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1. Impact of Reducing Statistically Small Population Sampling on Threshold Detection in FBG Optical Sensing

Author

Gabriel Cibira, Ivan Glesk, Jozef Dubovan, and Daniel Benedikovič

Subjects
statistically small population sampling, two-sided sampling, one-sided sampling, threshold detection, fiber Bragg gratings, FBG sensing, Chemical technology, TP1-1185
Abstract

Many techniques have been studied for recovering information from shared media such as optical fiber that carries different types of communication, sensing, and data streaming. This article focuses on a simple method for retrieving the targeted information with the least necessary number of significant samples when using statistical population sampling. Here, the focus is on the statistical denoising and detection of the fiber Bragg grating (FBG) power spectra. The impact of the two-sided and one-sided sliding window technique is investigated. The size of the window is varied up to one-half of the symmetrical FBG power spectra bandwidth. Both, two- and one-sided small population sampling techniques were experimentally investigated. We found that the shorter sliding window delivered less processing latency, which would benefit real-time applications. The calculated detection thresholds were used for in-depth analysis of the data we obtained. It was found that the normality three-sigma rule does not need to be followed when a small population sampling is used. Experimental demonstrations and analyses also showed that novel denoising and statistical threshold detection do not depend on prior knowledge of the probability distribution functions that describe the FBG power spectra peaks and background noise. We have demonstrated that the detection thresholds’ adaptability strongly depends on the mean and standard deviation values of the small population sampling.

Published
2024
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2. High-Efficiency Metamaterial-Engineered Grating Couplers for Silicon Nitride Photonics

Author

William Fraser, Radovan Korček, Ivan Glesk, Jan Litvik, Jens H. Schmid, Pavel Cheben, Winnie N. Ye, and Daniel Benedikovic

Subjects
integrated photonics, silicon nitride, surface grating couplers, subwavelength grating metamaterials, amorphous silicon, fiber–chip connections, Chemistry, QD1-999
Abstract

Silicon nitride (Si3N4) is an ideal candidate for the development of low-loss photonic integrated circuits. However, efficient light coupling between standard optical fibers and Si3N4 chips remains a significant challenge. For vertical grating couplers, the lower index contrast yields a weak grating strength, which translates to long diffractive structures, limiting the coupling performance. In response to the rise of hybrid photonic platforms, the adoption of multi-layer grating arrangements has emerged as a promising strategy to enhance the performance of Si3N4 couplers. In this work, we present the design of high-efficiency surface grating couplers for the Si3N4 platform with an amorphous silicon (α-Si) overlay. The surface grating, fully formed in an α-Si waveguide layer, utilizes subwavelength grating (SWG)-engineered metamaterials, enabling simple realization through single-step patterning. This not only provides an extra degree of freedom for controlling the fiber–chip coupling but also facilitates portability to existing foundry fabrication processes. Using rigorous three-dimensional (3D) finite-difference time-domain (FDTD) simulations, a metamaterial-engineered grating coupler is designed with a coupling efficiency of −1.7 dB at an operating wavelength of 1.31 µm, with a 1 dB bandwidth of 31 nm. Our proposed design presents a novel approach to developing high-efficiency fiber–chip interfaces for the silicon nitride integration platform for a wide range of applications, including datacom and quantum photonics.

Published
2024
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3. Design, Optimization, and Experimental Evaluation of Slow Light Generated by π-Phase-Shifted Fiber Bragg Grating for Use in Sensing Applications

Author

Matúš Vaňko, Ivan Glesk, Jarmila Müllerová, Jozef Dubovan, and Milan Dado

Subjects
π-phase-shifted fiber Bragg grating, slow light generation, group delay, optical fiber sensors, Chemical technology, TP1-1185
Abstract

This paper describes design, theoretical analysis, and experimental evaluation of a π-Phase-Shifted Fiber Bragg Grating (π-PSFBG) inscribed in the standard telecom fiber for slow light generation. At first, the grating was designed for its use in the reflection mode with a central wavelength of 1552 nm and a pass band width of less than 100 pm. The impact of fabrication imperfections was experimentally investigated and compared to model predictions. The optical spectra obtained experimentally show that the spectral region used for slow light generation is narrower (less than 10 pm), thus allowing for too-low levels of slow light optical-output power. In the next step, the optimization of the grating design was conducted to account for fabrication errors, to improve the grating’s spectral behavior and its temporal performance, and to widen the spectral interval for slow light generation in the grating’s transmission mode. The targeted central wavelength was 1553 nm. The π-PSFBG was then commercially fabricated, and the achieved parameters were experimentally investigated. For the region of (1551–1554) nm, a 15-fold increase in the grating’s pass band width was achieved. We have shown that a pair of retarded optical pulses were generated. The measured group delay was found to be ~10.5 ps (compared to 19 ps predicted by the model). The π-PSFBG operating in its transmission mode has the potential to operate as tunable delay line for applications in RF photonics, ultra-fast signal processing, and optical communications, where tunable high precision delay lines are highly desirable. The π-PSFBG can be designed and used for the generation of variable group delays from tens to hundreds of ps, depending on application needs.

Published
2024
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4. Beyond 5G Fronthaul Based on FSO Using Spread Spectrum Codes and Graphene Modulators

Author

Daniel Neves, Anderson Sanches, Rafael Nobrega, Hichem Mrabet, Iyad Dayoub, Kohei Ohno, Shyqyri Haxha, Ivan Glesk, Antonio Jurado-Navas, and Thiago Raddo

Subjects
fronthaul, FSO, 5G, 6G, graphene, modulator, Chemical technology, TP1-1185
Abstract

High data rate coverage, security, and energy efficiency will play a key role in the continued performance scaling of next-generation mobile systems. Dense, small mobile cells based on a novel network architecture are part of the answer. Motivated by the recent mounting interest in free-space optical (FSO) technologies, this paper addresses a novel mobile fronthaul network architecture based on FSO, spread spectrum codes, and graphene modulators for the creation of dense small cells. The network uses an energy-efficient graphene modulator to send data bits to be coded with spread codes for achieving higher security before their transmission to remote units via high-speed FSO transmitters. Analytical results show the new fronthaul mobile network can accommodate up to 32 remote antennas under error-free transmissions with forward error correction. Furthermore, the modulator is optimized to provide maximum efficiency in terms of energy consumption per bit. The optimization procedure is carried out by optimizing both the amount of graphene used on the ring resonator and the modulator’s design. The optimized graphene modulator is used in the new fronthaul network and requires as low as 4.6 fJ/bit while enabling high-speed performance up to 42.6 GHz and remarkably using one-quarter of graphene only.

