1 Introduction to Multivariable Fractional Polynomials (MFP)

1.1 Overview of MFP

Multivariable regression models are widely used across various fields of science where empirical data is analyzed. In model building, many researchers often assume a linear function for continuous variables, sometimes after applying “standard” transformations such as logarithms, or dividing the variable into several categories. Assuming linearity without considering non-linear relationships may hinder the detection of effects or cause the effects to be mismodeled. Categorizing continuous variables, which results in modelling implausible step functions, is a common practice but widely criticized (Royston et al. 2006; Sauerbrei et al. 2020).

When building a descriptive model with the aim of capturing the data structure parsimoniously, two components should be considered: first, variable selection to identify the subset of “important” covariates that have a significant impact on the outcome and second, whether non-linear relationships of continuous covariates fit the data (substantially) better.

The MFP approach has been proposed as a pragmatic method that combines variable and function selection simultaneously in multivariable regression modelling. This approach identifies non-linear functions for continuous variables if sufficiently supported by the data, and eliminates covariates with no or weak effects by backward elimination (BE). Despite its relative simplicity, the selected models often capture the essential information from the data. The MFP models are relatively straightforward to interpret and report, which is important for transportability and practical usability.

In detail, the MFP procedure combines: - variable selection through backward elimination with - selection of fractional polynomial (FP) functions for continuous variables.

The analyst must decide on nominal significance levels \((\alpha_1, \alpha_2)\) for both components. This choice has a strong influence on the complexity of the final model. Often, the same significance levels \((\alpha_1 = \alpha_2)\) are used for both components, but they can also differ. The decision regarding these significance levels strongly depends on the specific aim of the analysis.

The rest of the paper is organized as follows. Section 1.2 provides an overview of fractional polynomial functions for a single continuous covariate in the model, including the function selection procedure (FSP). Section 1.3 describes the MFP approach, focusing on models involving two or more covariates.

Section 2 is an introduction to the mfp2 package. It covers the installation process and provides instructions for utilizing the package in various linear regression models. The package functionality is predominantly demonstrated using Gaussian linear models (Subsection 2.3), while other models, such as logistic (Subsection 2.4),and Cox (Subsection 2.5), are briefly explained.

Section 3 introduces an extension of MFP using the approximate cumulative distribution (ACD) transformation of a continuous covariate. This extension allows for modelling a sigmoid relationship between covariates and an outcome variable (subsection 3.1).

For more comprehensive information about MFP and its extensions, please refer to Royston and Sauerbrei 2008 or visit MFP website (click here) and explore the references given there.

1.2 Fractional polynomial models for a continuous variable

Suppose that we have an outcome variable, a single continuous covariate \(x\), and a regression model relating them. A starting point is the straight-line model \(\beta_1x\) (for simplicity, we suppress the constant term, \(\beta_0\)). Often, a straight line is an adequate description of the relationship, but other models should be investigated for possible improvements in fit. A simple extension of the straight line is a power transformation model, \(\beta_1x^{p}\). The latter model has often been used by practitioners in an ad hoc way, utilizing different choices of \(p\). Royston and Altman (1994) formalized the model by calling it a first-degree fractional polynomial or FP1 function. The power \(p\) is chosen from a pragmatically restricted set of eight elements: \(S = \{-2, -1, -0.5, 0, 0.5, 1, 2, 3\}\), where \(x^0\) denotes the natural logarithm \(\log(x)\).

As with polynomial regression, extension from one-term FP1 functions to more complex and flexible two-term FP2 functions is straightforward. The quadratic function \(\beta_1x^1 + \beta_2x^2\) is written as \(\beta_1x^{p1} + \beta_2x^{p2}\) in FP terminology. The powers \(p1=1\) and \(p2=2\) are members of set \(S\). Royston and Altman extended the class of FP2 functions with different powers to cases with equal powers (\(p1=p2=p\)) by defining them as \(\beta_1x^p + \beta_2x^p \log(x)\). These are known as repeated-powers functions. Detailed definitions of FP functions are given in Section 4.3.1 of Royston and Sauerbrei (2008). For formal definitions, we use their notation.

FP1 functions are always monotonic and those with power \(p < 0\) have an asymptote as \(x\rightarrow \infty\). FP2 functions may be monotonic or unimodal (i.e., have one maximum or one minimum for positive values of \(x\)), and they have an asymptote as \(x\rightarrow \infty\) when both \(p1\) and \(p2\) are negative. For more details, see Royston and Sauerbrei (2008), Section 4.4.

Extension to FPm is straightforward but \(m>2\) is hardly needed when modelling health research data with MFP. For \(m = 2\), there are 44 models available within the set of FP powers (\(S\)), consisting of 8 FP1 models and 36 FP2 models. Although the allowed class of FP functions may seem limited, it encompasses a wide range of diverse shapes. This is illustrated in the Figure below, with the left panel displaying eight FP1 powers and the right panel depicting a subset of FP2 powers.

Illustration of the flexibility of the FP family. 8 FP1 functions (left panel) and a subset of FP2 functions (right panel). FPs are global functions. See section 1.3.1.4 for a proposed extension of local features

Illustration of the flexibility of the FP family. 8 FP1 functions (left panel) and a subset of FP2 functions (right panel). FPs are global functions. See section 1.3.1.4 for a proposed extension of local features

Based on extensive experience with real data and several simulation studies, FP1 and FP2 are generally considered adequate in the context of multivariable model building, particularly when the selection of variable and functional forms are required (Royston and Sauerbrei 2008; Sauerbrei et al. 2007a).

1.2.1 Function selection procedure (FSP)

This short description of the MFP methodology content is based on previously published encyclopedia articles (Sauerbrei and Royston, 2011; Sauerbrei and Royston, 2016).

Choosing the best fitting FP1, FP2, or linear function for a given dataset is conducted by grid search, computing the deviance (minus twice the maximized log-likelihood) and making a decision for the best function based on a suitable algorithm (e.g. via pre-defined significance levels).

The default function in most implementations of MFP is a linear function. Therefore, unless the data support a more complex FP function, a straight line model is chosen. Concerning the default, there are occasional exceptions. For example, to model time-varying regression coefficients in the Cox model, Sauerbrei et al. (2007b) chose a default time (\(t\)) transformation of \(\log (t)\) rather than \(t\).

It can be assumed that deviance difference between an FPm and an FP(m-1) model is distributed approximately as central \(\chi^2\) on 2 degrees of freedom (d.f.) (Royston and Sauerbrei 2008, Chapter 4.9; Ambler and Royston (2001)). To select a specific function, a closed test procedure was proposed (Royston and Sauerbrei 2008, Section 4.10). The complexity of the finally chosen function requires pre-definition of the nominal significance level \((\alpha)\) and the degree (\(m\)) of the most complex FP model allowed. Typical choices are \(\alpha = 0.05\) and FP2 (\(m = 2\)). We illustrate the strategy for \(m = 2\), which runs as follows:

  1. Use the deviance difference to test the best FP2 model for \(x\) at the \((\alpha)\) significance level against the null model using 4 d.f. If the test is not significant, stop and conclude that the effect of \(x\) is “not significant” at the \(\alpha\) level. Otherwise continue.
  2. Test the best FP2 for \(x\) against a straight line at the \(\alpha\) level using 3 d.f. If the test is not significant, stop, the final model being a straight line. Otherwise continue.
  3. Test the best FP2 for \(x\) against the best FP1 at the \(\alpha\) level using 2 d.f. If the test is not significant, the final model is FP1, otherwise, the final model is FP2. This marks the end of procedure.

Step 1 is a test of the overall association of the outcome with \(x\). Step 2 examines the evidence for nonlinearity. Step 3 chooses between a simpler or a more complex non-linear model.

1.3 MFP procedure

When developing a multivariable model with a relatively large number of candidate covariates (say between 10 and 30, we are not envisaging the case of high-dimensional data), an important distinction is between descriptive, predictive and explanatory modelling (Shmueli, 2010). MFP was mainly developed for descriptive modelling, aiming to capture the data structure parsimoniously. Nevertheless, a suitable descriptive model often has a fit similar to a model whose aim is good prediction (Sauerbrei et al. 2007a). In some fields, the term explanatory modelling is used exclusively for testing causal theory.

In many areas of science, the main interest often lies in the identification of influential variables and determination of appropriate functional forms for continuous variables. Often, linearity is presumed without checking this important assumption. The MFP procedure was proposed as a pragmatic strategy to investigate whether nonlinear functions can improve the model fit (Royston and Sauerbrei, 2008; Sauerbrei and Royston, 1999). MFP combines backward elimination for the selection of variables with a systematic search for possible nonlinearity by the function selection procedure (FSP). The extension is feasible with any type of regression model to which BE is applicable. The philosophy behind MFP modeling is to create interpretable and relatively simple models (Sauerbrei et al. 2007a). Consequently, an analyst using MFP should be less concerned about failing to include variables with a weak effect or failing to identify minor curvature in a functional form of a continuous covariate. Modifications that may improve MFP models are combination with post-estimation shrinkage (Dunkler et al., 2016, R-package shrink) and a more systematic check for overlooked local features (Binder and Sauerbrei, 2010, currently not implemented in the mfp2 package). Successful use of MFP requires only general knowledge about building regression models.

Two nominal significance level values are the main tuning parameters: \(\alpha_1\) for selecting variables with BE (in the first step of the FSP) and \(\alpha_2\) for comparing the fit of functions within the FSP. Often, \(\alpha_1=\alpha_2\) is a good choice. If available, subject-matter knowledge should replace or at least guide data-dependent model choice. Only minor modifications are required to incorporate various types of subject-matter knowledge into MFP modeling. For a detailed example, see Sauerbrei and Royston (1999). Recommendations for MFP modeling in practice are given in Sauerbrei et al. (2007a) and in Royston and Sauerbrei (2008, Section 12.2). In the mfp2 package you may replace \(\alpha_1\) and \(\alpha_2\) by AIC-P or BIC-P.

1.3.1 MFP – Key issues and approaches to handling them

Mainly focusing on the FP component, we briefly mention key issues of MFP modeling and refer to the literature for further reading. A brief overview is also given on the MFP website (https://mfp.imbi.uni-freiburg.de/fp). Regarding variable selection, we have summarized relevant issues and provided arguments for backward elimination as our preferred strategy (Royston and Sauerbrei 2008, Chapter 2). Even when a search for model improvement using a nonlinear function is not considered, that is, all functions are assumed linear, it is infeasible to derive a suitable and stable model for description in small datasets. Below we provide some information about sample size needed, but implicitly we assume that the sample size is “sufficient”.

1.3.1.1 The variable has to be positive

The class of FP1 and FP2 functions includes a log and other transformations which require that the continuous variable must be positive. A preliminary origin-shift transformation can be applied as shown in section 2.3.2.

