55 research outputs found
Time and Frequency Transfer in a Coherent Multistatic Radar using a White Rabbit Network
Networks of coherent multistatic radars require accurate and stable time and frequency transfer (TFT) for range and Doppler estimation. TFT techniques based on global navigation satellite systems (GNSS), have been favoured for several reasons, such as enabling node mobility through wireless operation, geospatial referencing, and atomic clock level time and frequency stability. However, such systems are liable to GNSS-denial, where the GNSS carrier is temporarily or permanently removed. A denial-resilient system should consider alternative TFT techniques, such as the White Rabbit (WR) project. WR is an Ethernet based protocol, that is able to synchronise thousands of nodes on a fibre-optic based network with sub-nanosecond accuracy and picoseconds of jitter. This thesis evaluates WR as the TFT network for a coherent multistatic pulse-Doppler radar – NeXtRAD. To test the hypothesis that WR is suitable for TFT in a coherent multistatic radar, the time and frequency performance of a WR network was evaluated under laboratory conditions, comparing the results against a network of multi-channel GPS-disciplined oscillators (GPSDO). A WR-disciplined oscillator (WRDO) is introduced, which has the short-term stability of an ovenised crystal (OCXO), and long-term stability of the WR network. The radar references were measured using a dual mixer time difference technique (DMTD), which allows the phase to be measured with femtosecond level resolution. All references achieved the stringent time and frequency requirements for short-term coherent bistatic operation, however the GPSDOs and WRDOs had the best short-term frequency stability. The GPSDOs had the highest amount of long-term phase drift, with a peak-peak time error of 9.6 ns, whilst the WRDOs were typically stable to within 0.4 ns, but encountered transient phase excursions to 1.5 ns. The TFT networks were then used on the NeXtRAD radar, where a lighthouse, Roman Rock, was used as a static target to evaluate the time and frequency performance of the references on a real system. The results conform well to the laboratory measurements, and therefore, WR can be used for TFT in coherent radar
Polarimetric Radar for Automotive Applications
Current automotive radar sensors prove to be a weather robust and low-cost solution, but are suffering from low resolution and are not capable of classifying detected targets. However, for future applications like autonomous driving, such features are becoming ever increasingly important. On the basis of successful state-of-the-art applications, this work presents the first in-depth analysis and ground-breaking, novel results of polarimetric millimeter wave radars for automotive applications
Polarization techniques for mitigation of low grazing angle sea clutter
Maritime surveillance radars are critical in commerce, transportation, navigation, and defense. However, the sea environment is perhaps the most challenging of natural radar backdrops because maritime radars must contend with electromagnetic backscatter from the sea surface, or sea clutter. Sea clutter poses unique challenges in very low grazing
angle geometries, where typical statistical assumptions regarding sea clutter backscatter do not hold. As a result, traditional constant false alarm rate (CFAR) detection schemes may yield a large number of false alarms while objects of interest may be challenging to detect. Solutions posed in the literature to date have been either computationally impractical or lacked robustness.
This dissertation explores whether fully polarimetric radar offers a means of enhancing detection performance in low grazing angle sea clutter. To this end, MIT Lincoln Laboratory funded an experimental data collection using a fully polarimetric X-band radar assembled largely from commercial off-the-shelf components. The Point de Chene Dataset, collected on the Atlantic coast of Massachusetts’ Cape Ann in October 2015, comprises multiple sea states, bandwidths, and various objects of opportunity. The dataset also comprises three different polarimetric transmit schemes. In addition to discussing the radar, the dataset, and associated post-processing, this dissertation presents a derivation showing that an established multiple input, multiple output radar technique provides a novel means of simultaneous polarimetric scattering matrix measurement. A novel scheme for polarimetric radar calibration using a single active calibration target is also presented.
