Gespeichert in:
Bibliographische Detailangaben
Hauptverfasser: Zhu, Yixuan, Zhang, Bo, Gao, Yinkang, Ren, Haoyuan, Tang, Cheng, Zhao, Caixu, Gong, Lei, Wang, Teng, Lou, Wenqi, Li, Xi
Format: Preprint
Veröffentlicht: 2026
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2604.09102
Tags: Tag hinzufügen
Keine Tags, Fügen Sie den ersten Tag hinzu!
_version_ 1866913021155082240
author Zhu, Yixuan
Zhang, Bo
Gao, Yinkang
Ren, Haoyuan
Tang, Cheng
Zhao, Caixu
Gong, Lei
Wang, Teng
Lou, Wenqi
Li, Xi
author_facet Zhu, Yixuan
Zhang, Bo
Gao, Yinkang
Ren, Haoyuan
Tang, Cheng
Zhao, Caixu
Gong, Lei
Wang, Teng
Lou, Wenqi
Li, Xi
contents In real-time systems, both individual task execution and data propagation must meet strict timing constraints. Cause-effect (CE) chains are widely used to analyze such behaviors by end-to-end latency. However, timing anomalies (TAs) can distort it, where a local reduction in execution times leads to an increase in the overall end-to-end latency. As a result, precisely analyzing the upper bounds of the latency becomes challenging, and such systems typically exhibit larger upper bounds than TA-eliminated systems. Existing studies either eliminate TAs by completely sacrificing average latency to simplify analysis or, despite adopting complex safe analysis methods, do not eliminate TAs effectively, still having high latencies. To address this issue, we identify two basic causes of TAs in end-to-end latency. Based on these causes, we propose the first treatment that eliminates TAs in the latency with negligible average latency loss using Deterministic Data Flow (DDF). We further formally prove its TA-free property. Therefore, we can get a precise upper bound for latency when all jobs execute with their worst-case execution times. Experimental results show that it effectively reduces the maximum end-to-end latency, the average latency, and latency jitter compared with the state-of-the-art (SOTA) method.
format Preprint
id arxiv_https___arxiv_org_abs_2604_09102
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Scheduling Cause-Effect Chains without Timing Anomalies in End-to-End Latency
Zhu, Yixuan
Zhang, Bo
Gao, Yinkang
Ren, Haoyuan
Tang, Cheng
Zhao, Caixu
Gong, Lei
Wang, Teng
Lou, Wenqi
Li, Xi
Systems and Control
In real-time systems, both individual task execution and data propagation must meet strict timing constraints. Cause-effect (CE) chains are widely used to analyze such behaviors by end-to-end latency. However, timing anomalies (TAs) can distort it, where a local reduction in execution times leads to an increase in the overall end-to-end latency. As a result, precisely analyzing the upper bounds of the latency becomes challenging, and such systems typically exhibit larger upper bounds than TA-eliminated systems. Existing studies either eliminate TAs by completely sacrificing average latency to simplify analysis or, despite adopting complex safe analysis methods, do not eliminate TAs effectively, still having high latencies. To address this issue, we identify two basic causes of TAs in end-to-end latency. Based on these causes, we propose the first treatment that eliminates TAs in the latency with negligible average latency loss using Deterministic Data Flow (DDF). We further formally prove its TA-free property. Therefore, we can get a precise upper bound for latency when all jobs execute with their worst-case execution times. Experimental results show that it effectively reduces the maximum end-to-end latency, the average latency, and latency jitter compared with the state-of-the-art (SOTA) method.
title Scheduling Cause-Effect Chains without Timing Anomalies in End-to-End Latency
topic Systems and Control
url https://arxiv.org/abs/2604.09102