Sometimes, there are variables that exhibit a spike at zero. This means that a certain proportion of individuals have zero values, while among those with positive values, the variable has a continuous distribution. In epidemiology, typical examples are cigarette consumption or alcohol intake. There are different approaches to modeling such variables. Royston and Sauerbrei (2008, chapter 4.15) and Royston et al. (2010) proposed a method that involves adding a small constant (to have positive values) and a binary indicator (for zero or positive values) to the regression model. Additionally, they utilized fractional polynomials to determine the functional form of the variable. In a two-stage procedure, they assessed whether the binary variable and/or the continuous function is required for a good fit to the data. Becher et al. (2012) proposed a slight modification of this approach. These two approaches are currently not implemented in the mfp2 package.

1.3.1.2 Sample size and influential observations

All statistical models are potentially adversely affected by influential observations or “outliers”. However, compared with models that comprise only linear functions, the situation may be more critical for FP functions because logarithmic or negative power transformations may produce extreme functional estimates at small values of \(x\). Conversely, the same may happen with large positive powers at large values of \(x\). Such transformations may create influential observations that may affect parts of the FSP. To mitigate the impact of influential observations, it is important to assess the robustness of FP functions. Some suggestions for investigating influential points (IPs) and handling such issues in MFP modeling can be found in Royston and Sauerbrei (2008, Chapters 5 and 10) and their paper on improving the robustness of FP models (Royston and Sauerbrei, 2007). Using synthetic data, a more detailed investigation of IPs is given in Sauerbrei et al. (2023). The authors conclude that for smaller sample sizes, IPs and low power are important reasons that the MFP approach may not be able to identify underlying functional relationships for continuous variables and selected models might differ substantially from the true model. However, for larger sample sizes (about 50 or more observations per variable) a carefully conducted MFP analysis (which includes checks for IPs and other aspects of model criticism) is often a suitable way to select a multivariable regression model which includes continuous variables.

1.3.1.3 Lack of fit

Based on experience we argue that FP1 or FP2 functions are sufficient to derive a good fitting model. Occasionally, higher order FP functions (with \(m = 3\) or \(m = 4\)) are useful in data analysis. Negative exponential or other types of pre-transformations may help to improve the fit of a complex function or may allow to incorporate subject specific knowledge. An example is discussed in section 3.1.3 in Sauerbrei and Royston (1999).

1.3.1.4 Local features

Unlike splines which have a local interpretation of the fitted function, FPs provide a curve with a global interpretation. To investigate possible “overlooked” local features of an FP function, Binder and Sauerbrei (2010) conducted a systematic analysis of residuals from a model obtained by MFP. If local features are detected by their MFP + L procedure, statistically significant local polynomials are then parsimoniously added to the FP function. This enables the identification and incorporation of local features that may have been missed by the global FP function. This approach is not currently implemented in the mfp2 package, but it is a potential area for future extensions.

2 Introduction to the mfp2 package

mfp2 is a package that implements the MFP approach to model selection. In addition, it has the ability to model a sigmoid relationship between x and an outcome variable y using the ACD transformation proposed by Royston (2014) and implemented in the Stata procedure MFPA (Royston and Sauerbrei 2016). The package offers three options for variable and function selection: nominal significance levels (p-value), adapted Akaike information criterion (AIC-P), and adapted Bayesian information criterion (BIC-P). It also provides functions for prediction and plotting. Currently, the package implements linear, logistic, Poisson, and Cox regression models. However, the package is designed in such a way that it can easily incorporate other regression models.

The main function, mfp2(), implements both MFP and MFPA. The latter adds sigmoid functions to the FP family and is only required if sigmoid functions are relevant. It offers two interfaces for input data. The first interface (matrix, default) allows direct input of the covariate matrix x and the outcome y. The second interface (formula) uses a formula object in conjunction with a data frame, similar to the glm() function with slight modifications. Both interfaces are equivalent in terms of functionality.

The package also includes several example datasets. We will illustrate working with mfp2 using the prostate dataset. Details about the dataset are found in the book by Royston and Sauerbrei (2008) and on the MFP website.

The current authors of mfp2 are Edwin Kipruto, Michael Kammer, Patrick Royston, and Willi Sauerbrei. We acknowledge the comments and suggestions provided by Georg Heinze and Gregory Steiner, which helped us improve our package. The R package is maintained by Edwin Kipruto, while the Stata MFP and MFPA programs are maintained by Patrick Royston. Parts of the text and some recommendations (e.g. section 2.3.3) have been taken from the Stata programs MFP and MFPA.

2.1 Estimation algorithm

The estimation algorithm employed in mfp2 sequentially processes the covariates using a back-fitting approach. It calculates the p-values of each covariate using the likelihood ratio test, assuming linearity, and then arranges the covariates based on these p-values. By default, the covariates are arranged in order of decreasing statistical significance. This ordering aims to prioritize modeling relatively important variables before less important ones, which can help mitigate potential challenges in model fitting arising from collinearity or, more generally, the presence of “concurvity” among the covariates (StataCorp. 2023). Although alternative options for covariate ordering are available in the mfp2 package, such as increasing statistical significance (xorder = "descending") and respecting the user’s original variable order (xorder = "original"), we strongly recommend the default option (xorder = "ascending"). Occasionally, there may be subject matter knowledge that provides arguments to change this order.

If a covariate contains non-positive values, the program by default shifts the location of the covariate to ensure positivity. In addition, it scales the shifted covariate before the first cycle of the algorithm. For more information on shifting and scaling, please see section 2.3.2.

During the initial cycle, the best-fitting FP function for the first variable (ordered by the p-values from the full model including all variables) is determined, with adjustment for all the other variables, assuming that continuous variables have a linear effect. The selected power terms are kept, and the process is repeated for the other variables. The first iteration concludes when all the variables have been processed in this way. Some variables may be eliminated, and for the remaining selected continuous variables linear, FP1 or FP2 functions are chosen. This is the starting point for the next cycle. It works similar to the initial cycle, with the selected power terms from the initial cycle being used for all variables except the one currently being processed.

Updating of FP functions and candidate variables continues through several cycles until the functions and variables included in the overall model do not change from one cycle to the next (convergence). Typically, MFP requires two to four cycles for convergence. Non-convergence may occur when there is oscillation between two or more models, but this situation is extremely rare. If this situation arises, try changing the nominal significance levels.

2.2 Installation

To install and load the mfp2 package, enter the following command in the R console:

# install the package
install.packages("mfp2")

# load the package
library(mfp2)

2.3 Linear regression

The default family in mfp2 package is family = "gaussian", which fits a Gaussian linear model. We will use the prostate cancer data (Stamey et al., 1989) included in our package to demonstrate how to fit this model. The dataset contains seven covariates (six continuous (age, pgg45, cavol, weight, bph, and cp) and one binary (svi)) and a continuous outcome variable log prostate-specific antigen (lpsa) of 97 male patients with prostate cancer. Our aim is to determine variables with influence on the outcome and whether non-linear functional relationships exist between the covariates and the outcome variable.

Load the prostate dataset from the mfp2 package and display the first six rows

# Load prostate data
data("prostate")
head(prostate, 6)
#> # A tibble: 6 × 9
#>   obsno   age   svi pgg45 cavol weight   bph    cp   lpsa
#>   <dbl> <dbl> <dbl> <dbl> <dbl>  <dbl> <dbl> <dbl>  <dbl>
#> 1     1    50     0     0 0.560   16.0  0.25  0.25 -0.431
#> 2     2    58     0     0 0.370   27.7  0.25  0.25 -0.163
#> 3     3    74     0    20 0.600   14.7  0.25  0.25 -0.163
#> 4     4    58     0     0 0.300   26.6  0.25  0.25 -0.163
#> 5     5    62     0     0 2.12    31.0  0.25  0.25  0.372
#> 6     6    50     0     0 0.350   25.2  0.25  0.25  0.765

# create covariate matrix x and numeric vector y
x <- as.matrix(prostate[, 2:8])
y <- as.numeric(prostate$lpsa)

The command data("prostate") loads a data frame from the mfp2 package. We create a matrix x and a numeric vector y from the data frame to be used by the matrix interface of the mfp2() function.

2.3.1 Fitting MFP models using the matrix and formula interfaces

The default interface of mfp2() requires a matrix of covariates x and a numeric vector of response y for continuous outcomes. If you have one covariate, make sure you convert it into a matrix with a single column.

We demonstrate how to fit the Gaussian linear model using the default parameters. The formula interface uses the fp() function to state that continuous variables should be modelled using fractional polynomials (with default parameters). The two approaches lead to the same results as demonstrated by calling summary() with the fitted models as input.

# default interface
fit_default <- mfp2(x, y, verbose = FALSE)
summary(fit_default)
#> 
#> Call:
#> glm(formula = y ~ ., family = family, data = data, weights = weights, 
#>     offset = offset, x = TRUE, y = TRUE)
#> 
#> Coefficients:
#>             Estimate Std. Error t value Pr(>|t|)    
#> (Intercept)  2.33129    0.08509  27.399  < 2e-16 ***
#> cavol.1      0.54021    0.07449   7.252  1.2e-10 ***
#> svi.1        0.67944    0.20807   3.265 0.001531 ** 
#> weight.1     1.41590    0.38967   3.634 0.000458 ***
#> ---
#> Signif. codes:  0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
#> 
#> (Dispersion parameter for gaussian family taken to be 0.5054218)
#> 
#>     Null deviance: 127.918  on 96  degrees of freedom
#> Residual deviance:  47.004  on 93  degrees of freedom
#> AIC: 215
#> 
#> Number of Fisher Scoring iterations: 2

# formula interface
fit_formula <- mfp2(lpsa ~ fp(age) + svi + fp(pgg45) + fp(cavol) + fp(weight) +
    fp(bph) + fp(cp), data = prostate, verbose = FALSE)
summary(fit_formula)
#> 
#> Call:
#> glm(formula = y ~ ., family = family, data = data, weights = weights, 
#>     offset = offset, x = TRUE, y = TRUE)
#> 
#> Coefficients:
#>             Estimate Std. Error t value Pr(>|t|)    
#> (Intercept)  2.33129    0.08509  27.399  < 2e-16 ***
#> cavol.1      0.54021    0.07449   7.252  1.2e-10 ***
#> svi.1        0.67944    0.20807   3.265 0.001531 ** 
#> weight.1     1.41590    0.38967   3.634 0.000458 ***
#> ---
#> Signif. codes:  0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
#> 
#> (Dispersion parameter for gaussian family taken to be 0.5054218)
#> 
#>     Null deviance: 127.918  on 96  degrees of freedom
#> Residual deviance:  47.004  on 93  degrees of freedom
#> AIC: 215
#> 
#> Number of Fisher Scoring iterations: 2

The main distinction between the formulas used in mfp2() and glm() functions in R is the inclusion of the fp() function within the formula. The presence of the fp() function in the formula indicates that the variables included within it should undergo FP transformation, provided that the degree of freedom (df) is not equal to 1. A df of 1 indicates a linear relationship, which does not require transformation. Note that df is an argument of the fp() function.

