31 research outputs found
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Active Contour Models
Active contour models have been widely applied to image segmentation and
analysis. It has been successfully used in contour detection for object recognition,
computer vision, computer graphics, and biomedical image processing such as X-ray,
MRI and Ultrasound images.
The energy-minimizing active contour models or snakes were developed by Kass,
Witkin and Terzopoulos in 1987. Snakes are curves defined in the image domain that
can move under the influence of internal forces within the curve itself and external
forces derived from the image data. Snakes perform well on certain types of images
(such as well-defined, convex shapes). There have been several improvements proposed
to the original snake or active contour model. These improvements include balloon
snakes, adaptive snakes, and GVF snakes. In this project, I reviewed and implemented
their algorithms as well as the original snake model.
GCBAC (Graph Cut Based Active Contour) is one of alternative solutions to the
object extraction problem. Although the GCBAC belongs to family of active contour
models, it differs fundamentally from original active contours. In this project, I also
review and implement the GCBAC algorithm as well
ANALYSIS AND CONTROL OF ELECTRICAL PROPERTIES OF ORGANIC MATERIALS BASED ON MORPHOLOGICAL AND STRUCTURAL CHARACTERISTICS FOR VARIOUS DEVICE APPLICATIONS
The discovery of electrical properties in organic π-conjugated materials signaled the rise in organic electronics. The delocalized nature of the π-orbitals from resonance stabilization opened new opportunities to design and engineer materials in micro/nano scales. Advantages of organic electronics are that they are transparent, printable, flexible, tunable, biocompatible, and solution processable materials.
However, these very advantages also make organic electrical materials less crystalline and ordered compared to inorganic materials, making it challenging to fabricate organic electronics with the high stability and performance of inorganic materials. Hence, many engineering strategies have been implemented to gain control over or an understanding of the packing parameters of small organic molecules when made into solid state devices. Two engineering approaches are widely adopted in this respect: molecular design and blending of different organic molecules.
In Chapter 2., we explore how molecular design affects packing parameters of organic molecules by analyzing various material properties of thin films made of pH triggered self-assembling peptide-Ď€-peptide molecules. We report interesting correlations between organic-inorganic hybrid systems where highly conductive electronic conduction pathways were occasionally formed. Based on this, we have found that the interaction between organic and inorganic domains fundamentally affects the electrical and structural properties of the ensuing solid state thin films. It was shown that we can control the structural and electrical properties of the organic-inorganic hybrid systems by altering the peptide side chains as well as the acid/base used to form the inorganic minerals.
In chapter 3, an electrically active small organic molecule (α4T) was blended in polystyrene (PS) dielectric matrix. At concentrations of α4T before percolation of the PS thin film, α4T crystals localized charges when charges were injected into dielectrics containing these crystals. The presence of α4T crystals increased dielectric polarization potential of the dielectric, storing charges more stably in the dielectric and increasing the maximum charge storage capacity. At concentrations of α4T above when percolation occurs, doping of α4T crystals by gases were observed electrically in reversible and non-reversible ways. Doping α4T by gases were shown to affect the structural, electrical, and thermodynamic properties of the α4T-PS blended thin films
Experimental Study: Enhancing Voice Spoofing Detection Models with wav2vec 2.0
Conventional spoofing detection systems have heavily relied on the use of
handcrafted features derived from speech data. However, a notable shift has
recently emerged towards the direct utilization of raw speech waveforms, as
demonstrated by methods like SincNet filters. This shift underscores the demand
for more sophisticated audio sample features. Moreover, the success of deep
learning models, particularly those utilizing large pretrained wav2vec 2.0 as a
featurization front-end, highlights the importance of refined feature encoders.
In response, this research assessed the representational capability of wav2vec
2.0 as an audio feature extractor, modifying the size of its pretrained
Transformer layers through two key adjustments: (1) selecting a subset of
layers starting from the leftmost one and (2) fine-tuning a portion of the
selected layers from the rightmost one. We complemented this analysis with five
spoofing detection back-end models, with a primary focus on AASIST, enabling us
to pinpoint the optimal configuration for the selection and fine-tuning
process. In contrast to conventional handcrafted features, our investigation
identified several spoofing detection systems that achieve state-of-the-art
performance in the ASVspoof 2019 LA dataset. This comprehensive exploration
offers valuable insights into feature selection strategies, advancing the field
of spoofing detection.Comment: 5 page
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Development of an online genome sequence annotation pipeline
Advances in DNA sequencing technology have significantly reduced the costs associated with sequencing an organism's genome. This has led to greater numbers of plant genomes being sequenced. Once sequenced and re-assembled, these genome sequences are annotated to identify genes and other important sequence features. Annotation usually involves computational analysis by a bioinformaticist followed by manual (biologist) curation of the predicted genes. While there are many standalone (command line) pipelines available and many individual web based tools available for annotation, there are no one-stop web sites where the biologist can access several gene prediction tools and have the integrated and optimized results returned to them for manual curation. Several fruit genomes are currently being sequenced (apple, peach, strawberry, citrus and cacao) and the annotations will be made available via the tree fruit genome databases housed at Washington State University. This project focuses on implementing a framework of web-based gene prediction and comparative sequence similarity applications that performs automated sequence annotation including gene structure and function predictions, and enable user based manipulation of the results via the application GenSAS, the Genome Sequence Annotation Server
