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Journal of the Royal Statistical Society: Series A (Statistics in Society)
Volume 178, Issue 3
Original Article

Network model‐assisted inference from respondent‐driven sampling data

Krista J. Gile

Corresponding Author

University of Massachusetts, Amherst, USA

Address for correspondence: Krista J. Gile, Department of Mathematics and Statistics, University of Massachusetts, Amherst, MA 01003‐9305, USA. E‐mail: gile@math.umass.eduSearch for more papers by this author
Mark S. Handcock

University of California at Los Angeles, USA

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First published: 27 January 2015
https://doi.org/10.1111/rssa.12091
Citations: 22

Summary

Respondent‐driven sampling is a widely used method for sampling hard‐to‐reach human populations by link tracing over their social networks. Inference from such data requires specialized techniques because the sampling process is both partially beyond the control of the researcher, and partially implicitly defined. Therefore, it is not generally possible to compute the sampling weights for traditional design‐based inference directly, and likelihood inference requires modelling the complex sampling process. As an alternative, we introduce a model‐assisted approach, resulting in a design‐based estimator leveraging a working network model. We derive a new class of estimators for population means and a corresponding bootstrap standard error estimator. We demonstrate improved performance compared with existing estimators, including adjustment for an initial convenience sample. We also apply the method and an extension to the estimation of the prevalence of human immunodeficiency virus in a high‐risk population.

