Your search keyword '"Aneta Vulgarakis Feljan"' showing total 12 results

1. Timing Predictability and Security in Safety-Critical Industrial Cyber-Physical Systems: A Position Paper

Author

Saad Mubeen, Elena Lisova, and Aneta Vulgarakis Feljan

Subjects

timing predictability, cyber-physical systems, CPS, functional safety, security, embedded systems, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Cyber Physical Systems (CPSs) are systems that are developed by seamlessly integrating computational algorithms and physical components, and they are a result of the technological advancement in the embedded systems and distributed systems domains, as well as the availability of sophisticated networking technology. Many industrial CPSs are subject to timing predictability, security and functional safety requirements, due to which the developers of these systems are required to verify these requirements during the their development. This position paper starts by exploring the state of the art with respect to developing timing predictable and secure embedded systems. Thereafter, the paper extends the discussion to time-critical and secure CPSs and highlights the key issues that are faced when verifying the timing predictability requirements during the development of these systems. In this context, the paper takes the position to advocate paramount importance of security as a prerequisite for timing predictability, as well as both security and timing predictability as prerequisites for functional safety. Moreover, the paper identifies the gaps in the existing frameworks and techniques for the development of time- and safety-critical CPSs and describes our viewpoint on ensuring timing predictability and security in these systems. Finally, the paper emphasises the opportunities that artificial intelligence can provide in the development of these systems.

Published

2020

2. Guest Editorial Special Issue on Distributed Learning Over Wireless Edge Networks—Part II

Author

Mingzhe Chen, Deniz Gunduz, Kaibin Huang, Walid Saad, Mehdi Bennis, Aneta Vulgarakis Feljan, and H. Vincent Poor

Subjects

Computer Networks and Communications, Electrical and Electronic Engineering

Published

2022

3. Distributed Learning in Wireless Networks: Recent Progress and Future Challenges

Author

Deniz Gunduz, Walid Saad, Kaibin Huang, Mingzhe Chen, Mehdi Bennis, Aneta Vulgarakis Feljan, H. Vincent Poor, Commission of the European Communities, and Engineering & Physical Science Research Council (EPSRC)

Subjects

FOS: Computer and information sciences, Technology, Computer Science - Machine Learning, Information privacy, Computer science, Distributed computing, 02 engineering and technology, ALLOCATION, Machine Learning (cs.LG), Data modeling, Engineering, DESIGN, COMMUNICATION-EFFICIENT, 0202 electrical engineering, electronic engineering, information engineering, federated distillation, Reinforcement learning, Wireless networks, wireless edge networks, Measurement, federated learning, Wireless network, POWER-CONTROL, Data models, 0906 Electrical and Electronic Engineering, Telecommunications, Performance evaluation, Enhanced Data Rates for GSM Evolution, Networking & Telecommunications, STOCHASTIC GRADIENT DESCENT, Edge device, multi-agent reinforcement learning, Computer Networks and Communications, Computer Science - Information Theory, 0805 Distributed Computing, UNCODED TRANSMISSION, THE-AIR COMPUTATION, 1005 Communications Technologies, Training, Overhead (computing), Wireless, Distance learning, Electrical and Electronic Engineering, 6G, Distributed learning, Science & Technology, business.industry, Information Theory (cs.IT), distributed inference, Engineering, Electrical & Electronic, 020206 networking & telecommunications, Computer aided instruction, business

Abstract

The next-generation of wireless networks will enable many machine learning (ML) tools and applications to efficiently analyze various types of data collected by edge devices for inference, autonomy, and decision making purposes. However, due to resource constraints, delay limitations, and privacy challenges, edge devices cannot offload their entire collected datasets to a cloud server for centrally training their ML models or inference purposes. To overcome these challenges, distributed learning and inference techniques have been proposed as a means to enable edge devices to collaboratively train ML models without raw data exchanges, thus reducing the communication overhead and latency as well as improving data privacy. However, deploying distributed learning over wireless networks faces several challenges including the uncertain wireless environment (e.g., dynamic channel and interference), limited wireless resources (e.g., transmit power and radio spectrum), and hardware resources (e.g., computational power). This paper provides a comprehensive study of how distributed learning can be efficiently and effectively deployed over wireless edge networks. We present a detailed overview of several emerging distributed learning paradigms, including federated learning, federated distillation, distributed inference, and multi-agent reinforcement learning. For each learning framework, we first introduce the motivation for deploying it over wireless networks. Then, we present a detailed literature review on the use of communication techniques for its efficient deployment. We then introduce an illustrative example to show how to optimize wireless networks to improve its performance. Finally, we introduce future research opportunities. In a nutshell, this paper provides a holistic set of guidelines on how to deploy a broad range of distributed learning frameworks over real-world wireless communication networks.

