Object recognition through multiple viewpoints

Salam, Rosalina Abdul

January 2000

No description available.

621.3994

A qualitative study of three American pattern drafting systems of the late nineteenth century

Burford, Karen Sundby

January 2011

Digitized by Kansas Correctional Industries

Dressmaking--Pattern design

Structural damage detection using signal-based pattern recognition

Qiao, Long

January 1900

Doctor of Philosophy / Department of Civil Engineering / Asadollah Esmaeily / Civil structures are susceptible to damages over their service lives due to aging, environmental loading, fatigue and excessive response. Such deterioration significantly affects the performance and safety of structure. Therefore, it is necessary to monitor the structural performance, detect and assess damages at the earliest possible stage in order to reduce the life-cycle cost of structure and improve its reliability. Over the last two decades, extensive research has been conducted on structural health monitoring and damage detection. In this study, a signal-based pattern-recognition method was applied to detect structural damages with a single or limited number of input/output signals. This method is based on the extraction of sensitive features of the structural response under a known excitation that present a unique pattern for any particular damage scenario. Frequency-based features and time-frequency-based features of the acceleration response were extracted from the measured vibration signals by Fast Fourier Transform (FFT) and Continuous Wavelet Transform (CWT) to form one-dimensional or two-dimensional patterns, respectively. Three pattern recognition algorithms were investigated when performing pattern-matching: (1) correlation, (2) least square distance, and (3) Cosh spectral distance. To demonstrate the validity and accuracy of the method, numerical and experimental studies were conducted on a simple small-scale three-story steel building. In addition, the efficiency of the features extracted by Wavelet Packet Transform (WPT) was examined in the experimental study. The results show that the features of the signal for different damage scenarios can be uniquely identified by these transformations. Suitable correlation algorithm can then be used to identify the most probable damage scenario. The proposed method is suitable for structural health monitoring, especially for the online monitoring applications. Meanwhile, the choice of wavelet function affects the resolution of the detection process and is discussed in the “experimental study part” of this report.

Damage detection

Pattern recognition

Engineering, Civil (0543)

A compositional framework for determining pattern applicability

Hakeem, Hossam Hassan

January 2010

The notion of ‘pattern’ originates in the work of Christopher Alexander and, in recent years, patterns have become a popular part of software development. A pattern is defined as a ‘three-part rule’: a relationship between a given context, a recurring system of forces peculiar to that context, and a specific spatial configuration that permits resolution of these forces. In essence, the ‘context’ of a pattern is the whole system under construction and its state in the construction process at the point at which the pattern is being applied. The nature of the context, therefore, changes at every step of the process and this has significant implications for how patterns should be used. Specifically, applying each pattern changes the context by changing the state of the system under construction and creates both a new design problem and a new context for the next pattern to be applied. The next picked pattern must have a certain criteria in order for it to be applied successfully and this is will be determined by the characteristics of the new context just created. The issue of composing pattern sequences is therefore more temporal than it is static and structural (as provided currently via pattern maps). The decision as to which one to use is temporally constrained in the sense that the choice is made only at a particular point in the construction process of some specific system, and may well be determined, or at least further constrained, by the current state of that system. The fundamental research question that is addressed here is: how is this dynamically changing context to be presented to guide pattern applications? In this thesis, a framework is presented to provide a systematic analysis of composition of pattern applications in terms of the properties of their context. Such an approach will reveal the ordering of patterns in space and time dimensions. Examples of composition of pattern applications include: - One pattern contains or generalises another smaller-scale pattern (this will be called in thesis refinement); - Two patterns are complementary, i.e., one pattern needs the other to be applied before (Sequential Order); - Two patterns solve different problems that overlap and coexist on the same level (Parallel Order); - Two patterns solve the same problem in alternative, but equally valid ways (Choice in Order). At the design phase, the framework provides mechanisms for analysing the choice of composition to ensure the correctness of a design or to compare between two different designs or to modify an existing design. This framework describes a pattern's context via a pair of constraints, known as Assumption and Commitment. In general, the Assumption is a constraint placed on the context and the Commitment is what the solution provided by the pattern commits to after the pattern's application. In addition, the thesis provides a set of composition rules that can be applied to aid in the analysis of the application of pattern sequences. The approach is domain independent as it does not depend on the nature of the catalogue from which the patterns originate. The work has been evaluated using various existing patterns from Ian Graham’s web usability (WU) pattern bank and the User Interface (UI) patterns of Welie.

