Design of a UAV-based radio receiver for avalanche beacon detection using software defined radio and signal processing

Hedlund, Richard

January 2019

A fully functional proof of concept radio receiver for detecting avalanche beacons atthe frequency 457 kHz was constructed in the work of this master thesis. The radioreceiver is intended to be mounted on an unmanned aerial vehicle (UAV or drone)and used to aid the mountain rescue teams by reducing the rescue time in findingavalanche victims carrying a transmitting beacon. The main parts of this master thesisinvolved hardware requirement analysis, software development, digital signalprocessing and wireless communications. The radio receiver was customized to receive low power signal levels becausemagnetic antennas are used and the avalanche beacon will operate in the reactive nearfield of the radio receiver. Noise from external sources has a significant impact on theperformance of the radio receiver. This master thesis allows for straightforward further development and refining of theradio receiver due to the flexibility of the used open-source software development kitGNU Radio where the digital signal processing was performed.

Signal processing

Software Defined Radio

Avalanche

Beacon

Antenna

SDR

DSP

Signalbehandling

Mjuvarudefinierad Radio

Lavin

Lavinsändare

Antenn

SDR

DSP

Signal Processing

Signalbehandling

Jitter-Tolerance and Blocker-Tolerance of Delta-Sigma Analog-to-Digital Converters for Saw-Less Multi-Standard Receivers

Ahmed, Ramy 1981-

14 March 2013

The quest for multi-standard and software-defined radio (SDR) receivers calls for high flexibility in the receiver building-blocks so that to accommodate several wireless services using a single receiver chain in mobile handsets. A potential approach to achieve flexibility in the receiver is to move the analog-to-digital converter (ADC) closer to the antenna so that to exploit the enormous advances in digital signal processing, in terms of technology scaling, speed, and programmability. In this context, continuous-time (CT) delta-sigma (ΔƩ) ADCs show up as an attractive option. CT ΔƩ ADCs have gained significant attention in wideband receivers, owing to their amenability to operate at a higher-speed with lower power consumption compared to discrete-time (DT) implementations, inherent anti-aliasing, and robustness to sampling errors in the loop quantizer. However, as the ADC moves closer to the antenna, several blockers and interferers are present at the ADC input. Thus, it is important to investigate the sensitivities of CT ΔƩ ADCs to out-of-band (OOB) blockers and find the design considerations and solutions needed to maintain the performance of CT ΔƩ modulators in presence of OOB blockers. Also, CT ΔƩ modulators suffer from a critical limitation due to their high sensitivity to the clock-jitter in the feedback digital-to-analog converter (DAC) sampling-clock. In this context, the research work presented in this thesis is divided into two main parts. First, the effects of OOB blockers on the performance of CT ΔƩ modulators are investigated and analyzed through a detailed study. A potential solution is proposed to alleviate the effect of noise folding caused by intermodulation between OOB blockers and shaped quantization noise at the modulator input stage through current-mode integration. Second, a novel DAC solution that achieves tolerance to pulse-width jitter by spectrally shaping the jitter induced errors is presented. This jitter-tolerant DAC doesn’t add extra requirements on the slew-rate or the gain-bandwidth product of the loop filter amplifiers. The proposed DAC was implemented in a 90nm CMOS prototype chip and provided a measured attenuation for in-band jitter induced noise by 26.7dB and in-band DAC noise by 5dB, compared to conventional current-steering DAC, and consumes 719µwatts from 1.3V supply.