The variable svi is a binary variable and is therefore not passed to the fp() function. This is because binary or factor variables should not undergo FP transformation. If a binary variable is passed to the fp() function, the program will automatically set the df to 1, treating the variable as linear. However, passing a factor variable to the fp() function will result in an error. For more details on how mfp2 handles categorical variables, refer to section 2.3.10.

2.3.2 Shifting and scaling of covariates

Fractional polynomials are defined only for positive variables due to the use of logarithms and other power transformations such as the square root. Thus, mfp2() estimates shifting factors for each variables to ensure positivity. The function find_shift_factor(), used internally by mfp2, automatically estimates shifting factors for each continuous variables. The formula used to estimate the shifting factor for a continuous variable, say \(x1\), is given by:

\[ shift_{x1} = \gamma - \min(x1) \]

where \(\min(x1)\) is the smallest observed value of \(x1\), while \(\gamma\) is the minimum increment between successive ordered sample values of \(x1\), excluding 0 (Royston and Sauerbrei, 2008). The new variable \(x1' = x1 + shift_{x1}\) will then be used by mfp2() in estimating the FP powers.

For example, to estimate shifting factors for covariate matrix x from prostate data in R, you can run the following code:

# minimum values for each covariate
apply(x, 2, min)
#>    age    svi  pgg45  cavol weight    bph     cp 
#>  41.00   0.00   0.00   0.26  10.75   0.25   0.25

# shifting values for each covariate
apply(x, 2, find_shift_factor)
#>    age    svi  pgg45  cavol weight    bph     cp 
#>      0      0      1      0      0      0      0

We see that among the continuous variables, only the variable pgg45 is shifted by a factor of 1, which is attributed to its minimum value being 0. Even though the variable svi also has a minimum value of 0, it is not shifted because it is a binary variable. The user can manually set the shifting factors for each variable in the mfp2() function if desired to e.g. improve interpretability.

If the values of the variables are too large or too small, it is important to scale the variables to reduce the chances of numerical underflow or overflow which can lead to inaccuracies and difficulties in estimating the model (Royston and Sauerbrei, 2008). Scaling can be done automatically or by directly specifying the scaling values for each variables so that the magnitude of the covariate values are not too extreme. By default scaling factors are estimated by the program as follows.

After adjusting the location of \(x\) (if necessary) so that its minimum value is positive, creating \(x'\), automatic scaling will divide each value of \(x'\) by \(10^p\) where the exponent \(p\) is given by

\[ p = sign(k) \times floor(|k|), \quad \text{where} \quad k = \log_{10} (\max(x')- \min(x')). \]

The mfp2() function uses this formula to scale the columns of the covariate matrix, implemented through the find_scale_factor() function. From the output below, we see that the variables age, cavol, and cp have scaling factors of 10 each, while the variables pgg45 and weight have scaling factors of 100 each. Each variable will be divided by its corresponding scaling factor. A scaling factor of 1 (e.g. bph and svi) implies no scaling.

# shift x if nonpositive values exist
shift <- apply(x, 2, find_shift_factor)
xnew <- sweep(x, 2, shift, "+")

# scaling factors
apply(xnew, 2, find_scale_factor)
#>    age    svi  pgg45  cavol weight    bph     cp 
#>     10      1    100     10    100      1     10

To manually enter shifting and scaling factors, the mfp2() function provides the shift and scale arguments. In the default usage of mfp2(), a vector of shifting or scaling factors, with a length equal to the number of covariates, can be provided. In the formula interface, shifting or scaling factors can be directly specified within the fp() function. Below is an example to illustrate this (not run):

# Default interface
mfp2(x, y, shift = c(0, 0, 1, 0, 0, 0, 0), scale = c(10, 1, 100, 10, 100, 1,
    10))

# Formula interface
mfp2(lpsa ~ fp(age, shift = 0, scale = 10) + svi + fp(pgg45, shift = 1, scale = 100) +
    fp(cavol, shift = 0, scale = 10) + fp(weight, shift = 0, scale = 100) +
    fp(bph, shift = 0, scale = 1) + fp(cp, shift = 0, scale = 10), data = prostate)

In the default interface, each variable in the x matrix is assigned a shifting and scaling factor based on their respective positions. For instance, the first variable in the column of x, which is age, is assigned a shifting factor of 0 and a scaling factor of 10. The second variable, svi, is assigned a shifting factor of 0 and a scaling factor of 1, and so on.

2.3.3 Setting degrees of freedom for each variable

The degrees of freedom (df) for each covariate (excluding the intercept) are twice the degrees of freedom of the FP. For instance, if the maximum allowed complexity of variable \(x1\) is a second-degree FP (FP2), then the degrees of freedom assigned to this variable should be 4. To find the best fitting function, FSP selects power terms \(p1\) and \(p2\) and the corresponding regression coefficients \(\beta_1\) and \(\beta_2\). The default df is 4 (\(m = 2\)) for each covariate.

After assigning the default degrees of freedom to each variable, the program overrides the default value if a variable has only a very small number of unique values as such variables may not be handled as other continuous variable. As proposed in the Stata program the rules for overriding the default degrees of freedom are as follows:

  • If a variable has 2-3 distinct values, it is assigned df = 1 (linear).
  • If a variable has 4-5 distinct values, it is assigned df = min(2, default).
  • If a variable has 6 or more distinct values, it is assigned df = default.

These rules ensure that the appropriate df are assigned to variables. For instance, it is not sensible to fit an FP2 function to a variable with only 3 distinct values (StataCorp. 2023).

The following code illustrates how to set different df for each variable. In the default interface, the df of the binary variable svi is explicitly set to 1 (linear), while in the formula interface, there is no need to specify the df, as the program automatically assigns df = 1 for binary variables.

If the user attempts to enter df = 4 for svi in the default interface, the program will reset the df to 1 and issue a warning.

# Default Interface
mfp2(x, y, df = c(4, 1, 4, 4, 4, 4, 4))

# Formula Interface
mfp2(lpsa ~ fp(age, df = 4) + svi + fp(pgg45, df = 4) + fp(cavol, df = 4) +
    fp(weight, df = 4) + fp(bph, df = 4) + fp(cp, df = 4), data = prostate)

In addition, if the user does not explicitly assign df to variables, the program will automatically assign df = 4 to each variable, corresponding to \(m = 2\) as the default for MFP modelling. It is important to note that even if a continuous variable is not passed to the fp() function in the formula interface, the df of that variable will still be set to the default value and will later be adjusted based on the unique values. The following examples are all equivalent:

# Default Interface
mfp2(x, y)

# Formula Interface, all continuous variables passed to the fp() function
mfp2(lpsa ~ fp(age) + svi + fp(pgg45) + fp(cavol) + fp(weight) + fp(bph) + fp(cp),
    data = prostate)

# Formula Interface, `cp` not passed to the fp() function
mfp2(lpsa ~ fp(age) + svi + fp(pgg45) + fp(cavol) + fp(weight) + fp(bph) + cp,
    data = prostate)

# Formula Interface, all covariates not passed to the fp() function
mfp2(lpsa ~ age + svi + pgg45 + cavol + weight + bph + cp, data = prostate)

2.3.4 Tuning parameters for MFP

The two key components of MFP are variable selection with backward elimination (BE) and function selection for continuous variables through the function selection procedure (FSP). The mfp2() function has an argument called criterion, which allows the user to specify the criterion applied for variable and function selection.

The default criterion is pvalue, which enables the user to set two nominal significance levels: \(\alpha_1\) for variable selection with BE and \(\alpha_2\) for comparing the fit of the functions (linear, best FP1, best FP2 and so on) within the FSP. The choice of these significance levels strongly influences the complexity and stability of the final model. Please refer to section section 2.3.4.1 for instructions on setting the nominal significance levels.

The mfp2 package offers alternative approaches to variable and function selection by utilizing information criteria. Within the MFP framework, each covariate is evaluated univariately while adjusting for the other covariates through an overarching back-fitting algorithm. This algorithm iteratively assesses each covariate and selects the model (null, linear, FP1, FP2) with the minimum AIC-P (criterion set to aic) or BIC-P (criterion set to bic) (see section 2.3.4.2). Here, AIC-P and BIC-P refer to the adapted versions of AIC and BIC, respectively, to distinguish them from the original AIC and BIC. However, in the program, we use the abbreviations AIC and BIC to denote AIC-P and BIC-P.

The “null” model refers to a model without the covariate of interest. A “linear” model assumes a linear relationship with the outcome variable, while an FP1 model assumes a non-linear relationship using the FP1 function. The criterion argument allows users to specify whether they want to use AIC-P or BIC-P criteria for both variable and function selection. If AIC-P or BIC-P is selected as the criterion, the nominal significance levels set through the select and alpha arguments will be ignored. For details on using AIC-P and BIC-P in variable and function selection, please refer to section 2.3.4.2.

2.3.4.1 Nominal significance levels

The mfp2() function has the arguments select and alpha for setting the nominal significance level for variable selection by BE and for testing between FP models of different degrees, respectively. When using these arguments, you should ensure that the criterion is set to "pvalue" to correctly use the specified significance levels.

For variable selection, a significance level can be set using the select argument. A value of 1 (select = 1) for all variables forces them all into the model. Setting the nominal significance level to be 1 for a given variable forces it into the model, leaving others to be selected or not. A variable is dropped if its removal leads to a nonsignificant increase in deviance. Default is select = 0.05 for each variable.

On the other hand, the alpha argument is used to determine the complexity of the selected FP function. A value of 1 (alpha = 1) will choose the most complex FP function permitted for a given variable. For example, if FP2 is the most complex function allowed for a continuous variable, setting alpha = 1 will select the best FP2 function. Default is alpha = 0.05 for each continuous variable.

The rules for setting select and alpha are the same as those for setting df (see section 2.3.3). The following R codes shows how to set equal nominal significance levels for variable and function selection \((\alpha_1 = \alpha_2 = 0.05)\) for each variable and produces identical results. Setting different nominal significance levels is straightforward. Simply replace the value 0.05 with the desired significance level of your choice.

# Default Interface
mfp2(x, y, select = rep(0.05, ncol(x)), alpha = rep(0.05, ncol(x)))

# Formula Interface
mfp2(lpsa ~ fp(age, select = 0.05) + svi + fp(pgg45, select = 0.05) + fp(cavol,
    select = 0.05) + fp(weight, select = 0.05) + fp(bph, select = 0.05) + fp(cp,
    select = 0.05), select = 0.05, alpha = 0.05, data = prostate)

In the formula interface, binary variables such as svi that are not passed in the fp() function utilize the global select argument. In our example, the global parameter is set to select = 0.05. If several binary variables exist in the model, the global parameters will be used for all of them. However, if specific parameters need to be set for individual binary variables, the user can use the fp()function. In summary, if a variable is not passed through the fp function, it will utilize the global parameters.

