Your search keyword '"Software-defined radio"' showing total 8,172 results

1. Development of a modular half-duplex frequency-agile X-band transceiver for CubeSats and robotic spacecraft.

Author

Bonny, Robin F., Simik, Martin, Weill, Jeremy, Challot, Juliette, and Bartle, Hannes

Subjects

*GEOCHEMISTRY, *TIME-of-flight mass spectrometry, *LIFE cycles (Biology), *SOFTWARE radio, *RADIO transmitter-receivers, *SPACE debris

Abstract

The EPFL Spacecraft Team (EST) is working on the Constellation of High-Performance Exospheric Science Satellites (CHESS) mission, which aims to launch a constellation of two CubeSats in 2027. These CubeSats will study the chemical composition of Earth's exosphere using time-of-flight mass spectrometry. To downlink the collected scientific data, the satellites will utilise a custom X-band transceiver, presented in this paper, operating in the amateur frequency range of 10.45 GHz to 10.50 GHz. The proposed transceiver architecture employs Software-Defined Radio (SDR) technology and can be easily adapted for different use cases. This modular approach has the potential to be suitable for future spacecraft missions, such as active debris removal or lifetime extension services, where flexible communication systems are required. • Hybrid SDR architectures enable versatile telecom systems for space missions. • IOD/IOV missions let students follow the entire life cycle of a space project. • Short development/prototyping cycles maximise the lessons learned in student teams. [ABSTRACT FROM AUTHOR]

Published

2024

2. Demonstration of a USRP-based Communication Network for Internet-of-Things (IOT) Application

Author

Sohaib Yaqoob Chaudhry and Jamal Haider

Subjects

signal processing, equalization, multipath fading, software-defined radio, sdr, internet of things, usrp, Telecommunication, TK5101-6720

Abstract

In this paper, an SDR-based single-carrier, simplex, wireless communication system is presented for Internet-of-Things (IOT) applications. The research work includes the design of both hardware and software such that the system can communicate reliably over a distance of 100 meters. The hardware component of this work includes the complete design and fabrication of the transmitter and receiver front-end PCBs. On the other hand, the software aspect which consists of signal processing is implemented on a software-defined radio where various impairment correction techniques are implemented to mitigate challenges in the wireless channel such as carrier frequency offset, phase offset, and timing offset. Furthermore, an equalization algorithm is implemented to compensate for errors that arise due to the phenomena of multipath fading. To demonstrate the efficacy of the proposed communication system in an indoor environment, an extensive validation test scheme was devised and performed. The proposed communication system demonstrates an optimum spectral efficiency of 3.2 bps/Hz at a bit rate of 26.66 Mbit/s.

Published

2024

3. Modified receiver architecture in software-defined radio for real-time modulation classification

Author

Quoc Nam Le, Tan Quoc Huynh, Hien Quang Ta, Phuoc Vo Tan, and Lap Luat Nguyen

Subjects

Real-time automatic modulation classification, Deep learning, Software-defined radio, Telecommunication, TK5101-6720, Electronics, TK7800-8360

Abstract

Abstract Automatic modulation classification (AMC) is an important process for future communication systems with prominent applications from spectrum management, and secure communication, to cognitive radio. The requirement for an efficient AMC classifier is due to its capability in blind modulation recognition, which is a difficult task in real scenarios where the limitations of traditional hardware and the complexity of channel impairments are involved. Therefore, this paper proposes a complete real-time AMC system based on software-defined radio and deep learning architecture. The system demodulation performance is verified through simulations and real channel impairment conditions to ensure reliability. With at most 6 times reduced number of parameters, two proposed models convolutional long short-term memory deep neural network and residual long short-term memory neural network also show a general improvement in classification accuracy compared with reference studies. The performance of these models at real-time AMC is tested with suitable processing time for practical applications.

Published

2024

4. Investigating Radio Frequency Vulnerabilities in the Internet of Things (IoT)

Author

Eirini Anthi, Lowri Williams, Vasilis Ieropoulos, and Theodoros Spyridopoulos

Subjects

internet of things (IoT), smart homes, networking, radio frequency, software-defined radio, Computer software, QA76.75-76.765, Technology, Cybernetics, Q300-390

Abstract

With the increase in the adoption of Internet of Things (IoT) devices, the security threat they face has become more pervasive. Recent research has demonstrated that most IoT devices are insecure and vulnerable to a range of cyber attacks. The impact of such attacks can vary significantly, from affecting the service of the device itself to putting their owners and their personal information at risk. As a response to improving their security, the focus has been on attacks, specifically on the network layer. However, the importance and impact of other vulnerabilities, such as low-level Radio Frequency (RF) attacks, have been neglected. Such attacks are challenging to detect, and they can be deployed using non-expensive equipment and can cause significant damage. This paper explores security vulnerabilities that target RF communications on popular commercial IoT devices such as Wi-Fi, Zigbee, and 433 Mz. Using software-defined radio, a range of attacks were deployed against the devices, including jamming, replay attacks, packet manipulation, protocol reverse engineering, and harmonic frequency attacks. The results demonstrated that all devices used were susceptible to jamming attacks, and in some cases, they were rendered inoperable and required a hard reset to function correctly again. This finding highlights the lack of protection against both intentional and unintentional jamming. In addition, all devices demonstrated that they were susceptible to replay attacks, which highlights the need for more hardened security measures. Finally, this paper discusses proposals for defence mechanisms for enhancing the security of IoT devices against the aforementioned attacks.

Published

2024

5. AI Optimization-Based Heterogeneous Approach for Green Next-Generation Communication Systems.

Author

Khaled, Haitham and Alkhazraji, Emad

Subjects

*SOFTWARE radio, *TELECOMMUNICATION systems, *COGNITIVE radio, *RADIO technology, *LONG-Term Evolution (Telecommunications)

Abstract

Traditional heterogeneous networks (HetNets) are constrained by their hardware design and configuration. These HetNets have a limited ability to adapt to variations in network dynamics. Software-defined radio technology has the potential to address this adaptability issue. In this paper, we introduce a software-defined radio (SDR)-based long-term evolution licensed assisted access (LTE-LAA) architecture for next-generation communication networks. We show that with proper design and tuning of the proposed architecture, high-level adaptability in HetNets becomes feasible with a higher throughput and lower power consumption. Firstly, maximizing the throughput and minimizing power consumption are formulated as a constrained optimization problem. Then, the obtained solution, alongside a heuristic solution, is compared against the solutions to existing approaches, showing our proposed strategy is drastically superior in terms of both power efficiency and system throughput. This study is then concluded by employing artificial intelligence techniques in multi-objective optimization, namely random forest regression, particle swarm, and genetic algorithms, to balance out the trade-offs between maximizing the throughput and power efficiency and minimizing energy consumption. These investigations demonstrate the potential of employing the proposed LTE-LAA architecture in addressing the requirements of next-generation HetNets in terms of power, throughput, and green scalability. [ABSTRACT FROM AUTHOR]

Published

2024

6. Software-Defined Radio Implementation of a LoRa Transceiver.

Author

de Omena Simas, João Pedro, Riviello, Daniel Gaetano, and Garello, Roberto

Subjects

*SOFTWARE radio, *INTERNET radio, *ACCESS control, *REVERSE engineering, *INTERNET of things

Abstract

The number of applications of low-power wide-area networks (LPWANs) has been growing quite considerably in the past few years and so has the number of protocol stacks. Despite this fact, there is still no fully open LPWAN protocol stack available to the public, which limits the flexibility and ease of integration of the existing ones. The closest to being fully open is LoRa; however, only its medium access control (MAC) layer, known as LoRaWAN, is open and its physical and logical link control layers, also known as LoRa PHY, are still only partially understood. In this paper, the essential missing aspects of LoRa PHY are not only reverse engineered, but also, a new design of the transceiver and its sub-components are proposed and implemented in a modular and flexible way using GNU Radio. Finally, some examples of applications of both the transceiver and its components, which are made to be run in a simple setup by using cheap and widely available off-the-shelf hardware, are given to show how the library can be used and extended. [ABSTRACT FROM AUTHOR]

Published

2024

7. Algorithms and Resources for the Monitoring of Very-Low-Frequency Signal Deviations Due to Solar Activity Using a Web-Based Software-Defined Radio-Distributed Network.