Published

2021

4. The TROCA Project: An autonomous transportation robot controlled by a cognitive architecture

Author

Wandemberg Gibaut, Sender Rocha, Ian Oliveira, Aneta Vulgarakis Feljan, Eduardo Fróes, Klaus Raizer, Eric Rohmer, André Luis Ogando Paraense, and Ricardo R. Gudwin

Subjects

Computer science, Generalization, business.industry, Cognitive Neuroscience, Control (management), Experimental and Cognitive Psychology, Mobile robot, 02 engineering and technology, Cognitive architecture, Autonomous robot, 03 medical and health sciences, 0302 clinical medicine, Work (electrical), Artificial Intelligence, 0202 electrical engineering, electronic engineering, information engineering, Robot, 020201 artificial intelligence & image processing, Architecture, Software engineering, business, 030217 neurology & neurosurgery, Software

Abstract

Autonomous mobile robots emerged as an important kind of transportation system in warehouses and factories. In this work, we present the use of MECA cognitive architecture in the development of an artificial mind for an autonomous robot responsible for multiple tasks, including transportation of packages along a factory floor, environment exploration, warehouse inventory, its internal energy management, self-monitoring and dealing with human operators and other robots. The present text provides a detailed specification for the architecture and its software implementation. Future work will present the simulation results under different configurations, together with a detailed analysis of the architecture performance and its generalization for autonomous robot control.

Published

2020

5. Intent-driven strategic tactical planning for autonomous site inspection using cooperative drones

Author

Marios Daoutis, Aneta Vulgarakis Feljan, Marin Orlic, Michael Cashmore, Daniele Magazzeni, Dorian Buksz, Swarup Kumar Mohalik, Ramamurthy Badrinath, and Anusha Mujumdar

Subjects

Computer science, TK, SIGNAL (programming language), Tactical planning, 02 engineering and technology, Drone, Task (project management), Base station, 020303 mechanical engineering & transports, 0203 mechanical engineering, Automated planning and scheduling, 0202 electrical engineering, electronic engineering, information engineering, Systems engineering, Task analysis, 020201 artificial intelligence & image processing, State (computer science)

Abstract

Realization of industry-scale, goal-driven, autonomous systems with AI planning technology faces several challenges: flexibly specifying planning goal states in varying situations, synthesizing plans in large state spaces, re-planning in dynamic situations, and facilitating humans to supervise, give feedback and intervene. In this paper, we present Intent-driven Strategic Tactical Planning (ISTP) to address these challenges. We demonstrate its efficacy through its application for radio base station inspection across several locations using drones. The inspection task involves capturing images, thermal images or signal measurements - called knowledge-objects - of various components of the base stations for downstream processing. In the ISTP approach, an operator indicates her goals by flying the drone to different components of interest. These goals are generalized to capture the intent of the operator, which are then instantiated in new situations to generate goals dynamically. Towards planning and re-planning in large state spaces to achieve these goals efficiently, we extend the Strategic-Tactical Planning paradigm. All the components of ISTP are integrated in an intuitive UI and demonstrated through a real life use-case built on the UNITY simulator platform.

Published

2021

6. Guest editorial special issue on distributed learning over wireless edge networks - Part i

Author

Walid Saad, H. Vincent Poor, Mehdi Bennis, Aneta Vulgarakis Feljan, Deniz Gunduz, Kaibin Huang, and Mingzhe Chen

Subjects

Information privacy, Edge device, Computer Networks and Communications, Computer science, business.industry, Wireless network, Distributed computing, Cloud computing, Server, Reinforcement learning, Wireless, Network performance, Electrical and Electronic Engineering, business

Abstract

Analyzing massive amounts of data using complex machine learning models requires significant computational resources. The conventional approach to such problems involves centralizing training data and inference processes in the cloud, i.e., in data centers. However, with the proliferation of mobile devices and increasing application of the Internet-of-Things (IoT) paradigm, very large amounts of data are collected at the edges of wireless networks, and due to privacy constraints and limited communication resources, it is undesirable or impractical to upload this data from mobile devices to the cloud for centralized learning. This problem can be solved by distributed learning at the network edge, by which edge devices collaboratively train a shared learning model using real-time mobile data. The avoidance of raw-data uploading not only helps to preserve privacy but may also alleviate network-traffic congestion and minimize latency. With that said, distributed training still requires a substantial amount of information exchange between devices and edge servers over wireless links. In the process, wireless impairments such as noise, interference, and imperfect knowledge of channel states can significantly slow down distributed learning (e.g., convergence speed) and degrades its performance (e.g., learning accuracy). This makes it crucial to optimize wireless network performance so as to support the efficient deployment of distributed learning algorithms. On the other hand, distributed learning algorithms provide a powerful tool-set for solving complex problems in wireless communication and networking. One important framework, called federated learning (FL), enables users to collaboratively learn a shared model while helping to preserve local data privacy. The application of FL can endow edge devices with capabilities of user behavior prediction, user identification, and wireless environment analysis. As another example, distributed reinforcement learning is capable of leveraging distributed computation power and data to solve complex optimization and control problems that arise in various use cases, such as network control, user clustering, resource management, and interference alignment. To cover this paradigm of distributed learning over wireless networks, this two-part Special Issue features papers dealing with two main research challenges: a) optimization of wireless network performance for efficient implementation of distributed learning in wireless networks, and b) distributed learning for solving communication problems and optimizing network performance.

