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List Experiment Design, Non-Strategic Respondent Error, and Item Count Technique Estimators

Published online by Cambridge University Press:  29 December 2017

John S. Ahlquist*
Affiliation:
Associate Professor, School of Global Policy and Strategy, UC San Diego, La Jolla, CA 92093, USA. Email: jahlquist@ucsd.edu
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Abstract

The item count technique (ICT-MLE) regression model for survey list experiments depends on assumptions about responses at the extremes (choosing no or all items on the list). Existing list experiment best practices aim to minimize strategic misrepresentation in ways that virtually guarantee that a tiny number of respondents appear in the extrema. Under such conditions both the “no liars” identification assumption and the computational strategy used to estimate the ICT-MLE become difficult to sustain. I report the results of Monte Carlo experiments examining the sensitivity of the ICT-MLE and simple difference-in-means estimators to survey design choices and small amounts of non-strategic respondent error. I show that, compared to the difference in means, the performance of the ICT-MLE depends on list design. Both estimators are sensitive to measurement error, but the problems are more severe for the ICT-MLE as a direct consequence of the no liars assumption. These problems become extreme as the number of treatment-group respondents choosing all the items on the list decreases. I document that such problems can arise in real-world applications, provide guidance for applied work, and suggest directions for further research.

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Articles
Copyright
Copyright © The Author(s) 2017. Published by Cambridge University Press on behalf of the Society for Political Methodology. 
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Table 1. Expected number of respondents in ${\mathcal{J}}(1,J+1)$ under the different list scenarios for $N=1,000$, equal probability of treatment assignment, and no error.

Figure 1

Figure 1. Percent of Monte Carlo runs in which the ICT-MLE exited with an error as a function of the mean number of observations in ${\mathcal{J}}(1,J+1)$. Text indicates the list condition, e.g., 3M refers to the $J=3$ list with medium prevalence for the sensitive item. Bold-text items are from runs with 3% top-biased error and jittered for clarity.

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Figure 2. Bias, RMSE, and 90% confidence interval coverage rates in $\hat{b}_{1}$ for the ICT-MLE applied to the Blair & Imai style list experiments. Bias and RMSE for the $J=4$, low-prevalence, no-error conditions are $-38$ and 903, respectively. These values are omitted from Figures 2(a) and 2(b) for clarity in presentation.

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Table 2. The distributions of point estimates for $b_{1}$ from the ICT-MLE applied to the “designed” lists with no error.

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Figure 3. Bias and 90% confidence interval coverage rates in $\hat{b}_{1}$ for the ICT-MLE applied to the “designed” list experiments with 3% top-biased error, as a function of list length and the prevalence of the sensitive item.

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Figure 4. Bias in $\hat{\unicode[STIX]{x1D70B}}_{Z^{\ast }}$ for the ICT-MLE (solid) and DiM (broken line) applied to the Blair–Imai style list experiments as a function of list length, the prevalence of the sensitive item, and presence of 3% top-biased error.

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Figure 5. RMSE for $\hat{\unicode[STIX]{x1D70B}}_{Z^{\ast }}$ for the ICT-MLE (solid) and DiM (broken line) applied to the Blair–Imai style list experiments as a function of list length, the prevalence of the sensitive item, and presence of 3% top-biased error.

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Figure 6. 90% confidence interval coverage rates for $\hat{\unicode[STIX]{x1D70B}}_{Z^{\ast }}$ for the ICT-MLE (solid) and DiM (broken line) applied to the Blair–Imai style list experiments as a function of list length, the prevalence of the sensitive item, and presence of 3% top-biased error.

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Figure 7. The distribution of point estimates of $\unicode[STIX]{x1D70B}_{Z^{\ast }}$ from the ICT-ML (black) and difference-in-means (gray) estimators applied to the “designed” list experiments, as a function of list length (left v. right), the prevalence of the sensitive item, and presence of 3% top-biased error (solid v. broken lines).

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Figure 8. 90% confidence interval coverage rates for $\hat{\unicode[STIX]{x1D70B}}_{Z^{\ast }}$ from the ICT-ML (black) and difference-in-means (gray) estimators applied to the “designed” list experiments, as a function of list length, the prevalence of the sensitive item, and presence of 3% top-biased error (left v. right).

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Figure 9. Evidence of problems with the ICT-MLE across three list experiments. Bars are 95% CIs for the DiM estimates and $\pm 2$SEs for the ICT estimates.

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Table 3. The proportion of respondents selecting the most extreme value is stable across survey waves and questions. Source: Ahlquist et al. (2014).

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