Global ETD Search

11	PicoRF: A PC-based SDR Platform using a High Performance PCIe Plug-in Card Extension Said, Karim A. 29 October 2012 (has links) Wireless communication serves as the foundation for a wide range of services that have become an integral part of human life in this day and age. Driven by the desire to have a single piece of hardware that can provide multiple wireless services, attention has been directed to SDRs due to their programmable nature and the flexibility they can offer in operating over multiple standards. In addition, they can provide effective solutions to current challenges in wireless communication, such as spectrum overcrowding and inter-standard operability, as well as future challenges to come due to their upgradeability. Although SDRs have been around in the research community for over a decade, they have not reached the point of transitioning to the mass consumer market, size being one of the major obstacles. Numerous SDR hardware platforms have been developed demonstrating successful functionality, yet to this day most of them remain trapped in desktop/benchtop form factors which are not suited for mobility. A main factor contributing to the size of SDR units is the RF front end. Using current technology, wide-band operation of SDR RF front-ends is achieved by aggregating multiple dedicated components, each covering a portion of the frequency range. Recent technology advances have enabled the integration of wide frequency functionality inside a single integrated package. One example is a prototype RFIC transceiver chip from Motorola Research Labs which contains a complete direct conversion RF transceiver in a single chip, with a frequency coverage range of 100MHz-2.4GHz. RFIC5, the latest version of the chip, has additionally integrated high speed ADC and DAC units, leading to a significant reduction in the component count and the overall size of the SDR hardware. This thesis describes the implementation of a highly compact, SDR PC plug-in card, known as PicoRF. PicoRF is based on the Motorola's RFIC chip for the RF front-end functionality, while the combined computational power of a V5 FPGA and a PC host is used for waveform signal processing. An overlay gird consisting of an interconnection of PR slots is reserved on the FPGA to host the components of a signal processing pipeline which can be modified during run-time. Through a high speed PCIe connection, partial bitstreams can be downloaded from the host PC to the FPGA at a very high speed making it possible for the radio to modify its function in very short time intervals and greatly reducing the service interruption time. Control software running on the PC host manages the overall system operation including the RFIC which is controlled through a custom developed API. The combination of the laptop host and the plug-in card form a small form factor, mobile SDR node that is one step towards satisfying both the performance and ergonomics demand of the consumer market. / Master of Science PCI Express Partial Reconfiguration GNU Radio RFIC SDR
12	Radiolänk med GNU Radio Nordin Hellström, Kristopher, Williams, Kenny January 2008 (has links) <p>At the Department of Technology and Built environment at the University of Gävle there was an interest to study GNU Radio, which is an "open source radio project. The project is based on that most of the radio signal processing is made in an ordinary PC. The idea behind this degree project was that in a laptop there are several radio transmitters/receivers that takes space, generates heat and transmit in varied frequency band etcetera.</p><p> </p><p>All these radio transmitters/receivers could be replaced with a Software Defined Radio system. It means that one common, general radio hardware is used to different communications such as: WLAN, Bluetooth, GPRS, 3G etcetera. The waveform is generated in the software, which makes the system very flexible. To transmit and receive radio signals a USB-based hardware is required, for example from Ettus Research LLC.</p><p> </p><p>During this degree project two PC:s was used for the signal processing and the signal transferring. The operating system that was used on the computers, were the Linux based Ubuntu 8.04. To generate the signals, to modulate/demodulate the signals and to get the communication on the sound cards in/out-port working, the different packages in the GNU Radio software was used and for programming the high level language, Python, was used.