Development of a sub-glacial array of radio antennas for the detection of the flux of GZK neutrinos

Meures, Thomas

12 December 2014

GZK neutrino are interesting messenger particles since, if detected, they can transmit<p>us exclusive information about ultra-high energy processes in the Universe. These particles,<p>which hold energies above 10^16 eV, interact very rarely. Therefore, detectors of<p>several gigatons of matter are needed to discover them. The ARA detector is planned<p>and currently being constructed at the South Pole. It is designed to use the Askaryan<p>effect, the emission of radio waves from neutrino induced cascades in the South Pole ice,<p>to detect neutrino interactions. With antennas distributed in 37 stations in the ice, such<p>interactions can be observed in a volume of several hundred cubic kilometers. Currently<p>2 ARA stations have been deployed in the ice and are taking data since the beginning<p>of the year 2013.<p>The first part of this thesis summarizes the current theories concerning the GZK mechanism<p>and the Askaryan effect to explain the interest in GZK neutrinos and in the used<p>detection method.<p>In the second part the ARA detector is described and calibrations of different detector<p>parts are presented. In this work, the digitization chips have been calibrated concerning<p>their timing precision and signal amplitude. In this way a timing precision of 100 ps<p>between antennas could be achieved. Furthermore, the geometry of the antenna clusters<p>is determined by cuts based on external signals to allow for a proper radio vertex reconstruction.<p>In the third part of the thesis the development of methods to distinguish radio signals<p>from thermal noise are presented. Moreover, a reconstruction method, developed to determine<p>the position of radio sources, is described. With only two stations operational<p>a discovery of GZK neutrinos is not expected and in fact no signal candidate has been<p>found in the analysis of the data. A neutrino <p>ux limit is calculated. This limit is not<p>competitive yet with the current best limits, but very promising for the full ARA detector.<p>The work shows that after completion this detector is expected to be capable of a<p>neutrino discovery. / Doctorat en Sciences / info:eu-repo/semantics/nonPublished

Physique

Neutrinos

Radio detectors

Neutrinos

Démodulateurs

radio detection

Askaryan radiation

GZK neutrinos

neutrinos

Comparison of quadrature detector and phase-locked loop demodulator performance with LEOSAT applications

Lim, Stephen T.

January 1991

M.S.

LD5655.V855 1991.L553

Demodulation (Electronics)

Phase-locked loops

Radio detectors -- Evaluation

Multi-gigabit low-power wireless CMOS demodulator

Yeh, David Alexander

30 June 2010

This dissertation presents system and circuit development of the low-power multi-gigabit CMOS demodulator using analog and mixed demodulation techniques. In addition, critical building blocks of the low-power analog quadrature front-ends are designed and implemented using 90 nm CMOS with a targeted compatibility to the traditional demodulator architecture. It exhibits an IF-to-baseband conversion gain of 25 dB with 1.8 GHz of baseband bandwidth and a dynamic range of 23 dB while consuming only 46 mW from a 1 V supply voltage. Several different demodulators using analog signal processor (ASP) are implemented: (1) an ultra-low power non-coherent ASK demodulator is measured to demodulate a maximum speed of 3 Gbps while consuming 32 mW from 1.8 V supply; (2) a mere addition of 7.5 mW to the aforementioned analog quadrature front-end enables a maximum speed of 2.5 Gbps non-coherent ASK demodulation with an improved minimum sensitivity of -38 dBm; (3) a robust coherent BPSK demodulator is shown to achieve a maximum speed of 3.5 Gbps based on the same analog quadrature front-end with only additional 7 mW. Furthermore, an innovative seamless handover mechanism between ASP and PLL is designed and implemented to improve the frequency acquisition time of the coherent BPSK demodulator. These demodulator designs have been proven to be feasible and are integrated in a 60 GHz wireless receiver. The system has been realized in a product prototype and used to stream HD video as well as transfer large multi-media files at multi-gigabit speed.

Millimeter-wave

UWB

CMOS

Wireless system

Wireless transceiver

Multi-gigabit demodulator

Radio detectors

Wireless communication systems

Multi-gigabit CMOS analog-to-digital converter and mixed-signal demodulator for low-power millimeter-wave communication systems

