Help for package ebci

Title:

Robust Empirical Bayes Confidence Intervals

Version:

1.0.0

Description:

Computes empirical Bayes confidence estimators and confidence intervals in a normal means model. The intervals are robust in the sense that they achieve correct coverage regardless of the distribution of the means. If the means are treated as fixed, the intervals have an average coverage guarantee. The implementation is based on Armstrong, Kolesár and Plagborg-Møller (2020) <doi:10.48550/arXiv.2004.03448>.

Depends:

R (≥ 4.1.0)

License:

MIT + file LICENSE

Encoding:

UTF-8

LazyData:

true

Suggests:

spelling, testthat (≥ 2.1.0), lpSolve, knitr, rmarkdown

Language:

en-US

URL:

https://github.com/kolesarm/ebci

BugReports:

https://github.com/kolesarm/ebci/issues

RoxygenNote:

7.1.1

VignetteBuilder:

knitr

NeedsCompilation:

Packaged:

2021-09-02 17:29:45 UTC; kolesarm

Author:

Michal Kolesár

[aut, cre], Tim Armstrong [ctb], Mikkel Plagborg-Møller [ctb]

Maintainer:

Michal Kolesár <kolesarmi@googlemail.com>

Repository:

CRAN

Date/Publication:

2021-09-06 08:40:05 UTC

Compute average coverage critical value under moment constraints.

Description

Computes the critical value cva_{\alpha}(m_{2}, \kappa) from Armstrong, Kolesár, and Plagborg-Møller (2020).

Usage

cva(m2, kappa = Inf, alpha = 0.05, check = TRUE)

Arguments

m2

Bound on second moment of the normalized bias, m_{2}

kappa

Bound on the kurtosis of the normalized bias, \kappa

alpha

Determines confidence level, 1-\alpha.

check

If TRUE, verify accuracy of the solution by checking that the implied least favorable distribution satisfies the m2 and kappa constraints and yields the same non-coverage rate. If this fails (perhaps due to numerical accuracy issues), solve a finite-grid approximation (by discretizing the support of the normalized bias) to the primal linear programming problem, and check that it agrees with the dual solution.

Value

Returns a list with 4 components:

cv: Critical value for constructing two-sided confidence intervals.
alpha: The argument alpha.
x: Support points for the least favorable distribution for the squared normalized bias, b^2.
p: Probabilities associated with the support points.

References

Armstrong, Timothy B., Kolesár, Michal, and Plagborg-Møller, Mikkel (2020): Robust Empirical Bayes Confidence Intervals, https://arxiv.org/abs/2004.03448

Examples

# Usual critical value
cva(m2=0, kappa=Inf, alpha=0.05)
# Larger critical value that takes bias into account. Only uses second moment
# constraint on normalized bias.
cva(m2=4, kappa=Inf, alpha=0.05)
# Add a constraint on kurtosis. This tightens the critical value.
cva(m2=4, kappa=3, alpha=0.05)

Neighborhood effects data from Chetty and Hendren (2018)

Description

This dataset contains a subset of the publicly available data from Chetty and Hendren (2018). It contains raw estimates and standard errors of neighborhood effects at the commuting zone level

Usage

cz

Format

A data frame with 741 rows corresponding to commuting zones (CZ) and 10 columns corresponding to the variables:

cz: Commuting zone ID
czname: Name of CZ
state: 2-digit state code
pop: Population according to the year 2000 Census
theta25: Fixed-effect estimate of the causal effect of living in the CZ for one year on children's percentile rank in the national distribution of household earnings at age 26 relative to others in the same birth cohort for children growing up with parents at the 25th percentile of national income distribution
theta75: Fixed-effect estimate of the causal effect of living in the CZ for one year on children's percentile rank in the national distribution of household earnings at age 26 relative to others in the same birth cohort for children growing up with parents at the 75th percentile of national income distribution
se25: Standard error of theta25
se75: Standard error of theta75
stayer25: Average percentile rank in the national distribution of household earnings at age 26 relative to others in the same birth cohort for stayers (children who grew up in the CZ and did not move) with parents at the 25th percentile of national income distribution.
stayer75: Average percentile rank in the national distribution of household earnings at age 26 relative to others in the same birth cohort for stayers (children who grew up in the CZ and did not move) with parents at the 75th percentile of national income distribution.

