One way Doppler extractor. Volume 1: Vernier technique

A feasibility analysis, trade-offs, and implementation for a One Way Doppler Extraction system are discussed. A Doppler error analysis shows that quantization error is a primary source of Doppler measurement error. Several competing extraction techniques are compared and a Vernier technique is developed which obtains high Doppler resolution with low speed logic. Parameter trade-offs and sensitivities for the Vernier technique are analyzed, leading to a hardware design configuration. A detailed design, operation, and performance evaluation of the resulting breadboard model is presented which verifies the theoretical performance predictions. Performance tests have verified that the breadboard is capable of extracting Doppler, on an S-band signal, to an accuracy of less than 0.02 Hertz for a one second averaging period. This corresponds to a range rate error of no more than 3 millimeters per second

Conception d'un convertisseur temps-numérique dédié aux applications de tomographie optique diffuse en technologie CMOS 130 nm

La mesure de temps de vol de photons et/ou de temps de propagation d’ondes RF et ultra large bande est devenue une technique essentielle et indispensable pour de nombreuses applications telles qu’en géolocalisation en intérieur, en détection LASER et en imagerie biomédicale, notamment en tomographie optique diffuse (TOD) avec des mesures dans le domaine temporel (DT). De telles mesures nécessitent des convertisseurs temps-numérique aptes à mesurer des intervalles de temps très courts avec grande précision, et ce, à des résolutions temporelles allant de quelques picosecondes à quelques dizaines de picosecondes. Les scanners TOD-DT ont généralement recours à des cartes électroniques de comptage de photons uniques intégrant essentiellement des convertisseurs temps-numérique hybrides (un mixte de circuits monolithiques et non-monolithiques). Dans le but de réduire le temps d’acquisition de ces appareils et d’augmenter leur précision, plusieurs mesures à différentes positions et longueurs d’ondes doivent pouvoir être effectuées en parallèle, ce qui exige plusieurs cartes de comptage de photons. L’implémentation de tels dispositifs en technologie CMOS apporte de multiples avantages particulièrement en termes de coût, d’intégration et de consommation de puissance. Cette thèse apporte une solution architecturale d’un convertisseur temps-numérique à 10-bits dédié aux applications de TOD-DT. Le convertisseur réalisé en technologie CMOS 0,13 μm d’IBM et occupant une surface en silicium de 1,83 x 2,23 mm[indice supérieur 2] incluant les plots de connexion, présente une résolution temporelle de 12 ps sur une fenêtre de 12 ns pour une consommation en courant de 4,8 mA. Les avantages de l’architecture proposée par rapport à d’autres réalisations rapportées dans la littérature résident dans son immunité face aux variations globales du procédé de fabrication, l’indépendance de la résolution temporelle vis-à-vis de la technologie ciblée et la faible gigue temporelle qu’il présente. Le circuit intégré réalisé trouvera plusieurs champs d’applications autres que la TOD notamment dans les tomographes d’émission par positrons, les boucles à verrouillage de phase numériques et dans les systèmes de télédétection et d’imagerie 3D

Smart optical imaging systems with automated electronics

In this dissertation, proposed and demonstrated are several novel smart electronically automated optical designs to efficiently solve existing real-world problems in the field of shape sensing and imaging. First half of the thesis proposes shape sensing techniques that use an Electronically Controlled Variable Focus Lens (ECVFL) within a smart optical design suitable for a wide range of applications including shape sensing and projection displays. The second part of this dissertation involves the use of the Digital Micromirror Device (DMD) deployed within several smart optical designs including an embedded laser beam profiler and a new camera idea which is inspired by the Telecommunication science field. Specifically, proposed and demonstrated is the design and implementation of the novel imaging device called Coded Access Optical Sensor (CAOS) where CAOS is able of operating with different application dependent working modes. Experimentally and successfully demonstrated for the first time are its use for coherent light laser imaging as well as for incoherent imaging of a high dynamic range white light scenario. It is also shown how its design can be further extended for multispectral and hyperspectral imaging applications

