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Regression Discontinuity

Regression Discontinuity. Basic Idea. Sometimes whether something happens to you or not depends on your ‘score’ on a particular variable e.g You get a scholarship if you get above a certain mark in an exam, you get given remedial education if you get below a certain level,

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Regression Discontinuity

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  1. Regression Discontinuity

  2. Basic Idea • Sometimes whether something happens to you or not depends on your ‘score’ on a particular variable e.g • You get a scholarship if you get above a certain mark in an exam, • you get given remedial education if you get below a certain level, • a policy is implemented if it gets more than 50% of the vote in a ballot, • your sentence for a criminal offence is higher if you are above a certain age (an ‘adult’) • All these are potential applications of the ‘regression discontinuity’ design

  3. More formally.. • assignment to treatment depends in a discontinuous way on some observable variable W • simplest form has assignment to treatment being based on W being above some critical value w0- the discontinuity • method of assignment to treatment is the very opposite to that in random assignment – it is a deterministic function of some observable variable. • But, assignment to treatment is as ‘good as random’ in the neighbourhood of the discontinuity – this is hard to grasp but I hope to explain it

  4. Basics of RDD Estimator • Suppose average outcome in absence of treatment conditional on W is: • Suppose average outcome with treatment conditional on W is: • This is ‘full outcomes’ approach. • Treatment effect conditional on W is g1(W)-g0(W):

  5. How can we estimate this? • Basic idea is to compare outcomes just to the left and right of discontinuity i.e. to compare: • As δ→0 this comes to: • i.e. treatment effect at W=w0

  6. Comments • the RDD estimator compares the outcome of people who are just on both sides of the discontinuity - difference in means between these two groups is an estimate of the treatment effect at the discontinuity • says nothing about the treatment effect away from the discontinuity - this is a limitation of the RDD effect. • An important assumption is that underlying effect on W on outcomes is continuous so only reason for discontinuity is treatment effect

  7. E(y│W) w0 W Some pictures – underlying relationship between y and W is linear

  8. E(y│W) β w0 W Now introduce treatment

  9. The procedure in practice • If take process described above literally should choose a value of δ that is very small • This will result in a small number of observations • Estimate may be consistent but precision will be low • desire to increase the sample size leads one to choose a larger value of δ

  10. Dangers • If δ is not very small then may not estimate just treatment effect – look at picture • As one increases δ the measure of the treatment effect will get larger. This is spurious so what should one do about it? • The basic idea is that one should control for the underlying outcome functions.

  11. If underlying relationship linear • If the linear relationship is the correct specification then one could estimate the ATE simply by estimating the regression: • But no good reason to assume relationship is linear and this may cause problems

  12. g0(W) E(y│W) g1(W) w0 W Suppose true relationship is:

  13. g0(W) E(y│W) g1(W) w0 W Observed relationship between E(y) and W

  14. one would want to control for a different relationship between y and W for the treatment and control groups • Another problem is that the outcome functions might not be linear in W – it could be quadratic or something else. • The researcher then typically faces a trade-off: • a large value of δ to get more precision from a larger sample size but run the risk of a misspecification of the underlying outcome function. • Choose a flexible underlying functional form at the cost of some precision (intuitively a flexible functional form can get closer to approximating a discontinuity in the outcomes).

  15. In practice • it is usual for the researcher to summarize all the data in the graph of the outcome against W to get some idea of the appropriate functional forms and how wide a window should be chosen. • But its always a good idea to investigate the sensitivity of estimates to alternative specifications.

  16. An example • Lemieux and Milligan “Incentive Effects of Social Assistance: A regression discontinuity approach”, Journal of Econometrics, 2008 • In Quebec before 1989 childless benefit recipients received higher benefits when they reached their 30th birthday

  17. The Picture

  18. The Estimates

  19. Note • Note that the more flexible is the underlying relationship between employment rate and age, the less precise is the estimate

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