Using the ExPanD Notebook function

Exporting a Notebook from within ExPanD

When you start ExPanD with the parameter export_nb_option = TRUE, you can export an R notebook containing the current state of your analysis from within the ExPanD app. Let’s see how that works and what the notebook has to offer. First, start ExPanD with the included panel data on U.S. corporations and the option to export notebooks.

library(ExPanDaR)

ExPanD(df = russell_3000,  
       df_def = russell_3000_data_def, 
       df_name = "Russell 3000",
       config_list = ExPanD_config_russell_3000,
       export_nb_option = TRUE)

Next, after scrolling to the bottom of the page and clicking on the button below,

you should be rewarded with a file download dialog, asking you to store a file named ExPanD_nb.zip. Store and unzip it wherever you like. It contains two files

  • A notebook file ExPanD_nb_code.Rmd and
  • a data file ExPanD_nb_data.RData containing data and variable definitions.

Exploring the Notebook Code

Use RStudio to open the notebook file. You can directly knit it (Preview/Knit to HTML) but in order to work with and extend it, it is useful to take a deeper look at its code first. The first chunk silently loads required libraries and sets some knitting defaults. The second chunk is more interesting:

create_sample <- function(df, df_def) {
  # Set infinite numerical variables to NA
  df[, df_def$var_name[df_def$type == "numeric"]] <-
    lapply(df[, df_def$var_name[df_def$type == "numeric"]],
      function(x) ifelse(is.finite(x), x, NA))
 
  # Delete numerical variables that only contain NAs
  all_na_vars <- sapply(df, function (x) all(is.na(x)))
  df_def <- df_def[!all_na_vars,]
  df <- df[, df_def$var_name]
 
  # Drop observations that are NA in variables that are not allowed to
  df <- df[complete.cases(df[, df_def$var_name[which(df_def$can_be_na == FALSE)]]), ]
 
  # Outlier treatment as requested in ExPanD()
  nums <- df_def$var_name[df_def$type == "numeric"]
  df[, nums] <- treat_outliers(df[, nums], 0.01, FALSE, NULL)
 
  df <- droplevels(df)
  return(list(df = df, df_def = df_def))
}
 
load("ExPanD_nb_data.Rdata")
 
smp_list <- create_sample(nb_df, nb_df_def)
smp <- smp_list$df
smp_def <- smp_list$df_def

If you are not that familiar yet with R, the above might look a little bit intimidating. Let’s explore it step by step. The first large part of the code, starting with create_sample and ending several lines later with the closing curly bracket on a separate line defines a function. A function is a block of code that can take parameters and returns an object. The function is named create_sample and that is what it does: It creates the sample that is being used in the analysis further below. You see that the function is being called after loading the data with the command create_sample(nb_df, nb_df_def). Let’s look at the data that is passed on to the function before exploring what the function does in detail. After loading "ExPanD_nb_data.Rdata", you have the data frames nb_df and nb_df_def in your environment. The first contains the raw data for the analysis in long format. See:

kable(head(nb_df[, 1:7]), row.names = FALSE)
coid period coname sector industry toas sales
A FY2013 Agilent Technologies, Inc. Capital Goods Biotechnology: Laboratory Analytical Instruments 10686 3894
A FY2014 Agilent Technologies, Inc. Capital Goods Biotechnology: Laboratory Analytical Instruments 10815 4048
A FY2015 Agilent Technologies, Inc. Capital Goods Biotechnology: Laboratory Analytical Instruments 7479 4038
A FY2016 Agilent Technologies, Inc. Capital Goods Biotechnology: Laboratory Analytical Instruments 7794 4202
AA FY2014 Alcoa Corporation Capital Goods Metal Fabrications 18680 13147
AA FY2015 Alcoa Corporation Capital Goods Metal Fabrications 16413 11199

What is the second data frame for? Let’s have a peak:

kable(nb_df_def, row.names = FALSE) 
var_name var_def type can_be_na
coid Company identifier cs_id FALSE
period Fiscal year ts_id FALSE
coname Company name cs_id FALSE
sector Sector factor TRUE
industry Industry factor TRUE
toas Total assets at period end (M US-$) numeric TRUE
sales Sales of the period (M US-$) numeric TRUE
equity Total equity at period end (M US-$) numeric TRUE
debt_ta Total debt (% total assets) numeric TRUE
eq_ta Total equity (% total assets) numeric TRUE
gw_ta Goodwill (% total assets) numeric TRUE
oint_ta Other intangible assets (% total assets) numeric TRUE
ppe_ta Property, plant and equipment (% total assets) numeric TRUE
ca_ta Current assets (% total assets) numeric TRUE
cash_ta Cash (% total assets) numeric TRUE
roe Return on equity (net income divided by average equity) numeric TRUE
roa Return on assets (earnings before interest and taxes divided by average equity) numeric TRUE
nioa Net income divided by average assets numeric TRUE
cfoa Cash flow from operations divided by average assets numeric TRUE
accoa Total accruals divided by average assets numeric TRUE
cogs_sales Cost of goods sold divided by sales numeric TRUE
ebit_sales Earnings before interest and taxes divided by sales numeric TRUE
ni_sales Net income divided by sales numeric TRUE
return Stock return of the period (%) numeric TRUE

So this data frame contains variable definitions and defines how ExPanD should treat the variables. type indicates the cross-sectional (cs_id) and time series (ts_id) identifiers as well as whether the variables should be understood as numeric, logical or as a factor. can_be_na indicates whether ExPanD should require the variable to be not NA. If can_be_na is set to FALSE for a variable and its data is missing for a certain observation then ExPanD drops the whole observation (the row of the data frame) from the analysis.