Author

Iliev, Ilia, Tudjarov, Kostadin, Nachev, Ivaylo, Petkov, Peter Z., Velchev, Yuliyan, and Ilieva, Ana

Subjects

*SOLAR activity, *SOFTWARE-defined networking, *SOFTWARE radio, *CORONAL mass ejections, *SOLAR system, *MAGNETIC storms, *SOLAR flares, *COMPUTER software testing

Abstract

This work presents the development and testing of an experimental web-based SDR (software-defined radio) monitoring system for indirect solar activity detection, which has the ability to estimate and potentially predict various events in space and on earth, including solar flares, coronal mass ejections, and geomagnetic storms. The proposed system can be used to investigate the effect of solar activity on the propagation of very-low-frequency (VLF) signals. The advantages and benefits of the given approach are as follows: increasing measurement accuracy and eventual solar activity identification by combining measurements from multiple spatially distributed SDRs. The verification process involves carrying out several experiments comparing data from the GOES satellite system and the Dunksin SuperSID system with information received by the SDR monitoring system. Then, utilizing Pearson correlation coefficients, the measured data from the SDRs, along with those from the GOES satellite system and the Dunsing monitoring station, are investigated. At the time of a solar flare, the correlation value is above 90% for most of the stations used. Combining the signal-to-noise ratio via summation also shows an improvement in the results, with a correlation above 98%. [ABSTRACT FROM AUTHOR]

Published

2024

8. Modified receiver architecture in software-defined radio for real-time modulation classification.

Author

Le, Quoc Nam, Huynh, Tan Quoc, Ta, Hien Quang, Tan, Phuoc Vo, and Nguyen, Lap Luat

Subjects

SOFTWARE radio, ELECTRONIC modulation, ARTIFICIAL neural networks, DEEP learning, SPECTRUM allocation, TELECOMMUNICATION systems

Abstract

Automatic modulation classification (AMC) is an important process for future communication systems with prominent applications from spectrum management, and secure communication, to cognitive radio. The requirement for an efficient AMC classifier is due to its capability in blind modulation recognition, which is a difficult task in real scenarios where the limitations of traditional hardware and the complexity of channel impairments are involved. Therefore, this paper proposes a complete real-time AMC system based on software-defined radio and deep learning architecture. The system demodulation performance is verified through simulations and real channel impairment conditions to ensure reliability. With at most 6 times reduced number of parameters, two proposed models convolutional long short-term memory deep neural network and residual long short-term memory neural network also show a general improvement in classification accuracy compared with reference studies. The performance of these models at real-time AMC is tested with suitable processing time for practical applications. [ABSTRACT FROM AUTHOR]

Published

2024

9. Recent Advances on Jamming and Spoofing Detection in GNSS.

Author

Radoš, Katarina, Brkić, Marta, and Begušić, Dinko

Subjects

*GLOBAL Positioning System, *MACHINE learning, *SOFTWARE radio, *LOCAL transit access

Abstract

Increased interest in the development and integration of navigation and positioning services into a wide range of receivers makes them susceptible to a variety of security attacks such as Global Navigation Satellite Systems (GNSS) jamming and spoofing attacks. The availability of low-cost devices including software-defined radios (SDRs) provides a wide accessibility of affordable platforms that can be used to perform these attacks. Early detection of jamming and spoofing interferences is essential for mitigation and avoidance of service degradation. For these reasons, the development of efficient detection methods has become an important research topic and a number of effective methods has been reported in the literature. This survey offers the reader a comprehensive and systematic review of methods for detection of GNSS jamming and spoofing interferences. The categorization and classification of selected methods according to specific parameters and features is provided with a focus on recent advances in the field. Although many different detection methods have been reported, significant research efforts toward developing new and more efficient methods remain ongoing. These efforts are driven by the rapid development and increased number of attacks that pose high-security risks. The presented review of GNSS jamming and spoofing detection methods may be used for the selection of the most appropriate solution for specific purposes and constraints and also to provide a reference for future research. [ABSTRACT FROM AUTHOR]

Published

2024

10. Investigating Radio Frequency Vulnerabilities in the Internet of Things (IoT).

Author

Anthi, Eirini, Williams, Lowri, Ieropoulos, Vasilis, and Spyridopoulos, Theodoros

Subjects

INTERNET of things, RADIO frequency, SOFTWARE radio, RADIO interference, SMART homes

Abstract

With the increase in the adoption of Internet of Things (IoT) devices, the security threat they face has become more pervasive. Recent research has demonstrated that most IoT devices are insecure and vulnerable to a range of cyber attacks. The impact of such attacks can vary significantly, from affecting the service of the device itself to putting their owners and their personal information at risk. As a response to improving their security, the focus has been on attacks, specifically on the network layer. However, the importance and impact of other vulnerabilities, such as low-level Radio Frequency (RF) attacks, have been neglected. Such attacks are challenging to detect, and they can be deployed using non-expensive equipment and can cause significant damage. This paper explores security vulnerabilities that target RF communications on popular commercial IoT devices such as Wi-Fi, Zigbee, and 433 Mz. Using software-defined radio, a range of attacks were deployed against the devices, including jamming, replay attacks, packet manipulation, protocol reverse engineering, and harmonic frequency attacks. The results demonstrated that all devices used were susceptible to jamming attacks, and in some cases, they were rendered inoperable and required a hard reset to function correctly again. This finding highlights the lack of protection against both intentional and unintentional jamming. In addition, all devices demonstrated that they were susceptible to replay attacks, which highlights the need for more hardened security measures. Finally, this paper discusses proposals for defence mechanisms for enhancing the security of IoT devices against the aforementioned attacks. [ABSTRACT FROM AUTHOR]

Published

2024

11. A Software Defined Radio Testbed to Analyze the Performance of Channel Estimation in MIMO Systems

Author

Mercado-Perez, Dalyana, Kumar, Venkataramani, Ye, Feng, 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, Kadoch, Michel, editor, Lu, Kejie, editor, Ye, Feng, editor, and Qian, Yi, editor

Published

2024

12. RHLab: Towards Implementing a Partial Reconfigurable SDR Remote Lab

Author

Zhang, Zhiyun, Inoñan, Marcos, Orduña, Pablo, Hussein, Rania, 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, Auer, Michael E., editor, Langmann, Reinhard, editor, May, Dominik, editor, and Roos, Kim, editor

Published

2024

13. RHLab Interoperable Software-Defined Radio (SDR) Remote Laboratory

Author

Inoñan, Marcos, Zhang, Zhiyun, Amarante, Pedro, Orduña, Pablo, Hussein, Rania, Arabshahi, Payman, 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, Auer, Michael E., editor, Langmann, Reinhard, editor, May, Dominik, editor, and Roos, Kim, editor

Published

2024

14. Cognitive Radio

Author

Bilén, Sven G., Lakhtakia, Akhlesh, editor, Furse, Cynthia M., editor, and Mackay, Tom G., editor

Published

2024

15. Reinforcement Learning Based Angle-of-Arrival Detection for Millimeter-Wave Software-Defined Radio Systems

Author

Jean, Marc, Yuksel, Murat, Rannenberg, Kai, Editor-in-Chief, Soares Barbosa, Luís, Editorial Board Member, Goedicke, Michael, Editorial Board Member, Tatnall, Arthur, Editorial Board Member, Neuhold, Erich J., Editorial Board Member, Stiller, Burkhard, Editorial Board Member, Stettner, Lukasz, Editorial Board Member, Pries-Heje, Jan, Editorial Board Member, Kreps, David, Editorial Board Member, Rettberg, Achim, Editorial Board Member, Furnell, Steven, Editorial Board Member, Mercier-Laurent, Eunika, Editorial Board Member, Winckler, Marco, Editorial Board Member, Malaka, Rainer, Editorial Board Member, Puthal, Deepak, editor, Mohanty, Saraju, editor, and Choi, Baek-Young, editor

Published

2024

16. Revealing IoT Cryptographic Settings through Electromagnetic Side-Channel Analysis.

Author

Zunaidi, Muhammad Rusyaidi, Sayakkara, Asanka, and Scanlon, Mark

Subjects

DIGITAL forensics, FORENSIC sciences, DIGITAL technology, SUPPORT vector machines, INTERNET of things

Abstract

The advancement of cryptographic systems presents both opportunities and challenges in the realm of digital forensics. In an era where the security of digital information is crucial, the ability to non-invasively detect and analyze cryptographic configurations has become significant. As cryptographic algorithms become more robust with longer key lengths, they provide higher levels of security. However, non-invasive side channels, specifically through electromagnetic (EM) emanations, can expose confidential cryptographic details, thus presenting a novel solution to the pressing forensic challenge. This research delves into the capabilities of EM side-channel analysis (EM-SCA), specifically focusing on detecting both cryptographic key lengths and the algorithms employed utilizing a machine-learning-based approach, which can be instrumental for digital forensic experts during their investigations. Through meticulous data processing and analysis, the Support Vector Machine (SVM) model, among others, demonstrated a notable accuracy of 94.55% in distinguishing between AES and ECC cryptographic operations. This capability significantly enhances digital forensic methodologies, offering a novel avenue for noninvasively uncovering encrypted data's cryptographic settings. By identifying key lengths and algorithms without invasive procedures, this research contributes substantially to the advancement of forensic investigations in encrypted environments. [ABSTRACT FROM AUTHOR]

Published

2024

17. Implementation of a High-Sensitivity Global Navigation Satellite System Receiver on a System-on-Chip Field-Programmable Gate Array Platform.

