Based on the `basque`

dataset and the corresponding example of package `Synth`

, this vignette illustrates the usage of package `MSCMT`

. Thereby, parts of Abadie and Gardeazabal (2003) are reproduced in this example.

The `MSCMT`

package expects its input data to be a `list`

of matrices, where each matrix corresponds to one variable of interest. The column names of the matrices correspond to the names of all units (treated unit and control units) and have to be identical across all elements of the list. The row names correspond to the instants of time where data is available, they may well be different between variables.

Currently, all variables must either contain annual, quarterly or monthly data.^{1} The row names must therefore match one of the following patterns (where `d`

corresponds to a single digit):

`dddd`

for annual dates, e.g.`2016`

,`ddddQd`

for quarterly dates, e.g.`2016Q1`

for the first quarter of 2016,`dddd-dd`

for monthly dates, e.g.`2016-03`

for March 2016.

A list of matrices is a very useful, but quite unusual data format. Therefore, a helper function called `listFromLong`

, which generates a list of matrices from a more common data representation, the so-called ‘long’ format, has been included in package `MSCMT`

. With `listFromLong`

, migrating from the `Synth`

package to `MSCMT`

is simple, because package `Synth`

(more precisely, its `dataprep`

function) expects its input data to be in ‘long’ format.

The `basque`

dataset in package `Synth`

in ‘long’ format has the following structure:

```
## [1] "regionno" "regionname"
## [3] "year" "gdpcap"
## [5] "sec.agriculture" "sec.energy"
## [7] "sec.industry" "sec.construction"
## [9] "sec.services.venta" "sec.services.nonventa"
## [11] "school.illit" "school.prim"
## [13] "school.med" "school.high"
## [15] "school.post.high" "popdens"
## [17] "invest"
```

```
## regionno regionname year gdpcap sec.agriculture
## 703 17 Basque Country (Pais Vasco) 1969 6.081405 5.53
## sec.energy sec.industry sec.construction sec.services.venta
## 703 3.75 45.39 6.45 34.09
## sec.services.nonventa school.illit school.prim school.med school.high
## 703 4.8 43.2716 1093.236 123.8557 30.35246
## school.post.high popdens invest
## 703 15.08178 246.89 26.37294
```

With `listFromLong`

from package `MSCMT`

, the conversion to ‘list’ format is a simple task. The names of the parameters correspond to the names of the parameters for function `dataprep`

of package `Synth`

:

```
library(MSCMT)
Basque <- listFromLong(basque, unit.variable="regionno", time.variable="year", unit.names.variable="regionname")
names(Basque)
```

```
## [1] "gdpcap" "sec.agriculture"
## [3] "sec.energy" "sec.industry"
## [5] "sec.construction" "sec.services.venta"
## [7] "sec.services.nonventa" "school.illit"
## [9] "school.prim" "school.med"
## [11] "school.high" "school.post.high"
## [13] "popdens" "invest"
```

```
## Spain (Espana) Andalucia Aragon Principado De Asturias
## 1955 2.354542 1.688732 2.288775 2.502928
## 1956 2.480149 1.758498 2.445159 2.615538
## 1957 2.603613 1.827621 2.603399 2.725793
## 1958 2.637104 1.852756 2.639032 2.751857
## 1959 2.669880 1.878035 2.677092 2.777421
## 1960 2.869966 2.010140 2.881462 2.967295
## Baleares (Islas) Canarias Cantabria Castilla Y Leon
## 1955 3.143959 1.914382 2.559412 1.729149
## 1956 3.347758 2.071837 2.693873 1.838332
## 1957 3.549629 2.226078 2.820337 1.947658
## 1958 3.642673 2.220866 2.879035 1.971365
## 1959 3.734862 2.213439 2.943730 1.995144
## 1960 4.058841 2.357684 3.137032 2.138817
## Castilla-La Mancha Cataluna Comunidad Valenciana Extremadura Galicia
## 1955 1.327764 3.546630 2.575978 1.243430 1.634676
## 1956 1.415096 3.690446 2.738503 1.332548 1.725578
## 1957 1.503570 3.826835 2.899886 1.422451 1.816481
## 1958 1.531420 3.875678 2.963510 1.440231 1.840903
## 1959 1.559340 3.921737 3.026207 1.458083 1.865396
## 1960 1.667524 4.241788 3.219294 1.535847 1.983290
## Madrid (Comunidad De) Murcia (Region de) Navarra (Comunidad Foral De)
## 1955 4.594473 1.679520 2.555127
## 1956 4.786632 1.764282 2.698158
## 1957 4.963439 1.850328 2.839831
## 1958 4.906170 1.887389 2.881891
## 1959 4.846401 1.924093 2.930877
## 1960 5.161097 2.118609 3.163525
## Basque Country (Pais Vasco) Rioja (La)
## 1955 3.853185 2.390460
## 1956 3.945658 2.535204
## 1957 4.033562 2.680020
## 1958 4.023422 2.726435
## 1959 4.013782 2.772851
## 1960 4.285918 2.969866
```

