Your search keyword '"Lemic, Filip"' showing total 174 results

1. Generating Realistic Synthetic Head Rotation Data for Extended Reality using Deep Learning

Author

Struye, Jakob, Lemic, Filip, and Famaey, Jeroen

Subjects

Computer Science - Computer Vision and Pattern Recognition, Computer Science - Artificial Intelligence

Abstract

Extended Reality is a revolutionary method of delivering multimedia content to users. A large contributor to its popularity is the sense of immersion and interactivity enabled by having real-world motion reflected in the virtual experience accurately and immediately. This user motion, mainly caused by head rotations, induces several technical challenges. For instance, which content is generated and transmitted depends heavily on where the user is looking. Seamless systems, taking user motion into account proactively, will therefore require accurate predictions of upcoming rotations. Training and evaluating such predictors requires vast amounts of orientational input data, which is expensive to gather, as it requires human test subjects. A more feasible approach is to gather a modest dataset through test subjects, and then extend it to a more sizeable set using synthetic data generation methods. In this work, we present a head rotation time series generator based on TimeGAN, an extension of the well-known Generative Adversarial Network, designed specifically for generating time series. This approach is able to extend a dataset of head rotations with new samples closely matching the distribution of the measured time series., Comment: Published and presented at International Conference on Multimedia 2022 (ACMMM), Workshop on Interactive eXtended Reality (IXR)

Published

2025

2. Opportunities and Challenges for Virtual Reality Streaming over Millimeter-Wave: An Experimental Analysis

Author

Struye, Jakob, Ravuri, Hemanth Kumar, Assasa, Hany, Fiandrino, Claudio, Lemic, Filip, Widmer, Joerg, Famaey, Jeroen, and Vega, Maria Torres

Subjects

Computer Science - Networking and Internet Architecture

Abstract

Achieving extremely high-quality and truly immersive interactive Virtual Reality (VR) is expected to require a wireless link to the cloud, providing multi-gigabit throughput and extremely low latency. A prime candidate for fulfilling these requirements is millimeter-wave (mmWave) communications, operating in the 30 to 300 GHz bands, rather than the traditional sub-6 GHz. Evaluations with first-generation mmWave Wi-Fi hardware, based on the IEEE 802.11ad standard, have so far largely remained limited to lower-layer metrics. In this work, we present the first experimental analysis of the capabilities of mmWave for streaming VR content, using a novel testbed capable of repeatably creating blockage through mobility. Using this testbed, we show that (a) motion may briefly interrupt transmission, (b) a broken line of sight may degrade throughput unpredictably, and (c) TCP-based streaming frameworks need careful tuning to behave well over mmWave., Comment: Published and presented at International Conference on Network of the Future 2022

Published

2025

3. Toward Interactive Multi-User Extended Reality Using Millimeter-Wave Networking

Author

Struye, Jakob, Van Damme, Sam, Bhat, Nabeel Nisar, Troch, Arno, Van Liempd, Barend, Assasa, Hany, Lemic, Filip, Famaey, Jeroen, and Vega, Maria Torres

Subjects

Computer Science - Networking and Internet Architecture

Abstract

Extended Reality (XR) enables a plethora of novel interactive shared experiences. Ideally, users are allowed to roam around freely, while audiovisual content is delivered wirelessly to their Head-Mounted Displays (HMDs). Therefore, truly immersive experiences will require massive amounts of data, in the range of tens of gigabits per second, to be delivered reliably at extremely low latencies. We identify Millimeter-Wave (mmWave) communications, at frequencies between 24 and 300 GHz, as a key enabler for such experiences. In this article, we show how the mmWave state of the art does not yet achieve sufficient performance, and identify several key active research directions expected to eventually pave the way for extremely-high-quality mmWave-enabled interactive multi-user XR., Comment: Published in IEEE Communications Magazine

Published

2025

4. Miniature UAV Empowered Reconfigurable Energy Harvesting Holographic Surfaces in THz Cooperative Networks

Author

Song, Yifei, Jalali, Jalal, Lemic, Filip, Devroye, Natasha, and Famaey, Jeroen

Subjects

Electrical Engineering and Systems Science - Signal Processing

Abstract

This paper focuses on enhancing the energy efficiency (EE) of a cooperative network featuring a `miniature' unmanned aerial vehicle (UAV) that operates at terahertz (THz) frequencies, utilizing holographic surfaces to improve the network's performance. Unlike traditional reconfigurable intelligent surfaces (RIS) that are typically used as passive relays to adjust signal reflections, this work introduces a novel concept: Energy harvesting (EH) using reconfigurable holographic surfaces (RHS) mounted on the miniature UAV. In this system, a source node facilitates the simultaneous reception of information and energy signals by the UAV, with the harvested energy from the RHS being used by the UAV to transmit data to a specific destination. The EE optimization involves adjusting non-orthogonal multiple access (NOMA) power coefficients and the UAV's flight path, considering the peculiarities of the THz channel. The optimization problem is solved in two steps. Initially, the trajectory is refined using a successive convex approximation (SCA) method, followed by the adjustment of NOMA power coefficients through a quadratic transform technique. The effectiveness of the proposed algorithm is demonstrated through simulations, showing superior results when compared to baseline methods.

Published

2024

5. Tailoring Graph Neural Network-based Flow-guided Localization to Individual Bloodstreams and Activities

Author

Galván, Pablo, Lemic, Filip, Bartra, Gerard Calvo, Abadal, Sergi, and Pérez, Xavier Costa

Subjects

Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Computer Science - Emerging Technologies, Computer Science - Networking and Internet Architecture

Abstract

Flow-guided localization using in-body nanodevices in the bloodstream is expected to be beneficial for early disease detection, continuous monitoring of biological conditions, and targeted treatment. The nanodevices face size and power constraints that produce erroneous raw data for localization purposes. On-body anchors receive this data, and use it to derive the locations of diagnostic events of interest. Different Machine Learning (ML) approaches have been recently proposed for this task, yet they are currently restricted to a reference bloodstream of a resting patient. As such, they are unable to deal with the physical diversity of patients' bloodstreams and cannot provide continuous monitoring due to changes in individual patient's activities. Toward addressing these issues for the current State-of-the-Art (SotA) flow-guided localization approach based on Graph Neural Networks (GNNs), we propose a pipeline for GNN adaptation based on individual physiological indicators including height, weight, and heart rate. Our results indicate that the proposed adaptions are beneficial in reconciling the individual differences between bloodstreams and activities., Comment: 7 pages, 9 figures, 2 tables, 16 references, accepted at ACM NanoCom'25

Published

2024

6. Multi-Gigabit Interactive Extended Reality over Millimeter-Wave: An End-to-End System Approach

Author

Struye, Jakob, Lemic, Filip, and Famaey, Jeroen

Subjects

Computer Science - Networking and Internet Architecture, Electrical Engineering and Systems Science - Signal Processing

Abstract

Achieving high-quality wireless interactive Extended Reality (XR) will require multi-gigabit throughput at extremely low latency. The Millimeter-Wave (mmWave) frequency bands, between 24 and 300GHz, can achieve such extreme performance. However, maintaining a consistently high Quality of Experience with highly mobile users is challenging, as mmWave communications are inherently directional. In this work, we present and evaluate an end-to-end approach to such a mmWave-based mobile XR system. We perform a highly realistic simulation of the system, incorporating accurate XR data traffic, detailed mmWave propagation models and actual user motion. We evaluate the impact of the beamforming strategy and frequency on the overall performance. In addition, we provide the first system-level evaluation of the CoVRage algorithm, a proactive and spatially aware user-side beamforming approach designed specifically for highly mobile XR environments., Comment: Published and presented at IEEE International Symposium on Personal, Indoor and Mobile Radio Communications (PIMRC) 2024

