State of the art baseband DSP platforms for Software Defined Radio: A survey

Software Defined Radio (SDR) is an innovative approach which is becoming a more and more promising technology for future mobile handsets. Several proposals in the field of embedded systems have been introduced by different universities and industries to support SDR applications. This article presents an overview of current platforms and analyzes the related architectural choices, the current issues in SDR, as well as potential future trends.Peer reviewe

Portable Waveform Development for Software Defined Radios

This work focuses on the question: "How can we build waveforms that can be moved from one platform to another?\u27\u27 Therefore an approach based on the Model Driven Architecture was evaluated. Furthermore, a proof of concept is given with the port of a TETRA waveform from a USRP platform to an SFF SDR platform

FPGA-based Implementation of Multiple PHY Layers of IEEE 802.15.4 Targeting SDR Platform

International audienceWhile SDR platforms become more and more accessible to a large community of researchers with affordable prices, open source FPGA-based implementation of wireless communication systems are still not available. This paper presents an open source FPGA-based design of IEEE 802.15.4 PHY Layers developed in the context of a new SDR testbed named FIT/CorteXlab. We propose a VHDL implementation of the three available options of the IEEE 802.15.4 physical layer parametrized and easily reconfigurable. We have validated our design on Nutaq platform which combines Xilinx Virtex-6 FPGA and tunable Radio420x RF transceiver. A tutorial style approach is adopted to describe the multiple PHY Layers of both the baseband TX and RX IPs of IEEE 802.15.4 standard. More focus is given to the symbol timing/carrier recovery and considerations for FPGA implementation are outlined. The IPs presented here will participate to the building of an open source hardware SDR library similar to GNU radio but targeted to FPGA-based platforms.Nous présentons une implémentation FPGA opensource de la couche physique du standard IEEE 802.15.4. Cette implémentation est réalisée dans le cadre de l'équipex FIT/CorteXlab, sur une plateforme Nutaq qui contient un FPGA Xilinx Virtex-6 et un front-end radio flexible Radio420x RF

Architecture and Analysis for Next Generation Mobile Signal Processing.

Mobile devices have proliferated at a spectacular rate, with more than 3.3 billion active cell phones in the world. With sales totaling hundreds of billions every year, the mobile phone has arguably become the dominant computing platform, replacing the personal computer. Soon, improvements to today’s smart phones, such as high-bandwidth internet access, high-definition video processing, and human-centric interfaces that integrate voice recognition and video-conferencing will be commonplace. Cost effective and power efficient support for these applications will be required. Looking forward to the next generation of mobile computing, computation requirements will increase by one to three orders of magnitude due to higher data rates, increased complexity algorithms, and greater computation diversity but the power requirements will be just as stringent to ensure reasonable battery lifetimes. The design of the next generation of mobile platforms must address three critical challenges: efficiency, programmability, and adaptivity. The computational efficiency of existing solutions is inadequate and straightforward scaling by increasing the number of cores or the amount of data-level parallelism will not suffice. Programmability provides the opportunity for a single platform to support multiple applications and even multiple standards within each application domain. Programmability also provides: faster time to market as hardware and software development can proceed in parallel; the ability to fix bugs and add features after manufacturing; and, higher chip volumes as a single platform can support a family of mobile devices. Lastly, hardware adaptivity is necessary to maintain efficiency as the computational characteristics of the applications change. Current solutions are tailored specifically for wireless signal processing algorithms, but lose their efficiency when other application domains like high definition video are processed. This thesis addresses these challenges by presenting analysis of next generation mobile signal processing applications and proposing an advanced signal processing architecture to deal with the stringent requirements. An application-centric design approach is taken to design our architecture. First, a next generation wireless protocol and high definition video is analyzed and algorithmic characterizations discussed. From these characterizations, key architectural implications are presented, which form the basis for the advanced signal processor architecture, AnySP.Ph.D.Electrical EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttp://deepblue.lib.umich.edu/bitstream/2027.42/86344/1/mwoh_1.pd

