Online Trajectory Prediction for Metropolitan Scale Mobility Digital Twin

TL;DR

This paper introduces a two-stage online human mobility prediction method for metropolitan-scale digital twins, effectively modeling daily variations and complex constraints with high efficiency, enabling real-time citywide mobility forecasting.

Contribution

It proposes a novel two-stage prediction framework that combines coarse trend extraction with fine-grained trajectory retrieval, reducing computational costs for real-time urban mobility prediction.

Findings

Achieved accurate 1-hour mobility predictions for 220K users in about 2 minutes.

Effectively modeled daily mobility variations and complex transportation constraints.

Demonstrated scalability and efficiency on real-world GPS data from Japan.

Abstract

Knowing "what is happening" and "what will happen" of the mobility in a city is the building block of a data-driven smart city system. In recent years, mobility digital twin that makes a virtual replication of human mobility and predicting or simulating the fine-grained movements of the subjects in a virtual space at a metropolitan scale in near real-time has shown its great potential in modern urban intelligent systems. However, few studies have provided practical solutions. The main difficulties are four-folds. 1) The daily variation of human mobility is hard to model and predict; 2) the transportation network enforces a complex constraints on human mobility; 3) generating a rational fine-grained human trajectory is challenging for existing machine learning models; and 4) making a fine-grained prediction incurs high computational costs, which is challenging for an online system. Bearing these difficulties in mind, in this paper we propose a two-stage human mobility predictor that stratifies the coarse and fine-grained level predictions. In the first stage, to encode the daily variation of human mobility at a metropolitan level, we automatically extract citywide mobility trends as crowd contexts and predict long-term and long-distance movements at a coarse level. In the second stage, the coarse predictions are resolved to a fine-grained level via a probabilistic trajectory retrieval method, which offloads most of the heavy computations to the offline phase. We tested our method using a real-world mobile phone GPS dataset in the Kanto area in Japan, and achieved good prediction accuracy and a time efficiency of about 2 min in predicting future 1h movements of about 220K mobile phone users on a single machine to support more higher-level analysis of mobility prediction.