Your search keyword '"Forward error correction"' showing total 1,379 results

1. Floquet nonadiabatic mixed quantum–classical dynamics in periodically driven solid systems.

Author

Chen, Jingqi, Wang, Yu, and Dou, Wenjie

Subjects

PHONONS, SURFACE dynamics, POPULATION dynamics, FORWARD error correction

Abstract

In this paper, we introduce the Floquet mean-field dynamics and Floquet surface hopping approaches to study the nonadiabatic dynamics in periodically driven solid systems. We demonstrate that these two approaches can be formulated in both real and reciprocal spaces. Using the two approaches, we are able to simulate the interaction between electronic carriers and phonons under periodic drivings, such as strong light–matter interactions. Employing the Holstein and Peierls models, we show that strong light–matter interactions can effectively modulate the dynamics of electronic population and mobility. Notably, our study demonstrates the feasibility and effectiveness of modeling low-momentum carriers' interactions with phonons using a truncated reciprocal space basis, an approach impractical in real space frameworks. Moreover, we reveal that even with a significant truncation, carrier populations derived from surface hopping maintain greater accuracy compared to those obtained via mean-field dynamics. These results underscore the potential of our proposed methods in advancing the understanding of carrier–phonon interactions in various periodically driven materials. [ABSTRACT FROM AUTHOR]

Published

2024

2. MIMO and PDM-based intersatellite optical link for high-speed data transfer and remote sensing application.

Author

Chaudhary, Sushank, Meng, Yahui, Sharma, Abhishek, and Naeem, Muhammad Ali

Subjects

FORWARD error correction, BIT error rate, ATMOSPHERIC turbulence, OPTICAL communications, ERROR rates

Abstract

Inter-Satellite Optical Wireless Communication (Is-OWC) is a pivotal technology for advancing global connectivity and the effectiveness of space-based operations. It serves as the linchpin for various applications such as global internet coverage, Earth observation, and remote sensing, bolstering our capacity to monitor the planet and deliver essential services. This paper presents the design and performance evaluation of a Polarization Division Multiplexing (PDM) and Multiple Input Multiple Output (MIMO)-based Is-OWC system operating at a data rate of 60 Gbps. The system was tested under varying transmission distances, atmospheric turbulence, and pointing error conditions. At a transmission distance of 10,000 km, the system achieved a Bit Error Rate (BER) of 6.76 × 10⁻3 for Channel 1 (X polarization) and 7.1 × 10⁻3 for Channel 4 (Y polarization), both within Forward Error Correction (FEC) limits. The introduction of a 4 × 4 MIMO configuration extended the transmission range to 14,000 km, with a corresponding BER of 9.1 × 10⁻3 for Channel 1 and 8.7 × 10⁻⁵ for Channel 4. Eye diagrams confirm successful signal reception, demonstrating that the system can maintain high data rates and low error rates over long distances. The proposed PDM-MIMO system showcases high-capacity, robust performance under challenging conditions, such as turbulence and pointing errors, validating its suitability for space-based communication applications. These findings highlight the potential of the system for future deployments in satellite networks, offering reliable, high-throughput, and low-latency data transmission over extended distances. [ABSTRACT FROM AUTHOR]

Published

2024

3. Ultra-high-cardinality geometric shaping in the finite SNR regime.

Author

Goossens, Sebastiaan, Gültekin, Yunus Can, Vassilieva, Olga, Kim, Inwoong, Palacharla, Paparao, Okonkwo, Chigo, and Alvarado, Alex

Subjects

ADDITIVE white Gaussian noise, FORWARD error correction, OPTIMIZATION algorithms, AUTOMATIC differentiation, GEOMETRIC shapes

Abstract

Four-dimensional (4D) constellations with up to 131 072 points (17 bit/4D-sym) are designed for the first time using geometric shaping. The constellations are optimized in terms of mutual information (MI) and generalized MI (GMI) for the additive white Gaussian noise (AWGN) channel, targeting a forward error correction (FEC) rate of 0.8 at finite signal-to-noise ratios. The presented 15–17 bit constellations are currently the highest-performing constellations in the literature, having a gap to the AWGN capacity as low as 0.17 dB (MI) and 0.45 dB (GMI) at 17 bit/4D-sym. For lower cardinalities, our constellations match or closely approach the performance of previously published optimized constellations. We also show that (GMI-)optimized constellations with a symmetry constraint, optimized for a FEC rate of 0.8, perform nearly identical to their unconstrained counterparts for cardinalities above 8 bit/4D-sym. A symmetry constraint for MI-optimized constellations is shown to have a negative impact in general. The proposed procedure relies on a Monte-Carlo-based approach for evaluating performance and is extendable to other (nonlinear) channels. Stochastic gradient descent is used for the optimization algorithm for which the gradients are computed using automatic differentiation. This article is part of the theme issue 'Celebrating the 15th anniversary of the Royal Society Newton International Fellowship'. [ABSTRACT FROM AUTHOR]

Published

2024

4. Ultraviolet communication system utilizing effective performance β-Ga2O3 photodetector.

Author

Gao, Xiang, Xie, Tianlong, Wu, Jiang, Fu, Jingwei, Gao, Xumin, Xie, Mingyuan, Zhao, Haitao, Wang, Yongjin, and Shi, Zheng

Subjects

FORWARD error correction, METAL detectors, OXYGEN detectors, MAGNETRON sputtering, QUANTUM efficiency, BINARY sequences, SAPPHIRES

Abstract

In recent years, solar-blind ultraviolet photodetectors (PDs) based on β -Ga2O3 have gained significant attention for their applications in military and commercial fields. This study explores the grain orientation and crystal quality of Ga2O3 films grown on sapphire substrates via RF magnetron sputtering at various growth temperatures and post-annealing temperatures. After determining optimal temperatures, we investigated the photoelectric performance of the metal/semiconductor/metal detectors with different oxygen flow ratios (0%, 5%, 10%). The PD grown in a pure Ar atmosphere exhibited the highest responsivity (48.93 A/W), remarkable detectivity (1.35 × 1014 Jones), excellent external quantum efficiency (2.39 × 104%), and also rapid photoresponse time (0.118 s rise time/0.031 s decay time) under 1000 μ W/cm2 254 nm light illumination. These results are attributed to the internal gain from an optimal concentration of oxygen vacancies in the well-crystallized film, without the deep-level defects typically induced under oxygen-rich conditions. Leveraging this optimized chip, we developed a deep ultraviolet communication system using a Ga2O3-based detector. The system achieved a data rate of 65 kbps with a pseudo-random binary sequence signals utilizing on-off keying. Additionally, using discrete multi-tone signals modulated with 32-quadrature amplitude modulation, it reached a maximum data rate of 80.65 kbps, both satisfying forward error correction threshold of 3.8 × 10−3. These results highlight the considerable potential of high-quality β -Ga2O3 solar-blind PDs for ultraviolet communication applications. [ABSTRACT FROM AUTHOR]

Published

2024

5. The Digital Twin Framework for the Physical Wideband and Long‐Haul Optical Fiber Communication Systems.

Author

Yang, Hang, Niu, Zekun, Fan, Qirui, Li, Lyu, Shi, Minghui, Zeng, Chuyan, Xiao, Shilin, Hu, Weisheng, and Yi, Lilin

Subjects

OPTICAL fiber communication, OPTICAL communications, OPTICAL fiber networks, DIGITAL twins, REAL-time control, FORWARD error correction

Abstract

Digital twin (DT) modeling is essential to optical fiber communication systems, particularly for enhancing system performance, controlling the system in real time, and understanding signal nonlinearity. Conventional split‐step Fourier method ‐based simulations, however, struggle with wide‐band transmissions, plagued by increasing complexity and inherent biases due to inconsistent link parameter availability. Addressing these challenges, a hybrid data‐driven and model‐driven DT approach for the wide‐band and long‐haul physical systems with various system effects is developed. The approach utilizes a neural network (NN) to capture fiber nonlinear features as well as biased perturbations as "lumped" stochastic noises while offloading the linear effects to modules described by physical models of link elements. The model, tested in a 30.5‐Tbps 1200 km fiber transmission link with 40 channels, achieves a mean Q factor error of less than 0.1 dB and a maximum runtime of 1.3 s for NN processing under various launch powers, transmission lengths, and optical signal‐to‐noise ratios. Furthermore, the study has implemented a nonlinear compensation algorithm on the DT model, yielding a consistent enhancement in experimental data. The accuracy and adaptability of the DT model underline its suitability for planning, design, and optimization within the physical optical fiber communication systems. [ABSTRACT FROM AUTHOR]

Published

2024

6. Hierarchical QAM and Inter-Layer FEC for Multi-View Video Plus Depth Format in Two-Way Relay Channels.

Author

You, Dongho, Kim, Sung-Hoon, and Kim, Dong Ho

Subjects

FORWARD error correction, QUADRATURE amplitude modulation, DATA structures, STREAMING video & television, DATA protection, LINEAR network coding

Abstract

This paper presents an enhanced method for the transmission of 3D video in the Multi-view Video plus Depth (MVD) format over Two-Way Relay Channels (TWRC). Our approach addresses the unique challenges of MVD-based 3D video by combining Hierarchical Quadrature Amplitude Modulation (HQAM), a method that prioritizes data layers based on importance, and Inter-Layer Forward Error Correction (IL-FEC), which protects critical data from errors. These are specifically designed to handle the dual-layer data structure where color data and depth information require different levels of error protection, and it reduces transmission errors and enhances the quality of MVD-based 3D video over TWRC. In the TWRC scenario, the proposed scheme optimizes transmission by reducing the number of relayed bitstreams by half while maintaining high-quality requirements, as demonstrated by significant improvements in the Structural Similarity Index (SSIM) for virtually synthesized views. Furthermore, we identify and optimize the hierarchical modulation parameter (α), which controls the priority and protection levels of different data streams. Systematically varying α reveals its substantial impact on the quality of the reconstructed 3D video, as measured by SSIM. Our results demonstrate that the proposed combination of HQAM and IL-FEC not only maintains the target SSIM of 0.9 for the virtually synthesized view under various relay conditions but also reveals the optimal α value for balancing the error protection between the color and depth map data streams. Notably, while increasing α enhances the protection of critical data (such as color video streams), it may concurrently degrade the quality of less important streams (like depth maps), highlighting the importance of fine-tuning α to achieve the best overall video quality. These findings suggest that our method provides a flexible and effective solution for high-quality 3D video transmission in challenging communication environments, potentially advancing the development of future 3D video delivery systems. [ABSTRACT FROM AUTHOR]

Published

2024

7. An unsupervised coherent receiver digital signal processing algorithm based on spectral clustering with no data preamble.

