Martin Chamberland scite author profile

Martin Chamberland

5Publications

128Citation Statements Received

10Citation Statements Given

How they've been cited

181

128

How they cite others

Affiliations

Telus (Canada), Université Laval, Synopsys (Switzerland)

Publications

Order By: Most citations

Chemical agent detection and identification with a hyperspectral imaging infrared sensor

Farley¹,

Vallières²,

Villemaire³

et al. 2007

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Standoff detection, identification and quantification of chemical agents are fundamental needs in several fields of applications. Additional required sensor characteristics include high sensitivity, low false alarms and high-speed (ideally real-time) operation, all in a compact and robust package. The thermal infrared portion of the electromagnetic spectrum has been utilized to implement such chemical sensors, either with spectrometers (with none or moderate imaging capability) or with imagers (with moderate spectral capability). Only with the recent emergence of high-speed, large format infrared imaging arrays, has it been possible to design chemical sensors offering uncompromising performance in the spectral, spatial, as well as the temporal domain.Telops has developed an innovative instrument that can not only provide an early warning for chemical agents and toxic chemicals, but also one that provides a "Chemical Map" in the field of view. To provide to best field imaging spectroscopy instrument, Telops has developed the FIRST, Field-portable Imaging Radiometric Spectrometer Technology, instrument. This instrument is based on a modular design that includes: a high-performance infrared FPA and data acquisition electronics, onboard data processing electronics, a high-performance Fourier transform modulator, dual integrated radiometric calibration targets and a visible boresight camera. These modules, assembled together in an environmentally robust structure, used in combination with Telops' proven radiometric and spectral calibration algorithms make this instrument a world-class passive standoff detection system for chemical imaging. This paper presents chemical detection and identification results obtained with the FIRST sensor.

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Microwave signals generated by optical heterodyne between injection-locked semiconductor lasers

Genest

Chamberland²,

Tremblay

et al. 1997

IEEE J. Quantum Electron.

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Standoff gas identification and quantification from turbulent stack plumes with an imaging Fourier-transform spectrometer

Tremblay¹,

Savary

Rolland

et al. 2010

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Algorithms for chemical detection, identification and quantification for thermal hyperspectral imagers

Vallières¹,

Villemaire²,

Chamberland³

et al. 2005

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Standoff detection, identification and quantification of chemicals in the gaseous state are fundamental needs in several fields of applications. Sensor requirements derived from these applications include high sensitivity, low false alarms and real-time operation, all in a compact and robust package suitable for field use. The thermal infrared portion of the electromagnetic spectrum has been utilized to implement such chemical sensors, either with spectrometers (with no or moderate imaging capability) or with imagers (with moderate spectral capability). Only with the recent emergence of high-speed, large format infrared imaging arrays has it been possible to design chemical sensors offering uncompromising performance in the spectral, spatial, as well as the temporal domain. It is clear from analytical studies that the combined spatial and spectral information holds enormous promises on improving the current performance of passive detection, identification and quantification of chemical agents. This paper presents detection, identification and quantification algorithms developed for hyperspectral imagers operating in the thermal infrared. The effectiveness of these algorithms is illustrated using gaseous releases datacubes acquired using the Telops FIRST imaging spectrometer in the field.

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Development and testing of a hyperspectral imaging instrument for field spectroscopy

Farley¹,

Belzile²,

Chamberland³

et al. 2004

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