Gct-TTE: graph convolutional transformer for travel time estimation

被引：6

作者：

Mashurov, Vladimir ^{[1
]}

Chopuryan, Vaagn ^{[1
]}

Porvatov, Vadim ^{[1
,2
]}

Ivanov, Arseny ^{[2
]}

Semenova, Natalia ^{[1
,3
]}

机构：

[1] PJSC Sberbank, Vavilova St, Moscow 117312, Russia

[2] Natl Univ Sci & Technol MISiS, Lenin Ave 4, Moscow 119049, Russia

[3] Artificial Intelligence Res Inst, Nizhny Susalny Lane 5, Moscow 105064, Russia

来源：

JOURNAL OF BIG DATA | 2024年 / 11卷 / 01期

关键词：

Machine learning; Graph convolutional networks; Transformers; Geospatial data; Travel time estimation;

D O I：

10.1186/s40537-023-00841-1

中图分类号：

TP301 [理论、方法];

学科分类号：

081202 ;

摘要：

This paper introduces a new transformer-based model for the problem of travel time estimation. The key feature of the proposed GCT-TTE architecture is the utilization of different data modalities capturing different properties of an input path. Along with the extensive study regarding the model configuration, we implemented and evaluated a sufficient number of actual baselines for path-aware and path-blind settings. The conducted computational experiments have confirmed the viability of our pipeline, which outperformed state-of-the-art models on both considered datasets. Additionally, GCT-TTE was deployed as a web service accessible for further experiments with user-defined routes.

引用

页数：14

共 50 条

[31] Travel Time of Public Transport Vehicles Estimation
Birr, Krystian
Jamroz, Kazimierz
Kustra, Wojciech
17TH MEETING OF THE EURO WORKING GROUP ON TRANSPORTATION, EWGT2014, 2014, 3 : 359 - 365
[32] Vehicle travel time estimation by sparse trajectories
Jiang, Mingyang
Zhao, Tianqi
2019 IEEE 43RD ANNUAL COMPUTER SOFTWARE AND APPLICATIONS CONFERENCE (COMPSAC), VOL 1, 2019, : 433 - 442
[33] Reliability of Bluetooth Technology for Travel Time Estimation
Araghi, Bahar Namaki
Olesen, Jonas Hammershoj
Krishnan, Rajesh
Christensen, Lars Torholm
Lahrmann, Harry
JOURNAL OF INTELLIGENT TRANSPORTATION SYSTEMS, 2015, 19 (03) : 240 - 255
[34] Improving Maliciousness Estimation of Indicator of Compromise Using Graph Convolutional Networks
Kazato, Yuta
Nakagawa, Yoshihide
Nakatani, Yuichi
2020 IEEE 17TH ANNUAL CONSUMER COMMUNICATIONS & NETWORKING CONFERENCE (CCNC 2020), 2020,
[35] Structure-aware human pose estimation with graph convolutional networks
Bin, Yanrui
Chen, Zhao-Min
Wei, Xiu-Shen
Chen, Xinya
Gao, Changxin
Sang, Nong
PATTERN RECOGNITION, 2020, 106
[36] Estimation of Graph Convolutional Network in Ames Prediction of Drug Candidate Compounds
Handa, Chiaki
Ozawa, Tomonaga
Fukuzawa, Kaori
Yonemochi, Etsuo
JOURNAL OF COMPUTER CHEMISTRY-JAPAN, 2021, 20 (01) : 1 - 9
[37] Route to Time and Time to Route: Travel Time Estimation from Sparse Trajectories
Zhang, Zhiwen
Wang, Hongjun
Fan, Zipei
Chen, Jiyuan
Song, Xuan
Shibasaki, Ryosuke
MACHINE LEARNING AND KNOWLEDGE DISCOVERY IN DATABASES, ECML PKDD 2022, PT VI, 2023, 13718 : 489 - 504
[38] Evaluation of floating car technologies for travel time estimation
Steven CHIEN
Kitae KIM
Journal of Modern Transportation, 2012, (01) : 49 - 56
[39] Travel-Time Estimation by Cubic Hermite Curve
Tamin, Owen
Ikram, Badrul
Ramli, Ahmad Lutfi Amri
Moung, Ervin Gubin
Yee, Christie Chin Pei
INFORMATION, 2022, 13 (07)
[40] VEHICLE TRAVEL TIME ESTIMATION USING SEQUENCE PREDICTION
Gunduz, Gultekin
Acarman, Tankut
PROMET-TRAFFIC & TRANSPORTATION, 2020, 32 (01): : 1 - 12

← 1 2 3 4 5 →