A novel technique for phased array receivers based on an economic sampling scheme

Blanco Moro, Rodrigo

04 September 2013

Phased array systems present desirable antenna features like beam steering and high gain. However, due to their high cost, civilian applications cannot generally afford them, restricting their usage to military. Hardware involved in phased array systems is expensive and the number of devices is high, since there is usually one device of each kind (filter, amplifier, shifter..) for each individual antenna. Alternative techniques, mainly based on TDMA, have been developed looking for lowering the number of elements in the system. However, these approaches increase the system bandwidth, multiplying it by a factor of $N$ (Number of antennas), as they use redundant information. In this thesis, a novel phased receiver, based on an economic sampling scheme is proposed. All the elements in an array receive a common information (signal amplitude) and a unique information (relative delay between elements). The idea is to sample only the information required to reconstruct the transmitted signal and discard the redundant one. This idea is achieved by sampling just one antenna during each RF cycle and then gathering all the information taking in account the relative delay between different antenna elements. The proposed technique is mathematically proved and validated by simulation. As a first approach, the equation for the received signal in the frequency domain is derived for a linear array. The radiation pattern and the received signals are simulated for equally spaced planar and linear arrays. Bandwidth signal transmission is demonstrated and tapering effects are shown. After that, the proposed technique is expanded for arbitrary structures and the resulting system bandwidth is enhanced by using different sampling order sequences. / Master of Science

Antennas

Bandwidth enhancement

Phased Array

Sampling Scheme

Tapering

Measurements, Estimations and Calibration with a Fully Digital Array

Magnér, Oscar

January 2023

In modern digital communication, transmission and reception of information through electromagnetic signals requires digital devices that can process high data rates accurately despite being located in information heavy environments. One type of antenna receiver is the digital antenna array, which can steer its lobes electronically to increase or decrease sensitivity in specific directions. A rather recently developed system is the Wideband Digital Array Receiver, developed at Saab Surveillance in Järfälla and referred to as WiDAR. The implementations and possibilities of WiDAR are broad, but no matter its future applications, calibration is an essential feature to ensure truthful reception of data. Any type of electronic system risks errors due to hardware imperfections. The aim of this thesis is to explore and reduce these errors. Measurements with WiDAR were performed in a manner such that some of the intercepted signals were transmitted from a far away located FM and TV-mast. The data was then used to retrieve weights by calculating their relative transfer function, which were applied to calibrate all channels in the antenna array towards a chosen reference channel. These weights could then be on any accumulated set of data measured by WiDAR with hopes to compensate errors in both phase and magnitude. The results show that reducing errors this way was possible, working slightly better when calibrating phase than calibrating magnitude. If more advanced calibration is deemed necessary, further measurements could be performed to investigate where errors or variations occur by isolating different parts of the system. The calibration method used could be further developed by adding an online calibration procedure, meaning relative transfer functions are calculated in real time when performing measurements.

WiDAR

signal processing

digital array

broadband antenna

array antenna

antenna

calibration

direct sampling

antenn

bredbandig

digital array

array antenn

direktsampling

signalbehandling

kalibrering

WiDAR

Saab AB

SAAB

Signal Processing

Signalbehandling

Single ytterbium atoms in an optical tweezer array: high-resolution spectroscopy, single-photon Rydberg excitation, and a scheme for nondestructive detection / 単一イッテルビウム原子光ピンセットアレイ：超狭線幅分光と１光子リドベルグ励起及び非破壊検出スキーム

Okuno, Daichi

25 July 2022

付記する学位プログラム名: 京都大学卓越大学院プログラム「先端光・電子デバイス創成学」 / 京都大学 / 新制・課程博士 / 博士(理学) / 甲第24123号 / 理博第4851号 / 新制||理||1694(附属図書館) / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)教授 高橋 義朗, 教授 石田 憲二, 教授 田中 耕一郎 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DFAM

Ytterbium

Quantum computing

Rydberg state

Optical tweezer array

400

"Design and Characterization of Mach 5 Flow for Higly Turbulent Hypersonic Test Facility