Author

Majoral, Marc, Arribas, Javier, and Fernández-Prades, Carles

Subjects

*GLOBAL Positioning System, *SYSTEMS on a chip, *GATE array circuits, *PROCESS capability, *SIGNAL processing

Abstract

This paper presents the design, proof-of-concept implementation, and preliminary performance assessment of an affordable real-time High-Sensitivity (HS) Global Navigation Satellite System (GNSS) receiver. Specifically tailored to capture and track weak Galileo E1b/c signals, this receiver aims to support research endeavors focused on advancing GNSS signal processing algorithms, particularly in scenarios characterized by pronounced signal attenuation. Leveraging System-on-Chip Field-Programmable Gate Array (SoC-FPGA) technology, this design merges the adaptability of Software Defined Radio (SDR) concepts with the the robust hardware processing capabilities of FPGAs. This innovative approach enhances power efficiency compared to conventional designs relying on general-purpose processors, thereby facilitating the development of embedded software-defined receivers. Within this architecture, we implemented a modular GNSS baseband processing engine, offering a versatile platform for the integration of novel algorithms. The proposed receiver undergoes testing with live signals, showcasing its capability to process GNSS signals even in challenging scenarios with a carrier-to-noise density ratio ( C / N 0 ) as low as 20 dB-Hz, while delivering navigation solutions. This work contributes to the advancement of low-cost, high-sensitivity GNSS receivers, providing a valuable tool for researchers engaged in the development, testing, and validation of experimental GNSS signal processing techniques. [ABSTRACT FROM AUTHOR]

Published

2024

18. GNSS Software-Defined Radio: History, Current Developments, and Standardization Efforts.

Author

Pany, Thomas, Akos, Dennis, Arribas, Javier, Bhuiyan, M. Zahidul H., Closas, Pau, Dovis, Fabio, Fernandez-Hernandez, Ignacio, Fernández–Prades, Carles, Gunawardena, Sanjeev, Humphreys, Todd, Kassas, Zaher M., López Salcedo, José A., Nicola, Mario, Psiaki, Mark L., Rügamer, Alexander, Young-Jin Song, and Jong-Hoon Won

Subjects

*GLOBAL Positioning System, *SIGNAL-to-noise ratio, *CRYOSPHERE, *INTEGRATED circuits, *STANDARDIZATION

Abstract

Taking the work conducted by the global navigation satellite system (GNSS) software-defined radio (SDR) working group during the last decade as a seed, this contribution summarizes, for the first time, the history of GNSS SDR development. This report highlights selected SDR implementations and achievements that are available to the public or that influenced the general development of SDR. Aspects related to the standardization process of intermediate-frequency sample data and metadata are discussed, and an update of the Institute of Navigation SDR Standard is proposed. This work focuses on GNSS SDR implementations in general-purpose processors and leaves aside developments conducted on field programmable gate array and application-specific integrated circuit platforms. Data collection systems (i.e., front-ends) have always been of paramount importance for GNSS SDRs and are thus partly covered in this work. This report represents the knowledge of the authors but is not meant as a complete description of SDR history. [ABSTRACT FROM AUTHOR]

Published

2024

19. Software-Defined Radio-Based IEEE 802.15.4 SUN FSK Evaluation Platform for Highly Mobile Environments

Author

Jaeseok Lim, Keito Nakura, Shota Mori, and Hiroshi Harada

Subjects

802.15.4, IoT, mobile, software-defined radio, Wi-SUN, FSK, Transportation engineering, TA1001-1280, Transportation and communications, HE1-9990

Abstract

IEEE 802.15.4 smart utility network (SUN) frequency-shift keying (FSK) has attracted considerable attention as a wireless communication standard designed for use in essential applications required by Internet of Things (IoT) systems. However, longer transmission distances in highly mobile environments are required to support various applications in next-generation IoT systems, such as vehicle-to-everything, automated driving, and drone control systems. Although research on wide-area, highly mobile communications has been conducted via computer simulations, an experimental evaluation platform for further research has not been developed. In this study, we developed an experimental evaluation platform for SUN FSK in very high frequency bands. The developed platform comprises a signal generator-based transmitter and a software-defined radio-based receiver. It was proven to be capable of transmitting a power of ≥5 W through a power amplifier and was suitable for laboratory and field experiments. In addition, we developed received signal processing methods, including a packet detection method and a channel estimation method, which were designed to achieve wide-area, highly mobile communication. In laboratory experiments, the packet error rate characteristics required by IEEE 802.15.4 were achieved even at a transmission distance of >10 km at vehicular speeds of several tens of km/h.

Published

2024

20. Accurate Phase Synchronization for Precoding-Enabled GEO Multibeam Satellite Systems

Author

Liz Martinez Marrero, Juan Carlos Merlano Duncan, Jorge Luis Gonzalez, Jevgenij Krivochiza, Symeon Chatzinotas, Bjorn Ottersten, and Adriano Camps

Subjects

phase noise, phase synchronization, precoding, software-defined radio, Telecommunication, TK5101-6720, Transportation and communications, HE1-9990

Abstract

Synchronizing the local oscillators in multibeam satellites with the objective of coherent communications is still an open challenge. It has to be addressed to implement full-frequency reuse approaches, such as precoding techniques using the already deployed multibeam satellites. This article addresses the required phase synchronization to enable precoding techniques in multibeam satellite systems. It contains the detailed design of a frequency and phase compensation loop based on the proportional-integral controller, which deals with the phase drift introduced by the hardware components. Specifically, the phase noise of the local oscillators used for up and down conversion at each system element (gateway, satellite, and user terminals). The implementation of the two-state phase noise model used to emulate this phase drift is included in the article. Besides, a comparative analysis of several methods to combine the frequency and phase measurements obtained from the user terminals is also included. Finally, the performance of the proposed closed-loop synchronization method is validated through simulations using our in-house developed MIMO end-to-end satellite emulator based on SDR platforms.

Published

2024

21. Software-Defined Radio-Based IEEE 802.15.4 SUN OFDM Evaluation Platform for Highly Mobile Environments

Author

Keito Nakura, Shota Mori, Hiroko Masaki, and Hiroshi Harada

Subjects

802.15.4, IoT, mobile, software-defined radio, UTW-OFDM, Wi-SUN, Transportation engineering, TA1001-1280, Transportation and communications, HE1-9990

Abstract

Next-generation Internet of Things (IoT) systems require faster data transmission, support for moving objects, and long-distance transmission when compared to the currently available IoT systems. The IEEE 802.15.4 smart utility network (SUN) orthogonal frequency-division multiplexing (OFDM) can satisfy these requirements. Mobile-communication-oriented receiver systems are typically used in urban environments for SUN OFDM. However, the evaluation depends on computer simulations and requires an experimental evaluation platform based on software-defined radio (SDR) that can modify transmitter-receiver functions. We present a platform for SUN OFDM that enables high-speed mobile communication. The proposed platform comprises a signal generator-based transmitter and an SDR-based receiver; the receiver baseband signal processing is performed by MATLAB. We also proposed signal processing functions that can receive the SUN OFDM packets even at speeds of tens of km/h. We applied a simplified universal time-domain windowed (UTW)-OFDM scheme to this platform to operate even at sub-1 GHz, where the spectrum mask is more limited. In the experimental evaluation, the required packet error rate for SUN OFDM was achieved in an 80 km/h multipath fading environment, and out-of-band emission can be suppressed by over 43 dB from the peak power while achieving performance equivalent to that without applying the simplified UTW.

