Journal of Zhejiang University

ENGINEERING Information Technology & Electronic Engineering

Accepted manuscript available online (unedited version)

High-precision temperature prediction under atmospheric refractivity cor-rection using Kalman spatiotemporal data fusion

Author(s): Ziru LI^1, ^2, ³, Zhaobin XU^1, ^2, ^3*, Tao ZHANG^1, ^2, ³, Xinbo YUAN^1, ^2, ³, Zhonghe JIN^1, ^2, ³
Affiliation(s): ¹Micro-Satellite Research Center, Zhejiang University, Hangzhou 310027, China ²Huanjiang Laboratory, Zhuji 311899, China ³Key Laboratory of Micro-Nano Satellite Research Zhejiang Province, Hangzhou 310027, China
Corresponding email(s): Zhaobin XU, zjuxzb@zju.edu.cn
Key Words: Temperature prediction; Kalman filter expanded fusion (KFEF); Atmospheric refraction correction; Absolute distance measurement; GRNN optimization

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Ziru LI^1,^2,³, Zhaobin XU^1,^2,^3*, Tao ZHANG^1,^2,³, Xinbo YUAN^1,^2,³, Zhonghe JIN^1,^2,³. High-precision temperature prediction under atmospheric refractivity cor-rection using Kalman spatiotemporal data fusion[J]. Journal of Zhejiang University Science ,in press.Frontiers of Information Technology & Electronic Engineering,in press.https://doi.org/10.1631/ENG.ITEE.2025.0005

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journal="Journal of Zhejiang University Science ",
year="in press",
publisher="Zhejiang University Press & Springer",
doi="https://doi.org/10.1631/ENG.ITEE.2025.0005"
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Abstract
Chinese Summary
Academic Network
Reviewer Comment

Abstract: In absolute distance measurement and positioning applications, atmospheric refraction error is a critical factor limiting measurement accuracy. Temperature plays a dominant role in computing the atmospheric refractive index. However, accurately acquiring the temperature field along the ranging path in complex and dynamic outdoor environments remains challenging due to limited sensor deployment and environmental nonstationarity. This paper proposes a spatiotemporal temperature data fusion method for atmospheric refraction correction,which integrates the strengths of the generalized regression neural network (GRNN) and kriging interpolation within a Kalman filter. This method achieves dynamic prediction and high-accuracy reconstruction of temperature parameters. The proposed method is systematically validated through simulation analysis as well as indoor and kilometer-scale outdoor experimental measurements. The simulation results demonstrate that KFEF outperforms the traditional interpolation method RBF as well as the advanced spatiotemporal interpolation and prediction methods STK and GP in terms of both reconstruction accuracy and stability of the temperature field. Specifically, KFEF achieves a 61.54% reduction in RMSE compared with RBF and reductions of 34.21% and 32.43% relative to STK and GP, respectively. This indicates its strong practical value for long-distance high-precision ranging engineering applications. Furthermore, the proposed spatiotemporal data fusion framework is highly general and scalable. It can also be applied to other temperature field prediction and reconstruction problems.

FTHOE：一种面向晶圆级互连网络的哈密顿驱动容错路由算法

侯帅康¹，刘勤让²，张文博¹，吕平¹，李沛杰¹，郭威¹
¹信息工程大学，中国郑州市，450001
²复旦大学大数据研究院，中国上海市，200433
摘要：随着应用场景日益复杂，晶圆级系统对互连网络可靠性提出愈发严苛的要求。在不可避免的工艺制造缺陷和环境干扰下，晶圆级互连网络中节点和链路故障频发，使得容错能力成为提升系统整体可靠性关键因素。针对晶圆级互连网络中的芯片粒节点故障和链路故障，本文提出一种名为FTHOE的负载均衡无虚通道容错路由算法。该算法基于哈密顿路由策略和奇偶转向模型，通过利用当前节点的本地故障向量信息，动态调整输出端口选择优先级，从而在绕开故障区域时缩短迂回路径，并有效降低数据包陷入故障邻域的概率。同时，FTHOE在故障条件下保留了哈密顿路由的自适应特性，维持较高的最短路径多样性，进而增强网络负载均衡能力与整体通信性能。仿真结果表明，与现有容错路由算法相比，FTHOE显著降低了平均网络延迟并提高了吞吐量，在复杂故障场景下展现出鲁棒的容错能力和负载均衡性能。

关键词组：晶圆级系统；容错；哈密顿路径；奇偶转向模型；负载均衡

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