High-Precision Low-Cost Gimballing Platform for Long-Range Railway Obstacle Detection

Assaf, Elio Hajj; Cornelius, von Einem,; Cadena, César; Siegwart, Roland; Tschopp, Florian

doi:10.3390/s22020474

Cited by 5 publications

(2 citation statements)

References 130 publications

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“…The gearbox is placed between the motor and the encoder to correct for any potential backlash. 33 The small form factor of the DYNAMIXEL actuator allows it to sit on the central axis of the Filter-Tilter. This direct drive placement allows the angle sensor in the actuator to directly measure the rotation position angle of the filter.…”

Section: Filter-tilter Accuracymentioning

confidence: 99%

The Dragonfly Spectral Line Mapper: design and first light

Chen

Lokhorst

Shen

et al. 2022

Ground-Based and Airborne Telescopes IX

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The Dragonfly Spectral Line Mapper (DSLM) is the latest evolution of the Dragonfly Telephoto Array, which turns it into the world's most powerful wide-field spectral line imager. The DSLM will be the equivalent of a 1.6m aperture f /0.26 refractor with a built-in Integral Field Spectrometer, covering a five square degree field of view. The new telescope is designed to carry out ultra-narrow bandpass imaging of the low surface brightness universe with exquisite control over systematic errors, including real-time calibration of atmospheric variations in airglow. The key to Dragonfly's transformation is the "Filter-Tilter", a mechanical assembly which holds ultra-narrow bandpass interference filters in front of each lens in the array and tilts them to smoothly shift their central wavelength. Here we describe our development process based on rapid prototyping, iterative design, and mass production. This process has resulted in numerous improvements to the design of the DSLM from the initial pathfinder instrument, including changes to narrower bandpass filters and the addition of a suite of calibration filters for continuum light subtraction and sky line monitoring. Improvements have also been made to the electronics and hardware of the array, which improve tilting accuracy, rigidity and light baffling. Here we present laboratory and on-sky measurements from the deployment of the first bank of lenses in May 2022, and a progress report on the completion of the full array in early 2023.

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Section: Filter-tilter Accuracymentioning

confidence: 99%

The Dragonfly Spectral Line Mapper: design and first light

Chen

Lokhorst

Shen

et al. 2022

Ground-Based and Airborne Telescopes IX

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“…It is a critical component of modern railway systems aiming for safer, more efficient, and more reliable transport networks. The majority of OD systems in railways are deployed as on-board systems installed on trains themselves, consisting of different on-board sensors such as cameras and lidar sensors [4][5][6][7][8]. These on-board systems are designed to continuously monitor the tracks ahead and detect any obstacles or hazards that may pose a risk to the train's safe operation.…”

Section: Introductionmentioning

confidence: 99%

Toward the Enhancement of Rail Sustainability: Demonstration of a Holistic Approach to Obstacle Detection in Operational Railway Environments

Simonović,

Banić,

Stamenković

et al. 2024

Sustainability

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Rail transport plays a crucial role in promoting sustainability and reducing the environmental impact of transport. Ongoing efforts to improve the sustainability of rail transport through technological advancements and operational improvements are further enhancing its reputation as a sustainable mode of transport. Autonomous obstacle detection in railways is a critical aspect of railway safety and operation. While the widespread deployment of autonomous obstacle detection systems is still under consideration, the ongoing advancements in technology and infrastructure are paving the way for their full implementation. The SMART2 project developed a holistic obstacle detection (OD) system consisting of three sub-systems: long-range on-board, trackside (TS), and Unmanned Aerial Vehicle (UAV)-based OD sub-systems. All three sub-systems are integrated into a holistic OD system via interfaces to a central Decision Support System (DSS) that analyzes the inputs of all three sub-systems and makes decision about locations of possible hazardous obstacles with respect to trains. A holistic approach to autonomous obstacle detection for railways increases the detection area, including areas behind a curve, a slope, tunnels, and other elements blocking the train’s view on the rail tracks, in addition to providing long-range straight rail track OD. This paper presents a demonstration of the SMART2 holistic OD performed during the operational cargo haul with in-service trains. This paper defines the demonstration setup and scenario and shows the performance of the developed holistic OD system in a real environment.

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