Published
2023
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5. 2-D Optical-CDMA Modulation With Hard-Limiting for Automotive Time-of-Flight LiDAR

Author

Feng-Wen Lo, Guu-Chang Yang, Wei-Yi Lin, Ivan Glesk, and Wing C. Kwong

Subjects
Automotive, code division multiple access, LiDAR, time-of-flight, Applied optics. Photonics, TA1501-1820, Optics. Light, QC350-467
Abstract

In this proof-of-principle paper, the application of 2-D optical code-division multiple-access (OCDMA) modulation to long-range automotive time-of-flight (ToF) light detection and ranging (LiDAR) is studied. The regulations and physical constraints that govern the design parameters are reviewed. Using 2-D carrier-hopping prime codes (CHPCs), the modulation model and a novel 2-D hard-limiting decoder are designed and validated with OptiSystem$^{\rm {TM}}$ simulations. Based on the design parameters, the 2-D CHPCs have six times as many distinct sequences (for sensor identification) as 1-D code sequences. Analytical and simulation studies show that the proposed 2-D OCDMA modulation model can eliminate the near-far (power) problem and support more LiDAR sensors with distinctive ToF tags, greater interference robustness for more simultaneous ToF measurements, and better performance than the 1-D counterparts. The simulation results show that the 2-D model can support four times as many simultaneous emitting sensors without false detections as the 1-D model. In summary, the 2-D OCDMA modulation has more benefits and is more cost efficient overall, even though it is more complex.

Published
2021
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6. On The Performance of The Effects of Temperature Variation in Ultrafast Incoherent Fiber-Optic CDMA Systems With SOA-Based Tunable Dispersion Compensator

Author

Che-Wei Chang, Guu-Chang Yang, Ivan Glesk, and Wing C. Kwong

Subjects
Code division multiple access, dispersion compensation, optical fiber communications, temperature variation, Applied optics. Photonics, TA1501-1820, Optics. Light, QC350-467
Abstract

Recent studies show that temperature variation in ultrafast incoherent fiber-optic code-division multiple-access (FO-CDMA) systems using picosecond multiwavelength codes is a realistic problem even though dispersion-compensating fiber is utilized. The phenomenon creates distortions in auto- and cross-correlation functions and then worsens system performance. A physical-layer mitigation approach has been reported by using a recently demonstrated semiconductor-optical-amplifier-based tunable dispersion compensator to fully recover the auto-correlation peaks. Applying the concept of “chip granularity” to account for the effects of temperature variation to the cross-correlation functions, this paper formulates a new performance-analytical model for such FO-CDMA systems. The model also supports adjustable quality-of-services through code weight control.

Published
2019
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7. Design of an Athermal Interferometer Based on Tailored Subwavelength Metamaterials for On-Chip Microspectrometry

Author

Umair A. Korai, Alaine H. Bermello, Michael J. Strain, Ivan Glesk, and Aitor V. Velasco

Subjects
Integrated optics, athermal design, spectroscopy, thermo-optic effects, silicon-on-insulator., Applied optics. Photonics, TA1501-1820, Optics. Light, QC350-467
Abstract

Temperature dependence is one of the main challenges of the silicon-on-insulator platform due to the large thermo-optic coefficient of its core material. In this work we propose a design of an all-passive athermal silicon-on-insulator Mach-Zehnder interferometer (MZI) based on the standard silicon material platform. The MZI's temperature compensation is achieved by optimizing the relative length of the wire and subwavelength grating arms and by tailoring the thermal response of the subwavelength structure. Simulations of the device performance showed that an overall temperature sensitivity of 7.5 pm/K could be achieved over a 100 nm spectral range near the 1550 nm region.

Published
2019
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8. An Improved Particle Swarm Algorithm for Multi-Objectives Based Optimization in MPLS/GMPLS Networks

Author

Mohsin Masood, Mohamed Mostafa Fouad, Rashid Kamal, Ivan Glesk, and Imran Ullah Khan

Subjects
Communication networks optimization, exploration problem, multi-objective constrained optimization, particle swarm optimization, swarm intelligence, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

Particle swarm optimization (PSO) is a swarm-based optimization technique capable of solving different categories of optimization problems. Nevertheless, PSO has a serious exploration issue that makes it a difficult choice for multi-objectives constrained optimization problems (MCOP). At the same time, Multi-Protocol Label Switched (MPLS) and its extended version Generalized MPLS, has become an emerging network technology for modern and diverse applications. Therefore, as per MPLS and Generalized MPLS MCOP needs, it is important to find the Pareto based optimal solutions that guarantee the optimal resource utilization without compromising the quality of services (QoS) within the networks. The paper proposes a novel version of PSO, which includes a modified version of the Elitist learning Strategy (ELS) in PSO that not only solves the existing exploration problem in PSO, but also produces optimal solutions with efficient convergence rates for different MPLS/ GMPLS network scales. The proposed approach has also been applied with two objective functions; the resource provisioning and the traffic load balancing costs. Our simulations and comparative study showed improved results of the proposed algorithm over the well-known optimization algorithms such as standard PSO, Adaptive PSO, Bat and Dolphin algorithm.