Number of times cited according to CrossRef: 22

  • Antonio D. Sirianni, Christopher J. Cameron, Yongren Shi, Douglas D. Heckathorn, Bias decomposition and estimator performance in respondent-driven sampling, Social Networks, 10.1016/j.socnet.2020.08.002, 64, (109-121), (2021).
    Crossref
  • Olivier Robineau, Marcelo F. C. Gomes, Carl Kendall, Ligia Kerr, André Périssé, Pierre-Yves Boëlle, Model-based Respondent-driven sampling analysis for HIV prevalence in brazilian MSM, Scientific Reports, 10.1038/s41598-020-59567-2, 10, 1, (2020).
    Crossref
  • Lin Zhu, Nicolas A. Menzies, Jianing Wang, Benjamin P. Linas, Steven M. Goodreau, Joshua A. Salomon, Estimation and correction of bias in network simulations based on respondent-driven sampling data, Scientific Reports, 10.1038/s41598-020-63269-0, 10, 1, (2020).
    Crossref
  • Isabel Sathane, Makini A.S. Boothe, Roberta Horth, Cynthia Semá Baltazar, Noela Chicuecue, Jessica Seleme, Henry F. Raymond, Population Size Estimate of Men Who Have Sex With Men, Female Sex Workers, and People Who Inject Drugs in Mozambique: A Multiple Methods Approach, Sexually Transmitted Diseases, 10.1097/OLQ.0000000000001214, 47, 9, (602-609), (2020).
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  • A K B Green, T H McCormick, A E Raftery, Consistency for the tree bootstrap in respondent-driven sampling, Biometrika, 10.1093/biomet/asz067, (2020).
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  • Guri Tyldum, Surveying migrant populations with respondent-driven sampling. Experiences from surveys of east-west migration in Europe, International Journal of Social Research Methodology, 10.1080/13645579.2020.1786239, (1-13), (2020).
    Crossref
  • Sunghee Lee, Ai Rene Ong, Chen Chen, Michael Elliott, Respondent Driven Sampling for Immigrant Populations: A Health Survey of Foreign-Born Korean Americans, Journal of Immigrant and Minority Health, 10.1007/s10903-020-01077-4, (2020).
    Crossref
  • Miles Q. Ott, Krista J. Gile, Matthew T. Harrison, Lisa G. Johnston, Joseph W. Hogan, Reduced bias for respondent‐driven sampling: accounting for non‐uniform edge sampling probabilities in people who inject drugs in Mauritius, Journal of the Royal Statistical Society: Series C (Applied Statistics), 10.1111/rssc.12353, 68, 5, (1411-1429), (2019).
    Wiley Online Library
  • Olga V. Chyzh, Mark S. Kaiser, A Local Structure Graph Model: Modeling Formation of Network Edges as a Function of Other Edges, Political Analysis, 10.1017/pan.2019.8, (1-18), (2019).
    Crossref
  • Krista J. Gile, Isabelle S. Beaudry, Mark S. Handcock, Miles Q. Ott, Methods for Inference from Respondent-Driven Sampling Data, Annual Review of Statistics and Its Application, 10.1146/annurev-statistics-031017-100704, 5, 1, (65-93), (2018).
    Crossref
  • Kayo Fujimoto, Ming Cao, Lisa M. Kuhns, Dennis Li, John A. Schneider, Statistical adjustment of network degree in respondent-driven sampling estimators: Venue attendance as a proxy for network size among young MSM, Social Networks, 10.1016/j.socnet.2018.01.003, 54, (118-131), (2018).
    Crossref
  • Michael W Spiller, Krista J Gile, Mark S Handcock, Corinne M Mar, Cyprian Wejnert, Evaluating Variance Estimators for Respondent-Driven Sampling, Journal of Survey Statistics and Methodology, 10.1093/jssam/smx018, 6, 1, (23-45), (2017).
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  • Jianghong Li, Thomas W. Valente, Hee-Sung Shin, Margaret Weeks, Alexei Zelenev, Gayatri Moothi, Heather Mosher, Robert Heimer, Eduardo Robles, Greg Palmer, Chinekwu Obidoa, Overlooked Threats to Respondent Driven Sampling Estimators: Peer Recruitment Reality, Degree Measures, and Random Selection Assumption, AIDS and Behavior, 10.1007/s10461-017-1827-1, 22, 7, (2340-2359), (2017).
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  • Mark S. Handcock, Discussion of “Adaptive and Network Sampling for Inference and Interventions in Changing Populations” by Steven K. Thompson, Journal of Survey Statistics and Methodology, 10.1093/jssam/smw040, 5, 1, (29-33), (2017).
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  • Douglas D. Heckathorn, Christopher J. Cameron, Network Sampling: From Snowball and Multiplicity to Respondent-Driven Sampling, Annual Review of Sociology, 10.1146/annurev-soc-060116-053556, 43, 1, (101-119), (2017).
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  • Saran Chen, Xin Lu, An Immunization Strategy for Hidden Populations, Scientific Reports, 10.1038/s41598-017-03379-4, 7, 1, (2017).
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  • Yongren Shi, Christopher J. Cameron, Douglas D. Heckathorn, Model-Based and Design-Based Inference: Reducing Bias Due to Differential Recruitment in Respondent-Driven Sampling, Sociological Methods & Research, 10.1177/0049124116672682, 48, 1, (3-33), (2016).
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  • Dennis M. Feehan, Matthew J. Salganik, Generalizing the Network Scale-up Method, Sociological Methodology, 10.1177/0081175016665425, 46, 1, (153-186), (2016).
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  • Jens Malmros, Naoki Masuda, Tom Britton, Random Walks on Directed Networks: Inference and Respondent-Driven Sampling, Journal of Official Statistics, 10.1515/jos-2016-0023, 32, 2, (433-459), (2016).
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  • Forrest W. Crawford, The Graphical Structure of Respondent-driven Sampling, Sociological Methodology, 10.1177/0081175016641713, 46, 1, (187-211), (2016).
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  • J. Malmros, F. Liljeros, T. Britton, Respondent-driven sampling and an unusual epidemic, Journal of Applied Probability, 10.1017/jpr.2016.17, 53, 2, (518-530), (2016).
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  • Aaron J. Baraff, Tyler H. McCormick, Adrian E. Raftery, Estimating uncertainty in respondent-driven sampling using a tree bootstrap method, Proceedings of the National Academy of Sciences, 10.1073/pnas.1617258113, 113, 51, (14668-14673), (2016).
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