Published

2021

7. Timing Predictability and Security in Safety-Critical Industrial Cyber-Physical Systems: A Position Paper

Author

Aneta Vulgarakis Feljan, Elena Lisova, and Saad Mubeen

Subjects

Computer science, Context (language use), 02 engineering and technology, security, cyber-physical systems, lcsh:Technology, lcsh:Chemistry, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Predictability, Instrumentation, lcsh:QH301-705.5, Fluid Flow and Transfer Processes, Functional safety, lcsh:T, Process Chemistry and Technology, General Engineering, Cyber-physical system, functional safety, CPS eco-system, 020207 software engineering, lcsh:QC1-999, 020202 computer hardware & architecture, Computer Science Applications, timing predictability, Risk analysis (engineering), lcsh:Biology (General), lcsh:QD1-999, lcsh:TA1-2040, Position (finance), Position paper, CPS, embedded systems, State (computer science), Technological advance, lcsh:Engineering (General). Civil engineering (General), lcsh:Physics

Abstract

Cyber Physical Systems (CPSs) are systems that are developed by seamlessly integrating computational algorithms and physical components, and they are a result of the technological advancement in the embedded systems and distributed systems domains, as well as the availability of sophisticated networking technology. Many industrial CPSs are subject to timing predictability, security and functional safety requirements, due to which the developers of these systems are required to verify these requirements during the their development. This position paper starts by exploring the state of the art with respect to developing timing predictable and secure embedded systems. Thereafter, the paper extends the discussion to time-critical and secure CPSs and highlights the key issues that are faced when verifying the timing predictability requirements during the development of these systems. In this context, the paper takes the position to advocate paramount importance of security as a prerequisite for timing predictability, as well as both security and timing predictability as prerequisites for functional safety. Moreover, the paper identifies the gaps in the existing frameworks and techniques for the development of time- and safety-critical CPSs and describes our viewpoint on ensuring timing predictability and security in these systems. Finally, the paper emphasises the opportunities that artificial intelligence can provide in the development of these systems.

Published

2020

8. Knowledge Representation of Cyber-physical Systems for Monitoring Purpose

Author

Elena Fersman, Swarup Kumar Mohalik, Didem Gürdür, Ramamurthy Badrinath, Anusha Mujumdar, Aneta Vulgarakis Feljan, and Jad El-khoury

Subjects

Production Engineering, Human Work Science and Ergonomics, Computer and Information Sciences, 0209 industrial biotechnology, Knowledge management, Knowledge representation and reasoning, business.industry, Computer science, Produktionsteknik, arbetsvetenskap och ergonomi, Cyber-physical system, Data- och informationsvetenskap, Robotics, 02 engineering and technology, Business objectives, 020901 industrial engineering & automation, Robotteknik och automation, Work (electrical), 0202 electrical engineering, electronic engineering, information engineering, General Earth and Planetary Sciences, Manufacturing, Surface and Joining Technology, 020201 artificial intelligence & image processing, Bearbetnings-, yt- och fogningsteknik, business, General Environmental Science

Abstract

Automated warehouses, as a form of cyber-physical systems (CPSs), require several components to work collaboratively to address the common business objectives of complex logistics systems. During the collaborative operations, a number of key performance indicators (KPI) can be monitored to understand the proficiency of the warehouse and control the operations and decisions. It is possible to drive and monitor these KPIs by looking at both the state of the warehouse components and the operations carried out by them. Therefore, it is necessary to represent this knowledge in an explicit and formally-specified data model and provide automated methods to derive the KPIs from the representation. In this paper, we implement a minimalistic data model for a subset of warehouse resources using linked data in order to monitor a few KPIs, namely sustainability, safety and performance. The applicability of the approach and the data model is illustrated through a use case. We demonstrate that it is possible to develop minimalistic data models through Open Services for Lifecycle Collaboration (OSLC) resource shapes which enables compatibility with the declarative and procedural knowledge of automated warehouse agents specified in Planning Domain Definition Language (PDDL). QC 20180530 SCOTT

