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powerTransform: Finding Univariate or Multivariate Power Transformations

Description

powerTransform uses the maximum likelihood-like approach of Box and Cox (1964) to select a transformatiion of a univariate or multivariate response for normality, linearity and/or constant variance. Available families of transformations are the default Box-Cox power family and two additioal families that are modifications of the Box-Cox family that allow for (a few) negative responses. The summary method automatically computes two or three likelihood ratio type tests concerning the transformation powers.

Usage

powerTransform(object, ...)

# S3 method for default powerTransform(object, family="bcPower", ...)

# S3 method for lm powerTransform(object, family="bcPower", ...)

# S3 method for formula powerTransform(object, data, subset, weights, na.action, family="bcPower", ...)

# S3 method for lmerMod powerTransform(object, family="bcPower", ...)

Arguments

object

This can either be an object of class lm or lmerMod, a formula, or a matrix or vector; see below.

family

The quoted name of a family of transformations. The available options are "bcPower" for the default for the Box-Cox power family; "bcnPower" for a two-parameter modification of the Box-Cox family that allows negative responses (Hawkins and Weisberg (2017)), and the "yjPower" family (Yeo and Johnson(2000)), another modifiation of the Box-Cox family that allows a few negative values. All three families are documented at bcPower.

data

A data frame or environment, as in ‘lm’.

subset

Case indices to be used, as in ‘lm’.

weights

Weights as in ‘lm’.

na.action

Missing value action, as in ‘lm’.

...

Additional arguments that used in the interative algorithm; defaults are generally adequate.

Value

An object of class powerTransform or class bcnPowerTransform if family="bcnPower" that inherits from powerTransform is returned, including the components listed below.

A summary method presents estimated values for the transformation power ‘lambda’ and for the ‘bcnPower’ family the location paramter ‘gamma’ as well. Standard errors and Wald 95% confidence intervals based on the standard errors are computed from the inverse of the sample Hessian matrix evaluted at the estimates. The interval estimates for the ‘gamma’ parameters will generally be very wide, reflecting little information available about the location parameter. Likelihood ratio type tests are also provided. For the ‘bcnPower’ family these are based on the profile loglikelihood for ‘lambda’ alone; that is, we treat ‘gamma’ as a nusiance parameter and average over it.

The components of the returned object includes

lambda

Estimated transformation parameter

roundlam

Convenient rounded values for the estimates. These rounded values will usually be the desired transformations.

gamma

Estimated location parameters for bcnPower, NULL otherwise

invHess

Estimated covariance matrix of the estimated parameters

llik

Value of the log-likelihood at the estimates

The summary method for powerTransform returns an array with columns labeled "Est Power" for the value of lambda that maximizes the likelihood; "Rounded Pwr" for roundlam, and columns "Wald Lwr Bnd" and "Wald Ur Bnd" for a 95 percent Wald normal theory confidence interval for lambda computed as the estimate plus or minus 1.96 times the standard error.

Details

This function implements the Box and Cox (1964) method of selecting a power transformation of a variable toward normality, and its generalization by Velilla (1993) to a multivariate response. Cook and Weisberg (1999) and Weisberg (2014) suggest the usefulness of transforming a set of predictors z1, z2, z3 for multivariate normality. It also includes two additional families that allow for negative values.

If the ‘object’ argument is of class ‘lm’ or ‘lmerMod’, the Box-Cox procedure is applied to the conditional distribution of the response given the predictors. For ‘lm’ objects, the respose may be multivariate, and each column will have its own transformation. With ‘lmerMod’ the response must be univariate.

The ‘object’ argument may also be a formula. For example, z ~ x1 + x2 + x3 will estimate a transformation for the response z from a family after fitting a linear model with the given formula. cbind(y1, y2, y3) ~ 1 specifies transformations to multivariate normality with no predictors. A vector value for ‘object’, for example powerTransform(ais$LBM), is equivalent topowerTransform(LBM ~ 1, ais). Similarly, powerTransform(cbind(ais$LBM, ais$SSF)), where the first argument is a matrix rather than a formula is equivalent to specification of a mulitvariate linear model powerTransform(cbind(LBM, SSF) ~ 1, ais).

Three families of power transformations are available. The default Box-Cox power family (family="bcPower") of power transformations effectively replaces a vector by that vector raised to a power, generally in the range from -3 to 3. For powers close to zero, the log-transformtion is suggested. In practical situations, after estimating a power using the powerTransform function, a variable would be replaced by a simple power transformation of it, for example, if \(\lambda\approx 0.5\), then the correspoding variable would be replaced by its square root; if \(\lambda\) is close enough to zero, the the variable would be replaced by its natural logarithm. The Box-Cox family requires the responses to be strictly positive.

