181 lines
6.5 KiB
TeX
181 lines
6.5 KiB
TeX
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%%% OUTLINE
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%\documentclass[twocolumn]{article}
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\documentclass{article}
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%\documentclass[twocolumn,10pt]{report}
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\usepackage{graphicx}
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\usepackage{fancyhdr}
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%\usepackage{wassysym}
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\usepackage{tikz}
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\usepackage{amsfonts,amsmath,amsthm}
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\usetikzlibrary{shapes.gates.logic.US,trees,positioning,arrows}
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%\input{../style}
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\usepackage{ifthen}
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\usepackage{lastpage}
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\usetikzlibrary{shapes,snakes}
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\newcommand{\tickYES}{\checkmark}
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\newcommand{\fc}{fault~scenario}
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\newcommand{\fcs}{fault~scenarios}
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\date{}
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%\renewcommand{\encodingdefault}{T1}
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%\renewcommand{\rmdefault}{tnr}
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%\newboolean{paper}
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%\setboolean{paper}{true} % boolvar=true or false
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\newcommand{\derivec}{{D}}
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%\newcommand{\fti}{{ \ensuremath{4\mA \; \rightarrow \; 20mA} }}
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\newcommand{\fti}{4mA~to~20mA}
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\newcommand{\ftt}{FTTI}
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\newcommand{\permil}{\ensuremath{{ }^0/_{00}}}
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\newcommand{\oc}{\ensuremath{^{o}{C}}}
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\newcommand{\adctw}{{${\mathcal{ADC}}_{12}$}}
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\newcommand{\adcten}{{${\mathcal{ADC}}_{10}$}}
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\newcommand{\ohms}[1]{\ensuremath{#1\Omega}}
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\newcommand{\fm}{failure~mode}
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\newcommand{\fms}{failure~modes}
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\newcommand{\fg}{functional~grouping}
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\newcommand{\FG}{\mathcal{G}}
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\newcommand{\DC}{\mathcal{DC}}
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\newcommand{\fgs}{functional~groupings}
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\newcommand{\dc}{derived~component}
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\newcommand{\dcs}{derived~components}
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\newcommand{\bc}{base~component}
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\newcommand{\FMMD}{ModularFMEA}
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\newcommand{\bcs}{base~components}
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\newcommand{\irl}{in real life}
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\newcommand{\enc}{\ensuremath{\stackrel{enc}{\longrightarrow}}}
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\newcommand{\pin}{\ensuremath{\stackrel{pi}{\longleftrightarrow}}}
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%\newcommand{\pic}{\em pure~intersection~chain}
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\newcommand{\pic}{\em pair-wise~intersection~chain}
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\newcommand{\wrt}{\em with~respect~to}
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\newcommand{\abslevel}{\ensuremath{\Psi}}
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\newcommand{\fmmdgloss}{\glossary{name={FMMD},description={Failure Mode Modular De-Composition, a bottom-up methodology for incrementally building failure mode models, using a procedure taking functional groups of components and creating derived components representing them, and in turn using the derived components to create higher level functional groups, and so on, that are used to build a failure mode model of a system}}}
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\newcommand{\fmodegloss}{\glossary{name={failure mode},description={The way in which a failure occurs. A component or sub-system may fail in a number of ways, and each of these is a
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failure mode of the component or sub-system}}}
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\newcommand{\fmeagloss}{\glossary{name={FMEA}, description={Failure Mode and Effects analysis (FMEA) is a process where each potential failure mode within a system, is analysed to determine system level failure modes, and to then classify them {\wrt} perceived severity}}}
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\newcommand{\frategloss}{\glossary{name={failure rate}, description={The number of failure within a population (of size N), divided by N over a given time interval}}}
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\newcommand{\pecgloss}{\glossary{name={PEC},description={A Programmable Electronic controller, will typically consist of sensors and actuators interfaced electronically, with some firmware/software component in overall control}}}
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\newcommand{\bcfm}{base~component~failure~mode}
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\newcommand{\cf}[1]{\textbf{#1()}}
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\newcommand{\swhw}{software~hardware}
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\newcommand{\sw}{software}
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\newcommand{\hw}{hardware}
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\newcommand{\uP}{micro~processor}
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\def\layersep{1.8cm}
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\newboolean{pld}
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\setboolean{pld}{false} % boolvar=true or false : draw analysis using propositional logic diagrams
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\newboolean{dag}
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\setboolean{dag}{true} % boolvar=true or false : draw analysis using directed acylic graphs
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% \setlength{\topmargin}{0in}
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% \setlength{\headheight}{0in}
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% \setlength{\headsep}{0in}