Published
2019
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9. WON-OCDMA System Based on MW-ZCC Codes for Applications in Optical Wireless Sensor Networks

Author

Saleh Seyedzadeh, Andrew Agapiou, Majid Moghaddasi, Milan Dado, and Ivan Glesk

Subjects
optical sensors, vibration sensing, quality of service differentiation, wireless optical networks, free space optics, multiwavelength laser, Chemical technology, TP1-1185
Abstract

The growing demand for extensive and reliable structural health monitoring resulted in the development of advanced optical sensing systems (OSS) that in conjunction with wireless optical networks (WON) are capable of extending the reach of optical sensing to places where fibre provision is not feasible. To support this effort, the paper proposes a new type of a variable weight code called multiweight zero cross-correlation (MW-ZCC) code for its application in wireless optical networks based optical code division multiple access (WON-OCDMA). The code provides improved quality of service (QoS) and better support for simultaneous transmission of video surveillance, comms and sensor data by reducing the impact of multiple access interference (MAI). The MW-ZCC code’s power of two code-weight properties provide enhanced support for the needed service differentiation provisioning. The performance of this novel code has been studied by simulations. This investigation revealed that for a minimum allowable bit error rate of 10−3, 10−9 and 10−12 when supporting triple-play services (sensing, datacomms and video surveillance, respectively), the proposed WON-OCDMA using MW-ZCC codes could support up to 32 simultaneous services over transmission distances up to 32 km in the presence of moderate atmospheric turbulence.

Published
2021
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10. Impact of Wind Gust on High-Speed Characteristics of Polarization Mode Dispersion in Optical Power Ground Wire Cables

Author

Jozef Dubovan, Jan Litvik, Daniel Benedikovic, Jarmila Mullerova, Ivan Glesk, Andrej Veselovsky, and Milan Dado

Subjects
optical fiber, polarization, differential group delay, principal state of polarization, eye diagram, sensing, Chemical technology, TP1-1185
Abstract

Polarization mode dispersion is recognized as a key factor limiting optical transmission systems, particularly those fiber links that run at bit rates beyond 10 Gbps. In-line test and characterization of polarization mode dispersion are thus of critical importance to evaluate the quality of installed optical fibers that are in use for high-speed signal traffics. However, polarization-based effects in optical fibers are stochastic and quite sensitive to a range of environmental changes, including optical cable movements. This, in turn, gives rise to undesired variations in light polarization that adversely impair the quality of the signal transmission in the link. In this work, we elaborate on experimental testing and theoretical analysis to asses changes of polarization mode dispersion in optical fibers that are caused by environmental variations, here wind gusts in particular. The study was performed on commercially harnessed optical fibers installed within optical power ground wire cables, taking into account different weather conditions. More specifically, we showed that changes caused by wind gusts significantly influence the differential group delay and the principal state of polarization in those optical fibers. For this, we experimentally measured a number of parameters to characterize light polarization properties. Measurements were carried out on C-band operated fiber-optic link formed by 111-km-long power ground wire cables and 88 spectral channels, with a test time step of 1 min during 12 consecutive days. Variations in differential group delay allowed for sensitive testing of environmental changes with measured maxims up to 10 ps under the worst wind conditions. Moreover, measured parameters were used in a numerical model to assess the quality of transmitted high-bit-rate optical signals as a function of wind conditions. The analysis revealed a negligible impact of wind on a 10 Gbps transmission, while substantial influence was noticed for higher bit rates up to 100 Gbps. These results show promises for efficient sensing of environmental changes and subsequent monitoring of the quality of recently used fiber-optic link infrastructures.

Published
2020
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11. A Practical Design and Implementation of a Low Cost Platform for Remote Monitoring of Lower Limb Health of Amputees in the Developing World

Author

Neha Mathur, Greig Paul, James Irvine, Mohamed Abuhelala, Arjan Buis, and Ivan Glesk

Subjects
Accelerometer, e-health, elastomer, extrapolation, gait, Gaussian processes for machine learning (GPML), Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

In many areas of the world accessing professional physicians “when needed/as needed” might not be always possible for a variety of reasons. Therefore, in such cases, a targeted e-Health solution to safeguard patient long-term health could be a meaningful approach. Today's modern healthcare technologies, often built around electronic and computer-based equipment, require an access to a reliable electricity supply. Many healthcare technologies and products also presume access to the high speed internet is available, making them unsuitable for use in areas where there is no fixed-line internet connectivity, access is slow, unreliable, and expensive, yet where the most benefit to patients may be gained. In this paper, a full mobile sensor platform is presented, based around readily-purchased consumer components, to facilitate a low cost and efficient means of monitoring the health of patients with prosthetic lower limbs. This platform is designed such that it can also be operated in a standalone mode, i.e., in the absence of internet connectivity, thereby making it suitable to the developing world. Also, to counter the challenge of power supply issues in e-Health monitoring, a self-contained rechargeable solution to the platform is proposed and demonstrated. The platform works with an Android mobile device, in order to allow for the capture of data from a wireless sensor unit, and to give the clinician access to results from the sensors. The results from the analysis, carried out within the platform's Raspberry Pi Zero, are demonstrated to be of use for remote monitoring. This is specifically targeted for monitoring the tissue health of lower limb amputees. The monitoring of residual limb temperature and gait can be a useful indicator of tissue viability in lower limb amputees especially those suffering from diabetes. We describe a route wherein non-invasive monitoring of tissue health is achievable using the Gaussian process technique. This knowledge will be useful in establishing biomarkers related to a possible deterioration in a patient's health or for assessing the impact of clinical interventions.