Chuang, Kevin

05 1900

The objective of the research is to develop high-speed ADCs and mixed-signal demodulator for multi-gigabit communication systems using millimeter-wave frequency bands in standard CMOS technology. With rapid advancements in semiconductor technologies, mobile communication devices have become more versatile, portable, and inexpensive over the last few decades. However, plagued by the short lifetime of batteries, low power consumption has become an extremely important specification in developing mobile communication devices. The ever-expanding demand of consumers to access and share information ubiquitously at faster speeds requires higher throughputs, increased signal-processing functionalities at lower power and lower costs. In today’s technology, high-speed signal processing and data converters are incorporated in almost all modern multi-gigabit communication systems. They are key enabling technologies for scalable digital design and implementation of baseband signal processors. Ultimately, the merits of a high performance mixed-signal receiver, such as data rate, sensitivity, signal dynamic range, bit-error rate, and power consumption, are directly related to the quality of the embedded ADCs. Therefore, this dissertation focuses on the analysis and design of high-speed ADCs and a novel broadband mixed-signal demodulator with a fully-integrated DSP composed of low-cost CMOS circuitry. The proposed system features a novel dual-mode solution to demodulate multi-gigabit BPSK and ASK signals. This approach reduces the resolution requirement of high-speed ADCs, while dramatically reducing its power consumption for multi-gigabit wireless communication systems.

Analog-to-digital converter

Mixed-signal

Demodulator

Multi-gigabit

CMOS

Analog-to-digital converters

Radio detectors

Millimeter wave communication systems

Ultra low power multi-gigabit digital CMOS modem technology for millimeter wave wireless systems

Muppalla, Ashwin K.

13 May 2010

The objective of this research is to present a low power modem technology for a high speed millimeter wave wireless system. The first part of the research focuses on a robust ASIC design methodology. There are several aspects of the ASIC flow that require special attention such as logical synthesis, timing driven physical placement, Clock Tree Synthesis, Static Timing Analysis, estimation and reduction of power consumption and LVS and DRC closure. The latter part is dedicated to high speed baseband circuits such as Coherent and Non coherent demodulator which are critical components of a multi-gigabit wireless communication system. The demodulator operates at input data rates of multiple gigabits per second, which presents the challenge of designing the building blocks to operate at speeds of multiple GHz. The high speed complex multiplier is a major component of the non coherent demodulator. As part of the coherent demodulator the complex multiplier derotates the input sequence by multiplying with cosine and sine functions, Costas error calculator computes the phase error in the derotated input signal. The NCO (Numerically controlled Oscillator) is a look up table based system used to generate the cosine and sine functions, used by the derotator.The CIC filter is used to decimate the costas error signal as the loop bandwidth is significantly smaller compared to the sampling frequency. All these modules put together form the coherent demodulator which is an integral part of the wireless communication system. An implementation of Serdes is also presented which acts as an interface between the baseband modules and the RF front end.

Non-coherent demodulator

SerDes

Coherent demodulator

Demodulator

Modem

Millimeter wave communication systems

Wireless communication systems

Modems

Application-specific integrated circuits

Demodulation (Electronics)

Radio detectors

Design and development of novel radio frequency sensors based on far-field and near-field principles

Thai, Trang Thuy

13 January 2014

The objective of this work is to enhance and advance sensing technologies with the design and development of novel radio frequency (RF) sensors based on far-field and near-field principles of the electromagnetic (EM) resonances. In the first part of this thesis, original design and development of a passive RF temperature sensor, a passive RF strain sensor, and a passive RF pressure sensor are presented. The RF temperature sensor is presented in Chapter 3. It is based on split ring resonators loaded with bimorph cantilevers. Its operating principles and equivalent circuits are discussed in Chapter 4, where the design concept is illustrated to be robust and highly adaptable to different sensing ranges, environments, and applicable to other type of sensing beyond temperatures. The passive RF strain sensor, based on a patch antenna loaded with a cantilever-integrated open loop, is presented in Chapter 5, where it is demonstrated to have the highest strain sensitivity in the same remote and passive class of sensors in the state-of-the-art. Chapter 6 describes the passive RF pressure sensor, which is based on a dual-band stacked-patch antenna that allows both identification and sensing to be embedded in its unique dual resonant responses. In the second part of this thesis, an original and first-of-its-kind RF transducer is presented that enables non-touch sensing of human fingers within 3 cm of proximity (based on one unit sensor cell). The RF transducer is based on a slotted microstrip patch coupled to a half-wavelength parallel-coupled microstrip filter operating in the frequency range of 6 – 8 GHz. The sensing mechanism is based on the EM near-field coupling between the resonator and the human finger. Fundamentally different from the electric field capacitive sensing, this new method of sensing, the first of its kind, based on near-field interference that produces a myriad of nonlinearities in the sensing response, can introduce new capabilities for the interface of electronic displays (the detection is based on pattern recognition). What set this sensor and its platform apart from previous proximity sensors and microwave sensing platforms is the low profile planar structure of the system, and its compatibility with mobile applications. The thesis provides both breadth and depth in the proposed design and development and thus presenting a complete research in its contributions to RF sensing.

Radio frequency sensing

Chipless

Remote

Resonators

Long range

Pressure sensor

Temperature sensor

Strain sensor

Proximity sensor

Near-field

Far-field

Radio detectors

Near field communication

Radio frequency identification systems

Electromagnetic fields