A novel elliptic trajectory formula for active RSSI-based antenna tracking algorithm

İşcan, M. Ya̧sar; Tas, Ali Ihsan; Gurkan, Berkay; Yilmaz, Cüneyt

doi:10.1177/01423312231170925

Cited by 3 publications

References 22 publications

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An intelligent aortic valve model for complete cardiac cycle

Iscan,

Yesildirek

2024

Numer Methods Biomed Eng

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The aortic valve (AV) is crucial for cardiovascular (CV) hemodynamic, impacting cardiac output (CO) and left ventricular volumetric flow rate (LVQ). Its nonlinear behavior challenges standard LVQ prediction methods as well as CO one. This study presents a novel approach for modeling the AV in the CV system, offering an improved method for estimating crucial parameters like LVQ across various AV conditions, including aortic stenosis (AS). The model, based on AV channel length during the entire cardiac phase, introduces a time‐varying AV resistance (TV‐AVR) parameterized by the pressure ratio across the AV and LVQ, enabling the simulation of both healthy and AS‐related conditions. To validate this model, in vitro measurements are compared using a hybrid mock circulatory loop device. An unconventional use of a convolutional neural network (CNN) corrects the model's estimates, eliminating the need for labeled datasets. This approach, incorporating real‐time learning and transforming 1‐D CV signals into 2‐D tensors, significantly improves the accuracy of LVQ measurements, achieving an error rate of less than 3.41 ± 4.84% for CO in healthy conditions and 2.83 ± 1.35% in AS cases—a 33.13% enhancement over linear diode models. These results underscore the potential of this approach for enhancing the diagnosis, prediction, and treatment of AV diseases. The key contributions of the proposed method encompass nonlinear TV‐AVR estimation, investigation of transient CV responses, prediction of instantaneous CO, development of a flexible framework for noninvasive measurements integration, and the introduction of an adjustable resistance model using an extended Kalman filter (EKF) and CNN combination, all without requiring labeled data.

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An intelligent aortic valve model for complete cardiac cycle

Iscan,

Yesildirek

2024

Numer Methods Biomed Eng

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Two Axis Feedback System for Radiosonde Antenna Tracker Controller

Dwi Oktaviani,

Okta Wiyagi,

Ardiyanto

2023

2023 3rd International Conference on Electronic and Electrical Engineering and Intelligent System (ICE3IS)

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Adaptive elliptic trajectory-based received signal strength indicator antenna tracking algorithm

Tas,

Iscan,

Gurkan

et al. 2023

Transactions of the Institute of Measurement and Control

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The continuous telemetry transmission between unmanned aerial vehicles (UAVs) and ground control stations is important particularly in scenarios lacking global positioning system (GPS) data. This paper proposes an adaptive novel elliptic trajectory formula-based tracking algorithm for received signal strength indicator (ANETF-RSSI) which dynamically optimizes model parameters based on energy-associated RSSI measurement errors. ANETF-RSSI generates a variable two-dimensional (2D) RSSI map to identify optimal paths, even under challenging conditions like circular flight paths, varying operating ranges, and accelerated maneuvering, which causes uncertainty into RSSI measurements during flight. In contrast to previous methods, the proposed approach eliminates the reliance on telemetry data such as GPS or complex multiantenna configurations, ensuring robust UAV communication continuity across routes ranging from 100 m to 100 km, even as the UAV rotates around the antenna. This method offers substantial contributions, including enhanced monitoring precision, simplified hardware configurations, continuous tracking with superior accuracy, and adaptability to diverse range routes without the need for preflight parameter tuning. Performance evaluations demonstrate that the proposed ANETF-RSSI method consistently outperforms existing technique, improving nominal performance by 32.02% in the most challenging operational scenarios and achieving a remarkable 48.76% improvement in minimum RSSI values. Consequently, this research provides a versatile and adaptive tracking solution for unexpected UAV flight trajectories.

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A novel elliptic trajectory formula for active RSSI-based antenna tracking algorithm

Cited by 3 publications

References 22 publications

An intelligent aortic valve model for complete cardiac cycle

An intelligent aortic valve model for complete cardiac cycle

Two Axis Feedback System for Radiosonde Antenna Tracker Controller

Adaptive elliptic trajectory-based received signal strength indicator antenna tracking algorithm

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