Published
2016
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12. Investigation of 2D-WH/TS OCDMA Code Stability in Systems with SOA-Based Device

Author

Mohamed Abuhelala, Umair A. Korai, Anderson L. Sanches, Wing C. Kwong, and Ivan Glesk

Subjects
optical code division multiple access, semiconductor optical amplifier, gain recovery time, code carriers redshift, bit error rate, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999
Abstract

This paper investigates for the first time how the implementation of semiconductor optical amplifier (SOA)-based devices in photonic networks can negatively impact the integrity of two-dimensional wavelength-hopping time-spreading (2D-WH/TS) optical code-division multiple access (OCDMA) codes based on multi-wavelength picosecond code carriers. It is demonstrated and confirmed by simulations that the influence of an SOA under driving currents of 50 mA to 250 mA causes a 0.08 to 0.8 nm multi-wavelength picosecond code carriers’ wavelength redshift. The results obtained are then used to calculate the degradation of OCDMA system performance in terms of the probability of error Pe and the decrease in the number of simultaneous users. It is shown that, when the SOA-induced 0.8 nm code carriers redshift becomes equal to the code carries wavelength channel spacing, the (8,53)-OCDMA system performs only as a (7,53)-OCDMA system, and the number of simultaneous users drops from 14 to 10 or 84 to 74 with the forward error correction (FEC) Pe of 10−9, respectively. The impact of the 0.8 nm redshift is then shown on a (4,53)-OCDMA system, where it causes a drop in the number of simultaneous users from 4 to 3 or 37 to 24 with the FEC Pe of 10−9, respectively.

Published
2020
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13. An integrated nonlinear optical loop mirror in silicon photonics for all-optical signal processing

Author

Zifei Wang, Ivan Glesk, and Lawrence R. Chen

Subjects
Applied optics. Photonics, TA1501-1820
Abstract

The nonlinear optical loop mirror (NOLM) has been studied for several decades and has attracted considerable attention for applications in high data rate optical communications and all-optical signal processing. The majority of NOLM research has focused on silica fiber-based implementations. While various fiber designs have been considered to increase the nonlinearity and manage dispersion, several meters to hundreds of meters of fiber are still required. On the other hand, there is increasing interest in developing photonic integrated circuits for realizing signal processing functions. In this paper, we realize the first-ever passive integrated NOLM in silicon photonics and demonstrate its application for all-optical signal processing. In particular, we show wavelength conversion of 10 Gb/s return-to-zero on-off keying (RZ-OOK) signals over a wavelength range of 30 nm with error-free operation and a power penalty of less than 2.5 dB, we achieve error-free nonreturn to zero (NRZ)-to-RZ modulation format conversion at 10 Gb/s also with a power penalty of less than 2.8 dB, and we obtain error-free all-optical time-division demultiplexing of a 40 Gb/s RZ-OOK data signal into its 10 Gb/s tributary channels with a maximum power penalty of 3.5 dB.

Published
2018
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14. Has Silicon Reached It's Limit?

Author

Alan John Charles Davidson, Ivan Glesk, and Adrianus Buis

Subjects
data centre network, electronic bottleneck, ocdma, optical interconnect, optical switching, scalability., Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

In light of the rapidly increasing demand for ultra-high speed data transmission, data centres are under pressure to provide ever increasing data transmission through their networks and at the same time improve the quality of data handling in terms of reduced latency, increased scalability and improved channel speed for users. However as data rates increase, present electronic switching technology using current data centre architecture is becoming increasingly difficult to scale despite improvements in data management. In this paper the tremendous bandwidth potential of optical fibre based networks will be explored alongside the issues of electronic scalability and switching speed. A resulting need for alternative optical solutions for all-optical signal processing systems will be discussed. With this in mind, progress in the form of a novel and highly scalable optical interconnect will be reviewed.

Published
2014
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15. Application of Semiconductor Optical Amplifier (SOA) in Managing Chirp of Optical Code Division Multiple Access (OCDMA) Code Carriers in Temperature Affected Fibre Link

Author

Md Shakil Ahmed and Ivan Glesk

Subjects
group velocity dispersion, chirp, optical code division multiple access auto-correlation, fibre propagation, chromatic dispersion, temperature induced dispersion, super-continuum generation, optical code division multiple access transmitter, optical code division multiple access receiver/decoder, semiconductor optical amplifier, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999
Abstract

Chromatic and temperature induced dispersion can both severely affect incoherent high data rate communications in optical fibre. This is certainly also true for incoherent optical code division multiple access (OCDMA) systems with multi-wavelength picosecond code carriers. Here, even a relatively small deviation from a fully dispersion compensated transmission link can strongly impact the overall system performance, the number of simultaneous users, and the system cardinality due to the recovered OCDMA auto-correlation being strongly distorted, time-skewed, and having its full width at half maximum (FWHM) value changed. It is therefore imperative to have a simple tunable means for controlling fibre chromatic or temperature induced dispersion with high sub-picosecond accuracy. To help address this issue, we have investigated experimentally and by simulations the use of a semiconductor optical amplifier (SOA) for its ability to control the chirp of the passing optical signal (OCDMA codes) and to exploit the SOA ability for dispersion management of a fibre link in an incoherent OCDMA system. Our investigation is done using a 19.5 km long fibre transmission link that is exposed to different temperatures (20 °C and 50 °C) using an environmental chamber. By placing the SOA on a transmission site and using it to manipulate the code carrier’s chirp via SOA bias adjustments, we have shown that this approach can successfully control the overall fibre link dispersion, and it can also mitigate the impact on the received OCDMA auto-correlation and its FWHM. The experimental data obtained are in a very good agreement with our simulation results.

Published
2018
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31. Dynamic Bandwidth Allocation for C-Band Shared FBG Sensing and Telecommunications

Author

Gabriel Cibira, Ivan Glesk, and Jozef Dubovan

Subjects
Computer Networks and Communications, Hardware and Architecture, TK, Signal Processing, Computer Science Applications, Information Systems
Abstract

The telecommunications data transfer in singlemode (SM) optical fiber (OF) of a passive optical network (PON) is managed by dynamic bandwidth allocation (DBA). In most internet of things (IoT) sensor network applications, both raw sensing signals and telecommunication data are transmitted in SM OFs, too. At the present time, this is not done in a shared SM OF. This paper presents a novel concept to share FBG sensing and telecommunication services (TS) in the optical C-band of the shared transmission. This concept is based on statistical detection and monitoring of fiber Bragg gratings (FBGs) sensing signals. The key steps of the proposed concept are FBG power spectral peaks statistical detection, monitoring of the FBGs dynamics and periodical estimation of TChs occupancy and availability. The proposed concept was demonstrated and validated using sensor network with a deployed group of FBG-based sensors, by implementing various static or dynamic approaches. By doing so, we achieved telecommunication channels (TChs) bandwidth availability approaching 80 %, compared to previously wasted bandwidth with availability at most 15.6 %. Experimental results showed that a DBA system with implemented dynamic TChs occupancy is a reliable way to share fiber bandwidth between both FBG sensing and TChs.

