Matrices are important mathematical objects, and they often describe networks of flows among nodes. Example networks are given in the following table.
System type | Flows | Nodes |
---|---|---|
Ecological | nutrients | organisms |
Manufacturing | materials | factories |
Economic | money | economic sectors |
The power of matrices lies in their ability to organize network-wide calculations, thereby simplifying the work of analysts who study entire systems.
But wouldn’t it
be nice if there were an easy way to create R
data
frames whose entries were not numbers but entire matrices? If that were
possible, matrix algebra could be performed on columns of similar
matrices.
That’s the reason for matsindf
. It provides functions to
convert a suitably-formatted tidy data
frame into a data frame containing a column of matrices.
Furthermore, matsbyname
is a sister package that
dimnames
in R
) to free the
analyst from the task of aligning rows and columns of operands
(matrices) passed to matrix algebra functions andWhen used together, matsindf
and matsbyname
allow analysts to wield simultaneously the power of both matrix
mathematics and tidyverse
functional programming.
This vignette demonstrates the use of these packages and suggests a
workflow to accomplish sophisticated analyses using matrices in data
frames (matsindf
).
UKEnergy2000
To demonstrate the use of matsindf
functions, consider a
network of energy flows from the environment, through transformation and
distribution processes, and, ultimately, to final demand. Such energy
flow networks are called energy conversion chains (ECCs), and this
example is based on an approximation to a portion of the UK’s ECC circa
2000. (Note that these data are to be used for demonstration purposes
only and have been rounded to 1–2 significant digits.) These example
data first appeared in Figures 3 and 4 of Heun, Owen, and Brockway (2018).
head(UKEnergy2000, 2)
#> Country Year Ledger.side Flow.aggregation.point Flow
#> 1 GB 2000 Supply Total primary energy supply Resources - Crude
#> 2 GB 2000 Supply Total primary energy supply Resources - NG
#> Product E.ktoe
#> 1 Crude 50000
#> 2 NG 43000
Country
and Year
contain only one value
each, GB
and 2000
respectively. Following
conventions of the International Energy
Agency’s energy
balance tables,
Ledger.side
indicates Supply
or
Consumption
;Flow.aggregation.point
indicates how data are to be
aggregated;Flow
indicates the industry, machine, or final demand
sector for this flow;Product
indicates the energy carrier for this flow;
andE.ktoe
gives the magnitude of this flow in units
of kilotons of oil equivalent (ktoe).Each flow is its own observation (its own row) in the
UKEnergy2000
data frame, making it tidy.
The remainder of this vignette demonstrates an analysis conducted
using the UKEnergy2000
data frame as a basis. It:
matsbyname
functions,The EnergyUK2000
data frame is similar to “cleaned” data
from an external source: there are no missing entries, and it is tidy. But
the data are not organized as matrices, and additional metadata is
needed.
The collapse_to_matrices
function converts a tidy data
frame into a matsindf
data frame using using information
within the tidy data frame. So the first task is to prepare for
collapse by adding metadata columns.
collapse_to_matrices
needs the following
information:
argument to collapse_to_matrices |
identifies |
---|---|
matnames |
Name of the input column of matrix names |
values |
Name of the input column of matrix entries |
rownames |
Name of the input column of matrix row names |
colnames |
Name of the input column of matrix column name |
rowtypes |
Optional name of the input column of matrix row types |
coltypes |
Optional name of the input column of matrix column types |
The following code gives the approach to adding metadata, appropriate
for this application, relying on Ledger.side
, the sign of
E.ktoe
, and knowledge about the rows and columns for each
matrix. Each type of network will have its own algorithm for identifying
row names, column names, row types, and column types in a tidy data
frame.
UKEnergy2000_with_metadata <- UKEnergy2000 %>%
# Add a column indicating the matrix in which this entry belongs (U, V, or Y).
matsindf:::add_UKEnergy2000_matnames() %>%
# Add columns for row names, column names, row types, and column types.
matsindf:::add_UKEnergy2000_row_col_meta() %>%
mutate(
# Eliminate columns we no longer need
Ledger.side = NULL,
Flow.aggregation.point = NULL,
Flow = NULL,
Product = NULL,
# Ensure that all energy values are positive, as required for analysis.
E.ktoe = abs(E.ktoe)
)
head(UKEnergy2000_with_metadata, 2)
#> Country Year E.ktoe matname rowname colname rowtype coltype
#> 1 GB 2000 50000 V Resources - Crude Crude Industry Product
#> 2 GB 2000 43000 V Resources - NG NG Industry Product
With the metadata now in place,
UKEnergy2000_with_metadata
can be collapsed to a
matsindf
data frame by the
collapse_to_matrices
function. Much like
dplyr::summarise
, collapse_to_matrices
relies
on grouping to indicate which rows of the tidy data frame belong to
which matrices. The usual approach is to tidyr::group_by
the matnames
column and any other columns to be preserved
in the output, in this case Country
and
Year
.