Published

2024

22. Maritime Communications—Current State and the Future Potential with SDN and SDR

Author

Nadia Niknami, Avinash Srinivasan, Ken St. Germain, and Jie Wu

Subjects

autonomous underwater vehicles, IoT, maritime communication, software-defined networking, software-defined radio, unmanned aerial vehicles, Computer engineering. Computer hardware, TK7885-7895, Electronic computers. Computer science, QA75.5-76.95

Abstract

The rise of the Internet of Things (IoT) has opened up exciting possibilities for new applications. One such novel application is the modernization of maritime communications. Effective maritime communication is vital for ensuring the safety of crew members, vessels, and cargo. The maritime industry is responsible for the transportation of a significant portion of global trade, and as such, the efficient and secure transfer of information is essential to maintain the flow of goods and services. With the increasing complexity of maritime operations, technological advancements such as unmanned aerial vehicles (UAVs), autonomous underwater vehicles (AUVs), and the Internet of Ships (IoS) have been introduced to enhance communication and operational efficiency. However, these technologies also bring new challenges in terms of security and network management. Compromised IT systems, with escalated privileges, can potentially enable easy and ready access to operational technology (OT) systems and networks with the same privileges, with an increased risk of zero-day attacks. In this paper, we first provide a review of the current state and modalities of maritime communications. We then review the current adoption of software-defined radios (SDRs) and software-defined networks (SDNs) in the maritime industry and evaluate their impact as maritime IoT enablers. Finally, as a key contribution of this paper, we propose a unified SDN–SDR-driven cross-layer communications framework that leverages the existing SATCOM communications infrastructure, for improved and resilient maritime communications in highly dynamic and resource-constrained environments.

Published

2023

23. ION-FAST as the NIRFI's Ionospheric Diagnostic Platform.

Author

Moiseev, Sergey P., Shindin, Alexei V., Grekhneva, Kseniya K., Pavlova, Viktoriya A., and Timukin, Nikita S.

Subjects

*COST control, *IONOSPHERE, *GATE array circuits, *SOFTWARE radio, *RESEARCH institutes, *SHORTWAVE radio

Abstract

In December 2021, we presented a prototype of a fast ionosonde for vertical sounding based on the usage of publicly available radio-electronic components. This approach led to a major reduction in the cost of the created device. We called our development ION-FAST, which characterizes the key feature of the ionosonde: the possibility of continuous operation at a speed of one ionogram per second, which is required to study the rapid processes of redistribution of the electron concentration during heating experiments. In May 2022, an ionosonde for vertical sounding of the ionosphere, developed at the Radiophysical Research Institute of Nizhni Novgorod (NIRFI), was put into continuous operation at the SURA facility. This report provides a description of the improvements made to the prototype over the last year and the path to be passed from idea to implementation. The results of the first months of the prototype's operation (especially the results of the supporting optic experiment in August 2022), as well as prospects for further use and modernization, are provided. In addition, the realization of the oblique chirp-sounding receiver prototype as an extension of the proposed diagnostic platform's functionality, including the first results, is presented. [ABSTRACT FROM AUTHOR]

Published

2024

24. Frequency-shift Keying-based Underwater Acoustic Sonar Sensor Communication System with Robust Data Processing Technology.

Author

Chih-Ta Yen and Guo-Chang Wang

Subjects

DATA transmission systems, INFORMATION storage & retrieval systems, SWIMMING pools, SONAR, FREQUENCY shift keying, COMMUNICATIONS software, SUBMERGED structures, TELECOMMUNICATION systems, MOBILE communication systems

Abstract

Marine communication has attracted widespread attention in the wake of global warming and national defense awareness in recent years, where acoustic systems enabling smooth underwater communication have become a popular research topic. In this study, we proposed an underwater communication system equipped with modulators and demodulators (modems). Specifically, the wireless communication software GNU’s Not Unix Radio (GNU Radio) was adopted to develop communication formats and architectures applied to a Raspberry Pi computer, on which we developed a communication format available for signal synchronization to increase system robustness against underwater channel interferences. We also developed hardware and software modems for the system. The hardware device was developed using the XR2206 function generator and XR2211 equipment for frequency-shift keying (FSK)-based modulation and demodulation, respectively. The software FSK modem was developed using GNU Radio. To increase the robustness of the transmitted data, we added a cyclic redundancy check through the Async CRC32 block, after which the power distribution unit (PDU) to the Tagged Stream block placed a tag to the start of data combined with effective loads and CRC32, facilitating the attachment of header generators. Four experiments with different underwater scenarios were then conducted to verify the proposed system. The hardware modem had a 0 bit error rate (BER) during experiments implemented in a laboratory sink, a 20-m-long indoor swimming pool, and a 50-m-long outdoor swimming pool, compared with BERs of 2.8 × 10−3 and 6.6 × 10−3 during the breeding water tank experiment under transmission rates of 1 and 2 kbps, respectively. Similarly, the software modem delivered 0-BER performance in the laboratory sink as well as in the indoor and outdoor swimming pools, with its BERs being 2.3 × 10−4 and 2.98 × 10−4 under 1 and 2 kbps transmission rates, respectively. The proposed system comprises preambles, headers, and effective load communication formats for signal protection. In particular, its directional ultrasonic cylindrical piezoelectric transducer can mitigate multipath effects and interferences, thereby enhancing system robustness. [ABSTRACT FROM AUTHOR]

Published

2024

25. Machine Learning based calibration SDR in Digital Twin application.

Author

Leiras, Valdemar, Dixe, Sandra, Azevedo, L. Filipe, Dias, Sérgio, Faria, Sérgio, Fonseca, Jaime C., Moreira, António H.J., and Borges, João

Subjects

DIGITAL twins, SOFTWARE radio, MACHINE learning, RADIO (Medium), RADIO frequency, RADIO technology

Abstract

Software-Defined Radios are radio communications devices that have been growing and developing on a larger scale in recent years. Communications are intrinsically embedded in our day by day, thus presenting a higher motivation to use software-defined radios due to its attractive cost. However they present technical limitations. This paper addresses this problem, which is the non-linearity behaviour of gain and frequency in the LimeSDR-USB. That is, this equipment is used to produce a FM signal with an associated frequency and gain before being parameterised according to the internal parameters of each software-defined radio. Each software-defined radio presents a value of frequency and gain of its own, which correlates to the generated signals at the output level. To avoid this, machine learning networks were used, in which networks were trained to adapt to the non-linearity of these devices and correct it without the user noticing. This way, the user sets a desired frequency and gain in a signal, at the output of the software-defined radios, and a neural network calculates which values the software-defined radios should be parameterised, thus mitigating the non-linearity behaviour. This paper presents the evaluation of a laboratory prototype based on low-cost commercial software-defined radios equipment, to replace an expensive metrologically calibrated equipment used for radio frequency tests on a new concept of industrial test station, with description of the integration of Digital Twins, with their physical and virtual parts. [ABSTRACT FROM AUTHOR]

Published

2024

26. A novel self‐interference cancellation architecture based on asymmetrical power divider and its closed‐loop control.

Author

Qing, Shijun, Zhu, Ningli, Li, Huimin, Chen, Yihong, Feng, Quanyuan, and Xiang, Qianyin

Subjects

*POWER dividers, *OPTIMIZATION algorithms, *SOFTWARE radio, *RADIO frequency, *ELECTRIC power filters, *ADAPTIVE fuzzy control

Abstract

The asymmetric radio frequency (RF) self‐interference cancellation (SIC) architecture is studied, and the closed‐loop control of RF SIC based on software radio is realized. This system uses a circulator to isolate the receiving and transmitting chains, and its RF reconstruction chain is composed of a 4‐tap filter with fixed delay and tunable attenuation for each tap. The optimization of tap filter and asymmetric power divider's power allocation ratio is discussed. In the experiment, sensing, calibration, optimization algorithms and hardware control programs were proposed. A closed‐loop gradient descent algorithm for tuning the variable attenuator is implemented on the GNU Radio. From 910 MHz to 930 MHz, the isolation between the receiving and transmitting ports increases 40 dB, achieving an isolation of more than 65 dB and the transmission energy efficiency increases by 60%. [ABSTRACT FROM AUTHOR]