Studies of BONuS12 Radial GEM Detector and TCS Beam Spin Asymmetry in CLAS12

The Barely Offshell Nucleon Structure (BONuS12) experiment adopted the concept of spectator tagging technique to study the nearly-free neutron structure function F2n in the CLAS12 of Jefferson Lab. A novel Radial Time Projection Chamber (RTPC) detector was built, tested and integrated into the CLAS12 system to detect a back-moving low momentum tagged proton in d(e, ep)X deep-inelastic scattering. It was a 40 cm long gaseous detector consisting of 3 layers of cylindrical GEM foils for the charge amplification, with the data readout directly from the surrounding padboard. The RTPC detected the recoiling spectator proton, in coincidence with the scattered electron in the CLAS12. Nucleon structure functions are directly related to the partonic functions, quarks momentum distribution in one dimension. A Generalized Parton Distribution (GPD) came to the lime-light as it encodes the information of both longitudinal momentum and transverse position of partons inside the nucleons. Factorization of hard process such as DVCS allows to access GPDs. Timelike Compton Scattering (TCS), γp → γ∗p, is another process that allows to access the GPDs. TCS is studied experimentally in the CLAS12 of Jefferson lab using the quasi-real photoproduction of time-like photon which eventually decays to lepton pair. This dissertation presents the concept of spectator tagging in BONuS12, and the research and development efforts during the BONuS12 preparation leading up to the successful data-taking during spring and summer 2020. In addition, analysis framework to extract the beam spin asymmetry of TCS events through the CLAS12 Run group A data is presented

Validation of Nanosecond Pulse Cancellation Using a Quadrupole Exposure System

Nanosecond pulsed electric fields (nsPEFs) offer a plethora of opportunities for developing integrative technologies as complements or alternatives to traditional medicine. Studies on the biological effects of nsPEFs in vitro and in vivo have revealed unique characteristics that suggest the potential for minimized risk of complications in patients, such as the ability of unipolar nsEPs to create permanent or transient pores in cell membranes that trigger localized lethal or non-lethal outcomes without consequential heating. A more recent finding was that such responses could be diminished by applying a bipolar pulse instead, a phenomenon dubbed bipolar cancellation, paving the way for greater flexibility in nsPEF application design. Transitioning nsPEFs into practical use, however, has been hampered by both device design optimization and the intricacies of mammalian biology. Generating electric fields capable of beneficially manipulating human physiology requires high-voltage electrical pulses of nanosecond duration (nsEPs) with high repetition rates, but pulse generator and electrode design in addition to the complex electrical properties of biological fluids and tissues dictate the strength range and distribution of the resulting electric field. Faced with both promising and challenging aspects to producing a biomedically viable option for inducing a desired nsPEF response that is both focused and minimally invasive, the question becomes: how can the distinct features of unipolar and bipolar nsPEF bioeffects be exploited in a complex electrode exposure system to spatially modulate cell permeabilization? This dissertation presents a systematic study of an efficient coplanar quadrupole electrode nsPEF delivery system that exploits unique differences between unipolar and bipolar nsPEF effects to validate its ability to control cell responses to nsPEFs in space. Four specific aims were established to answer the research question, with specific attention to the roles played by pulse polarity, grounding configuration and electric field magnitude in influencing nsPEF stimulation of electropermeabilization in space. Using a prototype wire electrode applicator charged by a custom-built multimodal pulse generator, the aims were to spatially quantifyelectropermeabilization due (1) unipolar and (2) bipolar nsPEF exposure, to (3) apply synchronized pulses with a view to canceling bipolar cancellation (CANCAN) through superposition that could shift the effective nsPEF response, and to (4) evaluate the ability of the quadrupole system to facilitate remote nsPEF electropermeabilization. Numerical simulations were employed to approximate the nsPEF distribution for a two-dimensional (2-D) area resulting from unipolar, bipolar or CANCAN exposure in a varied-pulse quadrupole electrode configuration. For all experiments, the independent variables were fixed for pulse width (600 ns), pulse number (50) and repetition rate (10 Hz). Electropermeabilization served as the biological endpoint, with green fluorescence due to cell uptake of the nuclear dye YO-PRO-1® (YP1) tracer molecule serving the response variable. An agarose-based 3-D tissue model was used to acquire, quantify and compare fluorescence intensity data in vitro, which was measured by stereomicroscopy to enable macro versus micro level 2-D visualization. Results of this investigation showed that increasing the magnitude of the applied voltage shifts unipolar responses from localization at the anodal to cathodal electrode, and that adding a second proximal ground electrode increases the response area. Bipolar nsPEF responses were generally less intense than unipolar, but these depended on both the inter-electrode location measured and amplitude of the second phase. CANCAN preliminary indicated some ability to decrease strong uptake at electrodes, but evaluation across experimental and published data indicate that greater differences between unipolar and bipolar responses are needed to improve possibilities for distal stimulation. Overall, this work demonstrated the potential for more complex pulser-electrode configurations to successfully modulate nsPEF electropermeabilization in space by controlling unipolar and bipolar pulse delivery and contributed to a deeper understanding of bipolar cancellation. By providing a set of metrics for test and evaluation, the data provided herein may serve to inform model development to support prediction of nsPEF outcomes and help to more acutely define spatial-intensity relationships between nsPEFs and cell permeabilization as well as delineate requirements for future non-invasive nsPEF therapies