EnergyMats_2000 <- UKEnergy2000_with_metadata %>%
group_by(Country, Year, matname) %>%
collapse_to_matrices(matnames = "matname", matvals = "E.ktoe",
rownames = "rowname", colnames = "colname",
rowtypes = "rowtype", coltypes = "coltype") %>%
rename(matrix.name = matname, matrix = E.ktoe)
# The remaining columns are Country, Year, matrix.name, and matrix
glimpse(EnergyMats_2000)
#> Rows: 3
#> Columns: 4
#> $ Country <chr> "GB", "GB", "GB"
#> $ Year <int> 2000, 2000, 2000
#> $ matrix.name <chr> "U", "V", "Y"
#> $ matrix <list> <<matrix[11 x 9]>>, <<matrix[11 x 12]>>, <<matrix[4 x 2]>>
# To access one of the matrices, try one of these approaches:
(EnergyMats_2000 %>% filter(matrix.name == "U"))[["matrix"]] # The U matrix
#> [[1]]
#> Oil fields Oil refineries Crude dist. Diesel dist.
#> Crude 50000 0 0 0
#> Crude - Dist. 0 47000 0 0
#> Crude - Fields 0 0 47500 0
#> Diesel 0 0 0 15500
#> Diesel - Dist. 50 0 25 0
#> Elect 0 0 0 0
#> Elect - Grid 25 75 25 0
#> NG 0 0 0 0
#> NG - Dist. 0 0 0 0
#> NG - Wells 0 0 0 0
#> Petrol 0 0 0 0
#> Gas wells & proc. NG dist. Petrol dist. Elect. grid Power plants
#> Crude 0 0 0 0 0
#> Crude - Dist. 0 0 0 0 0
#> Crude - Fields 0 0 0 0 0
#> Diesel 0 0 0 0 0
#> Diesel - Dist. 50 25 250 0 0
#> Elect 0 0 0 6400 0
#> Elect - Grid 25 25 0 0 100
#> NG 43000 0 0 0 0
#> NG - Dist. 0 0 0 0 16000
#> NG - Wells 0 41000 0 0 0
#> Petrol 0 0 26500 0 0
#> attr(,"rowtype")
#> [1] "Product"
#> attr(,"coltype")
#> [1] "Industry"
EnergyMats_2000$matrix[[2]] # The V matrix
#> Crude - Dist. Diesel - Dist. Elect - Grid NG - Wells
#> Crude dist. 47000 0 0 0
#> Diesel dist. 0 15150 0 0
#> Elect. grid 0 0 6275 0
#> Gas wells & proc. 0 0 0 41000
#> NG dist. 0 0 0 0
#> Oil fields 0 0 0 0
#> Oil refineries 0 0 0 0
#> Petrol dist. 0 0 0 0
#> Power plants 0 0 0 0
#> Resources - Crude 0 0 0 0
#> Resources - NG 0 0 0 0
#> NG - Dist. Crude - Fields Diesel Petrol Petrol - Dist. Elect
#> Crude dist. 0 0 0 0 0 0
#> Diesel dist. 0 0 0 0 0 0
#> Elect. grid 0 0 0 0 0 0
#> Gas wells & proc. 0 0 0 0 0 0
#> NG dist. 41000 0 0 0 0 0
#> Oil fields 0 47500 0 0 0 0
#> Oil refineries 0 0 15500 26500 0 0
#> Petrol dist. 0 0 0 0 26000 0
#> Power plants 0 0 0 0 0 6400
#> Resources - Crude 0 0 0 0 0 0
#> Resources - NG 0 0 0 0 0 0
#> Crude NG
#> Crude dist. 0 0
#> Diesel dist. 0 0
#> Elect. grid 0 0
#> Gas wells & proc. 0 0
#> NG dist. 0 0
#> Oil fields 0 0
#> Oil refineries 0 0
#> Petrol dist. 0 0
#> Power plants 0 0
#> Resources - Crude 50000 0
#> Resources - NG 0 43000
#> attr(,"rowtype")
#> [1] "Industry"
#> attr(,"coltype")
#> [1] "Product"
EnergyMats_2000$matrix[[3]] # The Y matrix
#> Transport Residential
#> Diesel - Dist. 14750 0
#> Elect - Grid 0 6000
#> NG - Dist. 0 25000
#> Petrol - Dist. 26000 0
#> attr(,"rowtype")
#> [1] "Product"
#> attr(,"coltype")
#> [1] "Sector"
Larger studies will include data for multiple countries and years.
