More Web Proxy on the site http://driver.im/

research-article

Public Access

A Machine Learning Approach to Modeling Human Migration

Authors:

Caleb Robinson,

Bistra DilkinaAuthors Info & Claims

COMPASS '18: Proceedings of the 1st ACM SIGCAS Conference on Computing and Sustainable Societies

Article No.: 30, Pages 1 - 8

https://doi.org/10.1145/3209811.3209868

Published: 20 June 2018 Publication History

Abstract

Human migration is a type of human mobility, where a trip involves a person moving with the intention of changing their home location. Predicting human migration as accurately as possible is important in city planning applications, international trade, spread of infectious diseases, conservation planning, and public policy development. Traditional human mobility models, such as gravity models or the more recent radiation model, predict human mobility flows based on population and distance features only. These models have been validated on commuting flows, a different type of human mobility, and are mainly used in modeling scenarios where large amounts of prior ground truth mobility data are not available. One downside of these models is that they have a fixed form and are therefore not able to capture more complicated migration dynamics. We propose machine learning models that are able to incorporate any number of exogenous features, to predict origin/destination human migration flows. Our machine learning models outperform traditional human mobility models on a variety of evaluation metrics, both in the task of predicting migrations between US counties as well as international migrations. In general, predictive machine learning models of human migration will provide a flexible base with which to model human migration under different what-if conditions, such as potential sea level rise or population growth scenarios.

References

[1]

Duygu Balcan, Vittoria Colizza, Bruno Gonçalves, Hao Hu, José J Ramasco, and Alessandro Vespignani. 2009. Multiscale mobility networks and the spatial spreading of infectious diseases. Proceedings of the National Academy of Sciences 106, 51 (2009), 21484--21489.

[2]

Tianqi Chen and Carlos Guestrin. 2016. Xgboost: A scalable tree boosting system. In Proceedings of the 22nd acm sigkdd international conference on knowledge discovery and data mining. ACM, 785--794.

Digital Library

[3]

Gordon L Clark and Kenneth P Ballard. 1980. Modeling out-migration from depressed regions: the significance of origin and destination characteristics. Environment and Planning A 12, 7 (1980), 799--812.

[4]

Joel E Cohen, Marta Roig, Daniel C Reuman, and Cai GoGwilt. 2008. International migration beyond gravity: A statistical model for use in population projections. Proceedings of the National Academy of Sciences 105, 40 (2008), 15269--15274.

[5]

Andrea De Montis, Alessandro Chessa, Michele Campagna, Simone Caschili, and Giancarlo Deplano. 2010. Modeling commuting systems through a complex network analysis: A study of the Italian islands of Sardinia and Sicily. Journal of Transport and Land Use 2, 3 (2010).

[6]

Adam Dennett and Alan Wilson. 2013. A multilevel spatial interaction modelling framework for estimating interregional migration in Europe. Environment and Planning A 45, 6 (2013), 1491--1507.

[7]

Taryn Dinkelman and Martine Mariotti. 2016. The Long-Run Effects of Labor Migration on Human Capital Formation in Communities of Origin. American Economic Journal: Applied Economics 8, 4 (2016), 1--35.

[8]

Giorgio Fagiolo and Marina Mastrorillo. 2013. International migration network: Topology and modeling. Physical Review E 88, 1 (2013), 012812.

[9]

Daniel P Faith, Peter R Minchin, and Lee Belbin. 1987. Compositional dissimilarity as a robust measure of ecological distance. Vegetatio 69, 1-3 (1987), 57--68.

[10]

Jerome H Friedman. 2001. Greedy function approximation: a gradient boosting machine. Annals of statistics (2001), 1189--1232.

[11]

Michael J Greenwood. 1985. Human migration: Theory, models, and empirical studies. Journal of regional Science 25, 4 (1985), 521--544.

[12]

Xinjian Guo, Yilong Yin, Cailing Dong, Gongping Yang, and Guangtong Zhou. 2008. On the class imbalance problem. In Natural Computation, 2008. ICNC'08. Fourth International Conference on, Vol. 4. IEEE, 192--201.