Published

2024

7. Analytical Modelling of Raw Data for Flow-Guided In-body Nanoscale Localization

Author

Pascual, Guillem, Lemic, Filip, Delgado, Carmen, and Costa-Perez, Xavier

Subjects

Computer Science - Emerging Technologies, Computer Science - Information Retrieval, Computer Science - Machine Learning, Computer Science - Networking and Internet Architecture, Electrical Engineering and Systems Science - Signal Processing

Abstract

Advancements in nanotechnology and material science are paving the way toward nanoscale devices that combine sensing, computing, data and energy storage, and wireless communication. In precision medicine, these nanodevices show promise for disease diagnostics, treatment, and monitoring from within the patients' bloodstreams. Assigning the location of a sensed biological event with the event itself, which is the main proposition of flow-guided in-body nanoscale localization, would be immensely beneficial from the perspective of precision medicine. The nanoscale nature of the nanodevices and the challenging environment that the bloodstream represents, result in current flow-guided localization approaches being constrained in their communication and energy-related capabilities. The communication and energy constraints of the nanodevices result in different features of raw data for flow-guided localization, in turn affecting its performance. An analytical modeling of the effects of imperfect communication and constrained energy causing intermittent operation of the nanodevices on the raw data produced by the nanodevices would be beneficial. Hence, we propose an analytical model of raw data for flow-guided localization, where the raw data is modeled as a function of communication and energy-related capabilities of the nanodevice. We evaluate the model by comparing its output with the one obtained through the utilization of a simulator for objective evaluation of flow-guided localization, featuring comparably higher level of realism. Our results across a number of scenarios and heterogeneous performance metrics indicate high similarity between the model and simulator-generated raw datasets., Comment: 6 pages, 7 figures, 4 tables, 16 references. arXiv admin note: substantial text overlap with arXiv:2307.05551

Published

2023

8. Toward Energy Efficient Multiuser IRS-Assisted URLLC Systems: A Novel Rank Relaxation Method

Author

Jalali, Jalal, Lemic, Filip, Tabassum, Hina, Berkvens, Rafael, and Famaey, Jeroen

Subjects

Electrical Engineering and Systems Science - Signal Processing

Abstract

This paper proposes an energy efficient resource allocation design algorithm for an intelligent reflecting surface (IRS)-assisted downlink ultra-reliable low-latency communication (URLLC) network. This setup features a multi-antenna base station (BS) transmitting data traffic to a group of URLLC users with short packet lengths. We maximize the total network's energy efficiency (EE) through the optimization of active beamformers at the BS and passive beamformers (a.k.a. phase shifts) at the IRS. The main non-convex problem is divided into two sub-problems. An alternating optimization (AO) approach is then used to solve the problem. Through the use of the successive convex approximation (SCA) with a novel iterative rank relaxation method, we construct a concave-convex objective function for each sub-problem. The first sub-problem is a fractional program that is solved using the Dinkelbach method and a penalty-based approach. The second sub-problem is then solved based on semi-definite programming (SDP) and the penalty-based approach. The iterative solution gradually approaches the rank-one for both the active beamforming and unit modulus IRS phase-shift sub-problems. Our results demonstrate the efficacy of the proposed solution compared to existing benchmarks.

Published

2023

9. Graph Neural Networks as an Enabler of Terahertz-based Flow-guided Nanoscale Localization over Highly Erroneous Raw Data

Author

Bartra, Gerard Calvo, Lemic, Filip, Pascual, Guillem, Rodas, Aina Pérez, Struye, Jakob, Delgado, Carmen, and Pérez, Xavier Costa

Subjects

Computer Science - Machine Learning, Computer Science - Emerging Technologies, Computer Science - Networking and Internet Architecture

Abstract

Contemporary research advances in nanotechnology and material science are rooted in the emergence of nanodevices as a versatile tool that harmonizes sensing, computing, wireless communication, data storage, and energy harvesting. These devices offer novel pathways for disease diagnostics, treatment, and monitoring within the bloodstreams. Ensuring precise localization of events of diagnostic interest, which underpins the concept of flow-guided in-body nanoscale localization, would provide an added diagnostic value to the detected events. Raw data generated by the nanodevices is pivotal for this localization and consist of an event detection indicator and the time elapsed since the last passage of a nanodevice through the heart. The energy constraints of the nanodevices lead to intermittent operation and unreliable communication, intrinsically affecting this data. This posits a need for comprehensively modelling the features of this data. These imperfections also have profound implications for the viability of existing flow-guided localization approaches, which are ill-prepared to address the intricacies of the environment. Our first contribution lies in an analytical model of raw data for flow-guided localization, dissecting how communication and energy capabilities influence the nanodevices' data output. This model acts as a vital bridge, reconciling idealized assumptions with practical challenges of flow-guided localization. Toward addressing these practical challenges, we also present an integration of Graph Neural Networks (GNNs) into the flow-guided localization paradigm. GNNs excel in capturing complex dynamic interactions inherent to the localization of events sensed by the nanodevices. Our results highlight the potential of GNNs not only to enhance localization accuracy but also extend coverage to encompass the entire bloodstream., Comment: 16 pages, 16 figures, 6 tables, 45 references

Published

2023

10. Insights from the Design Space Exploration of Flow-Guided Nanoscale Localization

Author

Lemic, Filip, Bartra, Gerard Calvo, López, Arnau Brosa, Gómez, Jorge Torres, Struye, Jakob, Dressler, Falko, Abadal, Sergi, and Perez, Xavier Costa

Subjects

Computer Science - Networking and Internet Architecture, Computer Science - Machine Learning, Electrical Engineering and Systems Science - Signal Processing

Abstract

Nanodevices with Terahertz (THz)-based wireless communication capabilities are providing a primer for flow-guided localization within the human bloodstreams. Such localization is allowing for assigning the locations of sensed events with the events themselves, providing benefits along the lines of early and precise diagnostics, and reduced costs and invasiveness. Flow-guided localization is still in a rudimentary phase, with only a handful of works targeting the problem. Nonetheless, the performance assessments of the proposed solutions are already carried out in a non-standardized way, usually along a single performance metric, and ignoring various aspects that are relevant at such a scale (e.g., nanodevices' limited energy) and for such a challenging environment (e.g., extreme attenuation of in-body THz propagation). As such, these assessments feature low levels of realism and cannot be compared in an objective way. Toward addressing this issue, we account for the environmental and scale-related peculiarities of the scenario and assess the performance of two state-of-the-art flow-guided localization approaches along a set of heterogeneous performance metrics such as the accuracy and reliability of localization., Comment: 6 pages, 4 figures, 2 tables, 14 references, accepted at ACM NanoCom'24

Published

2023

11. Predictive Context-Awareness for Full-Immersive Multiuser Virtual Reality with Redirected Walking

Author

Lemic, Filip, Struye, Jakob, Van Onsem, Thomas, Famaey, Jeroen, and Perez, Xavier Costa

Subjects

Computer Science - Networking and Internet Architecture, Computer Science - Machine Learning

Abstract

The advancement of Virtual Reality (VR) technology is focused on improving its immersiveness, supporting multiuser Virtual Experiences (VEs), and enabling users to move freely within their VEs while remaining confined to specialized VR setups through Redirected Walking (RDW). To meet their extreme data-rate and latency requirements, future VR systems will require supporting wireless networking infrastructures operating in millimeter Wave (mmWave) frequencies that leverage highly directional communication in both transmission and reception through beamforming and beamsteering. We propose the use of predictive context-awareness to optimize transmitter and receiver-side beamforming and beamsteering. By predicting users' short-term lateral movements in multiuser VR setups with Redirected Walking (RDW), transmitter-side beamforming and beamsteering can be optimized through Line-of-Sight (LoS) "tracking" in the users' directions. At the same time, predictions of short-term orientational movements can be utilized for receiver-side beamforming for coverage flexibility enhancements. We target two open problems in predicting these two context information instances: i) predicting lateral movements in multiuser VR settings with RDW, and ii) generating synthetic head rotation datasets for training orientational movements predictors. Our experimental results demonstrate that Long Short-Term Memory (LSTM) networks feature promising accuracy in predicting lateral movements, and context-awareness stemming from VEs further enhances this accuracy. Additionally, we show that a TimeGAN-based approach for orientational data generation can create synthetic samples that closely match experimentally obtained ones., Comment: 7 pages, 6 figures