The ‘list’ representation allows for simple, reproducible data preparations. To reproduce the analysis of Abadie and Gardeazabal (2003), the following preparations are sufficient:

```
# define the sum of all cases
school.sum <- with(Basque,colSums(school.illit + school.prim + school.med + school.high + school.post.high))
# combine school.high and school.post.high in a single class
Basque$school.higher <- Basque$school.high + Basque$school.post.high
# calculate ratios and multiply by number of observations to obtain percentages from totals
for (item in c("school.illit", "school.prim", "school.med", "school.higher"))
Basque[[item]] <- 6 * 100 * t(t(Basque[[item]]) / school.sum)
```

In package `Synth`

, data preparation and model formulation are combined in function `dataprep`

, whereas the estimation is separated from the model formulation. The approach of package `MSCMT`

is different: in order to facilitate the estimation of (potentially many) different models based on the same dataset, the model formulation has been moved to function `mscmt`

, which also does the model estimation.

To allow for the methodological extensions (**Multivariate** Synthetic Control Methods using **Time-Series**), the model syntax had to be made more flexible. A model formulation now consists of

- defining the (single)
^{2}treated unit (single character string, parameter`treatment.identifier`

), - defining the (multiple) control units (vector of character strings, parameter
`controls.identifier`

), - defining one or more dependent variables and the corresponding optimization periods as a
`2 x L`

-matrix (parameter`times.dep`

), where- the column names consist of the names of the
`L`

dependent variables, - the first row contains the starting times of the optimization periods in the appropriate (annual, quarterly, or monthly) format,
- the second row contains the end times of the optimization periods in the appropriate format,

- the column names consist of the names of the
- defining several predictor variables and the corresponding optimization periods as a
`2 x K`

-matrix (parameter`times.pred`

), where- the column names consist of the names of the
`K`

predictor variables, - the first row contains the starting times of the optimization periods in the appropriate (annual, quarterly, or monthly) format,
- the second row contains the end times of the optimization periods in the appropriate format,

- the column names consist of the names of the
- an (optional) vector of the names of
`K`

aggregation functions (parameter`agg.fns`

) for the predictor variables. If missing, all predictor variables are considered to be time series, which corresponds to the function name`"id"`

. Whenever the result of an aggregation function has length exceeding 1, the resulting data is considered as a time series, too.

Note that `times.dep`

and `times.pred`

may contain duplicate column names for further increased flexibility of the model specification.

The following model specification reproduces the model in Abadie and Gardeazabal (2003):

```
treatment.identifier <- "Basque Country (Pais Vasco)"
controls.identifier <- setdiff(colnames(Basque[[1]]),
c(treatment.identifier, "Spain (Espana)"))
times.dep <- cbind("gdpcap" = c(1960,1969))
times.pred <- cbind("school.illit" = c(1964,1969),
"school.prim" = c(1964,1969),
"school.med" = c(1964,1969),
"school.higher" = c(1964,1969),
"invest" = c(1964,1969),
"gdpcap" = c(1960,1969),
"sec.agriculture" = c(1961,1969),
"sec.energy" = c(1961,1969),
"sec.industry" = c(1961,1969),
"sec.construction" = c(1961,1969),
"sec.services.venta" = c(1961,1969),
"sec.services.nonventa" = c(1961,1969),
"popdens" = c(1969,1969))
agg.fns <- rep("mean", ncol(times.pred))
```

After preparing the data and formulating the model, the model estimation is done with function `mscmt`

. Apart from the function parameters concerning data and model specification, there are further parameters which, e.g.,

- control for several aspects of the optimization procedure, including weights for the inner and outer target functions,
- choose and tune the optimizers,
- verbose output,
- initiate placebo studies
- allow to use the computational power of a multi-core cpu or cluster for placebo studies.