Digital Library

[13]

Yann LeCun, Yoshua Bengio, and Geoffrey Hinton. 2015. Deep learning. Nature 521, 7553 (2015), 436--444.

[14]

Everett S Lee. 1966. A theory of migration. Demography 3, 1 (1966), 47--57.

[15]

Pierre Legendre and Loic FJ Legendre. 2012. Numerical ecology. Vol. 24. Elsevier.

[16]

Maxime Lenormand, Aleix Bassolas, and José J Ramasco. 2016. Systematic comparison of trip distribution laws and models. Journal of Transport Geography 51 (2016), 158--169.

[17]

Maxime Lenormand, Sylvie Huet, Floriana Gargiulo, and Guillaume Deffuant. 2012. A universal model of commuting networks. PloS one 7, 10 (2012), e45985.

[18]

Emmanuel Letouzé, Mark Purser, Francisco Rodríguez, Matthew Cummins, and others. 2009. Revisiting the migration-development nexus: a gravity model approach. Human Development Research Paper 44 (2009).

[19]

Llew Mason, Jonathan Baxter, Peter L Bartlett, and Marcus R Frean. 1999. Boosting Algorithms as Gradient Descent. In NIPS. 512--518.

Digital Library

[20]

A Paolo Masucci, Joan Serras, Anders Johansson, and Michael Batty. 2013. Gravity versus radiation models: On the importance of scale and heterogeneity in commuting flows. Physical Review E 88, 2 (2013), 022812.

[21]

Anastasios Noulas, Salvatore Scellato, Renaud Lambiotte, Massimiliano Pontil, and Cecilia Mascolo. 2012. A tale of many cities: universal patterns in human urban mobility. PloS one 7, 5 (2012), e37027.

[22]

Çağlar Özden, Christopher R Parsons, Maurice Schiff, and Terrie L Walmsley. 2011. Where on earth is everybody? The evolution of global bilateral migration 1960-2000. The World Bank Economic Review 25, 1 (2011), 12--56.

[23]

Kevin Pierce. 2015. SOI migration data. A new approach: Methodological improvements for SOICâĂ&Zacute;s United States population migration data, calendar years 2011--2012. Technical Report. Statistics of Income, Internal Revenue Service.

[24]

Yihui Ren, Mária Ercsey-Ravasz, Pu Wang, Marta C González, and Zoltán Toroczkai. 2014. Predicting commuter flows in spatial networks using a radiation model based on temporal ranges. Nature communications 5 (2014).

[25]

Morton Schneider. 1959. Gravity models and trip distribution theory. Papers in Regional Science 5, 1 (1959), 51--56.

[26]

Filippo Simini, Marta C González, Amos Maritan, and Albert-László Barabási. 2012. A universal model for mobility and migration patterns. Nature 484, 7392 (2012), 96--100.

[27]

Alessandro Sorichetta, Tom J Bird, Nick W Ruktanonchai, Elisabeth zu Erbach-Schoenberg, Carla Pezzulo, Natalia Tejedor, Ian C Waldock, Jason D Sadler, Andres J Garcia, Luigi Sedda, and others. 2016. Mapping internal connectivity through human migration in malaria endemic countries. Scientific Data 3 (2016).

[28]

Samuel A Stouffer. 1940. Intervening opportunities: a theory relating mobility and distance. American sociological review 5, 6 (1940), 845--867.

[29]

World Bank. 2017. http://databank.worldbank.org/data/reports.aspx. (2017).

[30]

Yingxiang Yang, Carlos Herrera, Nathan Eagle, and Marta C González. 2014. Limits of predictability in commuting flows in the absence of data for calibration. Scientific reports 4 (2014).

[31]

George Kingsley Zipf. 1946. The P 1 P 2/D hypothesis: on the intercity movement of persons. American sociological review 11, 6 (1946), 677--686.