Published

2018

9. HIPR: An Architecture for Iterative Plan Repair in Hierarchical Multi-agent Systems

Author

Mahesh Babu Jayaraman, Swarup Kumar Mohalik, Aneta Vulgarakis Feljan, and Ramamurthy Badrinath

Subjects

020301 aerospace & aeronautics, 0203 mechanical engineering, General Computer Science, Computer science, Multi-agent system, Distributed computing, 0103 physical sciences, 02 engineering and technology, Plan (drawing), Architecture, 010303 astronomy & astrophysics, 01 natural sciences

Published

2018

10. Visualizing Autonomous Warehouse Data Streams Through User-Centered Design

Author

Raghu Nayyar, Didem Gürdür Broo, and Aneta Vulgarakis Feljan

Subjects

data visualization, information visualization, cyber-physical systems, user experience, user-centered design, expert opinion interviews, prototyping, data structures, supply chain, autonomous warehouse, intelligent agents, dashboard design, Teknik och teknologier, Engineering and Technology, Inbäddad systemteknik, Computer Engineering, Human Computer Interaction, Embedded Systems, Människa-datorinteraktion (interaktionsdesign), Datorteknik

Abstract

This paper summarizes the work is done, which is carried out to develop and evaluate a dashboard design that visualizes a stream of data from different entities involved in autonomous warehouses, as a subset of cyber-physical systems. The dashboard is designed and developed through User- Centered Design (UCD) methodologies based on two iterations of feedback sessions with the stakeholders. During these sessions, semi-structured expert opinion interviews are conducted. The paper discusses the different stages involved in building the proposed dashboard design, the design decisions, the technical aspects of the libraries used, and the results of the feedback sessions towards the end of the project. It also presents the implemented dashboard as proof of development efforts and explains its different functionalities. The study concludes by evaluating the dashboard through the semi-structured interviews with the respective stakeholders and suggests features for further development. QC 20190304 SCOTT

Published

2019

11. Feasibility Assessment to Realise Vehicle Teleoperation using Cellular Networks

Author

Leonid Mokrushin, Nicolas Schrammar, Aneta Vulgarakis Feljan, Athanasios Karapantelakis, Rafia Inam, Elena Fersman, and Keven Wang

Subjects

Engineering, ComputerApplications_COMPUTERSINOTHERSYSTEMS, 02 engineering and technology, Domain (software engineering), 0502 economics and business, 0202 electrical engineering, electronic engineering, information engineering, Use case, Quality-of-Service, Simulation, 050210 logistics & transportation, business.industry, Computer Sciences, Quality of service, Mobile broadband, 05 social sciences, Testbed, Communication Systems, Cellular networks, 020206 networking & telecommunications, Telekommunikation, Datavetenskap (datalogi), Teleoperation, Cellular network, vehicle teleoperation, Telecommunications, ITS, business, 5G, Kommunikationssystem

Abstract

Future cellular networks (5G) will be used for a diversity of use cases. Transportation is one domain where cellular networks can play a significant role not only in connecting autonomous vehicles to other vehicles, infrastructures, and people, but also in realizing vehicle teleoperation i.e., vehicle driven by an operator from a distance. In this paper, we assess the feasibility of using a cellular network to realise vehicle teleoperation. We identify the network requirements for a teleoperated vehicle use case in an urban environment using a test setup of an LTE network and simulations. Testbed measurements reveal that teleoperation use cases can be supported even with less than excellent signal strength. Through simulation we show that the testbed can scale to cover greater distances and support teleoperation use cases even with background mobile broadband traffic.

Published

2016

12. Towards Automated Service-Oriented Lifecycle Management for 5G Networks

Author

Leonid Mokrushin, Aneta Vulgarakis Feljan, Rafia Inam, Elena Fersman, Konstantinos Vandikas, and Athanasios Karapantelakis

Subjects

Structure of Management Information, Decision support system, Knowledge management, Process management, network slicing, Computer science, FCAPS, Data management, Internet of Things, Mobile computing, Application lifecycle management, Network management application, Information Technology Infrastructure Library, Software, Customer Service Assurance, Configuration management, Service product management, business.industry, cloud computing, Communication Systems, knowledge management, Telekommunikation, Network management, service management lifecycle, Network service, Element management system, Telecommunications, business, Network management station, 5G, Kommunikationssystem

Abstract

5G networks will be a key enabler for the Internet of Things by providing a platform to connect a massive number of devices with heterogeneous sets of network quality requirements. In this environment, 5G network operators will have to solve the complex challenge of managing network services for diverse customer sectors (such as automotive, health or energy) with different requirements throughout their lifecycle.In this paper, we present current state of our work on automating part of the network service lifecycle management using knowledge management- and decision support techniques. We also present our ongoing implementation steps for such management function in 5G networks. QC 20210210.QC 20210723

Published

2015