Published

2023

12. Toward Standardized Performance Evaluation of Flow-guided Nanoscale Localization

Author

López, Arnau Brosa, Lemic, Filip, Struye, Jakob, Gómez, Jorge Torres, Municio, Esteban, Delgado, Carmen, Bartra, Gerard Calvo, Dressler, Falko, Alarcón, Eduard, Famaey, Jeroen, Abadal, Sergi, and Pérez, Xavier Costa

Subjects

Computer Science - Networking and Internet Architecture, Computer Science - Emerging Technologies, Electrical Engineering and Systems Science - Systems and Control

Abstract

Nanoscale devices with Terahertz (THz) communication capabilities are envisioned to be deployed within human bloodstreams. Such devices will enable fine-grained sensing-based applications for detecting early indications (i.e., biomarkers) of various health conditions, as well as actuation-based ones such as targeted drug delivery. Associating the locations of such events with the events themselves would provide an additional utility for precision diagnostics and treatment. This vision yielded a new class of in-body localization coined under the term "flow-guided nanoscale localization". Such localization can be piggybacked on THz communication for detecting body regions in which biological events were observed based on the duration of one circulation of a nanodevice in the bloodstream. From a decades-long research on objective benchmarking of "traditional" indoor localization, as well as its eventual standardization (e.g., ISO/IEC 18305:2016), we know that in early stages the reported performance results were often incomplete (e.g., targeting a subset of relevant performance metrics), carrying out benchmarking experiments in different evaluation environments and scenarios, and utilizing inconsistent performance indicators. To avoid such a "lock-in" in flow-guided localization, in this paper we propose a workflow for standardized performance evaluation of such localization. The workflow is implemented in the form of an open-source simulation framework that is able to jointly account for the mobility of the nanodevices, in-body THz communication between with on-body anchors, and energy-related and other technological constraints (e.g., pulse-based modulation) at the nanodevice level. Accounting for these constraints, the framework is able to generate the raw data that can be streamlined into different flow-guided localization solutions for generating standardized performance benchmarks., Comment: 10 pages, 9 figures, 34 references, code available at: https://bitbucket.org/filip_lemic/flow-guided-localization-in-ns3/src/sequential/

Published

2023

13. Multi-channel Medium Access Control Protocols for Wireless Networks within Computing Packages

Author

Ollé, Bernat, Talarn, Pau, Cabellos-Aparicio, Albert, Lemic, Filip, Alarcón, Eduard, and Abadal, Sergi

Subjects

Computer Science - Emerging Technologies

Abstract

Wireless communications at the chip scale emerge as a interesting complement to traditional wire-based approaches thanks to their low latency, inherent broadcast nature, and capacity to bypass pin constraints. However, as current trends push towards massive and bandwidth-hungry processor architectures, there is a need for wireless chip-scale networks that exploit and share as many channels as possible. In this context, this work addresses the issue of channel sharing by exploring the design space of multi-channel Medium Access Control (MAC) protocols for chip-scale networks. Distinct channel assignment strategies for both random access and token passing are presented and evaluated under realistic traffic patterns. It is shown that, even with the improvements enabled by the multiple channels, both protocols maintain their intrinsic advantages and disadvantages., Comment: Accepted for lecture presentation at IEEE ISCAS 2023

Published

2023

14. CoVRage: Millimeter-Wave Beamforming for Mobile Interactive Virtual Reality

Author

Struye, Jakob, Lemic, Filip, and Famaey, Jeroen

Subjects

Computer Science - Networking and Internet Architecture, Electrical Engineering and Systems Science - Signal Processing

Abstract

Contemporary Virtual Reality (VR) setups often include an external source delivering content to a Head-Mounted Display (HMD). "Cutting the wire" in such setups and going truly wireless will require a wireless network capable of delivering enormous amounts of video data at an extremely low latency. The massive bandwidth of higher frequencies, such as the millimeter-wave (mmWave) band, can meet these requirements. Due to high attenuation and path loss in the mmWave frequencies, beamforming is essential. In wireless VR, where the antenna is integrated into the HMD, any head rotation also changes the antenna's orientation. As such, beamforming must adapt, in real-time, to the user's head rotations. An HMD's built-in sensors providing accurate orientation estimates may facilitate such rapid beamforming. In this work, we present coVRage, a receive-side beamforming solution tailored for VR HMDs. Using built-in orientation prediction present on modern HMDs, the algorithm estimates how the Angle of Arrival (AoA) at the HMD will change in the near future, and covers this AoA trajectory with a dynamically shaped oblong beam, synthesized using sub-arrays. We show that this solution can cover these trajectories with consistently high gain, even in light of temporally or spatially inaccurate orientational data., Comment: Published in IEEE Transactions on Wireless Communications

Published

2022

15. Short-Term Trajectory Prediction for Full-Immersive Multiuser Virtual Reality with Redirected Walking

Author

Lemic, Filip, Struye, Jakob, and Famaey, Jeroen

Subjects

Computer Science - Networking and Internet Architecture, Computer Science - Machine Learning, Computer Science - Multimedia

Abstract

Full-immersive multiuser Virtual Reality (VR) envisions supporting unconstrained mobility of the users in the virtual worlds, while at the same time constraining their physical movements inside VR setups through redirected walking. For enabling delivery of high data rate video content in real-time, the supporting wireless networks will leverage highly directional communication links that will "track" the users for maintaining the Line-of-Sight (LoS) connectivity. Recurrent Neural Networks (RNNs) and in particular Long Short-Term Memory (LSTM) networks have historically presented themselves as a suitable candidate for near-term movement trajectory prediction for natural human mobility, and have also recently been shown as applicable in predicting VR users' mobility under the constraints of redirected walking. In this work, we extend these initial findings by showing that Gated Recurrent Unit (GRU) networks, another candidate from the RNN family, generally outperform the traditionally utilized LSTMs. Second, we show that context from a virtual world can enhance the accuracy of the prediction if used as an additional input feature in comparison to the more traditional utilization of solely the historical physical movements of the VR users. Finally, we show that the prediction system trained on a static number of coexisting VR users be scaled to a multi-user system without significant accuracy degradation., Comment: 7 pages, 9 figures, 2 tables

Published

2022

16. Intelligent Reflective Surface vs. Mobile Relay-supported NLoS Avoidance in Indoor mmWave Networks

Author

Madrid, Maria Bustamante, Famaey, Jeroen, and Lemic, Filip

Subjects

Computer Science - Networking and Internet Architecture, Computer Science - Emerging Technologies, Electrical Engineering and Systems Science - Signal Processing

Abstract

The 6th generation of wireless communication (6G) is envisioned to give rise to various technologies for improving the end-to-end communication performance, where the communication is envisioned to utilize wireless signals in the millimeter wave (mmWave) frequencies and above. Among others, these technologies comprise Intelligent Reflective Surfaces (IRSs) and Mobile Relays (MRs), whose envisaged roles include mitigating the negative effects of Non-Line-of-Sight (NLoS) connectivity, in particular at mmWave and higher frequencies. The core idea behind these technologies is to use cooperative networking where the source sends a signal to a repeater, in this case the IRS or the MR, which is upon reception forwarded to the destination. When comparing the two technologies, it is important to realize that the IRSs are primarily envisioned to be static entities attached to various objects in the environment such as walls and furniture. In contrast, the MRs will feature a higher degree of freedom, as they will be able to position themselves seamlessly in the environment. Based on the above assumptions, we derive an approach for determining the optimal position of the IRS and MR in indoor environments, i.e., the one that maximizes the end-to-end link quality between the source and the destination. We follow by capturing the communication quality indicators for both IRS- and MR-supported NLoS avoidance in indoor mmWave communication in a number of scenarios. Our results show that, from the end-to-end link quality perspective, the MRs generally outperform the IRSs, suggesting their utilization potential for throughput-optimized NLoS avoidance scenarios., Comment: 6 pages, 5 figures