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% \setlength{\textheight}{22cm}
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% \setlength{\textwidth}{18cm}
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% %\setlength{\textheight}{24.35cm}
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% %\setlength{\textwidth}{20cm}
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% \setlength{\oddsidemargin}{0in}
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% \setlength{\evensidemargin}{0in}
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% \setlength{\parindent}{0.0in}
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% %\setlength{\parskip}{6pt}
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% % \setlength{\parskip}{1cm plus4mm minus3mm}
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% \setlength{\parskip}{0pt}
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% \setlength{\parsep}{0pt}
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% \setlength{\headsep}{0pt}
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% \setlength{\topskip}{0pt}
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% \setlength{\topmargin}{0pt}
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% \setlength{\topsep}{0pt}
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% \setlength{\partopsep}{0pt}
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% \setlength{\itemsep}{1pt}
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% \renewcommand\subsection{\@startsection
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% {subsection}{2}{0mm}%
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% {-\baslineskip}
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% {0.5\baselineskip}
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% {\normalfont\normalsize\itshape}}%
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\linespread{1.0}
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\begin{document}
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%\pagestyle{fancy}
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%\fancyhf{}
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%\fancyhead[LO]{}
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%\fancyhead[RE]{\leftmark}
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%\cfoot{Page \thepage\ of \pageref{LastPage}}
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%\rfoot{\today}
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%\lhead{Developing a rigorous bottom-up modular static failure mode modelling methodology}
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%\lhead{Developing a rigorous bottom-up modular static failure modelling methodology}
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% numbers at outer edges
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\pagenumbering{arabic} % Arabic page numbers hereafter
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\author{R.Clark$^\star$ \\ %, A.~Fish$^\dagger$ , C.~Garrett$^\dagger$, J.~Howse$^\dagger$ \\
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$^\star${\em Energy Technology Control, UK. r.clark@energytechnologycontrol.com} \and $^\dagger${\em University of Brighton, UK}
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}
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%\title{Developing a rigorous bottom-up modular static failure mode modelling methodology}
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\title{Matter conceived as whirlpools of trapped energy}
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%\nodate
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\maketitle
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\today
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\paragraph{Keywords:} fermion, boson, matter,relativity, gravity
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%\small
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\abstract{ % \em
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%\input{abs}
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This paper explores ideas about the structure of matter, fermions and bosons,
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as waves, in effect stable whirlpools of energy.
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With this concept in mind, the effects of special and general relativity
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can be visualised.
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%
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} % abstract
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\section{Introduction}
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\begin{itemize}
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\item Objects in matter are whirlpools of energy similar to Jon Conways stable structures in the game of life.
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%
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\item For special relativity, comparing a frame of reference to another moving at some proportion of $c$
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the particle in the faster frame of reference will be stretched along its path of travel.
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%
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Its wave function
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(for it) will appear to be slower than the particle in the slower frame of reference. Thus time
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will appear to slow down for the particle in the faster frame.
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%
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\item For General relativity a particle in an accelerating frame of reference will also have its
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wave path compressed, or squashed, so its wave function has more distance to travel to complete its whirlpool.
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%
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Time will therefore run slower for the particle being accelerated.
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%
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This is bourne out by experiment.
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%
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\end{itemize}
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\section{Modelling 3 dimensional Life whirlpools}
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\section{ Applying acceleration and relative velocity to these models}
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{
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\footnotesize
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\bibliographystyle{plain}
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\bibliography{../../vmgbibliography,../../mybib}
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}
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\today
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%\today
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\end{document}
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