Your search keyword '"delay spread"' showing total 4,953 results

1. New indoor propagation model proposed for future B5G/6G rollout.

Author

Bagayogo, Mamadou, Hamouda, Soumaya, and Barrak, Rim

Subjects

MILLIMETER waves, RAINFALL, ANTENNAS (Electronics)

Abstract

The rollout of the fifth-generation (5G) mobile network was completed in 2020. Now, the focus shifts towards exploring the new perspectives of Beyond 5G (B5G) and 6G. Despite being a key enabler of 5G, millimeter wave technology has not yet been fully implemented due to various deployment challenges. Over the past decade, numerous efforts have been dedicated to modeling the propagation channel across the spectrum from 0.5 to 100 GHz. Propagation models such as Close-In (CI), Floating Intercept (FI), and single frequency Alpha-Beta-Gamma (ABG) have been extensively utilized. However, a significant deviation between co- and cross-polarization models has been observed in many estimated models in the literature. In this paper, we propose an optimization of the classic CI model by considering both TX and RX antenna heights, along with a correction coefficient. Initially, we estimate the propagation channel using the classic CI model in indoor environments, revealing a notable deviation between co- and cross-polarization models. Subsequently, we introduce a new model aimed at reducing this deviation and optimizing the Path Loss Exponent (PLE). With our proposed model, the estimated channel depolarization in Line-of-Sight (LOS) conditions stands at 2.8 dB, 5.6 dB, and 2.9 dB for room, corridor, and stairwell environments, respectively. In contrast, utilizing the conventional model yields channel depolarization figures of 4.8 dB, 8.2 dB, and 7 dB for the same environments. This disparity in channel depolarization can have significant implications for millimeter wave propagation, particularly during meteorological events such as rainfall. [ABSTRACT FROM AUTHOR]

Published

2024

2. Comprehensive FR1(C) and FR3 Lower and Upper Mid-Band Propagation and Material Penetration Loss Measurements and Channel Models in Indoor Environment for 5G and 6G

Author

Dipankar Shakya, Mingjun Ying, Theodore S. Rappaport, Hitesh Poddar, Peijie Ma, Yanbo Wang, and Idris Al-Wazani

Subjects

3GPP, 5G, 6G, angular spread, CI path loss, delay spread, Telecommunication, TK5101-6720, Transportation and communications, HE1-9990

Abstract

Wide bandwidth requirements for multi-Gbps communications have prompted the global telecommunications industry to consider new mid-band spectrum allocations in the 4–8 GHz FR1(C) and 7–24 GHz FR3 bands, above the crowded bands below 6 GHz. Allocations in the lower and upper mid-band aim to balance coverage and capacity, but there is limited knowledge about the radio propagation characteristics in the 4–24 GHz frequency bands. Here we present the world’s first comprehensive indoor propagation measurement and channel modeling study at 6.75 GHz and 16.95 GHz in mid-band spectrum conducted at the NYU WIRELESS Research Center spanning distances from 11–97 m using 31 dBm EIRP transmit power with 15 and 20 dBi gain rotatable horn antennas at 6.75 GHz and 16.95 GHz, respectively. Analysis of the omnidirectional and directional propagation path loss using the close-in free space model with 1 m reference distance reveals a familiar waveguiding effect in indoor environments for line-of-sight (LOS). Compared to mmWave frequencies, the omnidirectional LOS and non-LOS (NLOS) path loss exponents (PLE) are similar, when using a close-in 1 m free space path loss reference distance model. Observations of the omnidirectional and directional RMS delay spread (DS) at FR1(C) and FR3 as compared to mmWave and sub-THz frequencies indicate decreasing RMS DS as the carrier frequency is increased. The RMS angular spreads (AS) at 6.75 GHz are found to be wider compared to 16.95 GHz, showing greater number of multipath components from a broader set of directions in the azimuthal spatial plane when compared to higher frequencies. This work also presents results from extensive material penetration loss measurements at 6.75 GHz and 16.95 GHz using co and cross polarized antenna configurations for ten common construction materials found inside buildings and on building perimeters, including concrete walls, low-emissivity glass, wood, doors, drywall, and whiteboard. Our findings show penetration loss increases with frequency for all of the ten materials and partitions tested, and suggest further investigation of 3GPP material penetration loss models for at least infrared reflective (IRR) glass and concrete may be necessary. The empirical data and resulting models for radio propagation and penetration loss presented in this paper provide critical information for future 5G and 6G wireless communications.

Published

2024

3. Realistic Channel and Delay Coefficient Generation for Dual Mobile Space-Ground Links: A Tutorial

Author

Hongzhao Zheng, Mohamed Atia, and Halim Yanikomeroglu

Subjects

Channel coefficient, delay spread, Doppler spectrum, multipath, quasi deterministic radio channel generator (QuaDRiGa), state duration, Transportation engineering, TA1001-1280, Transportation and communications, HE1-9990

Abstract

Channel and delay coefficient are two essential parameters for the characterization of a multipath propagation environment. It is crucial to generate realistic channel and delay coefficient in order to study the channel characteristics that involves signals propagating through environments with severe multipath effects. While many deterministic channel models, such as ray-tracing (RT), face challenges like high computational complexity, data requirements for geometrical information, and inapplicability for space-ground links, and nongeometry-based stochastic channel models (NGSCMs) might lack spatial consistency and offer lower accuracy, we present a scalable tutorial for the channel modeling of dual mobile space-ground links in urban areas, utilizing the Quasi Deterministic Radio Channel Generator (QuaDRiGa), which adopts a geometry-based stochastic channel model (GSCM), in conjunction with an International Telecommunication Union (ITU) provided state duration model. This tutorial allows for the generation of realistic channel and delay coefficients in a multipath environment for dual mobile space-ground links. We validate the accuracy of the work by analyzing the generated channel and delay coefficient from several aspects, such as received signal power and amplitude, multipath delay distribution, delay spread and Doppler spectrum.

Published

2024

4. A Machine Learning Approach to Wireless Propagation Modeling in Industrial Environment

Author

Mohammad Hossein Zadeh, Marina Barbiroli, and Franco Fuschini

Subjects

Delay spread, industrial environment, machine learning, path loss, shadowing, wireless propagation channel, Telecommunication, TK5101-6720

Abstract

Wireless channel properties in industrial environments can differ from residential or office settings due to the considerable impact of heavy machinery that triggers intricate multipath propagation effects and strong blockage effects. Previous investigations on wireless propagation in factories often consisted of empirical models, that is simple analytical formulas based on measurement data. Unfortunately, they usually lack in flexibility, since they seldom include geometrical parameters describing the industrial scenario and therefore turn out reliable only in industrial scenarios sharing the same propagation characteristics as those where the measurements were performed. In response to this limitation, this article harnesses the power of Machine Learning to model propagation markers like path loss, shadowing, and delay spread in the industrial environment. By employing Machine Learning techniques, the objective is to achieve flexibility and adaptability in modeling, enabling the system to effectively generalize across diverse industrial scenarios. The proposed model relies on a combination of predictive algorithms, including a linear regression model and a Multi-Layer Perceptron, working collaboratively to model the relationship between the considered propagation markers and input features like frequency and machine size, spacing, and density. Results are in fair overall agreement with previous studies and highlight some trends about the sensitivity of the propagation parameters to the considered input features.

Published

2024

5. Dependency of Indoor Delay Spread and Path Loss on 5G and 6G Frequencies and Its Simple Formulation

Author

Kawser, Mohammad Tanvir, Ahmed, Zebun Nasreen, Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, and Arai, Kohei, editor

Published

2023

6. Investigation of Characteristics of Underwater Acoustic Channel and Quality of Underwater Acoustic Communication in Line-of-Sight and Non-Line-of-Sight Environments.