Subsequent research leveraged this dataset to develop Polarimetric Co-location Layering (PCL), a practical algorithm for mitigation of low grazing angle sea clutter, which is the most significant contribution of this dissertation. PCL routinely achieves a significant reduction in the standard CFAR false alarm rate while maintaining detections on objects of interest. Moreover, PCL is elegant: It exploits fundamental characteristics of both sea clutter and object returns to determine which CFAR detections are due to sea clutter. We demonstrate that PCL is robust across a range of bandwidths, pulse repetition frequencies, and object types. Finally, we show that PCL integrates in parallel into the standard radar signal processing chain without incurring a computational time penalty
Application-Specific Broadband Antennas for Microwave Medical Imaging
The goal of this work is the introduction of efficient antenna structures on the basis of the requirement of different microwave imaging methods; i.e. quantitative and qualitative microwave imaging techniques. Several criteria are proposed for the evaluation of single element antenna structures for application in microwave imaging systems. The performance of the proposed antennas are evaluated in simulation and measurement scenarios
M-sequenze based ultra-wideband radar and its application to crack detection in salt mines
Die vorliegende Dissertation beschreibt einen innovativen ultra-breitband
(UWB)elektromagnetischen Sensor basierend auf einem
Pseudo-Rauschverfahren.Der Sensor wurde für zerstörungsfreies Testen in
zivilen Anwendungen entwickelt.Zerstörungsfreies Testen entwickelt sich zu
einem immer wichtiger werdenden Bereich in Forschung und Entwicklung. Neben
unzähligen weiteren Anwendungen und Technologien, besteht ein primäres
Aufgabenfeld in der Ăśberwachung und Untersuchung von Bauwerken und
Baumaterialien durch berĂĽhrungslose Messung aus der Ferne.Diese Arbeit
konzentriert sich auf das Beispiel der Auflockerungszone im Salzgestein.Der
Hintergrund und die Notwendigkeit, den Zustand der oberflächennahen
Salzschichten in Salzminen kennen zu mĂĽssen, werden beleuchtet und die
Messaufgabe anhand einfacher theoretischer Ăśberlegungen beschrieben. Daraus
werden die Anforderungen fĂĽr geeignete UWB Sensoren abgeleitet. Die
wichtigsten Eigenschaften sind eine sehr hohe Messband breite sowie eine sehr
saubere Systemimpulsantwort frei von systematischen Gerätefehlern. Beide
Eigenschaften sind notwendig, um die schwachen RĂĽckstreuungen
der Auflockerungen trotz der unvermeidlichen starken Oberflächenreflexion
detektieren zu können.Da systematische Fehler bei UWB Geräten technisch
nicht von vorne herein komplett vermeidbar sind, muss der Sensor eine
Gerätekalibrierung erlauben, um solche Fehler möglichst gut zu
unterdrĂĽcken.Aufgrund der genannten Anforderungen und den Nebenbedingungen
der Messumgebung unter Tage, wurde aus den verschiedenen UWB-Technologien
ein Prinzip ausgewählt, welches pseudozufällige Maximalfolgen als
Anregungssignal benutzt. Das M-Sequenzkonzept dient als Ausgangpunkt fĂĽr
zahlreiche Weiterentwicklungen. Ein neues Sendemodul erweitert dabei die
Messbandbreite auf 12~GHz. Die äquivalente Abtastrate wird um den Faktor
vier auf 36~GHz erhöht, ohne den geringen Abtastjitter des ursprünglichen
Konzepts zu vergrössern.Weiterhin wird die Umsetzung eines
Zweitormesskopfes zur Erfassung von S-Parametern sowie einer automatische
Kalibriereinheit beschrieben. Etablierte Kalibrierverfahren aus dem Bereich
der Netzwerkanalyse werden kurz rekapituliert und die Adaption des 8-Term
Verfahrens mit unbekanntem Transmissionsnormal fĂĽr das
M-Sequenzsystem beschrieben. Dabei werden Kennwerte vorgeschlagen, die dem
Bediener unter Tage einfach erlauben, die Kalibrierqualität einzuschätzen
und Hinweise auf mögliche Gerätefehler oder andere Probleme zu bekommen.
Die Kalibriergenauigkeit des neuen Sensors im Labor wird mit der eines
Netzwerkanalysators verglichen. Beide Geräte erreichen eine störungsfreie
Dynamik von mehr als 60~dB in den Systemimpulsantworten fĂĽr Reflexion und
Transmission.Der neu entwickelte UWB Sensor wurde in zahlreichen Messungen
in Salzminen in Deutschland getestet. Zwei Messbeispiele werden vorgestellt
- ein sehr alter, kreisrunder Tunnel sowie ein ovaler Tunnelstumpf,
welcher kurz vor den Messungen erst aufgefahren wurde. Messaufbauten und
Datenverarbeitung werden beschrieben. SchlieĂźlich werden Schlussfolgerungen
und Vorschläge für zukünftige Arbeiten mit dem neuen M-Sequenzsensor sowie
der Messung von Auflockerungen im Salzgestein diskutiert.This dissertation describes an innovative ultra-wideband
(UWB) electromagnetic sensor device based on a pseudo-noise principle
developed in the context of non-destructive testing in civil
engineering.Non-destructive testing is becoming a more and more important
fieldfor researchers and engineers alike. Besides the vast field of
possibleapplications and testing technologies, a prime and therefore
typical topic is the inspection and monitoringof constructions and
materials by means of contactless remote sensing techniques.This work
focuses on one example the assessment of the disaggregation zone in salt
rock tunnels.The background and relevance of knowing the state of salt rock
layers near a tunnel's surface are explainedand simple theoretical
considerations for requirements of suitable UWB sensor devices are shown.
