Rohan Kapoor

RMIT University, School of Engineering, Aerospace and Aviation Discipline, Graduate Student

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Ellips Masehian

California State Polytechnic University at Pomona

Christian Hempstead

US Merchant Marine Academy

Remo Caponi

University of Cologne

Steven Seegel

The University of Texas at Austin

S. M. Nima Shojaee

Islamic Azad University, Science and Research Branch

Chenhao Qi

Southeast University (China)

Bülent Yilmazer

Middle East Technical University

Felipe N Martins

Hanze University of Applied Sciences

Subramanian Ramasamy

RMIT University

Alessandro Gardi

Khalifa University

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A Multistatic Ultrasonic Navigation System for GNSS-denied Environments

AIAA Scitech 2019 Forum, 2019

This paper presents a novel indoor navigation technique using acoustic sensors, with emphasis on ... more This paper presents a novel indoor navigation technique using acoustic sensors, with emphasis on performance modeling and the system layout. Acoustic transmitters are arranged at known fixed locations and broadcast their respective signals following a Time Division Multiple Access (TDMA) scheme. The receiver position is calculated based on Time of Arrival (TOA) based ranging measurements from a minimum of four transmitters. The transmitters are arranged optimally to minimize Position Dilution of Precision (PDOP) as well as maximizing sensor availability. The proposed technique can provide accurate navigation observables in indoor environments, where conventional satellite-based navigation systems cannot deliver the required Position, Velocity, and Time (PVT) data. Additionally, being based on acoustic signals, it is immune to signal-in-space electromagnetic interferences. The TDMA based acoustic navigation system is described, with potential errors in ranging due to Doppler effect, multipath, atmospheric propagation, and signal delays. The error in positioning due to platform dynamics is also discussed. This analysis will lead to an optimized arrangement of transmitters supporting the future ground and flight experimental activities.

Network Optimization for Multistatic Ultrasonic Sensors Based Indoor Navigation System

2018 5th IEEE International Workshop on Metrology for AeroSpace (MetroAeroSpace), 2018

This paper presents a novel indoor navigation technique using acoustic sensors, with emphasis on ... more This paper presents a novel indoor navigation technique using acoustic sensors, with emphasis on performance modelling and the system layout optimisation. Acoustic transmitters are arranged at known fixed locations and broadcast their respective signals following a Time Division Multiple Access (TDMA) scheme. The receiver position is calculated based on ranging measurements from a minimum of four transmitters. The range is calculated based on time-of-flight (TOF) of acoustic waves from the transmitter to the receiver. The transmitters are arranged optimally to minimize Position Dilution of Precision (PDOP). Optimizing the location of transmitters for minimum PDOP also leads to better coverage in the indoor environment, where conventional satellite based navigation systems cannot deliver the required Position, Velocity and Time (PVT) data. The attenuation of sound in air is discussed along with potential ranging errors and signal delays. Simulations are carried out to optimize the arrangement of transmitters for future experiments with indoor air and surface vehicles.

Acoustic Positioning and Navigation System for Micro Aerial Vehicle Navigation

2020 AIAA/IEEE 39th Digital Avionics Systems Conference (DASC), 2020

Animals, especially mammals like bats and dolphins, use acoustic waves that vary in frequency, si... more Animals, especially mammals like bats and dolphins, use acoustic waves that vary in frequency, signal duration, and intensity, for navigation and tracking. The directionality of acoustic waves has also been long used for localization by human beings. The term ‘echolocation’ was coined by Donald R. Griffin, where he discusses ship captains exploiting sound to ascertain the ship's surroundings and avoid obstacles in low-visibility environments. Acoustic sensors can provide a low-cost, size, weight, and power (C-SWaP) navigation solution, which is scalable and robust. Moreover, acoustic sensors have the capability to provide high-resolution spatial information at short distance range. This paper presents a novel acoustic positioning and navigation system for a micro aerial vehicle. Flight tests are performed to evaluate the system, where the performance of the acoustic system is compared with a motion capture system.

Advances in Integrated System Health Management for mission-essential and safety-critical aerospace applications

Progress in Aerospace Sciences, 2022

Integrated System Health Management (ISHM) is a promising technology that fuses sensor data and h... more Integrated System Health Management (ISHM) is a promising technology that fuses sensor data and historical state-of-health information of components and subsystems to provide actionable information and enable intelligent decision-making regarding the operation and maintenance of aerospace systems. ISHM fundamentally relies on assessments and predictions of system health, including the early detection of failures and estimation of Remaining Useful Life (RUL). Model-based, data-driven or hybrid reasoning techniques can be utilized to maximise the timeliness and reliability of diagnosis and prognosis information. The benefits of ISHM include enhancing the maintainability, reliability, safety and performance of systems. The next evolution of the ISHM concept, Intelligent Health and Mission Management (IHMM), delves deeper into the utilization of on-line system health predictions to modify mission profiles to ensure safety and reliability, as well as efficiency through predictive integrity. This concept is particularly important for Trusted Autonomous System (TAS) applications, where an accurate assessment of the current and future system state-of-health to make operational decisions (with or without human intervention) is integral to both flight safety and mission success. IHMM systems introduce the capability of predicting degradation in the functional performance of subsystems, with sufficient time to dynamically identify which appropriate restorative or reconfiguration actions to take in order to ensure that the system can perform at an acceptable level of operational capability before the onset of a failure event. This paper reviews some of the key advancements and contributions to knowledge in the field of ISHM for the aerospace industry, with a particular focus on various architectures and reasoning strategies involving the use of artificial intelligence. The paper also discusses the key challenges faced in the development and deployment of ISHM systems in the aerospace industry and highlights the safety-critical role that IHMM will play in future cyber-physical and autonomous system applications (both vehicle and ground support systems), such as Unmanned Aircraft Systems (UAS) Traffic Management (UTM), Urban Air Mobility (UAM) and Distributed Satellite Systems (DSS).

Acoustic Sensors for Air and Surface Navigation Applications

Sensors (Basel, Switzerland), Jan 7, 2018

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