Delta-Sigma (ΔƩ) modulators

analog-to-digital converter (ADC)

blocker-tolerance

clock-jitter

continuous-time (CT) ΔƩ

multi-standard receivers

software-defined radio (SDR)

Implementation of a Software-Defined Radio Transceiver on High-Speed Digitizer/Generator SDR14

Björklund, Daniel

January 2012

This thesis describes the specification, design and implementation of a software-defined radio system on a two-channel 14-bit digitizer/generator. The multi-stage interpolations and decimations which are required to operate two analog-to-digital converters at 800 megasamples per second (MSps) and two digital-to-analog converters at 1600 MSps from a 25 MSps software-side interface, were designed and implemented. Quadrature processing was used throughout the system, and a combination of fine-tunable low-rate mixers and coarse high-rate mixers were implemented to allow frequency translation across the entire first Nyquist band of the converters. Various reconstruction filter designs for the transmitter side were investigated and a cheap implementation was done through the use of programmable base-band filters and polynomial approximation.

transceiver

complex mixer

software defined radio

SDR

up-conversion

down-conversion

DUC

DDC

high-rate

high-speed

inverse-sinc

reconstruction

FPGA

SP Devices

Maximizing the Utility of Radio Spectrum: Broadband Spectrum Measurements and Occupancy Model for Use by Cognitive Radio

Petrin, Allen John

19 July 2005

Radio spectrum is a vital national asset; proper management of this finite resource is essential to the operation and development of telecommunications, radio-navigation, radio astronomy, and passive remote sensing services. To maximize the utility of the radio spectrum, knowledge of its current usage is beneficial. As a result, several spectrum studies have been conducted in urban Atlanta, suburban Atlanta, and rural North Carolina. These studies improve upon past spectrum studies by resolving spectrum usage by nearly all its possible parameters: frequency, time, polarization, azimuth, and location type. The continuous frequency range from 400MHz to 7.2 GHz was measured with a custom-designed system. More than 8 billion spectrum measurements were taken over several months of observation. A multi-parameter spectrum usage detection method was developed and analyzed with data from the spectrum studies. This method was designed to exploit all the characteristics of spectral information that was available from the spectrum studies. Analysis of the spectrum studies showed significant levels of underuse. The level of spectrum usage in time and azimuthal space was determined to be only 6.5 % for the urban Atlanta, 5.3 % for suburban Atlanta, and 0.8 % for the rural North Carolina spectrum studies. Most of the frequencies measured never experienced usage. Interference was detected in several protected radio astronomy and sensitive radio navigation bands. A cognitive radio network architecture to share spectrum with fixed microwave systems was developed. The architecture uses a broker-based sharing method to control spectrum access and investigate interference issues.

Spectrum management

Radio spectrum

Cognitive radio

Software defined radio

Usage detection

Radio broadcasting

Radio Interference

Radio frequency allocation

Broadband communication systems

Digital Radio Implementation for NASA S-Band Space Network Transceiver

Berhanu, Samuel, Neupane, Kamal

10 1900

The system diagrams for the digital radio compatible with NASA's S-Band Space Network operating from 2025.8 - 2117.9 MHz (forward link) to 2200 - 2300 MHz (return link) are presented. The digital radio implementation includes binary phase shift keying (BPSK), quadrature phase shift keying (QPSK) and staggered quadrature phase shift keying (SQPSK). We have derived the system requirements for these modulation schemes from the Space Network User Guide (SNUG) and thereafter, derived system diagrams for the communication links. The designed system diagrams for the transceiver were implemented using Simulink models and USRP2 platform.

Software Defined Radio (SDR)

Digital Radio (DR)

Space Network User Guide (SNUG)

Binary Phase Shift Keying (BPSK)

Quadrature Phase Shift Keying (QPSK)

