Scientific Machine Learning-Supported Heterogeneous Track-to-Track Fusion Using Radar and Infrared Sensors

Recep Ayzit; Yasin Baykal; Gokhan Inalhan; Baris Baspinar

doi:10.1109/CCTA53793.2025.11151411

Scientific Machine Learning-Supported Heterogeneous Track-to-Track Fusion Using Radar and Infrared Sensors

Uçak Mühendisliği Bölümü

Istanbul Technical University
Altay Aerospace Technologies

Araştırma sonucu: Kitap/Rapor/Konferans Bildirisinde Bölüm › Konferans katkısı › bilirkişi

Özet

In modern surveillance and defense systems, accurate tracking of aerial and ground targets remains a critical challenge due to the presence of uncertainties and dynamic target maneuvers. This study presents a robust air-to-air and air-to-ground tracking framework that integrates heterogeneous sensor measurements from radar and infrared sensors. The core methodology is based on an Extended Kalman Filter with a constant velocity motion model, further enhanced by heterogeneous track-to-track fusion. To mitigate estimation errors arising from dynamic uncertainties, a scientific machine learning-supported approach is proposed to tune the process noise covariance and sensor trackers' covariances adaptively. The proposed method refines the covariance coefficients to improve tracking accuracy under various maneuvering conditions, including climbing, descending, constant rate turns, and accelerated motions. The optimization is conducted over multiple simulated scenarios, where optimal parameters and estimated state vectors of the tracked objects serve as input features. Neural network models are then trained on these features to generalize the optimization results, enabling real-time estimation of process noise covariance coefficients in unseen scenarios. Experimental evaluations demonstrate the effectiveness of the proposed approach in adapting to dynamic target maneuvers, reducing estimation errors, and improving overall tracking performance.

Orijinal dil	İngilizce
Ana bilgisayar yayını başlığı	2025 IEEE Conference on Control Technology and Applications, CCTA 2025
Editörler	Christopher Vermillion, Sorin Olaru, Johanna Mathieu, Mehmet Mercangoz, Stephanie Stockar, Alireza Karimi, Timm Faulwasser, Eric Kerrigan, Rolf Fineisen, Sebastien Gros, Ionela Prodan, Christopher Edwards, Fabrizio Dabbene, Airlie Chapman, Behrouz Touri
Yayınlayan	Institute of Electrical and Electronics Engineers Inc.
Sayfalar	711-716
Sayfa sayısı	6
ISBN (Elektronik)	9798331539085
DOI'lar	https://doi.org/10.1109/CCTA53793.2025.11151411
Yayın durumu	Yayınlandı - 2025
Etkinlik	9th IEEE Conference on Control Technology and Applications, CCTA 2025 - San Diego, United States Süre: 25 Ağu 2025 → 27 Ağu 2025

Yayın serisi

Adı	2025 IEEE Conference on Control Technology and Applications, CCTA 2025

???event.eventtypes.event.conference???

???event.eventtypes.event.conference???	9th IEEE Conference on Control Technology and Applications, CCTA 2025
Ülke/Bölge	United States
Şehir	San Diego
Periyot	25/08/25 → 27/08/25

Bibliyografik not

Publisher Copyright:
© 2025 IEEE.

Belgeye Erişim

10.1109/CCTA53793.2025.11151411

Diğer Dosyalar ve Linkler

Link to publication in Scopus

Alıntı Yap

Ayzit, R., Baykal, Y., Inalhan, G., & Baspinar, B. (2025). Scientific Machine Learning-Supported Heterogeneous Track-to-Track Fusion Using Radar and Infrared Sensors. In C. Vermillion, S. Olaru, J. Mathieu, M. Mercangoz, S. Stockar, A. Karimi, T. Faulwasser, E. Kerrigan, R. Fineisen, S. Gros, I. Prodan, C. Edwards, F. Dabbene, A. Chapman, & B. Touri (Eds.), 2025 IEEE Conference on Control Technology and Applications, CCTA 2025 (pp. 711-716). (2025 IEEE Conference on Control Technology and Applications, CCTA 2025). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/CCTA53793.2025.11151411

Ayzit, Recep ; Baykal, Yasin ; Inalhan, Gokhan et al. / Scientific Machine Learning-Supported Heterogeneous Track-to-Track Fusion Using Radar and Infrared Sensors. 2025 IEEE Conference on Control Technology and Applications, CCTA 2025. editör / Christopher Vermillion ; Sorin Olaru ; Johanna Mathieu ; Mehmet Mercangoz ; Stephanie Stockar ; Alireza Karimi ; Timm Faulwasser ; Eric Kerrigan ; Rolf Fineisen ; Sebastien Gros ; Ionela Prodan ; Christopher Edwards ; Fabrizio Dabbene ; Airlie Chapman ; Behrouz Touri. Institute of Electrical and Electronics Engineers Inc., 2025. pp. 711-716 (2025 IEEE Conference on Control Technology and Applications, CCTA 2025).