The ECC data from UK in year 2000
can be duplicated for
2001
and for a fictitious country AB
. Although
the data are unchanged, the additional rows serve to illustrate the
functional programming aspects of the matsindf
and
matsbyname
packages.
Energy <- EnergyMats_2000 %>%
# Create rows for a fictitious country "AB".
# Although the rows for "AB" are same as the "GB" rows,
# they serve to illustrate functional programming with matsindf.
rbind(EnergyMats_2000 %>% mutate(Country = "AB")) %>%
spread(key = Year, value = matrix) %>%
mutate(
# Create a column for a second year (2001).
`2001` = `2000`
) %>%
gather(key = Year, value = matrix, `2000`, `2001`) %>%
# Now spread to put each matrix in a column.
spread(key = matrix.name, value = matrix)
glimpse(Energy)
#> Rows: 4
#> Columns: 5
#> $ Country <chr> "AB", "AB", "GB", "GB"
#> $ Year <chr> "2000", "2001", "2000", "2001"
#> $ U <list> <<matrix[11 x 9]>>, <<matrix[11 x 9]>>, <<matrix[11 x 9]>>, <<…
#> $ V <list> <<matrix[11 x 12]>>, <<matrix[11 x 12]>>, <<matrix[11 x 12]>>,…
#> $ Y <list> <<matrix[4 x 2]>>, <<matrix[4 x 2]>>, <<matrix[4 x 2]>>, <<ma…
An important step in any analysis is data verification. For an ECC analysis, it is important to verify that energy is conserved (i.e., energy is in balance) across all industries. Equations 1 and 2 in Heun, Owen, and Brockway (2018) show that energy balance is verified by
\[\mathbf{W} = \mathbf{V}^\mathrm{T} - \mathbf{U},\]
and
\[\mathbf{W}\mathbf{i} - \mathbf{Y}\mathbf{i} = \mathbf{0}.\]
Energy balance verification can be implemented with
matsbyname
functions and tidyverse
functional
programming:
Check <- Energy %>%
mutate(
W = difference_byname(transpose_byname(V), U),
# Need to change column name and type on y so it can be subtracted from row sums of W
err = difference_byname(rowsums_byname(W),
rowsums_byname(Y) %>%
setcolnames_byname("Industry") %>% setcoltype("Industry")),
EBalOK = iszero_byname(err)
)
Check %>% select(Country, Year, EBalOK)
#> Country Year EBalOK
#> 1 AB 2000 TRUE
#> 2 AB 2001 TRUE
#> 3 GB 2000 TRUE
#> 4 GB 2001 TRUE
all(Check$EBalOK %>% as.logical())
#> [1] TRUE
This example demonstrates that energy balance can be verified for
all combinations of Country and Year with a few lines of code.
In fact, the exact same code can be applied to the Energy
data frame, regardless of the number of rows in it.
Secure in the knowledge that energy is conserved across all ECCs in
the Energy
data frame, other analyses can proceed.
To further illustrate the power of matsbyname
functions
in the context of matsindf
, consider the calculation of the
efficiency of every industry in the ECC as column vector \(\eta\) as shown by Equation 11 of Heun,
Owen, and Brockway (2018).
\[\mathbf{g} = \mathbf{V}\mathbf{i}\]
\[\mathbf{\eta} = \widehat{\mathbf{U}^\mathrm{T} \mathbf{i}}^{\mathrm{-}1} \mathbf{g}\]
Etas <- Energy %>%
mutate(
g = rowsums_byname(V),
eta = transpose_byname(U) %>% rowsums_byname() %>%
hatize_byname(keep = "rownames") %>% invert_byname() %>%
matrixproduct_byname(g) %>%
setcolnames_byname("eta") %>% setcoltype("Efficiency")
) %>%
select(Country, Year, eta)
Etas$eta[[1]]
#> eta
#> Crude dist. 0.9884332
#> Diesel dist. 0.9774194
#> Elect. grid 0.9804688
#> Gas wells & proc. 0.9518282
#> NG dist. 0.9987820
#> Oil fields 0.9485771
#> Oil refineries 0.8921933
#> Petrol dist. 0.9719626
#> Power plants 0.3975155
#> attr(,"rowtype")
#> [1] "Industry"
#> attr(,"coltype")
#> [1] "Efficiency"
Note that only a few lines of code are required to perform the same
series of matrix operations on every combination of Country
and Year
. In fact, the same code will be used to calculate
the efficiency of any number of industries in any number of countries
and years!