Design of concurrent cooperative transmission systems on software-defined radios

Chang, Yong Jun

13 January 2014

Concurrent cooperative transmission (CCT) occurs when a collection of power-constrained single-antenna radios transmit simultaneously to form a distributed multi-input and multi-output (DMIMO) link. DMIMO can be a means for highly reliable and low-latency cooperative routing, when the MIMO channel is exploited for transmit and receive diversity; in this context, the range extension benefit is emphasized. Alternatively, DMIMO can be a means for high-throughput ad hoc networking, when the MIMO channel is used with spatial multiplexing. In both cases, concatenated DMIMO links are treated. The key contribution of this dissertation is a method of pre-synchronization of distributed single-antenna transmitters to form a virtual antenna array, in the absence of a global clock, such as a global positioning system (GPS) receiver or a network time protocol (NTP) to provide reference signals for the synchronization. Instead, the reference for synchronization comes from a packet, transmitted by the previous virtual array and simultaneously received by all the cooperative transmitters for the next hop. The method is realized for two types of modulation: narrowband non-coherent binary frequency-shift keying (NCBFSK) and wideband orthogonal frequency division multiplexing (OFDM). The pre-synchronization algorithms for transmission are designed to minimize the root-mean-square (RMS) transmit time, sampling and carrier frequency error between cooperative transmitters, with low implementation complexity. Since CCT is not supported by any existing standard or off-the-shelf radios, CT must be demonstrated by using software-defined radios (SDRs). Therefore, another contribution is a fully self-contained and real-time SDR testbed for CCT-based networking. The NCBFSK and OFDM systems have been designed and implemented in C++ and Python programming languages in the SDR testbed, providing practical performance of the CCT-based systems.

Cooperative communication

Concurrent cooperative transmission

Distributed MIMO

Software-defined radio

Implementation

Testbed

MIMO systems

Wireless communication systems

Radio Packet transmission

Digital communications

Synchronization

Antenna arrays

Feasibility of a Direct Sampling Dual-Frequency SDR Galileo Receiver for Civil Aviation / Faisabilité d’un récepteur Galileo SDR bi-fréquence à échantillonnage direct pour l’Aviation Civile

