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Data Basics Data Matrix • Many datasets can be represented as a data matrix. • Rows corresponding to entities • Columns represents attributes. • N: size of the data • D: dimensionality of the data • Univariate analysis: the analysis of a single attribute. • Bivariate analysis: simultaneous analysis of two attributes. • Multivariate analysis: simultaneous analysis of multiple attributes. Example for Data Matrix Attributes • Categorical Attributes • composed of a set of symbols • has a set-valued domain • E.g., Sex with domain(Sex) = {M, F}, Education with domain(Education) = { High School, BS, MS, PhD}. • Two types of categorical attributes – Nominal • values in the domain are unordered • Only equality comparisons are allowed • E.g. Sex – Ordinal • Values are ordered • Both equality and inequality comparisons are allowed • E.g. Education Attributes Cont. • Numeric Attributes – Has real-valued or integer-valued domain – E.g. Age with domain (Age) = N, where N denotes the set of natural numbers (non-negative integers). • Two types of numeric attributes – Discrete: values take on finite or countably infinite set. – Continuous: values take on any real value • Another Classification – Interval-scaled • for attributes only differences make sense • E.g. temperature. – Ratio-scaled • Both difference and ratios are meaningful • E.g. Age Algebraic View of Data • If the d attributes in the data matrix D are all numeric • each row can be considered as a d-dimensional point • or equivalently, each row may be considered a d-dimensional column vector • Linear combination of the standard basis vectors Example of Algebraic View of Data Geometric View of Data Distance of Angle Example of Distance and Angle Mean and Total Variance Centered Data Matrix • The centered data matrix is obtained by subtracting the mean from all the points Orthogonality • Two vectors a and b are said to be orthogonal if and only if • It implies that the angle between them is 90◦ or π/2 radians. Orthogonal Projection P: orthogonal projection of b on the vector a; R: error vector between points b and p Example of Projection Linear Independence and Dimensionality • : the set of all possible linear combinations of the vectors. • If spanning set for . then we say that v1, · · · , vk is a Row and Column Space • The column space of D, denoted col(D) is the set of all linear combinations of the d column vectors or attributes • The row space of D, denoted row(D), is the set of all linear combinations of the n row vectors or points • Note also that the row space of D is the column space of Linear Independence Dimension and Rank • Let S be a subspace of Rm. • A basis for S: a set of linearly independent vectors v1, · · · , vk , and span(v1, · · · , vk) = S. • orthogonal basis for S: If the vectors in the basis are pair-wise orthogonal • If in addition they are also normalized to be unit vectors, then they make up an orthonormal basis for S. • For instance, the standard basis for Rm is an orthonormal basis consisting of the vectors • Any two bases for S must have the same number of vectors. • Dimension: The number of vectors in a basis for S, denoted as dim(S). • For any matrix, the dimension of its row and column space are the same, and this dimension is also called as the rank of the matrix. Data: Probabilistic View • Assumes that each numeric attribute Xj is a random variable, defined as a function that assigns a real number to each outcome of an experiment. • Given as Xj : O → R, where O, the domain of Xj , called as the sample space • R, the range of Xj , is the set of real numbers. • If the outcomes are numeric, and represent the observed values of the random variable, then Xj : O → O is simply the identity function: Xj (v) = v for all v ∈ O. Data: Probabilistic View • A random variable X is called a discrete random variable if it takes on only a finite or countably infinite number of values in its range. • X is called a continuous random variable if it can take on any value in its range. Example • Be default, consider the attribute X1 to be a continuous random variable, given as the identity function X1(v) = v, since the outcomes are all numeric. • On the other hand, if we want to distinguish between iris flowers with short and long sepal lengths, we define a discrete random variable A as follows • In this case the domain of A is [4.3, 7.9]. The range of A is {0, 1}, and thus A assumes non-zero probability only at the discrete values 0 and 1. Example: Bernoulli and Binomial Distribution • only 13 irises have sepal length of at least 7cm • In this case we say that A has a Bernoulli distribution with parameter p ∈ [0, 1]. p denotes the probability of a success, whereas 1− p represents the probability of a failure Example: Bernoulli and Binomial Distribution • Let us consider another discrete random variable B, denoting the number of irises with long sepal lengths in m independent Bernoulli trials with probability of success p. • B takes on the discrete values [0,m], and its probability mass function is given by the Binomial distribution • For example, taking p = 0.087 from above, the probability of observing exactly k = 2 long sepal length irises in m = 10 trials is given as full probability mass function for different values of