Author

He, Jianhua, Zhan, Yueying, Pan, Haoyuan, and Peng, Hui

Subjects

FORWARD error correction, DIGITAL signal processing, OPTICAL receivers, BIT error rate, OPTICAL modulation

Abstract

A coherent optical receiver digital signal processing (DSP) scheme is proposed based on spectral clustering, which utilises spectral clustering to cluster the signals outputted by the DSP. Compared to existing blind DSP algorithms for coherent optical receivers operating at over 100Gbps with PM‐mQAM, the proposed scheme effectively suppresses various physical impairments, achieving lower bit error rates (BERs) at the same transmission distance, thus enabling longer transmission distances under the same forward error correction threshold. Furthermore, simulations of the proposed scheme on a 14GBaud PM‐16QAM coherent optical transmission system show that, at a BER of 1.9E‐2, the maximum transmission distance increases from 1700 to 2000 km, and at a BER of 3.8E‐3, it increases from 700 to 900 km. [ABSTRACT FROM AUTHOR]

Published

2024

8. Bilateral Chemical Linking at NiOx Buried Interface Enables Efficient and Stable Inverted Perovskite Solar Cells and Modules.

Author

Yang, Yang, Chen, Ruihao, Wu, Jiandong, Dai, Zhiyuan, Luo, Chuanyao, Fang, Zhiyu, Wan, Shuyuan, Chao, Lingfeng, Liu, Zhe, and Wang, Hongqiang

Subjects

SOLAR cells, PEROVSKITE, VALENCE bands, CHARGE carrier mobility, SURFACE defects, FORWARD error correction

Abstract

Inverted NiOx‐based perovskite solar cells (PSCs) exhibit considerable potential because of their low‐temperature processing and outstanding excellent stability, while is challenged by the carriers transfer at buried interface owing to the inherent low carrier mobility and abundant surface defects that directly deteriorates the overall device fill factor. Present work demonstrates a chemical linker with the capability of simultaneously grasping NiOx and perovskite crystals by forming a Ni−S−Pb bridge at buried interface to significantly boost the carriers transfer, based on a rationally selected molecule of 1,3‐dimethyl‐benzoimidazol‐2‐thione (NCS). The constructed buried interface not only reduces the pinholes and needle‐like residual PbI2 at the buried interface, but also deepens the work function and valence band maximum positions of NiOx, resulting in a smaller VBM offset between NiOx and perovskite film. Consequently, the modulated PSCs achieved a high fill factor up to 86.24 %, which is as far as we know the highest value in records of NiOx‐based inverted PSCs. The NCS custom‐tailored PSCs and minimodules (active area of 18 cm2) exhibited a champion efficiency of 25.05 % and 21.16 %, respectively. The unencapsulated devices remains over 90 % of their initial efficiency at maximum power point under continuous illumination for 1700 hours. [ABSTRACT FROM AUTHOR]

Published

2024

9. Parity Check Codes for Second Order Diversity.

Author

Patel, Aaqib A., Mateen Ahmed, Abdul, Praveen Sai, B., and Ali Khan, Mohammed Zafar

Subjects

FORWARD error correction, RAYLEIGH fading channels, MODULATION coding, ERROR rates, RADIO transmitter fading, 5G networks

Abstract

Short block length "block" codes are typically not used in wireless standards as soft decision decoding is computationally intensive and hard decision decoding results in performance loss. However, short block lengths are of interest to massive machine-type communications (mMTC) and ultra-reliable low-latency communications (URLLC). In this paper, we propose a diversity preserving enhanced hard-decision decoding scheme for parity check codes (PCC) over Rayleigh fading channels. The proposed flip decoding scheme has linear complexity in the block length. Theoretical analysis and simulation results verify the correctness of the proposed detection scheme. [ABSTRACT FROM AUTHOR]

Published

2024

10. The imperfections of the screen to camera OCC systems.

Author

Jameel, Zainab N. and Jihad, Noor J.

Abstract

Despite the several significant features of the S2C/OCC systems that were mentioned before, the system implementation is difficult due to several issues such as different sources of noise that degrade the performance of the S2C/OCC communication system. This system is affected by several noise sources which include optical noise such as normal light-emitting and light ambient sources, whereas electrical noise comes from electronic components. Moreover, interference is another problem for the S2C/OCC systems, as would other imperfections. The OCC system for multiple cell transmitters and imaging cell receivers supports the data detection techniques, including the decoding and sampling techniques that are tested experimentally under different conditions. The impact of the S2C system impairments such as the ambient light, blur phenomenon, and perspective distortion are tested experimentally. As mentioned previously, the proposed combination of RS-FEC with CC-FEC is an appropriate technique for effective consecutive data transmission, particularly supportive of the S2C/OCC system. [ABSTRACT FROM AUTHOR]

Published

2024

11. A study of forward error-correction techniques in digital communication systems.

Author

Jassim, Ghada Abood and Hussain, Ghasan Ali

Subjects

FORWARD error correction, ERROR-correcting codes, CHANNEL coding, ELECTRIC circuits, LOW density parity check codes

Abstract

Ensuring data reliability in the world of digital communication systems is of utmost importance, especially when faced with the problems presented by noisy transmission channels. The problems of multipath fading, atmospheric variations, and electromagnetic interference can have a substantial impact on the operation of the system, requiring the use of strong error correction algorithms. The focus of our analysis revolves around two main channel coding methodologies: automated repeat request (ARQ) and forward error correction (FEC). Within the realm of Forward Error Correction (FEC), we investigate a range of codes, including Turbo, Hamming, LDPC, Convolutional, RS, Polar, and BCH. Each code possesses distinct complexity and reliability profiles. The purpose of our analysis is to clarify the relative advantages and disadvantages of various codes, providing valuable information on their appropriateness for specific uses. RS and Hamming codes are particularly notable for their ability to effectively correct both random and burst mistakes while having relatively low coding complexities. In contrast, turbo and convolutional codes have higher levels of complexity, yet they provide impressive error correction capabilities. Nevertheless, there are subtle distinctions present in these codes. For example, the LDPC code, despite its strong error correction capabilities, has an error floor, making it inappropriate for applications that require extremely low error rates. Similarly, Polar codes, while effective, have limitations when it comes to code length. However, error-correcting codes have a wide range of applications, including 5G, WIFI, WiMAX, LTE, electrical circuits, magnetic recording devices, and even NASA applications. Although they have inherent limitations, their numerous advantages surpass their drawbacks, making them essential assets in the current communication infrastructure. [ABSTRACT FROM AUTHOR]

Published

2024

12. Mitigation of atmospheric losses using dual‐polarized 16‐QAM MIMO technique in free‐space optical system in various weather conditions.

Author

M, Vinoth Kumar, Singh, Rupali, and Karuppiah, Marimuthu

Subjects

WEATHER, FORWARD error correction, BIT error rate, SIGNAL processing, ATMOSPHERIC turbulence, DATA transmission systems, FOG

Abstract

Summary: The technique to overcome the challenge while implementing the fiber optical link is investigated using an alternative optical link called a free‐space optical (FSO) link with advanced modulation and signal processing techniques. A dual‐polarized 16‐quadrature amplitude‐modulated signal is transmitted over single and multi‐FSO channels under various atmospheric attenuation conditions. High bandwidth and data rates (up to 10 Gbps), unlicensed spectrum (above 300 GHz), and simplicity of deployment are significant benefits of the FSO system. However, the weather conditions of haze, rain, and fog cause signal attenuation when the optical carrier wave is transmitted over free space, and atmospheric turbulence is a challenge to FSO implementation, which degrades the transmission performance of optical signals for long‐distance communication. For 120 Gbps data transmission, the performance of a multi‐input and multi‐output (MIMO) FSO system is evaluated by observing the bit error rate (BER) and received signal constellation diagram. Optical signal‐to‐noise ratio (OSNR) parameters were iterated to determine the optimal value for back‐to‐back, single‐input, single‐output (SISO), and MIMO systems. Moreover, we examined the proposed system's output with recent articles, including MIMO, multiplexing, and various modulation techniques. The comparison of results shows that the suggested MIMO‐FSO model has enhanced the performance with the lower BER as less than 3.8 × 10−3 (log of BER is −2.42) forward error correction (FEC) limit for 18.7 km link range in clear air with 0.54 dB/km attenuation, 4.8, 4.5, 1.35, and 0.57 km under haze, light fog, medium, and heavy fog with 4.6, 6.9, 28.9, and 75 dB/km attenuations. [ABSTRACT FROM AUTHOR]