</p><p> </p><p>In this degree project a lot of experiments where made, for example a sine wave was generated in computer 1 and the signal was amplitude modulated and transferred to computer 2, through the sound card. In computer 2 the signal was demodulated and filtrated, before it was saved to the hard drive. When the signal was saved on computer 2, it could be sent out on the sound card and be studied on an oscilloscope. This transfer between the computers was made with a stereo cable, but also with a radio link equipment on the University of Gävle.</p><p> </p><p>The result of this degree project was satisfying, because the signal was possible to modulate, transfer, demodulate and save. In the wire transfer a lot of noise was generated on to the signal, mostly because of the sound cards. When the wireless transfer was made it appeared more noise, because of the quality of the receiver, the transmitter and the antennas.</p><p> </p><p>This work can be developed to more advanced systems.</p> / <p>Vid Högskolan i Gävle på institutionen för Teknik och Byggd miljö (ITB) fanns ett intresse att undersöka GNU Radio, som är ett open source radio-projekt. Projektet bygger på att den största delen av radiosignalbehandlingen sker i en vanlig PC. Idén som låg till grund för detta examensarbete var att det i en laptop finns ett stort antal radiosändar- och mottagarkretsar som tar plats, genererar värme och sänder på olika frekvensband med mera.</p><p> </p><p>Alla dessa radiosändar- och mottagarkretsar skulle kunna ersättas med ett Software Defined Radio-system. Vilket innebär att en gemensam, generell radiohårdvara används för olika kommunikationer som: WLAN, Bluetooth, GPRS, 3G med flera. Vågformerna genereras i mjukvaran, vilket gör systemet mycket flexibelt. För att kunna ta emot och sända radiosignaler behövs en hårdvara. Denna hårdvara har bland annat Ettus Research LLC tagit fram, med USB-anslutning.</p><p> </p><p>Under examensarbetet har två stycken PC använts för behandling av signaler, samt överföring mellan dessa. Operativsystemet som användes på datorerna var det Linuxbaserade Ubuntu 8.04. För att generera signaler, modulation/demodulation av dessa signaler samt för att få kommunikation med ljudkortets in-/utgång att fungera, användes de olika paketen i mjukvaran GNU Radio och för programmering användes högnivåspråket Python.</p><p> </p><p>I detta examensarbete utfördes ett flertal experiment, bland annat genererades en sinussignal i dator 1 och signalen amplitudmodulerades och överfördes till dator 2 via ljudkortet. På dator 2 demodulerades denna signal och filtrerades, innan den sparades på hårddisken. Signalen kunde sedan skickas ut på ljudkortet och studeras med ett oscilloskop. Överföringen mellan datorerna gjordes med en stereokabel, men också med en radiolänkutrustning som fanns på Högskolan i Gävle.</p><p> </p><p>Resultatet var tillfredställande då signalen kunde moduleras, överföras samt demoduleras och sparas. I den trådbundna överföringen uppstod mycket brus i signalen, till största delen berodde detta på ljudkorten. När den trådlösa överföringen gjordes uppstod mera brus, vilket berodde på kvalitén hos mottagare, sändare och antennerna.</p><p> </p><p>Detta arbete kan utvecklas till mer avancerade system.</p> gnu gnu radio gnu project ubuntu python modulation usrp universal software radio peripheral gnu gnu radio gnu project ubuntu python modulation usrp universal software radio peripheral
13	Radiolänk med GNU Radio Nordin Hellström, Kristopher, Williams, Kenny January 2008 (has links) At the Department of Technology and Built environment at the University of Gävle there was an interest to study GNU Radio, which is an "open source radio project. The project is based on that most of the radio signal processing is made in an ordinary PC. The idea behind this degree project was that in a laptop there are several radio transmitters/receivers that takes space, generates heat and transmit in varied frequency band etcetera. All these radio transmitters/receivers could be replaced with a Software Defined Radio system. It means that one common, general radio hardware is used to different communications