Blais, Antoine

25 September 2014

Cette thèse étudie l'intérêt des architectures SDR à échantillonnage direct pour des récepteurs Galileo dans le contexte particulier de l'Aviation Civile, caractérisé notamment par une exigence de robustesse à des interférences bien spécifiées, principalement les interférences causées par les signaux DME ou CW. Le concept de Software Defined Radio traduit la migration toujours plus grande, au sein des récepteurs, des procédés de démodulation d'une technologie analogique à du traitement numérique, donc de façon logicielle. La quasi généralisation de ce choix de conception dans les architectures nouvelles nous a conduit à le considérer comme acquis dans notre travail. La méthode d'échantillonnage direct, ou Direct Sampling, quant à elle consiste à numériser les signaux le plus près possible de l'antenne, typiquement derrière le LNA et les filtres RF associés. Cette technique s'affranchit donc de toute conversion en fréquence intermédiaire, utilisant autant que possible le principe de l'échantillonnage passe-bande afin de minimiser la fréquence d'échantillonnage et en conséquence les coûts calculatoires ultérieurs. De plus cette thèse s'est proposée de pousser jusqu'au bout la simplification analogique en renonçant également à l'utilisation de l'AGC analogique qui équipe les récepteurs de conception traditionnelle. Seuls des amplificateurs à gain fixe précéderont l'ADC. Ce mémoire rend compte des travaux menés pour déterminer si ces choix peuvent s'appliquer aux récepteurs Galileo multifréquences (signaux E5a et E1) destinés à l'Aviation Civile. La structure du document reflète la démarche qui a été la notre durant cette thèse et qui a consisté à partir de l'antenne pour, d'étape en étape, aboutir au signal numérique traité par la partie SDR. Après une introduction détaillant le problème posé et le contexte dans lequel il s'inscrit, le deuxième chapitre étudie les exigences de robustesse aux interférences auquel doit se soumettre un récepteur de navigation par satellites destiné à l'Aviation Civile. Il s'agit de la base qui conditionne toute la démarche à suivre. Le troisième chapitre est consacré au calcul des fréquences d'échantillonnage. Deux architectures d'échantillonnage sont proposées. La première met en oeuvre un échantillonnage cohérent des deux bandes E5a et E1 tandis que la seconde implémente un échantillonnage séparé. Dans les deux cas, la nécessité de filtres RF supplémentaires précédant l'échantillonnage est mise en évidence. L'atténuation minimale que doivent apporter ces filtres est spécifiée. Ces spécifications sont suffisamment dures pour qu'il ait été jugé indispensable d'effectuer une étude de faisabilité. C'est l'objet du chapitre quatre où une approche expérimentale à base d'un composant disponible sur étagère a été menée. La problématique de la gigue de l'horloge d'échantillonnage, incontournable ici eu égard à la haute fréquence des signaux à numériser, est étudiée dans le chapitre cinq. Des résultats de simulation sont présentés et un dimensionnement de la qualité de l'horloge d'échantillonnage est proposé. Dans le chapitre six, la quantification, second volet de la numérisation, est détaillée. Il s'agit très précisément du calcul du nombre minimum de bits de quantification que doit exhiber l'ADC pour représenter toute la dynamique, non seulement du signal utile mais aussi des interférences potentielles. Au vu des débits de données conséquents mis en évidence dans les chapitres trois et six, le chapitre sept évalue la possibilité de réduire la dynamique de codage du signal à l'aide de fonctions de compression. Le dernier chapitre est focalisé sur la séparation numérique des bandes E5a et E1 dans l'architecture à échantillonnage cohérent introduite au chapitre deux. Ici aussi l'atténuation minimale que doivent apporter les filtres requis est spécifiée. / This thesis studies the relevance of DS SDR architectures applied to Galileo receivers in the specific context of Civil Aviation, characterized in particular by strict requirements of robustness to interference, in particular, interference caused by DME or CW signals. The Software Defined Radio concept renders the major tendency, inside the receiver, to move the demodulation part from an analog technology to digital signal processing, that is software. The choice of this kind of design is nearly generalized in new receiver architectures so it was considered the case in this work. The Direct Sampling method consists in digitizing the signal as close as possible to the antenna, typically after the LNA and the associated RF bandpass filter. So this technique does not use any conversion to an intermediate frequency, using as much as possible the bandpass sampling principle in order to minimize the sampling frequency and consequently the downstream computational costs. What is more, this thesis aiming at the greatest simplification of the analog part of the receiver, the decision was made to suppress the analog AGC which equips the receivers of classical architecture. Only fixed gained amplifiers should precede the ADC. This document exposes the work done to determine if these choices can apply to a multifrequency (E5a and E1 signals) Galileo receiver intended for a Civil Aviation use. The structure of the document reflects the approach used during this thesis. It progresses step by step from the antenna down to the digital signal, to be processed then by the SDR part. After an introduction detailing the problem to study and its context, the second chapter investigates the Civil Aviation requirements of robustness to interference a satellite navigation receiver must comply with. It is the basis which completely conditions the design process. The third chapter is devoted to the determination of the sampling frequency. Two sampling architectures are proposed: the first implements coherent sampling of the two E5a and E1 bands while the second uses separate sampling. In both cases the necessity to use extra RF filters is shown. The minimum attenuation to be provided by these filters is also specified. These requirements are strong enough to justify a feasibility investigation. It is the subject of chapter four where an experimental study, based on a SAW filter chip available on the shelf, is related. The issue of the sampling clock jitter, of concern with the Direct Sampling technique because of the high frequency of the signal to digitize, is investigated in chapter five. Some simulation results are presented and a dimensioning of the quality of the sampling clock is proposed. In chapter six, quantization, a byproduct of digitization, is detailed. Precisely it is the calculation of the number of bits the ADC must have to digitally represent the whole dynamic of, not only the useful signal, but also of the potential interference. Considering the high binary throughput highlighted in chapters three and six, chapter seven evaluates the possibility to reduce the coding dynamic of the digital signal at the output of the ADC by means of compression functions. The last chapter is focused on the digital separation of the two E5a and E1 bands in the coherent sampling architecture presented in chapter two. Here also specifications of minimum attenuation are given. Lastly the conclusions synthesize the contributions of this thesis and proposes ideas for future work to enrich them and more generally the subject of DS-SDR Galileo receivers for Civil Aviation.