Author

Takuya Waki, Yuto Hara, Tadashi Ebihara, Naoto Wakatsuki, and Koichi Mizutani

Subjects

UNDERWATER acoustic communication, SIGNAL-to-noise ratio, WATER depth, ORTHOGONAL frequency division multiplexing, DATA analysis

Abstract

Underwater acoustic (UWA) communication is an essential technology for networking underwater sensors and drones to support maritime activities. However, real-time data transfer among mobile nodes faces technical difficulties due to the severe nature of the UWA channel, which has large delay and Doppler spreads. Furthermore, the performance of UWA communication may be severely impaired by marked channel changes between line-of-sight (LoS) and non-line-of-sight (NLoS) environments. The goal of this work is to explore the UWA channel under LoS and NLoS conditions and evaluate their effect on UWA communication in terms of communication quality. Specifically, we measured the delay and Doppler spreads of the UWA channel by switching LoS/NLoS conditions. We also investigated the relationship between the signal-to-noise ratio (SNR) and bit error rate (BER) for UWA communication using Dopplerresilient orthogonal signal division multiplexing (D-OSDM). Experimental results showed that the delay spread of the UWA channel and received signal power markedly changes depending on LoS/NLoS conditions. Specifically, the delay spread in the LoS environment was about 10 ms, while that in the NLoS environment was much larger or difficult to observe owing to signal power attenuation. Furthermore, SNR in the NLoS environment was approximately 15 dB less than that in the LoS environment, resulting in increased BER. The obtained results suggest that adaptive signal power control is necessary to realize stable UWA communication in shallow water areas where there is a mixture of LoS and NLoS condition. [ABSTRACT FROM AUTHOR]

Published

2023

7. Uncertainty Analysis Methodology for Measurements of Dynamic Millimeter-Wave Channels

Author

Robbert Schulpen, A. Bart Smolders, Ulf Johannsen, and L. A. Bronckers

Subjects

Channel dynamics, channel sounding, delay spread, Doppler spread, millimeter-wave propagation, path loss, Telecommunication, TK5101-6720

Abstract

Quantification of uncertainties in the results of channel sounding measurements is important for their interpretation and further usage. In this paper, a novel uncertainty analysis methodology to quantify uncertainties of condensed parameters in measurements of dynamic millimeter-wave channels is presented. The bandwidth limitation and multipath threshold are identified as important impairments. Therefore, the methodology provides three uncertainty metrics for condensed parameters, namely a standard uncertainty to quantify the impact of random variations; a bias due to the multipath threshold; and a total bias including the impact of the bandwidth limitation. These uncertainty metrics are highly channel dependent. Therefore, the proposed methodology creates reference channels, which are representative of corresponding measured channels. Hardware and processing impairments are included in the analysis via a Monte Carlo simulation. This results in a general methodology that can quantify uncertainties in both static and dynamic channel measurements of any wideband channel sounder. The methodology is implemented, verified and demonstrated for the TU/e channel sounder, which exemplifies how it can be used. The proposed methodology can improve the analysis, interpretation and reporting of channel measurement results.

Published

2023

8. Introduction to Mediumband Wireless Communication

Author

Dushyantha A. Basnayaka

Subjects

Communication theory, multipath, delay spread, wireless channel models, Telecommunication, TK5101-6720, Transportation and communications, HE1-9990

Abstract

The multipath is unavoidable in radio frequency (RF) wireless communication, and affects almost every element of the communication systems. The impact of multipath on the received signal depends on whether the delay spread (i.e., spread of time delays associated with different multipath components) is large or small relative to the symbol period of the wireless communication system. In narrowband channels, the symbol period is set such that the delay spread is about one tenth (or less) of it. In broadband channels, it is set such that the delay spread is many times greater than the symbol period. In between these two extremes, there appears to exist an important, yet overlooked, class of channels whose delay spread is neither small nor large enough for them to fall into these two basic channel classes. In this paper, we study the effect of multipath on channels that fall in the transitional region between narrowband and broadband referred henceforth as “mediumband”. This paper shows that mediumband channels possess a distinct channel model, and pose both challenges and opportunities for reliable wireless communication. For instance, mediumband channels enable signalling at a significantly higher rate than that of narrowband channels, but on the flip side, as the degree of mediumband-ness increases, the quality of the channel deteriorates rapidly due to the excessive inter-symbol-interference (ISI). However, mediumband channels have an inherent ability to avoid deep fading, and if designed properly, mediumband wireless communication, which refers to wireless communication through mediumband channels, could be made to be significantly more reliable too.

Published

2023

9. Research on the Propagation Characteristics of Millimeter Wave Signals in Complicated Enclosed Spaces

Author

Zhang, Shaoqing, Zhang, Liang, Lu, Yi, Ding, Tongyu, Chinese Society of Aeronautics and Astronautics, Angrisani, Leopoldo, Series Editor, Arteaga, Marco, Series Editor, Panigrahi, Bijaya Ketan, Series Editor, Chakraborty, Samarjit, Series Editor, Chen, Jiming, Series Editor, Chen, Shanben, Series Editor, Chen, Tan Kay, Series Editor, Dillmann, Rüdiger, Series Editor, Duan, Haibin, Series Editor, Ferrari, Gianluigi, Series Editor, Ferre, Manuel, Series Editor, Hirche, Sandra, Series Editor, Jabbari, Faryar, Series Editor, Jia, Limin, Series Editor, Kacprzyk, Janusz, Series Editor, Khamis, Alaa, Series Editor, Kroeger, Torsten, Series Editor, Li, Yong, Series Editor, Liang, Qilian, Series Editor, Martín, Ferran, Series Editor, Ming, Tan Cher, Series Editor, Minker, Wolfgang, Series Editor, Misra, Pradeep, Series Editor, Möller, Sebastian, Series Editor, Mukhopadhyay, Subhas, Series Editor, Ning, Cun-Zheng, Series Editor, Nishida, Toyoaki, Series Editor, Pascucci, Federica, Series Editor, Qin, Yong, Series Editor, Seng, Gan Woon, Series Editor, Speidel, Joachim, Series Editor, Veiga, Germano, Series Editor, Wu, Haitao, Series Editor, Zamboni, Walter, Series Editor, and Zhang, Junjie James, Series Editor

Published

2022

10. Radio frequency channel characterization for energy harvesting in factory environments

Author

Adegoke, Elijah

Subjects

621.31, Energy harvesting, Ambient measurements, RF channel modelling, Fractals, Wireless propagation, Delay spread

Abstract

This thesis presents ambient energy data obtained from a measurement campaign carried out at an automobile plant. At the automobile plant, ambient light, ambient temperature and ambient radio frequency were measured during the day time over two days. The measurement results showed that ambient light generated the highest DC power. For plant and operation managers at the automobile plant, the measurement data can be used in system design considerations for future energy harvesting wireless sensor nodes at the plant. In addition, wideband measurements obtained from a machine workshop are presented in this thesis. The power delay profile of the wireless channel was obtained by using a frequency domain channel sounding technique. The measurements were compared with an equivalent ray tracing model in order to validate the suitability of the commercial propagation software used in this work. Furthermore, a novel technique for mathematically recreating the time dispersion created by factory inventory in a radio frequency channel is discussed. As a wireless receiver design parameter, delay spread characterizes the amplitude and phase response of the radio channel. In wireless sensor devices, this becomes paramount, as it determines the complexity of the receiver. In reality, it is sometimes difficult to obtain full detail floor plans of factories for deterministic modelling or carry out spot measurements during building construction. As a result, radio provision may be suboptimal. The method presented in this thesis is based on 3-D fractal geometry. By employing the fractal overlaying algorithm presented, metallic objects can be placed on a floor plan so as to obtain similar radio frequency channel effects. The environment created using the fractal approach was used to estimate the amount of energy a harvesting device can accumulate in a University machine workshop space.

Published

2018

11. Mathematical Model of Time Varying Wireless Channel Model

Author

Gopi, E. S., Celebi, Emre, Series Editor, Chen, Jingdong, Series Editor, Gopi, E. S., Series Editor, Neustein, Amy, Series Editor, Poor, H. Vincent, Series Editor, and Gopi, E.S.