such as: WLAN, Bluetooth, GPRS, 3G etcetera. The waveform is generated in the software, which makes the system very flexible. To transmit and receive radio signals a USB-based hardware is required, for example from Ettus Research LLC. During this degree project two PC:s was used for the signal processing and the signal transferring. The operating system that was used on the computers, were the Linux based Ubuntu 8.04. To generate the signals, to modulate/demodulate the signals and to get the communication on the sound cards in/out-port working, the different packages in the GNU Radio software was used and for programming the high level language, Python, was used. In this degree project a lot of experiments where made, for example a sine wave was generated in computer 1 and the signal was amplitude modulated and transferred to computer 2, through the sound card. In computer 2 the signal was demodulated and filtrated, before it was saved to the hard drive. When the signal was saved on computer 2, it could be sent out on the sound card and be studied on an oscilloscope. This transfer between the computers was made with a stereo cable, but also with a radio link equipment on the University of Gävle. The result of this degree project was satisfying, because the signal was possible to modulate, transfer, demodulate and save. In the wire transfer a lot of noise was generated on to the signal, mostly because of the sound cards. When the wireless transfer was made it appeared more noise, because of the quality of the receiver, the transmitter and the antennas. This work can be developed to more advanced systems. / Vid Högskolan i Gävle på institutionen för Teknik och Byggd miljö (ITB) fanns ett intresse att undersöka GNU Radio, som är ett open source radio-projekt. Projektet bygger på att den största delen av radiosignalbehandlingen sker i en vanlig PC. Idén som låg till grund för detta examensarbete var att det i en laptop finns ett stort antal radiosändar- och mottagarkretsar som tar plats, genererar värme och sänder på olika frekvensband med mera. Alla dessa radiosändar- och mottagarkretsar skulle kunna ersättas med ett Software Defined Radio-system. Vilket innebär att en gemensam, generell radiohårdvara används för olika kommunikationer som: WLAN, Bluetooth, GPRS, 3G med flera. Vågformerna genereras i mjukvaran, vilket gör systemet mycket flexibelt. För att kunna ta emot och sända radiosignaler behövs en hårdvara. Denna hårdvara har bland annat Ettus Research LLC tagit fram, med USB-anslutning. Under examensarbetet har två stycken PC använts för behandling av signaler, samt överföring mellan dessa. Operativsystemet som användes på datorerna var det Linuxbaserade Ubuntu 8.04. För att generera signaler, modulation/demodulation av dessa signaler samt för att få kommunikation med ljudkortets in-/utgång att fungera, användes de olika paketen i mjukvaran GNU Radio och för programmering användes högnivåspråket Python. I detta examensarbete utfördes ett flertal experiment, bland annat genererades en sinussignal i dator 1 och signalen amplitudmodulerades och överfördes till dator 2 via ljudkortet. På dator 2 demodulerades denna signal och filtrerades, innan den sparades på hårddisken. Signalen kunde sedan skickas ut på ljudkortet och studeras med ett oscilloskop. Överföringen mellan datorerna gjordes med en stereokabel, men också med en radiolänkutrustning som fanns på Högskolan i Gävle. Resultatet var tillfredställande då signalen kunde moduleras, överföras samt demoduleras och sparas. I den trådbundna överföringen uppstod mycket brus i signalen, till största delen berodde detta på ljudkorten. När den trådlösa överföringen gjordes uppstod mera brus, vilket berodde på kvalitén hos mottagare, sändare och antennerna. Detta arbete kan utvecklas till mer avancerade system. gnu gnu radio gnu project ubuntu python modulation usrp universal software radio peripheral gnu gnu radio gnu project ubuntu python modulation usrp universal software radio peripheral
