simultaneously, Contrastive loss aims to pull together samples of the same class and push apart samples of different classes. This is shown to reduce class misalignment and negative transfer even with as little as a single labeled sample per class. We demonstrate the effectiveness of ACSSDA with experiments on several benchmark data sets. The results show the superiority of our method over state-of-the-art approaches.

Published

2022

39. Semi-Supervised Learning for Forklift Activity Recognition from Controller Area Network (CAN) Signals

Author

Chen, Kunru, primary, Rögnvaldsson, Thorsteinn, additional, Nowaczyk, Sławomir, additional, Pashami, Sepideh, additional, Johansson, Emilia, additional, and Sternelöv, Gustav, additional

Published

2022

40. Why Is Multiclass Classification Hard?

Author

Moral, Pablo Del, primary, Nowaczyk, Slawomir, additional, and Pashami, Sepideh, additional

Published

2022

41. Forklift Truck Activity Recognition from CAN Data

Author

Chen, Kunru, Pashami, Sepideh, Nowaczyk, Sławomir, Johansson, Emilia, Sternelöv, Gustav, Rögnvaldsson, Thorsteinn, Chen, Kunru, Pashami, Sepideh, Nowaczyk, Sławomir, Johansson, Emilia, Sternelöv, Gustav, and Rögnvaldsson, Thorsteinn

Abstract

Machine activity recognition is important for accurately esti- mating machine productivity and machine maintenance needs. In this paper, we present ongoing work on how to recognize activities of forklift trucks from on-board data streaming on the controller area network. We show that such recognition works across different sites. We first demon- strate the baseline classification performance of a Random Forest that uses 14 signals over 20 time steps, for a 280-dimensional input. Next, we show how a deep neural network can learn low-dimensional representa- tions that, with fine-tuning, achieve comparable accuracy. The proposed representation achieves machine activity recognition. Also, it visualizes the forklift operation over time and illustrates the relationships across different activities. © Springer Nature Switzerland AG 2020

Published

2021

42. Hierarchical Multi-class Classification for Fault Diagnosis

Author

Del Moral, Pablo, Nowaczyk, Sławomir, Pashami, Sepideh, Del Moral, Pablo, Nowaczyk, Sławomir, and Pashami, Sepideh

Abstract

This paper formulates the problem of predictive maintenance for complex systems as a hierarchical multi-class classification task. This formulation is useful for equipment with multiple sub-systems and components performing heterogeneous tasks. Often, the data available describes the whole system's operation and is not ideal for accurate condition monitoring. In this setup, specialized predictive models analyzing one component at a time rarely perform much better than random. However, using machine learning and hierarchical approaches, we can still exploit the data to build a fault isolation system that provides measurable benefits for technicians in the field. We propose a method for creating a taxonomy of components to train hierarchical classifiers that aim to identify the faulty component. The output of this model is a structured set of predictions with different probabilities for each component. In this setup, traditional machine learning metrics fail to capture the relationship between the performance of the models and its usefulness in the field.We introduce a new metric to evaluate our approach's benefits; it measures the number of tests a technician needs to perform before pinpointing the faulty component. Using a dataset from a real-case problem coming fro the automotive industry, we demonstrate how traditional machine learning performance metrics, like accuracy, fail to capture practical benefits. Our proposed hierarchical approach succeeds in exploiting the information in the data and outperforms non-hierarchical machine learning solutions. In addition, we can identify the weakest link of our fault isolation model, allowing us to improve it efficiently.

Published

2021

43. COCLUBERT : Clustering Machine Learning Source Code

Author

Hägglund, Marcus, Pena, Francisco J., Pashami, Sepideh, Al-Shishtawy, Ahmad, Payberah, Amir H., Hägglund, Marcus, Pena, Francisco J., Pashami, Sepideh, Al-Shishtawy, Ahmad, and Payberah, Amir H.

Abstract

Nowadays, we can find machine learning (ML) applications in nearly every aspect of modern life, and we see that more developers are engaged in the field than ever. In order to facilitate the development of new ML applications, it would be beneficial to provide services that enable developers to share, access, and search for source code easily. A step towards making such a service is to cluster source code by functionality. In this work, we present COCLUBERT, a BERT-based model for source code embedding based on their functionality and clustering them accordingly. We build COCLUBERT using CuBERT, a variant of BERT pre-trained on source code, and present three ways to fine-tune it for the clustering task. In the experiments, we compare COCLUBERT with a baseline model, where we cluster source code using CuBERT embedding without fine-tuning. We show that COCLUBERT significantly outperforms the baseline model by increasing the Dunn Index metric by a factor of 141, the Silhouette Score metric by a factor of two, and the Adjusted Rand Index metric by a factor of 11., QC 20220530Part of proceedings ISBN 978-1-6654-4337-1