Published

2024

13. Neural Network Equalisation for High-Speed Eye-Safe Optical Wireless Communication with 850 nm SM-VCSELs.

Author

Osahon, Isaac N. O., Kostakis, Ioannis, Powell, Denise, Meredith, Wyn, Missous, Mohamed, Haas, Harald, Tang, Jianming, and Rajbhandari, Sujan

Subjects

PULSE amplitude modulation, FORWARD error correction, SURFACE emitting lasers, OPTICAL communications, BIT rate

Abstract

In this paper, we experimentally illustrate the effectiveness of neural networks (NNs) as non-linear equalisers for multilevel pulse amplitude modulation (PAM-M) transmission over an optical wireless communication (OWC) link. In our study, we compare the bit-error-rate (BER) performances of two decision feedback equalisers (DFEs)—a multilayer-perceptron-based DFE (MLPDFE), which is the NN equaliser, and a transversal DFE (TRDFE)—under two degrees of non-linear distortion using an eye-safe 850 nm single-mode vertical-cavity surface-emitting laser (SM-VCSEL). Our results consistently show that the MLPDFE delivers superior performance in comparison to the TRDFE, particularly in scenarios involving high non-linear distortion and PAM constellations with eight or more levels. At a forward error correction (FEC) threshold BER of 0.0038, we achieve bit rates of ~28 Gbps, ~29 Gbps, ~22.5 Gbps, and ~5 Gbps using PAM schemes with 2, 4, 8, and 16 levels, respectively, with the MLPDFE. Comparably, the TRDFE yields bit rates of ~28 Gbps and ~29 Gbps with PAM-2 and PAM-4, respectively. Higher PAM levels with the TRDFE result in BERs greater than 0.0038 for bit rates above 2 Gbps. These results highlight the effectiveness of the MLPDFE in optimising the performance of SM-VCSEL-based OWC systems across different modulation schemes and non-linear distortion levels. [ABSTRACT FROM AUTHOR]

Published

2024

14. Experimental analysis of reducing outage probability using deep interleaving for long‐distance free space optical systems.

Author

Chang, Yunfan, Cai, Shanyong, Wang, Liqian, Zhang, Haojie, and Zhang, Zhiguo

Subjects

FORWARD error correction, OPTICAL communications, FREE-space optical technology, TURBULENCE, ATMOSPHERIC turbulence, PROBABILITY theory, BANDWIDTHS

Abstract

Free space optical communication (FSO) has become a popular research direction due to its high bandwidth, easy deployment, and inherent security. Its channel state is unstable because of atmospheric environment, especially in long‐distance ground transmission system. Interleaving combined with forward error correction coding (FEC) have been utilised to improve the stability of system. However, there is little detailed experimental results of deep interleaving combined with FEC under different atmospheric turbulence intensity over long‐distance FSO system. A deep interleaving with FEC method was designed and implemented on a 7 km long online experiment. The performance of different depth interleaving is analysed under weak and strong atmospheric turbulence state. The experiment results show that deep interleaving performs better under weak turbulence for the larger correlation factor of the channel and the outage probability of the system with deep interleaving can be greatly reduced. [ABSTRACT FROM AUTHOR]

Published

2024

15. Assessment of tuberculosis transmission probability in three Thai prisons based on five dynamic models.

Author

Mahawan, Nithinan, Rattananupong, Thanapoom, Sri-Uam, Puchong, and Jiamjarasrangsi, Wiroj

Subjects

DYNAMIC models, MULTIPLE regression analysis, TUBERCULOSIS, FORWARD error correction, BLAND-Altman plot, PRISONS, PROBABILITY theory

Abstract

This study aimed to assess and compare the probability of tuberculosis (TB) transmission based on five dynamic models: the Wells–Riley equation, two Rudnick & Milton-proposed models based on air changes per hour (ACH) and liters per second per person (L/s/p), the model proposed by Issarow et al, and the Applied Susceptible-Exposed-Infected-Recovered (SEIR) TB transmission model. This study also aimed to determine the impact of model parameters on such probabilities in three Thai prisons. A cross-sectional study was conducted using data from 985 prison cells. The TB transmission probability for each cell was calculated using parameters relevant to the specific model formula, and the magnitude of the model agreement was examined by Spearman's rank correlation and Bland–Altman plot. Subsequently, a multiple linear regression analysis was conducted to investigate the influence of each model parameter on the estimated probability. Results revealed that the median (Quartiles 1 and 3) of TB transmission probability among these cells was 0.052 (0.017, 0.180). Compared with the pioneered Wells–Riley's model, the remaining models projected discrepant TB transmission probability from less to more commensurate to the degree of model modification from the pioneered model as follows: Rudnick & Milton (ACH), Issarow et al., and Rudnick & Milton (L/s/p), and the applied SEIR models. The ventilation rate and number of infectious TB patients in each cell or zone had the greatest impact on the estimated TB transmission probability in most models. Additionally, the number of inmates in each cell, the area per person in square meters, and the inmate turnover rate were identified as high-impact parameters in the applied SEIR model. All stakeholders must urgently address these influential parameters to reduce TB transmission in prisons. Moreover, further studies are required to determine their relative validity in accurately predicting TB incidence in prison settings. [ABSTRACT FROM AUTHOR]

Published

2024

16. Efficient Direct Detection of Twin Single-Sideband Quadrature-Phase Shift Keying Using a Single Detector with Hierarchical Blind-Phase Search.

Author

Zhang, Hongbo, Liu, Jiao, Lu, Guo-Wei, Zhang, Min, Wan, Feng, Cai, Ju, Ling, Weiwei, and Hu, Liming

Subjects

FORWARD error correction, QUADRATURE amplitude modulation, SINGLE-mode optical fibers, LIGHT transmission, PHOTODETECTORS, BIT error rate

Abstract

We propose a novel reception scheme for twin single-sideband (twin-SSB) signals using just a single photodetector (PD), significantly reducing the system complexity and cost. To detect a twin-SSB with power-unbalanced quadrature-phase shift keying (QPSK) sidebands upon detection via a single PD at the receiver side, two QPSKs carried in two sidebands are coherently superposed and detected in a 16-ary quadrature amplitude modulation (16-QAM) format. This technique notably diminishes the linearity and effective number of bits required for the transmitter components in high-speed optical transmission systems. Moreover, a hierarchical blind-phase search (HBPS) algorithm is proposed to compensate for the imperfect phase rotation of QPSK signals during transmission. To demonstrate the effectiveness of our proposed method, we successfully conducted simulations of 112 Gb/s 16-QAM signal transmission over a 10 km standard single-mode fiber (SSMF), achieving bit error ratios (BERs) of 7.84 × 10 − 4 , well below the 7% hard-decision forward error correction (HD-FEC) threshold of 3.8 × 10 − 3 . In addition, the synthetic transmission scheme proposed in this paper is compared with the traditional 16-QAM signal transmission scheme, and the results show that the proposed scheme does not introduce a performance cost with the same received optical power (ROP) and transmission distance. [ABSTRACT FROM AUTHOR]

Published

2024

17. High‐Speed GaN‐Based 405 nm Violet Superluminescent Diode with Tilted Facet for Visible Light Communications.

Author

Dong, Mengxi, Yi, Shulan, Wang, Junfei, Ma, Chicheng, Li, Dong, Wang, Shanshan, Hou, Yuqi, Li, Ziwei, Zhang, Junwen, Shi, Jianyang, Chi, Nan, and Shen, Chao

Subjects

VISIBLE spectra, OPTICAL communications, FORWARD error correction, DIODES, SEMICONDUCTOR lasers, INDIUM gallium nitride, LIGHT sources

Abstract

Visible light communication (VLC) based on superluminescent diode (SLD) is a promising technology with great potential for future 6G optical wireless network. In this work, a 405 nm violet SLD device is fabricated with an 8° tilted facet at one end of the waveguide based on InGaN/GaN quantum wells. The device has an optical power of 14.67 mW under continuous‐wave operation. The full width at half maximum (FWHM) of the SLD at 400 mA is 12.52 nm, which is significantly larger than that in a violet laser diode (LD). Using the SLD as transmitter in VLC system, a high data transmission rate of 3.299 Gbps has been achieved using the discrete multiple tone (DMT) modulation. The corresponding bit error ratio (BER) is measured to be 1.67 × 10−3, which satisfies the forward error correction (FEC) threshold of 3.8 × 10−3. The results suggest that such device can be used as a promising light source for VLC and light fidelity (LiFi) applications. [ABSTRACT FROM AUTHOR]

Published

2024

18. A Low-Density Parity-Check Coding Scheme for LoRa Networking.

Author

Yang, Kang and Du, Wan

Subjects

GRAPH neural networks, FORWARD error correction, HAMMING codes, DECODING algorithms

Abstract

This article presents a novel system, LLDPC,1 which brings Low-Density Parity-Check (LDPC) codes into Long Range (LoRa) networks to improve Forward Error Correction, a task currently managed by less efficient Hamming codes. Three challenges in achieving this are addressed: First, Chirp Spread Spectrum (CSS) modulation used by LoRa produces only hard demodulation outcomes, whereas LDPC decoding requires Log-Likelihood Ratios (LLR) for each bit. We solve this by developing a CSS-specific LLR extractor. Second, we improve LDPC decoding efficiency by using symbol-level information to fine-tune LLRs of error-prone bits. Finally, to minimize the decoding latency caused by the computationally heavy Soft Belief Propagation (SBP) algorithm typically used in LDPC decoding, we apply graph neural networks to accelerate the process. Our results show that LLDPC extends default LoRa's lifetime by 86.7% and reduces SBP algorithm decoding latency by 58.09×. [ABSTRACT FROM AUTHOR]

Published

2024

19. Research on performance enhancement scheme of optical camera communication based on adaptive exponential weighted moving average algorithm.

