# Xgboost tweedie: Why is the formula to get the prediction from the link = exp(link)/ 2?

This is a somewhat niche question, but I really don't get it.

When I run a Tweedie GLM, one can get the prediction from the link by doing exp(link). To get the prediction for a Tweedie GLM, I get the prediction from the link by doing exp(link)/2. I don't understand why I need to divide by 2.

Minimal reproducible example below, inspired from the tweedie regression demo at https://github.com/dmlc/xgboost/blob/master/R-package/demo/tweedie_regression.R

``````library(xgboost)
library(data.table)
library(cplm) # for insurance data
library(statmod) # for tweedie glm
data(AutoClaim)

# auto insurance dataset analyzed by Yip and Yau (2005)
dt <- data.table(AutoClaim)

# exclude these columns from the model matrix
exclude <-  c('POLICYNO', 'PLCYDATE', 'CLM_FREQ5', 'CLM_AMT5', 'CLM_FLAG', 'IN_YY')

# retains the missing values
# NOTE: this dataset is comes ready out of the box
options(na.action = 'na.pass')
x <- sparse.model.matrix(~ . - 1, data = dt[, -exclude, with = F])
options(na.action = 'na.omit')

# response
y <- dt[, CLM_AMT5]

d_train <- xgb.DMatrix(data = x, label = y, missing = NA)

# the tweedie_variance_power parameter determines the shape of
# distribution
# - closer to 1 is more poisson like and the mass
#   is more concentrated near zero
# - closer to 2 is more gamma like and the mass spreads to the
#   the right with less concentration near zero

params <- list(
objective = 'reg:tweedie',
eval_metric = 'rmse',
tweedie_variance_power = 1.4,
max_depth = 2,
eta = 1)
set.seed(42)
bst <- xgb.train(
data = d_train,
params = params,
maximize = FALSE,
watchlist = list(train = d_train),
nrounds = 3)

xgb.plot.tree(model = bst)
```

# Manually extract the values for the first record :
x[1,]

# travtime < 102, bluebook <61645 -->tree #1 value= 2.49922585
# revolkedyes <  -9.53674316e-07,   npolicy < 5.5 --> tree #2  value= 2.48586464
# REVOLKEDYes <  -9.53674316e-07, areaurban >  -9.53674316e-07 --> tree #2 vakye =  2.36028123

# Take exp(link_gbm), divide by 2
exp(link_gbm ) / 2 # 774.5053

# Compare with getting prediction directly from GBM.

predict(bst, d_train) # 774.5053

# Let's do the same with a GLM:
dt2 <-  dt[, -exclude, with = F]
dt2\$CLM_AMT5 <-  dt\$CLM_AMT5

tweedie_fit <-
glm(CLM_AMT5 ~ .,
data = dt2)

summary(tweedie_fit)
# Manually get the link value for the first record

dt2[1,]
14 * tweedie_fit\$coefficients["TRAVTIME"] +
14230 * tweedie_fit\$coefficients["BLUEBOOK"] +
11 * tweedie_fit\$coefficients["RETAINED"]  +
1 * tweedie_fit\$coefficients["NPOLICY"] +
1 * tweedie_fit\$coefficients["CAR_TYPESedan"] +
1 * tweedie_fit\$coefficients["RED_CARyes"] +
3 * tweedie_fit\$coefficients["MVR_PTS"] +
60 * tweedie_fit\$coefficients["AGE"] +
11 * tweedie_fit\$coefficients["YOJ"] +
67349 * tweedie_fit\$coefficients["INCOME"] +
1 * tweedie_fit\$coefficients["GENDERM"] +
1 * tweedie_fit\$coefficients["JOBCLASSProfessional"] +
1 * tweedie_fit\$coefficients["MAX_EDUCPhD"] +
18 * tweedie_fit\$coefficients["SAMEHOME"] +
1 * tweedie_fit\$coefficients["AREAUrban"]