Published

2021

12. Measurement and modeling of wireless body area network propagation characteristics of indoor environment at 10 GHz

Author

Qin YANG, Lihua YANG, Lulu REN, Shanhu HUANG, and Jiahuan LIU

Subjects

wireless body area network, indoor environment, high frequency band, path loss, delay spread, body angle, Information technology, T58.5-58.64, Management information systems, T58.6-58.62

Abstract

To explore the feasibility of high-frequency in indoor wireless body area network (WBAN) communication, the propagation characteristics of 10 GHz for WBAN in indoor scenario was given.Based on a large number of measurement data, the path loss, the shadow effect and the root-based delay spread of the 10 GHz were present, and a novel path loss model with the body angle was proposed, which utilizes the body angular factor to correct the path loss caused by the change of body angle.Meanwhile, the influence of receiving antenna at different heights of body on path loss was analyzed.Research results show that the path loss exponent has a quadratic function relationship with the body angle, the relationship between the path loss (PBA) caused by the body angle and the body angle can be expressed by a trigonometric function with a coefficient, which has a monotonously decreasing exponential function relationship with the distance between the receiving and sending ends.In addition, when the body is at different angles, the effect of the receiving ends in the human body on the path loss is smaller than when there is no body rotation angle.The above research results can provide the theoretical and practical basis for the use of 10 GHz indoor wireless body area network in the future.

Published

2022

13. Measurement and Evaluation of 28 GHz Propagation Characteristics in Specific Environments

Author

Satoshi Ito and Takahiro Hayashi

Subjects

5G mobile communication system, millimeter-wave band, radio wave propagation, path loss, delay spread, angular spread, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

New specific scenarios are expected for 5G systems in various environments, such as stadiums, subway platforms, factories, livestock barns. On the other hand, the applicability of conventional propagation models to new specific environments has not been clarified. In this paper, we report path loss and spatiotemporal characteristics such as delay spread (DS) and azimuth and zenith angular spread of arrival (ASA and ZSA) in the 28 GHz-band in various environments. By comparing the degree of fit to the conventional models, we considered whether the models for conventional scenarios assumed by previous mobile systems can be applied to the propagation characteristics in each specific environment. As a result, we clarify that the following points should be considered when applying the conventional model. The measured path loss characteristics were mostly close to those of the conventional models. However, the path loss in the non-line-of-sight with propagation to another room was larger than the conventional model, assuming there was a hall space environment with some blockers. Regarding the DS, we obtained the results that the characteristics were mainly affected by existence of long-distance delayed wave caused by a long narrow space and materials of the internal walls and ceiling. Larger ASA characteristics were obtained in the subway platform environment and the factory environment because of metallic obstacles and walls. Regarding the ZSA, a larger ZSA was obtained in the stadium due to scattering from spectator seats, and a smaller ZSA was obtained in the subway platform due to the low ceiling height and long propagation distance.

Published

2022

14. Investigation of Small-Scale and Multipath Fading of Radio Wave Propagation in a Complex Building Environment.

Author

Itamakinde, Akinyele A., Ejidokun, Temitayo O., Owolabi, Esan I., Awe, Olusegun P., and Adejumobi, Babatunde S.

Subjects

RADIO wave propagation, MULTIPATH channels, SIGNAL processing software, RADIO transmitter fading, INTERSYMBOL interference

Abstract

In this study, an investigation into the small-scale and multipath fading of radio wave propagation in a complex building environment has been conducted by using Afe Babalola University Ado-Ekiti Nigeria, College of Engineering building as a case study. The study utilizes sliding correlator channel sounding measurement techniques, implemented on NI USRP 2920 modules by using GNU radio software. Moreover, single-input and single-output configurations have been employed by setting one module as a transmitter and the other one as a receiver, propagating at a carrier frequency of 1.2 GHz. Five scenarios within the first floor of the building have been considered and various cases in each one of the scenarios are either outdoor-to-indoor, indoor-to-outdoor, indoor or outdoor measurement. The analysis of the scatter plot of the maximum delay spread against the distance of experiments for the line-of-sight and non-line-ofsight cases show that analytical expression cannot be obtained due to the complexity of the building structure. The result obtained also shows that the maximum delay spread values are between 575 µs and 1023 µs, which points to the existence of a frequency selective fading condition that causes intersymbol interference and data rate reduction. [ABSTRACT FROM AUTHOR]

Published

2022

15. OFDM Signals and Systems Signals and systems

Author

Yang, Sung-Moon Michael and Yang, Sung-Moon Michael

Published

2020

16. Performance Measurements Methodology for LTN IoT Systems

Author

Staniec, Kamil and Staniec, Kamil

Published

2020

17. High-Resolution Delay Spread of Wide-Band Wireless Link in Long Tunnels—Theory and Experimental Verification.

Author

Taragin, Yehuda, Rapaport, Liat, Elkayamn, Niv, Pinhasi, Gad A., and Pinhasi, Yosef

Subjects

TUNNELS, RAY tracing, WIRELESS communications

Abstract

The need for wireless communication appears everywhere, and with as few interruptions as possible. An extensive and in-depth study has been conducted on the limitations of wireless communication in pedestrian tunnels. Using an analytical mathematical ray tracing model, and performing tunnel measurements, with an autonomous measuring setup, the model was validated. An extraordinary wide band was used for the experiments, which also featured optical systems to ensure accurate results. Since the tunnel is narrow, the differences between the different paths are small, and in order to distinguish them a resolution of 0.2 ns was used. The RMS delay spread, σ τ , decreases throughout the tunnel, and at no point exceeds 1 ns. [ABSTRACT FROM AUTHOR]

Published

2022

18. Underwater acoustic positioning in multipath environment using time-of-flight signal group and database matching.

Author

Yoshihara, Tohru, Ebihara, Tadashi, Mizutani, Koichi, and Sato, Yuma

Abstract

One of the challenges in underwater acoustic positioning is the occurrence of missing measurements and large errors in multipath environments, such as shallow water and harbor areas. In this paper, we propose a new underwater positioning method for multipath environments by using direct wave arrival time groups and database matching. The proposed method accurately measures baseline length from the impulse response of the underwater channel by calculating time window groups that cover the propagation time from the sound source to each hydrophone in advance and then extracting only the impulse response around the propagation time of the direct waves when the sound source exists in a certain region of the measurement space. The performance of the proposed method was experimentally evaluated in a static environment. The results showed that the proposed method achieved an accuracy of 0.03 m and a precision of 0.02 m in a test tank. [ABSTRACT FROM AUTHOR]

Published

2022

19. Characterizing in-band full-duplex in broadcast communications: From field trials to a loopback channel model.

Author

Bilbao, Iñigo, Iradier, Eneko, Fernandez, Marta, Montalban, Jon, Angueira, Pablo, Hong, Zhihong Hunter, and Wu, Yiyan

Subjects

*FIELD research, *BROADCAST channels, *BROADCASTING studios, *TRANSMITTING antennas, *RECEIVING antennas, *COGNITIVE radio

Abstract

In-band full duplex (IBFD) communications are a potential solution to spectrum scarcity. IBFD communications offer greater spectral efficiency than traditional half-duplex communications by transmitting and receiving on the same frequency channel. However, IBFD operation requires overcoming the challenge of eliminating the self-interference coupled from the transmit antenna to the receive subsystem. Knowledge of the characteristics of the loopback propagation channel makes it easier to cancel out the self-interference. Nevertheless, complex field trials are required to adequately characterize loopback channels, which is still lacking in the recent literature. This paper proposes a measurement campaign in a real and ongoing broadcast transmission center to characterize the main characteristics of loopback channels. The work proposes a set of loopback channels based on field trials and an empirical analysis of the most relevant parameters of the channel model, such as the Doppler spectrum, the delay spread, and the K-factor. • A new methodology for measuring and characterizing broadcast loopback channels. • Characterizing the loopback channel in terms of the amplitude and the delay of the paths. • An analysis of the obtained delay spread and K-factor values. • Characterizing the Doppler spectrum of the loopback channel in broadcast transmitters. • Performance evaluation of the proposed channel models under an ATSC 3.0 compliant transceiver chain. [ABSTRACT FROM AUTHOR]

Published

2024

20. OFDM Signals and Systems

Author

Michael Yang, Sung-Moon and Michael Yang, Sung-Moon

Published

2019

21. Channel Modeling and Over-the-Air Signal Quality at 3.5 GHz for 5G New Radio

Author

Elijah I. Adegoke, Erik Kampert, and Matthew D. Higgins

Subjects

Path loss, delay spread, EVM, RF propagation, OTA testing, urban environment, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