Author

Jia, Wenyang, Tian, Ming, and Feng, Jinliang

Subjects

MOVING average process, FORWARD error correction, BIT error rate, OPTICAL communications, GRAYSCALE model, DATA transmission systems

Abstract

When the COMS camera of optical camera communication (OCC) system acquired the information image, the grayscale value of pixels fluctuated due to the influence of blooming effect and light noise, so that the data logic could not be correctly judged by the decision threshold, which affected the bit error rate (BER) performance transmission distance and data rate, and degraded the system performance. In this paper, the adaptive exponential weighted moving average algorithm is proposed, and the optimal grayscale value matrix of signal demodulation is verified by experiment, so as to reduce the fluctuation of grayscale value and improve the performance of OCC system. The experimental results show that for data processing and analysis based on ZYNQ7020 experimental platform, a 7% forward error correction（BER = 3.8 × 10−3）requirements can be satisfied at 150 cm when the data rate is 3 Kbps, and a 7% forward error correction（BER = 3.8 × 10−3）requirements can be satisfied at 100 cm when the data rate is 5 Kbps. [ABSTRACT FROM AUTHOR]

Published

2024

20. Preparation and Modeling of Graphene Bubbles to Obtain Strain-Induced Pseudomagnetic Fields.

Author

Yu, Chuanli, Cao, Jiacong, Zhu, Shuze, and Dai, Zhaohe

Subjects

GRAPHENE, OXYGEN plasmas, CHEMICAL reactions, BUBBLES, FORWARD error correction

Abstract

It has been both theoretically predicted and experimentally demonstrated that strain can effectively modulate the electronic states of graphene sheets through the creation of a pseudomagnetic field (PMF). Pressurizing graphene sheets into bubble-like structures has been considered a viable approach for the strain engineering of PMFs. However, the bubbling technique currently faces limitations such as long manufacturing time, low durability, and challenges in precise control over the size and shape of the pressurized bubble. Here, we propose a rapid bubbling method based on an oxygen plasma chemical reaction to achieve rapid induction of out-of-plane deflections and in-plane strains in graphene sheets. We introduce a numerical scheme capable of accurately resolving the strain field and resulting PMFs within the pressurized graphene bubbles, even in cases where the bubble shape deviates from perfect spherical symmetry. The results provide not only insights into the strain engineering of PMFs in graphene but also a platform that may facilitate the exploration of the strain-mediated electronic behaviors of a variety of other 2D materials. [ABSTRACT FROM AUTHOR]

Published

2024

21. Vectorial‐Optics‐Enabled Multi‐View Non‐Line‐Of‐Sight Imaging with High Signal‐To‐Noise Ratio.

Author

Wang, Zewei, Li, Xiaoyin, Pu, Mingbo, Chen, Lianwei, Zhang, Fei, Zhang, Qi, Zhao, Zhibin, Yang, Longfei, Guo, Yinghui, and Luo, Xiangang

Subjects

SIGNAL-to-noise ratio, VECTOR fields, IMAGE reconstruction, IMAGE recognition (Computer vision), BREWSTER'S angle, FORWARD error correction

Abstract

Non‐line‐of‐sight (NLOS) imaging enables the reconstruction of targets beyond the direct line of sight, which has extensive applications across various fields. However, it remains unclear how and to what extent the vectorial nature of light, which plays a critical role in optical imaging and object recognition, can enhance the imaging performance of active NLOS imaging. Here, this work proposes a method that utilizes vector optical fields (VOFs) with arbitrarily designed polarization distributions to realize NLOS imaging in challenging conditions with low signal‐to‐noise ratio (SNR). A generalized VOF reflection model is established at the relay surface for active NLOS imaging to determine the optimal illumination angle and polarization as well as the received polarization. Based on this model, the feasibility of multi‐view NLOS imaging is demonstrated with enhanced SNR of echo signals under proper VOF modulation, surpassing the limitations of conventional single‐view NLOS imaging. Simulations and experiments validate the superior performance of the proposed approach to realize accurate reconstruction and recognition of hidden objects. [ABSTRACT FROM AUTHOR]

Published

2024

22. A New Algorithm to Mitigate Fragmentation and Crosstalk in Multi-Core Elastic Optical Networks.

Author

Lacerda Jr., Jurandir C., Morais, Aline G., Cartaxo, Adolfo V. T., and Soares, André C. B.

Subjects

SPECTRUM allocation, ALGORITHMS, RADIO frequency allocation, FORWARD error correction, BANDWIDTHS

Abstract

This paper proposes a core and spectrum allocation algorithm for elastic optical networks based on multi-core fibers. In this context, the fragmentation and crosstalk mitigation algorithm (FraCA) is proposed. FraCA implements mechanisms to reduce spectral fragmentation and inter-core crosstalk in the network, proving efficient when compared with six other algorithms reported in the literature. The numerical results show that when compared with the most competitive of the six algorithms, FraCA achieves a gain of request blocking probability of at least 16.87%, a gain of bandwidth blocking probability of at least 43.95%, and a mean increase in spectral utilization of at least 4.36%. [ABSTRACT FROM AUTHOR]

Published

2024

23. Low-Polarization, Broad-Spectrum Semiconductor Optical Amplifiers.

Author

Zhang, Meng, Zhang, Tianyi, Tang, Hui, Liang, Lei, Chen, Yongyi, Qin, Li, Song, Yue, Lei, Yuxin, Jia, Peng, Wang, Yubing, Qiu, Cheng, Cao, Yuntao, Ning, Yongqiang, and Wang, Lijun

Subjects

SEMICONDUCTOR optical amplifiers, OPTICAL polarization, POTENTIAL barrier, QUANTUM wells, FORWARD error correction

Abstract

Polarization-insensitive semiconductor optical amplifiers (SOAs) in all-optical networks can improve the signal-light quality and transmission rate. Herein, to reduce the gain sensitivity to polarization, a multi-quantum-well SOA in the 1550 nm band is designed, simulated, and developed. The active region mainly comprises the quaternary compound InGaAlAs, as differences in the potential barriers and wells of the components cause lattice mismatch. Consequently, a strained quantum well is generated, providing the SOA with gain insensitivity to the polarization state of light. In simulations, the SOA with ridge widths of 4 µm, 5 µm, and 6 µm is investigated. A 3 dB gain bandwidth of >140 nm is achieved with a 4 µm ridge width, whereas a 6 µm ridge width provides more output power and gain. The saturated output power is 150 mW (21.76 dB gain) at an input power of 0 dBm but increases to 233 mW (13.67 dB gain) at an input power of 10 dBm. The polarization sensitivity is <3 dBm at −20 dBm. This design, which achieves low polarization sensitivity, a wide gain bandwidth, and high gain, will be applicable in a wide range of fields following further optimization. [ABSTRACT FROM AUTHOR]

Published

2024

24. High-Throughput Polar Code Decoders with Information Bottleneck Quantization.

Author

Kestel, Claus, Johannsen, Lucas, and Wehn, Norbert

Subjects

FORWARD error correction, WIRELESS Internet, DECODING algorithms, MULTICASTING (Computer networks), ERROR rates, COMPUTATIONAL complexity, VIDEO coding

Abstract

In digital baseband processing, the forward error correction (FEC) unit belongs to the most demanding components in terms of computational complexity and power consumption. Hence, efficient implementation of FEC decoders is crucial for next-generation mobile broadband standards and an ongoing research topic. Quantization has a significant impact on the decoder area, power consumption and throughput. Thus, lower bit widths are preferred for efficient implementations but degrade the error correction capability. To address this issue, a non-uniform quantization based on the Information Bottleneck (IB) method is proposed that enables a low bit width while maintaining the essential information. Many investigations on the use of the IB method for Low-density parity-check code) LDPC decoders exist and have shown its advantages from an implementation perspective. However, for polar code decoder implementations, there exists only one publication that is not based on the state-of-the-art Fast Simplified Successive-Cancellation (Fast-SSC) decoding algorithm, and only synthesis implementation results without energy estimation are shown. In contrast, our paper presents several optimized Fast-SSC polar code decoder implementations using IB-based quantization with placement and routing results using advanced 12 nm FinFET technology. Gains of up to 16% in area and 13% in energy efficiency are achieved with IB-based quantization at a Frame Error Rate (FER) of 10 − 7 and a polar code of N = 1024 , R = 0.5 compared to state-of-the-art decoders. [ABSTRACT FROM AUTHOR]

Published

2024

25. Design and Optimization of a Mid-Field Wireless Power Transfer System for Enhanced Energy Transfer Efficiency.

Author

Khan, Daud, Ahmad, Ashfaq, and Choi, Dong-you

Subjects

WIRELESS power transmission, ENERGY transfer, CURRENT distribution, ARTIFICIAL implants, ANTENNA feeds, FORWARD error correction