14	[en] IMPLEMENTATION OF THE ENERGY DETECTOR AND PERFORMANCE ANALYSIS SCHEMES IN GNU RADIO: SIMULATIONS AND TESTS / [pt] IMPLEMENTAÇÃO DO DETECTOR DE ENERGIA E ESQUEMAS DE ANÁLISE DE DESEMPENHO NO GNU RADIO: SIMULAÇÕES E TESTES ELIZEU CALEGARI 28 September 2018 (has links) [pt] O rádio cognitivo é uma tecnologia que visa o compartilhamento do espectro radioelétrico entre usuários primários licenciados e os demais usuários secundários de maneira harmoniosa, sem provocar interferências que prejudiquem a prestação dos serviços e visando uma melhoria na eficiência do uso do espectro radioelétrico, que é um recurso cada vez mais escasso. No âmbito da pesquisa referente a esta dissertação, é construído e implementado no GNU Radio um esquema de avaliação de desempenho de detectores para rádio cognitivo, é construído o detector de energia, e são implementadas simulações computacionais e ensaios por meio de duas USRP para avaliar o desempenho do detector criado, visando os requisitos do padrão IEEE 802.22. / [en] Cognitive radio is a technology that aims to share the radio spectrum between licensed primary users and other secondary users in a harmonious way without causing interference that prevent the services provision and aiming at an improvement in the efficiency in the use of the radioelectric spectrum, which is a resource increasingly scarce. In the scope of the research related to this dissertation, a performance evaluation scheme of cognitive radio detectors is constructed and implemented in GNU Radio, the energy detector is constructed, and computational simulations and tests are implemented through two USRPs to evaluate the performance of the detector created, targeting the requirements of the IEEE 802.22 standard. [pt] RADIO COGNITIVO [en] COGNITIVE RADIO [pt] DETECTOR DE ENERGIA [en] ENERGY DETECTOR [pt] SENSORIAMENTO DE ESPECTRO [en] SPECTRUM SENSING [pt] GNU RADIO [en] GNU RADIO [pt] USRP [en] USRP
15	Modulador 1-seg para SBTVD usando GNU Radio Maciel, Yuri Pontes 06 February 2015 (has links) Made available in DSpace on 2016-03-15T19:37:55Z (GMT). No. of bitstreams: 1 YURI PONTES MACIEL.pdf: 3993729 bytes, checksum: a06d968ea944e726fa6263339ad70976 (MD5) Previous issue date: 2015-02-06 / This paper describes by theoretical conceptualization and pratical experiences two relevant themes of electrical engineering and communications: software defined radio and the Brazilian digital television standard. This paper develops a specific modulator aimed to the portable reception of this digital television system, many times denominated as oneseg reception, by means of computational algorithms developed in the C++ programming language. These algorithms are executed in a development environment named GNU Radio, a open-source tool. Computer simulations are made to prove the correct behaviour of the project. Finnaly the modulator is implemented by means of a development kit of software defined radio then chained to a real communication system, thus proving its practical operation. It is also possible to verify the versatility of the software defined radio, changing the modulator parameters in a fast and easy fashion. / Este trabalho aborda por meio de conceituação teórica e experiências práticas dois temas relevantes da engenharia elétrica e de comunicações: rádios definidos por software e o padrão de televisão digital usado no Brasil. Este trabalho desenvolve um modulador específico para recepção portátil deste sistema de televisão digital, muitas vezes chamada de recepção one-seg, por meio da elaboração de algoritmos computacionais feitos na linguagem de programação C++. Estes algoritmos por sua vez são executados em um ambiente de desenvolvimento chamado GNU Radio, uma ferramenta do tipo open-source. Simulações computacionais são feitas de modo a comprovar o funcionamento do projeto. Finalmente o modulador é implementado em um kit de desenvolvimento de rádio definido por software e então encadeado em um sistema de comunicação real, assim comprovando o seu funcionamento prático. É possível também verificar a versatilidade do rádio definido por software, alterando as configurações do modulador de maneira rápida e prática. rádio definido por software televisão digital modulador SBTVD GNU Radio software defined radio digital television modulator SBTVD GNU Radio CNPQ::ENGENHARIAS::ENGENHARIA ELETRICA