Suppose we want to force the variables "age" and "svi" in the model. To achieve this, we have two options:

  • Set select = 1 for age and svi in the mfp2() function.
  • Alternatively, we can use the keep argument, which resets the nominal significance levels for age and svi to 1 if they are different from 1. This ensures that these variables are retained in the model.
# default Interface Set select to 1 for variables 'age' and 'svi'
mfp2(x, y, select = c(1, 1, 0.05, 0.05, 0.05, 0.05, 0.05), alpha = rep(0.05,
    ncol(x)))

# use keep argument
mfp2(x, y, select = rep(0.05, ncol(x)), alpha = rep(0.05, ncol(x)), keep = c("age",
    "svi"))

# formula Interface use fp() function and set select to 1 for 'age' and
# 'svi'
mfp2(lpsa ~ fp(age, select = 1) + fp(svi, df = 1, select = 1) + fp(pgg45, select = 0.05) +
    fp(cavol, select = 0.05) + fp(weight, select = 0.05) + fp(bph, select = 0.05) +
    fp(cp, select = 0.05), select = 0.05, alpha = 0.05, data = prostate)

# use keep argument
mfp2(lpsa ~ fp(age, select = 0.05) + svi + fp(pgg45, select = 0.05) + fp(cavol,
    select = 0.05) + fp(weight, select = 0.05) + fp(bph, select = 0.05) + fp(cp,
    select = 0.05), select = 0.05, alpha = 0.05, keep = c("age", "svi"), data = prostate)

2.3.4.2 Information criteria

Instead of using nominal significance levels for variable and function selection, an alternative approach is to directly use adapted versions of AIC or BIC, defined below.

\[\begin{align*} AIC-P & = -2 \log(L) + 2k \\ BIC-P & = -2 \log(L) + \log(n) \times k, \end{align*}\]

where \(\log(L)\) is the maximum log-likelihood of the fitted model, which measures how well the model fits the data. The parameter \(k\) corresponds to the number of estimated parameters in the model (regression estimates and FP powers) and \(n\) is the sample size or the number of observations in the dataset. AIC-P and BIC-P consider both model fit and complexity, with lower values indicating better-fitting models.

For instance, let’s assume we want to select the best model for a variable of interest (\(z\)) with fixed adjustment variables \(x1\) (with power \(p3\) as the best FP1 function) and \(x2\) (linear function was pre-specified). Then, we can compare the AIC and BIC of different models, such as FP2, FP1, linear, and null models for \(z\). The adjustment models all have the same number of parameters (2 for \(x1\), 1 for \(x2\), and perhaps an intercept if it exists). For \(z\), we have 4, 2, and 1 parameter(s) for FP2, FP1, and linear models, respectively, for a model without an intercept. In a model without an intercept, the total number of parameters, including adjustment variables, for variable z are 7 (4 + 3) for FP2, 5 (2 + 3) for FP1, and 4 (1 + 3) for a linear model. These total number of parameters for each model type is used in calculating the AIC-P and BIC-P. The model with the smallest AIC-P or BIC-P is then selected for \(z\).

In mfp2 package, this can be achieved by setting the criterion argument to either "aic" or "bic" in the mfp2() function. Additionally, if there is a need to force certain variables, such as age and svi, into the model, the keep argument can be used.

The following R code demonstrates how to implement this approach using both the default and formula interfaces, as well as how to force specific variables into the model:

# Default Interface
mfp2(x, y, criterion = "aic", keep = c("age", "svi"))

# Formula Interface
mfp2(lpsa ~ fp(age) + fp(svi, df = 1) + fp(pgg45) + fp(cavol) + fp(weight) +
    fp(bph) + fp(cp), criterion = "aic", keep = c("age", "svi"), data = prostate)

2.3.5 Model comparison tests

The FSP in mfp2() function compares various models for the variable of interest. For instance, if the most complex allowed FP function is FP2, the FSP will compare the best FP2 model with the null model, the best FP2 model with the linear model, and the best FP2 model with the best FP1 model, when the criterion = "pvalue". The deviance for each model (null, linear, FP1, and FP2) and their corresponding differences and p-values will be calculated.

When comparing Gaussian models, the mfp2() function provides two options for calculating p-values: the F-test and the Chi-square test. The Chi-square test is the default option. For other non-Gaussian models such Cox and logistic regression models, the Chi-square test is used. For more detailed information, please refer to page 23 of the MFP Stata manual paper (here)

To use the F-test, we can set the ftest = TRUE, as demonstrated in the example below. Conversely, to use the Chi-square test, set ftest = FALSE.

# Default Interface
mfp2(x, y, criterion = "pvalue", ftest = TRUE)

# Formula Interface
mfp2(lpsa ~ fp(age) + svi + fp(pgg45) + fp(cavol) + fp(weight) + fp(bph) + fp(cp),
    criterion = "pvalue", ftest = TRUE, data = prostate)

Please note that the p-values reported by the mfp program in Stata for Gaussian models are based on the F-test. If you intend to compare the results between the two software packages, it is crucial to ensure that ftest = TRUE is set in R since the default is ftest = FALSE.

It is important to be aware that the older version of the mfp package in R uses the Chi-square test for all model types, which may yield different results compared to the Stata program, for Gaussian models. In summary, the mfp2 package reproduces the results of Stata (mfp and mfpa programs), as well as the old mfp program in R if you set ftest = FALSE.

2.3.6 Subject matter knowledge may require changes in fractional polynomial powers

By default, the mfp2() function uses the predefined set \(S = \{-2, -1, -0.5, 0, 0.5, 1, 2, 3\}\) for each continuous covariate, as proposed in the original paper by Royston and Altman (1994). However, there may be situations where users want to provide their own power terms based on subject matter knowledge (not all powers allowed). In such cases, the powers argument which takes a list of powers can be employed to specify the desired power terms. More extreme powers may be considered for a possible improvement of the model fit. This may be sensible if the ‘extreme’ power terms (-2, -2) or (3,3) are selected, Considering (-3,-3) or (4,4) may be a suitable option. By default, the covariates are arranged in order of decreasing statistical significance (see section 2.1 for other options).

The following example illustrates how to assign different power terms to continuous covariates. Two power terms (1 and 0.5) are evaluated for the age covariate. This set includes three models of degree 2 (with power combinations of (1, 0.5), (1, 1), and (0.5, 0.5)),and a model of degree 1 (with power of 0.5). A linear model (power=1) is also allowed.

The cavol variable is assigned three powers (1, 0, 1). The remaining continuous variables, namely pgg45, weight, bph, and cp, are not assigned any power terms. Instead, the default powers defined in set \(S\) are used and a search through all possible fractional polynomials up to the degree set by df is performed.

When using the fp() function in the formula interface, the power terms provided must be a vector not a list since they are specific to a particular variable.

# create a list of power terms for covariates 'age' and 'cavol'
powx <- list(age = c(1, 0.5), cavol = c(1, 0, 1))

# Default Interface
mfp2(x, y, criterion = "pvalue", powers = powx)

# Formula Interface
mfp2(lpsa ~ fp(age, powers = c(1, 0.5)) + svi + fp(pgg45) + fp(cavol, powers = c(1,
    0, 1)) + fp(weight) + fp(bph) + fp(cp), data = prostate)

2.3.7 Explanation of output from model-selection algorithm

Using the prostate example, we briefly explain how the algorithm works. Similar to backward elimination, it starts with the full model (model with all variables, linear function for all continuous variables) and investigates whether variables can be eliminated and whether non-linear functions improve the fit. For each of the continuous variables, the FSP is used to check whether a non-linear function fits the data significantly better than a linear function. After the first cycle, some variables may be eliminated from the model, and for some continuous variables, a more suitable non-linear function may be identified as a better fit for the data.

The algorithm then proceeds to the second cycle, but the new starting model now has fewer variables due to the elimination process in the previous cycle. Additionally, non-linear functions may have been identified for some of the continuous variables. In the second cycle, all variables will be reconsidered, even if they were not significant at the end of the first cycle, and FSP is used again to determine the ‘best’ fitting FP function (the selected functions may be different due to potential variations in the adjustment variables). The results obtained from the second cycle then serve as the starting model for the third cycle. In most cases, the variables and functions selected remain unchanged in cycles 3 or 4 and the algorithm stops with the final MFP model.

The order of ‘searching’ for model improvement by better fitting non-linear functions is important. Mismodelling the functional form of a variable with a strong effect is more critical than mismodelling the functional form of a variable with a weak effect. Therefore, the order is determined by the p-values from the full model. Variables with small p-values are considered first.

To explain the output of the MFP algorithm, we will use the default interface of the mfp2() function to build an MFP model with the default parameters. Specifically, all continuous variables are assigned a degree of freedom (df) of 4, implying that FP2 is the most complex permitted function. Moreover, we employ the ‘pvalue’ as the criterion for variable and function selection, and we set the nominal significance levels for both components to 0.05 for all variables. Finally, we use the F-test instead of Chi-square to calculate the p-values.

The R output displays the df used for each variable, as denoted by the “initial degrees of freedom”. The program correctly identifies svi as a binary variable and assigns it a df of 1. Additionally, the variables are ordered based on their p-values in descending order of significance, as indicated by the “visiting order”. The variable cavol has the smallest p-value and will be evaluated first, while age has the largest p-value and will be evaluated last.