Published

2024

27. Software Platform for the Comprehensive Testing of Transmission Protocols Developed in GNU Radio.

Author

Stef, Mihai Petru and Polgar, Zsolt Alfred

Subjects

*SOFTWARE radio, *WIRELESS communications, *COMPUTER software, *TIME series analysis, *WIRELESS communications security, *COMPUTER software testing, *INTERNETWORKING

Abstract

With the constant growth of software-defined radio (SDR) technologies in fields related to wireless communications, the need for efficient ways of testing and evaluating the physical-layer (PHY) protocols developed for these technologies in real-life traffic scenarios has become more critical. This paper proposes a software testbed that enhances the creation of network environments that allow GNU radio applications to be fed with test traffic in a simple way and through an interoperable interface. This makes the use of any traffic generator possible—existing ones or one that is custom-built—to evaluate a GNU radio application. In addition, this paper proposes an efficient way to collect PHY-specific monitoring data to improve the performance of the critical components of the message delivery path by employing the protocol buffers library. This study considers the entire testing and evaluation ecosystem and demonstrates how PHY-specific monitoring information is collected, handled, stored, and processed as time series to allow complex visualization and real-time monitoring. [ABSTRACT FROM AUTHOR]

Published

2024

28. Design and Development of a CCSDS 131.2-B Software-Defined Radio Receiver Based on Graphics Processing Unit Accelerators.

Author

Ciardi, Roberto, Giuffrida, Gianluca, Bertolucci, Matteo, and Fanucci, Luca

Subjects

SOFTWARE radio, TELECOMMUNICATION systems, EARTH stations, SIGNAL processing, RADIO technology, GRAPHICS processing units, VIDEO coding

Abstract

In recent years, the number of Earth Observation missions has been exponentially increasing. Satellites dedicated to these missions usually embark with payloads that produce large amount of data and that need to be transmitted towards ground stations, in time-limited windows. Moreover, the noisy nature of the link between satellites and ground stations makes it hard to achieve reliable communication. To address these problems, a standard for a flexible advanced coding and modulation scheme for high-rate telemetry applications has been defined by the Consultative Committee for Space Data Systems (CCSDS). The defined standard, referred to as CCSDS 131.2-B, makes use of Serially Concatenated Convolutional Codes (SCCC) based on 27 ModCods to optimize transmission quality. A limiting factor in the adoption of this standard is represented by the complexity and the cost of the hardware required for developing high-performance receivers. In the last decade, the performance of software has grown due to the advancement of general-purpose processing hardware, leading to the development of many high-performance software systems even in the telecommunication sector. These are commonly referred to as Software-Defined Radio (SDR), indicating a radio communication system in which components that are usually implemented in hardware, by means of FPGAs or ASICs, are instead implemented in software, offering many advantages such as flexibility, modularity, extensibility, cheaper maintenance, and cost saving. This paper proposes the development of an SDR based on NVIDIA Graphics Processing Units (GPU) for implementing the receiver end of the CCSDS 131.2-B standard. At first, a brief description of the CCSDS 131.2-B standard is given, focusing on the architecture of the transmitter and receiver sides. Then, the receiver architecture is shown, giving an overview of its functional blocks and of the implementation choices made to optimize the processing of the signal, especially for the SCCC Decoder. Finally, the performance of the system is analyzed in terms of data-rate and error correction and compared with other SW systems to highlight the achieved improvements. The presented system has been demonstrated to be a perfect solution for CCSDS 131.2-B-compliant device testing and for its use in science missions, providing a valid low-cost alternative with respect to the state-of-the-art HW receivers. [ABSTRACT FROM AUTHOR]

Published

2024

29. SDR-Based Portable System for Evaluating Exposure to Ambient Electromagnetic Fields.

Author

Tuta, Leontin, Panait-Radu, Florentina, Ardelean, Felix, Gorgoteanu, Damian, and Rosu, Georgiana

Subjects

ELECTROMAGNETIC fields, SOFTWARE radio, DATABASES, SQL, CITIES & towns, WIRELESS Internet

Abstract

This paper discusses the need to accurately determine the population's exposure to low-intensity radio-frequency electromagnetic fields (RF-EMF) from modern technologies like mobile networks, Wi-Fi, and IoT and proposes a practical solution for this assessment. There is no scientific consensus on the biological effects, mostly due to challenges in conducting accurate biological experiments. Recent research suggests that real-life exposure sources trigger stronger biological responses than laboratory-generated RF-EMF. However, there is a lack of research comparing the effects of these sources. This paper introduces a portable system for assessing and monitoring EMF exposure in urban areas. Employing a Software-Defined Radio (SDR) platform to ensure adaptability, the system incorporates two measurement configurations. The initial version concentrates on determining the average power within a 20 MHz Wi-Fi channel, whereas the subsequent configuration augments its functionality by introducing a frequency sweep. This sweep broadens the scrutinized bandwidth, thereby enriching the captured data content through the storage of spectrum sweeps corresponding to each average power value. These data can be used to create EMF profile maps based on individuals' geographical coordinates. Compared to current limited-performance commercial exposimeters, the proposed system offers expanded capabilities by broadening the frequency bandwidth, georeferencing measurements, and storing data in an SQL database. Compared to high-performance commercial exposimeters, the major advantage of the system is its ability to detect short-term fluctuations in signal spectra and store the corresponding data for subsequent analysis. [ABSTRACT FROM AUTHOR]

Published

2023

30. Deployment and Implementation Aspects of Radio Frequency Fingerprinting in Cybersecurity of Smart Grids.

Author

Awan, Maaz Ali, Dalveren, Yaser, Catak, Ferhat Ozgur, and Kara, Ali

Subjects

RADIO frequency, PHYSICAL layer security, INTERNET security, DEEP learning, INTERNET of things

Abstract

Smart grids incorporate diverse power equipment used for energy optimization in intelligent cities. This equipment may use Internet of Things (IoT) devices and services in the future. To ensure stable operation of smart grids, cybersecurity of IoT is paramount. To this end, use of cryptographic security methods is prevalent in existing IoT. Non-cryptographic methods such as radio frequency fingerprinting (RFF) have been on the horizon for a few decades but are limited to academic research or military interest. RFF is a physical layer security feature that leverages hardware impairments in radios of IoT devices for classification and rogue device detection. The article discusses the potential of RFF in wireless communication of IoT devices to augment the cybersecurity of smart grids. The characteristics of a deep learning (DL)-aided RFF system are presented. Subsequently, a deployment framework of RFF for smart grids is presented with implementation and regulatory aspects. The article culminates with a discussion of existing challenges and potential research directions for maturation of RFF. [ABSTRACT FROM AUTHOR]

Published

2023

31. A Flexible System-on-Chip Field-Programmable Gate Array Architecture for Prototyping Experimental Global Navigation Satellite System Receivers.

Author

Majoral, Marc, Fernández-Prades, Carles, and Arribas, Javier

Subjects

*GLOBAL Positioning System, *SYSTEMS on a chip, *GATE array circuits, *SOFTWARE radio

Abstract

Global navigation satellite system (GNSS) technology is evolving at a rapid pace. The rapid advancement demands rapid prototyping tools to conduct research on new and innovative signals and systems. However, researchers need to deal with the increasing complexity and integration level of GNSS integrated circuits (IC), resulting in limited access to modify or inspect any internal aspect of the receiver. To address these limitations, the authors designed a low-cost System-on-Chip Field-Programmable Gate Array (SoC-FPGA) architecture for prototyping experimental GNSS receivers. The proposed architecture combines the flexibility of software-defined radio (SDR) techniques and the energy efficiency of FPGAs, enabling the development of compact, portable, multi-channel, multi-constellation GNSS receivers for testing novel and non-standard GNSS features with live signals. This paper presents the proposed architecture and design methodology, reviewing the practical application of a spaceborne GNSS receiver and a GNSS rebroadcaster, and introducing the design and initial performance evaluation of a general purpose GNSS receiver serving as a testbed for future research. The receiver is tested, demonstrating the ability of the receiver to acquire and track GNSS signals using static and low Earth orbit (LEO)-scenarios, assessing the observables' quality and the accuracy of the navigation solutions. [ABSTRACT FROM AUTHOR]

