TY - JOUR
T1 - Utilizing a Diffusion Model for Pedestrian Trajectory Prediction in Semi-Open Autonomous Driving Environments
AU - Tang, Yingjuan
AU - He, Hongwen
AU - Wang, Yong
AU - Wu, Yifan
N1 - Publisher Copyright:
IEEE
PY - 2024
Y1 - 2024
N2 - In recent years, the pervasive deployment and progression of autonomous driving technology have engendered heightened demands, particularly within the intricate campus and surrounding environments frequently traversed by autonomous delivery vehicles, such as automated food delivery and courier services. Accurately predicting pedestrian trajectories is paramount in the realm of autonomous driving. In the face of complex scenarios within campus and surrounding environments, traditional pedestrian trajectory prediction methods have failed to achieve satisfactory results. To address this challenge systematically, this paper employs a digital twin methodology to establish a novel dataset, denoted as the vulnerable pedestrian trajectory prediction dataset (VPT), grounded in the authentic road network structures of six campuses and their environs. This paper proposed a UTD-PTP trajectory prediction framework based on the diffusion model, which seeks to forecast pedestrian trajectories in settings characterized by heightened pedestrian traffic, disorderliness, and irregularities. Importantly, the applicability of our proposed methodology extends beyond campus environments, showcasing commendable performance on standard autonomous driving datasets. Experimental results reveal an average enhancement of 0.03 in ADE and 0.05 in FDE on publicly available datasets. On the VPT dataset, our method demonstrates substantial improvements of 0.12 in ADE and 0.38 in FDE relative to the baseline model. Overall, our proposed method exhibits superiority in pedestrian trajectory prediction models, substantially reinforcing confidence in the safety of vulnerable road users in autonomous driving.
AB - In recent years, the pervasive deployment and progression of autonomous driving technology have engendered heightened demands, particularly within the intricate campus and surrounding environments frequently traversed by autonomous delivery vehicles, such as automated food delivery and courier services. Accurately predicting pedestrian trajectories is paramount in the realm of autonomous driving. In the face of complex scenarios within campus and surrounding environments, traditional pedestrian trajectory prediction methods have failed to achieve satisfactory results. To address this challenge systematically, this paper employs a digital twin methodology to establish a novel dataset, denoted as the vulnerable pedestrian trajectory prediction dataset (VPT), grounded in the authentic road network structures of six campuses and their environs. This paper proposed a UTD-PTP trajectory prediction framework based on the diffusion model, which seeks to forecast pedestrian trajectories in settings characterized by heightened pedestrian traffic, disorderliness, and irregularities. Importantly, the applicability of our proposed methodology extends beyond campus environments, showcasing commendable performance on standard autonomous driving datasets. Experimental results reveal an average enhancement of 0.03 in ADE and 0.05 in FDE on publicly available datasets. On the VPT dataset, our method demonstrates substantial improvements of 0.12 in ADE and 0.38 in FDE relative to the baseline model. Overall, our proposed method exhibits superiority in pedestrian trajectory prediction models, substantially reinforcing confidence in the safety of vulnerable road users in autonomous driving.
KW - Autonomous driving
KW - Autonomous vehicles
KW - Computational modeling
KW - Pedestrians
KW - Predictive models
KW - Sensors
KW - Trajectory
KW - Uncertainty
KW - data-driven model
KW - diffusion model
KW - pedestrian trajectory prediction
KW - vulnerable traffic participants
UR - http://www.scopus.com/inward/record.url?scp=85189777210&partnerID=8YFLogxK
U2 - 10.1109/JSEN.2024.3382406
DO - 10.1109/JSEN.2024.3382406
M3 - Article
AN - SCOPUS:85189777210
SN - 1530-437X
SP - 1
JO - IEEE Sensors Journal
JF - IEEE Sensors Journal
ER -