@inproceedings{45812ed2df7d4221b4048c950f6a1ea9,

title = "Scientific Machine Learning-Supported Heterogeneous Track-to-Track Fusion Using Radar and Infrared Sensors",

abstract = "In modern surveillance and defense systems, accurate tracking of aerial and ground targets remains a critical challenge due to the presence of uncertainties and dynamic target maneuvers. This study presents a robust air-to-air and air-to-ground tracking framework that integrates heterogeneous sensor measurements from radar and infrared sensors. The core methodology is based on an Extended Kalman Filter with a constant velocity motion model, further enhanced by heterogeneous track-to-track fusion. To mitigate estimation errors arising from dynamic uncertainties, a scientific machine learning-supported approach is proposed to tune the process noise covariance and sensor trackers' covariances adaptively. The proposed method refines the covariance coefficients to improve tracking accuracy under various maneuvering conditions, including climbing, descending, constant rate turns, and accelerated motions. The optimization is conducted over multiple simulated scenarios, where optimal parameters and estimated state vectors of the tracked objects serve as input features. Neural network models are then trained on these features to generalize the optimization results, enabling real-time estimation of process noise covariance coefficients in unseen scenarios. Experimental evaluations demonstrate the effectiveness of the proposed approach in adapting to dynamic target maneuvers, reducing estimation errors, and improving overall tracking performance.",

keywords = "Scientific machine learning, heterogeneous track-to-track fusion, neural network, parameter optimization",

author = "Recep Ayzit and Yasin Baykal and Gokhan Inalhan and Baris Baspinar",

note = "Publisher Copyright: {\textcopyright} 2025 IEEE.; 9th IEEE Conference on Control Technology and Applications, CCTA 2025 ; Conference date: 25-08-2025 Through 27-08-2025",

year = "2025",

doi = "10.1109/CCTA53793.2025.11151411",

language = "English",

series = "2025 IEEE Conference on Control Technology and Applications, CCTA 2025",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

pages = "711--716",

editor = "Christopher Vermillion and Sorin Olaru and Johanna Mathieu and Mehmet Mercangoz and Stephanie Stockar and Alireza Karimi and Timm Faulwasser and Eric Kerrigan and Rolf Fineisen and Sebastien Gros and Ionela Prodan and Christopher Edwards and Fabrizio Dabbene and Airlie Chapman and Behrouz Touri",

booktitle = "2025 IEEE Conference on Control Technology and Applications, CCTA 2025",

address = "United States",

}

Ayzit, R, Baykal, Y, Inalhan, G & Baspinar, B 2025, Scientific Machine Learning-Supported Heterogeneous Track-to-Track Fusion Using Radar and Infrared Sensors. in C Vermillion, S Olaru, J Mathieu, M Mercangoz, S Stockar, A Karimi, T Faulwasser, E Kerrigan, R Fineisen, S Gros, I Prodan, C Edwards, F Dabbene, A Chapman & B Touri (eds), 2025 IEEE Conference on Control Technology and Applications, CCTA 2025. 2025 IEEE Conference on Control Technology and Applications, CCTA 2025, Institute of Electrical and Electronics Engineers Inc., pp. 711-716, 9th IEEE Conference on Control Technology and Applications, CCTA 2025, San Diego, United States, 25/08/25. https://doi.org/10.1109/CCTA53793.2025.11151411

Scientific Machine Learning-Supported Heterogeneous Track-to-Track Fusion Using Radar and Infrared Sensors. / Ayzit, Recep; Baykal, Yasin; Inalhan, Gokhan et al.
2025 IEEE Conference on Control Technology and Applications, CCTA 2025. ed. / Christopher Vermillion; Sorin Olaru; Johanna Mathieu; Mehmet Mercangoz; Stephanie Stockar; Alireza Karimi; Timm Faulwasser; Eric Kerrigan; Rolf Fineisen; Sebastien Gros; Ionela Prodan; Christopher Edwards; Fabrizio Dabbene; Airlie Chapman; Behrouz Touri. Institute of Electrical and Electronics Engineers Inc., 2025. p. 711-716 (2025 IEEE Conference on Control Technology and Applications, CCTA 2025).

