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Randomization Inference with Rainfall Data: Using Historical Weather Patterns for Variance Estimation

Published online by Cambridge University Press:  11 July 2017

Alicia Dailey Cooperman*
Affiliation:
Department of Political Science, Columbia University, New York, NY 10027, USA. Email: [email protected]

Abstract

Many recent papers in political science and economics use rainfall as a strategy to facilitate causal inference. Rainfall shocks are as-if randomly assigned, but the assignment of rainfall by county is highly correlated across space. Since clustered assignment does not occur within well-defined boundaries, it is challenging to estimate the variance of the effect of rainfall on political outcomes. I propose using randomization inference with historical weather patterns from 73 years as potential randomizations. I replicate the influential work on rainfall and voter turnout in presidential elections in the United States by Gomez, Hansford, and Krause (2007) and compare the estimated average treatment effect (ATE) to a sampling distribution of estimates under the sharp null hypothesis of no effect. The alternate randomizations are random draws from national rainfall patterns on election and would-be election days, which preserve the clustering in treatment assignment and eliminate the need to simulate weather patterns or make assumptions about unit boundaries for clustering. I find that the effect of rainfall on turnout is subject to greater sampling variability than previously estimated using conventional standard errors.

Type
Articles
Copyright
Copyright © The Author(s) 2017. Published by Cambridge University Press on behalf of the Society for Political Methodology. 

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Footnotes

Author’s note: I am grateful to Donald Green, Gregory Wawro, Tara Slough, Alex Coppock, Lindsay Dolan, Robert Erikson, Patrick Healy, Ayal Margalith, and two anonymous referees for their helpful comments, suggestions, and encouragement. I thank the Columbia Digital Social Science Center for assistance with processing the precipitation data. I thank Brad Gomez, Thomas Hansford, and George Krause for making their replication data available. For replication materials, see Cooperman (2017). Supplementary materials for this article are available on the Political Analysis website.

