Estimating human trajectories and hotspots through mobile phone data

Hoteit, Sahar; Secci, Stefano; Sobolevsky, Stanislav; Ratti, Carlo; Pujolle, Guy

doi:10.1016/j.comnet.2014.02.011

Cited by 165 publications

(106 citation statements)

References 30 publications

(27 reference statements)

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“…In recent years this has inspired intensive research, such as the analysis of human mobility behavior, e.g. (Gonzalez et al 2008;Schneider et al 2013;Ratti et al 2006;Ratti et al 2007;Sevtsuk and Ratti 2010;Calabrese et al 2013;Hoteit et al 2014), origin-destination flows, e.g. (Tettamanti and Varga 2014;Wang et al 2013;Caceres et al 2012;Calabrese et al 2011;Friedrich et al 2010), and road usage patterns (Wang et al 2012).…”

Section: Introductionmentioning

confidence: 99%

Discovering urban activity patterns in cell phone data

et al. 2015

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Massive and passive data such as cell phone traces provide samples of the whereabouts and movements of individuals. These are a potential source of information for models of daily activities in a city. The main challenge is that phone traces have low spatial precision and are sparsely sampled in time, which requires a precise set of techniques for mining hidden valuable information they contain. Here we propose a method to reveal activity patterns that emerge from cell phone data by analyzing relational signatures of activity time, duration, and land use. First, we present a method of how to detect stays and extract a robust set of geolocated time stamps that represent trip chains. Second, we show how to cluster activities by combining the detected trip chains with land use data. This is accomplished by modeling the dependencies between activity type, trip scheduling, and land use types via a Relational Markov Network. We apply the method to two different kinds of mobile phone datasets from the metropolitan areas of Vienna, Austria and Boston, USA. The former data includes information from mobility management signals, while the latter are usual Call Detail Records. The resulting trip sequence patterns and activity scheduling from both datasets agree well with their respective city surveys, and we show that the inferred activity clusters are stable across different days and both cities. This method to infer activity patterns from cell phone data allows us to use these as a novel and cheaper data source for activity-based modeling and travel behavior studies.

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Section: Introductionmentioning

confidence: 99%

Discovering urban activity patterns in cell phone data

et al. 2015

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“…It is worth mentioning that since we are working on a cell-based data set with 6-minute interval sessions and in order to capture user's position at each instant of time, we use the following strategy: if the user remains in the same cell in two consecutive sessions, he is considered as a non-moving user (its position is chosen randomly in the cell), however if the user changes its cell from one session to another, he is considered as moving along a linear trajectory from its position in the first cell to its position in the second cell. The latter property was indeed established based on an in-depth analysis about human trajectories by the authors of [26], where they show that for users moving short distances, the linear trajectory is the best estimation of their real trajectories. This property applies strongly in our model, as the region of study is relatively small.…”

Section: A C C E P T E D Mmentioning

confidence: 91%

Mobile data traffic offloading over Passpoint hotspots

et al. 2015

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Wi-Fi technology has always been an attractive solution for catering the increasing data demand in mobile networks because of the availability of WiFi networks, the high bit rates they provide, and the lower cost of ownership. However, the legacy WiFi technology lacks of seamless interworking between Wi-Fi and mobile cellular networks on the one hand, and between Wi-Fi hotspots on the other hand. Nowadays, the recently released Wi-Fi Certified Passpoint Program provides the necessary control-plane for these operations. Service providers can henceforth look to such Wi-Fi systems as a viable way to seamlessly offload mobile traffic and deliver added-value services, so that subscribers no longer face the frustration and aggravation of connecting to Wi-Fi hotspots. However, the technology being rather recent, we are not aware of public studies at the state of the art documenting the achievable gain in real mobile networks. In this paper, we evaluate the capacity and energy saving gain that one can get by offloading cellular data traffic over Passpoint hotspots as a function of different hotspot placement schemes and of access point selection policies (two enabled by the Passpoint control-plane and one independent of it). We compare the policies using real mobile data from the Orange network in Paris. We show that offloading using Passpoint control-plane information can grant up to 15% capacity gain and 13% energy saving gain with respect to Passpoint-agnostic ones based on signal quality information. As of placement strategy, installing Passpoint hotspots in the outer annulus of the macrocell coverage grants the maximum capacity gain.

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“…Since 2006, a number of studies has been initiated to analyze human mobility patterns (e.g. Eagle and Pentland, 2006;Mateos and Fisher, 2006;Shoval, 2007;Gonzalez et al, 2008;Park et al, 2010;Song et al, 2010aSong et al, , 2010bCsáji et al, 2012;Hoteit et al, 2014). For example, Gonzalez et al (2008) conclude that human trajectories show a high degree of temporal and spatial regularity, and follow simple reproducible patterns.…”

Section: Analysing Human Activity Places and Mobility Patternsmentioning

confidence: 99%