The most important sensor parameters are a very large measurement bandwidth
and a very clean impulse response. The latterparameter translates into the
mandatory application of calibration techniques to remove systematic errors
of the sensor system itself. This enables detection of weak scattering
responses from near-surface disaggregation despite the presence of a strong
surface reflection.According to the mentioned requirements and other side
conditions in salt mine environments an UWB sensor principlebased on
pseudo-noise stimuli namely M-Sequences is selected as a starting point for
system development. A newtransmitter frontend for extending the stimulus
bandwidth up to 12~GHz is presented. Furthermore, a technique for
increasing the (equivalent) sampling rate while keeping the stable and
low-jitter sampling regime of the M-Sequencesapproach is introduced and its
implementation is shown. Moreover, an automatic calibration unit for full
two-port coaxial calibration of the new UWB sensor has been developed.
Common calibration techniques from the area of vector network analysers are
shortly reviewed and a reasonablealgorithm the 8-term method with an
unknown line standard - is selected for the M-Sequences device. The 8-term
method is defined in the frequency domain and is adapted for use with time
domain devices. Some performance figures and comparisonwith calibration
results from network analysers are discussed to show the effectiveness of
the calibration.A spurious-free dynamic range of the time domain impulse
responses in excess of 60~dB has been achieved for reflection as well as
transmission measurements.The new UWB sensor was used in various real world
measurements in different salt mines throughout Germany. Two
measurementexamples are described and results from the disaggregation zone
of a very old and a freshly cut tunnel will be presented. Measurement setup
and data processing are discussed and finally some conclusions for future
work on this topic are drawn
Traceable Radiometric Calibration of Synthetic Aperture Radars
Synthetic aperture radar (SAR) systems allow to quantitatively measure the radar backscatter of an imaged terrain region. In order to achieve comparability between measurement results, traceable radiometric calibration is indispensable.
The central claim of the work is that nowadays, however, radiometric SAR measurements are not traceably calibrated. In order to resolve this problem, five contributions are made: (a) The new measurement quantity “equivalent radar cross section” (ERCS) is defined. (b) A numerical approach for linking the known quantity “radar cross section” (RCS) with the novel ERCS is introduced. (c) The effect of the chosen apodization functions on radiometric measurements is analytically investigated. (d) The novel three-transponder method is developed which allows accurate RCS calibrations of SAR transponders. (e) The method of hierarchical Bayesian data analysis is introduced to the field of radiometric SAR calibration.
The achieved traceability for radiometric SAR measurements allows more accurate radiometric measurement results especially for modern, high-resolution SAR systems. Furthermore, data exchange and cooperation is facilitated
Target shadow profile reconstruction in forward scatter radar
This thesis is dedicated to the matter of imaging (further explained as profile reconstruction) in Forward Scatter Radars (FSR). Firstly, an introduction to radar systems, including forward scatter radar, is made, then an introduction to the scalar theory of diffraction and principles of holography follows. The application of holographic imaging principles in the microwave domain is studied. The practical modelling of forward scatter radar target signals is made, based on the theoretical expectations and approximations outlined. Theoretical background of the imaging in FSR is made, based on previously published work. A novel approach for profile reconstruction is introduced based on the practices of holographic imaging, together with simulated results. Experimental set-ups used in the feasibility proof are described and experimental results are presented for 8 different targets in both a single-node and multistatic configurations. Preliminary accuracy analysis of these reconstructed target profiles is done, outlining practical application issues and domain of accuracy. Quantitative measures of the accuracy of the reconstructed images are defined
Advanced Techniques for Ground Penetrating Radar Imaging
Ground penetrating radar (GPR) has become one of the key technologies in subsurface sensing and, in general, in non-destructive testing (NDT), since it is able to detect both metallic and nonmetallic targets. GPR for NDT has been successfully introduced in a wide range of sectors, such as mining and geology, glaciology, civil engineering and civil works, archaeology, and security and defense. In recent decades, improvements in georeferencing and positioning systems have enabled the introduction of synthetic aperture radar (SAR) techniques in GPR systems, yielding GPR–SAR systems capable of providing high-resolution microwave images. In parallel, the radiofrequency front-end of GPR systems has been optimized in terms of compactness (e.g., smaller Tx/Rx antennas) and cost. These advances, combined with improvements in autonomous platforms, such as unmanned terrestrial and aerial vehicles, have fostered new fields of application for GPR, where fast and reliable detection capabilities are demanded. In addition, processing techniques have been improved, taking advantage of the research conducted in related fields like inverse scattering and imaging. As a result, novel and robust algorithms have been developed for clutter reduction, automatic target recognition, and efficient processing of large sets of measurements to enable real-time imaging, among others. This Special Issue provides an overview of the state of the art in GPR imaging, focusing on the latest advances from both hardware and software perspectives
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