Contributing Editor: Jonathan N. Katz

References

Aronow, P. M., Samii, C., and Assenova, V. A.. 2015. Cluster–robust variance estimation for dyadic data. Political Analysis 23(4):564577.Google Scholar
Barnhart, J. D. 1925. Rainfall and the populist party in nebraska. American Political Science Review 19(03):527540.Google Scholar
Barrios, T., Diamond, R., Imbens, G. W., and Kolesar, M.. 2012. Clustering, spatial correlations, and randomization inference. Journal of the American Statistical Association 107(498):578591.Google Scholar
Borden, K. A., and Cutter, S. L.. 2008. Spatial patterns of natural hazards mortality in the united states. International Journal of Health Geographics 7(1):1.Google Scholar
Brückner, M., and Ciccone, A.. 2011. Rain and the democratic window of opportunity. Econometrica 79(3):923947.Google Scholar
Cameron, A. C., and Miller, D. L.. 2015. A practitioner’s guide to cluster-robust inference. Journal of Human Resources 50(2):317372.Google Scholar
Chen, J. 2013. Voter partisanship and the effect of distributive spending on political participation. American Journal of Political Science 57(1):200217.Google Scholar
Conley, T. G. 1999. Gmm estimation with cross sectional dependence. Journal of Econometrics 92(1):145.Google Scholar
Conley, T. G., and Topa, G.. 2002. Socio-economic distance and spatial patterns in unemployment. Journal of Applied Econometrics 17(4):303327.Google Scholar
Cooperman, A. D.2017. Replication data for: Randomization inference with rainfall data: Using historical weather patterns for variance estimation. Harvard Dataverse, http://dx.doi.org/10.7910/DVN/RJF61A.Google Scholar
Dell, M., Jones, B. F., and Olken, B. A.. 2012. Temperature shocks and economic growth: Evidence from the last half century. American Economic Journal: Macroeconomics 66–95.Google Scholar
Dell, M., Jones, B. F., and Olken, B. A.. 2014. What do we learn from the weather? The new climate–economy literature. Journal of Economic Literature 52(3):740798.Google Scholar
Erikson, R. S., Pinto, P. M., and Rader, K. T.. 2010. Randomization tests and multi-level data in us state politics. State Politics and Policy Quarterly 10(2):180198.Google Scholar
Erikson, R. S., Pinto, P. M., and Rader, K. T.. 2014. Dyadic analysis in international relations: A cautionary tale. Political Analysis 22(4):457463.Google Scholar
Fisher, R. A. 1935. The Design of Experiments . Edinburgh: Oliver & Boyd.Google Scholar
Gerber, A. S., and Green, D. P.. 2012. Field experiments: Design, analysis, and interpretation . WW Norton.Google Scholar
Gomez, B. T., and Hansford, T. G.. 2010. Estimating the electoral effects of voter turnout. American Political Science Review 104(2):268288.Google Scholar
Gomez, B. T., Hansford, T. G., and Krause, G. A.. 2007. The republicans should pray for rain: Weather, turnout, and voting in us presidential elections. Journal of Politics 69(3):649663.Google Scholar
Gomez, B. T., Hansford, T. G., and Krause, G. A.. 2015. Replication data for: The republicans should pray for rain. http://myweb.fsu.edu/bgomez/research.html.Google Scholar
Hsiang, S. M., Burke, M., and Miguel, E.. 2013. Quantifying the influence of climate on human conflict. Science 341(6151): 1235367.Google Scholar
Hsiang, S. M., and Jina, A. S.. 2015. The causal effects of environmental catastrophe on economic growth: Evidence from 6,700 tropical cyclones. NBER Working Paper No. 20352.Google Scholar
Hsiang, S. M., Meng, K. C., and Cane, M. A.. 2011. Civil conflicts are associated with the global climate. Nature 476(7361):438441.Google Scholar
Husak, G. J., Michaelsen, J. C., and Funk, C. C.. 2007. Use of the gamma distribution to represent monthly rainfall in africa for drought monitoring applications. International Journal of Climatology 27(7):935944.Google Scholar
Koubi, V., Bernauer, T., Kalbhenn, A., and Spilker, G.. 2012. Climate variability, economic growth, and civil conflict. Journal of Peace Research 49(1):113127.Google Scholar
Lind, J.2015. Spurious weather effects. CESifo Working Paper Series 5365.Google Scholar
Lyall, J. 2009. Does indiscriminate violence incite insurgent attacks? evidence from chechnya. Journal of Conflict Resolution .Google Scholar
Maccini, S., and Yang, D.. 2009. Under the weather: Health, schooling, and economic consequences of early-life rainfall. American Economic Review 99(3):10061026.Google Scholar
Madestam, A., Shoag, D., Veuger, S., and Yanagizawa-Drott, D.. 2013. Do political protests matter? evidence from the tea party movement. The Quarterly Journal of Economics .Google Scholar
Malcolm, B.2013. The Spatial and Temporal Anatomy of Seasonal Influenza in the United States, 1968–2008. Ph. D. thesis, Columbia University.Google Scholar
McKee, T. B., Doesken, N. L., and Kliest, J.. 1993. The relationship of drought frequency and duration to time scales. In Proceedings of the 8th Conference of Applied Climatology Boston: American Meteorological Society, pp. 179184.Google Scholar
Miguel, E., Satyanath, S., and Sergenti, E.. 2004. Economic shocks and civil conflict: An instrumental variables approach. Journal of Political Economy 112(4):725753.Google Scholar
NWS. 2009. Public geographic areas of responsibility (NWSM 10-507 ed.). National Weather Service.Google Scholar
NWS. 2012. NWS Regions. National Weather Service, Office of Science and Technology.Google Scholar
NWS. 2016. National weather service county warning area boundaries. Silver Spring, MD: National Weather Service.Google Scholar
Rubin, D. B. 1990. Formal mode of statistical inference for causal effects. Journal of Statistical Planning and Inference 25(3):279292.Google Scholar
Schutte, S., and Weidmann, N. B.. 2011. Diffusion patterns of violence in civil wars. Political Geography 30(3):143152.Google Scholar
Taylor, R. B., and Covington, J.. 1988. Neighborhood changes in ecology and violence. Criminology 26(4):553590.Google Scholar
Yang, D. 2008. Coping with disaster: The impact of hurricanes on international financial flows, 1970–2002. The B.E. Journal of Economic Analysis and Policy 8(1):145.Google Scholar
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