TY - GEN
T1 - Parallel Task Scheduling in Autonomous Robotic Systems
T2 - 53rd International Conference on Parallel Processing, ICPP 2024
AU - Gao, Wen
AU - Yu, Zhiwen
AU - Xiong, Hui
AU - Guo, Bin
AU - Wang, Liang
AU - Yao, Yuan
N1 - Publisher Copyright:
© 2024 Owner/Author.
PY - 2024/8/12
Y1 - 2024/8/12
N2 - In autonomous robotic systems, the parallel processing of multiple tasks often competes for limited resources, affecting system performance and the robot's responsiveness to environmental changes. Traditional computational task scheduling methods often overlook the dynamic nature of task priorities in autonomous robotic systems, where task importance can shift based on interactions with the external environment. Therefore, there's a crucial need for a mechanism capable of adaptively adjusting task scheduling in response to environmental changes, ensuring timely access to resources for critical tasks. To address this challenge, this study presents Priorest, a neural network model that incorporates multimodal data processing and multitask learning. Priorest integrates sensor data with logs monitoring computational device performance to predict events influencing task priority, enabling task adjustments while preserving essential resource allocations. When deployed in autonomous robotic systems, Priorest's event-prediction-based adjustment strategy reduced critical task completion times by 18.7%, which demonstrates the effectiveness of Priorest in enhancing parallel task scheduling.
AB - In autonomous robotic systems, the parallel processing of multiple tasks often competes for limited resources, affecting system performance and the robot's responsiveness to environmental changes. Traditional computational task scheduling methods often overlook the dynamic nature of task priorities in autonomous robotic systems, where task importance can shift based on interactions with the external environment. Therefore, there's a crucial need for a mechanism capable of adaptively adjusting task scheduling in response to environmental changes, ensuring timely access to resources for critical tasks. To address this challenge, this study presents Priorest, a neural network model that incorporates multimodal data processing and multitask learning. Priorest integrates sensor data with logs monitoring computational device performance to predict events influencing task priority, enabling task adjustments while preserving essential resource allocations. When deployed in autonomous robotic systems, Priorest's event-prediction-based adjustment strategy reduced critical task completion times by 18.7%, which demonstrates the effectiveness of Priorest in enhancing parallel task scheduling.
KW - Autonomous robotic systems
KW - event-driven multimodal prediction.
KW - parallel task scheduling
UR - http://www.scopus.com/inward/record.url?scp=85202449818&partnerID=8YFLogxK
U2 - 10.1145/3673038.3673147
DO - 10.1145/3673038.3673147
M3 - 会议稿件
AN - SCOPUS:85202449818
T3 - ACM International Conference Proceeding Series
SP - 742
EP - 751
BT - 53rd International Conference on Parallel Processing, ICPP 2024 - Main Conference Proceedings
PB - Association for Computing Machinery
Y2 - 12 August 2024 through 15 August 2024
ER -