Plotting values from a matsindf
data frame can be
accomplished by expanding the matrices of the
matsindf
data frame (in this example, Etas
)
back out to a tidy data frame. Expanding is the reverse of
collapse-ing, and the following information must be supplied to
the expand_to_tidy
function:
argument to expand_to_tidy |
identifies |
---|---|
matnames |
Name of the input column of matrix names |
matvals |
Name of the input column of matrices to be expanded |
rownames |
Name of the output column of matrix row names |
colnames |
Name of the output column of matrix column name |
rowtypes |
Optional name of the output column of matrix row types |
coltypes |
Optional name of the output column of matrix column types |
drop |
Optional value to be dropped from output (often 0) |
Prior to expand
ing, it is usually necessary to
gather
columns of matrices.
etas_forgraphing <- Etas %>%
gather(key = matrix.names, value = matrix, eta) %>%
expand_to_tidy(matnames = "matrix.names", matvals = "matrix",
rownames = "Industry", colnames = "etas",
rowtypes = "rowtype", coltypes = "Efficiencies") %>%
mutate(
# Eliminate columns we no longer need.
matrix.names = NULL,
etas = NULL,
rowtype = NULL,
Efficiencies = NULL
) %>%
rename(
eta = matrix
)
# Compare to Figure 8 of Heun, Owen, and Brockway (2018)
etas_forgraphing %>% filter(Country == "GB", Year == 2000)
#> # A tibble: 9 × 4
#> Country Year Industry eta
#> <chr> <chr> <chr> <dbl>
#> 1 GB 2000 Crude dist. 0.988
#> 2 GB 2000 Diesel dist. 0.977
#> 3 GB 2000 Elect. grid 0.980
#> 4 GB 2000 Gas wells & proc. 0.952
#> 5 GB 2000 NG dist. 0.999
#> 6 GB 2000 Oil fields 0.949
#> 7 GB 2000 Oil refineries 0.892
#> 8 GB 2000 Petrol dist. 0.972
#> 9 GB 2000 Power plants 0.398
etas_forgraphing
is a data frame of efficiencies, one
for each Country, Year, and Industry, in a format that is amenable to
plotting with packages such as ggplot.
The following code creates a bar graph of efficiency results for the UK in 2000:
etas_UK_2000 <- etas_forgraphing %>% filter(Country == "GB", Year == 2000)
etas_UK_2000 %>%
ggplot(mapping = aes_string(x = "Industry", y = "eta",
fill = "Industry", colour = "Industry")) +
geom_bar(stat = "identity") +
labs(x = NULL, y = expression(eta[UK*","*2000]), fill = NULL) +
scale_y_continuous(breaks = seq(0, 1, by = 0.2)) +
scale_fill_manual(values = rep("white", nrow(etas_UK_2000))) +
scale_colour_manual(values = rep("gray20", nrow(etas_UK_2000))) +
guides(fill = FALSE, colour = FALSE) +
theme(axis.text.x = element_text(angle = 90, vjust = 0.4, hjust = 1))
#> Warning: `aes_string()` was deprecated in ggplot2 3.0.0.
#> ℹ Please use tidy evaluation idioms with `aes()`.
#> ℹ See also `vignette("ggplot2-in-packages")` for more information.
#> This warning is displayed once every 8 hours.
#> Call `lifecycle::last_lifecycle_warnings()` to see where this warning was
#> generated.
#> Warning: The `<scale>` argument of `guides()` cannot be `FALSE`. Use "none" instead as
#> of ggplot2 3.3.4.
#> This warning is displayed once every 8 hours.
#> Call `lifecycle::last_lifecycle_warnings()` to see where this warning was
#> generated.
This vignette demonstrated the use of the matsindf
and
matsbyname
packages and suggested a workflow to accomplish
sophisticated analyses using matrices in data frames
(matsindf
).
The workflow is as follows:
UKEnergy2000
above.collapse_to_matrices
to create a data frame of
matrices with columns for matrix names and matrices themselves, similar
to EnergyMats_2000
above.tidyr::spread
the matrices to obtain a data frame with
columns for each matrix, similar to Energy
above.Check
above.matsbyname
functions in a manner similar to the process of
generating the Etas
data frame above.tidyr::gather
the columns to obtain a tidy data frame
of matrices.expand_to_tidy
to create a tidy data frame of
matrix elements, similar to etas_forgraphing
above.Data frames of matrices, such as those created by
matsindf
, are like magic spreadsheets in which single cells
contain entire matrices. With this data structure, analysts can wield
simultaneously the power of both matrix
mathematics and tidyverse
functional programming.