Cited By

Özdilek Ü(2025)Integrating Lotka-Volterra dynamics and gravity modeling for regional population forecastingFrontiers in Built Environment10.3389/fbuil.2025.146989011Online publication date: 20-Feb-2025
https://doi.org/10.3389/fbuil.2025.1469890
Rekunenko IKobushko IDzydzyguri OBalahurovska IYurynets OZhuk O(2025)The use of artificial intelligence in public administration: Bibliometric analysisProblems and Perspectives in Management10.21511/ppm.23(1).2025.1623:1(209-224)Online publication date: 12-Feb-2025
https://doi.org/10.21511/ppm.23(1).2025.16
Morshed SAmine KHadi M(2025)Crowdsourced Insights: Shaping Origin–Destination Matrix Estimation Utilizing Transportation Data on DemandJournal of Urban Planning and Development10.1061/JUPDDM.UPENG-5119151:1Online publication date: Mar-2025
https://doi.org/10.1061/JUPDDM.UPENG-5119
Show More Cited By

Index Terms

A Machine Learning Approach to Modeling Human Migration
1. Computing methodologies
  1. Machine learning
    1. Learning paradigms
      1. Supervised learning
        Supervised learning by regression
  2. Modeling and simulation
    1. Model development and analysis
      1. Modeling methodologies
2. Social and professional topics
  1. Professional topics
    1. Computing industry
      1. Sustainability

Recommendations

A machine learning approach to live migration modeling
SoCC '17: Proceedings of the 2017 Symposium on Cloud Computing

Live migration is one of the key technologies to improve data center utilization, power efficiency, and maintenance. Various live migration algorithms have been proposed; each exhibiting distinct characteristics in terms of completion time, amount of ...
Machine Learning Approach for Live Migration Cost Prediction in VMware Environments
CLOSER 2019: Proceedings of the 9th International Conference on Cloud Computing and Services Science

Virtualization became a commonly used technology in datacenters during the last decade. Live migration is an essential feature in most of the clusters hypervisors. Live migration process has a cost that includes the migration time, downtime, IP network ...
Performance Modeling of Virtual Machine Live Migration
CLOUD '11: Proceedings of the 2011 IEEE 4th International Conference on Cloud Computing

System virtualization is becoming pervasive and it is enabling important new computing diagrams such as cloud computing. Live virtual machine (VM) migration is a unique capability of system virtualization which allows applications to be transparently ...

Comments

Please enable JavaScript to view thecomments powered by Disqus.

Information & Contributors

Information

Published In

cover image ACM Conferences

COMPASS '18: Proceedings of the 1st ACM SIGCAS Conference on Computing and Sustainable Societies

June 2018

472 pages

ISBN:9781450358163

DOI:10.1145/3209811

Conference Chair:
Ellen Zegura
Georgia Tech

Copyright © 2018 ACM.

Permission to make digital or hard copies of all or part of this work for personal or classroom use is granted without fee provided that copies are not made or distributed for profit or commercial advantage and that copies bear this notice and the full citation on the first page. Copyrights for components of this work owned by others than ACM must be honored. Abstracting with credit is permitted. To copy otherwise, or republish, to post on servers or to redistribute to lists, requires prior specific permission and/or a fee. Request permissions from [email protected]

Sponsors

SIGCAS: ACM Special Interest Group on Computers and Society

Publisher

Association for Computing Machinery

New York, NY, United States

Publication History

Published: 20 June 2018

Permissions

Request permissions for this article.

