RF TRANSCEIVER DESIGN FOR WIRELESS SENSOR NETWORKS

Ph.DDOCTOR OF PHILOSOPH

Energy Aware RF Transceiver for Wireless Body Area Networks (WBAN)

Ph.DDOCTOR OF PHILOSOPH

Wireless sensor networks for flight applications

Die Prognosen der Marktentwicklung im Luftfahrtbereich sehen sehr positiv aus. In den kommenden 20 Jahren soll sich die Anzahl der Passagierflugzeuge verdoppeln, was sicherlich die Geschäfte im Luftfahrtbereich anregen wird. Jedoch bildet sich neue Konkurrenz in Asien, welche den Wettbewerb erhöhen wird. Um in dieser neuen Marktsituation weiterhin bestehen zu können, müssen Flugzeughersteller vermehrt innovative Flugzeugkonzepte entwickeln, mit welchen sie sich von ihren Konkurrenten absetzen können. Die meisten Innovationen zielen auf eine Reduzierung des Gewichts und auf höhere Energieeffizienz von Flugzeugen ab. Ebenso steht eine Reduzierung der Inbetriebnahme- und Betriebskosten im Fokus. Ein vielversprechender Ansatz diese Ziele zu erreichen, ist der Einsatz von drahtlosen Sensornetzen, um Luftfahrtanwendungen anzubinden. Der Einsatz so eines drahtlosen Sensornetzes kann in vielerlei Hinsicht Nutzen bringen. Verkabelung kann eingespart werden was große Gewichtsreduktionen mit sich bringt. Arbeitsabläufe können verbessert werden, wodurch Inbetriebnahme- und Betriebskosten reduziert werden können. Zusätzlich kann der Einsatz von drahtlosen Sendernetzen dazu beitragen, bisher nicht sinnvoll realisierbare Anwendungen einzuführen, beziehungsweise diese erst zu ermöglichen. In dieser Arbeit werden typische Flugzeuganwendungen identifiziert, welche von dem Einsatz eines drahtlosen Sendernetzes profitieren können. Die Herausforderungen, die der Einsatz so eines drahtlosen Sensornetzes hervorruft, werden beleuchtet, als auch entsprechende Technologien und Protokolle vorgestellt, welche darauf abzielen, diesen Herausforderungen zu begegnen.The market forecast for aircraft manufacturers is very promising; the fleet of passenger aircraft will double. This will clearly generate a strong business for aircraft manufactures. But new competitors arise and, hence, rivalry is increasing. To succeed in this market situation, aircraft manufacturers have to build innovative aircraft to set themselves apart from competitors. Most of the research effort is concentrated on developing lighter, more energy-efficient aircraft which reduce operational costs for airline operators. A very promising approach to accomplish this goal is to introduce wireless sensor networks for flight applications. Such wireless sensor networks can be very beneficial: they can help to reduce weight by saving cabling, they can improve workflows and, hence, reduce commissioning and operational costs, and they can enable new applications which were not feasible or even possible before.In this work, flight applications are investigated to identify the challenges which arise when introducing such a wireless sensor network. Technologies and protocols are presented which aim to tackle these challenges. In particular, the most demanding prerequisites are energy efficiency, transmission reliability, scalability, synchronization, and localization. Four of these demands will be addressed by three different protocols. First, a clock synchronization protocol is presented which uses a special hardware devicea wake-up receiverto achieve synchronization in a very energy-efficient, reliable, and scalable way. Second, using this same technology a clustering protocol is presented which can reduce redundant transmissions. In doing so, it becomes possible to lower the mean energy consumption for hundreds of sensor nodes. Last, a custom-tailored medium access protocol is presented which utilizes spatial diversity to increase transmission reliability while keeping a very low power demand.Tag der Verteidigung: 25.08.2015Paderborn, Univ., Diss., 201

Integrated Circuit and System Design for Cognitive Radio and Ultra-Low Power Applications

The ubiquitous presence of wireless and battery-powered devices is an inseparable and invincible feature of our modern life. Meanwhile, the spectrum aggregation, and limited battery capacity of handheld devices challenge the exploding demand and growth of such radio systems. In this work, we try to present two separate solutions for each case; an ultra-wideband (UWB) receiver for Cognitive Radio (CR) applications to deal with spectrum aggregation, and an ultra-low power (ULP) receiver to enhance battery life of handheld wireless devices. Limited linearity and LO harmonics mixing are two major issues that ultra-wideband receivers, and CR in particular, are dealing with. Direct conversion schemes, based on current-driven passive mixers, have shown to improve the linearity, but unable to resolve LO harmonic mixing problem. They are usually limited to 3rd, and 5th harmonics rejection or require very complex and power hungry circuitry for higher number of harmonics. This work presents a heterodyne up-down conversion scheme in 180 nm CMOS technology for CR applications (54-862 MHz band) that mitigates the harmonic mixing issue for all the harmonics, while by employing an active feedback loop, a comparable to the state-of-the art IIP3 of better than +10 dBm is achieved. Measurements show an average NF of 7.5 dB when the active feedback loop is off (i.e. in the absence of destructive interference), and 15.5 dB when the feedback loop is active and a 0 dBm interferer is applied, respectively. Also, the second part of this work presents an ultra-low power super-regenerative receiver (SRR) suitable for OOK modulation and provides analytical insight into its design procedure. The receiver is fabricated in 40 nm CMOS technology and operates in the ISM band of 902-928 MHz. Binary search algorithm through Successive Approximation Register (SAR) architecture is being exploited to calibrate the internally generated quench signal and the working frequency of the receiver. Employing an on-chip inductor and a single-ended to differential architecture for the input amplifier has made the receiver fully integrable, eliminating the need for external components. A power consumption of 320 µW from a 0.65 V supply results in an excellent energy efficiency of 80 pJ/b at 4 Mb/s data rate. The receiver also employs an ADC that enables soft-decisioning and a convenient sensitivity-data rate trade-off, achieving sensitivity of -86.5, and -101.5 dBm at 1000 and 31.25 kbps data rate, respectivel