Published

2022

17. Small UAVs-supported Autonomous Generation of Fine-grained 3D Indoor Radio Environmental Maps

Author

Mendes, Ken, Lemic, Filip, and Famaey, Jeroen

Subjects

Computer Science - Networking and Internet Architecture, Computer Science - Robotics, Electrical Engineering and Systems Science - Systems and Control

Abstract

Radio Environmental Maps (REMs) are a powerful tool for enhancing the performance of various communication and networked agents. However, generating REMs is a laborious undertaking, especially in complex 3-Dimensional (3D) environments, such as indoors. To address this issue, we propose a system for autonomous generation of fine-grained REMs of indoor 3D spaces. In the system, multiple small indoor Unmanned Aerial Vehicles (UAVs) are sequentially used for 3D sampling of signal quality indicators. The collected readings are streamlined to a Machine Learning (ML) system for its training and, once trained, the system is able to predict the signal quality at unknown 3D locations. The system enables automated and autonomous REM generation, and can be straightforwardly deployed in new environments. In addition, the system supports REM sampling without self-interference and is technology-agnostic, as long as the REM-sampling receivers features suitable sizes and weights to be carried by the UAVs. In the demonstration, we instantiate the system design using two UAVs and show its capability of visiting 72 waypoints and gathering thousands of Wi-Fi data samples. Our results also include an instantiation of the ML system for predicting the Received Signal Strength (RSS) of known Wi-Fi Access Points (APs) at locations not visited by the UAVs.

Published

2021

18. Sensing Integrated DFT-Spread OFDM Waveform and Deep Learning-powered Receiver Design for Terahertz Integrated Sensing and Communication Systems

Author

Wu, Yongzhi, Lemic, Filip, Han, Chong, and Chen, Zhi

Subjects

Electrical Engineering and Systems Science - Signal Processing

Abstract

Terahertz (THz) communications are envisioned as a key technology of next-generation wireless systems due to its ultra-broad bandwidth. One step forward, THz integrated sensing and communication (ISAC) system can realize both unprecedented data rates and millimeter-level accurate sensing. However, THz ISAC meets stringent challenges on waveform and receiver design to fully exploit the peculiarities of THz channel and transceivers. In this work, a sensing integrated discrete Fourier transform spread orthogonal frequency division multiplexing (SI-DFT-s-OFDM) system is proposed for THz ISAC, which can provide lower peak-to-average power ratio than OFDM and is adaptive to flexible delay spread of the THz channel. Without compromising communication capabilities, the proposed SI-DFT-s-OFDM realizes millimeter-level range estimation and decimeter-per-second-level velocity estimation accuracy. In addition, the bit error rate (BER) performance is improved by 5 dB gain at the $10^{-3}$ BER level compared with OFDM. At the receiver, a deep learning based ISAC receiver with two neural networks is developed to recover transmitted data and estimate target range and velocity, while mitigating the imperfections and non-linearities of THz systems. Extensive simulation results demonstrate that the proposed deep learning methods can realize mutually enhanced performance for communication and sensing, and is robust against Doppler effects, phase noise, and multi-target estimation.

Published

2021

19. Millimeter-Wave Beamforming with Continuous Coverage for Mobile Interactive Virtual Reality

Author

Struye, Jakob, Lemic, Filip, and Famaey, Jeroen

Subjects

Computer Science - Networking and Internet Architecture

Abstract

Contemporary Virtual Reality (VR) setups commonly consist of a Head-Mounted Display (HMD) tethered to a content-generating server. "Cutting the wire" in such setups and going truly wireless will require a wireless network capable of delivering enormous amounts of video data at an extremely low latency. Higher frequencies, such as the millimeter-wave (mmWave) band, can support these requirements. Due to high attenuation and path loss in the mmWave frequencies, beamforming is essential. For VR setups, beamforming must adapt in real-time to the user's head rotations, but can rely on the HMD's built-in sensors providing accurate orientation estimates. In this work, we present coVRage, a beamforming solution tailored for VR HMDs. Based on past and current head orientations, the HMD predicts how the Angle of Arrival (AoA) from the access point will change in the near future, and covers this AoA trajectory with a dynamically shaped beam, synthesized using sub-arrays. We show that this solution can cover such trajectories with consistently high gain, unlike regular single-beam solutions.

Published

2021

20. Toward Location-aware In-body Terahertz Nanonetworks with Energy Harvesting

Author

Lemic, Filip, Abadal, Sergi, Stevanovic, Aleksandar, Alarcón, Eduard, and Famaey, Jeroen

Subjects

Computer Science - Emerging Technologies, Computer Science - Networking and Internet Architecture

Abstract

Nanoscale wireless networks are expected to revolutionize a variety of domains, with significant advances conceivable in in-body healthcare. In healthcare, these nanonetworks will consist of energy-harvesting nanodevices passively flowing through the bloodstream, taking actions at certain locations, and communicating results to more powerful Body Area Network (BAN) nodes. Assuming such a setup and electromagnetic nanocommunication in the Terahertz (THz) frequencies, we propose a network architecture that can support fine-grained localization of the energy-harvesting in-body nanonodes, as well as their two-way communication with the outside world. The main novelties of our proposal lie in the introduction of location-aware and Wake-up Radio (WuR)-based wireless nanocommunication paradigms, as well as Software-Defined Metamaterials (SDMs), to THz-operating energy-harvesting in-body nanonetworks. We argue that, on a high level, the proposed architecture can handle (and actually benefits from) a large number of nanonodes, while simultaneously dealing with a short range of THz in-body propagation and highly constrained nanonodes., Comment: 7 pages, 5 figures, 1 table

Published

2021

21. Localization in Power-Constrained Terahertz-Operating Software-Defined Metamaterials

Author

Lemic, Filip, Abadal, Sergi, Han, Chong, Marquez-Barja, Johann, Alarcón, Eduard, and Famaey, Jeroen

Subjects

Electrical Engineering and Systems Science - Signal Processing, Computer Science - Emerging Technologies, Computer Science - Networking and Internet Architecture, Electrical Engineering and Systems Science - Systems and Control

Abstract

Software-Defined Metamaterials (SDMs) show a strong potential for advancing the engineered control of electromagnetic waves. As such, they are envisioned to enable a variety of exciting applications, among others in the domains of smart textiles, high-resolution structural monitoring, and sensing in challenging environments. Many of the applications envisage deformations of the SDM structures, such as their bending, stretching or rolling, which implies that the locations of metamaterial elements will be changing relative to one another. In this paper, we argue that if the metamaterial elements would be accurately localizable, this location information could potentially be utilized for enabling novel SDM applications, as well as for optimizing the control of the elements themselves. To enable their localization, we assume that these elements are controlled wirelessly through a Terahertz (THz)-operating nanonetwork. We consider the elements to be power-constrained, with their sole powering option being to harvest energy from different environmental sources. By means of simulation, we demonstrate sub-millimeter accuracy of the two-way Time of Flight (ToF)-based localization, as well as high availability of the service (i.e., consistently more than 80% of the time), which is a result of the low energy consumed in the localization process. Finally, we qualitatively characterize the latency of the proposed localization service, as well as outline several challenges and future research directions., Comment: 49 pages, 19 figures, 2 tables