Araştırma sonucu: Kitap/Rapor/Konferans Bildirisinde Bölüm › Konferans katkısı › bilirkişi

TY - GEN

T1 - Scientific Machine Learning-Supported Heterogeneous Track-to-Track Fusion Using Radar and Infrared Sensors

AU - Ayzit, Recep

AU - Baykal, Yasin

AU - Inalhan, Gokhan

AU - Baspinar, Baris

PY - 2025

Y1 - 2025

N2 - In modern surveillance and defense systems, accurate tracking of aerial and ground targets remains a critical challenge due to the presence of uncertainties and dynamic target maneuvers. This study presents a robust air-to-air and air-to-ground tracking framework that integrates heterogeneous sensor measurements from radar and infrared sensors. The core methodology is based on an Extended Kalman Filter with a constant velocity motion model, further enhanced by heterogeneous track-to-track fusion. To mitigate estimation errors arising from dynamic uncertainties, a scientific machine learning-supported approach is proposed to tune the process noise covariance and sensor trackers' covariances adaptively. The proposed method refines the covariance coefficients to improve tracking accuracy under various maneuvering conditions, including climbing, descending, constant rate turns, and accelerated motions. The optimization is conducted over multiple simulated scenarios, where optimal parameters and estimated state vectors of the tracked objects serve as input features. Neural network models are then trained on these features to generalize the optimization results, enabling real-time estimation of process noise covariance coefficients in unseen scenarios. Experimental evaluations demonstrate the effectiveness of the proposed approach in adapting to dynamic target maneuvers, reducing estimation errors, and improving overall tracking performance.

AB - In modern surveillance and defense systems, accurate tracking of aerial and ground targets remains a critical challenge due to the presence of uncertainties and dynamic target maneuvers. This study presents a robust air-to-air and air-to-ground tracking framework that integrates heterogeneous sensor measurements from radar and infrared sensors. The core methodology is based on an Extended Kalman Filter with a constant velocity motion model, further enhanced by heterogeneous track-to-track fusion. To mitigate estimation errors arising from dynamic uncertainties, a scientific machine learning-supported approach is proposed to tune the process noise covariance and sensor trackers' covariances adaptively. The proposed method refines the covariance coefficients to improve tracking accuracy under various maneuvering conditions, including climbing, descending, constant rate turns, and accelerated motions. The optimization is conducted over multiple simulated scenarios, where optimal parameters and estimated state vectors of the tracked objects serve as input features. Neural network models are then trained on these features to generalize the optimization results, enabling real-time estimation of process noise covariance coefficients in unseen scenarios. Experimental evaluations demonstrate the effectiveness of the proposed approach in adapting to dynamic target maneuvers, reducing estimation errors, and improving overall tracking performance.

KW - Scientific machine learning

KW - heterogeneous track-to-track fusion

KW - neural network

KW - parameter optimization

UR - https://www.scopus.com/pages/publications/105017853166

U2 - 10.1109/CCTA53793.2025.11151411

DO - 10.1109/CCTA53793.2025.11151411

M3 - Conference contribution

AN - SCOPUS:105017853166

T3 - 2025 IEEE Conference on Control Technology and Applications, CCTA 2025

SP - 711

EP - 716

BT - 2025 IEEE Conference on Control Technology and Applications, CCTA 2025

A2 - Vermillion, Christopher

A2 - Olaru, Sorin

A2 - Mathieu, Johanna

A2 - Mercangoz, Mehmet

A2 - Stockar, Stephanie

A2 - Karimi, Alireza

A2 - Faulwasser, Timm

A2 - Kerrigan, Eric

A2 - Fineisen, Rolf

A2 - Gros, Sebastien

A2 - Prodan, Ionela

A2 - Edwards, Christopher

A2 - Dabbene, Fabrizio

A2 - Chapman, Airlie

A2 - Touri, Behrouz

PB - Institute of Electrical and Electronics Engineers Inc.

T2 - 9th IEEE Conference on Control Technology and Applications, CCTA 2025

Y2 - 25 August 2025 through 27 August 2025

ER -

Ayzit R, Baykal Y, Inalhan G , Baspinar B. Scientific Machine Learning-Supported Heterogeneous Track-to-Track Fusion Using Radar and Infrared Sensors. In Vermillion C, Olaru S, Mathieu J, Mercangoz M, Stockar S, Karimi A, Faulwasser T, Kerrigan E, Fineisen R, Gros S, Prodan I, Edwards C, Dabbene F, Chapman A, Touri B, editörler, 2025 IEEE Conference on Control Technology and Applications, CCTA 2025. Institute of Electrical and Electronics Engineers Inc. 2025. p. 711-716. (2025 IEEE Conference on Control Technology and Applications, CCTA 2025). doi: 10.1109/CCTA53793.2025.11151411

Scientific Machine Learning-Supported Heterogeneous Track-to-Track Fusion Using Radar and Infrared Sensors

Özet

Yayın serisi

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Bibliyografik not

Belgeye Erişim

Diğer Dosyalar ve Linkler

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