Deception jamming against anti-ship missiles which use doppler beam sharpening modes

Missile seekers are becoming increasingly more capable of using Doppler Beam Sharpening (DBS) modes as part of the homing cycle, which requires new countermeasures against this mode. One type of countermeasure, is to create false targets within the seeker DBS image. This thesis presents two implementation methods to insert false targets into DBS images. Both methods are used to create false targets at a precise location within a seeker DBS image, but are implemented in different ways. The first method proposes repeat jamming with a time-varying delay, whilst the second proposes a fixed delay and adding a specific Doppler shift to received waveforms. The effects of tracking errors on the position of the false target are analysed, both analytically and with simulations and used to assess the practical implementation of the jamming scheme. An experimental DBS system was built to test the effectiveness of the jamming scheme against a platform moving in steps and assess errors caused by incorrectly estimating the seeker trajectory. The overall result of the thesis is that using the derived jamming methods, false targets can be created at specific locations in the DBS image of the victim radar, providing the trajectory of the victim radar is known

A Deterministic and Random Propagation Study with the Design of an Open Path 320ghz to 340ghz Transmissometer

A Deterministic and Random Propagation Study with the Design of an Open Path THz 320GHz to 340GHz Transmissometer Thesis directed by Prof. Albin J. Gasiewski This program was implemented by Lawrence J. Scally for a Ph.D. under the EECE department at the University of Colorado at Boulder with most funding provided by the U.S. Army. Professor Gasiewski is the advisor and guider for the entire program; he has a strong history decades ago in this type of program. This program is developing a more advanced than previous years transmissometer, called Terahertz Atmospheric and Ionospheric Propagation, Absorption and Scattering System (TAIPAS), on an open path between the University of Colorado EE building roof and the mesa on owned by National Institute of Standards and Technology (NIST); NIST has invested money, location and support for the program. Besides designing and building the transmissometer, that has never be accomplished at this level, the system also analyzes the atmospheric propagation of frequencies by scanning between 320 GHz and 340 GHz, which includes the peak absorption frequency at 325.1529 GHz due to water absorption. The processing and characterization of the deterministic and random propagation characteristics of the atmosphere in the real world was significantly started; this will be executed with varies aerosols for decades on the permanently mounted system that is accessible 24/7 via a network over the CU Virtual Private Network (VPN)

Ground prototype of a rotating differential accelerometer for testing the Equivalence Principle in space: commissioning and reduction of low frequency noise