Published
2022

36. 2-D Optical-CDMA Modulation With Hard-Limiting for Automotive Time-of-Flight LiDAR

Author

Wing C. Kwong, Feng-Wen Lo, Ivan Glesk, Wei-Yi Lin, and Guu-Chang Yang

Subjects
LiDAR, Computer science, Code division multiple access, TK, Automotive, Ranging, QC350-467, Optics. Light, Interference (wave propagation), time-of-flight, Atomic and Molecular Physics, and Optics, Power (physics), code division multiple access, TA1501-1820, Lidar, Robustness (computer science), Modulation, Electronic engineering, Applied optics. Photonics, Electrical and Electronic Engineering, Decoding methods
Abstract

In this proof-of-principle paper, the application of 2-D optical code-division multiple-access (OCDMA) modulation to long-range automotive time-of-flight (ToF) light detection and ranging (LiDAR) is studied. The regulations and physical constraints that govern the design parameters are reviewed. Using 2-D carrier-hopping prime codes (CHPCs), the modulation model and a novel 2-D hard-limiting decoder are designed and validated with OptiSystem$^{\rm {TM}}$ simulations. Based on the design parameters, the 2-D CHPCs have six times as many distinct sequences (for sensor identification) as 1-D code sequences. Analytical and simulation studies show that the proposed 2-D OCDMA modulation model can eliminate the near-far (power) problem and support more LiDAR sensors with distinctive ToF tags, greater interference robustness for more simultaneous ToF measurements, and better performance than the 1-D counterparts. The simulation results show that the 2-D model can support four times as many simultaneous emitting sensors without false detections as the 1-D model. In summary, the 2-D OCDMA modulation has more benefits and is more cost efficient overall, even though it is more complex.

Published
2021

37. SNR-based dynamic statistical threshold detection of FBG spectral peaks

Author

Ivan Glesk and Gabriel Cibira

Abstract

This paper targets a dynamic statistical threshold detection algorithm of fiber Bragg grating (FBG) spectral peaks at the presence of changing Signal-to-Noise Ratio (SNR) in an optical fiber of a sensing application. The proposed post-demodulation SNR-based detection implements sliding window technique. Its detection threshold is adapted by the targeted probability of false alarms and by background noise statistics. The proposed detection algorithm is independent of FBG spectral peaks shapes and simple enough computationally to implement. It has been demonstrated and validated using sensor network with a deployed group of FBG-based sensors, by implementing simplified sliding window technique. When the adjacent FBG spectral peaks overlap partially, it provides a high degree of certainty in rejecting false FBG detection. The algorithm can be used for „spectral windowing“ or precise measurement of FBG spectral peaks parameters, especially in densely populated FBG sensor networks. This can lead to a significantly higher spectral bandwidth utilization in FBG sensing applications.

Published
2022

38. High-Speed Operation of Fiber-Optic Link Impaired by Wind Gusts

Author

Jozef Dubovan, Jan Litvik, Radovan Korcek, Daniel Benedikovic, Andrej Veselovsky, Ivan Glesk, Jarmila Mullerova, Milan Dado, and Jakab, Frantisek

Subjects
TK
Abstract

The fast signal transmission is critical long-haul communication systems. They represent the key advancements, shaping information-communication technologies. Fiber-optic transmission suffers from many degradation effects, and of particular concern are stochastic fiber impairments represented by polarization mode dispersion (PMD). The PMD is critical as it limits link operation at data rates higher than 10 Gbps. In this work, we report on experimental measurements and theoretical analysis characterization for PMD-based propagation effects in optical fibers influenced by wind gusts. The study was performed on fiber-optic link that runs through 111-km-long optical power ground wire cables. Measured maximum of DGD was up to 10 ps for a wind speed of 20 m/s. This wind condition, the optical link maintained a reliable operation only for established 10 Gbps, while considerable link degradation was seen for data rates of between 40 and 100 Gbps.

Published
2021

39. Power consumption analysis of an optical modulator based on different amounts of graphene

Author

Daniel Neves, Rafael Nobrega, Anderson Sanches, Antonio Jurado-Navas, Ivan Glesk, Shyqyri Haxha, and Thiago Raddo

Abstract

Energy-efficient devices will play a key role in the continued performance scaling of next-generation information and communications technology systems. Graphene has emerged as a key optoelectronic material with unique energy-like properties. But to the best of our knowledge, these advantages have not yet been fully exploited in optical modulators design. In this work, we design and analyze an optical modulator which is composed of two graphene layers and a ring resonator made with different amount of graphene. For performance analysis, the ring resonator’s amount of graphene is varied from 25 to 100% with four discrete steps. The critical coupling condition representing the OFF-state, and the 3-dB transmission level representing the ON-state of the device are obtained. Numerical results show this new optical modulator consumes as little energy as 4.6 fJ/bit whilst achieving a high-speed operation with a bandwidth up to 42.6 GHz when employing surprisingly only 25% of graphene. The 42.6 GHz modulator has a footprint as small as 22.1 µm2 with an active area of 1.68 µm2 only, the smallest active area to date. Alternatively, the optical modulator achieves up to ∼88.5 GHz at the expense of consuming 17.5 fJ/bit when using 100% of graphene. The proposed graphene-based modulator proved to be a compact, energy-efficient, high-speed device, useful for a myriad of applications including mobile fronthaul, telecom, and datacom.