Abstract

Mid-field wireless power transfer (WPT) offers a compelling solution for delivering power to miniature implantable medical devices deep within the human body. Despite its potential, the current power delivery levels remain constrained, and the design of a compact source structure to focus the transmitter field on such implants presents significant challenges. In this paper, a novel miniaturized transmitter antenna operating at 1.71 GHz is proposed. Leveraging the antenna proximity-coupled feeding technique, we achieve optimal current distribution for efficient power transfer. Additionally, a receiver integrated within the human body is proposed, comprising a slotted ground and a meandering slotted radiating element. This receiver is excited via a coaxial feedline with a truncated ground. Our findings demonstrate wireless power transfer of −23 dB (0.501%) at a distance of 30 mm between the transmitter and receiver, alongside a peak gain of −20 dB with an impedance bandwidth of 39.61%. These results highlight promising advancements in enhancing energy transfer efficiency for deep-implant applications. [ABSTRACT FROM AUTHOR]

Published

2024

26. Investigation of IEEE 802.16e LDPC Code Application in PM-DQPSK System.

Author

Xue, Jiaxin, Li, Yupeng, Zhang, Yichao, Wu, Xiao, and Zhang, Yanyue

Subjects

LOW density parity check codes, OPTICAL fiber communication, DIFFERENTIAL phase shift keying, FORWARD error correction, BIT error rate, QUADRATURE phase shift keying, OPTICAL communications, FREE-space optical technology

Abstract

With the development of the Internet and information technology, optical fiber communication systems need to meet people's information demand for large capacity and high speed. High-order phase modulation and channel multiplexing can improve the capacity and data rate of optical fiber communication systems, but they also bring the problem of bit error. To improve the transmission quality and reliability of optical fiber communication systems, forward error correction (FEC) coding techniques are commonly used, which serve as the fundamental approach to enhance the quality and reliability of fiber optic communication systems, ensuring that the received data remain accurate and reliable. The FEC in optical fiber communication systems is divided into three generations. The first generation FEC is mainly hard decision codewords, represented as RS code. The second generation FEC is mainly cascaded code, which stands for interleaved cascaded code. The third generation of FEC mainly refers to soft decision codes, which are represented as low-density parity-check (LDPC) codes. As a kind of FEC, LDPC codes stand out as pivotal contributors in the field of optical communication and have gained remarkable attention due to exceptional error correction performance and low decoding complexity. Based on IEEE802.16e standard, LDPC code with specific code length and rate is compiled and simulated in MATLAB and VPItransmissionMaker 10.1 and successfully incorporated into polarization multiplexed differential quadrature phase shift keying (PM-DQPSK) coherent optical transmission system. The simulation results indicate that the bit error rate (BER) can be reduced to 10−3 when the optical signal-to-noise ratio (OSNR) reaches 14.2 dB, and the BER experiences a reduction by nearly three orders of magnitude when the OSNR is 17.2 dB. These findings underscore the efficacy of LDPC codes in significantly improving the performance of optical communication systems, particularly in scenarios demanding robust error correction capabilities. This study provides valuable, significant results regarding the potential of LDPC codes for enhancing the reliability of optical transmission in real-world applications. [ABSTRACT FROM AUTHOR]

Published

2024

27. Controllable Wrinkling Inspired Multifunctional Metamaterial for Near‐Field and Holographic Displays.

Author

Han, Donghai, Li, Wenkang, Hou, Yushan, Chen, Xiaoming, Shi, Hongyu, Meng, Fanqi, Zhang, Liuyang, and Chen, Xuefeng

Subjects

HOLOGRAPHIC displays, METAMATERIALS, HOLOGRAPHY, METHODS engineering, INFORMATION processing, ALGEBRAIC field theory, FORWARD error correction

Abstract

Tunable electromagnetic (EM) metamaterials have received significant attention due to their compelling advantages of integration and minimization compared with conventional bulky devices. Meanwhile, mechanically reconfigurable metamaterials have witnessed a striving period over recent years due to their simplified structural composition and confined modulation capabilities. Here, a controllable‐wrinkling‐based reconfiguration method is proposed to design split‐ring resonant units with dynamic transmittance spectra by switching between planar and wrinkling morphologies. For the linear polarized incidence, the geometries of planar and wrinkled units are optimized to achieve on‐demanded manipulation of the phases and amplitudes, respectively. By simultaneously implementing the amplitude design and the phase gradient, the mechanically inspired metamaterial is engineered to display a near‐field and a holographic image. For circularly polarized incidences, the spin‐decoupled phases and chiral effects demonstrated in the planar and wrinkled state assist in designing a metamaterial to possess spin‐multiplexed and strain‐modulated fourfold displays. These results demonstrate the practical feasibility of the wrinkling method in engineering tunable metamaterials, and the design flexibility, as well as the mechanical strategy, can extend the potential toward the application scenarios such as information processing, sensing, imaging, flexible meta‐devices, etc. [ABSTRACT FROM AUTHOR]

Published

2024

28. Global Receptive Field Designed Complex-Valued Convolutional Neural Network Equalizer for Optical Fiber Communications.

Author

Han, Lu, Wang, Yongjun, Yang, Haifeng, Zhao, Yang, and Li, Chao

Subjects

CONVOLUTIONAL neural networks, OPTICAL fiber communication, OPTICAL fiber networks, TIME complexity, OPTICAL communications, OPTICAL fibers, FORWARD error correction

Abstract

In this paper, an improved complex-valued convolutional neural network (CvCNN) structure to be placed at the received side is proposed for nonlinearity compensation in a coherent optical system. This complex-valued global convolutional kernel-assisted convolutional neural network equalizer (CvGNN) has been verified in terms of Q-factor performance and complexity compared to seven other related nonlinear equalizers based on both the 64 QAM experimental platform and the QPSK numerical platform. The global convolution operation of the proposed CvGNN is more suitable for the calculation process of perturbation coefficients, and the global receptive field can also be more effective at extracting effective information from perturbation feature maps. The introduction of CvCNN can directly focus on the complex-valued perturbation feature maps themselves without separately processing the real and imaginary parts, which is more in line with the waveform-dependent physical characteristics of optical signals. Based on the experimental platform, compared with the real-valued neural network with small convolutional kernel (RvCNNC), the proposed CvGNNC improves the Q-factor by ∼2.95 dB at the optimal transmission power, while reducing the time complexity by ∼44.7%. [ABSTRACT FROM AUTHOR]

Published

2024

29. Efficient Pipeline Conflict Resolution for Layered QC-LDPC Decoders in OFDM-PON.

Author

Wang, Zhijie, Xu, Zhengjun, Chen, Kun, Qu, Yuanzhe, Liu, Xiaoqun, Li, Yingchun, and Zhang, Junjie

Subjects

FORWARD error correction, LOW density parity check codes, CONFLICT management, OPTICAL communications, ORDER picking systems

Abstract

The high standard of communication quality in optical access networks makes forward error correction (FEC) schemes, such as LDPC, an integral part of the system. However, pipeline conflict arising from data dependencies is a common issue encountered in the hardware implementation of layered QC-LDPC decoders. This paper proposes an efficient layered decoding architecture to reduce pipeline conflicts without introducing stall cycles. It can solve some of the pipeline conflicts by flexibly reordering the processing order of inter-layer and intra-layer submatrices offline. In addition, the patch method, based on variable-to-check messages, allows for the delayed use of gains between layer iterations, which can further minimize the performance loss caused by the remaining pipeline conflicts. The experimental results on the LDPC code of the IEEE802.16 standard in the OFDM-PON system demonstrate that the proposed architecture has sensitivity improvements of 0.125 dBm and 0.375 dBm, respectively, compared with our previous work and the method described in the other work. The optimized architecture improves the reliability of the decoder and can also make a contribution to efficient PON systems. [ABSTRACT FROM AUTHOR]

Published

2024

30. Experimental Study of Fast Orthogonal Frequency Division Multiplexing Transmission over a Random Media Channel for Optical Wireless Communications.

