Multi-sensor Data-driven Route Prediction in Instant Delivery with a 3-Conversion Network
Article No.: 50, Pages 1 - 21
Abstract
Route prediction in instant delivery is still challenging due to the unique characteristics compared with conventional delivery services, such as strict deadlines, overlapped delivery time of multiple orders, and diverse individual preferences on delivery routes. Recently, development in the mobile Internet of Things (IoT) offers the opportunity to collect multi-sensor data with rich real-time information. Therefore, this study proposes a route prediction model called Roupid, which leverages multi-sensor data to improve the accuracy of route prediction in instant delivery. Specifically, we design a 3-Conversion Network-based route prediction framework to take full advantage of various information provided by multi-sensor data, including the encounter data sensed by Bluetooth low energy (BLE) beacons, active site data reported by smart handheld devices, and trajectory data detected by GPS. The 3-Conversion Network we propose is based on a deep neural network framework, which integrates an improved relational graph attention network with edge features (RGATE) to encode global information that couriers typically consider when planning routes. We evaluate our Roupid with real-world data collected from one of the largest instant delivery companies in the world, i.e., Eleme. Experimental results show that our Roupid outperforms other state-of-the-art baselines and offers up to 85.51% of the route prediction precision.
References
[1]
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 (KDD’16). 785–794.
[2]
Deliveroo. 2021. Deliveroo. https://deliveroo.co.uk/
[3]
DoorDash. 2021. DoorDash. https://www.doordash.com/
[4]
Eleme. 2021. Eleme. https://www.ele.me/
[5]
Liyu Gong and Qiang Cheng. 2019. Exploiting edge features for graph neural networks. In Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition. 9211–9219.
[6]
Will Hamilton, Zhitao Ying, and Jure Leskovec. 2017. Inductive representation learning on large graphs. Advances in Neural Information Processing Systems 30 (2017), 1025–1035.
[7]
Apple Incorporation. 2021. Ibeacon. https://developer.apple.com/ibeacon/
[8]
InstaCart. 2021. InstaCart. https://www.instacart.com/
[9]
Manpreet Kaur, Flora D. Salim, Yongli Ren, Jeffrey Chan, Martin Tomko, and Mark Sanderson. 2020. Joint modelling of cyber activities and physical context to improve prediction of visitor behaviors. ACM Transactions on Sensor Networks (TOSN) 16, 3 (2020), 1–25.
[10]
P. Diederik Kingma and Lei Jimmy Ba. 2015. Adam: A method for stochastic optimization. In International Conference on Learning Representations.
[11]
N. Thomas Kipf and Max Welling. 2017. Semi-supervised classification with graph convolutional networks. In International Conference on Learning Representations.
[12]
Xiucheng Li, Gao Cong, and Yun Cheng. 2020. Spatial transition learning on road networks with deep probabilistic models. In 2020 IEEE 36th International Conference on Data Engineering (ICDE’20). IEEE, 349–360.
[13]
Meituan. 2021. Meituan. https://www.meituan.com/
[14]
Michael Schlichtkrull, Thomas N. Kipf, Peter Bloem, Rianne van den Berg, Ivan Titov, and Max Welling. 2018. Modeling relational data with graph convolutional networks. In The Semantic Web. Springer, 593–607.
[15]
Zachary Steever, H. Mark Karwan, and C. Chase Murray. 2019. Dynamic courier routing for a food delivery service. Computers & Operations Research 107, (2019), 173–188.
[16]
Kun Su, Yu Xiong, Li Qi, Yu Xia, Baisong Li, Lin Yang, Qin Li, Wenge Tang, Xian Li, Xiaowen Ruan, Shaofeng Lu, Xianxian Chen, Chaobo Shen, Jiaying Xu, Liang Xu, Mei Han, and Jing Xiao. 2018. City-wide influenza forecasting based on multi-source data. In 2018 IEEE International Conference on Big Data (Big Data). IEEE, 3930–3937.
[17]
Danfeng Sun, Jia Wu, Jian Yang, and Huifeng Wu. 2021. Intelligent data collaboration in heterogeneous-device IoT platforms. ACM Transactions on Sensor Networks (TOSN) 17, 3 (2021), 1–17.
[18]
Lisa Natswi Tafa, Xin Su, Jiman Hong, and Chang Choi. 2019. Automatic maritime traffic synthetic route: A framework for route prediction. In International Symposium on Pervasive Systems, Algorithms and Networks. Springer, 3–14.
[19]
Uber. 2021. Uber Eat. https://www.ubereats.com/
[20]
Petar Veličković, Guillem Cucurull, Arantxa Casanova, Adriana Romero, Pietro Lio, and Yoshua Bengio. 2017. Graph attention networks. arXiv preprint arXiv:1710.10903 (2017).
[21]
Jiachuan Wang, Peng Cheng, Libin Zheng, Chao Feng, Lei Chen, Xuemin Lin, and Zheng Wang. 2020. Demand-aware route planning for shared mobility services. Proceedings of the VLDB Endowment 13, 7 (2020), 979–991.
[22]
Wei Wang, Xiaofeng Zhao, Zhiguo Gong, Zhikui Chen, Ning Zhang, and Wei Wei. 2020. An attention-based deep learning framework for trip destination prediction of sharing bike. IEEE Transactions on Intelligent Transportation Systems 22, 7 (2020), 4601–4610.
[23]
Xing Wang, Shengyao Wang, Ling Wang, Huanyu Zheng, Jinghua Hao, Renqing He, and Zhizhao Sun. 2020. An effective iterated greedy algorithm for online route planning problem. In 2020 IEEE Congress on Evolutionary Computation (CEC). IEEE, 1–8.
[24]
Hu Wenjie, Yang Yang, Wang Jianbo, Huang Xuanwen, and Cheng Ziqiang. 2020. Understanding electricity-theft behavior via multi-source data. In The Web Conference, 2264–2274.
[25]
Weihua Yuan, Hong Wang, Baofang Hu, Lutong Wang, and Qian Wang. 2018. Wide and deep model of multi-source information-aware recommender system. IEEE Access 6 (2018), 49385–49398.
[26]
Yan Zhang, Yunhuai Liu, Genjian Li, Yi Ding, Ning Chen, Hao Zhang, Tian He, and Desheng Zhang. 2019. Route prediction for instant delivery. Proceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies 3, 3 (2019), 1–25.
[27]
Zhiyuan Zhou, Xiaolei Zhou, Yao Lu, Hua Yan, Baoshen Guo, and Shuai Wang. 2021. Multi-source data-driven route prediction for instant delivery. In 2021 17th International Conference on Mobility, Sensing and Networking (MSN). IEEE, 374–381.
Index Terms
- Multi-sensor Data-driven Route Prediction in Instant Delivery with a 3-Conversion Network
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Association for Computing Machinery
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Publication History
Published: 16 February 2024
Online AM: 02 January 2024
Accepted: 20 December 2023
Revised: 09 May 2023
Received: 03 July 2022
Published in TOSN Volume 20, Issue 2
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- the Science and Technology Innovation 2030-Major Project
- National Natural Science Foundation of China
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