fit <- mfp2(x, y, criterion = "pvalue", select = 0.05, alpha = 0.05, ftest = TRUE)
#> 
#> i Initial degrees of freedom:
#>    age svi pgg45 cavol weight bph cp
#> df   4   1     4     4      4   4  4
#> 
#> i Visiting order: cavol, svi, pgg45, weight, bph, cp, age
#> 
#> ---------------------
#> i Running MFP Cycle 1
#> ---------------------
#> 
#> Variable: cavol (keep = FALSE)
#>                  Powers    DF    Deviance    Versus           Deviance diff. P-value
#> FP2              -0.5, 1   12    196.3       .                .              .      
#> null             NA        8     240.1       FP2              43.8           0.0000 
#> linear           1         9     214.3       FP2              18.0           0.0011 
#> FP1              0         10    199.7       FP2              3.4            0.2226 
#> Selected: FP1
#> 
#> Variable: svi (keep = FALSE)
#>                  Powers    DF    Deviance    Versus           Deviance diff. P-value
#> null             NA        8     208.6       .                .              .      
#> linear           1         9     199.7       null             9.0            0.0042 
#> Selected: linear
#> 
#> Variable: pgg45 (keep = FALSE)
#>                  Powers    DF    Deviance    Versus           Deviance diff. P-value
#> FP2              -2, -2    12    196.7       .                .              .      
#> null             NA        8     202.0       FP2              5.3            0.3091 
#> Selected: null
#> 
#> Variable: weight (keep = FALSE)
#>                  Powers    DF    Deviance    Versus           Deviance diff. P-value
#> FP2              -2, -2    11    199.3       .                .              .      
#> null             NA        7     209.7       FP2              10.4           0.0521 
#> Selected: null
#> 
#> Variable: bph (keep = FALSE)
#>                  Powers    DF    Deviance    Versus           Deviance diff. P-value
#> FP2              -1, 3     10    207.7       .                .              .      
#> null             NA        6     217.7       FP2              10.0           0.0567 
#> Selected: null
#> 
#> Variable: cp (keep = FALSE)
#>                  Powers    DF    Deviance    Versus           Deviance diff. P-value
#> FP2              2, 3      9     213.2       .                .              .      
#> null             NA        5     217.9       FP2              4.6            0.3655 
#> Selected: null
#> 
#> Variable: age (keep = FALSE)
#>                  Powers    DF    Deviance    Versus           Deviance diff. P-value
#> FP2              -1, -1    8     216.6       .                .              .      
#> null             NA        4     217.9       FP2              1.2            0.8839 
#> Selected: null
#> 
#> ---------------------
#> i Running MFP Cycle 2
#> ---------------------
#> 
#> Variable: cavol (keep = FALSE)
#>                  Powers    DF    Deviance    Versus           Deviance diff. P-value
#> FP2              -0.5, 1   7     215.0       .                .              .      
#> null             NA        3     264.6       FP2              49.6           0.0000 
#> linear           1         4     238.1       FP2              23.0           0.0001 
#> FP1              0         5     217.9       FP2              2.8            0.2646 
#> Selected: FP1
#> 
#> Variable: svi (keep = FALSE)
#>                  Powers    DF    Deviance    Versus           Deviance diff. P-value
#> null             NA        3     226.9       .                .              .      
#> linear           1         4     217.9       null             9.0            0.0032 
#> Selected: linear
#> 
#> Variable: pgg45 (keep = FALSE)
#>                  Powers    DF    Deviance    Versus           Deviance diff. P-value
#> FP2              0.5, 3    8     214.3       .                .              .      
#> null             NA        4     217.9       FP2              3.6            0.4973 
#> Selected: null
#> 
#> Variable: weight (keep = FALSE)
#>                  Powers    DF    Deviance    Versus           Deviance diff. P-value
#> FP2              -2, -2    8     202.1       .                .              .      
#> null             NA        4     217.9       FP2              15.7           0.0052 
#> linear           1         5     205.0       FP2              2.9            0.4438 
#> Selected: linear
#> 
#> Variable: bph (keep = FALSE)
#>                  Powers    DF    Deviance    Versus           Deviance diff. P-value
#> FP2              0.5, 0.5  9     199.1       .                .              .      
#> null             NA        5     205.0       FP2              5.9            0.2460 
#> Selected: null
#> 
#> Variable: cp (keep = FALSE)
#>                  Powers    DF    Deviance    Versus           Deviance diff. P-value
#> FP2              2, 3      9     200.3       .                .              .      
#> null             NA        5     205.0       FP2              4.7            0.3617 
#> Selected: null
#> 
#> Variable: age (keep = FALSE)
#>                  Powers    DF    Deviance    Versus           Deviance diff. P-value
#> FP2              -0.5, 0   9     203.2       .                .              .      
#> null             NA        5     205.0       FP2              1.8            0.7926 
#> Selected: null
....

After the variables are ordered, the MFP algorithm starts by searching for a suitable function for cavol. It compares the best-fitting FP2 (-0.5, 1) function for cavol against a null model that excludes cavol. This comparison involves adjusting for all other six variables (svi to age) using linear functions. The test is highly significant (p = 0.0000), indicating that the best FP2 function fits significantly better than a null model. Next, the model with the best FP2 function is compared to a model assuming linearity, and the test remains significant (p = 0.0011). This suggests that cavol can be better described by a non-linear function at this stage. Finally, the best FP2 function is compared to the best FP1 (0) function, and the test is not significant (p = 0.2226). Thus, at this stage in the model-selection procedure, the final function for cavol is FP1 with power 0, denoting a log function.

The next variable to be evaluated is svi, which is a binary variable. In this case, only the test of null versus linear is appropriate. Both the null and linear models of svi are adjusted for log(cavol) (the log function just selected) and the other five variables (pgg45, cp, weight, bph, and age) that are still present in the model. The test of null versus linear is significant (p = 0.0042), indicating that svi remains in the model.

Next, we evaluate the continuous variable pgg45 in the same model as for svi. The p-value for the first test (FP2 versus null) is not significant (p = 0.3091), and the variable is eliminated from the model and will not be included in any of the models in the rest of the first cycle.

Next, the algorithm evaluates the variable weight in a model adjusting for log(cavol), svi, and the three variables (cp, bph, and age) that have not yet been evaluated. The first test is non-significant (p = 0.0521), and the variable is eliminated for the rest of the first cycle. In the subsequent steps, bph, cp, and age are also eliminated.

At the end of the first cycle, only two variables were selected: log(cavol) and svi.

The variables and functions selected in the first cycle becomes the new starting model for the second cycle. The second cycle starts with the evaluation of the effect of cavol, but this time in a simpler model adjusting for svi only. Deviances are larger compared to cycle 1 because the five variables (pgg45, age, weight, bph and cp) no longer belong to the ‘adjustment’ model. However, the FSP still selects log(cavol), now with a different estimate for the regression parameter.

Then svi is evaluated in a model that includes only log(cavol), and the test of linear vs null confirms that the variable should be included in the model. Pgg45 is evaluated in a model with svi and log(cavol) as adjustment variables, but the test of inclusion (FP2 vs null) is not significant and the variable is again eliminated.

The variable weight is considered next in a model with svi and log(cavol). In contrast to the first cycle, the test for inclusion (FP2 vs null) is significant (p = 0.0052), indicating that weight needs to be re-included into the model. The second test of the FSP (FP2 vs linearity) is non-significant and a linear function is chosen for weight. The inclusion of weight in the second cycle is a result of eliminating bph, cp and age in the first cycle, and of the correlation between these variables.

In the subsequent steps, bph, cp, and age are investigated in models adjusting for log(cavol), svi, and weight (linear). Compared to the first cycle, the p-values change, but all of them are much larger than 0.05. Therefore, none of these variables are included in the model.

The second cycle ends with the model consisting of log(cavol), svi (binary), and weight (linear).

This model serves as the starting point for the third cycle (not shown), where all seven variables are investigated again. However, there are no further change in the selected variables or functions, so MFP terminates with the three variables selected in the second cycle.

2.3.8 Methods defined for mfp2

Once you fit an MFP model using the mfp2() function, you can apply various methods to the resulting model object to extract information or perform specific tasks. Suppose we fit an MFP model for the Gaussian family with default parameters as follows:

fit <- mfp2(x, y, verbose = FALSE)
class(fit)
#> [1] "mfp2" "glm"  "lm"

The fit is an object of class mfp2, which inherits properties from glm and lm. If the family = "cox", the fit will inherit from coxph in the survival package. This means that mfp2 can utilize methods and functions defined for glm, lm or coxph.

To obtain a summary of the final mfp2 object, you can simply enter the object name (e.g., fit in our example) or use the print function. The print() function provides a comprehensive summary of the final MFP model, including the parameters used in the MFP model such as shifting and scaling factors, degrees of freedom (denoted by df_initial), nominal significance levels (select and alpha), and other relevant information.

Furthermore, it shows the final degrees of freedom (denoted by df_final), where a df of 0 indicates that a variable was eliminated, which is confirmed by the selected column. The power column shows the final FP powers for variables, with eliminated variables assigned NA. The acd column, which indicates whether ACD transformation was applied to a covariate, will only be displayed when the user chooses to apply ACD transformation to at least one covariate.

print(fit)
#> Shifting, Scaling and Centering of covariates 
#>        shift scale center
#> cavol      0    10   TRUE
#> svi        0     1   TRUE
#> pgg45      1   100   TRUE
#> weight     0   100   TRUE
#> bph        0     1   TRUE
#> cp         0    10   TRUE
#> age        0    10   TRUE
#> 
#> Final Multivariable Fractional Polynomial for y 
#>        df_initial select alpha selected df_final power1
#> cavol           4   0.05  0.05     TRUE        2      0
#> svi             1   0.05  0.05     TRUE        1      1
#> pgg45           4   0.05  0.05    FALSE        0     NA
#> weight          4   0.05  0.05     TRUE        1      1
#> bph             4   0.05  0.05    FALSE        0     NA
#> cp              4   0.05  0.05    FALSE        0     NA
#> age             4   0.05  0.05    FALSE        0     NA
#> 
#> MFP algorithm convergence: TRUE
#> 
#> Call:  glm(formula = y ~ ., family = family, data = data, weights = weights, 
#>     offset = offset, x = TRUE, y = TRUE)
#> 
#> Coefficients:
#> (Intercept)      cavol.1        svi.1     weight.1  
#>      2.3313       0.5402       0.6794       1.4159  
#> 
#> Degrees of Freedom: 96 Total (i.e. Null);  93 Residual
#> Null Deviance:       127.9 
#> Residual Deviance: 47    AIC: 215

To display the regression coefficients from the final MFP model, you can use the coef() or summary() function. It’s important to note that the variables in the model have names with dot extensions. This means that a variable with two FP powers (FP2) will be denoted as “var.1” and “var.2”. Please note that the displayed regression coefficients are not currently scaled back to the original scale.

# extract only regression coefficients
coef(fit)
#> (Intercept)     cavol.1       svi.1    weight.1 
#>   2.3312906   0.5402090   0.6794446   1.4158958

# display regression coefficients with other statistics
summary(fit)
#> 
#> Call:
#> glm(formula = y ~ ., family = family, data = data, weights = weights, 
#>     offset = offset, x = TRUE, y = TRUE)
#> 
#> Coefficients:
#>             Estimate Std. Error t value Pr(>|t|)    
#> (Intercept)  2.33129    0.08509  27.399  < 2e-16 ***
#> cavol.1      0.54021    0.07449   7.252  1.2e-10 ***
#> svi.1        0.67944    0.20807   3.265 0.001531 ** 
#> weight.1     1.41590    0.38967   3.634 0.000458 ***
#> ---
#> Signif. codes:  0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
#> 
#> (Dispersion parameter for gaussian family taken to be 0.5054218)
#> 
#>     Null deviance: 127.918  on 96  degrees of freedom
#> Residual deviance:  47.004  on 93  degrees of freedom
#> AIC: 215
#> 
#> Number of Fisher Scoring iterations: 2

Users can generate predictions for new or existing data based on the fitted MFP model using the predict() function. To illustrate this, let’s consider an example using the prostate dataset. Suppose we want to make predictions for the first five observations in the matrix \(x\) (considering them as new observations). We can achieve this with the following code:

# extract the first five observations from 'x'
new_observations <- x[1:5, ]
dim(new_observations)
#> [1] 5 7

# make predictions for these new observations.
predict(fit, newdata = new_observations)
#>           [,1]
#> [1,] 0.9297156
#> [2,] 0.8714946
#> [3,] 0.9499953
#> [4,] 0.7440425
#> [5,] 1.8612448

To prepare the newdata for prediction, the predict() function applies any necessary shifting and scaling based on the factors obtained from the development data. It is important to note that if the shifting factors are not sufficiently large as estimated from the development data, variables in newdata may end up with negative values, which can cause prediction errors if non-linear functional forms are used. A warning is given in this case by the function.