Integrated Circuit and System Design for Cognitive Radio and Ultra-Low Power Applications

The ubiquitous presence of wireless and battery-powered devices is an inseparable and invincible feature of our modern life. Meanwhile, the spectrum aggregation, and limited battery capacity of handheld devices challenge the exploding demand and growth of such radio systems. In this work, we try to present two separate solutions for each case; an ultra-wideband (UWB) receiver for Cognitive Radio (CR) applications to deal with spectrum aggregation, and an ultra-low power (ULP) receiver to enhance battery life of handheld wireless devices. Limited linearity and LO harmonics mixing are two major issues that ultra-wideband receivers, and CR in particular, are dealing with. Direct conversion schemes, based on current-driven passive mixers, have shown to improve the linearity, but unable to resolve LO harmonic mixing problem. They are usually limited to 3rd, and 5th harmonics rejection or require very complex and power hungry circuitry for higher number of harmonics. This work presents a heterodyne up-down conversion scheme in 180 nm CMOS technology for CR applications (54-862 MHz band) that mitigates the harmonic mixing issue for all the harmonics, while by employing an active feedback loop, a comparable to the state-of-the art IIP3 of better than +10 dBm is achieved. Measurements show an average NF of 7.5 dB when the active feedback loop is off (i.e. in the absence of destructive interference), and 15.5 dB when the feedback loop is active and a 0 dBm interferer is applied, respectively. Also, the second part of this work presents an ultra-low power super-regenerative receiver (SRR) suitable for OOK modulation and provides analytical insight into its design procedure. The receiver is fabricated in 40 nm CMOS technology and operates in the ISM band of 902-928 MHz. Binary search algorithm through Successive Approximation Register (SAR) architecture is being exploited to calibrate the internally generated quench signal and the working frequency of the receiver. Employing an on-chip inductor and a single-ended to differential architecture for the input amplifier has made the receiver fully integrable, eliminating the need for external components. A power consumption of 320 µW from a 0.65 V supply results in an excellent energy efficiency of 80 pJ/b at 4 Mb/s data rate. The receiver also employs an ADC that enables soft-decisioning and a convenient sensitivity-data rate trade-off, achieving sensitivity of -86.5, and -101.5 dBm at 1000 and 31.25 kbps data rate, respectivel

Ultra-Low-Power Uwb Impulse Radio Design: Architecture, Circuits, And Applications

Recent advances in home healthcare, environmental sensing, and low power computing have created a need for wireless communication at very low power for low data rate applications. Due to higher energy/bit requirements at lower data -rate, achieving power levels low enough to enable long battery lifetime (~10 years) or power-harvesting supplies have not been possible with traditional approaches. Dutycycled radios have often been proposed in literature as a solution for such applications due to their ability to shut off the static power consumption at low data rates. While earlier radio nodes for such systems have been proposed based on a type of sleepwake scheduling, such implementations are still power hungry due to large synchronization uncertainty (~1[MICRO SIGN]s). In this dissertation, we utilize impulsive signaling and a pulse-coupled oscillator (PCO) based synchronization scheme to facilitate a globally synchronized wireless network. We have modeled this network over a widely varying parameter space and found that it is capable of reducing system cost as well as providing scalability in wireless sensor networks. Based on this scheme, we implemented an FCC compliant, 3-5GHz, timemultiplexed, dual-band UWB impulse radio transceiver, measured to consume only 20[MICRO SIGN]W when the nodes are synchronized for peer-peer communication. At the system level the design was measured to consume 86[MICRO SIGN]W of power, while facilitating multi- hop communication. Simple pulse-shaping circuitry ensures spectral efficiency, FCC compliance and ~30dB band-isolation. Similarly, the band-switchable, ~2ns turn-on receiver implements a non-coherent pulse detection scheme that facilitates low power consumption with -87dBm sensitivity at 100Kbps. Once synchronized the nodes exchange information while duty-cycling, and can use any type of high level network protocols utilized in packet based communication. For robust network performance, a localized synchronization detection scheme based on relative timing and statistics of the PCO firing and the timing pulses ("sync") is reported. No active hand-shaking is required for nodes to detect synchronization. A self-reinforcement scheme also helps maintain synchronization even in the presence of miss-detections. Finally we discuss unique ways to exploit properties of pulse coupled oscillator networks to realize novel low power event communication, prioritization, localization and immediate neighborhood validation for low power wireless sensor applications