I have a generalized linear model (family - gamma) with interaction, and need to plot it specifically in ggplot2 (on a response scale).
The model was constructed with following code:
fit1mult = glm(SIZE_OOCYTE ~ TREATMENT * CASTE,
family = Gamma(link = "log"), data=data1)
I made a plot using the lattice package, and it looks like this:
How can I make a similar one in ggplot? I know that the geom_smooth has an option glm, but don't know how to apply it.
Thanks in advance for suggestions!
UPD. Solution:
library(ggeffects)
mydf1 <- ggpredict(fit1mult, terms = c("CASTE", "TREATMENT"))
plot(mydf1)
Result:
new plot
Related
I have create a multivariate linear regression model in R called modelP. I want to plot this in ggplot, but can't work this out. The model is:
modelP <- lm(House_Price ~ FactorA + FactorB + FactorC, data=df)
I have plotted individual linear regression lines for each factor, but I want to create a graph of the model combining all factors. I would like to do something like this:
ggplot(df)+
geom_smooth(aes(y = House_Price, x = FactorA + FactorB + FactorC))
Or
ggplot(modelP$model)+
geom_smooth(method="lm")
But neither approach seems like it will work. I would really appreciate any help.
In the past, I had used the sjp.glmer from the package sjPlot to visualize the different slopes from a generalized mixed effects model. However, with the new package, I can't figure out how to plot the individual slopes, as in the figure for the probabilities of fixed effects by (random) group level, located here
Here is the code that, I think, should allow for the production of the figure. I just can't seem to get it in the new version of sjPlot.
library(lme4)
library(sjPlot)
data(efc)
# create binary response
efc$hi_qol = 0
efc$hi_qol[efc$quol_5 > mean(efc$quol_5,na.rm=T)] = 1
# prepare group variable
efc$grp = as.factor(efc$e15relat)
# data frame for 2nd fitted model
mydf <- na.omit(data.frame(hi_qol = as.factor(efc$hi_qol),
sex = as.factor(efc$c161sex),
c12hour = as.numeric(efc$c12hour),
neg_c_7 = as.numeric(efc$neg_c_7),
grp = efc$grp))
# fit 2nd model
fit2 <- glmer(hi_qol ~ sex + c12hour + neg_c_7 + (1|grp),
data = mydf,
family = binomial("logit"))
I have tried to graph the model using the following code.
plot_model(fit2,type="re")
plot_model(fit2,type="prob")
plot_model(fit2,type="eff")
I think that I may be missing a flag, but after reading through the documentation, I can't find out what that flag may be.
Looks like this might do what you want:
(pp <- plot_model(fit2,type="pred",
terms=c("c12hour","grp"),pred.type="re"))
type="pred": plot predicted values
terms=c("c12hour", "grp"): include c12hour (as the x-axis variable) and grp in the predictions
pred.type="re": random effects
I haven't been able to get confidence-interval ribbons yet (tried ci.lvl=0.9, but no luck ...)
pp+facet_wrap(~group) comes closer to the plot shown in the linked blog post (each random-effects level gets its own facet ...)
Ben already posted the correct answer. sjPlot uses the ggeffects-package for marginal effects plot, so an alternative would be using ggeffects directly:
ggpredict(fit2, terms = c("c12hour", "grp"), type="re") %>% plot()
There's a new vignette describing how to get marginal effects for mixed models / random effects. However, confidence intervals are currently not available for this plot-type.
The type = "ri.prob" option in the linked blog-post did not adjust for covariates, that's why I first removed that option and later re-implemented it (correctly) in ggeffects / sjPlot. The confidence intervals shown in the linked blog-post are not correct, either. Once I figure out a way how to obtain CI or prediction intervals, I'll add this option as well.
I'm trying to plot the resultant curve from fitting a non-linear mixed model. It should be something like a curve of a normal distribution but skewed to the right. I followed previous links here and here, but when I use my data I can not make it happen for different difficulties (see below).
Here is the dataset
and code
s=read.csv("GRVMAX tadpoles.csv")
t=s[s$SPP== levels(s$SPP)[1],]
head(t)
vmax=t[t$PERFOR=="VMAX",]
colnames(vmax)[6]="vmax"
vmax$TEM=as.numeric(as.character(vmax$TEM));
require(lme4)
start =c(TEM=25)
is.numeric(start)
nm1 <- nlmer ( vmax ~ deriv(TEM)~TEM|INDIVIDUO,nlpars=start, nAGQ =0,data= vmax)# this gives an error suggesting nlpars is not numeric, despite start is numeric...:~/
After that, I want to plot the curve over the original data
with(vmax,plot(vmax ~ (TEM)))
x=vmax$TEM
lines(x, predict(nm1, newdata = data.frame(TEM = x, INDIVIDUO = "ACI5")))
Any hint?
Thanks in advance
Hi I am currently estimating happiness and age using the gam model.
My command for the regression is
fit <- gam(happy ~ s(age) + s(age, by=nochild) ,data=happy)
and I would like to visualise the estimated effect of the interactive variable "s(age):nochild" using visreg. I am struggling to do so as only the estimation for age and nochild has shown up when using
visreg(fit)
I want the graph to look like this
Y axis : s(age):nochild
X axis : age
However, I am not sure how to do this with visreg or is there any other commands that can help to do this?
Thank you so much in advance
I got the code that I need now so I think I might share this.
plot(fit, select=2, main="No Children")
I have a logistic regression model (using R) as
fit6 <- glm(formula = survived ~ ascore + gini + failed, data=records, family = binomial)
summary(fit6)
I'm using pROC package to draw ROC curves and figure out AUC for 6 models fit1 through fit6.
I have approached this way to plots one ROC.
prob6=predict(fit6,type=c("response"))
records$prob6 = prob6
g6 <- roc(survived~prob6, data=records)
plot(g6)
But is there a way I can combine the ROCs for all 6 curves in one plot and display the AUCs for all of them, and if possible the Confidence Intervals too.
You can use the add = TRUE argument the plot function to plot multiple ROC curves.
Make up some fake data
library(pROC)
a=rbinom(100, 1, 0.25)
b=runif(100)
c=rnorm(100)
Get model fits
fit1=glm(a~b+c, family='binomial')
fit2=glm(a~c, family='binomial')
Predict on the same data you trained the model with (or hold some out to test on if you want)
preds=predict(fit1)
roc1=roc(a ~ preds)
preds2=predict(fit2)
roc2=roc(a ~ preds2)
Plot it up.
plot(roc1)
plot(roc2, add=TRUE, col='red')
This produces the different fits on the same plot. You can get the AUC of the ROC curve by roc1$auc, and can add it either using the text() function in base R plotting, or perhaps just toss it in the legend.
I don't know how to quantify confidence intervals...or if that is even a thing you can do with ROC curves. Someone else will have to fill in the details on that one. Sorry. Hopefully the rest helped though.