Published

2023

32. Maritime Communications—Current State and the Future Potential with SDN and SDR.

Author

Niknami, Nadia, Srinivasan, Avinash, St. Germain, Ken, and Wu, Jie

Subjects

MARINE communication, DRONE aircraft, COMPUTER network management, SUBMERSIBLES, INFORMATION technology

Abstract

The rise of the Internet of Things (IoT) has opened up exciting possibilities for new applications. One such novel application is the modernization of maritime communications. Effective maritime communication is vital for ensuring the safety of crew members, vessels, and cargo. The maritime industry is responsible for the transportation of a significant portion of global trade, and as such, the efficient and secure transfer of information is essential to maintain the flow of goods and services. With the increasing complexity of maritime operations, technological advancements such as unmanned aerial vehicles (UAVs), autonomous underwater vehicles (AUVs), and the Internet of Ships (IoS) have been introduced to enhance communication and operational efficiency. However, these technologies also bring new challenges in terms of security and network management. Compromised IT systems, with escalated privileges, can potentially enable easy and ready access to operational technology (OT) systems and networks with the same privileges, with an increased risk of zero-day attacks. In this paper, we first provide a review of the current state and modalities of maritime communications. We then review the current adoption of software-defined radios (SDRs) and software-defined networks (SDNs) in the maritime industry and evaluate their impact as maritime IoT enablers. Finally, as a key contribution of this paper, we propose a unified SDN–SDR-driven cross-layer communications framework that leverages the existing SATCOM communications infrastructure, for improved and resilient maritime communications in highly dynamic and resource-constrained environments. [ABSTRACT FROM AUTHOR]

Published

2023

33. Improving the Efficiency of UAV Communication Channels in the Context of Electronic Warfare

Author

Serhii Semendiai, Yuliіa Tkach, Mykhailo Shelest, Oleksandr Korchenko, Ruslana Ziubina, and Olga Veselska

Subjects

cognitive radio, software-defined radio, neural networks, coding, electronic warfare, communication channel, wireless communications, spectrum analysis, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Telecommunication, TK5101-6720

Abstract

The article is devoted to the development of a method for increasing the efficiency of communication channels of unmanned aerial vehicles (UAVs) in the conditions of electronic warfare (EW). The author analyses the threats that may be caused by the use of electronic warfare against autonomous UAVs. A review of some technologies that can be used to create original algorithms for countering electronic warfare and increasing the autonomy of UAVs on the battlefield is carried out. The structure of modern digital communication systems is considered. The requirements of unmanned aerial vehicle manufacturers for onboard electronic equipment are analyzed, and the choice of the hardware platform of the target radio system is justified. The main idea and novelty of the proposed method are highlighted. The creation of a model of a cognitive radio channel for UAVs is considered step by step. The main steps of modelling the spectral activity of electronic warfare equipment are proposed. The main criteria for choosing a free spectral range are determined. The type of neural network for use in the target cognitive radio system is substantiated. The idea of applying adaptive coding in UAV communication channels using multicomponent turbo codes in combination with neural networks, which are simultaneously used for cognitive radio, has been further developed.

Published

2023

34. Software-Defined Radio Applied to a Shielding Effectiveness Measurement

Author

Marcelo B. Perotoni, Stilante K. Manfrin, and Vinicius F. Silva

Subjects

Software-defined radio, Electromagnetic compatibility, signal processing., Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Abstract This article describes the use of a low-cost softwaredefined radio applied to an Electromagnetic Compatibility (EMC) test. The proposed system is indicated for cases when an autonomous instrument is better suited, i.e., when there is no need for external signal or power connections. As a proof of concept, a metallic cavity has its shielding parameter measured, and the obtained results illustrate the kind of outputs the instrument can provide. Details concerning the hardware and software utilized are mentioned, alongside observed pitfalls and trade-offs. It is an affordable and versatile method, which can replace the traditional use of spectrum analyzers and receivers, especially in precompliance tasks.

Published

2023

35. Software-Defined Radio Implementation of a LoRa Transceiver

Author

João Pedro de Omena Simas, Daniel Gaetano Riviello, and Roberto Garello

Subjects

Internet of Things, LoRa, software-defined radio, GNU Radio, Chemical technology, TP1-1185

Abstract

The number of applications of low-power wide-area networks (LPWANs) has been growing quite considerably in the past few years and so has the number of protocol stacks. Despite this fact, there is still no fully open LPWAN protocol stack available to the public, which limits the flexibility and ease of integration of the existing ones. The closest to being fully open is LoRa; however, only its medium access control (MAC) layer, known as LoRaWAN, is open and its physical and logical link control layers, also known as LoRa PHY, are still only partially understood. In this paper, the essential missing aspects of LoRa PHY are not only reverse engineered, but also, a new design of the transceiver and its sub-components are proposed and implemented in a modular and flexible way using GNU Radio. Finally, some examples of applications of both the transceiver and its components, which are made to be run in a simple setup by using cheap and widely available off-the-shelf hardware, are given to show how the library can be used and extended.

Published

2024

36. AI Optimization-Based Heterogeneous Approach for Green Next-Generation Communication Systems

Author

Haitham Khaled and Emad Alkhazraji

Subjects

AI optimization, cognitive radio, software-defined radio, green communication, Chemical technology, TP1-1185

Abstract

Traditional heterogeneous networks (HetNets) are constrained by their hardware design and configuration. These HetNets have a limited ability to adapt to variations in network dynamics. Software-defined radio technology has the potential to address this adaptability issue. In this paper, we introduce a software-defined radio (SDR)-based long-term evolution licensed assisted access (LTE-LAA) architecture for next-generation communication networks. We show that with proper design and tuning of the proposed architecture, high-level adaptability in HetNets becomes feasible with a higher throughput and lower power consumption. Firstly, maximizing the throughput and minimizing power consumption are formulated as a constrained optimization problem. Then, the obtained solution, alongside a heuristic solution, is compared against the solutions to existing approaches, showing our proposed strategy is drastically superior in terms of both power efficiency and system throughput. This study is then concluded by employing artificial intelligence techniques in multi-objective optimization, namely random forest regression, particle swarm, and genetic algorithms, to balance out the trade-offs between maximizing the throughput and power efficiency and minimizing energy consumption. These investigations demonstrate the potential of employing the proposed LTE-LAA architecture in addressing the requirements of next-generation HetNets in terms of power, throughput, and green scalability.

Published

2024

37. Recent Advances on Jamming and Spoofing Detection in GNSS

Author

Katarina Radoš, Marta Brkić, and Dinko Begušić

Subjects

GNSS, spoofing, jamming, detection methods, machine learning models, software-defined radio, Chemical technology, TP1-1185

Abstract

Increased interest in the development and integration of navigation and positioning services into a wide range of receivers makes them susceptible to a variety of security attacks such as Global Navigation Satellite Systems (GNSS) jamming and spoofing attacks. The availability of low-cost devices including software-defined radios (SDRs) provides a wide accessibility of affordable platforms that can be used to perform these attacks. Early detection of jamming and spoofing interferences is essential for mitigation and avoidance of service degradation. For these reasons, the development of efficient detection methods has become an important research topic and a number of effective methods has been reported in the literature. This survey offers the reader a comprehensive and systematic review of methods for detection of GNSS jamming and spoofing interferences. The categorization and classification of selected methods according to specific parameters and features is provided with a focus on recent advances in the field. Although many different detection methods have been reported, significant research efforts toward developing new and more efficient methods remain ongoing. These efforts are driven by the rapid development and increased number of attacks that pose high-security risks. The presented review of GNSS jamming and spoofing detection methods may be used for the selection of the most appropriate solution for specific purposes and constraints and also to provide a reference for future research.

