Tissue parameter determination with MRI in the presence of imperfect radiofrequency pulses /

Li, Xing.

January 1994

Thesis (M.S.)--Rochester Institute of Technology, 1994. / Typescript. Bibliography: leaves 97-101.

Ultra-wideband systems exploiting orthonormal waveforms

Kim, Youngok,

January 1900

Thesis (Ph. D.)--University of Texas at Austin, 2006. / Vita. Includes bibliographical references.

Noise considerations in nuclear pulse amplifiers

Landis, Donald Allen.

January 1962

Thesis (M.S. in Electrical Engineering)--University of California, Berkeley, Jan. 1962. / "UCRL-10001." Includes bibliographical references (leaf 65).

Measuring broadband, ultraweak, ultrashort pulses

Shreenath, Aparna Prasad.

January 2005

Thesis (Ph. D.)--Physics, Georgia Institute of Technology, 2006. / Trebino, Rick, Committee Chair ; First, Phillip, Committee Member ; Ralph, Stephen, Committee Member ; Kennedy, Brian, Committee Member ; Buck, John, Committee Member.

Nuclear magnetic relaxation and spin diffusion in multicomponent systems

Boss, Bruce David,

January 1967

Thesis (Ph. D.)--University of Wisconsin, 1967. / Typescript. Vita. Includes reprints of 3 articles from the Journal of chemical physics and the Journal of physical chemistry by the author and others. eContent provider-neutral record in process. Description based on print version record. Includes bibliographies.

An analysis of multipath neural systems using random parameter models.

Segal, Bernard N.

January 1973

No description available.

Pulse techniques (Electronics)

Nervous system

Stochastic processes

Labyrinth (Ear)

Millimetre wave quasi-optical signal processing systems

Webb, M. R.

January 1993

The development of spatial signal processing techniques at millimetre wavelengths represents an area of science and technology that is new. At optical wavelengths, spatial signal processing techniques are well developed and are being applied to a variety of situations. In particular they are being used in pattern recognition systems with a great deal of success. At millimetre wavelengths, the kind of technology used for signal transport and processing is typically either waveguide based or quasi-optically based, or some hybrid of the two. It is the use of quasi-optical methods that opens up the possibility of applying some of the spatial signal processing techiques that up to the present time have almost exclusively been used at optical wavelengths. A generic device that opens up this dimension of spatial signal processing to millimetre wave quasi-optical systems is at the heart of the work described within this thesis. The device could be suitably called a millimetre wave quasi-optical spatial light modulator (8LM), and is identical in operation to the spatial light modulators used in many optical signal processing systems. Within this thesis both a theoretical and an experimental analysis of a specific millimetre wave quasi-optical spatial light modulator is undertaken. This thesis thus represents an attempt to open up this new area of research and development, and to establish for it, a helpful theoretical and experimental foundation. It is an area that involves a heterogeneous mix of various technologies, and it is an area that is full of potential. The development of the experimental method for measuring the beam patterns produced by millimetre wave quasi-optical spatial light modulators involved the separate development of two other components. Firstly, a sensitive, low-cost millimetre wave pyroelectric detector has been developed and characterised. And secondly, a high performance quasi-optical Faraday rotator (a polarisation rotator) has been developed and characterised. The polarisation state of a quasi-optical beam is the parameter most often exploited for signal processing applications in millimetre wave quasi-optical systems, and thus a high performance polarisation rotator has readily found many opportunities for use.

530.0724

Programmable complex signals processing via ultrasonic dispersive delay lines

梁志堅, Leung, Chi-kin.

January 1984

published_or_final_version / Electrical Engineering / Master / Master of Philosophy

Pulse techniques (Electronics)

Signal processing - Digital techniques.

Transfer functions.

Delay lines.

Modeling and Optimal Design of Annular Array Based Ultrasound Pulse-Echo System

WAN, Li

18 April 2001

The ability to numerically determine the received signal in an ultrasound pulse-echo system is very important for the development of new ultrasound applications, such as tissue characterization, complex object recognition, and identification of surface topology. The output signal from an ultrasound pulse-echo system depends on the transducer geometry, reflector shape, location and orientation, among others, therefore, only by numerical modeling can the output signal for a given measurement configuration be predicted. This thesis concerns about the numerical modeling and optimal design of annular array based ultrasound pulse-echo system for object recognition. Two numerical modeling methods have been implemented and evaluated for calculating received signal in a pulse-echo system. One is the simple, but computationally demanding Huygens Method and the other one is the computationally more efficient Diffraction Response for Extended Area Method (DREAM). The modeling concept is further extended for pulse-echo system with planar annular array. The optimal design of the ultrasound pulse-echo system is based on annular array transducer that gives us the flexibility to create a wide variety of insonifying fields and receiver characteristics. As the first step towards solving the optimization problem for general conditions, the problem of optimally identifying two specific reflectors is investigated. Two optimization methods, the straightforward, but computationally intensive Global Search Method and the efficient Waveform Alignment Method, have been investigated and compared.

optimal design

modeling

object identification

ultrasound pulse-echo system

annular array

Pulse techniques (Electronics)

Ultrasonic transducers

Reflector geometry specific modeling of an annular array based ultrasound pulse-echo system

Nadkarni, Aditya

12 September 2007

"Abstract Conventional ultrasound imaging systems use array transducers for focusing and beam steering, to improve lateral resolution and permit real-time imaging. This thesis research investigates a different use of array transducers, where the acoustic field and the receiver characteristics are designed such that the energy of the output signal from targets of a specified geometry is maximized. The output signal is the sum of the received signals obtained using all the possible combinations of transducer array elements as transmitter and receiver. This work is based on annular array transducers, but is applicable for any array configuration. The first step is the development of software for the efficient modeling of the wave interaction between transmitted field and target, and between the transducer and receiver field. Using this software, we have calculated the received signal for each combination of an array element as transmitter and the same or another array element as receiver, leading to an N x N received signal matrix for an N element array transducer. A waveform optimization algorithm is then implemented for the purpose of determining the set of delays for the individual array elements, which maximizes the energy of the sum of the received signals. In one implementation of this algorithm, the received signal with the maximum energy is considered as a reference signal, and specific delays are applied to the other signals so that any two signals produce a maximum correlation. This leads to an N x N delay matrix, which, however, is not readily implemented in a practical real-time system, which uses all the elements in an array transducer simultaneously to customize acoustic fields. Hence, the values in this delay matrix are fed into a linear programming optimizer tool to obtain a set of delay values, which makes its implementation practical. The optimized set of delays thus obtained is used to maximize the energy of the received signal for a given transducer and target geometry and hence to enhance the reflectivity of that target. It is also important to check the robustness of the optimized set of delays obtained above, for a given target geometry. Robustness refers to the sensitivity of the optimization to variation in target geometry. This aspect is also evaluated as a part of this thesis work."

ultrasound modeling

annular arrays

ultrasound

Ultrasonics

Pulse techniques (Electronics)

Ultrasonic transducers