daisy: Dissimilarity Matrix Calculation

an object of class "dissimilarity" containing the dissimilarities among the rows of x. This is typically the input for the functions pam, fanny, agnes or

diana. For more details, see dissimilarity.object.

The original version of daisy is fully described in chapter 1 of Kaufman and Rousseeuw (1990). Compared to dist whose input must be numeric variables, the main feature of daisy is its ability to handle other variable types as well (e.g. nominal, ordinal, (a)symmetric binary) even when different types occur in the same data set.

The handling of nominal, ordinal, and (a)symmetric binary data is achieved by using the general dissimilarity coefficient of Gower (1971). If x contains any columns of these data-types, both arguments metric and stand will be ignored and Gower's coefficient will be used as the metric. This can also be activated for purely numeric data by metric = "gower". With that, each variable (column) is first standardized by dividing each entry by the range of the corresponding variable, after subtracting the minimum value; consequently the rescaled variable has range $[0,1]$, exactly.

Note that setting the type to symm (symmetric binary) gives the same dissimilarities as using nominal (which is chosen for non-ordered factors) only when no missing values are present, and more efficiently.

Note that daisy signals a warning when 2-valued numerical variables do not have an explicit type specified, because the reference authors recommend to consider using "asymm"; the warning may be silenced by warnBin = FALSE.

In the daisy algorithm, missing values in a row of x are not included in the dissimilarities involving that row. There are two main cases,

1. If all variables are interval scaled (and metric is not "gower"), the metric is "euclidean", and $n_g$ is the number of columns in which neither row i and j have NAs, then the dissimilarity d(i,j) returned is $\sqrt{p/n_g}$ ($p=$ncol(x)) times the Euclidean distance between the two vectors of length $n_g$ shortened to exclude NAs. The rule is similar for the "manhattan" metric, except that the coefficient is $p/n_g$. If $n_g=0$, the dissimilarity is NA.

2. When some variables have a type other than interval scaled, or if metric = "gower" is specified, the dissimilarity between two rows is the weighted mean of the contributions of each variable. Specifically, $$d_{ij}=d(i,j)=\frac{\sum _{k=1}^p{w}_k{\delta }_{ij}^{(k)}{d}_{ij}^{(k)}}{\sum _{k=1}^p{w}_k{\delta }_{ij}^{(k)}}.$$ In other words, $d_{ij}$ is a weighted mean of $d_{ij}^{(k)}$ with weights $w_k{\delta }_{ij}^{(k)}$, where $w_k$= weigths[k], ${\delta }_{ij}^{(k)}$ is 0 or 1, and $d_{ij}^{(k)}$, the k-th variable contribution to the total distance, is a distance between x[i,k] and x[j,k], see below.

   The 0-1 weight ${\delta }_{ij}^{(k)}$ becomes zero when the variable x[,k] is missing in either or both rows (i and j), or when the variable is asymmetric binary and both values are zero. In all other situations it is 1.

   The contribution $d_{ij}^{(k)}$ of a nominal or binary variable to the total dissimilarity is 0 if both values are equal, 1 otherwise. The contribution of other variables is the absolute difference of both values, divided by the total range of that variable. Note that “standard scoring” is applied to ordinal variables, i.e., they are replaced by their integer codes 1:K. Note that this is not the same as using their ranks (since there typically are ties).

   As the individual contributions $d_{ij}^{(k)}$ are in $[0,1]$, the dissimilarity $d_{ij}$ will remain in this range. If all weights $w_k{\delta }_{ij}^{(k)}$ are zero, the dissimilarity is set to NA.