knitr::opts_chunk$set( collapse = TRUE, warning = FALSE, message = FALSE, fig.path = "figs/", fig.retina = 3, comment = "#>" ) set.seed(5678)
Once a model has been estimated, it can be used to predict probabilities and / or outcomes for a set of alternatives. This vignette demonstrates examples of how to so using the predict()
method along with an estimated model.
You can make predictions for any set of alternatives, so long as the columns in the alternatives correspond to estimated coefficients in your model. By default, if no new data are provided via the newdata
argument, then predictions will be made for the original data used to estimate the model.
Predictions can be made using both preference space and WTP space models, as well as multinomial logit and mixed logit models. For mixed logit models, heterogeneity is modeled by simulating draws from the population estimates of the estimated model.
In the example below, a preference space MNL model is estimated (mnl_pref
) and then used to predict probabilities for the data used to estimate the model:
library("logitr") mnl_pref <- logitr( data = yogurt, outcome = 'choice', obsID = 'obsID', pars = c('price', 'feat', 'brand') ) probs <- predict(mnl_pref) head(probs)
The predict()
method returns a data frame containing the observation ID as well as the predicted probabilities. The original data can also be returned in the data frame by setting returnData = TRUE
:
probs <- predict(mnl_pref, returnData = TRUE) head(probs)
To make predictions for a new set of alternatives, use the newdata
argument. The example below makes predictions for just two of the choice observations from the yogurt
dataset:
data <- subset( yogurt, obsID %in% c(42, 13), select = c('obsID', 'alt', 'price', 'feat', 'brand')) probs_mnl_pref <- predict( mnl_pref, newdata = data, obsID = "obsID" ) probs_mnl_pref
Upper and lower bounds of a confidence interval for predicted probabilities can be obtained by setting interval = "confidence"
, and the tolerance level (0 to 1) is set with the level
argument (defaults to 0.95). Intervals are estimated using the Krinsky and Robb parametric bootstrapping method [@Krinsky1986]. For example, a 95% CI is obtained with the following:
probs_mnl_pref <- predict( mnl_pref, newdata = data, obsID = "obsID", interval = "confidence", level = 0.95 ) probs_mnl_pref
WTP space models can also be used to predict probabilities. In the example below, a WTP space model is estimated and used to predict probabilities for the same data
data frame as in the previous examples:
mnl_wtp <- logitr( data = yogurt, outcome = 'choice', obsID = 'obsID', pars = c('feat', 'brand'), scalePar = 'price', numMultiStarts = 10 ) probs_mnl_wtp <- predict( mnl_wtp, newdata = data, obsID = "obsID", interval = "confidence" ) probs_mnl_wtp
Here is a bar chart comparing the predicted probabilities from the preference space and WTP space models. Since both models are equivalent except in different spaces, the predicted probabilities are identical:
library("ggplot2") probs <- rbind(probs_mnl_pref, probs_mnl_wtp) probs$model <- c(rep("mnl_pref", 8), rep("mnl_wtp", 8)) probs$alt <- rep(c("dannon", "hiland", "weight", "yoplait"), 4) probs$obs <- paste0("Observation ID: ", probs$obsID) ggplot(probs, aes(x = alt, y = predicted_prob, fill = model)) + geom_bar(stat = 'identity', width = 0.7, position = "dodge") + geom_errorbar(aes(ymin = predicted_prob_lower, ymax = predicted_prob_upper), width = 0.2, position = position_dodge(width = 0.7)) + facet_wrap(vars(obs)) + scale_y_continuous(limits = c(0, 1)) + labs(x = 'Alternative', y = 'Expected Choice Probabilities') + theme_bw()
knitr::include_graphics('probs.png')
The predict()
method can also be used to predict outcomes by setting type = "outcome"
(the default is "prob"
for predicting probabilities). In the examples below, outcomes are predicted using the same preference space and WTP space models as in the previous examples. The returnData
argument is also set to TRUE
so that the predicted outcomes can be compared to the actual choices made:
outcomes_pref <- predict( mnl_pref, type = "outcome", returnData = TRUE ) head(outcomes_pref) outcomes_wtp <- predict( mnl_wtp, type = "outcome", returnData = TRUE ) head(outcomes_wtp)
The accuracy of each model can be computed by dividing the number of correctly predicted choices by the total number of choices:
chosen_pref <- subset(outcomes_pref, choice == 1) chosen_pref$correct <- chosen_pref$choice == chosen_pref$predicted_outcome accuracy_pref <- sum(chosen_pref$correct) / nrow(chosen_pref) accuracy_pref chosen_wtp <- subset(outcomes_wtp, choice == 1) chosen_wtp$correct <- chosen_wtp$choice == chosen_wtp$predicted_outcome accuracy_wtp <- sum(chosen_wtp$correct) / nrow(chosen_wtp) accuracy_wtp
These results show that both models correctly predicted choice for approximately r scales::percent(round(accuracy_pref, 2))
of the observations in the yogurt
data frame, which is significantly better than random (25%).
Any scripts or data that you put into this service are public.
Add the following code to your website.
For more information on customizing the embed code, read Embedding Snippets.