| ppml {gravity} | R Documentation |
Poisson Pseudo Maximum Likelihood (PPML)
Description
ppml estimates gravity models in their
multiplicative form via Poisson Pseudo Maximum Likelihood.
Usage
ppml(
dependent_variable,
distance,
additional_regressors,
robust = FALSE,
data,
...
)
Arguments
dependent_variable |
(Type: character) name of the dependent variable. This variable is used as the dependent variable in the estimation. |
distance |
(Type: character) name of the distance variable that should be taken as the key independent variable in the estimation. The distance is logged automatically when the function is executed. |
additional_regressors |
(Type: character) names of the additional regressors to include in the model (e.g. a dummy variable to indicate contiguity). Unilateral metric variables such as GDPs can be added but those variables have to be logged first. Interaction terms can be added. Write this argument as |
robust |
(Type: logical) whether robust fitting should be used. By default this is set to |
data |
(Type: data.frame) the dataset to be used. |
... |
Additional arguments to be passed to the function. |
Details
ppml is an estimation method for gravity models
belonging to generalized linear models. It is estimated via glm using the quasipoisson
distribution and a log-link. ppml is presented in Silva and Tenreyro (2006).
For similar functions, utilizing the multiplicative form via the log-link,
but different distributions, see gpml, nls,
and nbpml.
ppml estimation can be used for both, cross-sectional as well as
panel data. The function is designed to be consistent with the
results from the Stata function ppml written by Silva and Tenreyro (2006).
The function ols was therefore tested for cross-sectional data. For the use with panel data
no tests were performed. Therefore, it is up to the user to ensure that the functions can be applied
to panel data.
Depending on the panel dataset and the variables - specifically the type of fixed effects - included in the model, it may easily occur that the model is not computable. Also, note that by including bilateral fixed effects such as country-pair effects, the coefficients of time-invariant observables such as distance can no longer be estimated.
Depending on the specific model, the code of the respective function may has to be changed in order to exclude the distance variable from the estimation.
At the very least, the user should take special care with respect to the meaning of the estimated coefficients and variances as well as the decision about which effects to include in the estimation. When using panel data, the parameter and variance estimation of the models may have to be changed accordingly.
For a comprehensive overview of gravity models for panel data see Egger and Pfaffermayr (2003), Gómez-Herrera (2013) and Head et al. (2010) as well as the references therein.
Value
The function returns the summary of the estimated gravity model as an
glm-object.
References
For more information on gravity models, theoretical foundations and estimation methods in general see
Anderson JE (1979). “A Theoretical Foundation for the Gravity Equation.” The American Economic Review, 69(1), 106–116. ISSN 00028282.
Anderson JE, van Wincoop E (2001). “Gravity with Gravitas: A Solution to the Border Puzzle.” Working Paper 8079, National Bureau of Economic Research. doi:10.3386/w8079.
Anderson JE (2010). “The Gravity Model.” Working Paper 16576, National Bureau of Economic Research. doi:10.3386/w16576.
Baier SL, Bergstrand JH (2009). “Bonus vetus OLS: A simple method for approximating international trade-cost effects using the gravity equation.” Journal of International Economics, 77(1), 77 - 85. ISSN 0022-1996, doi:10.1016/j.jinteco.2008.10.004.
Baier SL, Bergstrand JH (2010). “The Gravity Model in International Trade: Advances and Applications.” In van Bergeijk PAG, Brakman S (eds.), chapter 4. Cambridge University Press. doi:10.1017/CBO9780511762109.
Feenstra RC (2002). “Border effects and the gravity equation: consistent methods for estimation.” Scottish Journal of Political Economy, 49(5), 491–506.
Head K, Mayer T, Ries J (2010). “The erosion of colonial trade linkages after independence.” Journal of International Economics, 81(1), 1 - 14. ISSN 0022-1996, doi:10.1016/j.jinteco.2010.01.002.
Head K, Mayer T (2014). “Chapter 3 - Gravity Equations: Workhorse,Toolkit, and Cookbook.” In Gopinath G, Helpman E, Rogoff K (eds.), Handbook of International Economics, volume 4 of Handbook of International Economics, 131 - 195. Elsevier. doi:10.1016/B978-0-444-54314-1.00003-3.
Silva JMCS, Tenreyro S (2006). “The Log of Gravity.” The Review of Economics and Statistics, 88(4), 641-658. doi:10.1162/rest.88.4.641.
and the citations therein.
See Gravity Equations: Workhorse, Toolkit, and Cookbook for gravity datasets and Stata code for estimating gravity models.
For estimating gravity equations using panel data see
Egger P, Pfaffermayr M (2003). “The proper panel econometric specification of the gravity equation: A three-way model with bilateral interaction effects.” Empirical Economics, 28(3), 571–580. ISSN 1435-8921, doi:10.1007/s001810200146.
Gómez-Herrera E (2013). “Comparing alternative methods to estimate gravity models of bilateral trade.” Empirical Economics, 44(3), 1087–1111. ISSN 1435-8921, doi:10.1007/s00181-012-0576-2.
and the references therein.
See Also
Examples
# Example for CRAN checks:
# Executable in < 5 sec
library(dplyr)
data("gravity_no_zeros")
# Choose 5 countries for testing
countries_chosen <- c("AUS", "CHN", "GBR", "BRA", "CAN")
grav_small <- filter(gravity_no_zeros, iso_o %in% countries_chosen)
fit <- ppml(
dependent_variable = "flow",
distance = "distw",
additional_regressors = c("rta", "iso_o", "iso_d"),
data = grav_small
)