A simple estimation (without a placebo study) produces the following console output (if parameter `verbose`

is `TRUE`

, which is the default):

```
## 09:54:25: Number of 'sunny' donors: 16 out of 16
## 09:54:25: Unrestricted outer optimum (obtained by ignoring all predictors)
## 09:54:25: with RMSPE 0.064236669716524 and MSPE (loss v)
## 09:54:25: 0.0041263497362698 is INFEASIBLE when respecting the predictors.
## 09:54:25: Starting optimization via DEoptC, random seed 1.
## 09:54:36: Optimization finished (1122001 calls to inner optimizer), rmspe:
## 09:54:36: 0.0654680949292753, mspe: 0.00428607145366861.
## Final rmspe: 0.06546809, mspe (loss v): 0.004286071
## Optimal weights:
## Baleares (Islas) Cataluna Madrid (Comunidad De)
## 0.2192728 0.6327857 0.1479414
```

Package `MSCMT`

ships with an `S3`

method for `print`

, which gives a nice human-readable summary of the estimation results:

```
## Specification:
## --------------
##
## Model type: SCM
## Treated unit: Basque Country (Pais Vasco)
## Control units: Andalucia, Aragon, Principado De Asturias,
## Baleares (Islas), Canarias, Cantabria, Castilla Y Leon,
## Castilla-La Mancha, Cataluna, Comunidad Valenciana,
## Extremadura, Galicia, Madrid (Comunidad De),
## Murcia (Region de), Navarra (Comunidad Foral De),
## Rioja (La)
## Dependent(s): gdpcap with optimization period from 1960 to 1969
## Predictors:
## school.illit from 1964 to 1969, aggregated via 'mean',
## school.prim from 1964 to 1969, aggregated via 'mean',
## school.med from 1964 to 1969, aggregated via 'mean',
## school.higher from 1964 to 1969, aggregated via 'mean',
## invest from 1964 to 1969, aggregated via 'mean',
## gdpcap from 1960 to 1969, aggregated via 'mean',
## sec.agriculture from 1961 to 1969, aggregated via 'mean',
## sec.energy from 1961 to 1969, aggregated via 'mean',
## sec.industry from 1961 to 1969, aggregated via 'mean',
## sec.construction from 1961 to 1969, aggregated via 'mean',
## sec.services.venta from 1961 to 1969, aggregated via 'mean',
## sec.services.nonventa from 1961 to 1969, aggregated via 'mean',
## popdens from 1969 to 1969, aggregated via 'mean'
##
##
## Results:
## --------
##
## Result type: Ordinary solution, ie. no perfect preditor fit possible
## and the predictors impose some restrictions on the outer
## optimization.
## Optimal W: Baleares (Islas) : 21.92728%,
## Cataluna : 63.27857%,
## Madrid (Comunidad De): 14.79414%
## Dependent loss: MSPE ('loss V'): 0.004286071,
## RMSPE : 0.065468095
## (Optimal) V: Some optimal weight vectors V are:
## min.loss.w max.order
## school.illit.mean.1964.1969 9.998580e-09 1.578398e-05
## school.prim.mean.1964.1969 9.998580e-09 1.578398e-05
## school.med.mean.1964.1969 9.998580e-09 1.578398e-05
## school.higher.mean.1964.1969 9.998580e-09 2.903475e-04
## invest.mean.1964.1969 8.469442e-05 2.990163e-04
## gdpcap.mean.1960.1969 9.998580e-01 9.992528e-01
## sec.agriculture.mean.1961.1969 9.998580e-09 1.578398e-05
## sec.energy.mean.1961.1969 9.998580e-09 1.578398e-05
## sec.industry.mean.1961.1969 9.998580e-09 1.578398e-05
## sec.construction.mean.1961.1969 9.998580e-09 1.578398e-05
## sec.services.venta.mean.1961.1969 9.998580e-09 1.578398e-05
## sec.services.nonventa.mean.1961.1969 5.718465e-05 1.578398e-05
## popdens.mean.1969.1969 9.998580e-09 1.578398e-05
## ----------
## pred. loss 1.139851e-04 3.374961e-04
## (Predictor weights V are standardized by sum(V)=1)
##
```

While there is a basic `S3`

method for `plot`

, it is strongly recommended to use package `ggplot2`

and the corresponding `S3`

method for `ggplot`

contained in package `MSCMT`

. With the results of a simple estimation, two types of plots are available, the first being a comparison of original and synthesized data for the treated unit. The variable to be plotted can be selected with parameter `what`

, by default the (first) dependent variable is being chosen:

The second type of plot is a plot of the gaps, ie. the differences between original and synthesized data:

It is possible to plot several variables by providing a vector for argument `what`

. Pre-defined sets of variables named `"dependents"`

, `"predictors"`

, and `"all"`

can be selected with parameter `what.set`

.

Placebo studies are performed by simply setting the function argument `placebo`

to `TRUE`

. By default, the original treated unit is not added to the donor pool of the (original) control units, but this can be changed with parameter `placebo.with.treated`

.

A remarkable speed-up (depending on the number of control units) can be achieved for placebo studies by making use of a cluster, which can be set up with the help of package `parallel`

. The simplest form of a cluster is a local cluster, which makes the power of multi-core cpus available for the (lengthy) computations involved with placebo studies. Setting up a local cluster is very easy, see the example below.