Author

Zhang, Lu and Chen, Yanan

Subjects

ORTHOGONAL frequency division multiplexing, OPTICAL communications, WIRELESS communications, WIRELESS channels, FORWARD error correction, ATMOSPHERIC turbulence

Abstract

In this paper, a 4 amplitude shift keying (4-ASK) fast orthogonal frequency division multiplexing (FOFDM) scheme was experimentally investigated over a turbulent air–water channel for optical wireless communications. The experiment results showed that the 4-ASK-FOFDM modulated signals were not sensitive to weak atmospheric turbulence, and the bit-error rate (BER) was lower than the 7% forward error correction (FEC) limit of 3.8 × 10−3. Under the condition of the same spectra efficiency, the 4-ASK-FOFDM scheme just had a tiny performance penalty compared to the 16-QAM-OFDM scheme. Consequently, the 4-ASK-FOFDM scheme is a promising alternative to the conventional 16-QAM-OFDM scheme in optical wireless communications. [ABSTRACT FROM AUTHOR]

Published

2024

31. Modulation Format Identification Based on Multi-Dimensional Amplitude Features for Elastic Optical Networks.

Author

Hao, Ming, He, Wei, Jiang, Xuedong, Liang, Shuai, Jin, Wei, Chen, Lin, and Tang, Jianming

Subjects

FORWARD error correction, K-nearest neighbor classification, OPTICAL dispersion, SIGNAL-to-noise ratio, COMPUTATIONAL complexity

Abstract

A modulation format identification (MFI) scheme based on multi-dimensional amplitude features is proposed for elastic optical networks. According to the multi-dimensional amplitude features, incoming polarization division multiplexed (PDM) signals can be identified as QPSK, 8QAM, 16QAM, 32QAM, 64QAM and 128QAM signals using the k-nearest neighbors (KNNs) algorithm in the digital coherent receivers. The proposed scheme does not require any prior training or optical signal-to-noise ratio (OSNR) information. The performance of the proposed MFI scheme is verified based on numerical simulations with 28GBaud PDM-QPSK/-8QAM/-16QAM/-32QAM/-64QAM/-128QAM signals. The results show that the proposed scheme can achieve 100% of the correct MFI rate for all six modulation formats when the OSNR values are greater than their thresholds corresponding to the 20% forward error correction (FEC) related to a BER of 2.4 × 10−2. Meanwhile, the effects of residual chromatic dispersion, polarization mode dispersion and fiber nonlinearities on the proposed scheme are also explored. Finally, the computational complexity of the proposed scheme is analyzed, which is compared with relevant MFI schemes. The work indicates that the proposed technique could be regarded as a good candidate for identifying modulation formats up to 128QAM. [ABSTRACT FROM AUTHOR]

Published

2024

32. Light-Field Optimization of Deep-Ultraviolet LED Modules for Efficient Microbial Inactivation.

Author

Huang, Jiaxin, Wang, Qingna, Ye, Xiaofang, Li, Wenxiang, Cheng, Keyang, Qu, Shanzhi, Kang, Wenyu, Yin, Jun, and Kang, Junyong

Subjects

MICROBIAL inactivation, ELECTRIC power consumption, OPTICAL measurements, LIGHT emitting diodes, POWER density, FORWARD error correction, POLARITONS

Abstract

Public awareness of preventing pathogenic microorganisms has significantly increased. Among numerous microbial prevention methods, the deep-ultraviolet (DUV) disinfection technology has received wide attention by using the nitride-based light-emitting diode (LED). However, the light extraction efficiency of DUV LEDs and the utilization rate of emitted DUV light are relatively low at the current stage. In this study, a light distribution design (referred to as the reflective system) was explored to enhance the utilization of emitted DUV from LEDs, leading to successful and efficient surface and air disinfection. Optical power measurements and microbial inactivation tests demonstrated an approximately 79% improvement in average radiation power density achieved by the reflective system when measured at a 5 cm distance from the irradiation surface. Moreover, a statistically significant enhancement in local surface disinfection was observed with low electric power consumption. The reflective system was integrated into an air purifier and underwent air disinfection testing, effectively disinfecting a 3 m3 space within ten minutes. Additionally, a fluorine resin film at the nanolevel was developed to protect the light module from oxidation, validated through a 1200 h accelerated aging test under humid conditions. This research offers valuable guidance for efficient and energy-saving DUV disinfection applications. [ABSTRACT FROM AUTHOR]

Published

2024

33. An Efficient Design for the DVB-S2 Forward Link System Outer Layer Encoding Based on PCC Turbo Coding Across Fading Channel.

Author

Salih, Omar M. and Hameed, Ashwaq Q.

Subjects

TURBO codes, FORWARD error correction, DIGITAL video broadcasting, LOW density parity check codes, CHANNEL coding, TRANSMITTING antennas

Abstract

Copyright of Journal of Engineering (17264073) is the property of Republic of Iraq Ministry of Higher Education & Scientific Research (MOHESR) and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

34. Passive frequency comb generation at radiofrequency for ranging applications.

Author

Hussein, Hussein M. E., Kim, Seunghwi, Rinaldi, Matteo, Alù, Andrea, and Cassella, Cristian

Subjects

PARAMETRIC oscillators, RADIO frequency, QUALITY factor, CRYSTAL resonators, SPECTRAL lines, AUTONOMOUS vehicles, FORWARD error correction

Abstract

Optical frequency combs, featuring evenly spaced spectral lines, have been extensively studied and applied to metrology, signal processing, and sensing. Recently, frequency comb generation has been also extended to MHz frequencies by harnessing nonlinearities in microelectromechanical membranes. However, the generation of frequency combs at radio frequencies (RF) has been less explored, together with their potential application in wireless technologies. In this work, we demonstrate an RF system able to wirelessly and passively generate frequency combs. This circuit, which we name quasi-harmonic tag (qHT), offers a battery-free solution for far-field ranging of unmanned vehicles (UVs) in GPS-denied settings, and it enables a strong immunity to multipath interference, providing better accuracy than other RF approaches to far-field ranging. Here, we discuss the principle of operation, design, implementation, and performance of qHTs used to remotely measure the azimuthal distance of a UV flying in an uncontrolled electromagnetic environment. We show that qHTs can wirelessly generate frequency combs with μWatt-levels of incident power by leveraging the nonlinear interaction between an RF parametric oscillator and a high quality factor piezoelectric microacoustic resonator. Our technique for frequency comb generation opens new avenues for a wide range of RF applications beyond ranging, including timing, computing and sensing. In contrast to the commonly studied optical frequency combs, here, the authors demonstrate a radio frequency system able to wirelessly and passively generate frequency combs as a battery-free solution for far-field ranging of unmanned vehicles in GPS-denied settings. [ABSTRACT FROM AUTHOR]

Published

2024

35. Simulation Validation of an 8-Channel Parallel-Transmit Dipole Array on an Infant Phantom: Including RF Losses for Robust Correlation with Experimental Results.

Author

Clément, Jérémie Daniel and Ipek, Özlem

Subjects

REFLECTANCE, INFANTS, FORWARD error correction, SIMULATION methods & models

Abstract

It is crucial to demonstrate a robust correlation between the simulated and manufactured parallel-transmit (pTx) arrays performances to release the currently-used, very restrictive safety margins. In this study, we describe the qualitative and quantitative validation of a simulation model with respect to experimental results for an 8-channel dipole array at 7T. An approach that includes the radiofrequency losses into the simulation model is presented and compared to simulation models neglecting these losses. Simulated S-matrices and individual B1+-field maps were compared with experimentally measured quantities. With the proposed approach, an average relative difference of ~1.1% was found between simulated and experimental reflection coefficients, ~4.2% for the 1st coupling terms, and ~9.4% for the 2nd coupling terms. A maximum normalized root-mean-square error of 4.8% was achieved between experimental and simulated individual B1+-field maps. The effectiveness of the simulation model to accurately predict the B1+-field patterns was assessed, qualitatively and quantitatively, through a comparison with experimental data. We conclude that, using the proposed model for radiofrequency losses, a robust correlation is achieved between simulated and experimental data using the 8-channel dipole array at 7T. [ABSTRACT FROM AUTHOR]

Published

2024

36. Micro-Satellite Systems Design, Integration, and Flight.

Author

Naumann, Philip and Sands, Timothy

Subjects

NANOSATELLITES, SYSTEMS design, AEROSPACE engineering, AEROSPACE engineers, SYSTEMS engineering, MICROSPACECRAFT

Abstract

Within the past decade, the aerospace engineering industry has evolved beyond the constraints of using single, large, custom satellites. Due to the increased reliability and robustness of commercial, off-the-shelf printed circuit board components, missions have instead transitioned towards deploying swarms of smaller satellites. Such an approach significantly decreases the mission cost by reducing custom engineering and deployment expenses. Nanosatellites can be quickly developed with a more modular design at lower risk. The Alpha mission at the Cornell University Space Systems Studio is fabricated in this manner. However, for the purpose of development, the initial proof of concept included a two-satellite system. The manuscript will discuss system engineering approaches used to model and mature the design of the pilot satellite. The two systems that will be primarily focused on are the attitude control system of the carrier nanosatellite and the radio frequency communications on the excreted femto-satellites. Milestones achieved include ChipSat to ChipSat communication, ChipSat to ground station communication, packet creation, error correction, appending a preamble, and filtering the signal. Other achievements include controller traceability/verification and validation, software rigidity tests, hardware endurance testing, Kane damper, and inertial measurement unit tuning. These developments matured the technological readiness level (TRL) of systems in preparation for satellite deployment. [ABSTRACT FROM AUTHOR]

Published

2024

37. Phase Change Materials‐Based Bilayer Metasurfaces for Near‐Infrared Photonic Routing.

Author

Li, Chensheng, Du, Shuo, Pan, Ruhao, Xiong, Xiaoyu, Tang, Zhiyang, Zheng, Ruixuan, Liu, Yunan, Geng, Guangzhou, Sun, Jingbo, Gu, Changzhi, Guo, Haiming, and Li, Junjie

Subjects

AMPLITUDE modulation, AMORPHOUS silicon, COHERENCE (Optics), INTEGRATED circuits, OPTICAL modulation, FREE-space optical technology, OPTICAL communications, FORWARD error correction

