The hardware and bandwidth for this mirror is donated by METANET, the Webhosting and Full Service-Cloud Provider.
If you wish to report a bug, or if you are interested in having us mirror your free-software or open-source project, please feel free to contact us at mirror[@]metanet.ch.
To add interactions between covariates in your model, you can add
additional arguments in the pars
vector in the
logitr()
function separated by the *
symbol.
For example, let’s say we want to interact price
with
feat
in the following model:
library("logitr")
model <- logitr(
data = yogurt,
outcome = 'choice',
obsID = 'obsID',
pars = c('price', 'feat', 'brand')
)
To do so, I could add "price*feat"
to the
pars
vector:
model_price_feat <- logitr(
data = yogurt,
outcome = 'choice',
obsID = 'obsID',
pars = c('price', 'feat', 'brand', 'price*feat')
)
The model now has an estimated coefficient for the
price*feat
effect:
summary(model_price_feat)
#> =================================================
#>
#> Model estimated on: Wed Jul 24 05:46:54 2024
#>
#> Using logitr version: 1.1.2
#>
#> Call:
#> logitr(data = yogurt, outcome = "choice", obsID = "obsID", pars = c("price",
#> "feat", "brand", "price*feat"))
#>
#> Frequencies of alternatives:
#> 1 2 3 4
#> 0.402156 0.029436 0.229270 0.339138
#>
#> Exit Status: 3, Optimization stopped because ftol_rel or ftol_abs was reached.
#>
#> Model Type: Multinomial Logit
#> Model Space: Preference
#> Model Run: 1 of 1
#> Iterations: 19
#> Elapsed Time: 0h:0m:0.01s
#> Algorithm: NLOPT_LD_LBFGS
#> Weights Used?: FALSE
#> Robust? FALSE
#>
#> Model Coefficients:
#> Estimate Std. Error z-value Pr(>|z|)
#> price -0.356909 0.024696 -14.4522 < 2.2e-16 ***
#> feat 1.155206 0.378237 3.0542 0.002257 **
#> brandhiland -3.724702 0.146520 -25.4212 < 2.2e-16 ***
#> brandweight -0.640221 0.054543 -11.7380 < 2.2e-16 ***
#> brandyoplait 0.724315 0.080317 9.0182 < 2.2e-16 ***
#> price:feat -0.086381 0.047275 -1.8272 0.067672 .
#> ---
#> Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
#>
#> Log-Likelihood: -2655.5403770
#> Null Log-Likelihood: -3343.7419990
#> AIC: 5323.0807540
#> BIC: 5357.8100000
#> McFadden R2: 0.2058178
#> Adj McFadden R2: 0.2040234
#> Number of Observations: 2412.0000000
In the above example, both price
and feat
were continuous variables, so only a single interaction coefficient was
needed.
In the case of interacting discrete variables, multiple
interactions coefficients will be estimated according to the number of
levels in the discrete attribute. For example, the interaction of
price
with brand
will require three new
interactions - one for each level of the brand
variable
except the first reference level:
model_price_brand <- logitr(
data = yogurt,
outcome = 'choice',
obsID = 'obsID',
pars = c('price', 'feat', 'brand', 'price*brand')
)
The model now has three estimated coefficients for the
price*brand
effect:
summary(model_price_brand)
#> =================================================
#>
#> Model estimated on: Wed Jul 24 05:46:54 2024
#>
#> Using logitr version: 1.1.2
#>
#> Call:
#> logitr(data = yogurt, outcome = "choice", obsID = "obsID", pars = c("price",
#> "feat", "brand", "price*brand"))
#>
#> Frequencies of alternatives:
#> 1 2 3 4
#> 0.402156 0.029436 0.229270 0.339138
#>
#> Exit Status: 3, Optimization stopped because ftol_rel or ftol_abs was reached.
#>
#> Model Type: Multinomial Logit
#> Model Space: Preference
#> Model Run: 1 of 1
#> Iterations: 37
#> Elapsed Time: 0h:0m:0.03s
#> Algorithm: NLOPT_LD_LBFGS
#> Weights Used?: FALSE
#> Robust? FALSE
#>
#> Model Coefficients:
#> Estimate Std. Error z-value Pr(>|z|)
#> price -0.389503 0.045247 -8.6085 < 2.2e-16 ***
#> feat 0.421899 0.122578 3.4419 0.0005777 ***
#> brandhiland -1.691789 0.623149 -2.7149 0.0066295 **
#> brandweight -2.228475 0.561641 -3.9678 7.254e-05 ***
#> brandyoplait 0.438702 0.450424 0.9740 0.3300689
#> price:brandhiland -0.434271 0.115531 -3.7589 0.0001707 ***
#> price:brandweight 0.199919 0.069830 2.8629 0.0041973 **
#> price:brandyoplait 0.033233 0.050372 0.6598 0.5094089
#> ---
#> Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
#>
#> Log-Likelihood: -2643.2046775
#> Null Log-Likelihood: -3343.7419990
#> AIC: 5302.4093549
#> BIC: 5348.7150000
#> McFadden R2: 0.2095070
#> Adj McFadden R2: 0.2071145
#> Number of Observations: 2412.0000000
If you want to include interactions with individual-specific
variables (for example, to assess the difference in an effect between
groups of respondents), you should not include the
individual-specific variable interactions using *
in
pars
. This is because interactions inside pars
automatically generate the interaction coefficient as well as
coefficients for each covariate.