16	Cloud native design of IoT baseband functions : Introduction to cloud native principles / Cloud native design av IoT basebandfunktioner : Introduktion till molnprinciper Bakthavathsalu, Lalith Kumar January 2020 (has links) The exponential growth of research and deployment of 5G networks has led to an increased interest in massive Machine Type Communications (mMTC), as we are on the quest to connect all devices. This can be attributed to the constant development of long-distance and low-powered Internet-of- Things (IoT) technologies, or, Low Power Wide Area Network (LPWAN) technologies such as Long-Range (LoRa) and Narrow Band- IoT (NB-IoT). These technologies are gaining prominence in the IoT domain as the number of LPWAN connected devices has doubled from 2018 to 2019. This increase in devices warrants a proportional number of gateways to push the data to the Internet for further analytics. The traditional LPWAN architectures do not provide dynamic scaling of resources or energy-efficient solutions. Thus, a Cloud-Native (CN) split architecture based on the functional characteristics of the components is a necessity. In this work, a software-based implementation of the LoRa stack on GNU Radio is designed and implemented using Software-Defined Radio (SDR). The LoRa gateway is implemented in software completely, replicating the functions of the hardware for communicating with any LoRa Network Server. Several experiments with different setups have been performed on the testbed to measure the resource utilization and packet delay of the LoRa Physical (PHY) and Medium Access Control (MAC) layers. Also, the testbed has been moved into Docker containers to emulate a cloud-based platform and make the transition faster. Higher throughput and lower delay (Improvement in the range of 1.3x - 6.7x) were recorded upon splitting the testbed into Radio Head (RH) and Edge containers. Finally, three potential functional split architectures including the gateway have been discussed while providing a fair trade-off between pooling gain and consumed bandwidth for a CN split architecture. / Den exponentiella tillväxten av forskning och distribution av 5G-nät har lett till ett ökat intresse för massive Machine Type Communicationsn (mMTC) eftersom vi är på jakt att ansluta alla enheter. Detta kan tillskrivas den ständiga utvecklingen av långdistans- och lågdrivna Internet-of-Things-teknologier (IoT) -teknologier, eller, Low Power Wide Area Network (LPWAN) tekniker som Long-Range (LoRa) och Narrow Band- IoT (NB-IoT). Dessa teknologier blir framträdande inom IoT-domänen eftersom antalet LPWAN-anslutna enheter har fördubblats från 2018 till 2019. Denna ökning av enheterna motiverar ett proportionellt antal portar för att driva data till Internet för ytterligare analys. De traditionella LPWAN-arkitekturerna ger inte dynamisk skalning av resurser eller energieffektiva lösningar. Således är en moln-infödd delad arkitektur baserad på funktionernas egenskaper hos komponenterna en nödvändighet. I detta arbete designas och implementeras en programvarubaserad implementering av LoRa-stacken på GNU Radio med hjälp av Software- Defined Radio (SDR). LoRa-gatewayen implementeras i mjukvara fullständigt, vilket replikerar maskinvarans funktioner för att kommunicera med någon LoRaNetwork Server. Flera experiment med olika inställningar har utförts på testbädden för att mäta resursutnyttjandet och paketfördröjningen för LoRa Physical (PHY) och Medium Access Control (MAC) -skikten. Testbädden har också flyttats in i Docker-behållare för att emulera en molnbaserad plattform och göra övergången snabbare. Högre genomströmning och lägre fördröjning (Förbättring inom intervallet 1,3x - 6,7x) registrerades vid uppdelning av testbädden i Radio Head (RH) och Edge containrar. Slutligen har tre potentiella funktionella splitarkitekturer inklusive gateway diskuterats samtidigt som det ger en rättvis avvägning mellan pooling av vinst och förbrukad bandbredd. Cloud-native Gateway GNU Radio IoT LoRa LPWAN Software-Defined Radio Cloud-native Gateway GNU Radio IoT LoRa LPWAN Software-Defined Radio Computer and Information Sciences Data- och informationsvetenskap