Published

2024

38. Experimental Investigation on Spectrum Sensing Testbed Using GNU Radio and SDR

Author

Pandey, Manas, Chauhan, Anjali, Chowdhury, Dibyendu, DasMahapatra, Suddhendu, Angrisani, Leopoldo, Series Editor, Arteaga, Marco, 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, 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, Mukhopadhyay, Subhas, Series Editor, Ning, Cun-Zheng, Series Editor, Nishida, Toyoaki, Series Editor, Oneto, Luca, Series Editor, Panigrahi, Bijaya Ketan, 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, Zhang, Junjie James, Series Editor, Tan, Kay Chen, Series Editor, Sarkar, Dilip Kumar, editor, Sadhu, Pradip Kumar, editor, Bhunia, Sunandan, editor, Samanta, Jagannath, editor, and Paul, Suman, editor

Published

2023

39. Near-Ultrasonic Covert Channels Using Software-Defined Radio Techniques

Author

Sherry, R., Bayne, E., McLuskie, D., Onwubiko, Cyril, editor, Rosati, Pierangelo, editor, Rege, Aunshul, editor, Erola, Arnau, editor, Bellekens, Xavier, editor, Hindy, Hanan, editor, and Jaatun, Martin Gilje, editor

Published

2023

40. GNSS Software-Defined Radio: History, Current Developments, and Standardization Efforts

Author

Thomas Pany, Dennis Akos, Javier Arribas, M. Zahidul H. Bhuiyan, Pau Closas, Fabio Dovis, Ignacio Fernandez-Hernandez, Carles Fernández–Prades, Sanjeev Gunawardena, Todd Humphreys, Zaher M. Kassas, José A. López Salcedo, Mario Nicola, Mark L. Psiaki, Alexander Rügamer, Young-Jin Song, and Jong-Hoon Won

Subjects

gnss, software-defined radio, Canals and inland navigation. Waterways, TC601-791, Naval Science

Abstract

Taking the work conducted by the global navigation satellite system (GNSS) software-defined radio (SDR) working group during the last decade as a seed, this contribution summarizes, for the first time, the history of GNSS SDR development. This report highlights selected SDR implementations and achievements that are available to the public or that influenced the general development of SDR. Aspects related to the standardization process of intermediate-frequency sample data and metadata are discussed, and an update of the Institute of Navigation SDR Standard is proposed. This work focuses on GNSS SDR implementations in general-purpose processors and leaves aside developments conducted on field programmable gate array and application-specific integrated circuit platforms. Data collection systems (i.e., front-ends) have always been of paramount importance for GNSS SDRs and are thus partly covered in this work. This report represents the knowledge of the authors but is not meant as a complete description of SDR history.

Published

2024

41. Combining Software-Defined Radio Learning Modules and Neural Networks for Teaching Communication Systems Courses †.

Author

Camuñas-Mesa, Luis A. and de la Rosa, José M.

Subjects

*TELECOMMUNICATION systems, *SOFTWARE radio, *LEARNING modules, *COMMUNICATION education, *RADIO transmitters & transmission, *RADIO technology, *MOBILE communication systems

Abstract

The paradigm known as Cognitive Radio (CR) proposes a continuous sensing of the electromagnetic spectrum in order to dynamically modify transmission parameters, making intelligent use of the environment by taking advantage of different techniques such as Neural Networks. This paradigm is becoming especially relevant due to the congestion in the spectrum produced by increasing numbers of IoT (Internet of Things) devices. Nowadays, many different Software-Defined Radio (SDR) platforms provide tools to implement CR systems in a teaching laboratory environment. Within the framework of a 'Communication Systems' course, this paper presents a methodology for learning the fundamentals of radio transmitters and receivers in combination with Convolutional Neural Networks (CNNs). [ABSTRACT FROM AUTHOR]

Published

2023

42. Improving the Efficiency of UAV Communication Channels in the Context of Electronic Warfare.

Author

Semendiai, Serhii, Tkach, Yuliia, Shelest, Mykhailo, Korchenko, Oleksandr, Ziubina, Ruslana, and Veselska, Olga

Subjects

*DRONE aircraft, *MILITARY electronics, *COGNITIVE radio, *SOFTWARE radio, *ARTIFICIAL neural networks, *SPECTRUM analysis, *WIRELESS communications

Abstract

The article is devoted to the development of a method for increasing the efficiency of communication channels of unmanned aerial vehicles (UAVs) in the conditions of electronic warfare (EW). The author analyses the threats that may be caused by the use of electronic warfare against autonomous UAVs. A review of some technologies that can be used to create original algorithms for countering electronic warfare and increasing the autonomy of UAVs on the battlefield is carried out. The structure of modern digital communication systems is considered. The requirements of unmanned aerial vehicle manufacturers for onboard electronic equipment are analyzed, and the choice of the hardware platform of the target radio system is justified. The main idea and novelty of the proposed method are highlighted. The creation of a model of a cognitive radio channel for UAVs is considered step by step. The main steps of modelling the spectral activity of electronic warfare equipment are proposed. The main criteria for choosing a free spectral range are determined. The type of neural network for use in the target cognitive radio system is substantiated. The idea of applying adaptive coding in UAV communication channels using multicomponent turbo codes in combination with neural networks, which are simultaneously used for cognitive radio, has been further developed. [ABSTRACT FROM AUTHOR]

Published

2023

43. Measuring Power of Earth Disturbances Using Radio Wave Phase Imager.

Author

Sharif, Radwan N. K. and Herring, Rodney A.

Subjects

RADIO waves, IONOSPHERIC disturbances, SOFTWARE radio, OCEAN wave power, POWER density, WAVE energy

Abstract

Numerous studies have investigated ionospheric waves, also known as ionospheric disturbances. These disturbances exhibit complex wave patterns similar to those produced by solar, geomagnetic, and meteorological disturbances and human activities within the Earth's atmosphere. The radio wave phase imager described herein measures the power of the ionospheric waves using their phase shift seen in phase images produced by the Long Wavelength Array (LWA) at the New Mexico Observatory, a high-resolution radio camera. Software-defined radio (SDR) was used for processing the data to produce an amplitude image and phase image. The phase image revealed the ionospheric waves, whereas the amplitude image could not see them. From the phase image produced from the carrier wave received at the LWA, the properties of the ionospheric waves have been previously characterized in terms of their energy and wave vector. In this study, their power was measured directly from the phase shift of the strongest set of ionospheric waves. The power of these waves, which originated at Albuquerque, the local major power consumer, was 15.3 W, producing a power density of 0.018 W/m2. The calculated power density that should be generated from the local power generating stations around Albuquerque was also 0.018 W/m2, in agreement with the experimentally measured value. This correspondence shows that the power generated by power stations and being consumed is not lost but captured by the ionosphere. [ABSTRACT FROM AUTHOR]

Published

2023

44. An Assessment of Environmental RF Noise Due to IoT Deployment.

Author

Ingala, Dominique G. K., Pillay, Nelendran, and Pillay, Aritha

Subjects

*INTERNET of things, *RADIO transmitters & transmission, *NOISE, *PRODUCTION quantity, *SOFTWARE radio

Abstract

The advent of the Internet of Things (IoT) has contributed to an increase in the production volume of RF-featured equipment. According to statistics from the literature, the IoT industry will soon deploy billions of products. While the concept behind these applications seems exciting, this paper sought to assess the effects the radio emissions produced by IoT products would have on the ambient radio noise levels within the unlicensed frequency bands of 433 MHz, 868 MHz, and 2.4 GHz. The study extended to three environments: industrial, urban, and suburban. This study developed an IoT noise generator (ING) device to emulate RF noise signals in the desired IoT radio transmission band. The paper presents a simplified radio noise surveying system (RNSS) for data collection of ambient radio noise from five South African candidate sites. The statistical and empirical analysis agree that the level of ambient radio noise was directly proportional to the rate of IoT radio activities. The slopes of the regression lines demonstrate that 80% of the analyzed data developed augmenting trends. Approximately 20% of the data show declining trends. [ABSTRACT FROM AUTHOR]

Published

2023

45. A Model-Based Engineering Approach for Evaluating Software-Defined Radio Architecture.

Author

Albayati, Mohammed G., Dano, Eric B., Rajamani, Ravi, and Thompson, Amy E.

Subjects

SOFTWARE radio, ENGINEERING models, DIGITAL transformation, ARCHITECTURAL design, DIGITAL technology

Abstract

In product development, important specification and design decisions must be made at various stages of the lifecycle that include design, manufacturing, operations, and support. However, making these decisions becomes more complex when a multi-disciplinary team of stakeholders is involved in system-level or subsystem-level architecture and design decisions. Model-Based Engineering (MBE) approaches are enabling a digital thread of connected data and models. This work demonstrates a novel MBE approach that incorporates a model-based systems engineering (MBSE) method and a multi-criteria decision-making (MCDM) method to determine the best architecture solution that aligns with stakeholder needs and objectives over multiple domains. This approach demonstrates the connection of a system descriptive model, modeled using the systems modeling language (SysML), to underlying physics-based engineering models for the purpose of better predicting the technical performance of systems during the architecture development phase. This approach is demonstrated for a common aerospace communications application, a software-defined radio. This novel MBE approach supports digital transformation at organizations and allows for earlier design validation, enabling designers to test and select the best system architecture from many candidates and validate that the design meets stakeholder needs. [ABSTRACT FROM AUTHOR]

Published

2023

46. Software-Defined Radio Applied to a Shielding Effectiveness Measurement.

Author

Perotoni, Marcelo B., Manfrin, Stilante K., and Silva, Vinicius F.