Echantillonnage direct

Sdr

Gnss

Aviation civile

Radio logicielle

Galileo

Récepteur

Bi-Bande

Direct sampling

Software defined radio

Civil aviation

Interference

Galileo

Receiver

Dual-Band

Étude de relais multi-mode sous contrainte d'énergie dans un contexte de radio logicielle / Study of multi-mode relay under energetic constraints in the context of software radio

Lévy-Bencheton, Cédric

28 June 2011

La réduction d’énergie apparaît comme un besoin crucial dans les télécommunications modernes, tant au niveau des terminaux que des réseaux. Dans les réseaux modernes, un terminal peut se connecter à Internet via d’autres terminaux ou infrastructures à proximité, appelés relais. Bien que les relais offrent une solution intéressante pour limiter la puissance de transmission des terminaux, il n’est pas simple de garantir une réduction de la consommation d’énergie globale. Il devient alors nécessaire de développer des outils pour évaluer et quantifier la consommation d’énergie. Un terminal moderne dispose de plusieurs interfaces de communications, ce qui lui permet d’utiliser plusieurs standards. Sachant qu’un standard dispose de différents modes de communications, un terminal est multi-mode lorsqu’il possède cette capacité à communiquer sur les différents standards et modes disponibles. Nous nous sommes alors intéressés à l’utilisation du multi-mode dans le cadre des relais. Nous nous positionnons dans un contexte de radio logicielle, où la couche physique d’un terminal est représentée par des blocs programmables, ce qui facilite l’implémentation du multi-mode. Afin d’estimer la consommation d’énergie d’une radio logicielle, nous avons calculé la complexité algorithmique pour les couches physiques du 802.11g (ou Wi-Fi), de l’UMTS et du 802.15.4 (ou Zigbee). Dans cette thèse, nous avons développé des outils nous permettant d’évaluer l’intérêt d’un relais multi-mode dans la réduction d’énergie. Nous avons proposé un modèle d’énergie réaliste pour le multi-mode, qui prend en compte la couche d’accès au medium des protocoles considérés. Dans un but de réalisme accru, nous avons implémenté le multi-mode au sein de WSNet, un simulateur réseau précis, grâce auquel nous avons déterminé les paramètres ayant un impact sur la consommation d’énergie. Puis, nous avons proposé et validé des stratégies permettant de minimiser l’influence de ces paramètres. / Energy reduction appears as a crucial need in modern telecommunications, be it for the terminals or the network. In modern networks, a terminal can connect to the Internet through other terminals or infrastructures in their proximity, called relays. Even though these relays appear as an interesting solution by limiting the terminals transmission power output, the reduction of energy consumption is not a simple task to ensure. Hence, it becomes necessary to develop adapted tools in order to evaluate and quantify the energy consumption. A modern terminal features several communication interfaces, which allows it to use different standards. With each standard featuring different communication modes, a multi-mode terminal has the capacity to communicate on these different modes and standard available. Hence, we have been studying how this multi-mode property can lead to energy reduction in combination with relaying. Our study is realized in the context of software defined radio, in which the physical layer is represented by programmable software blocks. Thus, software defined radio allows an eased implementation of multi-mode. In order to estimate the energy consumption of a software defined radio, we have evaluated the algorithmic complexity for the physical layers of the following standards : 802.11g (or Wi-Fi), UMTS and 802.15.4 (or Zigbee). In this thesis, we have developed the tools to evaluate the energy consumption of a multimode relay. Firstly, we have proposed a realistic energy model for multi-mode, which takes into account the media access control layer of the protocols studied. In order to increase realism, we have implemented multi-mode in WSNet, a precise network simulator, which we have used to determine the parameters impacting the energy consumption. Then, we have proposed and validated different strategies allowing us to minimize the influence of these parameters.

