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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.

share|improve this question
    
Are you estimating random slopes and intercepts or just random intercepts? – User7598 Feb 22 '15 at 3:22
    
Please note, your sample code won't work for balanced panels either. You would need 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
    
Thanks. I haven't used the package recently but the info on the development version is useful. We're getting closer to an answer :) – Peter May 27 at 16:56

I found this that can help you, since the lm() solution was not working in my case (I got different coefficients comparing to the plm package)

Therefore, it is just about applying the suggestions by the authors of the plm package here http://r.789695.n4.nabble.com/fitted-from-plm-td3003924.html

So what I did is just to apply

plm.object <- plm(y ~ lag(y, 1) + z +z2, data = mdt, model= "within", effect="twoways")
fitted <- as.numeric(plm.object$model[[1]] - plm.object$residuals) 

where I need the as.numeric function since I need to use it as a vector to plug in for further manipulations. I also want to point out that if your model has a lagged dependent variable on the right hand side, the solution above with as.numeric provides a vector already NET of the missing values because of the lag. For me this is exactly what I needed to.

share|improve this answer
    
Hello Bob, thank you for your answer. It does not address what I needed though. I have used something identical to what you suggest (probably after reading the thread you linked to). What I wanted to do was to generate the estimates using only the independent variables and the estimated coefficients (incl. time/id effects). Something similar to what I added as an example with lm(). – Peter Apr 26 '15 at 8:50
    
This is what I wanted to do as well but I did not manage to. Also using your approach with lm() I get different estimates from the plm model – Bob Apr 27 '15 at 9:55

Is this what you wanted? Extract the fixed effects by fixef and match them to the individual index. Here is an example for the Grunfeld data:

data(Grunfeld, package = "plm")
fe <- plm(inv ~ value + capital, data=Grunfeld, model = "within")

temp <- merge(Grunfeld, data.frame(fixef_firm = names(fixef(fe)), fixef = as.numeric(fixef(fe))), all.x =T, by.x = c("firm"), by.y=c("fixef_firm"))
fitted_by_hand <- temp$fixef + fe$coefficients[1] * Grunfeld$value +  fe$coefficients[2] * Grunfeld$capital

fitted <- fe$model[ , 1] - fe$residuals

# just to remove attributs and specific classes 
fitted_by_hand <- as.numeric(fitted_by_hand)
fitted <- as.numeric(fitted)

all.equal(fitted, fitted_by_hand) # TRUE
cbind(fitted, fitted_by_hand) # see yourself
share|improve this answer
    
Hi, and thanks for posting. Your code works, but in essence it is just a subset in the code in my original question -- (1) deals with a balanced dataset, and (2) has only one effect, "individual". If you can get it to work with both time & individual effects and an unbalanced dataset (e.g. drop a row from Grunfeld), I'd be quite happy to accept it as an answer. – Peter Nov 13 '15 at 10:57

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