Published

2020

22. Towards Ultra-Low-Latency mmWave Wi-Fi for Multi-User Interactive Virtual Reality

Author

Struye, Jakob, Lemic, Filip, and Famaey, Jeroen

Subjects

Computer Science - Networking and Internet Architecture

Abstract

The need for cables with high-fidelity Virtual Reality (VR) headsets remains a stumbling block on the path towards interactive multi-user VR. Due to strict latency constraints, designing fully wireless headsets is challenging, with the few commercially available solutions being expensive. These solutions use proprietary millimeter wave (mmWave) communications technologies, as extremely high frequencies are needed to meet the throughput and latency requirements of VR applications. In this work, we investigate whether such a system could be built using specification-compliant IEEE 802.11ad hardware, which would significantly reduce the cost of wireless mmWave VR solutions. We present a theoretical framework to calculate attainable live VR video bitrates for different IEEE 802.11ad channel access methods, using 1 or more head-mounted displays connected to a single Access Point (AP). Using the ns-3 simulator, we validate our theoretical framework, and demonstrate that a properly configured IEEE 802.11ad AP can support at least 8 headsets receiving a 4K video stream for each eye, with transmission latency under 1 millisecond., Comment: Published at 2020 IEEE Global Communications Conference (GLOBECOM)

Published

2020

23. Survey on Terahertz Nanocommunication and Networking: A Top-Down Perspective

Author

Lemic, Filip, Abadal, Sergi, Tavernier, Wouter, Stroobant, Pieter, Colle, Didier, Alarcón, Eduard, Marquez-Barja, Johann, and Famaey, Jeroen

Subjects

Computer Science - Networking and Internet Architecture, Computer Science - Emerging Technologies, Electrical Engineering and Systems Science - Systems and Control

Abstract

Recent developments in nanotechnology herald nanometer-sized devices expected to bring light to a number of groundbreaking applications. Communication with and among nanodevices will be needed for unlocking the full potential of such applications. As the traditional communication approaches cannot be directly applied in nanocommunication, several alternative paradigms have emerged. Among them, electromagnetic nanocommunication in the terahertz (THz) frequency band is particularly promising, mainly due to the breakthrough of novel materials such as graphene. For this reason, numerous research efforts are nowadays targeting THz band nanocommunication and consequently nanonetworking. As it is expected that these trends will continue in the future, we see it beneficial to summarize the current status in these research domains. In this survey, we therefore aim to provide an overview of the current THz nanocommunication and nanonetworking research. Specifically, we discuss the applications envisioned to be supported by nanonetworks operating in the THz band, together with the requirements such applications pose on the underlying nanonetworks. Subsequently, we provide an overview of the current contributions on the different layers of the protocol stack, as well as the available channel models and experimentation tools. As the final contribution, we identify a number of open research challenges and outline several potential future research directions., Comment: 37 pages, 11 figures, 7 tables

Published

2019

24. Localization in power-constrained Terahertz-operating software-defined metamaterials

Author

Lemic, Filip, Abadal, Sergi, Han, Chong, Marquez-Barja, Johann M., Alarcón, Eduard, and Famaey, Jeroen

Published

2021

25. ViFi: Virtual Fingerprinting WiFi-based Indoor Positioning via Multi-Wall Multi-Floor Propagation Model

Author

Caso, Giuseppe, De Nardis, Luca, Lemic, Filip, Handziski, Vlado, Wolisz, Adam, and Di Benedetto, Maria-Gabriella

Subjects

Computer Science - Networking and Internet Architecture

Abstract

Widespread adoption of indoor positioning systems based on WiFi fingerprinting is at present hindered by the large efforts required for measurements collection during the offline phase. Two approaches were recently proposed to address such issue: crowdsourcing and RSS radiomap prediction, based on either interpolation or propagation channel model fitting from a small set of measurements. RSS prediction promises better positioning accuracy when compared to crowdsourcing, but no systematic analysis of the impact of system parameters on positioning accuracy is available. This paper fills this gap by introducing ViFi, an indoor positioning system that relies on RSS prediction based on Multi-Wall Multi-Floor (MWMF) propagation model to generate a discrete RSS radiomap (virtual fingerprints). Extensive experimental results, obtained in multiple independent testbeds, show that ViFi outperforms virtual fingerprinting systems adopting simpler propagation models in terms of accuracy, and allows a sevenfold reduction in the number of measurements to be collected, while achieving the same accuracy of a traditional fingerprinting system deployed in the same environment. Finally, a set of guidelines for the implementation of ViFi in a generic environment, that saves the effort of collecting additional measurements for system testing and fine tuning, is proposed., Comment: Accepted to IEEE Transactions on Mobile Computing (March 2019)

Published

2016

26. A Mathematical Model for Fingerprinting-based Localization Algorithms

Author

Behboodi, Arash, Lemic, Filip, and Wolisz, Adam

Subjects

Computer Science - Information Theory, Computer Science - Emerging Technologies, 68P30, 94A15

Abstract

A general theoretical framework for Fingerprinting Localization Algorithms (FPS), given their popularity, can be utilized for their performance studies. In this work, after setting up an abstract model for FPS, it is shown that fingerprinting-based localization problem can be cast as a hypothesis testing (HT) problem and therefore various results in HT literature can be used to provide insights, guidelines and performance bounds for general FPS. This framework results in characterization of scaling limits of localization reliability in terms of number of measurements and other environmental parameters. It is suggested that Kullback-Leibler (KL) divergence between probability distributions of selected feature for fingerprinting at different locations encapsulates information about both accuracy and latency and can be used as a central performance metric for studying FPS. Although developed for an arbitrary fingerprint, the framework is particularly used for studying simple Received Signal Strength (RSS)- based algorithm. The effect of various parameters on the performance of fingerprinting algorithms is discussed, which includes path loss and fading characteristics, number of measurements at each point, number of anchors and their position, and placement of training points. Representative simulations and experimentation are used to verify validity of the theoretical frameworks in realistic setups.

Published

2016

27. Sensitivity of Flow-Guided Localization Accuracy on the Locations of Diagnostically Relevant Medical Events

Author

Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Abadal Cavallé, Sergi, Lemic, Filip, Pérez Rodas, Aina, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Abadal Cavallé, Sergi, Lemic, Filip, and Pérez Rodas, Aina

Abstract

En los últimos años, se han hecho descubrimientos en nanotecnología y materiales, que están dando paso a nanodispositivos con capacidades de detección, almacenamiento y procesamiento de datos. Se prevé que estos nanodispositivos naveguen por el torrente sanguíneo, con el fin de detectar eventos médicos de interés. La denominada "flow-guided localization" pretende asignar estos eventos a sus posiciones físicas, lo que permitiría un rápido diagnóstico y una reducción en costes e invasividad. Dado que este campo de investigación se encuentra aún en sus primeras fases, actualmente no hay un estándar común en las evaluaciones de este tipo de localización. Este hecho dificulta comparaciones objetivas entre este tipo de soluciones, lo que obstaculiza el avance en el ámbito. Como consecuencia, los investigadores se han centrado en el desarrollo de marcos estandarizados para evaluar los sistemas de "flow-guided localization". Sin embargo, aún no se ha investigado el impacto que la selección de los eventos tiene en su localización. Este estudio aborda esta laguna de conocimiento, analizando cómo la cantidad y la ubicación de los eventos a detectar afectan al rendimiento de los sistemas de localización. Para ello, se presenta una metodología de muestreo de puntos de evaluación, que garantiza estimaciones representativas de la precisión de estos algoritmos en todo el sistema cardiovascular. El conjunto de eventos obtenido reduce los recursos computacionales necesarios para las valoraciones, a la vez que mantiene la objetividad y fiabilidad de los resultados., Recent advances in the field of nanotechnology and novel materials are paving the way towards nanodevices that integrate sensing, storage and processing capabilities. These nanodevices are envisioned to navigate through the bloodstream, while sensing for medical events of interest. Flow-guided localization seeks to map these events to physical sites, resulting in early diagnosis while lowering costs and invasiveness. As the field is still in its early stages, existing evaluations of flow-guided localization are non-standardized, making objective comparisons challenging. To promote advancement in the field, researchers have focused on developing standardized frameworks for evaluating flow-guided localization systems. However, research into the impact of target event selection on localization is still lacking in the literature. This study addresses this knowledge gap by looking at how the number and placement of medical target events affect the performance of flow-guided localization systems. To address this, a methodology for sampling evaluation points is presented, ensuring representative assessments of performance indicators across the cardiovascular system. The derived subset of target events reduces the computational resources required for testing while maintaining objectivity and reliability of the results.