The argument `cl`

of function `mscmt`

can be used to specify the cluster to be used for placebo studies. The only drawback of using a cluster for placebo studies is losing the verbose output from the individual (one for each unit) SCM estimations, which includes a lack of progress information for the whole placebo study. Nevertheless, the speed-up should compensate for this drawback in all applications where a placebo study is meaningful.

Although clusters should be shut down automatically when the corresponding (master) `R`

process is finished, function `stopCluster`

can (and should) be used to shut down the cluster manually.

In the following example, a (local) cluster with two nodes is used for the estimation.

```
library(parallel)
cl <- makeCluster(2)
resplacebo <- mscmt(Basque, treatment.identifier, controls.identifier, times.dep, times.pred, agg.fns, cl=cl, placebo=TRUE, seed=1)
```

```
## 09:54:38: Starting placebo study, excluding original treated unit, on the
## 09:54:38: cluster. Please hold the line.
## 09:56:18: Placebo study on cluster finished.
```

Object `resplacebo`

now contains single SCM estimations for each unit as well as aggregated information concerning original data, synthesized data, and gaps for all units. The individual SCM estimations can be accessed separately (as list elements with names corresponding to the units’ names). With the following plot, one can inspect whether there is some effect for Catalonia:

Several functions in package `MSCMT`

are able to make use of the results of the placebo study as a whole. One example are so-called placebo plots, by setting the plot type to `"placebo.gaps"`

(the default for results of a placebo study):

For statistical inference based on the results of a placebo study, the literature has developed so-called ‘placebo tests’, which have similarities to permutation tests. Two of these are

- tests for the (per-period) treatment effect based on the per-period gaps,
- tests for the aggregated treatment effect based on a difference-in-difference approach for aggregated (average) gaps.

Most often, not all control units can be synthesized with an acceptable fit in a placebo study, resulting in large pre-treatment gaps. Of course, large post-treatment gaps are expected for these units, but since these gaps are rather caused from lack of fit than from an existing treatment effect, excluding such units is strongly advisable while investigating the effect for the (original) treated unit.

Excluding control units with large pre-treatment errors is usually done by limiting the ratio of a control unit’s pre-treatment (r)mspe to the treated unit’s (r)mspe.

Control units with large pre-treatment errors can easily be excluded from placebo plots:

The p-values of per-period placebo tests can be calculated via function `pvalue`

or plotted via `ggplot`

with `plot.type="p.values"`

:

```
## Time Series:
## Start = 1970
## End = 1997
## Frequency = 1
## [1] 0.07142857 0.14285714 0.07142857 0.07142857 0.14285714 0.42857143
## [7] 0.14285714 0.07142857 0.07142857 0.07142857 0.07142857 0.07142857
## [13] 0.07142857 0.07142857 0.07142857 0.07142857 0.07142857 0.07142857
## [19] 0.07142857 0.07142857 0.07142857 0.07142857 0.07142857 0.07142857
## [25] 0.07142857 0.14285714 0.14285714 0.14285714
```

Calculating the aggregated treatment effect and testing its significance can be done with function `did`

of package `MSCMT`

:

```
## $effect.size
## [1] -0.7715269
##
## $average.pre
## [1] 0.0005933236
##
## $average.post
## [1] -0.7709335
##
## $p.value
## [1] 0.07692308
##
## $rank
## [1] 1
##
## $excluded
## [1] "Baleares (Islas)" "Castilla-La Mancha" "Extremadura"
## [4] "Madrid (Comunidad De)"
```

In this vignette, the basic workflow of preparing the data, defining and estimating the model, and evaluating the results of a (simple) SCM application with package `MSCMT`

has been illustrated.

Many features and options of package `MSCMT`

remained untouched, because this would have led far beyond the scope of this simple example. There are more specialized vignettes which illustrate

- how to check the feasibility of (and potentially improve) the results obtained by function
`synth`

of package`Synth`

, - an application of SCM using time series (SCM
**T**).

In future releases of this package, additional vignettes will (probably) be added to illustrate

- applications of
**M**SCM and**M**SCM**T**, - alternatives for the optimizers and its parameters,
- more functionality of the
`ggplot`

method. - the use of cross-validation, see Becker, Klößner, and Pfeifer (2018).

Abadie, Alberto, and Javier Gardeazabal. 2003. “The Economic Costs of Conflict: A Case Study of the Basque Country.” *The American Economic Review* 93 (1): 113–32. http://dx.doi.org/10.1257/000282803321455188.

Becker, Martin, Stefan Klößner, and Gregor Pfeifer. 2018. “Cross-Validating Synthetic Controls.” *Economics Bulletin* 38: 603–9. http://www.accessecon.com/Pubs/EB/2018/Volume38/EB-18-V38-I1-P58.pdf.