k Probability Density Function • If X is continuous, its range is the entire set of real numbers R. • probability density function: specifies the probability that the variable X takes on values in any interval [a, b] ⊂ R Cumulative Distribution Function • For any random variable X, whether discrete or continuous, we can define the cumulative distribution function (CDF) F : R → [0, 1], that gives the probability of observing a value at most some given value x The following examples are from Andrew Moore Probability Density Function f(x) • What is P(X=x) when x is on a real domain » f(x) >=0 and Normal Distribution • Let us assume that these values follow a Gaussian or normal density function, given as Bivariate Random Variables • considering a pair of attributes, X1 and X2, as a bivariate random variable In 2-Dimensions Multivariate Random Variable Multivariate Random Variable Numeric Attribute Analysis • Sample and Statistics • Univariate Analysis • Bivariate Analysis • Multivariate Analysis • Normal Distribution Random Sample and Statistics • Population: is used to refer to the set or universe of all entities under study. • However, looking at the entire population may not be feasible, or may be too expensive. • Instead, we draw a random sample from the population, and compute appropriate statistics from the sample, that give estimates of the corresponding population parameters of interest. Univariate Sample • Let X be a random variable, and let xi (1 ≤ i ≤ n) denote the observed values of attribute X in the given data, where n is the data size. • Given a random variable X, a random sample of size n from X is defined as a set of n independent and identically distributed (IID) random variables S1, S2, · · · , Sn. • since the variables Si are all independent, their joint probability function is given as Multivariate Sample • xi: the value of a d-dimensional vector random variable Si = (X1,X2, · · · ,Xd ). • Si are independent and identically distributed, and thus their joint distribution is given as • Assume d attributes X1,X2, · · · ,Xd are independent, (1.43) can be rewritten as Statistic • Let Si denote the random variable corresponding to data point xi , then a statistic ˆθ is a function ˆθ : (S1, S2, · · · , Sn) → R. • If we use the value of a statistic to estimate a population parameter, this value is called a point estimate of the parameter, and the statistic is called as an estimator of the parameter. Numeric Attribute Analysis • Sample and Statistics • Univariate Analysis • Bivariate Analysis • Multivariate Analysis • Normal Distribution Univariate Analysis Univariate analysis focuses on a single attribute at a time, thus the data matrix D can be thought of as a n × 1 matrix, or simply a column vector. Univariate Analysis X is assumed to be a random variable, and each point xi (1 ≤ i ≤ n) is assumed to be the value of a random variable Si , where the variables Si are all independent and identically distributed as X, i.e., they constitute a random sample drawn from X. In the vector view, we treat the sample as an ndimensional vector, and write X ∈ Rn. What can sample analysis do? • Unknown f(X) and F(X) • Parameters(μ,δ) Empirical Cumulative Distribution Function Where Inverse Cumulative Distribution Function Empirical Probability Mass Function Where Measures of Central Tendency (Mean) Population Mean: Sample Mean (Unbiased, not robust): Measures of Central Tendency Population Median: (Median) or Sample Median: Measures of Central Tendency (Mode) Sample Mode: 1. may not be very useful but not affected by the outliers too much Example Measures of Dispersion (Range) Range: Sample Range: Not robust, sensitive to extreme values Measures of Dispersion (Inter-Quartile Range) Inter-Quartile Range (IQR): Sample IQR: More robust Measures of Dispersion (Variance and Standard Deviation) Variance: Standard Deviation: Measures of Dispersion (Variance and Standard Deviation) Variance: Standard Deviation: Sample Variance & Standard Deviation: Normalization Linear Normalization: Z-Score: Normalization Example Topics • Sample and Statistics • Univariate Analysis • Bivariate Analysis • Multivariate Analysis • Normal Distribution Bivariate Analysis Bivariate analysis focuses on Two attributes at a time, thus the data matrix D can be thought of as a n × 2 matrix, or two column vectors. Empirical Joint Probability Mass Function or where Measures of Central Tendency (Mean) Population Mean: Sample Mean: Measures of Association (Covariance) Covariance: Sample Covariance: Measures of Association (Correlation) Correlation: Sample Correlation: Measures of Association (Correlation) Correlation Example Topics • Sample and Statistic • Univariate Analysis • Bivariate Analysis • Multivariate Analysis • Normal Distribution Multivariate Analysis Multivariate analysis focuses on multiple attributes at a time, thus the data matrix D can be thought of as a n × d matrix, or d column vectors. Measures of Central Tendency (Mean) Population Mean: Sample Mean: Measures of Association (Covariance Matrix) Measures of Association (Correlation) Correlation: Sample Correlation: Topics • Sample and Statistic • Univariate Analysis • Bivariate Analysis • Multivariate Analysis • Normal Distribution Univariate Normal Distribution Multivariate Normal Distribution • Thank You!