Improvements of optical power scale realization with a CCD-based laser stabilization system

Abstract We report realization of scales for optical power of lasers and spectral responsivity of laser power detectors based on a predictable quantum efficient detector (PQED) over the spectral range of 400 nm–800 nm. The PQED is characterized and used to measure optical power of a laser that is further used in calibration of the responsivities of a working standard trap detector at four distinct laser lines, with an expanded uncertainty of about 0.05%. We present a comparison of responsivities calibrated against the PQED at Aalto and the cryogenic radiometer at RISE, Sweden. The measurement results support the concept that the PQED can be used as a primary standard of optical power.

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Realization of Optical Power Scale Based on Cryogenic Radiometry and Trap Detectors

IEEE Transactions on Instrumentation and Measurement ◽

10.1109/tim.2014.2383072 ◽

2015 ◽

Vol 64 (6) ◽

pp. 1702-1708 ◽

Cited By ~ 3

Author(s):

Thiago Menegotto ◽

Thiago Ferreira da Silva ◽

Mauricio Simoes ◽

Willian A. T. de Sousa ◽

Giovanna Borghi

Keyword(s):

Optical Power ◽

Power Scale

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Closed-loop Laser Stabilization System

ELEKTRONIKA - KONSTRUKCJE TECHNOLOGIE ZASTOSOWANIA ◽

10.15199/13.2016.12.3 ◽

2016 ◽

Vol 1 (12) ◽

pp. 24-28

Author(s):

Paweł Plewinski

Keyword(s):

Closed Loop ◽

Stabilization System ◽

Laser Stabilization

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Advancements in NRC’s Primary Spectral Irradiance Scale Realization

Journal of Physics Conference Series ◽

10.1088/1742-6596/2149/1/012005 ◽

2022 ◽

Vol 2149 (1) ◽

pp. 012005

Author(s):

A Gamouras ◽

D J Woods ◽

É Côté ◽

A A Gaertner

Keyword(s):

International System ◽

National Research Council ◽

Optical Power ◽

Thermodynamic Temperature ◽

Wide Band ◽

Spectral Irradiance ◽

Improve Measurement ◽

Filter Radiometer ◽

System Of Units ◽

Power Scale

Abstract The National Research Council (NRC) of Canada has been working to establish new facilities and to improve measurement capabilities traceable to the International System of Units (SI units) in optical radiometry. The NRC primary spectral irradiance scale has transitioned from a detector-based approach in the range of 700 nm to 1600 nm to a detector and source-based realization from 250 nm to 2500 nm. A high temperature blackbody (HTBB) acts as the primary light source for the calibration of 1000 W FEL spectral irradiance standard lamps. The thermodynamic temperature of the HTBB is determined using an NRC-designed wide-band filter radiometer, with spectral responsivity SI-traceable to the NRC optical power scale. This new facility has significantly improved measurement uncertainties compared to the previous NRC spectral irradiance scale.

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Laser stabilization system for space application based on hydroxide-catalysis bonding

2014 European Frequency and Time Forum (EFTF) ◽

10.1109/eftf.2014.7331465 ◽

2014 ◽

Cited By ~ 1

Author(s):

Yingxin Luo ◽

Hongyin Li ◽

Huizong Duan ◽

Hsien-Chi Yeh

Keyword(s):

Space Application ◽

Stabilization System ◽

Laser Stabilization

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Optical Power Scale Realization by Laser Calorimeter after 45 Years of Operation

Journal of Research of the National Institute of Standards and Technology ◽

10.6028/jres.126.011 ◽

2021 ◽

Vol 126 ◽

Author(s):

Matthew T. Spidell ◽

Anna K. Vaskuri

Keyword(s):

Laser Power ◽

Thermal Modeling ◽

Optical Power ◽

Radiant Flux ◽

Optical Coupling ◽

Expanded Uncertainty ◽

Power Scale ◽

Power And Energy ◽

Uncertainty Contribution ◽

Uncertainty Level

To calibrate laser power and energy meters, the National Institute of Standards and Technology (NIST) uses several detector-based realizations of the scale for optical radiant flux; these realizations are appropriate for specific laser power/energy ranges and optical coupling configurations. Calibrations from 1 μW to 2 W are currently based upon calorimeters. Validation by comparisons against other primary representations of the optical watt over the last two decades suggests the instruments operate well within their typical reported uncertainty level of 0.86 % with 95 % confidence. The dominant uncertainty contribution in the instrument is attributable to light scattered by the legacy window, which was not previously recognized. The inherent electro-optical inequivalence in the calorimeter’s response was reassessed by thermal modeling to be 0.03 %. The principal contributions to the overall inequivalence were corrected, yielding a shift in scale representation under 0.2 % for typical calibrations. With updates in several uncertainty contributions resulting from this reassessment, the resulting combined expanded uncertainty (k = 2) is 0.84 %, which is essentially unchanged from the previous result provided to calibration customers.

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