600

A blackboard-based system for learning to identify images from feature data

Norman, Margaret

January 1991

A blackboard-based system which learns recognition rules for objects from a set of training examples, and then identifies and locates these objects in test images, is presented. The system is designed to use data from a feature matcher developed at R.S.R.E. Malvern which finds the best matches for a set of feature patterns in an image. The feature patterns are selected to correspond to typical object parts which occur with relatively consistent spatial relationships and are sufficient to distinguish the objects to be identified from one another. The learning element of the system develops two separate sets of rules, one to identify possible object instances and the other to attach probabilities to them. The search for possible object instances is exhaustive; its scale is not great enough for pruning to be necessary. Separate probabilities are established empirically for all combinations of features which could represent object instances. As accurate probabilities cannot be obtained from a set of preselected training examples, they are updated by feedback from the recognition process. The incorporation of rule induction and feedback into the blackboard system is achieved by treating the induced rules as data to be held on a secondary blackboard. The single recognition knowledge source effectively contains empty rules which this data can be slotted into, allowing it to be used to recognise any number of objects - there is no need to develop a separate knowledge source for each object. Additional object-specific background information to aid identification can be added by the user in the form of background checks to be carried out on candidate objects. The system has been tested using synthetic data, and successfully identified combinations of geometric shapes (squares, triangles etc.). Limited tests on photographs of vehicles travelling along a main road were also performed successfully.

621.3994

Performance characteristics of BGO multicrystal block detectors used in positron emission tomography

Mesbahi, Mohammad Esmail

January 1996

Positron Emission Tomography (PET) serves a unique and important role in medical research because it permits non-invasive quantitative study of biological processes using radionuclides of naturally occuring elements. In the last decade, the imaging properties of PET have improved significantly because of better understanding of the design principles and introduction of novel concepts. One such development has been that of the 'block' detector system, consisting of an array of scintillation crystals coupled to a relatively small number of photomultiplier tubes (PMTs). Identification of the particular element in the block is made by comparing the outputs from the PMTs. The block provides the basic unit of the detector rings in modern PET cameras. The prototype block detector system employed in this study incorporates the CTI 831 detector module (49.47 mm wide by 53.36 mm tall by 30 mm deep). This is segmented into a matrix of 8 by 4 crystal elements, 5.62 mm(transaxially) by 12.86 mm (axially) and 30 mm (deep), and coupled to four square PMTs. The drive towards improvement of image quality in PET has prompted the development of even smaller crystals, promising 'high resolution' multiplane imaging. While these detectors have significant advantages over other detectors, the aim of this study was to investigate the physical performance of this specific block detector and to assess how its limitations will affect the information obtained from it. The system investigated offered a coincidence time resolution of 5.8 ±0.3 ns FWHM for a pair of block detectors, an individual crystal energy resolution of 19 % ±3 FWHM at 511 keV, maximum intrinsic efficiency of 45.7% ±0.5 and a column transaxial resolution of 4.2 ±0.4 mm FWHM, offering important immediate advantages. However, the drawback in the current implementation scheme is the nonuniformity across the detector face. The variation of efficiency, energy and spatial resolution for the individual detector crystals across the face of the detector block were investigated, the factors contributing to these variations were identified and suggestions for reducing their effects were made. For example inter-detector scattering was found to be a problem that leads to mispositioning of detected events. Different techniques for evaluating the amount, distribution and consequently the removal of inter-detector scattering were established. Finally these block detectors offer other possibilities like gamma-gamma coincidence imaging, attractive for adaption to neutron induced gamma ray emission tomography (NIGET). This would reduce the long scanning times presently required. However, the 'electronic collimation' provided by the coincidence detection of the two annihilation photons along the line of response between the opposing detectors is lost. Imaging of the cascade gamma rays necessitates the use of physical collimation in order to define a plane through the object. This will however reduce the absolute efficiency of the system from 2.28*10-2t 2*104to 7.3*10-6± 3"10-7w hen collimation is used on both sides but increases the spatial resolution from 5.7 ±0.2 to 2.4 ±0.2 mm. However, if a collimator is used on one side only, the spatial resolution (3.8 ±0.2 mm) obtained is comparable to that of a Ge detector with a1 mm diameter hole collimator and the absolute efficiency of the system (1.1 *10-4±3`10'5) is many times better.

621.3994

Texture mapping architectures for high performance image generation

Dunnett, Graham J.

January 1994

No description available.

621.3994

Local and global interpretation of moving images

Scott, G. L.

January 1986

No description available.

621.3994

Interpreting images of a known moving object

Hogg, D. C.

January 1984

No description available.

621.3994

Auto-tracking antenna pattern effects on multipath channel model at test range

Sung-hoon, Jang, Sung-hee, Han, Heung-bum, Kim

10 1900

International Telemetering Conference Proceedings / October 22-25, 2001 / Riviera Hotel and Convention Center, Las Vegas, Nevada / Telemetry propagation channel is modeled to predict PCM/FM telemetry receiving signal level at APG(Anheung Proving Ground), ADD(Agency for Defense Development). Channel model is composed of direct wave and reflected wave in sea surface, so-called 2-ray model. Our 2-ray model includes transmitting antenna radiation pattern, auto-tracking antenna radiation pattern, sea surface reflection coefficient and phase depending on incident angle. Vertical and horizontal polarized receiving signal strength is obtained from pre-calculated flight trajectory of transmitter. Calculated results are compared with measured data in real flight test. 2-ray channel model can predict almost identical receiving signal level and calculate starting point of multi-path fading effect. Using these results, receiving system can be moved to more proper position before flight test.

Antenna pattern

mutipath fading

2-ray model