Statistics

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'''Statistics''' is the science and practice of developing human knowledge through the use of empirical data. It is based on statistical theory which is a branch of applied mathematics. Within statistical theory, randomness and uncertainty are modelled by probability theory. Statistical practice includes the planning, summarizing, and interpreting of uncertain observations. Because the aim of statistics is to produce the "best" information from available data, some authors make statistics a branch of decision theory. ==Origin== The word ''statistics'' comes from the modern Latin phrase ''statisticum collegium'' (lecture about state affairs), from which came the Italian word ''statista'', which means "statesman" or "politician" (compare to status) and the German ''Statistik'', originally designating the analysis of data about the state. It acquired the meaning of the collection and classification of data generally in the early nineteenth century. The collection of data about states and localities continues, largely through national and international statistical services; in particular, censuses provide regular information about the population. ==Statistical methods== We describe our knowledge (and ignorance) mathematically and attempt to learn more from whatever we can observe. This requires us to # plan our observations to control their variability (experiment design), # summarize a collection of observations to feature their commonality by suppressing details (descriptive statistics), and # reach consensus about what the observations tell us about the world we observe (statistical inference). In some forms of descriptive statistics, notably data mining, the second and third of these steps become so prominent that the first step (planning) appears to become less important. In these disciplines, data often are collected outside the control of the person doing the analysis, and the result of the analysis may be more an operational model than a consensus report about the world. ==Probability== The probability of an event is often defined as a number between one and zero. In reality however there is virtually nothing that has a probability of 1 or 0. You could say that the sun will certainly rise in the morning, but what if an extremely unlikely event destroys the sun? What if there is a nuclear war and the sky is covered in ash and smoke? We often round the probability of such things up or down because they are so likely or unlikely to occur, that it's easier to recognise them as a probability of one or zero. However, this can often lead to misunderstandings and dangerous behaviour, because people are unable to distinguish between, e.g., a probability of 10⁻⁴ and a probability of 10⁻⁹, despite the very practical difference between them. If you expect to cross the road about 10⁵ or 10⁶ times in your life, then reducing your risk of being run over per road crossing to 10⁻⁹ will make you safe for your whole life, while a risk per road crossing of 10⁻⁴ will make it very likely that you will have an accident, despite the intuitive feeling that 0.01% is a very small risk. Use of prior probabilities of 0 (or 1) causes problems in Bayesian statistics, since the posterior distribution is then forced to be 0 (or 1) as well. In other words, the data is not taken into account at all! As Lindley puts it, if a coherent Bayesian attaches a prior probability of zero to the hypothesis that the Moon is made of green cheese, then even whole armies of astronauts coming back bearing green cheese cannot convince him. Lindley advocates never using prior probabilities of 0 or 1. He calls it Cromwell's rule, from a letter Oliver Cromwell wrote to the synod of the Church of Scotland on August 5th, 1650 in which he said "I beseech you, in the bowels of Christ, consider it possible that you are mistaken." ==Specialized disciplines== Some sciences use applied statistics so extensively that they have specialized terminology. These disciplines include: * Biostatistics * Business statistics * Economic statistics * Engineering statistics * Statistical physics * Demography * Psychological statistics * Social statistics (for all the ''social'' sciences) * Process analysis and Chemometrics (for analysis of data from analytical chemistry and chemical engineering) * Reliability engineering Statistics form a key basis tool in business and manufacturing as well. It is used to understand measurement systems variability, control processes (as in statistical process control or SPC), for summarizing data, and to make data-driven decisions. In these roles it is a key tool, and perhaps the only reliable tool. ==Software== Modern statistics is supported by computers to perform some of the very large and complex calculations required. Whole branches of statistics have been made possible by computing, for example neural networks. The computer revolution has implications for the future of statistics, with a new emphasis on 'experimental' statistics. A list of statistical packages in common use * The R project for statistical computing R programming language [The R Wiki] * S+ -- the S programming language * Matlab * Octave * Excel * SAS * SPSS * STATA * MiniTab == See also == *Analysis of variance (ANOVA) *Extreme value theory *Regression analysis *List of academic statistical associations *List of national and international statistical services *List of statistical topics *List of statisticians *Machine learning *Multivariate statistics *Statistical phenomena *List of publications in statistics ==References== Lindley, D. Making Decisions. John Wiley. Second Edition 1985. ISBN 0471908088 ==External links== {| border="0" width="35%" cellpadding="5" class="noprint floatright" style="border:solid #008 2px; margin:0 0 .5em .5em;" |- |

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|style="font-weight:bold;"|Our sister project, Wikibooks, provides an electronic book on Statistics . |} {| border="0" width="35%" cellpadding="5" class="noprint floatright" style="border:solid #008 2px; margin:0 0 .5em .5em;" |- |

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