17	FPGA Co-Processing in Software-Defined Radios Fernandez, Leon January 2019 (has links) The Internet of Things holds great promises for the future. In the smart cities of tomorrow, wireless connectivity of everyday objects is deemed essential in ensuring efficient and sustainable use of vital, yet limited resources such as water, electricity and food. However, radio communication at the required scale does not come easily. Bandwidth is yet another limited resource that must be used efficiently so that wireless infrastructure for different IoT applications can coexist. Keeping up with the digitalization of modern society is difficult for wireless researchers and developers. The Software-Defined Radio (SDR) is a technology that allows swift prototyping and development of wireless systems by moving traditional hardware-based radio building blocks into the software domain. For developers looking to be on the bleeding edge of wireless technology, and thus keep up with the rapid digitalization, the SDR is a must. Many SDR systems consist of a radio peripheral that handles tasks such as amplification, AD/DA-conversion and resampling that are common to all wireless communication systems. The application-specific work is done in software at the baseband or an intermediate frequency by a host PC connected to the peripheral. That may include PHY-related processing such as the use of a specific modulation scheme as well as higher-layer tasks such as switching. While this setup does provide great flexibility and ease-of-use, it is not without its drawbacks. Many communication protocols specify a so-called round-trip time and devices wishing to adhere to the protocol must be able to respond to any transmission within that time. The link between the host and the peripheral is a major cause of latency and limits the use of many software-defined radio systems to proof-of-concept implementations and early prototyping since it prevents the round-trip time from being fulfilled. Overcoming the latency in the link would allow the flexibility of SDRs to be brought into field applications.This thesis aims to offload the link between the host PC and the radio peripheral in a typical SDR system. Selected parts IEEE 802.15.4, a wireless standard designed for IoT applications, were implemented by using unused programmable logic aboard the peripheral as a co-processor in order to reduce the amount of data that gets sent on the link. Frame success rate and round-trip time measurements were made and compared to measurements from a reference design without any co-processing in the radio peripheral. The co-processing greatly reduced traffic on the link while achieving a similar frame success rate as the reference design. In terms of round-trip time, the co-processing actually caused the latency to increase. Furthermore, the measurements from the coprocessing system showed a counter-intuitive behavior where the round-trip time decreased as the rate of the generated test frames increased. This unusual behavior is most likely due to internal buffer mechanisms of the operating system on the host PC. Further investigation is required in order to bring down the response time to a level more suitable for field applications. / Sakernas Internet, The Internet of Things (IoT), utlovar stora saker inom en snar framtid. I morgondagens smarta städer är trådlös uppkoppling av vardagliga ting en viktig komponent för effektiv och hållbar användning av begränsade resurser såsom vatten, elektricitet och mat. Desvärre är radiokommunikation i den skala som krävs en tuff utmaning. Bandbredd är ytterligare en begränsad resurs som måste användas effektivt så att trådlös infrastruktur för olika IoTapplikationer kan samexistera. Att hänga med i takten för det moderna samhällets digitalisering är svårt för forskare och utvecklare inom trådlösa system. Den mjukvarudefinierade radion, Software-Defined Radio (SDR), är en teknik som möjliggör smidig utveckling av trådlösa system. Grunden i tekniken är att flytta traditionella hårdvarubaserade byggblock för radio in i mjukvarudomänen. För utvecklare som vill befinna sig i framkanten för trådlösa system, och på så vis hålla takt med den snabba digitaliseringen, är SDR ett måste. Många SDR system består av en extern radiomodul som hanterar sådant som är gemensamt för de flesta trådlösa system, exempelvis förstärkning, AD/DA-omvandling och omsampling. Applikationsspecifik funktionalitet sköts av mjukvara i basbandet eller på en mellanfrekvens där mjukvaran körs på en PC. Ett SDR-system bestående av en PC med en extern radiomodul ger användaren stor flexibilitet men det har sina brister. Många kommunikationsprotokoll anger en så kallad Round-Trip Time (RTT). Enheter som strävar efter att följa protokollet