**Please note: I am trying to get the code to work with both time & individual fixed effects, and an unbalanced dataset. The sample code below works with a balanced dataset.**

**See edit below too, please**

I am trying to manually calculate the fitted values of a fixed effects model (with both individual and time effects) using the `plm`

package. This is more of an exercise to confirm I understand the mechanics of the model and the package, I know I can get the fitted values themselves from the `plm`

object, from the two related questions (here and here).

From the `plm`

vignette (p.2), the underlying model is:

**y**_it = **alpha** + **beta**_transposed * **x**_it + (**mu**_i + **lambda**_t + **epsilon**_it)

where mu_i is the individual component of the error term (a.k.a. "individual effect"), and lambda_t is the "time effect".

The fixed effects can be extracted by using `fixef()`

and I thought I could use them (together with the independent variables) to calculate the fitted values for the model, using (with two independent variables) in this way:

**fit**_it = **alpha** + **beta**_1 * **x1** + **beta**_2 * **x2** + **mu**_i + **lambda**_t

This is where I fail -- the values I get are nowhere near the fitted values (which I get as the difference between the actual values and the residuals in the model object). For one, I do not see `alpha`

anywhere. I tried playing with the fixed effects being shown as differences from the first, from the mean, etc., with no success.

What I am missing? It could well be a misunderstanding of the model, or an error in the code, I am afraid... Thanks in advance.

PS: One of the related questions hints that `pmodel.response()`

should be related to my issue (and the reason there is no `plm.fit`

function), but its help page does not help me understand what this function actually does, and I cannot find any examples how to interpret the result it produces.

Thanks!

Sample code of what I did:

```
library(data.table); library(plm)
set.seed(100)
DT <- data.table(CJ(id=c("a","b","c","d"), time=c(1:10)))
DT[, x1:=rnorm(40)]
DT[, x2:=rnorm(40)]
DT[, y:=x1 + 2*x2 + rnorm(40)/10]
DT <- DT[!(id=="a" & time==4)] # just to make it an unbalanced panel
setkey(DT, id, time)
summary(plmFEit <- plm(data=DT, id=c("id","time"), formula=y ~ x1 + x2, model="within", effect="twoways"))
# Extract the fitted values from the plm object
FV <- data.table(plmFEit$model, residuals=as.numeric(plmFEit$residuals))
FV[, y := as.numeric(y)]
FV[, x1 := as.numeric(x1)]
FV[, x2 := as.numeric(x2)]
DT <- merge(x=DT, y=FV, by=c("y","x1","x2"), all=TRUE)
DT[, fitted.plm := as.numeric(y) - as.numeric(residuals)]
FEI <- data.table(as.matrix(fixef(object=plmFEit, effect="individual", type="level")), keep.rownames=TRUE) # as.matrix needed to preserve the names?
setnames(FEI, c("id","fei"))
setkey(FEI, id)
setkey(DT, id)
DT <- DT[FEI] # merge the fei into the data, each id gets a single number for every row
FET <- data.table(as.matrix(fixef(object=plmFEit, effect="time", type="level")), keep.rownames=TRUE) # as.matrix needed to preserve the names?
setnames(FET, c("time","fet"))
FET[, time := as.integer(time)] # fixef returns time as character
setkey(FET, time)
setkey(DT, time)
DT <- DT[FET] # merge the fet into the data, each time gets a single number for every row
# calculate the fitted values (called calc to distinguish from those from plm)
DT[, fitted.calc := as.numeric(coef(plmFEit)[1] * x1 + coef(plmFEit)[2]*x2 + fei + fet)]
DT[, diff := as.numeric(fitted.plm - fitted.calc)]
all.equal(DT$fitted.plm, DT$fitted.calc)
```

My session is as follows:

```
R version 3.2.2 (2015-08-14)
Platform: x86_64-w64-mingw32/x64 (64-bit)
Running under: Windows 8 x64 (build 9200)
locale:
[1] LC_COLLATE=English_United States.1252 LC_CTYPE=English_United States.1252 LC_MONETARY=English_United States.1252 LC_NUMERIC=C
[5] LC_TIME=English_United States.1252
attached base packages:
[1] stats graphics grDevices utils datasets methods base
other attached packages:
[1] plm_1.4-0 Formula_1.2-1 RJSONIO_1.3-0 jsonlite_0.9.17 readxl_0.1.0.9000 data.table_1.9.7 bit64_0.9-5 bit_1.1-12 RevoUtilsMath_3.2.2
loaded via a namespace (and not attached):
[1] bdsmatrix_1.3-2 Rcpp_0.12.1 lattice_0.20-33 zoo_1.7-12 MASS_7.3-44 grid_3.2.2 chron_2.3-47 nlme_3.1-122 curl_0.9.3 rstudioapi_0.3.1 sandwich_2.3-4
[12] tools_3.2.2
```

**Edit: (2015-02-22)**
Since this has attracted some interest, I will try to clarify further. I was trying to fit a "fixed effects" model (a.k.a. "within" or "least squares dummy variables", as the plm package vignette calls it on p.3, top paragraph) -- same slope(s), different intercepts.

This is the same as running an ordinary OLS regression after adding dummies for `time`

and `id`

. Using the code below I can duplicate the fitted values from the `plm`

package using base `lm()`

. With the dummies, it is explicit that the first elements of both id and time are the group to compare to. What I still cannot do is how to use the facilities of the `plm`

package to do the same I can easily accomplish using `lm()`

.

```
# fit the same with lm() and match the fitted values to those from plm()
lmF <- lm(data = DT, formula = y ~ x1 + x2 + factor(time) + factor(id))
time.lm <- coef(lmF)[grep(x = names(coef(lmF)), pattern = "time", fixed = TRUE)]
time.lm <- c(0, unname(time.lm)) # no need for names, the position index corresponds to time
id.lm <- coef(lmF)[grep(x = names(coef(lmF)), pattern = "id", fixed = TRUE)]
id.lm <- c(0, unname(id.lm))
names(id.lm) <- c("a","b","c","d") # set names so that individual values can be looked up below when generating the fit
DT[, by=list(id, time), fitted.lm := coef(lmF)[["(Intercept)"]] + coef(lmF)[["x1"]] * x1 + coef(lmF)[["x2"]] * x2 + time.lm[[time]] + id.lm[[id]]]
all.equal(DT$fitted.plm, DT$fitted.lm)
```

Hope this is useful to others who might be interested. The issue might be something about how `plm`

and `fixef`

deal with the missing value I intentionally created. I tried playing with the `type=`

parameter of `fixef`

but to no effect.

`DT[, fitted.calc := as.numeric(coef(plmFEit)[1] * x1 + coef(plmFEit)[2]*x2 + fei + fet - within_intercept(plmFEit))]`

to get the same values.`within_intercept`

(currently, only in the dev version of plm) gives the overall (artifical) intercept of the FE model. Here, it accounts for the shared id/time effect. – Helix123 May 26 at 16:10