Abstract

Photonic routing holds immense significance in the fields of photonic integrated circuits (PICs) for free‐space optical linking. The emergence of programmable metasurfaces with powerful phase regulation capability provides a promising strategy for achieving designated wavefront modulation and thus photonic routing in the optical communication waveband. Here, a bilayer metasurfaces with four‐level codable unit pixels, which realize controllable photonic routing in near‐infrared (NIR) region is reported. The unit pixel of the metasurfaces consists of the underneath amorphous silicon (α‐Si) nanofin and the upper Ge2Sb2Te5 (GST) nano‐antenna, which contribute to the cross‐polarization generation and amplitude modulation of cross‐polarization light, respectively. Each unit pixel can be designated with desired states, thus achieving on‐demand non‐volatile photonic routing for coherent NIR light. In particular, polarization conversion modulation of the tunable metasurfaces comprising identical unit cell with large cross‐polarization switching (≈55%) at ≈1550 nm is demonstrated. Moreover, the metasurfaces with coded unit pixels to realize designated photonic routing are prototyped. The metasurfaces with four‐level programmability portend a new paradigm in NIR photonic routing for PICs. [ABSTRACT FROM AUTHOR]

Published

2024

38. Enhancing Computational Efficiency in Event-Based Optical Camera Communication Using N-Pulse Modulation.

Author

Aranda, Jaime, Guerra, Victor, Rabadan, Jose, and Perez-Jimenez, Rafael

Subjects

FORWARD error correction, PIXELS, DIGITAL cameras, OPTICAL modulation, OPTICAL communications, WIRELESS communications, CAMERAS

Abstract

Event cameras are bio-inspired devices that have revolutionized the acquisition of visual information by mimicking the neural architecture of the eye. These cameras respond asynchronously to changes in scene illumination at the pixel level, providing high-precision time information with low latency, typically in the order of microseconds. In this work, we experimentally evaluate an optical camera communication (OCC) link using an LED-based transmitter and an event camera as the receiver. We propose n-pulse modulation to encode data, adapting the system to the specific characteristics and operational principles of event cameras. The proposed scheme significantly reduces the demodulation complexity compared to other alternatives found in the literature. Furthermore, a set of experiments considering different camera bias sensitivities, encoding duty cycles, and LED radiant fluxes were carried out. The results showed that the BER performance was strongly dependent on the received optical power and the bias sensitivity. In addition, duty cycles between 0.3 and 0.7 at a 200 Hz transmission frequency presented the best performance, with a BER below 1.25 × 10 − 4 , which is under the forward error correction (FEC) limit. This work showcases the cutting-edge capabilities of event-camera-based OCC technology and contributes to the ongoing revolution in optical wireless communication (OWC). [ABSTRACT FROM AUTHOR]

Published

2024

39. Red Fluorescence Enhancement and Optical Communication Performance of CuI Crystals Grown in HI Solution.

Author

Ling, Qilong, Yang, Hongyu, Liu, Ping, Lv, Yanfei, Li, Jingzhou, Xi, Junhua, Fu, Li, Chen, Fei, Zhang, Rui, and Zhao, Shichao

Subjects

FORWARD error correction, FLUORESCENCE, OPTICAL communications, BIT error rate, CUPROUS iodide, FLUORESCENCE quenching

Abstract

The photoluminescence (PL) of cuprous iodide (CuI) has drawn significant attention in the scientific community. In order to investigate the growth methods and environmental conditions on the fluorescence, we first prepared CuI via immersion of copper in hydroiodic acid. This method is beneficial for the growth of large grains (> 20 μm) with intensive red fluorescence emission at 708 nm. The fluorescence has a high quantum yield (34 %), and superior stability. Then we studied the fluorescence behaviors in water. We observed fluorescence quenching, which is due to the energy transfer. Additionally, we studied the effect of temperature on the fluorescence. We found that the fluorescence intensity increased initially then decreased as the temperature increased. The underlying mechanism was analyzed in terms of fluorescence quencher (water) removal and thermal quenching. By controlling heating, we successfully obtained intensive and pure red fluorescence. Finally, we explored the potential application of the red fluorescent of CuI in optical communication. The results demonstrate bit error rates within permissible range of forward error correction, highlighting the superior performance of CuI in optical communication systems. [ABSTRACT FROM AUTHOR]

Published

2024

40. A double-layer high-transmission terahertz linear-to-circular polarization converter.

Author

Wu, JiangHao, Syed, Mohsin Ali Shah, Qi, Limei, Tao, Xiang, Yang, Jun, and Wen, Lue

Subjects

FORWARD error correction, MEASUREMENT

Abstract

A double-layer broadband high-transmission terahertz linear-to-circular polarization metasurface is experimentally demonstrated in frequencies between 0.46 and 0.62 THz. The measured results show a good agreement with the simulations. The values of co-polarization transmission coefficients T x x and T y y remain above 0.82 in both simulation and experiment, and the simulated and measured axial ratio is 26.2% and 29.6%, respectively. Moreover, the experimental ellipticity remains above 0.98 in the region from 0.5 to 0.62 THz. The average measured polarization conversion ratio is 0.68. The multi-reflection and transmission interference model is used to explain the physical mechanism of polarization conversion. The proposed structure could be used in terahertz transmission and detection because of its stable, high ellipticity and transmittance. [ABSTRACT FROM AUTHOR]

Published

2022

41. Google takes a quantum leap.

Author

Sparkes, Matthew

Subjects

QUANTUM computing, FORWARD error correction, QUANTUM states, QUBITS, PERSONAL computers, QUANTUM computers

Abstract

Google has made a breakthrough in error correction for quantum computers, which could allow for the development of larger and more practical machines. Quantum computers are more prone to errors than traditional computers, but Google's research has found a way to reduce errors faster than they are introduced. In experiments, Google was able to pass the breakeven point, or threshold, with a 72-qubit processor and a 105-qubit processor, each acting as a single logical qubit. However, significant hurdles remain, and scaling up quantum computers will require a large number of physical qubits. [Extracted from the article]

Published

2024

42. Geometrically Shaped Odd-Bit QAM Constellations Suitable for Principal Component-Based Phase Estimation.

Author

Wang, Xishuo, Lv, Kai, Zhang, Qi, Zhu, Lei, and Xin, Xiangjun

Subjects

FORWARD error correction, QUADRATURE amplitude modulation, OPTICAL communications, MONTE Carlo method, CONSTELLATIONS

Abstract

For high-speed optical communication systems, laser phase noise (LPN) stands as a pivotal factor influencing the quality of the received signal. Therefore, the employment of a highly accurate carrier phase recovery (CPR) algorithm at the receiving end is indispensable to ensure the reliability of transmission. While a CPR algorithm called principal component-based phase estimation (PCPE) has been proven to be capable of achieving low-complexity and high-performance phase recovery for even-bit quadrature amplitude modulation (QAM) (i.e., square QAM) signals, it is not compatible with traditional cross-shaped odd-bit QAM signals. To circumvent this problem, a signal constellation design scheme based on geometric shaping (GS) is proposed. The pair-wise optimization (PO) algorithm is used to optimize the constellation structure of 32QAM and 128QAM signals in order to obtain results that are compatible with the PCPE algorithm. Monte Carlo simulation results reveal that for odd-bit QAM signals utilizing PCPE for phase recovery, the proposed GS constellations enhance the mutual information (MI) performance across the entire measured signal-to-noise (SNR) range. Moreover, compared with regular 32QAM and 128QAM constellations using the well-known blind phase search (BPS) algorithm, the proposed GS and PCPE scheme can achieve SNR gains of 1.10 dB and 2.59 dB, respectively, when considering the 20% soft-decision forward error correction (SD-FEC) overhead. Verification through commercial simulation software corroborates these findings, demonstrating that the proposed GS constellations are particularly suitable for the PCPE algorithm, especially under conditions of high optical signal-to-noise ratio (OSNR). To the best of our knowledge, this is the first time that the incompatibility between the PCPE algorithm and odd-bit QAM signals has been investigated, and the proposed GS scheme has broadened the application scope of the low-complexity CPR algorithm. [ABSTRACT FROM AUTHOR]

Published

2024

43. A full duplex LG modes enabled millimeter-wave based FSO communication system for disaster zone.

Author

Iqbal, Saeed, Raza, Aadil, Kaleem, Mohammad, Iqbal, Muhammad, Adeel, Muhammad, and Ghafoor, Salman

Subjects

DIFFERENTIAL phase shift keying, TELECOMMUNICATION systems, FORWARD error correction, SEARCH & rescue operations, HETERODYNE detection, EMERGENCY communication systems, MOBILE communication systems, FREE-space optical technology

Abstract

Free space optical (FSO) communication is a wireless alternative to fiber-based communication as it may provide a backbone emergency communication link in disaster-hit areas. This paper proposes a full duplex millimeter wave (mm-wave) enabled FSO system to provide a high data rate communication link for search and rescue operations. The proposed system consists of a central unit which is connected to multiple unmanned aerial vehicles (UAVs) through an optical-amplify and forward relay over an FSO channel represented by Log-Normal channel model. An optical comb is generated and Laguerre-Gaussian modes of each wavelength of the optical comb are exploited to carry 10 Gbps differential phase shift keying modulated signals. 60 GHz mm-wave signals are generated at the remote UAVs by employing optical heterodyne detection for downlink transmission towards the user equipment. For the uplink transmission, a dedicated wavelength is used to carry 10 Gbps on-off keying baseband data for live streaming of the disaster-hit area. Furthermore, a single hop scheme is employed to counter the non-line of sight issue of the FSO link. The performance of the proposed model is evaluated under different weather conditions and refractive index structure parameter values. A maximum distance of 3.3 km is achieved for clear sky under low turbulence conditions. Moreover, the effect of misalignment due to hovering of the UAVs on the system performance is also investigated and tolerance in the x (horizontal) and y (vertical) directions is observed at the forward error correction BER limit of 10 - 9 . The simulation results reveal that the proposed system has the potential to provide reliable and quick emergency communication services in disaster-struck areas. [ABSTRACT FROM AUTHOR]