2.3.9 Graphical presentation of FP functions

The regression estimates (\(\hat{\beta}\)) for FP terms provide incomplete information as they only give limited insight into the fitted function for the variable of interest. A more informative approach is to visualize functions for variables with non-linear effects (Royston and Sauerbrei, 2008). The mfp2 package offers the fracplot() function specifically designed for this purpose.

By providing the mfp2 object and other relevant arguments, fracplot() generates plots of the functions for variables along with 95% confidence intervals. As for all data derived models, model based confidence limits may be too narrow. The bootstrap may be used to derive more realistic estimates of standard errors and pointwise confidence intervals (Sauerbrei and Royston 2007). You can specify the variable to be plotted using the terms argument. If terms is set to NULL (the default), the function returns a list of plots for all variables included in the model.

The fracplot() function, by default produces a component-plus-residual plot. This is because the partial_only argument is set to FALSE by default.

For Gaussian models with constant weights and a single covariate, this amounts to a plot of the outcome variable and each covariate with the fitted function.

For other normal-error models, weighted residuals are calculated and added to the fit. For models with two or more covariates, the function is the partial linear predictor for the variable of interest and includes the intercept.

For generalized linear and Cox models, the fracplot() function plots the fitted values on the scale of the linear predictor. Deviance residuals are added to the (partial) linear predictor for generalized linear models, while martingale residuals are added for Cox models to give component-plus-residual. These values are small circles on the plot. The component-plus-residual plots may show the amount of residual variation at each covariate and may indicate lack of fit or outliers in the outcome (Royston and Sauerbrei, 2008; StataCorp. 2023).

If you set partial_only = TRUE, the fracplot() function will plot only the partial linear predictor without including the residuals. For more detailed information on component-plus-residuals, you can refer to the Stata manual (here).

For instance, to plot the function for cavol in the model, you can use the following code:

plots <- fracplot(fit)

# plots is a list
class(plots)
#> [1] "list"

# The plot of cavol is the first element of the list
plots[[1]] + ggplot2::ylab("Partial predictor + residuals")
\label{fig:fig2}Prostate data. Graphical presentation of results from an FP analysis

Prostate data. Graphical presentation of results from an FP analysis

The fracplot() function also supports the incorporation of a reference point or target value in the plot. Including a reference point allows for visualizing whether other data points exceed or fall below the reference point. To achieve this, you can use the type argument and set it to “contrasts” (type = "contrasts"). Additionally, you can supply the reference point using the ref argument. By default, the ref argument is set to NULL, and average values are used as the reference points for continuous variables, while the minimum values are used as reference points for binary variables. For instance, if we want the reference value for the continuous variable cavol to be 30, we can use the following code:

plots <- fracplot(fit, type = "contrasts", ref = list(cavol = 30))
plots[[1]] + ggplot2::ylab("Partial predictor")
\label{fig:fig3}Prostate data. Illustration on how to use reference points (ref point = 30)

Prostate data. Illustration on how to use reference points (ref point = 30)

In certain cases, when the data points for a specific variable contain extreme values, the resulting function plotted using the original data can appear very sharp. This sharpness is primarily due to the limited number of data points that are close to the extreme values of the variable.

The fracplot() function provides two options for generating the plot. The first option is to use the original data that was used to fit the model (terms_seq = "data"). The second option is to generate a sequence of equidistant new data points using the range of the original data for the variable of interest (terms_seq = "equidistant").

To illustrate these options, we will use the art dataset included in the mfp2 package. This dataset is described in detail by Royston and Sauerbrei (2008, Chapter 10), and the outcome variable is continuous. In our example, we will fit an MFP model with a single covariate (\(x5\)) (see Figure below).


# load art data
data("art")

# fit mfp model using art data
xx <- as.matrix(art[, "x5", drop = FALSE])
yy <- as.numeric(art$y)
fit2 <- mfp2(xx, yy, verbose = FALSE)

# generate plot using original data
plot1 <- fracplot(fit2)
plot1[[1]] <- plot1[[1]] + ggplot2::ylab("Partial predictor + residuals")

# generate plot using sequence of data
plot2 <- fracplot(fit2, terms_seq = "equidistant")
plot2[[1]] <- plot2[[1]] + ggplot2::ylab("Partial predictor + residuals")

# combine plots
patchwork::wrap_plots(plot2[[1]], plot1[[1]], ncol = 2, widths = 8, heights = 4)
Art data. Illustration on how to use terms_seq argument in fracplot. In the original data, the function FP(0,3) was selected, equivalent to $\beta_0 + \beta_1log(x5) + \beta_2x5^3$. This function was plotted using the original values of x5 in the data (right panel) and a sequence of equidistant new data points using the range of the original x5 data (left panel). The two functions are identical up to x5 = 62. However, beyond this point, a linear trend is estimated when the original values are used due to lack of data points between 62.21 and 235. If the new data is used, it results in a curve, clearly depicting the FP2 function.

Art data. Illustration on how to use terms_seq argument in fracplot. In the original data, the function FP(0,3) was selected, equivalent to \(\beta_0 + \beta_1log(x5) + \beta_2x5^3\). This function was plotted using the original values of x5 in the data (right panel) and a sequence of equidistant new data points using the range of the original x5 data (left panel). The two functions are identical up to x5 = 62. However, beyond this point, a linear trend is estimated when the original values are used due to lack of data points between 62.21 and 235. If the new data is used, it results in a curve, clearly depicting the FP2 function.

2.3.10 Handling categorical variables

The mfp2 package requires the creation of dummy (indicator) variables for categorical independent variables before using the mfp2() function. The number of dummy variables depends on the number of classes in the categorical variable. As a general rule of thumb, a categorical variable with k classes is represented by k-1 dummy variables, each taking on the values of 0 and 1. It may be easiest to define k-1 new dummy variable before starting mfp2, including all k-1 dummy variables as independent variables. Based on subject matter knowledge you may also decide to combine some of the categories, resulting in a smaller number of dummy variables and decide to include these dummy variables in the model, not allowing their elimination. In principle, this would be an important decision from the initial data analysis process (Huebner et al 2018).

Categorical variables can be measured using an ordinal scale or a nominal scale. An ordinal variable indicates that the levels of the variable are ordered in some way, such as the levels of income (e.g., low income, medium income, and high income). On the other hand, a nominal variable has no intrinsic ordering among its categories. When variable selection is involved in the model building process, it is important to consider different approaches for coding ordinal and nominal variables in order to facilitate interpretation. This is because, during variable selection, certain dummy variables may be eliminated, which is analogous to combining some levels of variables. For more details on handling categorical variables, refer to Royston and Sauerbrei (2008, Chapter 3).

The model.matrix() function in R automatically generates dummy variables using a dummy coding for categorical variables. This will ignore any ordinal structure of the variables. The mfp2 package offers a function called create_dummy_variables() that provides an alternative to the model.matrix() specifically designed for creating dummy variables for both ordinal and nominal variables.

Before using the create_dummy_variables() function, we recommend converting the variable of interest to a factor using the factor() function in base R. If necessary, you can specify the levels of the variable. Otherwise, the first level will be used as the reference. We will illustrate how to handle categorical variables using the art data. The outcome variable is continuous, and there are 10 covariates.

The R code below demonstrates how to convert the ordinal variable x4, which has 3 levels (1 as the reference, 2, and 3), to dummy variables using ordinal coding. Similarly, it demonstrates how to convert the nominal variable x9, which also has 3 levels (1 as the reference, 2, and 3), to dummy variables using categorical coding. The final data will contain the dummy variables, which can be supplied to the mfp2() function.

# load art data
data("art")

# order the levels of the variable such that Levels: 1 < 2 < 3
art$x4 <- factor(art$x4, ordered = TRUE, levels = c(1, 2, 3))

# convert x9 to factor and assign level 1 as reference group
art$x9 <- factor(art$x9, ordered = FALSE, levels = c(1, 2, 3))

# create dummy variables for x4 and x9 based on ordinal an categorical
# coding and drop the original variable
art <- create_dummy_variables(art, var_ordinal = c("x4"), var_nominal = c("x9"),
    drop_variables = TRUE)

# display the first 20 observations
head(art, 10)
#>           y x1 x2 x3        x5  x6  x7 x8   x10 x4_1 x4_2 x92 x93
#> 1  12.81324 60  1 24  1.829647 247 302  0 33.13    0    0   0   0
#> 2  11.54249 35  1 20 10.335463  64  97  0 12.75    1    0   0   0
#> 3  10.15125 70  0 21  7.155877   0  76  1 16.92    1    0   0   0
#> 4  11.44530 64  0 17  7.745342  21   2  1 15.12    1    0   0   0
#> 5  13.01152 71  0 20  1.851301 226  92  0 31.75    1    0   1   0
#> 6  12.50528 50  1 17  2.471984  35 108  1  9.08    1    0   0   0
#> 7  11.48337 49  1 13  7.277893  15  66  1 23.75    1    1   0   0
#> 8  11.90820 44  1 20  6.306514  89 115  0 34.99    1    0   0   0
#> 9  12.55809 55  1 26  6.544373 171 133  1 22.64    1    0   1   0
#> 10 12.53969 56  1 14  2.057520  16 201  0 30.63    1    0   0   0

After creating the dummy variables (x4_1 and x4_2 for x4, and x92 and x93 for x9), we fit the MFP model using the mfp2() function with default parameters. If a categorical variable is not an important predictor of the outcome, all the dummy variables will be eliminated, as in the case of variable x9. On the other hand, variable x4 is an important predictor, and only one dummy (x4_2) out of the two was eliminated. Elimination of x4_2 means that the two categories 2 and 3 are collapsed as a result of the selection process.

