Your search keyword '"Ultrasound rangefinder"' showing total 5 results

1. A 1.25 μJ per Measurement Ultrasound Rangefinder System in 65 nm CMOS for Explorations With a Swarm of Sensor Nodes.

Author

Berkol, Gonenc, Baltus, Peter G. M., Harpe, Pieter J. A., and Cantatore, Eugenio

Subjects

*ULTRASONIC imaging, *DETECTORS, *TRANSMITTERS (Communication), *OPTICAL reflectors

Abstract

This paper presents an ultrasound rangefinder system able to find relative distances among energy-constrained sensor nodes. The nodes build a swarm that is operated in collision and multipath rich environments. A new distance measurement technique combining Wake-up and Frequency Modulated Continuous Wave (FMCW) is proposed to enable the ranging while neglecting the echoes from passive reflectors in the environment. The building blocks of the sensor nodes comprise a transmitter, a wake-up receiver, and a ranging receiver, all implemented in a 65 nm CMOS technology. The transmitter includes two switched-capacitor converters and an output multiplexer to generate a four-level driving signal and broadcast either a wake-up sequence or a digitally synthesized ultrasound Chirp. The transmitter dissipates $0.43~\mu \text{J}$ and ${0.82~\mu \text {J}}$ to broadcast the wake-up signal and the Chirp, respectively. A mixer first architecture is exploited in the wake-up receiver to reduce the always-on power consumption of the nodes. The ranging receiver uses a heterodyne architecture suited for the FMCW. The power consumption of the wake-up receiver and ranging receiver is 23.6 nW and $0.56~\mu \text{W}$ , respectively. The proposed rangefinder is experimentally characterized up to a 1 m distance in air and dissipates $1.25~\mu \text {J}$ per measurement, achieving a resolution of 18.7 mm at 0.55 m. [ABSTRACT FROM AUTHOR]

Published

2021

2. A 1.25 μJ per Measurement Ultrasound Rangefinder System in 65 nm CMOS for Explorations With a Swarm of Sensor Nodes

Author

Peter Baltus, Eugenio Cantatore, Gonenc Berkol, Pieter Harpe, Integrated Circuits, Center for Care & Cure Technology Eindhoven, Resource Efficient Electronics, Emerging Technologies, EAISI Health, and Center for Wireless Technology Eindhoven

Subjects

Physics, Heterodyne, business.industry, 020208 electrical & electronic engineering, Bandwidth (signal processing), Transmitter, Electrical engineering, Analog IC, Ranging, Swarm of sensor nodes, 02 engineering and technology, 7. Clean energy, Multiplexer, CMOS, 0202 electrical engineering, electronic engineering, information engineering, Chirp, Electrical and Electronic Engineering, Ultrasound front-end, Ultrasound receiver, business, Multipath propagation, Ultrasound rangefinder

Abstract

This paper presents an ultrasound rangefinder system able to find relative distances among energy-constrained sensor nodes. The nodes build a swarm that is operated in collision and multipath rich environments. A new distance measurement technique combining Wake-up and Frequency Modulated Continuous Wave (FMCW) is proposed to enable the ranging while neglecting the echoes from passive reflectors in the environment. The building blocks of the sensor nodes comprise a transmitter, a wake-up receiver, and a ranging receiver, all implemented in a 65 nm CMOS technology. The transmitter includes two switched-capacitor converters and an output multiplexer to generate a four-level driving signal and broadcast either a wake-up sequence or a digitally synthesized ultrasound Chirp. The transmitter dissipates $0.43~\mu \text{J}$ and ${0.82~\mu \text {J}}$ to broadcast the wake-up signal and the Chirp, respectively. A mixer first architecture is exploited in the wake-up receiver to reduce the always-on power consumption of the nodes. The ranging receiver uses a heterodyne architecture suited for the FMCW. The power consumption of the wake-up receiver and ranging receiver is 23.6 nW and $0.56~\mu \text{W}$ , respectively. The proposed rangefinder is experimentally characterized up to a 1 m distance in air and dissipates $1.25~\mu \text {J}$ per measurement, achieving a resolution of 18.7 mm at 0.55 m.

