rms (version 6.2-0)

predictrms: Predicted Values from Model Fit


The predict function is used to obtain a variety of values or predicted values from either the data used to fit the model (if type="adjto" or "adjto.data.frame" or if x=TRUE or linear.predictors=TRUE were specified to the modeling function), or from a new dataset. Parameters such as knots and factor levels used in creating the design matrix in the original fit are "remembered". See the Function function for another method for computing the linear predictors. predictrms is an internal utility function that is for the other functions.


predictrms(fit, newdata=NULL,
           type=c("lp", "x", "data.frame", "terms", "cterms", "ccterms",
             "adjto", "adjto.data.frame", "model.frame"),
           se.fit=FALSE, conf.int=FALSE,
           conf.type=c('mean', 'individual', 'simultaneous'),
           kint=NULL, na.action=na.keep, expand.na=TRUE,
           center.terms=type=="terms", ref.zero=FALSE,
           posterior.summary=c('mean', 'median', 'mode'),
           second=FALSE, ...)
# S3 method for bj
predict(object, newdata,
        type=c("lp", "x", "data.frame", "terms", "cterms", "ccterms",
               "adjto", "adjto.data.frame", "model.frame"), 
        se.fit=FALSE, conf.int=FALSE,
        na.action=na.keep, expand.na=TRUE,
        center.terms=type=="terms", …) # for bj

# S3 method for cph predict(object, newdata=NULL, type=c("lp", "x", "data.frame", "terms", "cterms", "ccterms", "adjto", "adjto.data.frame", "model.frame"), se.fit=FALSE, conf.int=FALSE, conf.type=c('mean','individual','simultaneous'), kint=1, na.action=na.keep, expand.na=TRUE, center.terms=type=="terms", …) # cph

# S3 method for Glm predict(object, newdata, type= c("lp", "x", "data.frame", "terms", "cterms", "ccterms", "adjto", "adjto.data.frame", "model.frame"), se.fit=FALSE, conf.int=FALSE, conf.type=c('mean','individual','simultaneous'), kint=1, na.action=na.keep, expand.na=TRUE, center.terms=type=="terms", …) # Glm

# S3 method for Gls predict(object, newdata, type=c("lp", "x", "data.frame", "terms", "cterms", "ccterms", "adjto", "adjto.data.frame", "model.frame"), se.fit=FALSE, conf.int=FALSE, conf.type=c('mean','individual','simultaneous'), kint=1, na.action=na.keep, expand.na=TRUE, center.terms=type=="terms", …) # Gls

# S3 method for ols predict(object, newdata, type=c("lp", "x", "data.frame", "terms", "cterms", "ccterms", "adjto", "adjto.data.frame", "model.frame"), se.fit=FALSE, conf.int=FALSE, conf.type=c('mean','individual','simultaneous'), kint=1, na.action=na.keep, expand.na=TRUE, center.terms=type=="terms", …) # ols

# S3 method for psm predict(object, newdata, type=c("lp", "x", "data.frame", "terms", "cterms", "ccterms", "adjto", "adjto.data.frame", "model.frame"), se.fit=FALSE, conf.int=FALSE, conf.type=c('mean','individual','simultaneous'), kint=1, na.action=na.keep, expand.na=TRUE, center.terms=type=="terms", …) # psm



a fit object with an rms fitting function


An S data frame, list or a matrix specifying new data for which predictions are desired. If newdata is a list, it is converted to a matrix first. A matrix is converted to a data frame. For the matrix form, categorical variables (catg or strat) must be coded as integer category numbers corresponding to the order in which value labels were stored. For list or matrix forms, matrx factors must be given a single value. If this single value is the S missing value NA, the adjustment values of matrx (the column medians) will later replace this value. If the single value is not NA, it is propagated throughout the columns of the matrx factor. For factor variables having numeric levels, you can specify the numeric values in newdata without first converting the variables to factors. These numeric values are checked to make sure they match a level, then the variable is converted internally to a factor. It is most typical to use a data frame for newdata, and the S function expand.grid is very handy here. For example, one may specify





Type of output desired. The default is "lp" to get the linear predictors - predicted \(X\beta\). For Cox models, these predictions are centered. You may specify "x" to get an expanded design matrix at the desired combinations of values, "data.frame" to get an S data frame of the combinations, "model.frame" to get a data frame of the transformed predictors, "terms" to get a matrix with each column being the linear combination of variables making up a factor (with separate terms for interactions), "cterms" ("combined terms") to not create separate terms for interactions but to add all interaction terms involving each predictor to the main terms for each predictor, "ccterms" to combine all related terms (related through interactions) and their interactions into a single column, "adjto" to return a vector of limits[2] (see datadist) in coded form, and "adjto.data.frame" to return a data frame version of these central adjustment values. Use of type="cterms" does not make sense for a strat variable that does not interact with another variable. If newdata is not given, predict will attempt to return information stored with the fit object if the appropriate options were used with the modeling function (e.g., x, y, linear.predictors, se.fit).


Defaults to FALSE. If type="linear.predictors", set se.fit=TRUE to return a list with components linear.predictors and se.fit instead of just a vector of fitted values. For Cox model fits, standard errors of linear predictors are computed after subtracting the original column means from the new design matrix.


