166 research outputs found
A conceptual model for e-government adoption in Egypt
Electronic government (e-government) was created as an efficient method for government adeptness and proficiency as a vital facilitator for citizen-oriented services. Since their establishment over a decade ago, E-government services are recognised as a vehicle for accessing online public services. Both governments and academic researchers comprehend the difficulty of low-level adoption of e-government services among citizens; a shared issue between both developing and developed countries. This paper investigates determinants and factors necessary to enhance adoption of citizens for e- government services in developing countries, with particular focus on Egypt, by extending the Technology Acceptance Model (TAM) using a set of political, social, and design constructs that were developed from different sources of research literatur
Assessing the adoption of e-government using TAM model: case of Egypt
Electronic government (e-government) was known as an efficient method for government expertness and proficiency as a vital facilitator for citizen-oriented services. Since their initiation over a decade ago, Egovernment services are recognised as a vehicle for accessing online public services. Both governments and academic researchers understand the difficulty of low-level adoption of e-government services among citizens; a common problem between both developing and developed countries. This paper investigates determinants and factors necessary to enhance adoption of citizens for e-government services in developing countries, with particular focus on Egypt, by extending the Technology Acceptance Model (TAM) using a set of political, social, and design constructs that were developed from different sources of research literature
On the thermodynamic framework of generalized coupled thermoelastic-viscoplastic-damage modeling
A complete potential based framework using internal state variables is put forth for the derivation of reversible and irreversible constitutive equations. In this framework, the existence of the total (integrated) form of either the (Helmholtz) free energy or the (Gibbs) complementary free energy are assumed a priori. Two options for describing the flow and evolutionary equations are described, wherein option one (the fully coupled form) is shown to be over restrictive while the second option (the decoupled form) provides significant flexibility. As a consequence of the decoupled form, a new operator, i.e., the Compliance operator, is defined which provides a link between the assumed Gibb's and complementary dissipation potential and ensures a number of desirable numerical features, for example the symmetry of the resulting consistent tangent stiffness matrix. An important conclusion reached, is that although many theories in the literature do not conform to the general potential framework outlined, it is still possible in some cases, by slight modifications of the used forms, to restore the complete potential structure
Explicit robust schemes for implementation of a class of principal value-based constitutive models: Theoretical development
The issue of developing effective and robust schemes to implement a class of the Ogden-type hyperelastic constitutive models is addressed. To this end, explicit forms for the corresponding material tangent stiffness tensors are developed, and these are valid for the entire deformation range; i.e., with both distinct as well as repeated principal-stretch values. Throughout the analysis the various implications of the underlying property of separability of the strain-energy functions are exploited, thus leading to compact final forms of the tensor expressions. In particular, this facilitated the treatment of complex cases of uncoupled volumetric/deviatoric formulations for incompressible materials. The forms derived are also amenable for use with symbolic-manipulation packages for systematic code generation
A study of SNARE-mediated autophagosome clearance using fluorescence lifetime microscopy
Cell survival requires the turnover of toxic cellular material and recycling of
biomolecules in low nutrient conditions. An efficient degradation system is
therefore essential for disease prevention and its dysfunction has been linked to
both neurodegeneration and oncogenesis. Bulk degradation is accomplished
through the collection of cytoplasmic material in a unique sequestration vesicle,
which forms de novo and subsequently deposits cargo in the lysosome for
degradation. This process, known as autophagy, therefore requires membrane
fusion between the autophagosomal vesicle and the lysosome. SNARE proteins
mediate membrane fusion events and therefore their careful regulation ensures
the proper organisation of the membrane trafficking network. The SNARE proteins
governing autophagosome clearance have been identified as syntaxin 17, SNAP29
and VAMP8 and SNARE assembly appears to be positively regulated by VPS33A.