Published

2021

3. A 2.67 µJ per Measurement FMCW Ultrasound Rangefinder System for the Exploration of Enclosed Environments

Author

Eugenio Cantatore, Peter Baltus, Pieter Harpe, Gonenc Berkol, Integrated Circuits, Center for Care & Cure Technology Eindhoven, Resource Efficient Electronics, Emerging Technologies, EAISI Health, and Center for Wireless Technology Eindhoven

Subjects

02 engineering and technology, swarm of sensor nodes, 01 natural sciences, Optics, ultrasound (US) rangefinder, 0202 electrical engineering, electronic engineering, information engineering, Chirp, Electrical and Electronic Engineering, Ultrasound rangefinder, Physics, Swarm of sensor nodes, business.industry, 020208 electrical & electronic engineering, 010401 analytical chemistry, Ultrasound, Bandwidth (signal processing), Transmitter, ultrasound receiver, Analog IC, Collision, 0104 chemical sciences, Transducer, CMOS, ultrasound front-end, business, Multipath propagation

Abstract

This letter presents the design and experimental characterization of an ultrasound rangefinder system. A new distance measurement method is proposed for determining the relative position among sensor nodes that are operated in a collision and multipath rich environment, while needing no common time reference between them. A 65 nm CMOS technology has been used to build the sensor nodes, which comprise an on-chip receiver and transmitter. The proposed rangefinder system is characterized up to 1 m in air and has a range resolution of 6.5 mm, while dissipating $2.67~\mu {\mathrm{ J}}$ per measurement.

Published

2020

4. A 1.25 µJ per Measurement Ultrasound Rangefinder System in 65nm CMOS for Explorations With a Swarm of Sensor Nodes

Author

Berkol, Gönenç, Baltus, Peter G.M., Harpe, Pieter J.A., Cantatore, Eugenio, Berkol, Gönenç, Baltus, Peter G.M., Harpe, Pieter J.A., and Cantatore, Eugenio

Abstract

This paper presents an ultrasound rangefinder system able to find relative distances among energy-constrained sensor nodes. The nodes build a swarm that is operated in collision and multipath rich environments. A new distance measurement technique combining Wake-up and Frequency Modulated Continuous Wave (FMCW) is proposed to enable the ranging while neglecting the echoes from passive reflectors in the environment. The building blocks of the sensor nodes comprise a transmitter, a wake-up receiver, and a ranging receiver, all implemented in a 65 nm CMOS technology. The transmitter includes two switched-capacitor converters and an output multiplexer to generate a four-level driving signal and broadcast either a wake-up sequence or a digitally synthesized ultrasound Chirp. The transmitter dissipates 0.43μ J and 0.82μ J to broadcast the wake-up signal and the Chirp, respectively. A mixer first architecture is exploited in the wake-up receiver to reduce the always-on power consumption of the nodes. The ranging receiver uses a heterodyne architecture suited for the FMCW. The power consumption of the wake-up receiver and ranging receiver is 23.6 nW and 0.56μ W, respectively. The proposed rangefinder is experimentally characterized up to a 1 m distance in air and dissipates 1.25μ J per measurement, achieving a resolution of 18.7 mm at 0.55 m.

Published

2021

5. A 2.67 µJ per Measurement FMCW Ultrasound Rangefinder System for the Exploration of Enclosed Environments

Author

Berkol, Gonenc, Baltus, Peter G.M., Harpe, Pieter J.A., Cantatore, Eugenio, Berkol, Gonenc, Baltus, Peter G.M., Harpe, Pieter J.A., and Cantatore, Eugenio

Abstract

This letter presents the design and experimental characterization of an ultrasound rangefinder system. A new distance measurement method is proposed for determining the relative position among sensor nodes that are operated in a collision and multipath rich environment, while needing no common time reference between them. A 65 nm CMOS technology has been used to build the sensor nodes, which comprise an on-chip receiver and transmitter. The proposed rangefinder system is characterized up to 1 m in air and has a range resolution of 6.5 mm, while dissipating 2.67~\mu {\mathrm{ J}} per measurement.

Published

2020