The function create_sample now uses both data frames to prepare the sample for the analysis. It first sets all non finite numerical values to NA. Next, it checks whether any variables contain only NA observations and, if such variables are present in the data frame, it deletes them. After that, observations with NA values for variables that have set can_be_na = FALSE are deleted. Last, the outlier treatment as specified in the ExPanD app is applied to the data by calling the ExPanDaR function treat_outliers(). The default configuration that you used when calling ExPanD specified that the data should be winsorized at the top and bottom 1% percentile, meaning that values above the top 1% or below the bottom 1% will be set to the respective percentiles.

After these data preparation steps the modified data frames containing the data and its definitions are returned to the user, wrapped into a list object. The last two commands store these data frames into smp and smp_def. The remaining code will use these data frames for the analysis.

The rest of the notebook is much easier to process. For example, the chunk

df <- smp
df$period <- as.factor(df$period)
df$sector <- as.factor(df$sector)
p <- ggplot(df, aes(x = period)) +
  geom_bar(aes(fill= sector), position = "stack") +
  labs(x = "period", fill = "sector")
p

provides a stacked bar chart of the ExPanD app.1

When you look at the histogram for a given variable (as produced by the sixth chunk)

var <- as.numeric(smp$nioa)
hist(var, main="", xlab = "nioa", col="red", right = FALSE, breaks= 150)

you directly see the effect of winsorization on the data (Net Income divided by average total assets in this case).

Most of the chunks make use of the wrapper functions provided by the ExPanDaR package. For one, the fifth chunk uses prepare_descriptive_table() to quickly produce a standard descriptive statistics table.

df <- smp
t <- prepare_descriptive_table(smp)
t$kable_ret  %>%
  kable_styling("condensed", full_width = F, position = "center")
Descriptive Statistics
N Mean Std. dev. Min. 25 % Median 75 % Max.
toas 8,770 7,120.241 17,672.452 32.797 436.235 1,532.440 4,943.997 123,268.709
sales 8,777 4,307.316 10,942.386 0.638 281.050 926.670 3,094.020 79,966.280
equity 8,770 2,294.681 5,610.286 -705.284 179.058 554.135 1,666.255 39,737.850
debt_ta 8,770 0.277 0.235 0.000 0.064 0.253 0.424 0.991
eq_ta 8,770 0.437 0.266 -0.466 0.277 0.446 0.621 0.930
gw_ta 6,382 0.174 0.153 0.000 0.047 0.132 0.268 0.610
oint_ta 6,754 0.096 0.111 0.000 0.018 0.057 0.136 0.576
ppe_ta 8,003 0.270 0.273 0.001 0.060 0.157 0.402 0.938
ca_ta 7,670 0.449 0.248 0.040 0.240 0.435 0.632 0.978
cash_ta 8,303 0.136 0.164 0.000 0.026 0.079 0.181 0.863
roe 6,398 0.017 0.262 -1.388 -0.008 0.043 0.086 1.145
roa 6,399 0.012 0.086 -0.366 -0.001 0.023 0.051 0.201
nioa 6,399 0.002 0.077 -0.355 -0.002 0.017 0.037 0.147
cfoa 6,399 0.034 0.068 -0.280 0.021 0.041 0.065 0.178
accoa 6,399 -0.032 0.043 -0.209 -0.046 -0.026 -0.012 0.092
cogs_sales 8,109 0.538 0.240 0.020 0.355 0.569 0.729 0.982
ebit_sales 8,777 -0.952 6.570 -56.918 -0.002 0.068 0.148 0.615
ni_sales 8,777 -0.947 6.381 -55.198 -0.005 0.048 0.110 0.573
return 6,009 0.088 0.375 -0.707 -0.136 0.065 0.269 1.568

See the help pages of these functions and the vignette “Using the functions of the ExPanDaR package” for more information on how to use them. Also, you can always take a look at their code (just call their name without the brackets) to see what they do under the hood and to extend or modify them.

Modifying and Extending the Notebook

Now that you understood how the notebook is set up, it is relatively easy to modify the notebook and extend your analysis without using ExPanD. For example: The chunk below from the notebook prepares a scatter plot of return relative to net income.

df <- smp
df <- df[, c("coid", "coname", "period", "nioa", "return", "sector", "toas")]
df <- df[complete.cases(df), ]
df$sector <- as.factor(df$sector)
prepare_scatter_plot(df, "nioa", "return", color = "sector", size = "toas", loess = 1)
## `geom_smooth()` using method = 'gam' and formula = 'y ~ s(x, bs = "cs")'

Let’s assume that in addition you want to see how cash flows from operations relate to stock returns. Easy! Just replace "nioa", the name of the net income variable with "cfoa", the name of the cash flow from operations variable.

df <- smp
df <- df[, c("coid", "coname", "period", "cfoa", "return", "sector", "toas")]
df <- df[complete.cases(df), ]
df$sector <- as.factor(df$sector)
prepare_scatter_plot(df, "cfoa", "return", color = "sector", size = "toas", loess = 1)
## `geom_smooth()` using method = 'gam' and formula = 'y ~ s(x, bs = "cs")'