Abstract
Understanding seasonal human mobility at subnational scales has important implications across sciences, from urban planning efforts to disease modelling and control. Assessing how, when, and where populations move over the course of the year, however, requires spatially and temporally resolved datasets spanning large periods of time, which can be rare, contain sensitive information, or may be proprietary. Here, we aim to explore how a set of broadly available covariates can describe typical seasonal subnational mobility in Kenya pre-COVID-19, therefore enabling better modelling of seasonal mobility across low- and middle-income country (LMIC) settings in non-pandemic settings. To do this, we used the Google Aggregated Mobility Research Dataset, containing anonymized mobility flows aggregated over users who have turned on the Location History setting, which is off by default. We combined this with socioeconomic and geospatial covariates from 2018 to 2019 to quantify seasonal changes in domestic and international mobility patterns across years. We undertook a spatiotemporal analysis within a Bayesian framework to identify relevant geospatial and socioeconomic covariates explaining human movement patterns, while accounting for spatial and temporal autocorrelations. Typical pre-pandemic mobility patterns in Kenya mostly consisted of shorter, within-county trips, followed by longer domestic travel between counties and international travel, which is important in establishing how mobility patterns changed post-pandemic. Mobility peaked in August and December, closely corresponding to school holiday seasons, which was found to be an important predictor in our model. We further found that socioeconomic variables including urbanicity, poverty, and female education strongly explained mobility patterns, in addition to geospatial covariates such as accessibility to major population centres and temperature. These findings derived from novel data sources elucidate broad spatiotemporal patterns of how populations move within and beyond Kenya, and can be easily generalized to other LMIC settings before the COVID-19 pandemic. Understanding such pre-pandemic mobility patterns provides a crucial baseline to interpret both how these patterns have changed as a result of the pandemic, as well as whether human mobility patterns have been permanently altered once the pandemic subsides. Our findings outline key correlates of mobility using broadly available covariates, alleviating the data bottlenecks of highly sensitive and proprietary mobile phone datasets, which many researchers do not have access to. These results further provide novel insight on monitoring mobility proxies in the context of disease surveillance and control efforts through LMIC settings.
Highlights
IntroductionGoogle Aggregated Mobility Research Dataset (GAMRD) data have further shown to be strongly predictive of human mobility patterns as measured through call data records, with a Pearson correlation coefficient nearing 0.90 between Google data and Vodafone mobility data for parts of Europe[7]
The applicability of this data has been shown to be comparable with more traditional forms of mobility signals, such as travel history s urveys[14,20]. While these data are likely biased in terms of wealth, gender, and urbanicity[21,22], mobile penetration rate and smartphone ownership within sub-Saharan Africa have been steadily increasing over the decades, with nearly half a billion people currently subscribing to mobile services and an estimated 65% of the population having access to a smartphone device by 202522
These data have proven timely and responsive in quickly informing reductions in mobility and social contacts as a result of non-pharmaceutical interventions, such as lockdown and social distancing measures, in the context of the 2019 coronavirus disease (COVID-19) p andemic[7,23]. These studies suggest that while Google Aggregated Mobility Research Dataset (GAMRD) data are subject to similar sociodemographic biases inherent to mobile phone data, they are highly accurate and representative of movement patterns captured among the study population
Summary
GAMRD data have further shown to be strongly predictive of human mobility patterns as measured through call data records, with a Pearson correlation coefficient nearing 0.90 between Google data and Vodafone mobility data for parts of Europe[7] These data have proven timely and responsive in quickly informing reductions in mobility and social contacts as a result of non-pharmaceutical interventions, such as lockdown and social distancing measures, in the context of the 2019 coronavirus disease (COVID-19) p andemic[7,23]. Despite its utility in describing population movement patterns, exploiting these large mobility datasets may be challenging for many researchers due to restrictive data sharing policies put in place to protect individual privacy[9] This often necessitates the use of freely available proxy data, such as satellite-derived imagery or modelled socioeconomic surfaces to approximate changes in population densities, yet few studies have explored the ability of these correlates to explain seasonal population m ovements[2]. We utilise a hierarchical Bayesian modelling approach to identify key correlates of overall monthly movement patterns while accounting for spatial and temporal autocorrelations
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