# create matrix x and outcome y
x <- as.matrix(art[, -1])
y <- as.numeric(art$y)

# fit mfp using default interface with default parameters
fit <- mfp2(x, y, verbose = FALSE)
fit
#> Shifting, Scaling and Centering of covariates 
#>      shift scale center
#> x5       0   100   TRUE
#> x1       0    10   TRUE
#> x7       1  1000   TRUE
#> x10      0    10   TRUE
#> x4_1     0     1   TRUE
#> x93      0     1   TRUE
#> x8       0     1   TRUE
#> x92      0     1   TRUE
#> x4_2     0     1   TRUE
#> x6       1  1000   TRUE
#> x2       0     1   TRUE
#> x3       0    10   TRUE
#> 
#> Final Multivariable Fractional Polynomial for y 
#>      df_initial select alpha selected df_final power1 power2
#> x5            4   0.05  0.05     TRUE        4      0      3
#> x1            4   0.05  0.05     TRUE        1      1     NA
#> x7            4   0.05  0.05    FALSE        0     NA     NA
#> x10           4   0.05  0.05     TRUE        1      1     NA
#> x4_1          1   0.05  0.05     TRUE        1      1     NA
#> x93           1   0.05  0.05    FALSE        0     NA     NA
#> x8            1   0.05  0.05     TRUE        1      1     NA
#> x92           1   0.05  0.05    FALSE        0     NA     NA
#> x4_2          1   0.05  0.05    FALSE        0     NA     NA
#> x6            4   0.05  0.05     TRUE        2      0     NA
#> x2            1   0.05  0.05    FALSE        0     NA     NA
#> x3            4   0.05  0.05     TRUE        1      1     NA
#> 
#> MFP algorithm convergence: TRUE
#> 
#> Call:  glm(formula = y ~ ., family = family, data = data, weights = weights, 
#>     offset = offset, x = TRUE, y = TRUE)
#> 
#> Coefficients:
#> (Intercept)         x5.1         x5.2         x1.1        x10.1       x4_1.1         x8.1  
#>     12.3794      -0.6793       0.1973      -0.2169       0.1787      -0.3616       0.3324  
#>        x6.1         x3.1  
#>      0.2318      -0.2350  
#> 
#> Degrees of Freedom: 249 Total (i.e. Null);  241 Residual
#> Null Deviance:       245 
#> Residual Deviance: 118.6     AIC: 543

2.4 Logistic regression

Logistic regression is a statistical method used to model binary outcomes. The mfp2() function implements the logistic regression model using the family = "binomial" argument. For illustration, we will use the Pima Indians dataset included in the mfp2 package, which was downloaded from the MFP website(here). The dataset originates from a study conducted on a cohort of 768 female Pima Indians, a group known to be particularly susceptible to diabetes. Out of the 768 individuals, 268 developed diabetes. The dataset consists of a binary outcome variable, denoting the presence (1) or absence (0) of diabetes, and eight covariates. For more information on the dataset, please refer to the book by Royston and Sauerbrei (2008) Chapter 9.7.

In the mfp2() function, the response variable y should be provided as a binary vector rather than a matrix. The other arguments whether using the “default” or “formula” interface for logistic regression, are nearly identical to those previously explained for the Gaussian family.

# load pima data
data("pima")
head(pima)
#> # A tibble: 6 × 10
#>      id pregnant glucose diastolic triceps insulin   bmi diabetes   age     y
#>   <dbl>    <dbl>   <dbl>     <dbl>   <dbl>   <dbl> <dbl>    <dbl> <dbl> <dbl>
#> 1     1        6     148        72      35     126  33.6    0.627    50     1
#> 2     2        1      85        66      29      76  26.6    0.351    31     0
#> 3     3        8     183        64      20     272  23.3    0.672    32     1
#> 4     4        1      89        66      23      94  28.1    0.167    21     0
#> 5     5        0     137        40      35     168  43.1    2.29     33     1
#> 6     6        5     116        74      19      72  25.6    0.201    30     0

# matrix x
x <- as.matrix(pima[, 2:9])
# outcome y
y <- as.vector(pima$y)

# fit mfp
fit <- mfp2(x, y, family = "binomial", verbose = FALSE)
fit
#> Shifting, Scaling and Centering of covariates 
#>           shift scale center
#> glucose       0   100   TRUE
#> bmi           0    10   TRUE
#> pregnant      1    10   TRUE
#> diabetes      0     1   TRUE
#> age           0    10   TRUE
#> diastolic     0    10   TRUE
#> triceps       0    10   TRUE
#> insulin       0   100   TRUE
#> 
#> Final Multivariable Fractional Polynomial for y 
#>           df_initial select alpha selected df_final power1 power2
#> glucose            4   0.05  0.05     TRUE        1      1     NA
#> bmi                4   0.05  0.05     TRUE        2     -2     NA
#> pregnant           4   0.05  0.05    FALSE        0     NA     NA
#> diabetes           4   0.05  0.05     TRUE        1      1     NA
#> age                4   0.05  0.05     TRUE        4      0      3
#> diastolic          4   0.05  0.05    FALSE        0     NA     NA
#> triceps            4   0.05  0.05    FALSE        0     NA     NA
#> insulin            4   0.05  0.05    FALSE        0     NA     NA
#> 
#> MFP algorithm convergence: TRUE
#> 
#> Call:  glm(formula = y ~ ., family = family, data = data, weights = weights, 
#>     offset = offset, x = TRUE, y = TRUE)
#> 
#> Coefficients:
#> (Intercept)    glucose.1        bmi.1   diabetes.1        age.1        age.2  
#>    -0.98769      3.61970    -15.16265      0.80648      4.38286     -0.01672  
#> 
#> Degrees of Freedom: 767 Total (i.e. Null);  762 Residual
#> Null Deviance:       993.5 
#> Residual Deviance: 683.5     AIC: 695.5

From the output, it is evident that four continuous variables (glucose(power 1), bmi(-2), diabetes(1) and age (0, 3)) are selected. We can use fracplot() function to generate plots for these selected variables, as illustrated below, which produced the Figure below.

Pima data. Graphical presentation of results from an MFP analysis

Pima data. Graphical presentation of results from an MFP analysis

2.5 Survival data

We illustrate two of the analyses performed by Sauerbrei and Royston (1999). We use the gbsg data, which contains prognostic factors data from the German Breast Cancer Study Group of patients with node-positive breast cancer. The response variable is recurrence-free survival time (rectime), and the censoring variable is censrec. There are 686 patients with 299 events. We use Cox regression to predict the log hazard of recurrence from prognostic factors, of which five are continuous (age, size, nodes, pgr, er), and one is binary (meno). The variable grade is ordinal, and we will use ordinal coding to create two dummy variables (grade_1 and grade_2). The treatment variable hormonal therapy (hormon) is forced into the model. As an alternative we stratify the analysis using the hormon variable.

We use the mfp2() function with default parameters to build a model from the initial set of eight covariates. We set the nominal significance level for variable and FP selection to 0.05 for all variables except hormon, which is forced into the model using the keep argument by setting the significance level of hormon to 1.

The mfp2() function for survival outcome requires the outcome variable to be a survival object created using the survival::Surv() function. Other arguments are similar to those explained previously for the Gaussian family.

# load gbsg data
data("gbsg")

# data preparation create dummy variable for grade using ordinal coding
gbsg <- create_dummy_variables(gbsg, var_ordinal = "grade", drop_variables = TRUE)

# covariate matrix x
x <- as.matrix(gbsg[, -c(1, 6, 10, 11)])
head(x, 10)
#>       age meno size nodes pgr  er hormon grade_1 grade_2
#>  [1,]  38    0   18     5 141 105      0       1       1
#>  [2,]  52    0   20     1  78  14      0       0       0
#>  [3,]  47    0   30     1 422  89      0       1       0
#>  [4,]  40    0   24     3  25  11      0       0       0
#>  [5,]  64    1   19     1  19   9      1       1       0
#>  [6,]  49    1   56     3 356  64      1       0       0
#>  [7,]  53    1   52     9   6  29      0       1       0
#>  [8,]  61    1   22     2   6 173      1       1       0
#>  [9,]  43    0   30     1  22   0      0       1       0
#> [10,]  74    1   20     1 462 240      1       1       0

# use Surv() function to create outcome y
y <- survival::Surv(gbsg$rectime, gbsg$censrec)

# fit mfp and keep hormon in the model
fit1 <- mfp2(x, y, family = "cox", keep = "hormon", control = coxph.control(iter.max = 50),
    verbose = FALSE)
fit1
#> Shifting, Scaling and Centering of covariates 
#>         shift scale center
#> nodes       0    10   TRUE
#> pgr         1  1000   TRUE
#> grade_1     0     1   TRUE
#> hormon      0     1   TRUE
#> size        0   100   TRUE
#> meno        0     1   TRUE
#> grade_2     0     1   TRUE
#> age         0    10   TRUE
#> er          1  1000   TRUE
#> 
#> Final Multivariable Fractional Polynomial for y 
#>         df_initial select alpha selected df_final power1 power2
#> nodes            4   0.05  0.05     TRUE        4   -2.0   -1.0
#> pgr              4   0.05  0.05     TRUE        2    0.5     NA
#> grade_1          1   0.05  0.05     TRUE        1    1.0     NA
#> hormon           1   1.00  0.05     TRUE        1    1.0     NA
#> size             4   0.05  0.05    FALSE        0     NA     NA
#> meno             1   0.05  0.05    FALSE        0     NA     NA
#> grade_2          1   0.05  0.05    FALSE        0     NA     NA
#> age              4   0.05  0.05     TRUE        4   -2.0   -0.5
#> er               4   0.05  0.05    FALSE        0     NA     NA
#> 
#> MFP algorithm convergence: TRUE
#> Call:
#> survival::coxph(formula = ff, data = d, weights = weights, control = control, 
#>     x = TRUE, y = TRUE, method = method, nocenter = nocenter)
#> 
#>                 coef  exp(coef)   se(coef)      z        p
#> nodes.1    3.879e-02  1.040e+00  7.697e-03  5.040 4.67e-07
#> nodes.2   -5.491e-01  5.775e-01  8.643e-02 -6.353 2.11e-10
#> pgr.1     -1.807e+00  1.642e-01  3.506e-01 -5.153 2.56e-07
#> grade_1.1  5.007e-01  1.650e+00  2.496e-01  2.006  0.04488
#> hormon.1  -4.024e-01  6.687e-01  1.281e-01 -3.142  0.00168
#> age.1      4.473e+01  2.677e+19  8.257e+00  5.418 6.03e-08
#> age.2     -1.792e+01  1.645e-08  3.910e+00 -4.584 4.55e-06
#> 
#> Likelihood ratio test=155.6  on 7 df, p=< 2.2e-16
#> n= 686, number of events= 299

According to Sauerbrei and Royston (1999), medical knowledge dictates that the estimated risk function for nodes (number of positive nodes), which was selected with FP powers (-2, -1), should be monotonic - but the selected function is not. Therefore, they proposed to estimate a preliminary exponential transformation, enodes = exp(-0.12 * nodes), for nodes and fitting a degree 1 FP for enodes, thus obtaining a monotonic risk function. The value of -0.12 was estimated univariately using nonlinear Cox regression. To ensure a negative exponent, Sauerbrei and Royston (1999) restricted the powers for enodes to be positive. Their Model III may be fit by using the following R command, which yields identical results to the mfp command in Stata(here):