Published

2021

44. Extracting Invariant Features for Predicting State of Health of Batteries in Hybrid Energy Buses

Author

Altarabichi, Mohammed Ghaith, Fan, Yuantao, Pashami, Sepideh, Sheikholharam Mashhadi, Peyman, Nowaczyk, Sławomir, Altarabichi, Mohammed Ghaith, Fan, Yuantao, Pashami, Sepideh, Sheikholharam Mashhadi, Peyman, and Nowaczyk, Sławomir

Abstract

Batteries are a safety-critical and the most expensive component for electric vehicles (EVs). To ensure the reliability of the EVs in operation, it is crucial to monitor the state of health of those batteries. Monitoring their deterioration is also relevant to the sustainability of the transport solutions, through creating an efficient strategy for utilizing the remaining capacity of the battery and its second life. Electric buses, similar to other EVs, come in many different variants, including different configurations and operating conditions. Developing new degradation models for each existing combination of settings can become challenging from different perspectives such as unavailability of failure data for novel settings, heterogeneity in data, low amount of data available for less popular configurations, and lack of sufficient engineering knowledge. Therefore, being able to automatically transfer a machine learning model to new settings is crucial. More concretely, the aim of this work is to extract features that are invariant across different settings. In this study, we propose an evolutionary method, called genetic algorithm for domain invariant features (GADIF), that selects a set of features to be used for training machine learning models, in such a way as to maximize the invariance across different settings. A Genetic Algorithm, with each chromosome being a binary vector signaling selection of features, is equipped with a specific fitness function encompassing both the task performance and domain shift. We contrast the performance, in migrating to unseen domains, of our method against a number of classical feature selection methods without any transfer learning mechanism. Moreover, in the experimental result section, we analyze how different features are selected under different settings. The results show that using invariant features leads to a better generalization of the machine learning models to an unseen domain., Som manuscript i avhandling/As manuscript in thesis

Published

2021

45. Parallel orthogonal deep neural network

Author

Sheikholharam Mashhadi, Peyman, Nowaczyk, Sławomir, Pashami, Sepideh, Sheikholharam Mashhadi, Peyman, Nowaczyk, Sławomir, and Pashami, Sepideh

Abstract

Ensemble learning methods combine multiple models to improve performance by exploiting their diversity. The success of these approaches relies heavily on the dissimilarity of the base models forming the ensemble. This diversity can be achieved in many ways, with well-known examples including bagging and boosting. It is the diversity of the models within an ensemble that allows the ensemble to correct the errors made by its members, and consequently leads to higher classification or regression performance. A mistake made by a base model can only be rectified if other members behave differently on that particular instance, and provide the aggregator with enough information to make an informed decision. On the contrary, lack of diversity not only lowers model performance, but also wastes computational resources. Nevertheless, in the current state of the art ensemble approaches, there is no guarantee on the level of diversity achieved, and no mechanism ensuring that each member will learn a different decision boundary from the others. In this paper, we propose a parallel orthogonal deep learning architecture in which diversity is enforced by design, through imposing an orthogonality constraint. Multiple deep neural networks are created, parallel to each other. At each parallel layer, the outputs of different base models are subject to Gram–Schmidt orthogonalization. We demonstrate that this approach leads to a high level of diversity from two perspectives. First, the models make different errors on different parts of feature space, and second, they exhibit different levels of uncertainty in their decisions. Experimental results confirm the benefits of the proposed method, compared to standard deep learning models and well-known ensemble methods, in terms of diversity and, as a result, classification performance. © 2021 The Author(s). Published by Elsevier Ltd., CAISR+

Published

2021

46. AI Perspectives in Smart Cities and Communities to Enable Road Vehicle Automation and Smart Traffic Control

Author

Englund, Cristofer, primary, Aksoy, Eren Erdal, additional, Alonso-Fernandez, Fernando, additional, Cooney, Martin Daniel, additional, Pashami, Sepideh, additional, and Åstrand, Björn, additional

Published

2021

47. Decentralized and Adaptive K-Means Clusteringfor Non-IID Data using HyperLogLog Counters

Author

Soliman, Amira, Girdzijauskas, Sarunas, Bouguelia, Mohamed-Rak, Pashami, Sepideh, and Nowaczyk2, Slawomir

Subjects

Other Electrical Engineering, Electronic Engineering, Information Engineering, Annan elektroteknik och elektronik

Abstract

The data shared over the Internet tends to originate from ubiquitous and autonomous sources such as mobile phones, fitness trackers, and IoT devices. Centralized and federated machine learning solutions represent the predominant way of providing smart services for users. However, moving data to central location for analysis causes not only many privacy concerns, but also communication overhead. Therefore, in certain situations machine learning models need to be trained in a collaborative and decentralized manner, similar to the way the data is originally generated without requiring any central authority for data or model aggregation. This paper presents a decentralized and adaptive k-means algorithm that clusters data from multiple sources organized in peer-to-peer networks. Our algorithm allows peers to reach an approximation of the global model without sharing any raw data. Most importantly, we address the challenge of decentralized clustering with skewed non-IID data and asynchronous computations by integrating HyperLogLog counters with k-means algorithm. Furthermore, our clustering algorithm allows nodes to individually determine the number of clusters that fits their local data. Results using synthetic and real-world datasets show that our algorithm outperforms state-of-the-art decentralized k-means algorithms achieving accuracy gain that is up-to 36%. QC 20200319

