I am conducting a study using a survey design to predict the total number of procedures per year in a dataset from 2017 to 2030. I am currently using Poisson regression to create these predictive estimates.
svydesign(
data = four,
strata = ~NIS_STRATUMnew,
ids = ~NISIDnew,
weights = ~DISCWTnew,
nest = T
)
I am able to successfully use the following to generate estimates and accurate confidence intervals for the years that we have data (prior to 2017):
kneetotal1<- svyby(~kneePJI, ~YEAR, design = mydesign, FUN = svytotal, vartype = "ci")
However, when I try to calculate prediction intervals for the estimates I run into issues (my prediction intervals are way too narrow), either if I try to directly use my data to make predictions (1) or if I use the svyby (2) results to make predictions:
(1)
AdjPoissonKnee <- svyglm(kneePJI ~ YEAR, family = poisson(), design = mydesign)
years <- data.frame(YEAR = 2018:2030)
predictHip <- predict(AdjPoissonHip, newdata = data.frame(YEAR = 2018:2030), type = "response", se.fit =TRUE, interval = "predict")
(This just seems to produce likelihood per person of a procedure. I am not sure how to yield a yearly cumulative sum for this, along with confidence intervals)
(2)
futureyears <- data.table(YEAR = 2018:2030)
AdjPoissonKnee <- glm(kneePJI ~ YEAR, family = poisson(), data=kneetotal1)
kneepredict <- predict(object = AdjPoissonKnee, newdata=futureyears, type = "response")
The dataset is extremely large, so that may be contributing to the issue of very narrow prediction intervals. Lmk if there is a way I can help by adding a snippet of some data.
Example output (2) combined with svyby of 2002-2017:
kneetotal1<- svyby(~kneePJI, ~YEAR, design = mydesign, FUN = svytotal, vartype = "ci")
> kneetotal1
YEAR kneePJI
2002 8205.194
2003 9648.019
2004 10362.076
2005 11771.961
2006 12099.399
2007 12993.681
2008 15438.871
2009 14303.562
2010 16051.562
2011 17158.166
2012 17055.006
2013 18064.991
2014 19080.006
2015 19429.988
2016 18070.002
2017 18399.995
AdjPoissonKnee <- glm(kneePJI ~ YEAR, family = poisson(), data=kneetotal1)
kneese <- predict(object = AdjPoissonKnee, newdata=futureyears, type = "response", interval = "prediction", se.fit =TRUE)
> kneese
$fit
1 2 3 4 5 6 7 8 9 10 11 12 13
22107.84 23232.34 24414.04 25655.84 26960.81 28332.15 29773.25 31287.64 32879.07 34551.44 36308.87 38155.70 40096.46
$se.fit
1 2 3 4 5 6 7 8 9 10 11 12 13
87.14235 100.68424 115.63713 132.05885 150.02228 169.61303 190.92798 214.07449 239.16993 266.34157 295.72666 327.47263 361.73741
> stderrKnee <- kneese$se.fit
> predfitKnee <- kneese$fit
> reserrsqKnee <- predfitKnee^2*summary(AdjPoissonKnee)$dispersion^2
> prederrsqKnee <- stderrKnee^2 + reserrsqKnee
> lower_pi <- predfitKnee - 1.96 * sqrt(prederrsqKnee)
> upper_pi <- predfitKnee + 1.96 * sqrt(prederrsqKnee)
> lower_pi
1 2 3 4 5 6 7 8 9 10 11 12 13
-21223.86 -22303.48 -23438.01 -24630.27 -25883.19 -27199.86 -28583.52 -30037.57 -31565.61 -33171.39 -34858.88 -36632.22 -38495.80
> upper_pi
1 2 3 4 5 6 7 8 9 10 11 12 13
65439.55 68768.16 72266.09 75941.96 79804.81 83864.16 88130.01 92612.86 97323.74 102274.27 107476.62 112943.62 118688.72