Thornton, Mason R

01 January 2021

In this paper, an array of converging-diverging nozzles in parallel is designed to create a highly turbulent, sufficiently mixed flow for the study of turbulent-compressibility effects and assist in the ongoing work of oblique detonation wave (ODW) research. Several nozzle array candidates were designed with varying numbers of nozzles and nozzle sizes and evaluated using computational fluid dynamics to determine which candidate produced the most viable conditions for investigating turbulent compressibility effects. Conditions and design restrictions of the nozzle arrays were tailored to the conditions set in the Hypersonic Wind Tunnel, which is located at the Propulsion and Energy Research Lab at the University of Central Florida.

Hypersonic

Detonation

Nozzle Array

Turbulence

Aerodynamics and Fluid Mechanics

Aerospace Engineering

Another approach to PLA folding

Tan, Chong Guan

January 1985

No description available.

Programmable array logic.

Conditional stuck-at fault model for PLA test generation

Cornelia, Olivian E.

January 1987

No description available.

Fault-tolerant computing

Electronic circuit design

Programmable array logic -- Testing

Active Sensor Array for UWB Breast-Cancer Screening

Tyagi, Vartika

January 2021

A microwave imaging system processes scattered electromagnetic fields in the microwave region to create images. It is an alternative or complementary imaging tool that can be used in breast cancer imaging. It employs non-ionising radiation and during measurement, compression of the scanned body part is avoided. These benefits potentially lead to safer and more comfortable examinations. It also has the potential to be both sensitive and specific to detect small tumors, whilst being much lower cost than current methods, such as magnetic resonant imaging, mammography and ultrasound. This thesis reports a multi-layer active antenna array for breast imaging using microwaves from 3 GHz to 8 GHz. The proposed structure resolves the outstanding problem in the design of large active antenna arrays for tissue imaging, namely, the isolation of the antennas from the electronic circuits. A ground plane within the multi-layer design separates the antenna array from the electronics array while providing shielding to the antennas from the back and improved power coupling into the tissue. The possibility of a high-speed vertical connector to provide interconnection between the antenna array and the mixer array is investigated and measurements show that it could be utilized for the frequency range from 3 GHz to 8 GHz. / Thesis / Master of Applied Science (MASc)

Breast cancer detection

UWB microwave imaging

Active antenna array

A Tool For Run Time Soft Error Fault Injection Into FPGA Circuits

Zuzarte, Marvin

06 1900

Safety and mission critical systems are currently deployed in many different fields where there is a greater presence of high energy particles (e.g.\ aerospace). The use of field programmable gate arrays (FPGAs) within safety critical systems is becoming more prevalent due to the design and cost benefits their use provides. The effects of externally caused faults on these safety critical systems cannot be neglected. In particular, high energy particle striking a circuit can cause a voltage change in the circuit known as a soft error. The effects these soft errors will have on the circuit needs to be understood in order to ensure that the systems will function properly in the event soft errors do occur. In this thesis a tool is designed to facilitate the run-time injection of soft errors into a hardware circuit running on a FPGA. The tool allows for the control over the number of injections that can be performed and control over the rate that the injections will occur at. Additionally the tool records time stamps of when injections occur and time stamps of when errors are detected. This recorded data allows for the analysis of designs in conditions prone to soft errors. The implemented tool allows for design time parametrization and run time configuration, allowing a multitude of tests to be run for a single compiled design. The tool also eliminates the need for a host computer after configuration by generating the injection locations and times on the FPGA. Eliminating the host computer allows for faster testing when compared to other methods as data transfer times are greatly reduced. The implemented tool was run on classical examples of redundant structures, such as duplication with comparison and triple modular redundancy as well as a non-redundant structure to establish a baseline. The results of multiple tests run on each structure are analyzed to illustrate the uses of the tool and how the tool may be used to test other designs. / Thesis / Master of Applied Science (MASc)

FPGA

Fault injection

Field programmable gate array

runtime

soft error

Transparent Capacitive and Piezoelectric Micromachined Ultrasonic Transducers for Tactile Feedback with 3D Displays