Subsampling receivers with applications to software defined radio systems

Este trabajo de tesis propone la utilización sistemas basados en submuestreo como una alternativa para la implementación de la etapa de down-conversion de los receptores de radio frecuencia (RF) empleados para aplicaciones multi-estándar y SDR (Software Defined Radio). El objetivo principal será el de optimizar el diseño en cuanto a flexibilidad y simplicidad, las cuales son propiedades inherentes en los sistemas basados en submuestreo. Por tanto, como reducir el número de componentes al mínimo es clave cuando un mismo receptor procesa diferentes estándares de comunicación, las arquitecturas basadas en submuestreo han sido seleccionadas, donde la reusabilidad de los componentes empleados es posible, así como la reducción de los costes totales de los receptores de comunicación y de los equipos de certificación que emplean estas arquitecturas. Un motivo adicional por el que los sistemas basados en submuestreo han sido seleccionados es el concerniente a la topología del receptor. Como la idea de la tecnología SDR es implementar todas las funcionalidades del receptor (filtrado, amplificación) en el dominio digital, el convertidores analógico-digital (ADC) deberá estar localizado en la cadena de recepción lo más cerca posible a la antena, siendo el objetivo final el convertir la señal directamente de RF a digital. Sin embargo, con los actuales ADC no es posible implementar esta idea debido al alto ancho de banda que necesitarían sin perder resolución para cubrir las especificaciones de los estándares de comunicaciones inalámbricas. Por tanto, los sistemas basados en submuestreo se presentan como la opción más adecuada para implementar este tipo de sistemas debido a que pueden muestrear la señal de entrada por debajo de la tasa de Nyquist, si se cumplen ciertas restricciones en cuanto a la elección de la frecuencia de muestreo. De este modo, los requerimientos del ADC serán relajados ya que, usando estas arquitecturas, este componente procesará la señal a frecuencias intermedias. Una vez se han introducido los conceptos principales de las técnicas de submuestreo, esta tesis doctoral presenta el diseño de una tarjeta de adquisición de datos basada en submuestreo con la finalidad de ser implementada como un receptor de test y certificación de banda ancha. El sistema propuesto proporciona una alta resolución para un elevado ancho de banda, a partir del uso de un S&H de bajo jitter y de un convertidor analógico digital ADC que trabaja a frecuencias intermedias. El sistema es implementado usando dispositivos comerciales en una placa de circuito impreso diseñada y fabricada, y cuya caracterización experimental muestra una resolución de más 8 bits para un ancho de banda analógico de 20 MHz. Concretamente, la resolución medida será mayor de 9 bits hasta una frecuencia de entrada de 2.9 GHz y mayor de 8 bits para una frecuencia de entrada de hasta 6.5 GHz, lo cual resulta suficiente para cubrir los requerimientos de la mayor parte de los actuales estándares de comunicaciones inalámbricas (GPS, GSM, GPRS, UMTS, Bluetooth, Wi-Fi, WiMAX). Sin embargo, los receptores basados en submuestreo presentan algunos importantes inconvenientes, como son adicionales fuentes de ruido (jitter y plegado de ruido térmico) y una dificultad añadida para implementarlo en escenarios multi-banda y no lineales. Acerca del plegado de ruido en la banda de interés, esta tesis propone el uso de una técnica basada en una arquitectura de reloj múltiple con el objetivo de aumentar la resolución y cubrir un número mayor de estándares para su test y certificación. Empleando una frecuencia de muestreo mayor para el caso del S&H, se conseguirá reducir este efecto, aumentando la resolución en aproximadamente 0.5-1 bit respecto al caso de sólo usar una fuente de reloj. Las expresiones teóricas de esta mejora son desarrolladas y presentadas en esta tesis, siendo posteriormente corroboradas de modo experimental. Por otra parte, esta tesis también propone novedosas técnicas para la aplicación de estos sistemas de submuestreo en entornos multi-banda y no lineales, los cuales presentan desafíos adicionales por el hecho de existir la posibilidad de solapamiento entre la señal de interés y los otros canales de comunicación, así como de solapamiento con sus armónicos. De este modo, esta tesis extiende el uso de los sistemas basados en submuestreo para este tipo de entornos, proponiendo técnicas para la elección de la frecuencia óptima de muestreo que evitan el solapamiento entre señales, a la vez que consiguen incrementar la resolución del receptor. Finalmente, se presentará la optimización en cuanto a características de ruido de un receptor concreto para aplicaciones de banda dual en entornos no lineales. Dicho receptor estará basado en las técnicas de reloj múltiple presentadas anteriormente y en una estructura de multi-filtro entre el S&H y el ADC. El sistema diseñado podrá emplearse para diversas aplicaciones a ambos lados de la cadena de comunicación, tal como en receptores de detección de espectro para radio cognitiva, o implementando el bucle de realimentación de un transmisor para la linealización de amplificadores de potencia. Por tanto, la presente tesis doctoral cuenta con tres contribuciones diferenciadas. La primera de ellas es la dedicada al diseño de un prototipo de recepción multi-estándar basado en submuestreo para aplicaciones de test y certificación. La segunda aportación es la dedicada a la optimización de las especificaciones de ruido a partir de las técnicas presentadas basadas en reloj múltiple. Por último, la tercera contribución principal es la relacionada con la extensión de este tipo de técnicas a sistemas multi-banda en entornos no lineales. Todas estas contribuciones han sido estudiadas teóricamente y experimentalmente validadas