Published

2024

44. Reduction of Blocking Probability in Generalized Multi-Protocol Label Switched Optical Networks.

Author

Dhawan, Monika, Singh, Simranjit, and Wason, Amit

Subjects

SWITCHING systems (Telecommunication), PROBABILITY theory, FORWARD error correction, QUALITY of service, BLOCK codes

Abstract

The blocking probability is studied for improving the quality of service of the network. The call blocking model for mode of operation to determine the types of applications suitable for Generalized Multi-Protocol Label Switched (GMPLS) networks is proposed. The performance of optical network depends upon various parameters such as number of channels, number of sources, traffic intensity which directly affect the blocking probability of the network. A mathematical model of an optical network for blocking probability of cleared calls and holding calls is developed. In the proposed model, blocking probability of the network gets reduced with a large number of servers. The proposed models decrease the blocking probability of the network to a level of 10–40. In addition, the blocking performance for held calls is also analyzed to compare the amount of traffic intensity that can be handled and completed properly with that of the cleared calls probability. The blocking probability is less for cleared calls than that for held calls as more traffic intensity can be handled in case of cleared calls but the chances for call completion increases in case of held calls. [ABSTRACT FROM AUTHOR]

Published

2024

45. Dual polarized optical multi‐input multi‐output transmission over 7‐core few‐mode fiber using adaptive recursive least squares constant modulus algorithm.

Author

Khalid, Hafiz A. and Ullah, Sibghat

Subjects

LIGHT transmission, MIMO systems, DATA transmission systems, FORWARD error correction, ALGORITHMS, FIBERS

Abstract

We describe a system with multi‐input multi‐output (MIMO) transmission over 7‐core few‐mode fiber (FMF) by incorporating polarization division multiplexing and mode division multiplexing. Three optical modes with x and y polarizations were used for 42 × 42 MIMO transmission over 7‐core FMF. We simulate the optical MIMO transmission at 20 Gbps with quadrature phase‐shift keying signals. By using the adaptive recursive least squares constant modulus algorithm (RLSCMA) at the receiver side, transmission data is successfully recovered by mitigating the effects of modal delay and mode coupling of received signals. The simulation results show that adaptive RLSCMA can improve the system performance of optical MIMO transmission systems. [ABSTRACT FROM AUTHOR]

Published

2024

46. Machine Learning Algorithm Estimation and Comparison of Live Network Values of the Inputs Which Have the Most Effect on the FEC Parameter in DWDM Systems.

Author

YÜCEL, Murat, OSMANCA, Mustafa Serdar, and MERCİMEK, I. Fatih

Subjects

MACHINE learning, FORWARD error correction, WAVELENGTH division multiplexing, PARAMETER estimation, DECISION trees

Abstract

Copyright of Journal of Polytechnic is the property of Journal of Polytechnic and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

47. An empirical analysis of concatenated polar codes for 5G wireless communication.

Author

Radha, N. and Maheswari, M.

Subjects

WIRELESS communications, FORWARD error correction, BIT error rate, CHANNEL coding, GRAY codes, BINARY codes

Abstract

This paper aims to explore the potential benefits and performance enhancements of combining a novel error correction code with polar codes through serial and parallel concatenation. The BGCC-EDAC (Binary to Gray Code Conversion Based Error Detection and Correction) code is a novel forward error correction code that functions as a channel coding technique. It has shown promising results in effectively detecting and correcting errors. This study presents an empirical analysis of the application of serial concatenation of BGCC-EDAC-aided polar code (SC-BPC) and parallel concatenation of BGCC-EDAC-aided polar code (PC-BPC). The simulation results obtained using Cadence 90 nm technology demonstrate that the SC-BPC and PC-BPC architectures presented in this study require fewer hardware resources compared to the other error correction codes currently available. The empirical analysis conducted using MATLAB demonstrates that the proposed codes exhibit a significant performance improvement compared to CRC-aided polar codes. The PC-BPC code proposed in this study exhibits a slight enhancement of 0.18 dB compared to the parallel concatenation technique of CRC-aided polar codes at a bit error rate of 10−4. Similarly, the SC-BPC code introduced in this research displays an identical improvement of 0.3dB when compared to the serial concatenation approach with CRC-aided polar codes at the same BER level. The PC-BPC and SC-BPC architectures are expected to be widely adopted in 5G wireless communication systems due to their advantageous features such as low latency, high throughput, and improved BER performance. [ABSTRACT FROM AUTHOR]

Published

2024

48. The strain gap in a system of weakly and strongly interacting two-level systems.

Author

Churkin, A., Gabdank, I., Burin, A. L., and Schechter, M.

Subjects

NUCLEAR spin, BAND gaps, ELECTRONIC systems, GAUSSIAN function, AMORPHOUS substances, FORWARD error correction, HYPERFINE interactions, HYPERFINE structure

Abstract

Many disordered lattices exhibit remarkable universality in their low-temperature properties, similar to that found in amorphous solids. Recently, a two-TLS (two-level system) model was derived based on the microscopic characteristics of disordered lattices. Within the two-TLS model, the quantitative universality of phonon attenuation, and the energy scale of 1–3K below which universality is observed, are derived as a consequence of the existence of two types of TLSs, differing by their interaction with the phonon field. In this paper, we calculate analytically and numerically the densities of states (DOS) of the weakly and strongly interacting TLSs. We find that the DOS of the former can be well described by a Gaussian function, whereas the DOS of the latter have a power-law correlation gap at low energies, with an intriguing dependence of the power on the short distance cutoff of the interaction. Both behaviors are markedly different from the logarithmic gap exhibited by a single species of interacting TLSs. Our results support the notion that it is the weakly interacting τ -TLSs that dictate the standard low-temperature glassy physics. Yet, the power-law DOS we find for the S-TLSs enables the prediction of a number of deviations from the universal glassy behavior that can be tested experimentally. Our results carry through to the analogous system of electronic and nuclear spins, implying that electronic spin flip rate is significantly reduced at temperatures smaller than the magnitude of the hyperfine interaction. [ABSTRACT FROM AUTHOR]

Published

2023

49. Obstacle-tolerant terahertz wireless link using self-healing Bessel beams.

Author

Katsuue, Yu, Yabuki, Ayumu, Morohashi, Isao, Kanno, Atsushi, Sekine, Norihiko, Nakajima, Junichi, and Hisatake, Shintaro

Subjects

BESSEL beams, FORWARD error correction, BIT error rate, GAUSSIAN beams, WIRELESS communications

Abstract

Wireless communications using highly directive terahertz (THz) waves exhibit lower immunity to obstructions than microwaves, limiting their applications. This study demonstrates an obstacle-tolerant THz wireless link established by a self-healing Bessel beam at 300 GHz. The Bessel beam is generated by sending a Gaussian beam through a dielectric axicon lens. Furthermore, experiments were conducted to investigate the short-range transmission (98 mm) reception characteristics with and without the dielectric cubic obstacle (7.5 λ in size) and the metallic obstacle (22 λ in length and 8 λ in width) in the Gaussian beam and self-healing Bessel beam cross sections. The maximum attenuation of the received power due to obstruction was 8.8 and 2.2 dB for the Gaussian and Bessel beams, respectively, when the dielectric obstacle is placed in the middle of the transmission path (49 mm from a transmission lens). This study further investigated the bit error rate (BER) characteristics (1 Gbps, on–off keying) with the dielectric obstacle crossing the beam cross section. When the obstacle crosses the Gaussian beam, the BER degrades as the obstacle approaches the optical axis, breaking the wireless link. In contrast, when the obstacle crosses the Bessel beam cross section, the BER is maintained at <3.8 × 10−3 (the forward error correction limit), and the wireless link is maintained. A self-healing beam, such as the Bessel beam, makes the THz wireless link more tolerant than the Gaussian beam to obstacle and expand applications for THz wireless communications. [ABSTRACT FROM AUTHOR]

Published

2023

50. Experimental results on nonlinear distortion compensation using photonic reservoir computing with a single set of weights for different wavelengths.

Author

Gooskens, Emmanuel, Sackesyn, Stijn, Dambre, Joni, and Bienstman, Peter

Subjects

FORWARD error correction, BIT error rate, WAVELENGTH division multiplexing, SIGNAL processing, DELAY lines, COMPUTING platforms

Abstract

Photonics-based computing approaches in combination with wavelength division multiplexing offer a potential solution to modern data and bandwidth needs. This paper experimentally takes an important step towards wavelength division multiplexing in an integrated waveguide-based photonic reservoir computing platform by using a single set of readout weights for up to at least 3 ITU-T channels to efficiently scale the data bandwidth when processing a nonlinear signal equalization task on a 28 Gbps modulated on-off keying signal. Using multiple-wavelength training, we obtain bit error rates well below that of the 1.5 × 10 - 2 forward error correction limit at high fiber input powers of 18 dBm, which result in high nonlinear distortion. The results of the reservoir chip are compared to a tapped delay line filter and clearly show that the system performs nonlinear equalization. This was achieved using only limited post processing which in future work can be implemented in optical hardware as well. [ABSTRACT FROM AUTHOR]

Published

2023