måste kunna svara på alla meddelanden inom den tiden som angetts som RTT. Länken mellan PC:n och radiomodulen är en stor bidragare till fördröjningar och begränsar användandet av SDR till konceptuella tester och tidiga prototyper efter som fördröjningarna oftar innebär ett brott mot protokollets RTT. Om problemet med fördröjningar kan undvikas skulle SDR kunna användas i fältapplikationer med all den flexibilitet som SDR innebär och därmed bli ett kraftfullt utvecklingsverktyg för forskare och utvecklare inom området.Det här arbetet avser att avlasta länken mellan PC:n och radiomodulen i ett typiskt SDR system. Utvalda delar av IEEE 802.15.4, en standard för trådlös kommunikation inom IoT, implementerades med hjälp av programmerbar logik på USRP:n så att de flesta samplingarna konsumeras innan länken. Antalet framgångsrikt mottagna ramar samt RTT mättes och jämfördes med en referensdesign där samtliga beräkningar hanteras av PC:n. Användandet av den programmerbara logiken ledde till mycket reducerade datamängder på länken utan nämnvärd förändring i antalet framgångsrikt mottagna ramar jämfört med referensdesignen. Dock, vart fördröjningarna i systemet större när den programmerbara logiken användes. Dessutom visade systemet ett oväntat beteende där fördröjningen minskade under när trycket från den trådlösa trafiken ökade. Detta märkliga beteende beror högst troligt på interna buffermekanismer i operativsystemet i PC:n. Fortsatt utredning krävs innan fördröjningarna kan reduceras till en nivå som passar för fältapplikationer. Internet of Things Software-Defined Radio USRP GNU Radio IEEE 802.15.4 Sakernas Internet Mjukvarudefinierad Radio USRP GNU Radio IEEE 802.15.4 Elektroteknik och elektronik
18	Wireless transceiver for the TLL5000 platform : an exercise in system design Perkey, Jason Cecil 26 August 2010 (has links) This paper will present the hardware system design, development, and plan for implementation of a wireless transceiver for The Learning Labs 5000 (TLL5000) educational platform. The project is a collaborative effort by Vanessa Canac, Atif Habib, and Jason Perkey to design and implement a complete wireless system including physical hardware, physical layer (PHY-layer) modulation and filters, error correction, drivers and user-interface software. While there are a number of features available on the TLL5000 for a wide variety of applications, there is currently no system in place for transmitting data wirelessly from one circuit board to another. The system proposed in this report is comprised of an external transceiver that communicates with a software application running on the TLL-SILC 6219 ARM9 processor that is interfaced with the TLL5000 baseboard. The details of a reference design, the hardware from the GNU Radio project, are discussed as a baseline and source of information. The state of the project and hardware design is presented as well as the specific portions of the project to which Jason Perkey made significant contributions. / text Wireless transceiver Transceiver TLL5000 System design GNU radio Software-defined radio USRP
19	Estudo e implementação de un sistema IEEE 802.11g empregando o conceito de software Defined Radio Perez Junior, José Antonio Gonzalez January 2017 (has links) Orientador: Prof. Dr. Carlos Eduardo Capovilla / Dissertação (mestrado) - Universidade Federal do ABC, Programa de Pós-Graduação em Engenharia Elétrica, 2017. / Com a evolução dos meios de comunicação e a constante necessidade por altas taxas de transferencia de dados, a comunicação sem fio torna-se constantemente o principal e favorito meio para as mais diversas aplicações. Por aliar agilidade, desempenho e facilidade de instalação, é frequentemente encontrada em sistemas de controle, áudio e televisão, acesso a internet, etc. Porém, devido as imperfeições e ruído no canal, essa comunicação requer uma eficiente modulação e uma adequada proteção contra erros na transmissao dos dados. A versão IEEE 802.11g, presente em praticamente todos sistemas de comunicação moderno e amplamente difundido pelas redes conhecidas como WiFi surge como perfeita solução, pois permite alinhar técnicas robustas e efcientes, como a modulação OFDM e a codificação Convolucional. Alinhado ao conceito digital e a forma dinamica que a comunicação sem fio proporciona, o conceito de SDR (Software Dened Radio), torna-se uma interessante e poderosa ferramenta com a possibilidade de simulação e implementação de transceptores para diversas aplicaçõess em um único dispositivo. Assim, este projeto de mestrado tem como objetivo o estudo e testabilidade de um sistema IEEE 802.11g de comunicação sem fio utilizando dispositivo SDR, com foco em sistemas eficientes e de baixo custo, para fazer a interface entre o meio físico e o ambiente de processamento do sinal digital. / With the advancements of communication technology and the constant need for high rates of data transfer, wireless communication is consistently the main and favorite option for the most kind of applications. By combining agility, performance and fast installation, it is often found in control systems, audio and television systems, internet access, etc. However, due to the imperfections and noise in the channel, this communication requires an eficient modulation and an adequate protection against errors in the data transmission. The IEEE 802.11g standard, also used in practically all modern communication systems and widely difused by the networks known as WiFi, appears as a perfect solution, since it allows to align robust and eficient techniques such as OFDM modulation and Convolutional coding. Using digital concept and the dynamic behavior of wireless communication, the concept of SDR (Software Dened Radio) becomes an interesting and powerful tool because the possibility of simulation and implementation of transceivers for several applications in a single device. This project aims to make a wireless IEEE 802.11g communication system using Software Defined Radios focusing on low cost radios and high performance to make the interface between the real world and the digital signal processing. CODIFICAÇÃO CONVOLUCIONAL GNU RADIO SOFTWARE DEFINED RADIO CONVOLUTIONAL CODING
20	Desenvolvimento de algoritmos de sincronismo e estimação de canal no GNU radio companion para o sistema ISDB-T Sapia, Thiago Montanaro 20 February 2017 (has links) Submitted by Rosa Assis (rosa_assis@yahoo.com.br) on 2017-09-20T19:20:11Z No. of bitstreams: 2 THIAGO MONTANARO SAPIA.pdf: 2974525 bytes, checksum: 7bf36cf4094936e1ee2d72e23c1f7094 (MD5) license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) / Approved for entry into archive by Paola Damato (repositorio@mackenzie.br) on 2017-09-22T13:38:31Z (GMT) No. of bitstreams: 2 THIAGO MONTANARO SAPIA.pdf: 2974525 bytes, checksum: 7bf36cf4094936e1ee2d72e23c1f7094 (MD5) license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) / Made available in DSpace on 2017-09-22T13:38:31Z (GMT). No. of bitstreams: 2 THIAGO MONTANARO SAPIA.pdf: 2974525 bytes, checksum: 7bf36cf4094936e1ee2d72e23c1f7094 (MD5) license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) Previous issue date: 2017-02-20 / Conselho Nacional de Desenvolvimento Científico e Tecnológico / This essay presents theoretical concepts of the Brazilian Digital TV System (SBTVD) and Software De ned Radio (SDR). The purpose of this essay is to implement timing synchronization stages and a channel estimator to enable ISDB-TB reception via RF. Thus, enabling the analysis of the constellations of the received signals. To achieve this goal, it was used SDR concepts and the C++ and Python programming languages. Through the use of the GNU Radio tool, time, frequency and OFDM frame synchronization were implemented. Besides that, a channel estimator was also implemented Computer simulations were carried out to verify the performance of the implementations. / Este trabalho apresenta uma descricão sobre o Sistema Brasileiro de TV Digital (SBTVD) e Software De fined Radio (SDR). O objetivo deste trabalho é implementar um estimador de canal e estágios de sincronismo para receber sinais ISDB-TB via RF. Com isso, sendo possível a análise das constelacões dos sinais recebidos. Para tal, foram utilizados conceitos de SDR e as linguagens de programacão C++ e Python. Por meio da ferramenta aberta GNU Radio, foram realizadas implementacões de sincronismo no tempo, frequência (inteira e fracionária) e de quadro OFDM. Além disso, um estimador de canal foi implementado. Simulacões computacionais foram realizadas para veri ficar o funcionamento das implementacões. ISDB-T SDR rádio definido por software GNU radio

Search results