J
Jennifer A. Scott
Researcher at Rutherford Appleton Laboratory
Publications - 148
Citations - 3276
Jennifer A. Scott is an academic researcher from Rutherford Appleton Laboratory. The author has contributed to research in topics: Solver & Sparse matrix. The author has an hindex of 27, co-authored 143 publications receiving 2986 citations. Previous affiliations of Jennifer A. Scott include Newcastle University & Science and Technology Facilities Council.
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A Finite element model of heat transport in the human eye
TL;DR: A mathematical model of the human eye based on the bioheat transfer equation is developed and the sensitivity of the temperature distribution to uncertainties in the parameters is investigated, and a set of control parameter values is suggested for the normal human eye.
Journal Article
A numerical evaluation of sparse direct solvers for the solution of large sparse, symmetric linear systems of equations
TL;DR: In this paper, the authors use performance profiles as a tool for evaluating and comparing the performance of serial sparse direct solvers on an extensive set of symmetric test problems taken from a range of practical applications.
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A numerical evaluation of sparse direct solvers for the solution of large sparse symmetric linear systems of equations
TL;DR: This study uses performance profiles as a tool for evaluating and comparing the performance of serial sparse direct solvers on an extensive set of symmetric test problems taken from a range of practical applications.
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The factorization of sparse symmetric indefinite matrices
TL;DR: The Harwell multifrontal code MA27 is able to solve symmetric indefinite systems of linear equations, but may sometimes lead to many more arithmetic operations being needed to factorize the matrix than is required by other strategies.
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The computation of temperature rises in the human eye induced by infrared radiation.
TL;DR: A finite element model of the human eye is employed to calculate the temperature rises experienced by the intraocular media when exposed to infrared radiation, and the effect of the eye's natural cooling mechanisms on the heating is investigated.