Published
2022

40. Performance evaluation of high-capacity RTD transmitters for THz microscale applications

Author

Thiago R. Raddo, Anderson L. Sanches, Murilo Loiola, Rafael Vinicius Tayette da Nobrega, Luiz A. Neto, Ulysses Rondina Duarte, and Ivan Glesk

Subjects
Materials science, business.industry, Terahertz radiation, TK, Transmitter, Electrical engineering, Bit error rate, Metre, High capacity, business, Microscale chemistry, Power (physics)
Abstract

This work addresses a transmitter based on a RTD oscillator operating at 1.03 THz supporting output power and capacity as high as 0.84 mW and 0.15 Tb/s whilst achieving a 7- meter THz link reach.

Published
2021

41. Subwavelength Grating Waveguide Devices for Telecommunications Applications

Author

Junjia Wang, Ivan Glesk, Lawrence R. Chen, and Behnam Naghdi

Subjects
Waveguide filter, Silicon photonics, Materials science, business.industry, TK, Photonic integrated circuit, Optical communication, Physics::Optics, 02 engineering and technology, Grating, 01 natural sciences, Waveguide (optics), Atomic and Molecular Physics, and Optics, 010309 optics, Resonator, 020210 optoelectronics & photonics, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Optoelectronics, Electrical and Electronic Engineering, Photonics, business
Abstract

Subwavelength grating (SWG) waveguides in silicon-on-insulator are emerging as an enabling technology for implementing compact, high-performance photonic integrated devices and circuits for signal processing and sensing applications. We provide an overview of recent work on developing wavelength selective SWG waveguide filters based on Bragg gratings, ring resonators, and contra-directional couplers, as well as optical delay lines for applications in optical communications and microwave photonics. These components increase the SWG waveguide component toolbox and can be used to realize more complex photonic integrated circuits with enhanced or new functionality.

Published
2019

42. Monitoring of polarization-based effects in fiber-optic transmission link caused by environmental variations

Author

Jan Litvik, Milan Dado, Andrej Veselovsky, Daniel Benedikovic, Jarmila Müllerová, Ivan Glesk, and Jozef Dubovan

Subjects
QC350, Optical fiber, Transmission (telecommunications), law, Computer science, Polarization mode dispersion, Differential group delay, Optical link, Optical communication, Electronic engineering, Optical power, Context (language use), law.invention
Abstract

The fast transmission of signals around the globe is fundamental to the flow of information for our society. A long-haul transmission certainly represents one of the key advancements that shaped modern ways of communicating and offers a nearly instant access to any available data or a latest information. However, fiber-optic transmission typically suffers from a variety of physical impairments that degrade the signal quality, thus imposing limits on both, the achievable transmission capacity and data reach. Of particular concerns are stochastic fiber impairments, primarily represented by polarization mode dispersion (PMD). The PMD originates from a random birefringence caused by imperfect fiber circularity and other, both internal and external, effects, basically completely re-defining the light polarization state of output signal compared to its initial counterpart. The PMD is particularly critical as it restricts operation of fiber-optic links running at speeds higher than 10 Gbps. This, in turn, hinders fiber link re-adaption towards higher transmission bit rates in future, however. In this context, both in-line link monitoring and testing of PMD-based effects is of great importance within the recently used optical fiber links. However, polarization-based effects are also very sensitive to the environmental changes, substantially degrading transmitted optical signals and reducing link quality. In this work, we provide experimental characterization for PMD-based propagation effects in optical fibers influenced by wind gusts. The investigation was performed on commercially used fiber-optic link that runs through optical power ground wire cables. The 111-km-long optical link under study comprised installed optical fibers with available 88 channels. Here, we monitored environmental changes caused by wind conditions over several consecutive days with a 60 second time frame and sensed PMD impact on the link performance. Here, differential group delay (DGD) was chosen to be a key parameter, enabling for sensitive characterization of wind related link changes. Measured maximum DGD’s were 4 and 10 ps for wind speeds up to 5 and 20 m/s, respectively. In addition, experimentally measured data were used in numerical model to assess the optical link quality. For a low wind condition, we observed negligible quality degradation in the optical link, considering transmission bit rates of 10, 40, and 100 Gbps. Conversely, in case of strong wind condition, the optical link maintained a reliable operation only for established 10 Gbps, while significant link degradation was observed for bit rates of 40 and 100 Gbps. Our work shows promising way to effectively sense and monitor undesired environmental variations and their impact on polarization-based fiber link propagation effects, which in turn, can allow an instant link quality evaluation.

Published
2021

43. WON-OCDMA system based on MW-ZCC codes for applications in optical wireless sensor networks

Author

Andrew Agapiou, Milan Dado, Saleh Seyedzadeh, Majid Moghaddasi, and Ivan Glesk

Subjects
optical sensors, Computer science, TK, vibration sensing, 02 engineering and technology, multiwavelength laser, lcsh:Chemical technology, wireless optical networks, 01 natural sciences, Biochemistry, Article, Analytical Chemistry, 010309 optics, 0103 physical sciences, Wireless, lcsh:TP1-1185, Electrical and Electronic Engineering, Instrumentation, Code division multiple access, business.industry, Quality of service, 021001 nanoscience & nanotechnology, Atomic and Molecular Physics, and Optics, optical code division multiple access (OCDMA), Transmission (telecommunications), Bit error rate, Optical wireless, quality of service differentiation, free space optics, 0210 nano-technology, business, Wireless sensor network, Computer hardware, Free-space optical communication
Abstract

The growing demand for extensive and reliable structural health monitoring resulted in the development of advanced optical sensing systems (OSS) that in conjunction with wireless optical networks (WON) are capable of extending the reach of optical sensing to places where fibre provision is not feasible. To support this effort, the paper proposes a new type of a variable weight code called multiweight zero cross-correlation (MW-ZCC) code for its application in wireless optical networks based optical code division multiple access (WON-OCDMA). The code provides improved quality of service (QoS) and better support for simultaneous transmission of video surveillance, comms and sensor data by reducing the impact of multiple access interference (MAI). The MW-ZCC code’s power of two code-weight properties provide enhanced support for the needed service differentiation provisioning. The performance of this novel code has been studied by simulations. This investigation revealed that for a minimum allowable bit error rate of 10−3, 10−9 and 10−12 when supporting triple-play services (sensing, datacomms and video surveillance, respectively), the proposed WON-OCDMA using MW-ZCC codes could support up to 32 simultaneous services over transmission distances up to 32 km in the presence of moderate atmospheric turbulence.