Published

2020

48. Stacked Ensemble of Recurrent Neural Networks for Predicting Turbocharger Remaining Useful Life

Author

Sheikholharam Mashhadi, Peyman, Nowaczyk, Sławomir, and Pashami, Sepideh

Subjects

predictive maintenance, Stacked Ensemble, remaining useful life, recurrent neural networks, LSTM, Other Computer and Information Science, Annan data- och informationsvetenskap

Abstract

Predictive Maintenance (PM) is a proactive maintenance strategy that tries to minimize a system’s downtime by predicting failures before they happen. It uses data from sensors to measure the component’s state of health and make forecasts about its future degradation. However, existing PM methods typically focus on individual measurements. While it is natural to assume that a history of measurements carries more information than a single one. This paper aims at incorporating such information into PM models. In practice, especially in the automotive domain, diagnostic models have low performance, due to a large amount of noise in the data and limited sensing capability. To address this issue, this paper proposes to use a specific type of ensemble learning known as Stacked Ensemble. The idea is to aggregate predictions of multiple models—consisting of Long Short-Term Memory (LSTM) and Convolutional-LSTM—via a meta model, in order to boost performance. Stacked Ensemble model performs well when its base models are as diverse as possible. To this end, each such model is trained using a specific combination of the following three aspects: feature subsets, past dependency horizon, and model architectures. Experimental results demonstrate benefits of the proposed approach on a case study of heavy-duty truck turbochargers. © 2019 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/). HEALTH-VINNOVA

Published

2020

49. Modeling turbocharger failures using Markov process for predictive maintenance

Author

Rahat, Mahmoud, Pashami, Sepideh, Nowaczyk, Sławomir, Kharazian, Zahra, Rahat, Mahmoud, Pashami, Sepideh, Nowaczyk, Sławomir, and Kharazian, Zahra

Abstract

The advancements of the telematics and connectivity solutions have provided new opportunities for the field of predictive maintenance. The number of sensors installed on a vehicle is increasing over time, and manufacturers are looking for new ways to improve the uptime of their fleet while at the same time reducing the costs related to unexpected breakdowns. The nature of the aggregated data from vehicles is sequential, and it is interesting to investigate existing methods for modeling partially observable state sequences to detect common patterns of failure. In this paper, we introduce a new approach for predicting turbocharger failures of Volvo trucks. The first step of the method deals with modeling a sequence of readouts from each vehicle using a Markov process. To do so, we identify the most informative signals and then employ spatial similarity clustering on the readouts. We interpret each cluster as a Markov state and further convert the history of a truck into a trajectory of states. This trajectory is then aligned with repairs information to form a standard sequence labeling problem. Finally, we train a hidden Markov model (HMM) classifier for assessing the health condition of the equipment. Empirical evaluations obtained on our realworld dataset of trucks suggest that the proposed method improves the AUC score of the final system up to 6% for predicting failures of a turbocharger.

Published

2020

50. Decentralized and Adaptive K-Means Clustering for Non-IID Data using HyperLogLog Counters

Author

Soliman, Amira, Girdzijauskas, Sarunas, Bouguelia, Mohamed-Rafik, Pashami, Sepideh, Nowaczyk, Sławomir, Soliman, Amira, Girdzijauskas, Sarunas, Bouguelia, Mohamed-Rafik, Pashami, Sepideh, and Nowaczyk, Sławomir

Abstract

The data shared over the Internet tends to originate from ubiquitous and autonomous sources such as mobile phones, fitness trackers, and IoT devices. Centralized and federated machine learning solutions represent the predominant way of providing smart services for users. However, moving data to central location for analysis causes not onlymany privacy concerns, but also communication overhead. Therefore, incertain situations machine learning models need to be trained in a collaborative and decentralized manner, similar to the way the data is originally generated without requiring any central authority for data or modelaggregation. This paper presents a decentralized and adaptive k-means algorithm that clusters data from multiple sources organized in peer-to-peer networks. Our algorithm allows peers to reach an approximation of the global model without sharing any raw data. Most importantly, we address the challenge of decentralized clustering with skewed non-IID data and asynchronous computations by integrating HyperLogLog counters with k-means algorithm. Furthermore, our clustering algorithm allows nodes to individually determine the number of clusters that fits their local data. Results using synthetic and real-world datasets show that our algorithm outperforms state-of-the-art decentralized k-means algorithms achieving accuracy gain that is up-to 36%. © Springer Nature Switzerland AG 2020., This research has been conducted within the BIDAF: A Big Data Analytics Framework for a Smart Society (http://bidaf.sics.se/).

Published

2020