With the next generation of mobile communication being trialled across the world, 5G New Radio (NR) promises to provide a flexible radio interface that fits a diverse range of use cases. As trials and pilots progress, propagation studies are required that evaluate electromagnetic (EM) propagation effects for 5G NR signals. In this article, 5G NR signals are used to evaluate the over-the-air (OTA) error vector magnitude (EVM) within a line-of-sight (LoS) rural/urban environment. For the same receiver locations, time dispersion and propagation loss were measured via the root mean square (RMS) delay spread and path loss. The transmitter-receiver distance investigated ranged from 60 m to 450 m. From the measurement campaign, the path loss exponent (PLE) using a directional antenna at the receiver was 1.98, and 1.82 with an omnidirectional antenna. The root mean square error (RMSE) of the floating intercept/close-in (FI/CI) models for the path loss was 4.96/4.74 and 3.84/3.23 for directional and omnidirectional receivers. The delay spread using a cross polar configuration showed significant increase and a dependency of the delay spread on the path loss was observed. For the measurement route, the mean delay spread was 24 ns and 35 ns for directional and omnidirectional measurements. With regards to the EVM, 16 and 64-QAM transmissions were robust along the entire route for directional and omnidirectional antennas, whereas 256-QAM worked in locations where there was minimal obstruction to the propagation path. The average EVM (%) for 16, 64 and 256-QAM measured along the route was 4.5/5.3/3.9 and 3.4/4.3/3.6 for omnidirectional and directional antennas. The OTA results also show that using a directional antenna (as the receiver) significantly improves the obtainable signal quality of 5G NR signals and also reduces outages for higher modulation schemes. With the measurement results presented, system designers can design efficient receivers, estimate coverage and adequately provision services using 5G NR on the sub-6 GHz frequency band.

Published

2021

22. Analysis of Intersymbol Interference Characterized by the Large Array Antennas Adopted in a 60-GHz-Band Gigabit Compact-Range Wireless Access System

Author

Miao Zhang, Masahiro Wakasa, Koji Toyosaki, Kiyomichi Araki, Jiro Hirokawa, and Makoto Ando

Subjects

Intersymbol interference, compact-range communication, large array antenna, near-field region, symbol rate, delay spread, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

A compact-range wireless access system in the 60-GHz band has been proposed for multi-Gb/s data transfer. A prototype Gigabit Access Transponder Equipment (GATE) was built to evaluate the system performance in terms of received signal strength, signal-to-noise ratio (SNR), and bit error rate (BER). The proposed system operates in the near-field regions of large array antennas adopted in the transmitter (Tx). The time delays due to the signals transmitted from different array elements to the receiver (Rx), or/and those due to the multiple reflections between Tx and Rx antennas become comparable with the symbol lengths in our gigabit wireless access system. In that sense, this system would be susceptible to intersymbol interference (ISI). In this study, the concept of ISI is introduced in the antenna field for the first time. An equivalent baseband communication system is newly proposed to evaluate the wireless channel, including Tx and Rx antennas. The analysis procedures and equations are provided for the calculation of ISI. The ISIs due to three potential contributions are analyzed in detail. It is verified that our proposed ISI analysis has succeeded in relating the antenna characteristic to the system performance observed in the baseband.

Published

2021

23. Millimeter-Wave Propagation Measurement and Modeling in Indoor Corridor and Stairwell at 26 and 38 GHz

Author

Yuyan Shen, Yu Shao, Liao Xi, Heng Zhang, and Jie Zhang

Subjects

Millimeter-wave, indoor propagation, path loss, cross-polarization discrimination ratio, delay spread, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Accurate propagation characteristics are essential for future indoor millimeter-wave (mmWave) small cell network planning. This paper presents propagation measurements at 26 GHz and 38 GHz which are important candidate bands for fifth generation mmWave communication. Measurements are conducted in an indoor corridor, as well as a stairwell whose mmWave channel is seldom investigated before. In these measurements, an omnidirectional biconical antenna is used as transmitter and a steerable directional horn antenna is used as receiver. The directional and omnidirectional path loss exponents, shadow factors, cross-polarization discrimination ratios and root-mean-square delay spreads are analyzed for both line-of-sight and non-line-of-sight scenarios in both co-polarization and cross-polarization, and these characteristics are compared for different frequencies and environments. It is found obvious depolarization phenomenon in non-line-of-sight scenario for higher frequency. Compared to the corridor, the stairwell has larger path loss exponents and root-mean-square delay spreads, and the depolarization is also more evident in stairwell. The results in this paper are beneficial to building efficient and robust indoor mmWave communication systems.

Published

2021

24. Centimeter and Millimeter-Wave Propagation Characteristics for Indoor Corridors: Results From Measurements and Models

Author

Feyisa Debo Diba, Md Abdus Samad, and Dong-You Choi

Subjects

Path loss models, delay spread, time cluster, mm-wave propagation, artificial intelligence, indoor corridor, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

The millimeter-wave (mm-wave) frequency band is projected to play a critical role in next-generation wireless networks owing to its large available bandwidth. Despite the theoretical potential for high data throughput, the mm-wave frequency faces numerous challenges—including severe path loss and high penetration loss. Therefore, a reliable understanding of channel propagation characteristics is required for the development of accurate and simple indoor communication systems. In this study, we conducted measurement campaigns with unique transmitter- receiver combinations using horn and tracking antennas, at 3.7 and 28 GHz in an indoor corridor environment on the $10^{th}$ floor of an IT building and the $3^{rd}$ floor of the main building of Chosun University, Gwangju, South Korea, and the details are presented herein. In both line-of-sight and non-line-of-sight scenarios, the large-scale path losses, and small-scale channel statistics, such as root mean square delay spread, and number of clusters, were obtained using the measurement results in a waveguide structure indoor corridor environment. We have proposed alternate methodologies beyond classical channel modeling to improve path loss models using artificial neural network (ANN) techniques—to alleviate channel complexity and avoid the time-consuming measurement process. The presented regression successfully assists the prediction of the path loss model in a new operating environment using measurement data from a specific scenario. The validated results suggest that the ANN large-scale path loss model used in this study outperforms the close-in reference distance and floating-intercept (alpha-beta) models. Additionally, our result shows that the number of time clusters follows an Erlang distribution.

Published

2021

25. On the Effect of Multipath Reflections in Indoor Visible Light Communication Links: Channel Characterization and BER Analysis

Author

Rishu Raj, Sonu Jaiswal, and Abhishek Dixit

Subjects

Multipath channel, delay spread, coherence bandwidth, inter-symbol interference, bit error rate, visible light communication, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Owing to its several advantages over other wireless schemes, visible light communication (VLC) shall be at the forefront of optical wireless communication technology. However, due to multipath reflections and spatial distribution of light-emitting diode (LED) transmitters, there is an inherent delay spread in the VLC channels. We perform a comprehensive quantitative study on the effect of several practical factors like LED semi-angle, wall reflectivity, number of reflections, number of LED panels, room size, and user locations on the channel delay parameters, namely RMS delay spread and coherence bandwidth of the channel. We present the detailed derivation of the multipath VLC channel model and incorporate the effect of inter-symbol interference in bit error rate (BER) performance of the multipath VLC system. We analyze the average BER of the system under different practical scenarios and determine the penalty in signal to noise ratio entailed by a change in the system parameters mentioned above. We conclude that it is sufficient to model up to three reflections in the VLC channel to emulate the effect of multipath propagation on the channel characterization and BER analysis of the system. The results and analyses presented herein provide critical insights into the effect of multipath reflections in indoor VLC links, particularly the BER performance and channel delay characteristics. We also provide some key recommendations for the design of practical VLC systems by outlining the data rates that can be served under different system configurations.

Published

2020

26. Implementation Mixed Wireless Network with Lower Number of Wi-Fi Routers for Optimal Coverage.

Author

Muttair, Karrar Shakir, Zahid, Ali Z. Ghazi, Al-Ani, Oras A. Shareef, AL-Asadi, Ahmed Mohammed Q., and Mosleh, Mahmood F.