The Weak Equivalence Principle is at the basis of General Relativity and for this reason it is very important that its validity be experimentally verified as accurately as possible. The best experimental results have been obtained with test masses of different composition suspended on slowly rotating torsion balances. The rotation of the balance is crucial to up-convert the signal (which is DC in the field of the Earth and at the diurnal frequency in the field of the Sun) to higher frequency where both electronics and thermal noise are lower. Inside a spacecraft orbiting the Earth at low altitude test masses suspended similarly to a torsion balance are subject to a driving acceleration signal from the Earth about 3 orders of magnitude stronger and can therefore significantly improve ground based results. The proposed GG space experiment has the additional advantage of a rotation frequency much higher than that of ground balances, with consequent lower electronics and thermal noise. This is achieved with the test masses weakly coupled and in rapid rotation to form a differential accelerometer in “supercritical regime” (namely with a rotation frequency higher than their coupling frequency) sensitive in both durections of the plane perpendiclar to the rotation axis. This new type of sensor is tested in the laboratory with the rotating GGG accelerometer. GGG has the same number of degrees of freedom and the same dynamical structure as the GG sensor, and it has large mass test bodies as in space of 10 kg each. Such large masses cannot be suspended and coupled with the same weak suspensions that can be used in absence of weight, hence the GGG accelerometer cannot be as sensitive as the GG accelerometer sensor in space. Moreover, GGG is subject to microseismic noise of the local terrain and to the noise from motor and bearings, both absent in space. These noise sources must be reduced for GGG to be sensitive to a very small differential acceleration at the low frequency at which the GG sensor in space would detect the signal of an Equivalence Principle violation in the field of the Earth, namely the orbital frequency of about 1.7x10^-4 Hz, up-converted to high frequency by rotation. In rotation is provided by the whole spacecraft without a motor (by angular momentum conservation after initial set-up) while in GGG it requires motor and bearings, whose noise must also be reduced. During this thesis passive attenuation of tilt and horizontal acceleration noise due to local microseismicity has been implemented whose expected advantage over active control has been confirmed. At first a non rotating 2D suspension was designed, made in separate components with clamped flexures. The thesis work started by setting up an apparatus for measuring the level of tilt attenuation achievable with the flexures of the non rotating suspension, and with a procedure for measuring the level of tilt attenuation on the real system. A degradation of performance was observed due to clamping. A monolithic 2D suspension was designed, which in addition could be mounted on the rotating shaft below the ball bearings so as to attenuate also tilts of the shaft due to balls and rings irregularities. The elastic constants of the suspension in both directions have been measured on bench by setting up a specific apparatus. A 1-month experimental run with this suspension mounted on GGG has provided good results reported in a review paper on GG which has appeared in August 2012 in a CQG issue dedicated to the Weak Equivalence Principle. Encouraged by these results and in order to further reduce low frequency tilt noise we have concentrated on improving the design of all GG monolithic CuBe suspensions. Despite the need to suspend large masses, an appropriate design allows the relevant stiffness to be reduced so as to improve the sensitivity to differential accelerations as well as the capability of attenuating tilts. All suspensions have been heat treated during manufacturing in order to improve their mechanical quality. We have measured the elastic constants of all new joints showing the improvement with respect to the old ones. Then, the GGG apparatus has been dismantled and reassembled with the new joints, and after a commissioning phase an experimental run has started and is ongoing. Finally, an additional set of capacitance plates has been designed and manufactured to read the relative displacements between the shaft and the arm which couples the test cylinders (both rotating); by an appropriate adjustment of the differential period such measurement would be (almost) unaffected by low frequency tilts of the shaft (they would be rejected) while being sensitive to differential accelerations between the test cylinders

Cumulative index to NASA Tech Briefs, 1986-1990, volumes 10-14

Tech Briefs are short announcements of new technology derived from the R&D activities of the National Aeronautics and Space Administration. These briefs emphasize information considered likely to be transferrable across industrial, regional, or disciplinary lines and are issued to encourage commercial application. This cumulative index of Tech Briefs contains abstracts and four indexes (subject, personal author, originating center, and Tech Brief number) and covers the period 1986 to 1990. The abstract section is organized by the following subject categories: electronic components and circuits, electronic systems, physical sciences, materials, computer programs, life sciences, mechanics, machinery, fabrication technology, and mathematics and information sciences

Interactive Training System for Medical Ultrasound

Ultrasound is an effective imaging modality because it is safe, unobtrusive and portable. However, it is also very operator-dependent and significant skill is required to capture quality images and properly detect abnormalities. Training is an important part of ultrasound, but the limited availability of training courses presents a significant hindrance to the use of ultrasound being used in additional settings. The goal of this work was to design and implement an interactive training system to help train and evaluate sonographers. The Interactive Training System for Medical Ultrasound is an inexpensive, software-based training system in which the trainee scans a lifelike manikin with a sham transducer containing a 6 degree of freedom tracking sensor. The observed ultrasound image is generated from a pre-stored 3D image volume and is controlled interactively by the sham transducer\u27s position and orientation. Based on the selected 3D volume, the manikin may represent normal anatomy, exhibit a specific trauma or present a given physical condition. The training system provides a realistic scanning experience by providing an interactive real-time display with adjustable image parameters such as scan depth, gain, and time gain compensation. A representative hardware interface has been developed including a lifelike manikin and convincing sham transducers, along with a touch screen user interface. Methods of capturing 3D ultrasound image volumes and stitching together multiple volumes have been evaluated. System performance was analyzed and an initial clinical evaluation was performed. This thesis presents a complete prototype training system with advanced simulation and learning assessment features. The ultrasound training system can provide cost-effective and convenient training of physicians and sonographers. This system is an innovative approach to training and is a powerful tool for training sonographers in recognizing a wide variety of medical conditions