Specify conf.int as a positive fraction to obtain upper and lower confidence intervals (e.g., conf.int=0.95). The \(t\)-distribution is used in the calculation for ols fits. Otherwise, the normal critical value is used. For Bayesian models conf.int is the highest posterior density interval probability.


specifies the type of confidence interval. Default is for the mean. For ols fits there is the option of obtaining confidence limits for individual predicted values by specifying conf.type="individual".


when making predictions from a Bayesian model, specifies whether you want the linear predictor to be computed from the posterior mean of parameters (default) or the posterior mode or median median


set to TRUE to use the model's second formula. At present this pertains only to a partial proportional odds model fitted using the blrm function. When second=TRUE and type='x' the Z design matrix is returned (that goes with the tau parameters in the partial PO model). When type='lp' is specified Z*tau is computed. In neither case is the result is multiplied by the by the cppo function.


a single integer specifying the number of the intercept to use in multiple-intercept models. The default is 1 for lrm and the reference median intercept for orm and blrm. For a partial PO model, kint should correspond to the response variable value that will be used when dealing with second=TRUE.


Function to handle missing values in newdata. For predictions "in data", the same na.action that was used during model fitting is used to define an naresid function to possibly restore rows of the data matrix that were deleted due to NAs. For predictions "out of data", the default na.action is na.keep, resulting in NA predictions when a row of newdata has an NA. Whatever na.action is in effect at the time for "out of data" predictions, the corresponding naresid is used also.


set to FALSE to keep the naresid from having any effect, i.e., to keep from adding back observations removed because of NAs in the returned object. If expand.na=FALSE, the na.action attribute will be added to the returned object.


set to FALSE to suppress subtracting adjust-to values from columns of the design matrix before computing terms with type="terms".


Set to TRUE to subtract a constant from \(X\beta\) before plotting so that the reference value of the x-variable yields y=0. This is done before applying function fun. This is especially useful for Cox models to make the hazard ratio be 1.0 at reference values, and the confidence interval have width zero.



datadist and options(datadist=) should be run before predictrms if using type="adjto", type="adjto.data.frame", or type="terms", or if the fit is a Cox model fit and you are requesting se.fit=TRUE. For these cases, the adjustment values are needed (either for the returned result or for the correct covariance matrix computation).

See Also

plot.Predict, ggplot.Predict, summary.rms, rms, rms.trans, predict.lrm, predict.orm, residuals.cph, datadist, gendata, gIndex, Function.rms, reShape, xYplot, contrast.rms


n <- 1000    # define sample size
set.seed(17) # so can reproduce the results
age            <- rnorm(n, 50, 10)
blood.pressure <- rnorm(n, 120, 15)
cholesterol    <- rnorm(n, 200, 25)
sex            <- factor(sample(c('female','male'), n,TRUE))
treat          <- factor(sample(c('a','b','c'), n,TRUE))

# Specify population model for log odds that Y=1
L <- .4*(sex=='male') + .045*(age-50) +
  (log(cholesterol - 10)-5.2)*(-2*(sex=='female') + 2*(sex=='male')) +
  .3*sqrt(blood.pressure-60)-2.3 + 1*(treat=='b')
# Simulate binary y to have Prob(y=1) = 1/[1+exp(-L)]
y <- ifelse(runif(n) < plogis(L), 1, 0)

ddist <- datadist(age, blood.pressure, cholesterol, sex, treat)

fit <- lrm(y ~ rcs(blood.pressure,4) + 
           sex * (age + rcs(cholesterol,4)) + sex*treat*age)

# Use xYplot to display predictions in 9 panels, with error bars,
# with superposition of two treatments

dat <- expand.grid(treat=levels(treat),sex=levels(sex),
# Add variables linear.predictors and se.fit to dat
dat <- cbind(dat, predict(fit, dat, se.fit=TRUE))
# This is much easier with Predict
# xYplot in Hmisc extends xyplot to allow error bars
             linear.predictors+1.96*se.fit) ~ cholesterol | sex*age,
       groups=treat, data=dat, type='b')

# Since blood.pressure doesn't interact with anything, we can quickly and
# interactively try various transformations of blood.pressure, taking
# the fitted spline function as the gold standard. We are seeking a
# linearizing transformation even though this may lead to falsely
# narrow confidence intervals if we use this data-dredging-based transformation

bp <- 70:160
logit <- predict(fit, expand.grid(treat="a", sex='male', age=median(age),
                 blood.pressure=bp), type="terms")[,"blood.pressure"]
#Note: if age interacted with anything, this would be the age
#      "main effect" ignoring interaction terms
#Could also use Predict(f, age=ag)$yhat
#which allows evaluation of the shape for any level of interacting
#factors.  When age does not interact with anything, the result from
#predict(f, \dots, type="terms") would equal the result from
#plot if all other terms were ignored

plot(bp^.5, logit)               # try square root vs. spline transform.
plot(bp^1.5, logit)              # try 1.5 power
plot(sqrt(bp-60), logit)

