| dwlm {dwlm} | R Documentation |
Solves the doubly weighted simple linear model
Description
Fits the simple linear model using weights on both the predictor and the response
Usage
dwlm(x, y, weights.x = rep(1, length(x)),
weights.y = rep(1, length(y)), subset = rep(TRUE, length(x)),
sigma2.x = rep(0, length(x[subset])),
from = min((y[subset] - mean(y[subset]))/(x[subset] - mean(x[subset]))),
to = max((y[subset] - mean(y[subset]))/(x[subset] - mean(x[subset]))),
n = 1000, max.iter = 100, tol = .Machine$double.eps^0.25,
method = c("MLE", "SSE", "R"), trace = FALSE, coef.H0 = c(0,1), alpha = 0.05)
Arguments
x |
the predictor values |
y |
the response values |
weights.x |
the weight attached to the predictor values |
weights.y |
the weight attached to the response values |
subset |
a logical vector or a numeric vector with the positions to be considered |
sigma2.x |
numeric, the variance due to heterogeneity in the predictor value |
from |
numeric, the lowest value of the slope to search for a solution |
to |
numeric, the highest value of the slope to search for a solution |
n |
integer, the number of slices the search interval (from, to) is divided in |
max.iter |
integer, the maximum number of allowed iterations |
tol |
numeric, the maximum allowed error tolerance |
method |
string, the selected method (MSE, SSE, R) as described in the references. |
trace |
logical, flag to keep track of the solution |
coef.H0 |
numeric vector, the coeffients to test against to for significant difference |
alpha |
numeric, the significance level for estimating the Degrees of Equivalence (DoE) |
Value
A list with the following elements:
x |
original pedictor values |
y |
original response values |
weights.x |
original predictor weigths |
weights.y |
original response weights |
subset |
original subset parameter |
coef.H0 |
original parameter value for hypothesis testing against to |
coefficients |
estimated parameters for the linear model solution |
cov.mle |
Maximum Likelihood Estimafor for the covariance matrix |
cov.lse |
Least Squares Estiimator for the covariance matrix |
x.hat |
fitted true predictor value, this is a latent (unobserved) variable |
y.hat |
fitted true response value, this is a latent (unobserved) variable |
df.residuals |
degrees of freedom |
MSE |
mean square error of the solution |
DoE |
pointwise degrees of equivalente between the observed and the latent variables |
u.DoE.mle |
uncerainty of the pointwise degrees of equivalence using maximum likelihood solution |
u.DoE.lse |
uncertainty of the pointwise degrees of equivalence using least squares solution |
dm.dXj |
partial gradient of the slope with respect to the jth predictor variable |
dm.dYj |
partial gradient of the slope with respect to the jth response variable |
dc.dXj |
partial gradient of the intercept with respect to the jth predictor variable |
dc.dYj |
partial gradient of the intercept with respect to the jth response variable |
curr.iter |
number of iterations |
curr.tol |
reached tolerance |
Author(s)
Hugo Gasca-Aragon
Maintainer: Hugo Gasca-Aragon <hugo_gasca_aragon@hotmail.com>
References
Reed, B.C. (1989) "Linear least-squares fits with errors in both coordinates", American Journal of Physics, 57, 642. https://doi.org/10.1119/1.15963
Reed, B.C. (1992) "Linear least-squares fits with errors in both coordinates. II: Comments on parameter variances", American Journal of Physics, 60, 59. https://doi.org/10.1119/1.17044
Ripley and Thompson (1987) "Regression techniques for the detection of analytical bias", Analysts, 4. https://doi.org/10.1039/AN9871200377
See Also
Examples
# Example ISO 28037 Section 7
X.i<- c(1.2, 1.9, 2.9, 4.0, 4.7, 5.9)
Y.i<- c(3.4, 4.4, 7.2, 8.5, 10.8, 13.5)
sd.X.i<- c(0.2, 0.2, 0.2, 0.2, 0.2, 0.2)
sd.Y.i<- c(0.2, 0.2, 0.2, 0.4, 0.4, 0.4)
# values obtained on sep-26, 2016
dwlm.res <- dwlm(X.i, Y.i, 1/sd.X.i^2, 1/sd.Y.i^2,
from = 0, to=3, coef.H0=c(0, 2), tol = 1e-10)
dwlm.res$coefficients
dwlm.res$cov.mle[1, 2]
dwlm.res$curr.tol
dwlm.res$curr.iter