Subjects

WIRELESS Internet, GRAPHICAL user interfaces, NETWORK performance, WIRELESS communications

Abstract

With the development of various wireless communication networks, Wi-Fi Router positioning and deployment systems have become widely popular in recent years to improve coverage in various environments. In this paper, we present an appropriate mechanism for defining the deployment of Wi-Fi Routers to improve coverage in the Oxford Languages Institute (OLI) environment. In addition, the institute's environment was simulated using the Wireless InSite (WI) Package. In this work, two types of Wi-Fi Routers are used. The first is the TP-Link, while the second is the Rocket. These two devices operate at 2.4 and 5 GHz frequencies. There are two objectives in this work. The first aim is to determine the best location to cover the simulated scene environment in a better way. The second aim is to compare Wi-Fi Routers to find out which Wi-Fi Router is better and find out how many Wi-Fi Routers we need to cover the institute's environment. The comparison between Wi-Fi Routers was based on basic parameters to measure the performance of wireless networks, the most important of which are Coverage Rate (CR) Percentage, Signal Quality Rate (SQR), and Received Power Rate (RPR). According to the results that were shown on the Graphical User Interface (GUI) using MATLAB Software. We noticed that the CR, SQR, and RPR of the Rocket are 83.9080%, 97.0082%, and -35.2337 dBm respectively, and these results are better than the results provided by the TP-Link, as it gave the CR, SQR, and RPR are 32.1839%, 77.8690%, and -58.1685 dBm, respectively. Finally, we conclude that CR using the Rocket is good and we need one device to cover the institute's environment. While CR using the TP-Link is bad and we need five devices to reach the coverage provided by the Rocket because the Rocket has high transmitted power and gain capacity. [ABSTRACT FROM AUTHOR]

Published

2021

27. 28 GHz MIMO Channel Characteristics Analysis for 5G Communication Systems

Author

Geng, Suiyan, Fan, Ningning, Zhang, Rui, Zhao, Xiongwen, Akan, Ozgur, Series editor, Bellavista, Paolo, Series editor, Cao, Jiannong, Series editor, Coulson, Geoffrey, Series editor, Dressler, Falko, Series editor, Ferrari, Domenico, Series editor, Gerla, Mario, Series editor, Kobayashi, Hisashi, Series editor, Palazzo, Sergio, Series editor, Sahni, Sartaj, Series editor, Shen, Xuemin Sherman, Series editor, Stan, Mircea, Series editor, Xiaohua, Jia, Series editor, Zomaya, Albert Y., Series editor, Long, Keping, editor, Leung, Victor C.M., editor, Zhang, Haijun, editor, Feng, Zhiyong, editor, Li, Yonghui, editor, and Zhang, Zhongshan, editor

Published

2018

28. Measurement-Based Characterization of 39 GHz Millimeter-Wave Dual-Polarized Channel Under Foliage Loss Impact

Author

Yejian Lv, Xuefeng Yin, Chao Zhang, and Haowen Wang

Subjects

Millimeter-wave, 39 GHz, foliage attenuation, delay spread, angular spread, polarimetric characterization, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper presents a measurement-based analysis of wideband 39 GHz millimeter wave (mm-wave) dual-polarized propagation channel under the impact of foliage presence between a transmitter (Tx) and a receiver (Rx). The measurements were conducted in a rich-vegetation area, and the so-called direction-scan-sounding (DSS) method which rotates a horn antenna in angular domains was applied, aiming at investigating the direction-of-arrival (DoA)-dependent characteristics of polarimetric channels. Four Tx-to-Rx polarization configurations were considered, including co-polarization scenarios with vertical Tx-polarization to vertical Rx-polarization (VV) and horizontal to horizontal (HH), as well as cross-polarization with vertical to horizontal (VH) and horizontal to vertical (HV), which allow scrutinizing the differences in delay-direction dispersion for usually-encountered scenarios. A foliage loss model for various vegetation depths in VV polarization configuration, was also presented in this paper. The results show that the foliage-loss DoA spectra for VH and HV are similar, while the spectra exhibit less penetration loss in most directions for VV than for the HH. Furthermore, the presence of vegetation between the Tx and the Rx leads to larger dispersion in delay compared to the clear line-of-sight (LoS) scenario, particularly for vertical polarization in the Tx side, and additionally, the foliage presence also results in evident DoA dispersion, specially in the HV scenario. Selectivity in directions caused by foliage is more significant in vertically-polarized Tx scenarios than in the horizontally-polarized Tx scenarios. A statistical model is established summarizing these comparison details.

Published

2019

29. Measurement-Based Massive MIMO Polarimetric Channel Characterization in Outdoor Environment

Author

Le Hao, Jose Rodriguez-Pineiro, Xuefeng Yin, and Haowen Wang

Subjects

Channel characterization, delay spread, K-factor, massive MIMO, power delay profile, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper introduces a measurement campaign to investigate the characteristics of massive multiple-input multiple-output (MIMO) channels in both line-of-sight (LoS) and obstructed LoS suburban outdoor environments. The measurements are conducted at the center frequency of 3.5 GHz with a bandwidth of 160 MHz. The transmitter is equipped with a 4 × 8 planar patch antenna array and the receiver is equipped with a 4 × 8 cylindrical patch antenna array. Each patch consists of two antenna ports which have main polarizations of +45° and -45°, respectively, resulting in a total of 64 × 64 sub-channels. We examined the influence of different polarization combinations on channel characteristics such as power delay profile (PDP), K-factor and delay spread for both LoS and obstructed LoS scenarios. Results show that the characteristics are more dependent on the Rx antennas rather than the Tx antennas. When the Rx antennas are facing the Tx antenna array, the received power is higher, the K-factor is lower and the delay spread is lower in cross-polarization cases with respect to the co-polarization ones in general. When the Rx antennas are back-facing the Tx antenna array, lower powers, higher K-factors and higher delay spreads can be observed in cross-polarization cases with respect to the co-polarization cases. In conclusion, the polarimetric influence on the channel characteristics depends on the antenna structure as well as the environment.

Published

2019

30. Optical Wireless Applications

Author

Zhou, Z., Kavehrad, M., Karlicek, Robert, editor, Sun, Ching-Cherng, editor, Zissis, Georges, editor, and Ma, Ruiqing, editor

Published

2017

31. Low Complexity Maximum Likelihood FBMC QAM for Improved Performance in Longer Delay Channels.

Author

Subalatha, M., Jayashri, S., Raja, J., and Sakthidasan @ Sankaran, K.

Subjects

QUADRATURE amplitude modulation, SIGNAL detection, CO-channel interference, FILTER banks, QUALITY of service

Abstract

Filter bank multi-carrier (FBMC) is an emerging 5G technology due to its finer spectral characteristics than its counterpart orthogonal frequency-division multiplexing (OFDM). In most cases, FBMC is united with an Offset Quadrature Amplitude modulation (OQAM) for individual sub-carrier to maximize the spectrum efficiency and Nyquist rate. But it is achieved at the cost of an inherent accumulative imaginary interference called intrinsic interference. When a channel is highly selective, the FBMC system undergoes inter-symbol-interference (ISI) and co-channel interference (CCI). In this research, we consider FBMC QAM as a solution to intrinsic interference and mitigates both ISI and CCI by incorporating ML equivalent signal detection. In this paper, some of the prominent issues related to the existing FBMC–OQAM are explored and its potential integrity constraints with existing MIMO and signal detection techniques are studied. In addition to that, a lightweight optimized ML which constitutes parallel sub-detectors with the least hardware complexity overhead is proposed. It also achieved a near-optimal performance that matches the CP-OFDM system. In this research, the experimental results proved that the proposed suboptimal ML detector offered significant complexity reduction with improved quality of services. Thus evidently shows the proposed system is attractive from both BER performance and hardware complexity reduction perspectives for 5G communications. [ABSTRACT FROM AUTHOR]

Published

2021

32. A study about signal variation with minor receiver displacement in a meeting room at 60 GHz: measurements and simulations.