Improved tensile properties of AZ31 Mg alloy subjected to various caliber-rolling strains
A multi-pass caliber rolling has attracted attentions as an alternative to severe plastic deformation processes. The present study enhanced strength and ductility of AZ31 Mg alloy simultaneously through the application of caliber rolling. The improving trends in tensile properties were interpreted with various caliber-rolling strains. The oval/circular-shaped calibers imposed a high plastic strain at the center of cross-section, leading to effective grain refinement to submicron scale. This work also confirmed the texture randomizing effect of caliber rolling. Such microstructural evolutions gave rise to the fabrication of high-strength material. Moreover, the caliber-rolled AZ31 Mg alloys exhibited an improvement in ductility as compared to the as-received sheet-rolled material. This was discussed in terms of activation of non-basal slip systems and suppression of mechanical twinning. This study successfully proved the possibility of caliber rolling to produce a bulk Mg rod with enhanced tensile properties. Keywords: Magnesium, AZ31 alloy, Caliber rolling, Grain refinement, Texture randomization, Mechanical improvemen
Synteny of Prunus and other model plant species
BACKGROUND: Fragmentary conservation of synteny has been reported between map-anchored Prunus sequences and Arabidopsis. With the availability of genome sequence for fellow rosid I members Populus and Medicago, we analyzed the synteny between Prunus and the three model genomes. Eight Prunus BAC sequences and map-anchored Prunus sequences were used in the comparison. RESULTS: We found a well conserved synteny across the Prunus species – peach, plum, and apricot – and Populus using a set of homologous Prunus BACs. Conversely, we could not detect any synteny with Arabidopsis in this region. Other peach BACs also showed extensive synteny with Populus. The syntenic regions detected were up to 477 kb in Populus. Two syntenic regions between Arabidopsis and these BACs were much shorter, around 10 kb. We also found syntenic regions that are conserved between the Prunus BACs and Medicago. The array of synteny corresponded with the proposed whole genome duplication events in Populus and Medicago. Using map-anchored Prunus sequences, we detected many syntenic blocks with several gene pairs between Prunus and Populus or Arabidopsis. We observed a more complex network of synteny between Prunus-Arabidopsis, indicative of multiple genome duplication and subsequence gene loss in Arabidopsis. CONCLUSION: Our result shows the striking microsynteny between the Prunus BACs and the genome of Populus and Medicago. In macrosynteny analysis, more distinct Prunus regions were syntenic to Populus than to Arabidopsis
Addition of a breeding database in the Genome Database for Rosaceae
Breeding programs produce large datasets that require efficient management systems to keep track of performance, pedigree, geographical and image-based data. With the development of DNA-based screening technologies, more breeding programs perform genotyping in addition to phenotyping for performance evaluation. The integration of breeding data with other genomic and genetic data is instrumental for the refinement of marker-assisted breeding tools, enhances genetic understanding of important crop traits and maximizes access and utility by crop breeders and allied scientists. Development of new infrastructure in the Genome Database for Rosaceae (GDR) was designed and implemented to enable secure and efficient storage, management and analysis of large datasets from the Washington State University apple breeding program and subsequently expanded to fit datasets from other Rosaceae breeders. The infrastructure was built using the software Chado and Drupal, making use of the Natural Diversity module to accommodate large-scale phenotypic and genotypic data. Breeders can search accessions within the GDR to identify individuals with specific trait combinations. Results from Search by Parentage lists individuals with parents in common and results from Individual Variety pages link to all data available on each chosen individual including pedigree, phenotypic and genotypic information. Genotypic data are searchable by markers and alleles; results are linked to other pages in the GDR to enable the user to access tools such as GBrowse and CMap. This breeding database provides users with the opportunity to search datasets in a fully targeted manner and retrieve and compare performance data from multiple selections, years and sites, and to output the data needed for variety release publications and patent applications. The breeding database facilitates efficient program management. Storing publicly available breeding data in a database together with genomic and genetic data will further accelerate the cross-utilization of diverse data types by researchers from various disciplines. Database URL: http://www.rosaceae.org/breeders_toolbox
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Extension modules for storage, visualization and querying of genomic, genetic and breeding data in Tripal databases
Tripal is an open-source database platform primarily used for development of genomic, genetic and breeding databases. We report here on the release of the Chado Loader, Chado Data Display and Chado Search modules to extend the functionality of the core Tripal modules. These new extension modules provide additional tools for (1) data loading, (2) customized visualization and (3) advanced search functions for supported data types such as organism, marker, QTL/Mendelian Trait Loci, germplasm, map, project, phenotype, genotype and their respective metadata. The Chado Loader module provides data collection templates in Excel with defined metadata and data loaders with front end forms. The Chado Data Display module contains tools to visualize each data type and the metadata which can be used as is or customized as desired. The Chado Search module provides search and download functionality for the supported data types. Also included are the tools to visualize map and species summary. The use of materialized views in the Chado Search module enables better performance as well as flexibility of data modeling in Chado, allowing existing Tripal databases with different metadata types to utilize the module. These Tripal Extension modules are implemented in the Genome Database for
Rosaceae
(rosaceae.org), CottonGen (cottongen.org), Citrus Genome Database (citrusgenomedb.org), Genome Database for Vaccinium (vaccinium.org) and the Cool Season Food Legume Database (coolseasonfoodlegume.org).
Database URL
:
https://www.citrusgenomedb.org/
,
https://www.coolseasonfoodlegume.org/
,
https://www.cottongen.org/
,
https://www.rosaceae.org/
,
https://www.vaccinium.org