This well established model of SNARE-mediated autophagosome clearance has not,
however, been demonstrated within the spatiotemporal framework of the cell and
little is known about how VPS33A modulates SNARE function. The research
presented in this thesis therefore aims to determine the applicability of the
proposed SNARE model within the cellular environment and to investigate the
regulatory mechanisms controlling syntaxin 17 function. To accomplish this,
carefully validated fluorescence colocalisation and time-resolved fluorescence
lifetime imaging techniques were primarily employed. The limitations of these
techniques were also considered for data interpretation and a novel prototype
SPAD array technology, designed for high-speed time-correlated single photon
counting, was trialled for widefield FLIM-FRET. FLIM-FRET revealed that VAMP8
has been incorrectly assigned as the dominant autophagosomal R-SNARE and
VPS33A studies evidence a multi-modal regulation of Stx17 that diverges from
other studied syntaxin family modulation mechanisms. A new model of SNAREmediated
autophagosome clearance is therefore proposed, where syntaxin 17
engages with SNAP29 and VAMP7 to drive membrane fusion with the
endolysosome in a manner governed by VPS33A and dependent on the
phosphorylation status of syntaxin 17
Explicit robust schemes for implementation of a class of principal value-based constitutive models: Symbolic and numeric implementation
The issue of developing effective and robust schemes to implement a class of the Ogden-type hyperelastic constitutive models is addressed. To this end, special purpose functions (running under MACSYMA) are developed for the symbolic derivation, evaluation, and automatic FORTRAN code generation of explicit expressions for the corresponding stress function and material tangent stiffness tensors. These explicit forms are valid over the entire deformation range, since the singularities resulting from repeated principal-stretch values have been theoretically removed. The required computational algorithms are outlined, and the resulting FORTRAN computer code is presented
On the symbolic manipulation and code generation for elasto-plastic material matrices
A computerized procedure for symbolic manipulations and FORTRAN code generation of an elasto-plastic material matrix for finite element applications is presented. Special emphasis is placed on expression simplifications during intermediate derivations, optimal code generation, and interface with the main program. A systematic procedure is outlined to avoid redundant algebraic manipulations. Symbolic expressions of the derived material stiffness matrix are automatically converted to RATFOR code which is then translated into FORTRAN statements through a preprocessor. To minimize the interface problem with the main program, a template file is prepared so that the translated FORTRAN statements can be merged into the file to form a subroutine (or a submodule). Three constitutive models; namely, von Mises plasticity, Drucker-Prager model, and a concrete plasticity model, are used as illustrative examples
Explicit robust schemes for implementation of general principal value-based constitutive models
The issue of developing effective and robust schemes to implement general hyperelastic constitutive models is addressed. To this end, special purpose functions are used to symbolically derive, evaluate, and automatically generate the associated FORTRAN code for the explicit forms of the corresponding stress function and material tangent stiffness tensors. These explicit forms are valid for the entire deformation range. The analytical form of these explicit expressions is given here for the case in which the strain-energy potential is taken as a nonseparable polynomial function of the principle stretches
A General Reversible Hereditary Constitutive Model
Using an internal-variable formalism as a starting point, we describe the viscoelastic extension of a previously-developed viscoplasticity formulation of the complete potential structure type. It is mainly motivated by experimental evidence for the presence of rate/time effects in the so-called quasilinear, reversible, material response range. Several possible generalizations are described, in the general format of hereditary-integral representations for non-equilibrium, stress-type, state variables, both for isotropic as well as anisotropic materials. In particular, thorough discussions are given on the important issues of thermodynamic admissibility requirements for such general descriptions, resulting in a set of explicit mathematical constraints on the associated kernel (relaxation and creep compliance) functions. In addition, a number of explicit, integrated forms are derived, under stress and strain control to facilitate the parametric and qualitative response characteristic studies reported here, as well as to help identify critical factors in the actual experimental characterizations from test data that will be reported in Part II
Parameter Estimation for Viscoplastic Material Modeling
A key ingredient in the design of engineering components and structures under general thermomechanical loading is the use of mathematical constitutive models (e.g. in finite element analysis) capable of accurate representation of short and long term stress/deformation responses. In addition to the ever-increasing complexity of recent viscoplastic models of this type, they often also require a large number of material constants to describe a host of (anticipated) physical phenomena and complicated deformation mechanisms. In turn, the experimental characterization of these material parameters constitutes the major factor in the successful and effective utilization of any given constitutive model; i.e., the problem of constitutive parameter estimation from experimental measurements
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