weighted coefficient of variation

Description

Assume that x=(x_1, x_2, \cdots , x_n) is the observed value of a random sample from a fuzzy population. In classical and usual random sample, the degree of belonging x_i into the random sample is equal to 1, for 1 \leq i \leq n. But considering fuzzy population, we denote the degree of belonging x_i into the fuzzy population (or into the observed value of random sample) by \mu_i which is a real-valued number from [0,1]. Therefore in such situations, it is more appropriate that we show the observed value of the random sample by notation \{ (x_1, \mu_1), (x_2, \mu_2), \cdots , (x_n, \mu_n) \} which we called it real-valued fuzzy data. The goal of w.cv function is computing the coefficient of variation (or, the weighted coefficient of variation) value of x_1, \cdots , x_n based on real-valued fuzzy data \{ (x_1, \mu_1), \cdots , (x_n, \mu_n) \} by considering its vector-valued weight. In other words, the weighted coefficient of variation is equal to the weighted standard deviation devided by the weighted mean.

Usage

w.cv(x, mu)

Arguments

Value

The weighted coefficient of variation for vector x, by considering weights vector mu, is numeric or a vector of length one.

Warning

The length of x and mu must be equal. Also, each element of mu must be in interval [0,1].

Author(s)

Abbas Parchami

Examples

x <- c(1:10)
mu <- c(0.9, 0.7, 0.8, 0.7, 0.6, 0.4, 0.2, 0.3, 0.0, 0.1)
w.cv(x, mu)

## The function is currently defined as
function(x, mu)  w.sd(x,mu) / w.mean(x,mu)