Subjects

SOFTWARE radio, ELECTROMAGNETIC compatibility, SPECTRUM analyzers, PROOF of concept

Abstract

This article describes the use of a low-cost softwaredefined radio applied to an Electromagnetic Compatibility (EMC) test. The proposed system is indicated for cases when an autonomous instrument is better suited, i.e., when there is no need for external signal or power connections. As a proof of concept, a metallic cavity has its shielding parameter measured, and the obtained results illustrate the kind of outputs the instrument can provide. Details concerning the hardware and software utilized are mentioned, alongside observed pitfalls and trade-offs. It is an affordable and versatile method, which can replace the traditional use of spectrum analyzers and receivers, especially in precompliance tasks. [ABSTRACT FROM AUTHOR]

Published

2023

47. A Study on the Derivation of Atmospheric Water Vapor Based on Dual Frequency Radio Signals and Intersatellite Communication Networks.

Author

Nyamukondiwa, Ramson Munyaradzi, Orger, Necmi Cihan, Nakayama, Daisuke, and Cho, Mengu

Subjects

ATMOSPHERIC water vapor, WATER vapor, TELECOMMUNICATION systems, GLOBAL Positioning System, RADIO frequency, SOFTWARE radio

Abstract

The atmospheric total water vapor content (TWVC) affects climate change, weather patterns, and radio signal propagation. Recent techniques such as global navigation satellite systems (GNSS) are used to measure TWVC but with either compromised accuracy, temporal resolution, or spatial coverage. This study demonstrates the feasibility of predicting, mapping, and measuring TWVC using spread spectrum (SS) radio signals and software-defined radio (SDR) technology on low Earth-orbiting (LEO) satellites. An intersatellite link (ISL) communication network from a constellation of small satellites is proposed to achieve three-dimensional (3D) mapping of TWVC. However, the calculation of TWVC from satellites in LEO contains contribution from the ionospheric total electron content (TEC). The TWVC and TEC contribution are determined based on the signal propagation time delay and the satellites' positions in orbit. Since TEC is frequency dependent unlike TWVC, frequency reconfiguration algorithms have been implemented to distinguish TWVC. The novel aspects of this research are the implementation of time stamps to deduce time delay, the unique derivation of TWVC from a constellation setup, the use of algorithms to remotely tune frequencies in real time, and ISL demonstration using SDRs. This mission could contribute to atmospheric science, and the measurements could be incorporated into the global atmospheric databases for climate and weather prediction models. [ABSTRACT FROM AUTHOR]

Published

2023

48. Bandpass Sigma–Delta Modulation: The Path toward RF-to-Digital Conversion in Software-Defined Radio

Author

Jose M. de la Rosa

Subjects

analog-to-digital conversion, sigma–delta modulation, software-defined radio, Electronic computers. Computer science, QA75.5-76.95, Electric apparatus and materials. Electric circuits. Electric networks, TK452-454.4

Abstract

This paper reviews the state of the art on bandpass ΣΔ modulators (BP-ΣΔMs) intended to digitize radio frequency (RF) signals. A priori, this is the most direct way to implement software-defined radio (SDR) systems since the analog/digital interface is placed closer to the antenna, thus reducing the analog circuitry and doing most of the signal processing in the digital domain. In spite of their higher programmability and scalability, RF BP-ΣΔM analog-to-digital converters (ADCs) require more energy to operate in the GHz range as compared with their low-pass (LP) counterparts. This makes conventional direct conversion receivers (DCRs) the commonplace approach due to their overall smaller energy consumption. This paper surveys some circuits and systems techniques which can make RF ADCs and SDR-based transceivers more efficient and feasible to be embedded in mobile terminals.

Published

2023

49. USING SOFTWARE-DEFINED RADIO RECEIVERS FOR DETERMINING THE COORDINATES OF LOW-VISIBLE AERIAL OBJECTS.

Author

Khudov, Hennadii, Kostianets, Oleksandr, Kovalenko, Oleksandr, Maslenko, Oleh, and Solomonenko, Yuriy

Subjects

SOFTWARE radio, DIRECTIONAL antennas, ARTIFICIAL satellites in navigation, RADIO technology, SIGNAL-to-noise ratio, TRACKING algorithms, COORDINATES

Abstract

The object of this study is the process of determining the coordinates of low-visible aerial objects. The main hypothesis of the research assumed that the signals emitted by airborne systems of airborne objects that are not visible to radar stations have a greater power than the signal reflected from the airborne object. This, in turn, could improve the signal/noise ratio and, accordingly, the accuracy of determining the coordinates of low-visible aerial objects. It is suggested to use Software-Defined Radio receivers to receive such signals emitted by on-board systems of low-visible aerial objects. It was established that the main sources of signals for Software-Defined Radio receivers are signals of command, telemetry, target channels, manual control channels, and satellite navigation. It was established that an additional distinguishing feature when determining the coordinates of low-visible aerial objects is the uniqueness of their spectra and spectrograms. The method of determining the coordinates of low-visible aerial objects when using Software-Defined Radio receivers has been improved, which, unlike the known ones, involves: – the use as signals for Software-Defined Radio of signal receivers of on-board equipment of low-visible aerial objects; – the use of a priori coordinate values of a low-visible aerial object; – conducting additional spectral analysis of signals of on-board systems of low-visible aerial objects. The spectra and spectrograms of signals of on-board systems of aerial objects when using non-directional and directional antennas were experimentally determined. The experimental studies confirm the possibility of using the Software-Defined Radio receiver to receive signals from airborne equipment and improve the signal-to-noise ratio. The accuracy of determining the coordinates of aerial objects when using Software-Defined Radio receivers was evaluated. A decrease in the error of determining plane coordinates by the Software-Defined Radio system of receivers compared to the accuracy of determining coordinates by the P-19 MA radar station was established by an average of 1.88–2.47 times, depending on the distance to the aerial object. [ABSTRACT FROM AUTHOR]

Published

2023

50. Modeling of Burst Impulse Noise Errors in an In-House M-QAM-Based Power Line Communications Channel Using the Fritchman–Markov Model.

Author

Iyiola, Akintunde O., Familua, Ayokunle D., Swart, Theo G., and Shongwe, Thokozani

Subjects

*CARRIER transmission on electric lines, *MARKOV processes, *BURST noise, *QUADRATURE amplitude modulation, *DATA transmission systems, *STATISTICAL errors

Abstract

Within the power line communication (PLC) network, a large number of electronic devices are connected, and environmental factors can cause unusual behavior, leading to high-amplitude impulse noise in the received signal and, as a result, packet losses and burst errors in the data that are sent. Burst errors make it difficult to send data over power line channels efficiently and accurately. Analyzing error patterns with intelligent techniques can provide valuable insights into data transmission efficiency, enhance transmission quality, and optimize PLC systems. This research proposes a three-state Fritchman–Markov chain-based power line communication error model and develops a software-defined PLC system. The goal is to analyze and model the system's statistical error process. The PLC system's fundamental error pattern is deduced from the transmission and reception of data on our software-defined (SD) PLC platform. The system is designed with multi-state quadrature amplitude modulation (M-QAM) data transmission and reception techniques. An error pattern consisting of 50,000 bits is obtained by comparing the bits transmitted with those received using the in-house M-QAM-based PLC transceiver system. The error characteristics of the newly developed M-QAM SD-PLC system are precisely modeled using the error model. Examining the burst error statistics of the reference error sequences of the SD-PLC system and the three-state Fritchman–Markov error model reveals striking similarities. According to the results, the error model accurately represents the error characteristics of the developed M-QAM SD-PLC system. The proposed three-state Fritchman–Markov chain-based error model for PLC has the potential to provide a comprehensive understanding of the error process in PLC. Additionally, it can assess error control strategies with less computational complexity and a shorter simulation time. [ABSTRACT FROM AUTHOR]

Published

2023