Laughlin, Emily Anne

06 August 2021

3D display technology is limited by the user's ability to interact with displays without being connected to external equipment. In order to feel tactile feedback in conjunction with displays, ultrasonic sound pressure fields have been created; however, ceramic transducers interfere with the user's immersive experience. We have created transparent ultrasonic transducers using capacitive micromachined ultrasonic transducer (CMUT) and piezoelectric micromachined ultrasonic transducer (PMUT) technology that allow the user to remain immersed in the experience while interacting with the display. Individual transparent piezoelectric transducers made with indium tin oxide (ITO) and polyvinylidene fluoride (PVDF) generate 66.9dB with 91.6% transparency. Samples were phased and modulated using a field programmable gate array (FPGA) in a 36-element array.

PMUT

CMUT

FPGA

phased array

transparent

haptic feedback

Engineering

Decentralized and Pulse-based Clock Synchronization in SpaceWire Networks for Time-triggered Data Transfers / Dezentralisierte und Puls-basierte Uhrensynchronisation in SpaceWire Netzwerken für zeitgesteuerten Datentransfer

Borchers, Kai

January 2020

Time-triggered communication is widely used throughout several industry do- mains, primarily for reliable and real-time capable data transfers. However, existing time-triggered technologies are designed for terrestrial usage and not directly applicable to space applications due to the harsh environment. In- stead, specific hardware must be developed to deal with thermal, mechanical, and especially radiation effects. SpaceWire, as an event-triggered communication technology, has been used for years in a large number of space missions. Its moderate complexity, her- itage, and transmission rates up to 400 MBits/s are one of the main ad- vantages and often without alternatives for on-board computing systems of spacecraft. At present, real-time data transfers are either achieved by prior- itization inside SpaceWire routers or by applying a simplified time-triggered approach. These solutions either imply problems if they are used inside dis- tributed on-board computing systems or in case of networks with more than a single router are required. This work provides a solution for the real-time problem by developing a novel clock synchronization approach. This approach is focused on being compatible with distributed system structures and allows time-triggered data transfers. A significant difference to existing technologies is the remote clock estimation by the use of pulses. They are transferred over the network and remove the need for latency accumulation, which allows the incorporation of standardized SpaceWire equipment. Additionally, local clocks are controlled decentralized and provide different correction capabilities in order to handle oscillator induced uncertainties. All these functionalities are provided by a developed Network Controller (NC), able to isolate the attached network and to control accesses. / Zeitgesteuerte Datenübertragung ist in vielen Industriezweigen weit verbreitet, primär für zuverlässige und echtzeitfähige Kommunikation. Bestehende Technologien sind jedoch für den terrestrischen Gebrauch konzipiert und aufgrund der rauen Umgebung nicht direkt auf Weltraumanwendungen anwendbar. Stattdessen wird spezielle Hardware entwickelt, um Strahlungseffekten zu widerstehen sowie thermischen und mechanischen Belastungen standzuhalten. SpaceWire wurde als ereignisgesteuerte Kommunikationstechnologie entwickelt und wird seit Jahren in einer Vielzahl von Weltraummissionen verwendet. Dessen erfolgreiche Verwendung, überschaubare Komplexität, und Übertragungsraten bis zu 400 MBit/s sind einige seiner Hauptvorteile. Derzeit werden Datenübertragungen in Echtzeit entweder durch Priorisierung innerhalb von SpaceWire Router erreicht, oder durch Anwendung von vereinfachten zeitgesteuerten Ansätzen. Diese Lösungen implizieren entweder Probleme in verteilten Systemarchitekturen oder in SpaceWire Netzwerken mit mehreren Routern. Diese Arbeit beschreibt eine Uhrensynchronisation, die bestimmte Eigenschaften von SpaceWire ausnutzt, um das Echtzeitproblem zu lösen. Der Ansatz ist dabei kompatibel mit verteilten Systemstrukturen und ermöglicht eine zeitgesteuerte Datenübertragung.

Datenübertragung

Field programmable gate array

Raumfahrttechnik

ddc:000