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Multivariate statistics is a subdivision of statistics encompassing the simultaneous observation and analysis of more than one outcome variable. The application of multivariate statistics is multivariate analysis. Multivariate statistics concerns understanding the different aims and background of each of the different forms of multivariate analysis, and how they relate to each other. The practical implementation of multivariate statistics to a particular problem may involve several types of univariate and multivariate analyses in order to understand the relationships between variables and their relevance to the actual problem being studied. In addition, multivariate statistics is concerned with multivariate probability distributions, in terms of both : *how these can be used to represent the distributions of observed data; : *how they can be used as part of statistical inference, particularly where several different quantities are of interest to the same analysis. Certain types of problem involving multivariate data, for example simple linear regression and multiple regression, are ''not'' usually considered as special cases of multivariate statistics because the analysis is dealt with by considering the (univariate) conditional distribution of a single outcome variable given the other variables. ==Types of analysis== There are many different models, each with its own type of analysis: # Multivariate analysis of variance (MANOVA) extends the analysis of variance to cover cases where there is more than one dependent variable to be analyzed simultaneously; see also MANCOVA. #Multivariate regression attempts to determine a formula that can describe how elements in a vector of variables respond simultaneously to changes in others. For linear relations, regression analyses here are based on forms of the general linear model. Note that Multivariate regression is distinct from Multivariable regression, which has only one dependent variable.〔Hidalgo, Bertha, and Melody Goodman. "Multivariate or multivariable regression?." American journal of public health 103.1 (2013): 39-40. http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3518362/〕 # Principal components analysis (PCA) creates a new set of orthogonal variables that contain the same information as the original set. It rotates the axes of variation to give a new set of orthogonal axes, ordered so that they summarize decreasing proportions of the variation. # Factor analysis is similar to PCA but allows the user to extract a specified number of synthetic variables, fewer than the original set, leaving the remaining unexplained variation as error. The extracted variables are known as latent variables or factors; each one may be supposed to account for covariation in a group of observed variables. # Canonical correlation analysis finds linear relationships among two sets of variables; it is the generalised (i.e. canonical) version of bivariate〔Unsophisticated analysts of bivariate Gaussian problems may find useful a crude but accurate (method ) of accurately gauging probability by simply taking the sum ''S'' of the ''N'' residuals' squares, subtracting the sum ''Sm'' at minimum, dividing this difference by ''Sm'', multiplying the result by (''N'' - 2) and taking the inverse anti-ln of half that product.〕 correlation. # Redundancy analysis (RDA) is similar to canonical correlation analysis but allows the user to derive a specified number of synthetic variables from one set of (independent) variables that explain as much variance as possible in another (independent) set. It is a multivariate analogue of regression. # Correspondence analysis (CA), or reciprocal averaging, finds (like PCA) a set of synthetic variables that summarise the original set. The underlying model assumes chi-squared dissimilarities among records (cases). # Canonical (or "constrained") correspondence analysis (CCA) for summarising the joint variation in two sets of variables (like redundancy analysis); combination of correspondence analysis and multivariate regression analysis. The underlying model assumes chi-squared dissimilarities among records (cases). # Multidimensional scaling comprises various algorithms to determine a set of synthetic variables that best represent the pairwise distances between records. The original method is principal coordinates analysis (PCoA; based on PCA). # Discriminant analysis, or canonical variate analysis, attempts to establish whether a set of variables can be used to distinguish between two or more groups of cases. # Linear discriminant analysis (LDA) computes a linear predictor from two sets of normally distributed data to allow for classification of new observations. # Clustering systems assign objects into groups (called clusters) so that objects (cases) from the same cluster are more similar to each other than objects from different clusters. # Recursive partitioning creates a decision tree that attempts to correctly classify members of the population based on a dichotomous dependent variable. # Artificial neural networks extend regression and clustering methods to non-linear multivariate models. # Statistical graphics such as tours, parallel coordinate plots, scatterplot matrices can be used to explore multivariate data. # Simultaneous equations models involve more than one regression equation, with different dependent variables, estimated together. # Vector autoregression involves simultaneous regressions of various time series variables on their own and each other's lagged values. 抄文引用元・出典: フリー百科事典『 ウィキペディア(Wikipedia)』 ■ウィキペディアで「Multivariate statistics」の詳細全文を読む スポンサード リンク
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