Published
2021

44. A modified whale optimisation algorithm for enhancing the features selection process in machine learning

Author

Ezaz Uddin Syed, Dr Mohsin Masood, Mohamed Mostafa Fouad, and Ivan Glesk

Subjects
TK, QA76
Abstract

In recent years, when there is an abundance of large datasets in various fields, the importance of feature selection problem has become critical for researchers. The real world applications rely on large datasets, which implies that datasets have hundreds of instances and attributes. Finding a better way of optimum feature selection could significantly improve the machine learning predictions. Recently, metaheuristics have gained momentous popularity for solving feature selection problem. Whale Optimization Algorithm has gained significant attention by the researcher community searching to solve the feature selection problem. However, the exploration problem in whale optimization algorithm still exists and remains to be researched as various parameters within the whale algorithm have been ignored and not introduced into machine learning models. This paper proposes a new and improved version of the whale algorithm entitled Modified Whale Optimization Algorithm (MWOA) that hybrid with the machine learning models such as logistic regression, decision tree, random forest, K-nearest neighbour, support vector machine, naïve Bayes model. To test this new approach and the performance, the breast cancer datasets were used for MWOA evaluation. The test results revealed the superiority of this model when compared to the results obtained by machine learning models.

Published
2021
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45. Performance analysis of a nanocolumn-RTD VCO for emerging THz wireless applications

Author

Rafael Vinicius Tayette da Nobrega, Ivan Glesk, Anderson L. Sanches, Murilo Loiola, Thiago R. Raddo, and Ulysses Rondina Duarte

Subjects
010302 applied physics, Computer science, business.industry, Terahertz radiation, Oscillation, TK, Energy conversion efficiency, Hardware_PERFORMANCEANDRELIABILITY, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Power (physics), Voltage-controlled oscillator, 0103 physical sciences, Hardware_INTEGRATEDCIRCUITS, Optoelectronics, Wireless, Photonics, 0210 nano-technology, business, Diode
Abstract

The data rates which can be processed by integrated communication systems are increasing as the CMOS process and photonic technologies scale. Emerging bandwidth-hungry applications demand new solutions based on terahertz (THz) systems. This work proposes a GaAs/AlAs nanocolumn-Resonant Tunneling Diode (Nano-RTD) device as a voltage-controlled oscillator (VCO) for frequency generation in the THz spectrum window, i.e., Y-band (325 - 500 GHz). A comprehensive semianalytical approach to evaluating the performance of the Nano-RTD VCO device is developed. The latter addresses the oscillation frequency, maximum oscillation frequency, tuning range, output power, DC consumption power, and DC/AC conversion efficiency. Moreover, the oscillation stability of the designed device in the Y-band was numerically verified. Results shown that the device can operate in the Y-band (@ ~500 GHz and 300 K), with a very-low DC power consumption down to 0.16 mW, along with a good DC/AC conversion efficiency (2.4%). The Nano-RTD VCO is compatible with current CMOS fabrication technology and has a very compact footprint (2000 nm2). Finally, the device may be used as part of system solutions to satisfying emerging THz wireless applications such as in-body nano-communication, wireless nano-networks, and network-on-chip.

Published
2020

46. Investigation of 2D-WH/TS OCDMA Code Stability in Systems with SOA-Based Device

Author

Wing C. Kwong, Anderson L. Sanches, Mohamed Abuhelala, Umair A. Korai, and Ivan Glesk

Subjects
TK, 02 engineering and technology, 01 natural sciences, lcsh:Technology, 010309 optics, lcsh:Chemistry, 020210 optoelectronics & photonics, gain recovery time, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Code (cryptography), General Materials Science, Forward error correction, code carriers redshift, Instrumentation, lcsh:QH301-705.5, Fluid Flow and Transfer Processes, Optical amplifier, Physics, semiconductor optical amplifier, business.industry, lcsh:T, Process Chemistry and Technology, optical code division multiple access, General Engineering, bit error rate, Redshift, lcsh:QC1-999, Computer Science Applications, Wavelength, lcsh:Biology (General), lcsh:QD1-999, lcsh:TA1-2040, Picosecond, Bit error rate, Optoelectronics, Photonics, business, lcsh:Engineering (General). Civil engineering (General), lcsh:Physics
Abstract

This paper investigates for the first time how the implementation of semiconductor optical amplifier (SOA)-based devices in photonic networks can negatively impact the integrity of two-dimensional wavelength-hopping time-spreading (2D-WH/TS) optical code-division multiple access (OCDMA) codes based on multi-wavelength picosecond code carriers. It is demonstrated and confirmed by simulations that the influence of an SOA under driving currents of 50 mA to 250 mA causes a 0.08 to 0.8 nm multi-wavelength picosecond code carriers&rsquo, wavelength redshift. The results obtained are then used to calculate the degradation of OCDMA system performance in terms of the probability of error Pe and the decrease in the number of simultaneous users. It is shown that, when the SOA-induced 0.8 nm code carriers redshift becomes equal to the code carries wavelength channel spacing, the (8,53)-OCDMA system performs only as a (7,53)-OCDMA system, and the number of simultaneous users drops from 14 to 10 or 84 to 74 with the forward error correction (FEC) Pe of 10&minus, 9, respectively. The impact of the 0.8 nm redshift is then shown on a (4,53)-OCDMA system, where it causes a drop in the number of simultaneous users from 4 to 3 or 37 to 24 with the FEC Pe of 10&minus, 9, respectively.