Published

2024

28. AI-based construction of 3D human face representations from 2D images for emotion recognition

Author

Universitat Politècnica de Catalunya. Departament de Ciències de la Computació, Abadal Cavallé, Sergi, Chica Calaf, Antonio, Lemic, Filip, Vilalta i Soler, Marcel, Universitat Politècnica de Catalunya. Departament de Ciències de la Computació, Abadal Cavallé, Sergi, Chica Calaf, Antonio, Lemic, Filip, and Vilalta i Soler, Marcel

Abstract

The commercialization of antennas that would operate in an extreme-frequency band is expected to be available in the following decade, which will provide a high- transmission rate integrated into small compact devices. The current restrictions the EU is posing on the machine learning techniques for facial emotion recognition force us to find ways to isolate the identity of a subject from the actual expression, making the approach of capturing through wireless signals suitable for that. The FER applications are well exploited in a wide range of areas, from the creation of avatars in computer graphics, to physiological analysis for diagnostic purposes in precision medicine. At the best of our knowledge, this work is focused on the analysis on the 2D RGB images (which despite the good results, there are still challenges to solve for wild type of data) leaving the geometry processing on point cloud/depth images scope still limited in terms of facial gesture detection. The work presented on this thesis aims to set the basis for the validation of the FER applications that utilize a point cloud or depth information as an input, by an- alyzing the current state-of-the-art from among different areas like depth estimators, face reconstruction and 2D RGB image facial emotion recognition, giving a common knowledge and presenting results across these to tackle this goal.

Published

2024

29. Graph Neural Networks as an Enabler of Terahertz-based Flow-guided Nanoscale Localization over Highly Erroneous Raw Data

Author

Bartra, Gerard Calvo, primary, Lemic, Filip, additional, Pascual, Guillem, additional, Rodas, Aina Pérez, additional, Struye, Jakob, additional, Delgado, Carmen, additional, and Pérez, Xavier Costa, additional

Published

2024

30. Real-time Generation of 3-Dimensional Representations of Static Objects using Small Unmanned Aerial Vehicles

Author

Talarn, Pau, primary, Ollé, Bernat, additional, Lemic, Filip, additional, Abadal, Sergi, additional, and Costa-Perez, Xavier, additional

Published

2023

31. Predictive Context-Awareness for Full-Immersive Multiuser Virtual Reality with Redirected Walking

Author

Lemic, Filip, primary, Struye, Jakob, additional, Van Onsem, Thomas, additional, Famaey, Jeroen, additional, and Costa-Pérez, Xavier, additional

Published

2023

32. Graph Neural Networks as an Enabler of Terahertz-Based Flow-Guided Nanoscale Localization Over Highly Erroneous Raw Data

Author

Calvo Bartra, Gerard, Lemic, Filip, Pascual, Guillem, Perez Rodas, Aina, Struye, Jakob, Delgado, Carmen, and Costa Perez, Xavier

Abstract

Contemporary research advances in nanotechnology and material science are rooted in the emergence of nanodevices as a versatile tool that harmonizes sensing, computing, wireless communication, data storage, and energy harvesting. These devices hold promise in precision medicine, offering novel pathways for disease diagnostics, treatment, and monitoring within the bloodstreams. Ensuring precise localization of events of diagnostic interest, which underpins the concept of flow-guided in-body nanoscale localization, would intuitively provide an added diagnostic value to the detected events. Raw data generated by the nanodevices is pivotal for this localization and consist of an event detection indicator and the time elapsed since the last passage of a nanodevice through the heart. The communication and energy constraints of the nanodevices lead to intermittent operation and unreliable communication, intrinsically affecting this data. This posits a need for comprehensively modelling the features of this data. These imperfections also have profound implications for the viability of existing flow-guided localization approaches, which are ill-prepared to address the intricacies of the environment. Our first contribution lies in an analytical model of raw data for flow-guided localization, dissecting how communication and energy capabilities influence the nanodevices’ data output. This model acts as a vital bridge, reconciling idealized assumptions with practical challenges of flow-guided localization. Toward addressing these practical challenges, we also present an integration of Graph Neural Networks (GNNs) into the flow-guided localization paradigm. GNNs, reinforced by the adaptability and resilience of Heterogeneous Graph Transformers (HGTs), excel in capturing complex dynamic interactions inherent to the localization of events sensed by the nanodevices. Our results highlight the potential of GNNs not only to enhance localization accuracy but also extend coverage to encompass the entire bloodstream.

Published

2024

33. Real-time generation of 3-dimensional representations of static objects using small unmanned aerial vehicles

Author

Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. IDEAI-UPC - Intelligent Data sciEnce and Artificial Intelligence Research Group, Talarn Bell-lloch, Pau, Ollé Ferrayuoli, Bernat, Lemic, Filip, Abadal Cavallé, Sergi, Costa Pérez, Xavier, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. IDEAI-UPC - Intelligent Data sciEnce and Artificial Intelligence Research Group, Talarn Bell-lloch, Pau, Ollé Ferrayuoli, Bernat, Lemic, Filip, Abadal Cavallé, Sergi, and Costa Pérez, Xavier

Abstract

Recent advances in robotics and nanotechnology resulted in a set of miniaturized Unmanned Aerial Vehicles (UAVs). Such small UAVs are envisioned to operate in hard-to-reach areas for enabling applications such as structural monitoring or content capturing. Towards showcasing this vision, we demonstrate a small UAV-supported setup for real-time autonomous generation of 3-Dimensional (3D) representations of static objects. In the setup, a small UAV (i.e., CrazyFlie 2.1) is envisioned to visit a set of locations, acting as a carrier and power source of a camera sensor. At each location, the sensor is expected to take a picture of the object and report it to the station. The station implements a pipeline for 3D reconstruction based on the pictures taken by the UAV., This work was funded by the MCIN/AEI/10.13039/01100011033/ FEDER/EU HoloMit 2.0 (PID2021-126551OB-C21) and MCIN/AEI/ 10.13039/501100011033 TRAINER-A (PID2020-118011GB-C21)., Peer Reviewed, Postprint (author's final draft)

Published

2023

34. Multi-channel medium access control protocols for wireless networks within computing packages

Author

Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica, Universitat Politècnica de Catalunya. IDEAI-UPC - Intelligent Data sciEnce and Artificial Intelligence Research Group, Ollé Ferrayuoli, Bernat, Talarn Bell-lloch, Pau, Cabellos Aparicio, Alberto, Lemic, Filip, Alarcón Cot, Eduardo José, Abadal Cavallé, Sergi, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica, Universitat Politècnica de Catalunya. IDEAI-UPC - Intelligent Data sciEnce and Artificial Intelligence Research Group, Ollé Ferrayuoli, Bernat, Talarn Bell-lloch, Pau, Cabellos Aparicio, Alberto, Lemic, Filip, Alarcón Cot, Eduardo José, and Abadal Cavallé, Sergi

Abstract

Wireless communications at the chip scale emerge as a interesting complement to traditional wire-based approaches thanks to their low latency, inherent broadcast nature, and capacity to bypass pin constraints. However, as current trends push towards massive and bandwidth-hungry processor architectures, there is a need for wireless chip-scale networks that exploit and share as many channels as possible. In this context, this work addresses the issue of channel sharing by exploring the design space of multi-channel Medium Access Control (MAC) protocols for chip-scale networks. Distinct channel assignment strategies for both random access and token passing are presented and evaluated under realistic traffic patterns. It is shown that, even with the improvements enabled by the multiple channels, both protocols maintain their intrinsic advantages and disadvantages., This work is supported by the European Commission under H2020 grant WiPLASH (GA 863337) and HE grant WINC (GA 101042080)., Peer Reviewed, Postprint (author's final draft)

