w.cv: weighted coefficient of variation

Description Usage Arguments Value Warning Author(s) Examples

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 ≤q i ≤q 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 μ_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, μ_1), (x_2, μ_2), \cdots , (x_n, μ_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, μ_1), \cdots , (x_n, μ_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

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w.cv(x, mu)

Arguments

x

A vector-valued numeric data which you want to compute its weighted coefficient of variation.

mu

A vector of weights. The length of this vector must be equal to the length of data and each element of it is belongs to interval [0,1].

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

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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)

Example output

[1] 0.59807
function (x, mu) 
w.sd(x, mu)/w.mean(x, mu)

Weighted.Desc.Stat documentation built on May 1, 2019, 7:06 p.m.