# remove nodes and include enodes
x <- as.matrix(gbsg[, -c(1, 5, 10, 11)])

# fit mfp and keep hormon in the model
fit2 <- mfp2(x, y, family = "cox", keep = "hormon", powers = list(enodes = c(0.5,
    1, 2, 3)), control = coxph.control(iter.max = 50), verbose = FALSE)
fit2
#> Shifting, Scaling and Centering of covariates 
#>         shift scale center
#> enodes      0     1   TRUE
#> pgr         1  1000   TRUE
#> hormon      0     1   TRUE
#> grade_1     0     1   TRUE
#> size        0   100   TRUE
#> meno        0     1   TRUE
#> grade_2     0     1   TRUE
#> age         0    10   TRUE
#> er          1  1000   TRUE
#> 
#> Final Multivariable Fractional Polynomial for y 
#>         df_initial select alpha selected df_final power1 power2
#> enodes           4   0.05  0.05     TRUE        1    1.0     NA
#> pgr              4   0.05  0.05     TRUE        2    0.5     NA
#> hormon           1   1.00  0.05     TRUE        1    1.0     NA
#> grade_1          1   0.05  0.05     TRUE        1    1.0     NA
#> size             4   0.05  0.05    FALSE        0     NA     NA
#> meno             1   0.05  0.05    FALSE        0     NA     NA
#> grade_2          1   0.05  0.05    FALSE        0     NA     NA
#> age              4   0.05  0.05     TRUE        4   -2.0   -0.5
#> er               4   0.05  0.05    FALSE        0     NA     NA
#> 
#> MFP algorithm convergence: TRUE
#> Call:
#> survival::coxph(formula = ff, data = d, weights = weights, control = control, 
#>     x = TRUE, y = TRUE, method = method, nocenter = nocenter)
#> 
#>                 coef  exp(coef)   se(coef)      z        p
#> enodes.1  -1.981e+00  1.379e-01  2.269e-01 -8.732  < 2e-16
#> pgr.1     -1.840e+00  1.588e-01  3.508e-01 -5.245 1.57e-07
#> hormon.1  -3.945e-01  6.740e-01  1.281e-01 -3.080  0.00207
#> grade_1.1  5.174e-01  1.678e+00  2.494e-01  2.075  0.03799
#> age.1      4.355e+01  8.226e+18  8.253e+00  5.277 1.31e-07
#> age.2     -1.748e+01  2.558e-08  3.912e+00 -4.469 7.87e-06
#> 
#> Likelihood ratio test=153.1  on 6 df, p=< 2.2e-16
#> n= 686, number of events= 299

See Figure 1 in Sauerbrei and Royston (1999) for the functions for nodes with powers (-2, - 1) and for enodes.

2.5.1 Stratified Cox model

The stratified Cox model is a variation of the Cox proportional hazards (PH) model that allows for controlling the effect of a covariate that does not satisfy the PH assumption (Therneau et al. 2000). The model includes covariates that are assumed to satisfy the PH assumption, while the covariate being stratified on is not included in the model. Instead of including the stratified variable as a covariate in the model, it is used to define distinct subgroups.

The mfp2() function, similar to the coxph() function in the survival package, includes a strata argument that enables stratification. The fitted MFP model assumes that the FP functions for a particular variable do not vary over the strata. However, it is essential for the user to evaluate this assumption.

To provide an illustrative example, we will stratify the analysis using the variable hormon. The following R code demonstrates how to fit a stratified Cox model using both the default and formula interfaces, along with their default parameters.

# using default interface
fit2 <- mfp2(x[, -7], y, family = "cox", strata = x[, 7], verbose = FALSE)
fit2
#> Shifting, Scaling and Centering of covariates 
#>         shift scale center
#> enodes      0     1   TRUE
#> pgr         1  1000   TRUE
#> grade_1     0     1   TRUE
#> size        0   100   TRUE
#> meno        0     1   TRUE
#> grade_2     0     1   TRUE
#> age         0    10   TRUE
#> er          1  1000   TRUE
#> 
#> Final Multivariable Fractional Polynomial for y 
#>         df_initial select alpha selected df_final power1 power2
#> enodes           4   0.05  0.05     TRUE        1    1.0     NA
#> pgr              4   0.05  0.05     TRUE        2    0.5     NA
#> grade_1          1   0.05  0.05     TRUE        1    1.0     NA
#> size             4   0.05  0.05    FALSE        0     NA     NA
#> meno             1   0.05  0.05    FALSE        0     NA     NA
#> grade_2          1   0.05  0.05    FALSE        0     NA     NA
#> age              4   0.05  0.05     TRUE        4   -2.0     -1
#> er               4   0.05  0.05    FALSE        0     NA     NA
#> 
#> MFP algorithm convergence: TRUE
#> Call:
#> survival::coxph(formula = ff, data = d, weights = weights, control = control, 
#>     x = TRUE, y = TRUE, method = method, nocenter = nocenter)
#> 
#>                 coef  exp(coef)   se(coef)      z        p
#> enodes.1  -1.978e+00  1.384e-01  2.272e-01 -8.704  < 2e-16
#> pgr.1     -1.808e+00  1.639e-01  3.507e-01 -5.156 2.52e-07
#> grade_1.1  5.134e-01  1.671e+00  2.495e-01  2.058   0.0396
#> age.1      6.057e+01  2.029e+26  1.188e+01  5.098 3.43e-07
#> age.2     -2.653e+01  3.007e-12  5.904e+00 -4.494 6.99e-06
#> 
#> Likelihood ratio test=142  on 5 df, p=< 2.2e-16
#> n= 686, number of events= 299

# using formula interface
fit3 <- mfp2(Surv(rectime, censrec) ~ age + meno + size + nodes + pgr + er +
    grade_1 + grade_2 + strata(hormon), family = "cox", data = gbsg, verbose = FALSE)

3 MFP with ACD transformation

Royston (2014) proposed the approximate cumulative distribution (ACD) transformation of a continuous covariate x as a route toward modeling a sigmoid relationship between x and an outcome variable y. The ACD transformation is a smooth function that maps a continuous covariate, x, to an approximation, ACD (x), of its distribution function. By construction, the distribution of ACD (x) in the sample is roughly uniform on (0, 1). FP modeling is then performed with the transformed values ACD (x) instead of x as a covariate. He further showed that such an approach could successfully represent a sigmoid function of x, something a standard FP function cannot do (Royston and Sauerbrei 2008). He went on to demonstrate that useful flexibility in functional form could be achieved by considering both x and a = ACD (x) simultaneously as independent covariates and applying the MFP algorithm to x and a. To limit instability and overfitting, he suggested restricting the models considered for x and a to FP1 functions. Furthermore, Royston (2014) highlighted that models based on ACD (x) may have other advantages in terms of interpretability of regression coefficients.

Royston and Sauerbrei (2016) extended the MFP modeling approach to incorporate the ACD transformation, resulting in the MFPA (MFP with ACD) algorithm. To implement this extension, the original FSP is replaced by a modified version known as FSPA (FSP with ACD transformation). The MFPA algorithm has all the features of the MFP algorithm plus the ability to model a sigmoid function. For additional information on MFPA, including FSPA, please refer to Royston and Sauerbrei (2016)

3.1 Modeling a sigmoid relationship

We will demonstrate how to fit the MFPA using the mfp2() function. In this example, we simulated the data to create an example that showcases this relationship. The simulation process is outlined below.

# Generate artificial data with sigmoid relationship
set.seed(54)
n <- 500
x <- matrix(rnorm(n), ncol = 1, dimnames = list(NULL, "x"))

# Apply sigmoid transformation to x
sigmoid <- function(x) {
    1/(1 + exp(-1.7 * x))
}

# Generate y with sigmoid relationship to x
y <- as.numeric(20 * sigmoid(x) + rnorm(n, mean = 0, sd = 0.5))

The mfp2() function has an acdx argument that allows the user to specify the names of continuous variables to undergo the ACD transformation. The use of acdx invokes the FSPA to determine the best-fitting model (see documentation for more details). The acdx parameter can be set in the formula interface using the fp() function, as demonstrated in the R code below. To avoid confusion with the original variable x, the variable representing the ACD transformation of x is named A(x) in the output.

# default interface
fit1 <- mfp2(x, y, acdx = "x", verbose = FALSE)

# formula interface
datax <- data.frame(y, x)
fit2 <- mfp2(y ~ fp(x, acdx = TRUE), data = datax, verbose = FALSE)

# display selected power terms
fit2
#> Shifting, Scaling and Centering of covariates 
#>      shift scale center
#> x 3.005751     1   TRUE
#> 
#> Final Multivariable Fractional Polynomial for y 
#>   df_initial select alpha  acd selected df_final power1 power2
#> x          4   0.05  0.05 TRUE     TRUE        4      1      1
#> 
#> MFP algorithm convergence: TRUE
#> 
#> Call:  glm(formula = y ~ ., family = family, data = data, weights = weights, 
#>     offset = offset, x = TRUE, y = TRUE)
#> 
#> Coefficients:
#> (Intercept)          x.1        A_x.1  
#>      9.8889      -0.5686      22.4108  
#> 
#> Degrees of Freedom: 499 Total (i.e. Null);  497 Residual
#> Null Deviance:       17060 
#> Residual Deviance: 129.7     AIC: 752.4

# fit usual mfp: bad idea but useful for illustration
fit3 <- mfp2(y ~ fp(x, acdx = FALSE), data = datax, verbose = FALSE)
fit3
#> Shifting, Scaling and Centering of covariates 
#>      shift scale center
#> x 3.005751     1   TRUE
#> 
#> Final Multivariable Fractional Polynomial for y 
#>   df_initial select alpha selected df_final power1 power2
#> x          4   0.05  0.05     TRUE        4      3      3
#> 
#> MFP algorithm convergence: TRUE
#> 
#> Call:  glm(formula = y ~ ., family = family, data = data, weights = weights, 
#>     offset = offset, x = TRUE, y = TRUE)
#> 
#> Coefficients:
#> (Intercept)          x.1          x.2  
#>      9.8889       0.9659      -0.4925  
#> 
#> Degrees of Freedom: 499 Total (i.e. Null);  497 Residual
#> Null Deviance:       17060 
#> Residual Deviance: 231.8     AIC: 1043

The selected function using the ACD transformation is FP1(1,1), represented by \(\beta_0 + \beta_1x^1 +\beta_2a^1\). On the other hand, the usual MFP approach selected FP2(3,3), equivalent to \(\beta_0 + \beta_1x^3 +\beta_2x^3 \log(x)\). The Figure below shows these functions. It is evident from the figure that the ACD approach provides a better fit to the data compared to the usual MFP model.

The selected function using the ACD transformation is FP1(1,1) represented by $\beta_0 + \beta_1x^1 +\beta_2a^1$(left panel), while the usual MFP selected FP2(3,3), equivalent to $\beta_0 + \beta_1x^3 +\beta_2x^3\log(x)$ (right panel). See text for more details

The selected function using the ACD transformation is FP1(1,1) represented by \(\beta_0 + \beta_1x^1 +\beta_2a^1\)(left panel), while the usual MFP selected FP2(3,3), equivalent to \(\beta_0 + \beta_1x^3 +\beta_2x^3\log(x)\) (right panel). See text for more details

4 References

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