Source

https://opportunityinsights.org/data/?paper_id=599

References

Chetty, R., & Hendren, N. (2018). The Impacts of Neighborhoods on Intergenerational Mobility II: County-Level Estimates. The Quarterly Journal of Economics, 133(3), 1163–1228. doi: 10.1093/qje/qjy006

Compute empirical Bayes confidence intervals by shrinking toward regression

Description

Computes empirical Bayes estimators based on shrinking towards a regression, and associated robust empirical Bayes confidence intervals (EBCIs), as well as length-optimal robust EBCIs.

Usage

ebci(
  formula,
  data,
  se,
  weights = NULL,
  alpha = 0.1,
  kappa = NULL,
  wopt = FALSE,
  fs_correction = "PMT"
)

Arguments

formula

object of class "formula" (or one that can be coerced to that class) of the form Y ~ predictors, where Y is a preliminary unbiased estimator, and predictors are predictors X that guide the direction of shrinkage. For shrinking toward the grand mean, use Y ~ 1, and for shrinking toward 0 use Y ~ 0

data

optional data frame, list or environment (or object coercible by as.data.frame to a data frame) containing the preliminary estimator Y and the predictors. If not found in data, these variables are taken from environment(formula), typically the environment from which the function is called.

se

Standard errors \sigma associated with the preliminary estimates Y

weights

An optional vector of weights to be used in the fitting process in computing \delta, \mu_2 and \kappa. Should be NULL or a numeric vector.

alpha

Determines confidence level, 1-\alpha.

kappa

If non-NULL, use pre-specified value for the kurtosis \kappa of \theta-X'\delta (such as Inf), instead of computing it.

wopt

If TRUE, also compute length-optimal robust EBCIs. These are robust EBCIs centered at estimates with the shrinkage factor w_i chosen to minimize the length of the resulting EBCI.

fs_correction

Finite-sample correction method used to compute \mu_2 and \kappa. These corrections ensure that we do not shrink the preliminary estimates Y all the way to zero. If "PMT", use posterior mean truncation, if "FPLIB" use limited information Bayesian approach with a flat prior, and if "none", truncate the estimates at 0 for \mu_2 and 1 for \kappa.

Value

Returns a list with the following components:

mu2: Estimated second moment of \theta-X'\delta, \mu_2. Vector of length 2, the first element corresponds to the estimate after the finite-sample correction as specified by fs_correction, the second element is the uncorrected estimate.
kappa: Estimated kurtosis \kappa of \theta-X'\delta. Vector of length 2 with the same structure as mu2.
delta: Estimated regression coefficients \delta
X: Matrix of regressors
alpha: Determines confidence level 1-\alpha used.
df: Data frame with components described below.

df has the following components:

w_eb: EB shrinkage factors, \mu_{2}/(\mu_{2}+\sigma^2_i)
w_opt: Length-optimal shrinkage factors
ncov_pa: Maximal non-coverage of parametric EBCIs
len_eb: Half-length of robust EBCIs based on EB shrinkage, so that the intervals take the form cbind(th_eb-len_eb, th_eb+len_eb)
len_op: Half-length of robust EBCIs based on length-optimal shrinkage, so that the intervals take the form cbind(th_op-len_op, th_op+len_op)
len_pa: Half-length of parametric EBCIs, which take the form cbind(th_eb-len_pa, th_eb+len_a)
len_us: Half-length of unshrunk CIs, which take the form cbind(th_us-len_us, th_us+len_us)
th_us: Unshrunk estimate Y
th_eb: EB estimate.
th_op: Estimate based on length-optimal shrinkage.
se: Standard error \sigma, as supplied by the argument se
weights: Weights used
residuals: The residuals Y_i-X_i\delta

References

Armstrong, Timothy B., Kolesár, Michal, and Plagborg-Møller, Mikkel (2020): Robust Empirical Bayes Confidence Intervals, https://arxiv.org/abs/2004.03448

Examples

## Same specification as in empirical example in Armstrong, Kolesár
## and Plagborg-Møller (2020), but only use data on NY commuting zones
r <- ebci(theta25 ~ stayer25, data=cz[cz$state=="NY", ],
          se=se25, weights=1/se25^2)