Three-dimensional Monte Carlo simulation of ion implantation

Li, Di

28 August 2008

Not available / text

Ion implantation--Computer simulation

Monte Carlo method

Towards a theory of affective mind: computationally modeling the generativity of goal appraisal

Jarrold, William Lawrence

28 August 2008

Not available / text

Emotions and cognition

Empathy

Modeling the self-organization of color selectivity in the visual cortex

De Paula, Judah Ben, 1978-

28 August 2008

How does the visual cortex represent and process color? Experimental evidence from macaque monkey suggests that cells selective for color are organized into small, spatially separated blobs in V1, and stripes in V2. This organization is strikingly different from that of orientation and ocular dominance maps, which consist of large, spatially contiguous patterns. In this dissertation, a self-organizing model of the early visual cortex is constructed using natural color image input. The modeled V1 develops realistic color-selective receptive fields, ocular dominance stripes, orientation maps, and color-selective regions, while the modeled V2 also creates realistic colorselective and orientation-selective neurons. V1 color-selective regions are generally located in the center of ocular dominance stripes as they are in biological maps; the model predicts that color-selective regions become more widespread in both cortical regions when the amount of color in the training images is increased. The model also predicts that in V1 there are three types of color-selective regions (red-selective, greenselective, and blue-selective), and that a unique cortical activation pattern exists for each of the HSV colors. In both V1 and V2, when regions of different color-selectivity are located nearby, bands of color form with gradually changing color preferences. The model also develops lateral connections between cells that are selective for similar orientations, matching previous experimental results, and predicts that cells selective for color primarily connect to other cells with similar chromatic preferences. Thus the model replicates the known data on the organization of color preferences in V1 and V2, provides a detailed explanation for how this structure develops and functions, and leads to concrete predictions to test in future experiments.

Visual cortex--Computer simulation

Color vision

Monte Carlo simulation of MeV ion implantation with computationally efficient models

Wang, Greg

11 April 2011

Not available / text

Ion implantation--Computer simulation

Monte Carlo method

An effective method of stochastic simulation of complex large-scale transport processes in naturally fractured reservoirs

Hu, Yujie

25 April 2011

Not available / text

Rocks--Fractures--Computer simulation

Stochastic analysis

Ultra-shallow junction formation : co-implantation and rapid thermal annealing

Li, Hong-jyh

16 May 2011

Not available / text

Boron compounds

Ion implantation

Diffusion--Computer simulation

General approach to automated analysis of thyristor converters with protective circuits

Law, Hing-yim, 羅慶琰

January 1978

published_or_final_version / Electrical Engineering / Master / Master of Philosophy

Thyristors.

Electric current converters.

Digital computer simulation.

Calibration of new sheared delay formulae for the estimation of queuesand delays in TRANSYT

Wong, Wai-tak., 王偉德.

January 1999

published_or_final_version / Civil Engineering / Master / Master of Philosophy

Computer modelling of cloth objects

趙宇飛, Zhao, Yufei.

January 1997

published_or_final_version / Mechanical Engineering / Doctoral / Doctor of Philosophy

Textile fabrics - Computer simulation.

Finite element method.

Application of traffic simulation by digital computer to the design ofa network of signalized intersections

Nip, Kam-fan, 聶錦勳

January 1973

published_or_final_version / Civil Engineering / Doctoral / Doctor of Philosophy

Traffic engineering.

Digital computer simulation.

Simulation methods.