Télécommunications

Radiocommunications

Radio logicielle

Autonomie d'énergie

Relais multi-modes

Multi-antennes

Telecommunications

Radiocommunications

Software defined Radio

Autonomous Energy

Multi-mode Relay

Multi-antennas

621.384 507 2

Radios cognitivos : implemetnação de uma plataforma multiagentes / A multiagent framework for cognitive radio

Portelinha, Francisco Martins

01 December 2007

Orientador: Luiz Carlos Kretly / Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Engenharia Eletrica e de Computação / Made available in DSpace on 2018-08-08T18:48:25Z (GMT). No. of bitstreams: 1 Portelinha_FranciscoMartins_D.pdf: 24786076 bytes, checksum: 9371c9850eefc768ce24e777299b0788 (MD5) Previous issue date: 2007 / Resumo: Em freqüênciasabaixode 3 GHz, ocorreuma demandade bandas no espectrode freqüência, devido à expansãodas redes de comunicaçõessem fio, principalmentepara aplicações outdoor. Estudosmostram que há grandes lacunas no espectrode freqüência até a faixa de 3 GHz. O modelo de alocação do espetrode freqüência,já ultrapassado, precisa ser reformuladopara uso destas lacunas.A utilização do espectro deve sair do modelo estático,para o modelodinâmico.Rádioscognitivose redes de rádios cognitivos surgem como opção tecnológica para uso deste novo modelo. Apresentamos uma arquitetura inovadorapara a implementaçãode rádios cognitivos,baseadosnos modelos computacionais de: rádios definidos por software,agentes e frameworks.Um estudo de caso, para rádio cognitivo nível 2, é apresentado para uso não licenciado no espectro nas faixas licenciadas para TV. Um algoritmo inovador, para detecção da disponibilidade de canais, é desenvolvido utilizando redes neurais / Abstract: In frequencies lower than 3 GHz, a demand occurs out of the frequency spectrum due to the expansion of the wireless communication network, mainly for outdoor applications. Studies show that, there are great gaps of the frequency spectrum in the bands up to 3 GHz. The allocation model of the frequency spectrum needs reformulatiQn for the use of these gaps. This utilization must come from, the change of a static model to a dynamic one. Cognitive radio and cognitive radio networks rise as a technological option for the use of the new model. We introduce and an innovatory architecture for the implementation of cognitive radios, based on the computational models of: software defined radio, agents and frameworks. A case study, for cognitive radio leveI 2, is introduced for use in licensed TV bands. A new algorithm is developed to detect available channel / Doutorado / Telecomunicações e Telemática / Doutor em Engenharia Elétrica

Sistemas de comunicação sem fio

Espectro de frequência

Rádio

Inteligência artificial

Redes neurais (Computação)

Wireless communication

Frequency allocation model

Cognitive radio

Software defined radio

Agent's frameworks

Neural networks applications

Gap filler adaptativo para sistema ISDB-Tb

Rocha, Chrystianne

07 August 2014

Made available in DSpace on 2016-03-15T19:37:50Z (GMT). No. of bitstreams: 1 Chrystianne Rocha.pdf: 2924776 bytes, checksum: a1d74db138a8b87f0518f3a6ef67c404 (MD5) Previous issue date: 2014-08-07 / This master thesis presents the proposal of assigning the cognitive ability to a gap filler. Differently from the usual repeaters found on the market, the adaptive gap filler is able to automatically monitor tuned channels with the intention of verifying if the protection ratio described in Resolution nº398 from Anatel is being respected. Spectrum sensing techniques and the concepts related to coverage area will be addressed. Tests were carried out on the Matlab and GNU Radio Software with the purpose of analyzing the adaptive gap filler performance on real channels. / Este trabalho apresenta a proposta de atribuir ao gap filler a capacidade cognitiva . Diferentemente dos repetidores encontrados no mercado, o gap filler adaptativo tem como função monitorar, de forma autônoma, os canais sintonizados para verificar se a relação de proteção descrita na Resolução nº 398 da Anatel está sendo respeitada. Como fundamentos dessa proposta são abordadas as técnicas de sensoriamento do espectro e os conceitos relacionados às áreas de cobertura. Em uma abordagem prática, os testes foram desenvolvidos no Matlab e no GNU Radio, em que se analisa a atuação do gap filler adaptativo em canais reais.

gap filler

rádio cognitivo

TV digital

rádio definido por software (RDS)

gap filler

cognitive radio

digital TV

software defined radio (SDR)

CNPQ::ENGENHARIAS::ENGENHARIA ELETRICA