Author

Sheikh, Muhammad Usman, Ruttik, Kalle, Jäntti, Riku, and Hämäläinen, Jyri

Subjects

*TRANSMITTERS (Communication), *CONFERENCE rooms, *HORN antennas, *OMNIDIRECTIONAL antennas, *ROOT-mean-squares, *RAY tracing, *MILLIMETER waves

Abstract

The aim of this work is to study the impact of small receiver displacement on a signal propagation in a typical conference room environment at a millimeter wave frequency of 60 GHz. While channel measurements provide insights on the propagation phenomena, their use for the wireless system performance evaluation is challenging. Whereas, carefully executed three-dimensional ray tracing (RT) simulations represent a more flexible option. Nevertheless, a careful validation of simulation methodology is needed. The first target of this article is to highlight the benefits of an in-house built three-dimensional RT tool at 60 GHz and shows the effectiveness of simulations in predicting different characteristics of the channel. To validate the simulation results against the measurements, two different transmitter (Tx) positions and antenna types along with ten receiver (Rx) positions are considered in a typical conference room. In first system configuration, an omnidirectional antenna is placed in the middle of the table, while in the second system configuration a directed horn antenna is located in the corner of the meeting room. After validating the simulation results with the measurement data, in the second part of this work, the impact of a small change, i.e., 20 cm in the receiver position, is studied. To characterize the impact, we apply as performance indicators the received power level, root mean square delay spread (RMS-DS) and RMS angular spread (RMS-AS) in azimuth plane. The channel characteristics are considered with respect to the direct orientation (DO), i.e., the Rx antenna is directed toward the strongest incoming path. Different antenna configurations at the Tx and Rx side are applied to highlight the role of antenna properties on the considered channel characteristics. Especially, in the second system configuration the impact of different antenna half power beamwidth on different considered channel characteristics is highlighted through acquired simulation results. The validation of results shows the RMS error of only 2–3 dB between the measured and simulated received power levels for different Tx configurations in the direction of DO. Results indicate that only a small change of the Rx position may result a large difference in the received power level even in the presence of line-of-sight between the Tx and Rx. It is found that the STD of received power level across the room increases with the decrease in HPBW of the antenna. As can be expected, directed antennas offer lower value of RMS-DS and RMS-AS compared with isotropic antenna. [ABSTRACT FROM AUTHOR]

Published

2021

33. Channel Sounding and Measurements for Pico Cells for LTE and Future Wireless Networks.

Author

Shukla, Sidharth, Bishnu, Abhijeet, and Bhatia, Vimal

Subjects

COMMUNICATION infrastructure, IMPULSE response, CIVIL defense, UNITS of measurement, INTERNET of things, MULTICASTING (Computer networks)

Abstract

Wireless networks are the preferred future access networks for both defense and civilian deployments as part of telecommunication networks. The successful implementation of long term evolution (LTE) networks and applications such as the Internet of Things (IoT) in the telecommunication infrastructure has guaranteed rates of up to 100 Mbps while supporting ultra-dense wireless access network. With the incorporation of LTE-Advanced and fifth-generation wireless protocols, the data rates are expected to reach upto 1 Gbps. Hence, there is a pertinent requirement to carry out channel measurements at sub 1 GHz, 2 GHz, and 3 GHz bands to enable the design and implementation of optimum transceivers for pico-cells of LTE and future wireless networks. For the first time measurements and comparison with standard models of channel impulse response models have also been carried out in five different terrains namely Urban, Semi-Urban, Forest, Rural, and Desert terrains in the Indian sub-continent to effectively cover a variety of deployments of future wireless access networks for defense wireless networks. [ABSTRACT FROM AUTHOR]

Published

2021

34. The development of an intelligent ray launching algorithm for wireless network planning

Author

Lai, Zhihua

Subjects

621.382, propagation simulation, path loss, discrete ray launching, multipath, delay spread, wireless network planning, parallel, POP-C++, wireless networks, G420 Networks and Communications

Abstract

Current propogation models are no longer sufficient for wireless network planning. They are neither accurate (empirical) nor fast enough (deterministic) to be applicable in the applications of Automated Cell Planning. This thesis focuses on the development of a new method, namely Intelligent Ray Launching Algorithm (IRLA), which is based on a fast, accurate and robust algorithm that is especially suitable for wireless network planning. The infrastructure of IRLA is thoroughly analysed in this thesis and the results are presented. Foster's design methodology has been used to parallelise the new model. Various scenarios for outdoor, indoor, indoor-to-outdoor and outdoor-to-indoor settings have been employed to test the effectiveness and efficiency of IRLA. The field strengths (path loss) and multipath information were calculated, which were used to demonstrate the application of IRLA. The accuracy of IRLA is guaranteed via the use of a meta-based heuristics calibration procedure. In order to achieve a simulation within a realistic time scale, acceleration techniques such as avoid double marking, multi-threading and the use of Parallel Object-Oriented Programming C++ have been employed. Since multipath for a large number of receiver locations can be easily obtained via IRLA, the study of delay spread has been presented. The success of the integration with a wireless network planning platform exemplifies that IRLA is suitable for wireless network planning and optimisation, which is beneficial to relevant academics and industries. Testing demonstrated that depending on various scenarios, IRLA obtains industrially-recognised accuracy ranging from 5 to 8 dB Root-Mean-Square-Error. This model is highly-efficient because its required runtime for most simulations is from a few seconds to a few minutes.

Published

2010

35. Experimental Characterization of Millimeter-Wave Indoor Propagation Channels at 28 GHz

Author

Guojin Zhang, Kentaro Saito, Wei Fan, Xuesong Cai, Panawit Hanpinitsak, Jun-Ichi Takada, and Gert Frolund Pedersen

Subjects

Decay factor, delay spread, angular spread, LOS power ratio, millimeter-wave, channel sounding, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

The increasing requirement for the mobile data traffic accelerates the research of millimeterwave (mm-wave) for future wireless systems. Accurate characterization of the mm-wave propagation channel is fundamental and essential for the system design and performance evaluation. In this paper, we conducted measurement campaigns in various indoor scenarios, including classroom, office, and hall scenarios, at the frequency bands of 27-29 GHz. The spatial channel characteristics were recorded by using a large-scale uniform circular array. A high-resolution parameter estimation algorithm was applied to estimate the mm-wave spherical propagation parameters, i.e., the azimuth angle, elevation angle, delay, source distance, and complex amplitude of multipath components. With the same measurement system, the channel parameters including decay factor, delay spread, angular spread, and line of sight power ratio are investigated thoroughly in individual indoor scenarios and compared in different indoor scenarios. Furthermore, the impact of the furniture richness level and indoor geometry on the propagation parameters are also investigated.

Published

2018

36. Measurement‐based determination of parameters for non‐stationary TDL models with reduced number of taps.

Author

Hassan, Nina, Käske, Martin, Schneider, Christian, Sommerkorn, Gerd, Thomä, Reiner, and Matolak, David

Abstract

This study proposes a new strategy of extracting parameters for tapped delay line (TDL) channel models from vehicle to infrastructure channel measurements. The proposed approach is based on an already existing method to derive parameters for a non‐stationary model using first‐order Markov chains. It will be shown that with the proposed method, the number of taps necessary to regenerate the delay spread of a channel can be significantly reduced. An approach will be discussed to evaluate the performance of the model. The feasibility of the method will be confirmed using channel sounding measurements. [ABSTRACT FROM AUTHOR]

Published

2020

37. Underwater Acoustic Communication Using Multiple-Input–Multiple-Output Doppler-Resilient Orthogonal Signal Division Multiplexing.