For example, if you had a group
variable that determined
whether individuals belongs to group A
or group
B
, including price*group
in pars
would create coefficients for price
, groupA
,
and price:groupA
, but the groupA
coefficient
would be unidentified. In this case, you should only include
price
and price:groupA
in the model. For now,
the only way to handle this situation is to manually create dummy-coded
interaction variables to include in the model.
To illustrate how one might do this, consider if the
yogurt
data frame had two groups of individuals:
A
and B
. For simple illustration, I’ll define
these groups arbitrarily based on whether or not the obsID
is even or odd:
An interaction between the group
variable and
price
can be included in the model by first manually
creating a price_groupA
interaction variable and then
including it in pars
:
# Create dummy coefficients for group interaction with price
yogurt$price_groupA <- yogurt$price*yogurt$groupA
model_price_group <- logitr(
data = yogurt,
outcome = 'choice',
obsID = 'obsID',
pars = c('price', 'feat', 'brand', 'price_groupA')
)
The model now has attribute coefficients for price
,
feat
, and brand
as well as an interaction
between the group
and price
:
summary(model_price_group)
#> =================================================
#>
#> Model estimated on: Wed Jul 24 05:46:54 2024
#>
#> Using logitr version: 1.1.2
#>
#> Call:
#> logitr(data = yogurt, outcome = "choice", obsID = "obsID", pars = c("price",
#> "feat", "brand", "price_groupA"))
#>
#> Frequencies of alternatives:
#> 1 2 3 4
#> 0.402156 0.029436 0.229270 0.339138
#>
#> Exit Status: 3, Optimization stopped because ftol_rel or ftol_abs was reached.
#>
#> Model Type: Multinomial Logit
#> Model Space: Preference
#> Model Run: 1 of 1
#> Iterations: 26
#> Elapsed Time: 0h:0m:0.02s
#> Algorithm: NLOPT_LD_LBFGS
#> Weights Used?: FALSE
#> Robust? FALSE
#>
#> Model Coefficients:
#> Estimate Std. Error z-value Pr(>|z|)
#> price -0.3680634 0.0273911 -13.4373 < 2.2e-16 ***
#> feat 0.4915271 0.1200725 4.0936 4.248e-05 ***
#> brandhiland -3.7155231 0.1454216 -25.5500 < 2.2e-16 ***
#> brandweight -0.6411384 0.0544999 -11.7640 < 2.2e-16 ***
#> brandyoplait 0.7345568 0.0806444 9.1086 < 2.2e-16 ***
#> price_groupA 0.0030007 0.0254484 0.1179 0.9061
#> ---
#> Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
#>
#> Log-Likelihood: -2656.8808982
#> Null Log-Likelihood: -3343.7419990
#> AIC: 5325.7617965
#> BIC: 5360.4911000
#> McFadden R2: 0.2054169
#> Adj McFadden R2: 0.2036225
#> Number of Observations: 2412.0000000
Suppose I want to include an interaction between two variables and I
also want one of those variables to be modeled as normally distributed
across the population. The example below illustrates this cases, where a
price*feat
interaction is specified and the
feat
parameter is modeled as normally distributed by
setting randPars = c(feat = "n")
:
model_price_feat_mxl <- logitr(
data = yogurt,
outcome = 'choice',
obsID = 'obsID',
pars = c('price', 'feat', 'brand', 'price*feat'),
randPars = c(feat = "n")
)
In this case, the price*feat
interaction parameter is
interpreted as a difference in the feat_mu
parameter and
price; that is, it an interaction in the mean feat
parameter and price
:
summary(model_price_feat_mxl)
#> =================================================
#>
#> Model estimated on: Wed Jul 24 05:46:54 2024
#>
#> Using logitr version: 1.1.2
#>
#> Call:
#> logitr(data = yogurt, outcome = "choice", obsID = "obsID", pars = c("price",
#> "feat", "brand", "price*feat"), randPars = c(feat = "n"))
#>
#> Frequencies of alternatives:
#> 1 2 3 4
#> 0.402156 0.029436 0.229270 0.339138
#>
#> Exit Status: 3, Optimization stopped because ftol_rel or ftol_abs was reached.
#>
#> Model Type: Mixed Logit
#> Model Space: Preference
#> Model Run: 1 of 1
#> Iterations: 32
#> Elapsed Time: 0h:0m:0.62s
#> Algorithm: NLOPT_LD_LBFGS
#> Weights Used?: FALSE
#> Robust? FALSE
#>
#> Model Coefficients:
#> Estimate Std. Error z-value Pr(>|z|)
#> price -0.388138 0.027026 -14.3615 < 2.2e-16 ***
#> feat 0.829059 0.552235 1.5013 0.1333
#> brandhiland -3.991584 0.165893 -24.0612 < 2.2e-16 ***
#> brandweight -0.662161 0.055780 -11.8709 < 2.2e-16 ***
#> brandyoplait 0.787758 0.086233 9.1352 < 2.2e-16 ***
#> price:feat -0.076752 0.071063 -1.0800 0.2801
#> sd_feat -2.341209 0.493326 -4.7458 2.077e-06 ***
#> ---
#> Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
#>
#> Log-Likelihood: -2645.2196926
#> Null Log-Likelihood: -3343.7419990
#> AIC: 5304.4393851
#> BIC: 5344.9569000
#> McFadden R2: 0.2089044
#> Adj McFadden R2: 0.2068109
#> Number of Observations: 2412.0000000
#>
#> Summary of 10k Draws for Random Coefficients:
#> Min. 1st Qu. Median Mean 3rd Qu. Max.
#> feat -Inf -0.7475368 0.8308482 0.832337 2.409772 Inf
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.