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ANZIAM Journal
Journal Prestige (SJR): 0.216  Number of Followers: 1  Open Access journalISSN (Print) 1446-1811 - ISSN (Online) 1446-8735 Published by Cambridge University Press  [353 journals]
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- ANZ VOLUME 63 ISSUE 4 COVER AND FRONT MATTER
Pages: 1 - 2
PubDate: 2021-12-06
DOI: 10.1017/S1446181121000195
- ANZ VOLUME 63 ISSUE 4 COVER AND BACK MATTER
Pages: 1 - 6
PubDate: 2021-12-06
DOI: 10.1017/S1446181121000201
- IDEAL PLANAR FLUID FLOW OVER A SUBMERGED OBSTACLE: REVIEW AND EXTENSION
Authors: FORBES; LAWRENCE K., WALTERS, STEPHEN J., HOCKING, GRAEME C.
Pages: 377 - 419
Abstract: A classical problem in free-surface hydrodynamics concerns flow in a channel, when an obstacle is placed on the bottom. Steady-state flows exist and may adopt one of three possible configurations, depending on the fluid speed and the obstacle height; perhaps the best known has an apparently uniform flow upstream of the obstacle, followed by a semiinfinite train of downstream gravity waves. When time-dependent behaviour is taken into account, it is found that conditions upstream of the obstacle are more complicated, however, and can include a train of upstream-advancing solitons. This paper gives a critical overview of these concepts, and also presents a new semianalytical spectral method for the numerical description of unsteady behaviour.
PubDate: 2021-10-25
DOI: 10.1017/S1446181121000341
- NUMERICAL SOLUTIONS TO A FRACTIONAL DIFFUSION EQUATION USED IN MODELLING
DYE-SENSITIZED SOLAR CELLS
Authors: MALDON; BENJAMIN, LAMICHHANE, BISHNU PRASAD, THAMWATTANA, NGAMTA
Pages: 420 - 433
Abstract: Dye-sensitized solar cells consistently provide a cost-effective avenue for sources of renewable energy, primarily due to their unique utilization of nanoporous semiconductors. Through mathematical modelling, we are able to uncover insights into electron transport to optimize the operating efficiency of the dye-sensitized solar cells. In particular, fractional diffusion equations create a link between electron density and porosity of the nanoporous semiconductors. We numerically solve a fractional diffusion model using a finite-difference method and a finite-element method to discretize space and an implicit finite-difference method to discretize time. Finally, we calculate the accuracy of each method by evaluating the numerical errors under grid refinement.
PubDate: 2021-11-16
DOI: 10.1017/S1446181121000353
- DO POOR ENVIRONMENTAL CONDITIONS DRIVE TRACHOMA TRANSMISSION IN
BURUNDI' A MATHEMATICAL MODELLING STUDY
Authors: NDISABIYE; D., WATERS, E. K., GORE, R., SIDHU, H.
Pages: 434 - 447
Abstract: Trachoma is an infectious disease and it is the leading cause of preventable blindness worldwide. To achieve its elimination, the World Health Organization set a goal of reducing the prevalence in endemic areas to less than
% by 2020, utilizing the SAFE (surgery, antibiotics, facial cleanliness, environmental improvement) strategy. However, in Burundi, trachoma prevalences of greater than 
% are still reported in 11 districts and it is hypothesized that this is due to the poor implementation of the environmental improvement factor of the SAFE strategy. In this paper, a model based on an ordinary differential equation, which includes an environmental transmission component, is developed and analysed. The model is calibrated to recent field data and is used to estimate the reductions in trachoma that would have occurred if adequate environmental improvements were implemented in Burundi. Given the assumptions in the model, it is clear that environmental improvement should be considered as a key component of the SAFE strategy and, hence, it is crucial for eliminating trachoma in Burundi.
PubDate: 2021-11-22
DOI: 10.1017/S1446181121000389
- BOUNDS ON THE CRITICAL TIMES FOR THE GENERAL FISHER–KPP EQUATION
Authors: RODRIGO; MARIANITO R.
Pages: 448 - 468
Abstract: The Fisher–Kolmogorov–Petrovsky–Piskunov (Fisher–KPP) equation is one of the prototypical reaction–diffusion equations and is encountered in many areas, primarily in population dynamics. An important consideration for the phenomena modelled by diffusion equations is the length of the diffusive process. In this paper, three definitions of the critical time are given, and bounds are obtained by a careful construction of the upper and lower solutions. The comparison functions satisfy the nonlinear, but linearizable, partial differential equations of Fisher–KPP type. Results of the numerical simulations are displayed. Extensions to some classes of reaction–diffusion systems and an application to a spatially heterogeneous harvesting model are also presented.
PubDate: 2021-11-02
DOI: 10.1017/S1446181121000365
- A MESHLESS LOCAL GALERKIN INTEGRAL EQUATION METHOD FOR SOLVING A TYPE OF
DARBOUX PROBLEMS BASED ON RADIAL BASIS FUNCTIONS
Authors: ASSARI; P., ASADI-MEHREGAN, F., DEHGHAN, M.
Pages: 469 - 492
Abstract: The main goal of this paper is to solve a class of Darboux problems by converting them into the two-dimensional nonlinear Volterra integral equation of the second kind. The scheme approximates the solution of these integral equations using the discrete Galerkin method together with local radial basis functions, which use a small set of data instead of all points in the solution domain. We also employ the Gauss–Legendre integration rule on the influence domains of shape functions to compute the local integrals appearing in the method. Since the scheme is constructed on a set of scattered points and does not require any background meshes, it is meshless. The error bound and the convergence rate of the presented method are provided. Some illustrative examples are included to show the validity and efficiency of the new technique. Furthermore, the results obtained demonstrate that this method uses much less computer memory than the method established using global radial basis functions.
PubDate: 2021-11-09
DOI: 10.1017/S1446181121000377