Published

2023

35. Early detection of diseases using nanorobots in the bloodstream

Author

Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Abadal Cavallé, Sergi, Lemic, Filip, Calvo Bartra, Gerard, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Abadal Cavallé, Sergi, Lemic, Filip, and Calvo Bartra, Gerard

Abstract

Els avenços en nanotecnologia i materials avançats anuncien una nova era per als dispositius a nano escala en medicina de precisió. Aquests dispositius, equipats amb capacitats integrades de detecció, computació, comunicació, emmagatzematge d'energia i de dades, estan dissenyats per travessar el sistema cardiovascular humà. A mesura que flueixen passivament i senten contínuament, detecten esdeveniments d'importància diagnòstica. La localització guiada per flux pot amplificar el potencial d'aquestes deteccions enllaçant cada esdeveniment amb la seva ubicació física. Abordant els reptes intrínsecs i recordant els dilemes tradicionals d'estandardització de la localització en interiors, introduïm un marc d'avaluació resistent per a aquesta tècnica de localització embrionària. El nostre enfocament gira al voltant d'un simulador de codi obert, que hem adaptat i posat en funcionament per facilitar una avaluació realista i sistemàtica de les solucions actuals de localització guiada per flux d'última generació. Aquest simulador no només serveix com a eina de generació de dades: proporciona una plataforma estandarditzada per entrenar models d'aprenentatge automàtic (ML), establint una base sòlida per a solucions de localització guiades per flux diverses i estandarditzades. El nostre treball aprofundeix en una avaluació exploratòria de dues tècniques de localització guiades per flux basades en ML, mostrant el seu rendiment a través de mètriques variades i revelant limitacions importants, especialment pel que fa a la precisió de la localització a tot el sistema cardiovascular. En resposta a aquests reptes identificats, oferim una nova solució de localització guiada per flux basada en xarxes neuronals de grafs (GNN), que demostra una millora del 50% en la precisió, i amb cobertura a tot el sistema cardiovascular. En resum, el nostre treball estableix les bases per a punts de referència estandarditzats en la localització a nano escala guiada per flux. Ofereix coneixements fonamen, Advancements in nanotechnology and advanced materials herald a new era for nanoscale devices in precision medicine. These devices, equipped with integrated sensing, computing, communication, data, and energy storage capabilities, are designed to traverse the human cardiovascular system. As they passively flow and continuously sense, they detect events of diagnostic significance. Flow-guided localization can amplify the potential of these detections by linking each event to its physical location. Addressing intrinsic challenges and recalling traditional indoor localization standardization dilemmas, we introduce a resilient evaluation framework for this embryonic localization technique. Our approach pivots around an open-source simulator, which we have adapted and operationalized to facilitate a realistic and systematic evaluation of the current state-of-the-art flow-guided localization solutions. This simulator does not merely serve as a data generation tool: it provides a standardized platform for training Machine Learning (ML) models, laying a solid foundation for diverse, standardized flow-guided localization solutions. Our work dives deep into an exploratory assessment of two ML-based flow-guided localization techniques, showcasing their performance across varied metrics and revealing significant limitations, especially regarding localization accuracy across the cardiovascular system. In response to these identified challenges, we proffer a novel flow-guided localization solution based on Graph Neural Networks (GNN), demonstrating a 50% improvement in accuracy and coverage across the cardiovascular system. In summation, our work lays the groundwork for standardized benchmarks in flow-guided nanoscale localization. It offers pivotal insights into optimizing GNN-driven localization solutions, thereby providing a dual contribution of evaluating existing solutions and proposing advanced alternatives.

Published

2023

36. Coarse-grained Localization of In-body Energy-harvesting Nanonodes

Author

Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Abadal Cavallé, Sergi, Lemic, Filip, Brosa López, Arnau, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Abadal Cavallé, Sergi, Lemic, Filip, and Brosa López, Arnau

Abstract

Dispositivos a escala nanométrica con capacidades de comunicación inalámbrica en Ter- ahertz (THz) aspiran a implementarse para aplicaciones de detección dentro del torrente sanguíneo humano. Estos dispositivos detectan biomarcadores, permiten la administración dirigida de medicamentos y mejoran el diagnóstico precoz. La introducción de la localización nanométrica guiada por flujo utiliza la comunicación basada en THz para establecer la comunicación entre nanonodos y anclas. Se espera que este enfoque localice con precisión las regiones donde ocurren los eventos mediante el tiempo de circulación del nanodispositivo en el torrente sanguíneo. Esto facilita la identificación precisa de biomarcadores de enfermedades, virus y bacterias, lo que permite una intervención dirigida y la detección temprana de diversas condiciones de salud. Para evitar los desafíos encontrados en la evaluación y estandarización de la localización tradicional, este trabajo presenta un flujo de trabajo para la evaluación del rendimiento estandarizado de la localización nanométrica guiada por flujo. El flujo de trabajo se implementa en forma de un simulador de código abierto, teniendo en cuenta la movilidad del nanodispositivo, la comunicación THz en el cuerpo con anclas externas y las restricciones relacionadas con la energía. El simulador puede generar datos que se pueden utilizar para optimizar diferentes soluciones de localización y establecer puntos de referencia de rendimiento estandarizados. La evaluación se realiza mediante una exploración del espacio de diseño. Los resultados indican que el flujo de trabajo propuesto y el simulador se pueden utilizar para capturar el rendimiento de los enfoques de localización guiados por flujo de manera que permita una comparación objetiva con otros enfoques, sentando así las bases para la evaluación estandarizada de soluciones futuras., Els dispositius a nanoescala amb capacitats de comunicació sense fils en Terahertz (THz) aspiren a implementar-se en aplicacions basades en detecció i actuació dins del torrent sanguini humà. Aquests dispositius detecten biomarcadors, permeten el lliurament precís de fàrmacs i proporcionen un diagnòstic precoç. La introducció de la localització a nanoescala guiada per flux utilitza la comunicació basada en THz per establir la comunicació entre nanonodes i ancoratges. Aquest enfocament aspira a localitzar amb precisió les regions on es produeixen els esdeveniments utilitzant el temps de circulació del nanodispositiu a cada una de les regions. Això permet la identificació precisa de biomarcadors de malalties, virus i bacteris, donant lloc a una intervenció dirigida i a la detecció precoç de diverses condicions de salut. Per evitar els inconvenients que sorgeixen en les primeres etapes d’investigació, aquest treball presenta un flux de treball per a l’avaluació estandarditzada del rendiment de la localització a nanoescala guiada per flux. El flux de treball s’implementa en forma d’un simulador de codi obert, tenint en compte la mobilitat del nanodispositiu, la comunicació THz dins del cos amb els ancoratges situats a la superfície del cos i les limitacions relacionades amb l’energia. El simulador és capaç de generar dades que després de ser processades, ens permeten obtenir una avaluació estandaritzada del sistema . L’avaluació es va realitzar en forma d’exploració espacial de disseny. Els resultats indiquen que el flux de treball proposat i el simulador es poden utilitzar per capturar el rendiment de la solució implementada d’una manera que permet la comparació objectiva amb altres enfocaments, servint d’aquesta manera com a base per a l’avaluació estandarditzada de futures solucions., Nanoscale devices with Terahertz (THz) wireless communication capabilities are envisioned for sensing and actuation-based applications within human bloodstreams. These devices detect biomarkers, enable targeted drug delivery, and improve precision diagnos- tics. The introduction of flow-guided nanoscale localization utilizes THz-based communication to establish communication between nanonodes and anchors. This approach is envisaged to accurately locate regions where events occur by using the nanodevice’s circulation duration in the bloodstream. This enables precise identification of disease biomarkers, viruses, and bacteria, facilitating targeted intervention and early detection of health conditions. To avoid the pitfalls encountered in benchmarking and standardizing traditional indoor localization, this work presents a workflow for standardized performance evaluation of flow-guided nanoscale localization. The workflow is implemented in the form of an open source simulator, considering nanodevice mobility, in-body THz communication with on- body anchors, and energy-related constraints. The simulator is able to generate raw data that can be used to streamline different flow-guided localization solutions and establish standardized performance benchmarks. The evaluation is performed in the form of a design space exploration. The results indicate that the proposed workflow and the simulator can be utilized for capturing the performance of flow-guided localization approaches in a way that allows objective comparison with other approaches serving as the foundation for standardized evaluation of future solutions.