Author

Ebihara, Tadashi, Ogasawara, Hanako, and Leus, Geert

Subjects

UNDERWATER acoustic communication, ORTHOGONAL frequency division multiplexing, DOPPLER effect, INTERSYMBOL interference, MULTIPLEXING, ERROR rates, UNDERWATER exploration

Abstract

In this paper, we propose a novel underwater acoustic (UWA) communication scheme that achieves energy and spectrum efficiency simultaneously by combining Doppler-resilient orthogonal signal division multiplexing (D-OSDM) and multiple-input–multiple-output (MIMO) signaling. We present both the transmitter processing and the receiver processing for MIMO D-OSDM. We evaluate the performance of MIMO D-OSDM in simulations with a large intersymbol interference of 25 symbols and a Doppler spread with a maximum Doppler shift of 8 Hz. In addition, the sea trial is performed in Suruga Bay, where the receiver is mounted on a barge and a research vessel with the transmitter makes round trips along a line with a speed of 4 kn. In the experiments, we obtain an intersymbol interference of 3.6–29.7 symbols and a Doppler spread of several Hertz (leading to a spread of over two to three subcarrier spacings). The simulation results suggest that MIMO D-OSDM has an advantage over normal D-OSDM, Doppler-resilient MIMO orthogonal frequency division multiplexing (MIMO D-OFDM), and classical OFDM with MIMO signaling (MIMO OFDM)—MIMO D-OSDM achieves better bit error rate performance than the benchmarks. The sea trial results also support the advantage of MIMO D-OSDM—it achieves a coded block error rate of 3.2% while normal D-OSDM and MIMO D-OFDM achieve a coded block error rate of 9.7% and 9.3%, respectively. We conclude that MIMO D-OSDM can become a viable technique that achieves reliable and effective UWA communication. [ABSTRACT FROM AUTHOR]

Published

2020

38. Measurement‐Based Experimental Statistical Modeling of Propagation Channel in Industrial IoT Scenario.

Author

Wang, Yu, Lv, Yejian, Yin, Xuefeng, and Duan, Jiawei

Subjects

ULTRA-wideband radar, ELECTRIC network analyzers, AUXILIARIES (Grammar), COMMUNICATION, TELECOMMUNICATION systems

Abstract

This paper presents 3–4 and 38–40 GHz wideband channel characteristics for industrial internet‐of‐things (IIoT) scenario based on measurements. The channel measurement equipment applied in the measurements consists of a programmable vector network analyzer and necessary auxiliaries. An extensive amount of data in line‐of‐sight (LoS) and non‐line‐of‐sight (NLoS) scenarios is collected with omnidirectional antennas in both transmitter and receiver ends. With the Space‐Alternating Generalized Expectation‐maximization (SAGE) algorithm, the multipath components (MPCs) of the received signals are extracted to calculate the channel model parameters, for example, channel gain coefficient, delay spread, and Ricean K factor. By studying the statistical characteristics of these parameters, a stochastic channel model in IIoT scenario is initially established and compared with the existing indoor channel models. Moreover, the distinctive characteristics of channel parameters in the millimeter wave band and sub‐6 GHz band in the IIoT scenario are demonstrated. Plain Language Summary: Usually, the industrial environments are complicated and variable, which makes the communications in factory more difficult than those in general indoor scenarios. Hence, more information about the characteristics of the radio propagation in industrial scenarios is needed. This work presents 3–4 and 38–40 GHz wideband channel characteristics for industrial internet‐of‐things (IIoT) scenarios based on measurements, which is helpful to the design of the communication systems and the installation of low‐latency, high‐speed, high‐stability communication facilities on automation production equipment in industrial environments. Key Points: The 3–4 and 38–40 GHz wideband channel models in an industrial internet‐of‐things (IIoT) scenario are presentedThe variance of shadow fading in the IIoT scenario is larger than that in general indoor scenariosThe values of K factors in the IIoT scenario demonstrate significant dependence on the premises of the Rx [ABSTRACT FROM AUTHOR]

Published

2020

39. Coherence Bandwidth and Its Relation to Other Channel Metrics for Urban Mobile Radio Channels at 2 GHz.

Author

Clarke, Hulya Gokalp

Abstract

This letter presents coherence bandwidth values at 1945 MHz over 50 MHz using mobile channel data from 107 small areas in an urban environment with transmit ranges up to 4 km. Empirical relationships between coherence bandwidth for correlation levels 0.9 and 0.5 and root mean square (rms) delay spread are derived and compared with those from the literature. In contrast to previous modeling attempts, this letter investigates whether the additional knowledge of distance and path-loss improves predictions for coherence bandwidth; significant improvement for 0.5 correlation level was found. [ABSTRACT FROM AUTHOR]

Published

2020

40. Performance Evaluation of OTFS Communication System in Doubly Selective Channel.

Author

Park, Byounghak and Ryu, Heung-Gyoon

Subjects

TELECOMMUNICATION systems, DOPPLER effect, FOURIER transforms, ALGORITHMS

Abstract

The 5th generation (5G), the next generation mobile communication, has more requirements than the previous generation 4th generation (4G). For example, Spectral efficiency, peak data rate and mobility it is. Of these requirements, Orthogonal Time Frequency Space (OTFS) has been proposed as a waveform design study to support mobility. OFDM used in 5G and 4G has a weak point in high speed environment. When the frequency shift occurs due to the Doppler effect, orthogonality between subcarriers of OFDM is broken and performance is degraded. To compensate for this, a complex Doppler compensation algorithm is required, which leads to an increase in complexity. OTFS processes signals in two dimensions in the delay-Doppler domain through the Symplectic Finite Fourier Transform (SFFT). It is compatible with conventional OFDM and can be used as pre-coder and post-coder to effectively handle Doppler without complicative compensation algorithms. This paper evaluates and compares the performance of OFDM and OTFS in high Doppler and time delay environments. As a receiver, we used MP detector proposed for OTFS. The performance is similar to OFDM at low SNR, and the performance is noticeably better than OFDM at high SNR. [ABSTRACT FROM AUTHOR]

Published

2020

41. Optical Wireless Body Area Networks for Healthcare Applications

Author

Julien-Vergonjanne, Anne, Sahuguède, Stéphanie, Chevalier, Ludovic, Uysal, Murat, editor, Capsoni, Carlo, editor, Ghassemlooy, Zabih, editor, Boucouvalas, Anthony, editor, and Udvary, Eszter, editor

Published

2016

42. Uncertainty Analysis Methodology for Measurements of Dynamic Millimeter-Wave Channels

Author

Schulpen, Robbert, Smolders, A. Bart, Johannsen, Ulf, Bronckers, L.A., Schulpen, Robbert, Smolders, A. Bart, Johannsen, Ulf, and Bronckers, L.A.

Abstract

Quantification of uncertainties in the results of channel sounding measurements is important for their interpretation and further usage. In this paper, a novel uncertainty analysis methodology to quantify uncertainties of condensed parameters in measurements of dynamic millimeter-wave channels is presented. The bandwidth limitation and multipath threshold are identified as important impairments. Therefore, the methodology provides three uncertainty metrics for condensed parameters, namely a standard uncertainty to quantify the impact of random variations; a bias due to the multipath threshold; and a total bias including the impact of the bandwidth limitation. These uncertainty metrics are highly channel dependent. Therefore, the proposed methodology creates reference channels, which are representative of corresponding measured channels. Hardware and processing impairments are included in the analysis via a Monte Carlo simulation. This results in a general methodology that can quantify uncertainties in both static and dynamic channel measurements of any wideband channel sounder. The methodology is implemented, verified and demonstrated for the TU/e channel sounder, which exemplifies how it can be used. The proposed methodology can improve the analysis, interpretation and reporting of channel measurement results.

Published

2023

43. Overview of MIMO-OFDM

Author

Ahmed, Bannour, Abdul Matin, Mohammad, Ahmed, Bannour, and Abdul Matin, Mohammad

Published

2015

44. Impact of Human Blockage on Dynamic Indoor Multipath Channels at 27 GHz

Author

Robbert Schulpen, Adrianus Bernardus Smolders, Laurens Bronckers, Ulf Johannsen, Electromagnetics, Center for Wireless Technology Eindhoven, Electrical Engineering, Center for Astronomical Instrumentation, EM Antenna Systems Lab, EM for Radio Science Lab, and EM-Metrology Lab

Subjects

Delay spread, indoor measurements, Semiconductor device measurement, delay spread (DS), path loss, Loss measurement, Channel dynamics, path loss (PL), channel sounding, Synchronization, Millimeter-wave propagation, Antenna measurements, Human blockage, millimeter-wave (mm-wave) propagation, Stairs, Power measurement, Delays, Electrical and Electronic Engineering

Abstract

Human blockage and its dynamics are potential challenges for millimeter-wave (mm-wave) mobile communication. This article presents the results of wideband measurements at 27 GHz with one human blocker close by a dynamic mobile terminal (MT) as well as one or multiple dynamic human blockers further away from an MT. The measured human blockage loss is largest when the direct path (DP) in a line-of-sight (LOS) is blocked, but this loss is limited by other multipath components (MPCs). For nonline-of-sight (NLOS) channels, it is shown that human blockage loss is typically negligible. The presented measurement results show that human blockage loss in multipath channels is much smaller than that reported in diffraction-and measurement-based models, which neglect or minimize the contribution of all MPCs other than the DP. This suggests that the multipath nature of the indoor wireless channel highly limits the impact of human blockage.