Channelization for Multi-Standard Software-Defined Radio Base Stations

As the number of radio standards increase and spectrum resources come under more pressure, it becomes ever less efficient to reserve bands of spectrum for exclusive use by a single radio standard. Therefore, this work focuses on channelization structures compatible with spectrum sharing among multiple wireless standards and dynamic spectrum allocation in particular. A channelizer extracts independent communication channels from a wideband signal, and is one of the most computationally expensive components in a communications receiver. This work specifically focuses on non-uniform channelizers suitable for multi-standard Software-Defined Radio (SDR) base stations in general and public mobile radio base stations in particular. A comprehensive evaluation of non-uniform channelizers (existing and developed during the course of this work) shows that parallel and recombined variants of the Generalised Discrete Fourier Transform Modulated Filter Bank (GDFT-FB) represent the best trade-off between computational load and flexibility for dynamic spectrum allocation. Nevertheless, for base station applications (with many channels) very high filter orders may be required, making the channelizers difficult to physically implement. To mitigate this problem, multi-stage filtering techniques are applied to the GDFT-FB. It is shown that these multi-stage designs can significantly reduce the filter orders and number of operations required by the GDFT-FB. An alternative approach, applying frequency response masking techniques to the GDFT-FB prototype filter design, leads to even bigger reductions in the number of coefficients, but computational load is only reduced for oversampled configurations and then not as much as for the multi-stage designs. Both techniques render the implementation of GDFT-FB based non-uniform channelizers more practical. Finally, channelization solutions for some real-world spectrum sharing use cases are developed before some final physical implementation issues are considered

Configurable circuits and their impact on multi-standard RF front-end architectures

This thesis studies configurable circuits and their impact on multi-standard RF front-end architectures. In particular, low-voltage low-power linear LNA and mixer topologies suitable for implementation in multi-standard front-ends are subject of the investigation. With respect to frequency and bandwidth, multi-standard front-ends can be implemented using either tunable or wideband LNA and mixer topologies. Based on the type of the LNA and mixer(s), multi-standard receiver RF front-ends can be divided into three groups. They can be (tunable) narrow-band, wide-band or combined. The advantages and disadvantages of the different multi-standard receiver RF front-ends have been discussed in detail. The partitioning between off-chip selectivity, on-chip selectivity provided by the LNA and mixer, linearity, power consumption and occupied chip area in each multi-standard RF front-end group are thoroughly investigated. A Figure of Merit (FOM) for the multi-standard receiver RF front-end has been introduced. Based on this FOM the most suitable multi-standard RF front-end group in terms of cost-effectiveness can be selected. In order to determine which multi-standard RF front-end group is the most cost-effective for a practical application, a GSM850/E-GSM/DCS/PCS/Bluetooth/WLANa/b/g multi-standard receiver RF front-end is chosen as a demonstrator. These standards are the most frequently used standards in wireless communication, and this combination of standards allows to users almost "anytime-anywhere" voice and data transfer. In order to verify these results, three demonstrators have been defined, designed and implemented, two wideband RF front-end circuits in 90nm CMOS and 65nm CMOS, and one combined multi-standard RF front-end circuit in 65nm CMOS. The proposed multi-standard demonstrators have been compared with the state-of the art narrow-band, wide-band and combined multi-standard RF front-ends. On the proposed multi-standard RF front-ends and the state-of the art multi-standard RF front-ends the proposed FOM have been applied. The comparison shows that the combined multi-standard RF front-end group is the most cost effective multi-standard group for this application

Applications in Electronics Pervading Industry, Environment and Society

This book features the manuscripts accepted for the Special Issue “Applications in Electronics Pervading Industry, Environment and Society—Sensing Systems and Pervasive Intelligence” of the MDPI journal Sensors. Most of the papers come from a selection of the best papers of the 2019 edition of the “Applications in Electronics Pervading Industry, Environment and Society” (APPLEPIES) Conference, which was held in November 2019. All these papers have been significantly enhanced with novel experimental results. The papers give an overview of the trends in research and development activities concerning the pervasive application of electronics in industry, the environment, and society. The focus of these papers is on cyber physical systems (CPS), with research proposals for new sensor acquisition and ADC (analog to digital converter) methods, high-speed communication systems, cybersecurity, big data management, and data processing including emerging machine learning techniques. Physical implementation aspects are discussed as well as the trade-off found between functional performance and hardware/system costs