Bert Cox scite author profile

Hybrid acoustic-RF systems offer excellent ranging accuracy, yet they typically come at a power consumption that is too high to meet the energy constraints of mobile IoT nodes. We combine pulse compression and synchronized wake-ups to achieve a ranging solution that limits the active time of the nodes to 1 ms. Hence, an ultra low-power consumption of 9.015 µW for a single measurement is achieved. The operation time is estimated on 8.5 years on a CR2032 coin cell battery at a 1 Hz update rate, which is over 250 times larger than state-of-the-art RF-based positioning systems. Measurements based on a proof-of-concept hardware platform show median distance error values below 10 cm. Both simulations and measurements demonstrate that the accuracy is reduced at low signal-to-noise ratios and when reflections occur. We introduce three methods that enhance the distance measurements at a low extra processing power cost. Hence, we validate in realistic environments that the centimeter accuracy can be obtained within the energy budget of mobile devices and IoT nodes. The proposed hybrid signal ranging system can be extended to perform accurate, low-power indoor positioning.

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Zero-Crossing Chirp Frequency Demodulation for Ultra-Low-Energy Precise Hybrid RF-Acoustic Ranging of Mobile Nodes

Cox

Perre

Strycker

2020

IEEE Sens. Lett.

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In this letter, we zoom in on the distance estimation in a chirp-based hybrid RF-acoustic ranging system. We present an ultra low-power solution based on zero-crossing demodulation. We have designed an experimental prototype to validate the approach and compared the power usage, accuracy and precision of this ranging system with a conventional method. Our measurements show that an accuracy and precision below 5 cm can be obtained for a mobile sensor node that has a lifespan of over 3794 days or ~10 years, at an update rate of 1 Hz. This constitutes a 4 times improvement with respect to conventional ADC-based indoor ranging techniques. The provided method can be extended to a system for indoor localisation and also opens the possibility to implement RF backscattering-based solutions for fully passive nodes.

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Techtile -- Open 6G R&D Testbed for Communication, Positioning, Sensing, WPT and Federated Learning

Callebaut¹,

Mulders²,

Ottoy³

et al. 2022

Preprint

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New concepts for next-generation wireless systems are being developed. It is expected that these 6G and beyond systems will incorporate more than only communication, but also sensing, positioning, (deep) edge computing, and other services. The discussed measurement facility and approach, named Techtile, is an open, both in design and operation, and unique testbed to evaluate these newly envisioned systems. Techtile is a multi-functional and versatile testbed, providing finegrained distributed resources for new communication, positioning and sensing technologies. The facility enables experimental research on hyperconnected interactive environments and validation of new algorithms and topologies. The backbone connects 140 resource units equipped with edge computing devices, software-defined radios (SDRs), sensors, and LED sources. By doing so, different network topologies and local-versuscentral computing can be assessed. The introduced diversity of i) the technologies (e.g., RF, acoustics and light), ii) the distributed resources and iii) the interconnectivity allows exploring more degrees and new types of diversity, which can be investigated in this testbed.

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Bert Cox

An accurate AOA localization method based on unreliable sensor detection

High precision hybrid RF and ultrasonic chirp-based ranging for low-power IoT nodes

Zero-Crossing Chirp Frequency Demodulation for Ultra-Low-Energy Precise Hybrid RF-Acoustic Ranging of Mobile Nodes

Techtile -- Open 6G R&D Testbed for Communication, Positioning, Sensing, WPT and Federated Learning

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