Request Permissions

Check for updates

Author Tags

Qualifiers

Research-article
Research
Refereed limited

Funding Sources

NSF

Conference

COMPASS '18

Sponsor:

SIGCAS

COMPASS '18: ACM SIGCAS Conference on Computing and Sustainable Societies

June 20 - 22, 2018

CA, Menlo Park and San Jose, USA

Acceptance Rates

Overall Acceptance Rate 25 of 50 submissions, 50%

Upcoming Conference

COMPASS '25

Sponsor:
sigcas
sigcas

ACM SIGCAS/SIGCHI Conference on Computing and Sustainable Societies

July 22 - 25, 2025

Toronto , ON , Canada

Contributors

Other Metrics

View Article Metrics

Bibliometrics & Citations

Bibliometrics

Article Metrics

46
Total Citations
View Citations
3,383
Total Downloads

Downloads (Last 12 months)819
Downloads (Last 6 weeks)102

Reflects downloads up to 05 Mar 2025

Other Metrics

View Author Metrics

Citations

Cited By

Özdilek Ü(2025)Integrating Lotka-Volterra dynamics and gravity modeling for regional population forecastingFrontiers in Built Environment10.3389/fbuil.2025.146989011Online publication date: 20-Feb-2025
https://doi.org/10.3389/fbuil.2025.1469890
Rekunenko IKobushko IDzydzyguri OBalahurovska IYurynets OZhuk O(2025)The use of artificial intelligence in public administration: Bibliometric analysisProblems and Perspectives in Management10.21511/ppm.23(1).2025.1623:1(209-224)Online publication date: 12-Feb-2025
https://doi.org/10.21511/ppm.23(1).2025.16
Morshed SAmine KHadi M(2025)Crowdsourced Insights: Shaping Origin–Destination Matrix Estimation Utilizing Transportation Data on DemandJournal of Urban Planning and Development10.1061/JUPDDM.UPENG-5119151:1Online publication date: Mar-2025
https://doi.org/10.1061/JUPDDM.UPENG-5119
Emre DBarker KGonzález ACilali BRadhakrishnan SNoyori-Corbett C(2025)Optimizing climate-induced migration: A temporal multi-layer network approachInternational Journal of Disaster Risk Reduction10.1016/j.ijdrr.2024.105172117(105172)Online publication date: Feb-2025
https://doi.org/10.1016/j.ijdrr.2024.105172
Atwal KAnderson TPfoser DZüfle A(2025)Commuting flow prediction using OpenStreetMap dataComputational Urban Science10.1007/s43762-025-00161-55:1Online publication date: 20-Jan-2025
https://doi.org/10.1007/s43762-025-00161-5
Kumar Rao Bangole NThanvitha LSuraiya TShashank YHarshith N(2024)Human Migration Analysis Using Machine LearningMedia Representation of Migrants and Refugees10.4018/979-8-3693-3459-1.ch005(68-79)Online publication date: 28-Jun-2024
https://doi.org/10.4018/979-8-3693-3459-1.ch005
Liu JXu LMa LChen N(2024)Modeling Population Mobility Flows: A Hybrid Approach Integrating a Gravity Model and Machine LearningISPRS International Journal of Geo-Information10.3390/ijgi1311037913:11(379)Online publication date: 30-Oct-2024
https://doi.org/10.3390/ijgi13110379
Seniutis MGružauskas VLileikiene ANavickas V(2024)Conceptual framework for ethical artificial intelligence development in social services sectorHuman Technology10.14254/1795-6889.2024.20-1.120:1(6-24)Online publication date: 27-May-2024
https://doi.org/10.14254/1795-6889.2024.20-1.1
Morgenstern SStrijbis O(2024)Forecasting migration movements using prediction marketsComparative Migration Studies10.1186/s40878-024-00404-012:1Online publication date: 9-Oct-2024
https://doi.org/10.1186/s40878-024-00404-0
Rong CDing JLi Y(2024)An Interdisciplinary Survey on Origin-destination Flows Modeling: Theory and TechniquesACM Computing Surveys10.1145/368205857:1(1-49)Online publication date: 26-Jul-2024
https://dl.acm.org/doi/10.1145/3682058
Show More Cited By

View Options

View options

PDF

View or Download as a PDF file.

eReader

View online with eReader.

Login options

Check if you have access through your login credentials or your institution to get full access on this article.

Full Access

Get this Publication

Figures

Tables

Media

View Table of Conten