A. Rosiewicz scite author profile

This work has sought to develop distributed feedback (DFB) diode-laser concepts and technologies necessary to facilitate NASAs upcoming Active Sensing of CO2 Emissions over Nights, Days, and Seasons (ASCENDS) mission. Specifically, a modified-COTS DFB laser module, incorporating a lownoise variable laser bias current supply and low-noise variable temperature control circuit, has been developed. Prototype hardware has been built and tested.

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Development of advanced seed laser modules for lidar and spectroscopy applications

Prasad

Rosiewicz

Coleman

2013

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We report on recent progress made in the development of highly compact, single mode, distributed feedback laser (DFB) seed laser modules with integrated drive electronics for lidar and spectroscopy applications from space based platforms. One of the intended application of this technology is in the NASA's Active Sensing of CO2 Emissions over Nights, Days, and Seasons (ASCENDS) mission. NASA Langley Research Center (LaRC) is working on a prototype laser based spectroscopy system for simultaneous measurement of CO 2 and O 2 for planned Active Sensing of CO 2 Emissions over Nights, Days, and Seasons (ASCENDS) mission application. For this purpose, 1571 nm spectral band for CO 2 sensing and 1262 nm spectral band for oxygen sensing have been selected. In this paper, we discuss recent progress made in the development of single mode, compact and stable, seed laser technologies for CO 2 and O 2 transmitters with focus on linewidth and noise measurements. The 1571 nm and 1262 nm DFB laser modules with integrated drive electronics have advanced current and temperature drivers built into them. A combination of temperature and current tuning allows coarse and fine adjustment of the diode wavelengths. The current tuning was demonstrated at a rate of ~0.7 pm/mV over a working range of ~1 V for a total of 0.7 nm. Also, temperature tuning at a rate of ~2 pm/mV over a working range of ~1 V for a total wavelength range of ~2 nm was demonstrated. The current tuning was performed at a rate of up to 200 kHz allowing rapid adjustment and dithering of the laser frequency. Furthermore, the best performance of laser linewidth observed was ~11 kHz with frequency stability <10 MHz over 1 hour period. The microcooler arrangement embedded inside these modules has provided significant reduction in power consumption. The electronics has been designed, prototyped and tested using space-qualified components within a hermetically sealed package of volume less than 2" x 2" x 0.5".

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A 20 GHz bandwidth InGaAsP/InP MTBH laser module

Atlas¹,

Rosiewicz

1993

IEEE Photon. Technol. Lett.

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High Reliability Packaging For Fibre Optic Sources

Rosiewicz¹

1987

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A. Rosiewicz

Dual-polarization microchip lasers for communications applications

Development of a low SWaP laser transmitter

Development of advanced seed laser modules for lidar and spectroscopy applications

A 20 GHz bandwidth InGaAsP/InP MTBH laser module

High Reliability Packaging For Fibre Optic Sources

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