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emmeans (version 1.10.6)

make.tran: Response-transformation extensions

Description

The make.tran function creates the needed information to perform transformations of the response variable, including inverting the transformation and estimating variances of back-transformed predictions via the delta method. make.tran is similar to make.link, but it covers additional transformations. The result can be used as an environment in which the model is fitted, or as the tran argument in update.emmGrid (when the given transformation was already applied in an existing model).

Usage

make.tran(type = c("genlog", "power", "boxcox", "sympower", "asin.sqrt",
  "atanh", "bcnPower", "scale"), alpha = 1, beta = 0, param, y, inner, ...)

inverse(y)

Value

A list having at least the same elements as those returned by

make.link. The linkfun component is the transformation itself. Each of the functions is associated with an environment where any parameter values are defined.

inverse returns the reciprocal of its argument. It allows the "inverse" link to be auto-detected as a response transformation.

Arguments

type

The name of a standard transformation supported by stat::make.link, or of a special transformation described under Details.

alpha, beta

Numeric parameters needed for special transformations.

param

If non-missing, this specifies either alpha or c(alpha, beta) (provided for backward compatibility). Also, for the same reason, if alpha is of length more than 1, it is taken as param.

y

A numeric response variable used (and required) with type = "scale", where scale(y) determines alpha and beta.

inner

another transformation. See the section on compound transformations

...

Additional arguments passed to other functions/methods

Cases where <code>make.tran</code> may not be needed

For standard transformations with no parameters, we usually don't need to use make.tran; just the name of the transformation is all that is needed. The functions emmeans, ref_grid, and related ones automatically detect response transformations that are recognized by examining the model formula. These are log, log2, log10, log1p, sqrt, logit, probit, cauchit, cloglog; as well as (for a response variable y) asin(sqrt(y)), asinh(sqrt(y)), atanh(y), and sqrt(y) + sqrt(y+1). In addition, any constant multiple of these (e.g., 2*sqrt(y)) is auto-detected and appropriately scaled (see also the tran.mult argument in update.emmGrid).

A few additional transformations may be specified as character strings and are auto-detected: "identity", "1/mu^2", "inverse", "reciprocal", "log10", "log2", "asin.sqrt", "asinh.sqrt", and "atanh".

Compound transformations

A transformation that is a function of another function can be created by specifying inner for the other function. For example, the transformation \(1/\sqrt{y}\) can be created either by make.tran("inverse", inner = "sqrt") or by make.tran("power", -0.5). In principle, transformations can be compounded to any depth. Also, if type is "scale", y is replaced by inner$linkfun(y), because that will be the variable that is scaled.

Details

The make.tran function returns a suitable list of functions for several popular transformations. Besides being usable with update, the user may use this list as an enclosing environment in fitting the model itself, in which case the transformation is auto-detected when the special name linkfun (the transformation itself) is used as the response transformation in the call. See the examples below.

The primary purpose of make.tran is to support transformations that require additional parameters, specified as alpha and beta; these are the onse shown in the argument-matching list. However, standard transformations supported by stats::make.link are also supported. In the following discussion of ones requiring parameters, we use \(\alpha\) and \(\beta\) to denote alpha and beta, and \(y\) to denote the response variable. The type argument specifies the following transformations:

"genlog"

Generalized logarithmic transformation: \(\log_\beta(y + \alpha)\), where \(y > -\alpha\). When \(\beta = 0\) (the default), we use \(\log_e(y + \alpha)\)

"power"

Power transformation: \((y-\beta)^\alpha\), where \(y > \beta\). When \(\alpha = 0\), \(\log(y-\beta)\) is used instead.

"boxcox"

The Box-Cox transformation (unscaled by the geometric mean): \(((y - \beta)^\alpha - 1) / \alpha\), where \(y > \beta\). When \(\alpha = 0\), \(\log(y - \beta)\) is used.

"sympower"

A symmetrized power transformation on the whole real line: \(|y - \beta|^\alpha\cdot sign(y - \beta)\). There are no restrictions on \(y\), but we require \(\alpha > 0\) in order for the transformation to be monotone and continuous.

"asin.sqrt"

Arcsin-square-root transformation: \(\sin^{-1}(y/\alpha)^{1/2}\). Typically, alpha will be either 1 (default) or 100.

"atanh"

Arctanh transformation: \(\tanh^{-1}(y/\alpha)\). Typically, alpha will be either 1 (default) or 100.

"bcnPower"

Box-Cox with negatives allowed, as described for the bcnPower function in the car package. It is defined as the Box-Cox transformation \((z^\alpha - 1) / \alpha\) of the variable \(z = y + (y^2+\beta^2)^{1/2}\). Note that this requires both parameters and that beta > 0.

"scale"

This one is a little different than the others, in that alpha and beta are ignored; instead, they are determined by calling scale(y, ...). The user should give as y the response variable in the model to be fitted to its scaled version.

Note that with the "power", "boxcox", or "sympower" transformations, the argument beta specifies a location shift. In the "genpower" transformation, beta specifies the base of the logarithm -- however, quirkily, the default of beta = 0 is taken to be the natural logarithm. For example, make.tran(0.5, 10) sets up the \(\log_{10}(y + \frac12)\) transformation. In the "bcnPower" transformation, beta must be specified as a positive value.

For purposes of back-transformation, the sqrt(y) + sqrt(y+1) transformation is treated exactly the same way as 2*sqrt(y), because both are regarded as estimates of \(2\sqrt\mu\).

Examples

Run this code
# Fit a model using an oddball transformation:
bctran <- make.tran("boxcox", 0.368)
warp.bc <- with(bctran, 
    lm(linkfun(breaks) ~ wool * tension, data = warpbreaks))
# Obtain back-transformed LS means:    
emmeans(warp.bc, ~ tension | wool, type = "response")

### Using a scaled response...
# Case where it is auto-detected:
mod <- lm(scale(yield[, 1]) ~ Variety, data = MOats)
emmeans(mod, "Variety", type = "response")

# Case where scaling is not auto-detected -- and what to do about it:
copt <- options(contrasts = c("contr.sum", "contr.poly"))
mod.aov <- aov(scale(yield[, 1]) ~ Variety + Error(Block), data = MOats)
emm.aov <- suppressWarnings(emmeans(mod.aov, "Variety", type = "response"))

# Scaling was not retrieved, but we can do:
emm.aov <- update(emm.aov, tran = make.tran("scale", y = MOats$yield[, 1]))
emmeans(emm.aov, "Variety", type = "response")

### Compound transformations
# The following amount to the same thing:
t1 <- make.tran("inverse", inner = "sqrt")
t2 <- make.tran("power", -0.5)

options(copt)


if (FALSE) {
### An existing model 'mod' was fitted with a y^(2/3) transformation...
  ptran = make.tran("power", 2/3)
  emmeans(mod, "treatment", tran = ptran)
}

pigs.lm <- lm(inverse(conc) ~ source + factor(percent), data = pigs)
emmeans(pigs.lm, "source", type = "response")

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