A machine learning approach to predict ethnicity using personal name and census location in Canada

Canada is an ethnically-diverse country, yet its lack of ethnicity information in many large databases impedes effective population research and interventions. Automated ethnicity classification using machine learning has shown potential to address this data gap but its performance in Canada is larg...

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Veröffentlicht in:	PloS one 2020-11, Vol.15 (11), p.e0241239-e0241239
Hauptverfasser:	Wong, Kai On, Zaïane, Osmar R, Davis, Faith G, Yasui, Yutaka
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Analysis Automation Bayes Theorem Bayesian analysis Canada Census Censuses Chinese languages Classification Computer and Information Sciences Ethnic Groups Ethnicity Feature selection French language Humans Identification and classification Inuit Italian language Japanese language Learning algorithms Logistic Models Machine Learning Medicine and Health Sciences Minority & ethnic groups Names, Personal People and Places Performance measurement Performance prediction Personal names Phonetics Physical Sciences Prediction models Public health Race Racial discrimination Racism Reproducibility of Results Research and Analysis Methods Russian language Strings Subject specialists Support Vector Machine Variables
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description	Canada is an ethnically-diverse country, yet its lack of ethnicity information in many large databases impedes effective population research and interventions. Automated ethnicity classification using machine learning has shown potential to address this data gap but its performance in Canada is largely unknown. This study conducted a large-scale machine learning framework to predict ethnicity using a novel set of name and census location features. Using census 1901, the multiclass and binary class classification machine learning pipelines were developed. The 13 ethnic categories examined were Aboriginal (First Nations, Métis, Inuit, and all-combined)), Chinese, English, French, Irish, Italian, Japanese, Russian, Scottish, and others. Machine learning algorithms included regularized logistic regression, C-support vector, and naïve Bayes classifiers. Name features consisted of the entire name string, substrings, double-metaphones, and various name-entity patterns, while location features consisted of the entire location string and substrings of province, district, and subdistrict. Predictive performance metrics included sensitivity, specificity, positive predictive value, negative predictive value, F1, Area Under the Curve for Receiver Operating Characteristic curve, and accuracy. The census had 4,812,958 unique individuals. For multiclass classification, the highest performance achieved was 76% F1 and 91% accuracy. For binary classifications for Chinese, French, Italian, Japanese, Russian, and others, the F1 ranged 68-95% (median 87%). The lower performance for English, Irish, and Scottish (F1 ranged 63-67%) was likely due to their shared cultural and linguistic heritage. Adding census location features to the name-based models strongly improved the prediction in Aboriginal classification (F1 increased from 50% to 84%). The automated machine learning approach using only name and census location features can predict the ethnicity of Canadians with varying performance by specific ethnic categories.
doi_str_mv	10.1371/journal.pone.0241239
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Automated ethnicity classification using machine learning has shown potential to address this data gap but its performance in Canada is largely unknown. This study conducted a large-scale machine learning framework to predict ethnicity using a novel set of name and census location features. Using census 1901, the multiclass and binary class classification machine learning pipelines were developed. The 13 ethnic categories examined were Aboriginal (First Nations, Métis, Inuit, and all-combined)), Chinese, English, French, Irish, Italian, Japanese, Russian, Scottish, and others. Machine learning algorithms included regularized logistic regression, C-support vector, and naïve Bayes classifiers. Name features consisted of the entire name string, substrings, double-metaphones, and various name-entity patterns, while location features consisted of the entire location string and substrings of province, district, and subdistrict. Predictive performance metrics included sensitivity, specificity, positive predictive value, negative predictive value, F1, Area Under the Curve for Receiver Operating Characteristic curve, and accuracy. The census had 4,812,958 unique individuals. For multiclass classification, the highest performance achieved was 76% F1 and 91% accuracy. For binary classifications for Chinese, French, Italian, Japanese, Russian, and others, the F1 ranged 68-95% (median 87%). The lower performance for English, Irish, and Scottish (F1 ranged 63-67%) was likely due to their shared cultural and linguistic heritage. Adding census location features to the name-based models strongly improved the prediction in Aboriginal classification (F1 increased from 50% to 84%). 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Automated ethnicity classification using machine learning has shown potential to address this data gap but its performance in Canada is largely unknown. This study conducted a large-scale machine learning framework to predict ethnicity using a novel set of name and census location features. Using census 1901, the multiclass and binary class classification machine learning pipelines were developed. The 13 ethnic categories examined were Aboriginal (First Nations, Métis, Inuit, and all-combined)), Chinese, English, French, Irish, Italian, Japanese, Russian, Scottish, and others. Machine learning algorithms included regularized logistic regression, C-support vector, and naïve Bayes classifiers. Name features consisted of the entire name string, substrings, double-metaphones, and various name-entity patterns, while location features consisted of the entire location string and substrings of province, district, and subdistrict. Predictive performance metrics included sensitivity, specificity, positive predictive value, negative predictive value, F1, Area Under the Curve for Receiver Operating Characteristic curve, and accuracy. The census had 4,812,958 unique individuals. For multiclass classification, the highest performance achieved was 76% F1 and 91% accuracy. For binary classifications for Chinese, French, Italian, Japanese, Russian, and others, the F1 ranged 68-95% (median 87%). The lower performance for English, Irish, and Scottish (F1 ranged 63-67%) was likely due to their shared cultural and linguistic heritage. Adding census location features to the name-based models strongly improved the prediction in Aboriginal classification (F1 increased from 50% to 84%). The automated machine learning approach using only name and census location features can predict the ethnicity of Canadians with varying performance by specific ethnic categories.</abstract><cop>United States</cop><pub>Public Library of Science</pub><pmid>33206667</pmid><doi>10.1371/journal.pone.0241239</doi><tpages>e0241239</tpages><orcidid>https://orcid.org/0000-0003-2572-0082</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Algorithms Analysis Automation Bayes Theorem Bayesian analysis Canada Census Censuses Chinese languages Classification Computer and Information Sciences Ethnic Groups Ethnicity Feature selection French language Humans Identification and classification Inuit Italian language Japanese language Learning algorithms Logistic Models Machine Learning Medicine and Health Sciences Minority & ethnic groups Names, Personal People and Places Performance measurement Performance prediction Personal names Phonetics Physical Sciences Prediction models Public health Race Racial discrimination Racism Reproducibility of Results Research and Analysis Methods Russian language Strings Subject specialists Support Vector Machine Variables
title	A machine learning approach to predict ethnicity using personal name and census location in Canada
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