The family="bcnPower", or Box-Cox with negatives, family proposed by Hawkins and Weisberg (2017) allows for (a few) non-positive values, while allowing for the transformed data to be interpreted similarly to the interpretation of Box-Cox transformed values. This family is the Box-Cox transformation of \(z = .5 * (y + (y^2 + \gamma^2)^{1/2})\) that depends on a location parameter \(\gamma\). The quantity \(z\) is positive for all values of \(y\). If \(\gamma = 0\) and \(y\) is strictly positive, then the Box-Cox and the bcnPower transformations are identical. When fitting the Box-Cox with negatives family, lambda is restricted to the range [-3, 3], and gamma is restricted to the range from .01 to the largest positive value of the variable, since values outside these ranges are unreasonable in practice.

The final family family="yjPower" uses the Yeo-Johnson transformation, which is the Box-Cox transformation of \(U+1\) for nonnegative values, and of \(|U|+1\) with parameter \(2-\lambda\) for \(U\) negative and thus it provides a family for fitting when (a few) observations are negative. Because of the unusual constraints on the powers for positive and negative data, this transformation is not used very often, as results are difficult to interpret. In practical problems, a variable would be replaced by its Yeo-Johnson transformation computed using the yjPower function.

The function testTransform is used to obtain likelihood ratio tests for any specified value for the transformation parameter(s).

Computations maimize the likelihood-like functions described by Box and Cox (1964) and by Velilla (2000). For univariate responses, the computations are very stable and problems are unlikely, although for ‘lmer’ models computations may be very slow because the model is refit many times. For multivariate responses with the bcnPower family, the computing algorithm may fail. In this case we recommend adding the argument itmax = 1 to the call to powerTransform. This will return the starting value estimates of the transformation parameters, fitting a d-dimensional response as if all the d responses were independent.

References

Box, G. E. P. and Cox, D. R. (1964) An analysis of transformations. Journal of the Royal Statisistical Society, Series B. 26 211-46.

Cook, R. D. and Weisberg, S. (1999) Applied Regression Including Computing and Graphics. Wiley.

Fox, J. and Weisberg, S. (2011) An R Companion to Applied Regression, Second Edition, Sage.

Hawkins, D. and Weisberg, S. (2017) Combining the Box-Cox Power and Generalized Log Transformations to Accomodate Negative Responses In Linear and Mixed-Effects Linear Models, submitted for publication.

Velilla, S. (1993) A note on the multivariate Box-Cox transformation to normality. Statistics and Probability Letters, 17, 259-263.

Weisberg, S. (2014) Applied Linear Regression, Fourth Edition, Wiley.

Yeo, I. and Johnson, R. (2000) A new family of power transformations to improve normality or symmetry. Biometrika, 87, 954-959.

See Also

testTransform, bcPower, bcnPower, transform, optim, boxCox.

Examples

Run this code
# NOT RUN {
# Box Cox Method, univariate
summary(p1 <- powerTransform(cycles ~ len + amp + load, Wool))
# fit linear model with transformed response:
coef(p1, round=TRUE)
summary(m1 <- lm(bcPower(cycles, p1$roundlam) ~ len + amp + load, Wool))

# Multivariate Box Cox uses Highway1 data
summary(powerTransform(cbind(len, adt, trks, sigs1) ~ 1, Highway1))

# Multivariate transformation to normality within levels of 'htype'
summary(a3 <- powerTransform(cbind(len, adt, trks, sigs1) ~ htype, Highway1))

# test lambda = (0 0 0 -1)
testTransform(a3, c(0, 0, 0, -1))

# save the rounded transformed values, plot them with a separate
# color for each highway type
transformedY <- bcPower(with(Highway1, cbind(len, adt, trks, sigs1)),
                        coef(a3, round=TRUE))
# }
# NOT RUN {
scatterplotMatrix( ~ transformedY|htype, Highway1) 
# }
# NOT RUN {
# With negative responses, use the bcnPower family
m2 <- lm(I1L1 ~ pool, LoBD)
summary(p2 <- powerTransform(m2, family="bcnPower"))
testTransform(p2, .5)
summary(powerTransform(update(m2, cbind(LoBD$I1L2, LoBD$I1L1) ~ .), family="bcnPower"))
# multivariate bcnPower, with 8 responses
summary(powerTransform(update(m2, as.matrix(LoBD[, -1]) ~ .), family="bcnPower"))
# multivariate bcnPower, fit with one iteration using starting values as estimates
summary(powerTransform(update(m2, as.matrix(LoBD[, -1]) ~ .), family="bcnPower", itmax=1))

# mixed effects model
# }
# NOT RUN {
  data <- reshape(LoBD[1:20, ], varying=names(LoBD)[-1], direction="long", v.names="y")
  names(data) <- c("pool", "assay", "y", "id")
  data$assay <- factor(data$assay)
  require(lme4)
  m2 <- lmer(y ~ pool + (1|assay), data)
  summary(l2 <- powerTransform(m2, family="bcnPower", verbose=TRUE))
# }

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