Published

2022

45. Robust time synchronization for NC-OFDM cognitive radio systems

Author

Suyoto Suyoto, Iskandar Iskandar, Sugihartono Sugihartono, and Adit Kurniawan

Subjects

Cognitive radio, General Computer Science, Multipath channels, Computer science, Modulation, Orthogonal frequency-division multiplexing, ComputerSystemsOrganization_COMPUTER-COMMUNICATIONNETWORKS, Electronic engineering, Data_CODINGANDINFORMATIONTHEORY, Center frequency, Multiplexing, Delay spread, Time synchronization

Abstract

In this paper, we propose a time-synchronization method for non-contiguous orthogonal frequency division multiplexing (NC-OFDM) systems. NC-OFDM is a modulation and multiplexing technique that is often used for cognitive radio (CR) systems. In OFDM-based CR systems, time synchronization is limited by a number of challenges: multipath channels with a high delay spread, a narrowband interference (NBI), and minimal number of subcarriers. Indeed, the proposed method addresses these problems since it does not require information on subcarriers nor the NBI center frequency; moreover, it works well on the multipath channel with a high delay spread.

Published

2022

46. Person Density Dependency on Path Loss and Root Mean Square Delay Spread for Smart Office Scenarios

Author

Liu Yang, Wen-Jun Lu, Zeng Wenhao, Hongbo Zhu, Tingting Liu, and Yu Yu

Subjects

Dependency (UML), Computer Networks and Communications, Computer science, Quadratic function, Computer Science Applications, Delay spread, Root mean square, Link budget, Hardware and Architecture, Signal Processing, Path loss, Ray tracing (graphics), Algorithm design, Algorithm, Information Systems

Abstract

Novel empirical path loss and root mean square delay spread (RDS) models for smart office scenarios are proposed. The effects of person density on the path loss and RDS are investigated based on the extensive measurements at 2.3-2.5GHz. Firstly, both of the measured path loss and RDS data are modeled as the dual log-distance functions. It is caused by the regular structure and furniture in the office environment. Secondly, in the proposed path loss model, the path loss exponents and the additional attenuation factor are modeled as quadratic functions of the person density. Meanwhile, the RDS is found to be uncorrelated with the person density. These phenomena reveal that the persons in the environments can be regarded as absorbers rather than scatters. rgb0.00,0.00,0.00Then, the accuracy of the proposed models is validated by the measured data and compared with two traditional models. Finally, the effect of the persons’ movements on the path loss and RDS are investigated, and the proposed models are extended to millimeter wave bands by ray tracing technology. The proposed models and results can provide necessary information for link budget and algorithm design for the Internet of Things smart office scenarios.

Published

2022

47. Effective Channel Hardening in an Indoor Multiband Scenario.

Author

Ghiaasi, Golsa, Abraham, Jens, Eide, Egil, and Ekman, Torbjörn

Subjects

*LARGE scale systems, *ANTENNA arrays, *SOFTWARE radio, *RADIO technology, *RADIO networks, *MOBILE geographic information systems, *COGNITIVE radio, *CHANNEL estimation

Abstract

We evaluate channel hardening for a large scale antenna system by means of indoor channel measurements over four frequency bands, 1.472 GHz , 2.6 GHz , 3.82 GHz and 4.16 GHz . NTNU's Reconfigurable Radio Network Platform has been used to record the channel estimates for 40 radio links to a 64 element array with wideband antennas in a rich scattering environment. We examine metrics for channel hardening, namely, the coherence bandwidth, the rms delay spread and the normalized effective subcarrier power, for the effective channel perceived by a single user after precoding and superposition in the downlink. We describe these metrics analytically and demonstrate them with measured data in order to characterize the rate of hardening of the effective channel as the number of antenna elements at the base station increases. The metrics allow for direct insight into the benefits of channel hardening with respect to radio system requirements. [ABSTRACT FROM AUTHOR]

Published

2019

48. Influence of Vegetation on the Outdoor-to- Indoor Mobile Radio Propagation in 700 MHz Band.

Author

Ribeiro, Leonardo G., Matos, Leni J., Castellanos, Pedro V. G., Moura, Matheus B., Mota, Vitor L. G., and Meza, Wyliam D. T.

Subjects

PROBABILITY density function, CONSTRUCTION & the environment, RADIOS, PLANTS, SHORTWAVE radio

Abstract

Starting from outdoor transmission, crossing vegetation, the wideband and narrowband characterization of the indoor mobile radio channel in the 700 MHz band is obtained from experiments carried out in the indoor environment of the Engineering building at Fluminense Federal University, and from the processed data, respectively, the power-delay profiles obtained permitted to calculate the time dispersion parameters and the envelope of the signal permitted to adjust probability density functions to the signal variability, concluding about the influence of vegetation on those characteristics. [ABSTRACT FROM AUTHOR]

Published

2019

49. Emulation Techniques for Small Scale Fading Aspects by Using Reverberation Chamber.

Author

Kihero, Abuu B., Karabacak, Murat, and Arslan, Huseyin

Subjects

*ANGLE of arrival (Wave motion), *SOUND reverberation, *ACOUSTIC surface waves, *RADIO attenuators, *DOPPLER effect

Abstract

Reverberation chambers (RVCs) are used to provide an efficient and reliable testbed for emulating the wireless channel effects in the laboratory environment. In the literature, various techniques have been studied to enrich the channel emulation capabilities of RVCs. However, insufficient control of some of the emulated channel characteristics (such as time and frequency dispersions) still leaves an open problem for RVC-based channel emulators. In this paper, novel channel emulation techniques by using RVC are introduced to enhance the flexibility in controlling the emulated time and frequency dispersions of the channels. Surface acoustic wave delay lines and power controllers (i.e., amplifiers and attenuators) are used to add degrees of freedom for manipulating the power delay profile during delay spread emulation. This technique also overcomes the challenge of achieving higher delay spread values with benchtop-sized RVC. The second technique is aimed to control the Doppler spectrum shape emulated in the chamber by judiciously placing radio frequency absorbers around the mechanical stirrer. Experimental and mathematical analyses are conducted to evaluate the proposed techniques, and the results show that the proposed methods can improve the channel emulation in the RVCs. [ABSTRACT FROM AUTHOR]

Published

2019

50. Facing the SNR Wall Detection in Full Duplex Cognitive Radio Networks Using a GLRT Multipath-Based Detector

Author

Dania Marabissi, Andrea Tani, and Romano Fantacci

Subjects

Orthogonal frequency-division multiplexing, Computer science, Applied Mathematics, Detector, Computer Science Applications, Delay spread, Cognitive radio, Colors of noise, Likelihood-ratio test, Electronic engineering, Electrical and Electronic Engineering, Multipath propagation, Computer Science::Information Theory, Communication channel

Abstract

Recently, with the advances in self-interference cancellation, full-duplex (FD) techniques have become a feasible approach to improve the spectrum usage in new generation wireless systems. In particular, in cognitive radio networks, FD allows a secondary user to simultaneously sense the spectrum and transmit, improving the network efficiency. However, the residual self interference (RSI) arising from an imperfect cancellation, represents a bottleneck for the spectrum sensing performance. This paper analytically demonstrates that RSI represents a colored noise which leads to the SNR Wall phenomenon making the typical OFDM signal detectors no longer robust. To overcome this drawback, we propose a generalized likelihood ratio test detector exploiting the multipath correlation due to the primary user’s (PU) channel. It is proven that the proposed method is not affected by the SNR Wall, hence it is robust w.r.t an imperfect self-interference cancellation. Specifically, best detection performance is achieved when an approximated knowledge of the maximum delay spread of the PU channel is available, otherwise it is shown that a limited performance degradation occurs. Moreover, provided results highlight that our approach outperforms the classical alternatives in different scenarios, including when PU employs a mixed numerology OFDM signal, which characterizes the 5G New Radio waveform.

Published

2022