SRT Division Algorithms As Dynamical Systems

Sweeney--Robertson--Tocher (SRT) division, as it was discovered in the late 1950s, represented an important improvement in the speed of division algorithms for computers at the time. A variant of SRT division is still commonly implemented in computers today. Although some bounds on the performance of the original SRT division method were obtained, a great many questions remained unanswered. In this paper, the original version of SRT division is described as a dynamical system. This enables us to bring modern dynamical systems theory, a relatively new development in mathematics, to bear on an older problem. In doing so, we are able to show that SRT division is ergodic, and is even Bernoulli, for all real divisors and dividends. With the Bernoulli property, we are able to use entropy to prove that the natural extensions of SRT division are isomorphic by way of the Kolmogorov--Ornstein theorem. We demonstrate how our methods and results can be applied to a much larger class of division algorithms

Some Results in the Theory of Arithmetic Codes

Coordinated Science Laboratory was formerly known as Control Systems LaboratoryJoint Services Electronics Program / DAAB 07-67-C-0199National Science Foundation / GK-1690 and GK-233

Cellular Automata on Group Sets

We introduce and study cellular automata whose cell spaces are left-homogeneous spaces. Examples of left-homogeneous spaces are spheres, Euclidean spaces, as well as hyperbolic spaces acted on by isometries; uniform tilings acted on by symmetries; vertex-transitive graphs, in particular, Cayley graphs, acted on by automorphisms; groups acting on themselves by multiplication; and integer lattices acted on by translations. For such automata and spaces, we prove, in particular, generalisations of topological and uniform variants of the Curtis-Hedlund-Lyndon theorem, of the Tarski-F{\o}lner theorem, and of the Garden-of-Eden theorem on the full shift and certain subshifts. Moreover, we introduce signal machines that can handle accumulations of events and using such machines we present a time-optimal quasi-solution of the firing mob synchronisation problem on finite and connected graphs.Comment: This is my doctoral dissertation. It consists of extended versions of the articles arXiv:1603.07271 [math.GR], arXiv:1603.06460 [math.GR], arXiv:1603.07272 [math.GR], arXiv:1701.02108 [math.GR], arXiv:1706.05827 [math.GR], and arXiv:1706.05893 [cs.FL

Design and optimization of approximate multipliers and dividers for integer and floating-point arithmetic

The dawn of the twenty-first century has witnessed an explosion in the number of digital devices and data. While the emerging deep learning algorithms to extract information from this vast sea of data are becoming increasingly compute-intensive, traditional means of improving computing power are no longer yielding gains at the same rate due to the diminishing returns from traditional technology scaling. To minimize the increasing gap between computational demands and the available resources, the paradigm of approximate computing is emerging as one of the potential solutions. Specifically, the resource-efficient approximate arithmetic units promise overall system efficiency, since most of the compute-intensive applications are dominated by arithmetic operations. This thesis primarily presents design techniques for approximate hardware multipliers and dividers. The thesis presents the design of two approximate integer multipliers and an approximate integer divider. These are: an error-configurable minimally-biased approximate integer multiplier (MBM), an error-configurable reduced-error approximate log based multiplier (REALM), and error-configurable integer divider INZeD. The two multiplier designs and the divider designs are based on the coupling of novel mathematically formulated error-reduction mechanisms in the classical approximate log based multiplier and dividers, respectively. They exhibit very low error bias and offer Pareto-optimal error vs. resource-efficiency trade-offs when compared with the state-of-the-art approximate integer multipliers/dividers. Further, the thesis also presents design of approximate floating-point multipliers and dividers. These designs utilize the optimized versions of the proposed MBM and REALM multipliers for mantissa multiplications and the proposed INZeD divider for mantissa division, and offer better design trade-offs than traditional precision scaling. The existing approximate integer dividers as well as the proposed INZeD suffer from unreasonably high worst-case error. This thesis presents WEID, which is a novel light-weight method for reducing worst-case error in approximate dividers. Finally, the thesis presents a methodology for selection of approximate arithmetic units for a given application. The methodology is based on a novel selection algorithm and utilizes the subrange error characterization of approximate arithmetic units, which performs error characterization independently in different segments of the input range

On Algebraic Singularities, Finite Graphs and D-Brane Gauge Theories: A String Theoretic Perspective

In this writing we shall address certain beautiful inter-relations between the construction of 4-dimensional supersymmetric gauge theories and resolution of algebraic singularities, from the perspective of String Theory. We review in some detail the requisite background in both the mathematics, such as orbifolds, symplectic quotients and quiver representations, as well as the physics, such as gauged linear sigma models, geometrical engineering, Hanany-Witten setups and D-brane probes. We investigate aspects of world-volume gauge dynamics using D-brane resolutions of various Calabi-Yau singularities, notably Gorenstein quotients and toric singularities. Attention will be paid to the general methodology of constructing gauge theories for these singular backgrounds, with and without the presence of the NS-NS B-field, as well as the T-duals to brane setups and branes wrapping cycles in the mirror geometry. Applications of such diverse and elegant mathematics as crepant resolution of algebraic singularities, representation of finite groups and finite graphs, modular invariants of affine Lie algebras, etc. will naturally arise. Various viewpoints and generalisations of McKay's Correspondence will also be considered. The present work is a transcription of excerpts from the first three volumes of the author's PhD thesis which was written under the direction of Prof. A. Hanany - to whom he is much indebted - at the Centre for Theoretical Physics of MIT, and which, at the suggestion of friends, he posts to the ArXiv pro hac vice; it is his sincerest wish that the ensuing pages might be of some small use to the beginning student.Comment: 513 pages, 71 figs, Edited Excerpts from the first 3 volumes of the author's PhD Thesi

On algebraic singularities, finite graphs and D-brane gauge theories: A String theoretic perspective

In this writing we shall address certain beautiful inter-relations between the construction of 4-dimensional supersymmetric gauge theories and resolution of algebraic singularities, from the perspective of String Theory. We review in some detail the requisite background in both the mathematics, such as orbifolds, symplectic quotients and quiver representations, as well as the physics, such as gauged linear sigma models, geometrical engineering, Hanany-Witten setups and D-brane probes. We investigate aspects of world-volume gauge dynamics using D-brane resolutions of various Calabi-Yau singularities, notably Gorenstein quotients and toric singularities. Attention will be paid to the general methodology of constructing gauge theories for these singular backgrounds, with and without the presence of the NS-NS B-field, as well as the T-duals to brane setups and branes wrapping cycles in the mirror geometry. Applications of such diverse and elegant mathematics as crepant resolution of algebraic singularities, representation of finite groups and finite graphs, modular invariants of affine Lie algebras, etc. will naturally arise. Various viewpoints and generalisations of McKay's Correspondence will also be considered. The present work is a transcription of excerpts from the first three volumes of the author's PhD thesis which was written under the direction of Prof. A. Hanany - to whom he is much indebted - at the Centre for Theoretical Physics of MIT, and which, at the suggestion of friends, he posts to the ArXiv pro hac vice; it is his sincerest wish that the ensuing pages might be of some small use to the beginning student

Educating and training mathematics teachers for secondary schools in Ireland: a new perspective on teacher education

This thesis is a record of experiments in the education of mathematics teachers for Irish Secondary schools conducted at Thomond College of Education, Limerick during the years 1975–77 inclusive. But it is more than a mere record of successes and failures. In its analyses and syntheses, based on experiments and programmes conducted under actual conditions, it endeavours in a true spirit of research in mathematical education to provide new insights. The research culminates in the redefinition of an old problem in mathematical education, and a first step towards a viable solution to the redefined problem is presented