Published
2020

47. Impact of Wind Gust on High-Speed Characteristics of Polarization Mode Dispersion in Optical Power Ground Wire Cables

Author

Jarmila Müllerová, Milan Dado, Jan Litvik, Ivan Glesk, Daniel Benedikovic, Andrej Veselovsky, and Jozef Dubovan

Subjects
optical fiber, Materials science, Optical fiber, Acoustics, TK, Optical power, 02 engineering and technology, eye diagram, lcsh:Chemical technology, 01 natural sciences, Biochemistry, Article, Analytical Chemistry, law.invention, 010309 optics, 020210 optoelectronics & photonics, law, principal state of polarization, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, lcsh:TP1-1185, Electrical and Electronic Engineering, Instrumentation, sensing, Optical fiber cable, differential group delay, polarization, Transmission system, Polarization (waves), Atomic and Molecular Physics, and Optics, Transmission (telecommunications), Polarization mode dispersion, Differential group delay
Abstract

Polarization mode dispersion is recognized as a key factor limiting optical transmission systems, particularly those fiber links that run at bit rates beyond 10 Gbps. In-line test and characterization of polarization mode dispersion are thus of critical importance to evaluate the quality of installed optical fibers that are in use for high-speed signal traffics. However, polarization-based effects in optical fibers are stochastic and quite sensitive to a range of environmental changes, including optical cable movements. This, in turn, gives rise to undesired variations in light polarization that adversely impair the quality of the signal transmission in the link. In this work, we elaborate on experimental testing and theoretical analysis to asses changes of polarization mode dispersion in optical fibers that are caused by environmental variations, here wind gusts in particular. The study was performed on commercially harnessed optical fibers installed within optical power ground wire cables, taking into account different weather conditions. More specifically, we showed that changes caused by wind gusts significantly influence the differential group delay and the principal state of polarization in those optical fibers. For this, we experimentally measured a number of parameters to characterize light polarization properties. Measurements were carried out on C-band operated fiber-optic link formed by 111-km-long power ground wire cables and 88 spectral channels, with a test time step of 1 min during 12 consecutive days. Variations in differential group delay allowed for sensitive testing of environmental changes with measured maxims up to 10 ps under the worst wind conditions. Moreover, measured parameters were used in a numerical model to assess the quality of transmitted high-bit-rate optical signals as a function of wind conditions. The analysis revealed a negligible impact of wind on a 10 Gbps transmission, while substantial influence was noticed for higher bit rates up to 100 Gbps. These results show promises for efficient sensing of environmental changes and subsequent monitoring of the quality of recently used fiber-optic link infrastructures.

Published
2020

48. Data driven model improved by multi-objective optimisation for prediction of building energy loads

Author

Saleh Seyedzadeh, Ivan Glesk, Stephen Oliver, Bimal Kumar, and Farzad Pour Rahimian

Subjects
Computer science, Process (engineering), 020209 energy, TK, 0211 other engineering and technologies, Evolutionary algorithm, Building energy, Control engineering, 02 engineering and technology, Building and Construction, Abstract machine, Data-driven, Control and Systems Engineering, 021105 building & construction, Hyperparameter optimization, 0202 electrical engineering, electronic engineering, information engineering, Sustainable design, Energy (signal processing), Civil and Structural Engineering
Abstract

Machine learning (ML) has been recognised as a powerful method for modelling building energy consumption. The capability of ML to provide a fast and accurate prediction of energy loads makes it an ideal tool for decision-making tasks related to sustainable design and retrofit planning. However, the accuracy of these ML models is dependent on the selection of the right hyper-parameters for a specific building dataset. This paper proposes a method for optimising ML models for forecasting both heating and cooling loads. The technique employs multi-objective optimisation with evolutionary algorithms to search the space of possible parameters. The proposed approach not only tunes single model to precisely predict building energy loads but also accelerates the process of model optimisation. The study utilises simulated building energy data generated in EnergyPlus to validate the proposed method, and compares the outcomes with the regular ML tuning procedure (i.e. grid search). The optimised model provides a reliable tool for building designers and engineers to explore a large space of the available building materials and technologies.

Published
2020

49. 2-D optical-CDMA modulation in automotive time-of-flight LIDAR systems

Author

Guu-Chang Yang, Wei-Yi Lin, Ivan Glesk, and Wing C. Kwong

Subjects
business.industry, Computer science, Code division multiple access, TK, 010401 analytical chemistry, Automotive industry, Ranging, 01 natural sciences, 0104 chemical sciences, 010309 optics, Time of flight, Lidar, Modulation, 0103 physical sciences, Code (cryptography), Electronic engineering, business, Decoding methods
Abstract

In this paper, the application of 2-D optical code-division multiple-access (OCDMA) modulation using wavelength-hopping time-spreading codes in long-range automotive time-of-flight (ToF) light detection and ranging (LIDAR) systems is proposed and demonstrated. The regulations and constraints that govern the design of the proposed system are presented. Using 2-D carrier-hopping prime codes, the modulation technique and associated hardware are implemented and validated with OptiSystemTM simulation. Interference-robustness studies show that the proposed 2-D OCDMA ToF LIDAR system is more flexible in the choice of system/code parameters and can support many more sensors and simultaneous ToF measurements than the 1-D counterpart. Keywords: Automotive, code division multiple access, LIDAR, time-of-flight.

Published
2020

50. Investigation of 2D-WH/TS OCDMA System Performance under the Influence of PMD

Author

Wing C. Kwong, Ivan Glesk, Milan Dado, Saleh Seyedzadeh, and Jozef Dubovan

Subjects
Physics, Code division multiple access, Polarization mode dispersion, TK, Differential group delay, Picosecond, Electronic engineering, Optical polarization, Coding (social sciences)
Abstract

The impact of a differential group delay (DGD) and polarization mode dispersion (PMD) on multi-wavelength picosecond code carriers used by two-dimensional wavelength-hopping time-spreading coding schemes in optical code division multiple access (2D-WH/TS OCDMA systems is investigated. Based on experimental data collected over ten days on a 111 km long commercially used fiber link PMD and DGD parameters are determined and used to find the code carriers temporal broadening. This information is then used to calculate the 2D-WH/TS OCDMA system performance degradation as a function of varying number of simultaneous users for different DGD.

Published
2020

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