#Some approaches to making a plot showing how predicted values
#vary with a continuous predictor on the x-axis, with two other
#predictors varying

combos <- gendata(fit, age=seq(10,100,by=10), cholesterol=c(170,200,230),
#treat, sex not specified -> set to mode
#can also used expand.grid

combos$pred <- predict(fit, combos)
xyplot(pred ~ age | cholesterol*blood.pressure, data=combos, type='l')
xYplot(pred ~ age | cholesterol, groups=blood.pressure, data=combos, type='l')
Key()   # Key created by xYplot
xYplot(pred ~ age, groups=interaction(cholesterol,blood.pressure),
       data=combos, type='l', lty=1:9)

# Add upper and lower 0.95 confidence limits for individuals
combos <- cbind(combos, predict(fit, combos, conf.int=.95))
xYplot(Cbind(linear.predictors, lower, upper) ~ age | cholesterol,
       groups=blood.pressure, data=combos, type='b')

# Plot effects of treatments (all pairwise comparisons) vs.
# levels of interacting factors (age, sex)

d <- gendata(fit, treat=levels(treat), sex=levels(sex), age=seq(30,80,by=10))
x <- predict(fit, d, type="x")
betas <- fit$coef
cov   <- vcov(fit, intercepts='none')

i <- d$treat=="a"; xa <- x[i,]; Sex <- d$sex[i]; Age <- d$age[i]
i <- d$treat=="b"; xb <- x[i,]
i <- d$treat=="c"; xc <- x[i,]

doit <- function(xd, lab) {
  xb <- matxv(xd, betas)
  se <- apply((xd %*% cov) * xd, 1, sum)^.5
  q <- qnorm(1-.01/2)   # 0.99 confidence limits
  lower <- xb - q * se; upper <- xb + q * se
  #Get odds ratios instead of linear effects
  xb <- exp(xb); lower <- exp(lower); upper <- exp(upper)
  #First elements of these agree with 
  #summary(fit, age=30, sex='female',conf.int=.99))
  for(sx in levels(Sex)) {
    j <- Sex==sx
    errbar(Age[j], xb[j], upper[j], lower[j], xlab="Age", 
           ylab=paste(lab, "Odds Ratio"), ylim=c(.1, 20), log='y')
    title(paste("Sex:", sx))
    abline(h=1, lty=2)

par(mfrow=c(3,2), oma=c(3,0,3,0))
doit(xb - xa, "b:a")
doit(xc - xa, "c:a")
doit(xb - xa, "c:b")

# NOTE: This is much easier to do using contrast.rms

# Demonstrate type="terms", "cterms", "ccterms"
n <- 40
x <- 1:n
w <- factor(sample(c('a', 'b'), n, TRUE))
u <- factor(sample(c('A', 'B'), n, TRUE))
y <- .01*x + .2*(w=='b') + .3*(u=='B') + .2*(w=='b' & u=='B') + rnorm(n)/5
ddist <- datadist(x, w, u)
f <- ols(y ~ x*w*u, x=TRUE, y=TRUE)
z <- predict(f, type='terms', center.terms=FALSE)
k <- coef(f)
## Manually compute combined terms
wb <- w=='b'
uB <- u=='B'
h  <- k['x * w=b * u=B']*x*wb*uB
tx <- k['x']  *x  + k['x * w=b']*x*wb + k['x * u=B']  *x*uB  + h
tw <- k['w=b']*wb + k['x * w=b']*x*wb + k['w=b * u=B']*wb*uB + h
tu <- k['u=B']*uB + k['x * u=B']*x*uB + k['w=b * u=B']*wb*uB + h
h   <- z[,'x * w * u'] # highest order term is present in all cterms
tx2 <- z[,'x']+z[,'x * w']+z[,'x * u']+h
tw2 <- z[,'w']+z[,'x * w']+z[,'w * u']+h
tu2 <- z[,'u']+z[,'x * u']+z[,'w * u']+h
ae <- function(a, b) all.equal(a, b, check.attributes=FALSE)
ae(tx, tx2)
ae(tw, tw2)
ae(tu, tu2)

zc <- predict(f, type='cterms')
ae(tx, zc[,'x'])
ae(tw, zc[,'w'])
ae(tu, zc[,'u'])

zc <- predict(f, type='ccterms')
# As all factors are indirectly related, ccterms gives overall linear
# predictor except for the intercept
ae(as.vector(zc + coef(f)[1]), f$linear.predictors)

# }
#A variable state.code has levels "1", "5","13"
#Get predictions with or without converting variable in newdata to factor
predict(fit, data.frame(state.code=c(5,13)))
predict(fit, data.frame(state.code=factor(c(5,13))))

#Use gendata function (gendata.rms) for interactive specification of
#predictor variable settings (for 10 observations)
df <- gendata(fit, nobs=10, viewvals=TRUE)
df$predicted <- predict(fit, df)  # add variable to data frame

df <- gendata(fit, age=c(10,20,30))  # leave other variables at ref. vals.
predict(fit, df, type="fitted")

# See reShape (in Hmisc) for an example where predictions corresponding to 
# values of one of the varying predictors are reformatted into multiple
# columns of a matrix
# }
# }