Published

2023

37. Graph Neural Network-enabled Terahertz-based Flow-guided Nanoscale Localization

Author

Bartra, Gerard Calvo, Lemic, Filip, Abadal, Sergi, and Perez, Xavier Costa

Subjects

Computer Science - Networking and Internet Architecture, Networking and Internet Architecture (cs.NI), FOS: Computer and information sciences, Computer Science - Machine Learning, Emerging Technologies (cs.ET), Computer Science - Emerging Technologies, Machine Learning (cs.LG)

Abstract

Scientific advancements in nanotechnology and advanced materials are paving the way toward nanoscale devices for in-body precision medicine; comprising integrated sensing, computing, communication, data and energy storage capabilities. In the human cardiovascular system, such devices are envisioned to be passively flowing and continuously sensing for detecting events of diagnostic interest. The diagnostic value of detecting such events can be enhanced by assigning to them their physical locations (e.g., body region), which is the main proposition of flow-guided localization. Current flow-guided localization approaches suffer from low localization accuracy and they are by-design unable to localize events within the entire cardiovascular system. Toward addressing this issue, we propose the utilization of Graph Neural Networks (GNNs) for this purpose, and demonstrate localization accuracy and coverage enhancements of our proposal over the existing State of the Art (SotA) approaches. Based on our evaluation, we provide several design guidelines for GNN-enabled flow-guided localization., Comment: 6 pages, 5 figures, 1 table, 15 references. arXiv admin note: text overlap with arXiv:2305.18493

Published

2023

38. Toward Full-Immersive Multiuser Virtual Reality With Redirected Walking

Author

Van Onsem, Thomas, primary, Struye, Jakob, additional, Perez, Xavier Costa, additional, Famaey, Jeroen, additional, and Lemic, Filip, additional

Published

2023

39. Sensing Integrated DFT-Spread OFDM Waveform and Deep Learning-Powered Receiver Design for Terahertz Integrated Sensing and Communication Systems

Author

Wu, Yongzhi, primary, Lemic, Filip, additional, Han, Chong, additional, and Chen, Zhi, additional

Published

2023

40. Short-Term Trajectory Prediction for Full-Immersive Multiuser Virtual Reality with Redirected Walking

Author

Lemic, Filip, primary, Struye, Jakob, additional, and Famaey, Jeroen, additional

Published

2022

41. Intelligent Reflective Surface vs. Mobile Relay-supported NLoS Avoidance in Indoor mmWave Networks

Author

Madrid, Maria Bustamante, primary, Famaey, Jeroen, additional, and Lemic, Filip, additional

Published

2022

42. Toward Interactive Multi-User Extended Reality Using Millimeter-Wave Networking

Author

Struye, Jakob, Van Damme, Sam, Bhat, Nabeel Nisar, Troch, Arno, Van Liempd, Barend, Assasa, Hany, Lemic, Filip, Famaey, Jeroen, and Vega, Maria Torres

Abstract

Extended Reality (XR) enables a plethora of novel interactive shared experiences. Ideally, users are allowed to roam around freely, while audiovisual content is delivered wirelessly to their Head-Mounted Displays (HMDs). Therefore, truly immersive experiences will require massive amounts of data, in the range of tens of gigabits per second, to be delivered reliably at extremely low latencies. We identify Millimeter-Wave (mmWave) communications, at frequencies between 24 and 300 GHz, as a key enabler for such experiences. In this article, we show how the mmWave state of the art does not yet achieve sufficient performance, and identify several key active research directions expected to eventually pave the way for extremely-high-quality mmWave-enabled interactive multi-user XR.

Published

2024

43. Generating Realistic Synthetic Head Rotation Data for Extended Reality using Deep Learning

Author

Struye, Jakob, primary, Lemic, Filip, additional, and Famaey, Jeroen, additional

Published

2022

44. Opportunities and Challenges for Virtual Reality Streaming over Millimeter-Wave: An Experimental Analysis

Author

Struye, Jakob, primary, Ravuri, Hemanth Kumar, additional, Assasa, Hany, additional, Fiandrino, Claudio, additional, Lemic, Filip, additional, Widmer, Joerg, additional, Famaey, Jeroen, additional, and Vega, Maria Torres, additional

Published

2022

45. Toward location-aware in-body terahertz nanonetworks with energy harvesting

Author

Lemic, Filip, primary, Abadal, Sergi, additional, Stevanovic, Aleksandar, additional, Alarcón, Eduard, additional, and Famaey, Jeroen, additional

Published

2022

46. Location-Based Discovery and Network Handover Management for Heterogeneous IEEE 802.11ah IoT Applications

Author

Santi, Serena, primary, Lemic, Filip, additional, and Famaey, Jeroen, additional

Published

2022

47. Small UAVs-supported Autonomous Generation of Fine-grained 3D Indoor Radio Environmental Maps

Author

Mendes, Ken, primary, Lemic, Filip, additional, and Famaey, Jeroen, additional

Published

2022

48. Toward location-aware in-body terahertz nanonetworks with energy harvesting

Author

Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica, Universitat Politècnica de Catalunya. IDEAI-UPC - Intelligent Data sciEnce and Artificial Intelligence Research Group, Lemic, Filip, Abadal Cavallé, Sergi, Stevanovic, Aleksandar, Alarcón Cot, Eduardo José, Famaey, Jeroen, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica, Universitat Politècnica de Catalunya. IDEAI-UPC - Intelligent Data sciEnce and Artificial Intelligence Research Group, Lemic, Filip, Abadal Cavallé, Sergi, Stevanovic, Aleksandar, Alarcón Cot, Eduardo José, and Famaey, Jeroen

Abstract

Nanoscale wireless networks are expected to revolutionize a variety of domains, with significant advances conceivable in in-body healthcare. These nanonetworks will consist of energy-harvesting nanodevices passively flowing through the bloodstream, taking actions at certain locations, and communicating results to a more powerful Body Area Network (BAN). Assuming such a setup and electro-magnetic nanocommunication in the Terahertz (THz) frequencies, we propose a network architecture that can support fine-grained localization of the energy-harvesting in-body nanonodes, as well as their two-way communication with the outside world. The main novelties of our proposal lie in the utilization of location-aware and Wake-up Radio (WuR)-based wireless nanocommunication paradigms, as well as Software-Defined Metamaterials (SDMs), for supporting the envisioned functionalities in THz-operating energy-harvesting in-body nanonetworks. We argue that, on a high level, the proposed architecture can handle a large number of nanonodes, while simultaneously dealing with a short range of THz in-body propagation and highly constrained nanonodes., The author Filip Lemic was supported by the EU Marie Curie Actions Individual Fellowship project Scalable Localization-enabled In-body Terahertz Nanonetwork (SCaLeITN), grant nr. 893760., Peer Reviewed, Postprint (author's final draft)

Published

2022

49. CoVRage: Millimeter-Wave Beamforming for Mobile Interactive Virtual Reality

Author

Struye, Jakob, primary, Lemic, Filip, additional, and Famaey, Jeroen, additional

Published

2022

50. Nanorouter Awareness in Flow-Guided Nanocommunication Networks

Author

Asorey-Cacheda, Rafael, primary, Lemic, Filip, additional, Garcia-Sanchez, Antonio-Javier, additional, Abadal, Sergi, additional, Famaey, Jeroen, additional, and Garcia-Haro, Joan, additional

Published

2021