Abstract: A method is disclosed for providing enhanced quantitative analysis of materials by a dual-laser Raman probe wherein the wavelengths of the lasers used to illuminate a target object are selected in a manner to improve and enhance the quantitative analysis performance of the Raman signals.
Abstract: A method is disclosed for providing enhanced quantitative analysis of materials by a dual-laser Raman probe wherein the wavelengths of the lasers used to illuminate a target object are selected in a manner to improve and enhance the quantitative analysis performance of the Raman signals.
Abstract: A method is disclosed for providing enhanced quantitative analysis of materials by a dual-laser Raman probe wherein the wavelengths of the lasers used to illuminate a target object are selected in a manner to improve and enhance the quantitative analysis performance of the Raman signals.
Abstract: A compact dual-wavelength Raman probe using two laser sources each providing Raman excitation light at a different wavelength is disclosed causing Raman scattering in a fingerprint region associated with one excitation wavelength and causing Raman scattering in a stretch region, which are detected by the same detector array.
Type:
Grant
Filed:
June 4, 2018
Date of Patent:
July 23, 2019
Assignee:
Innovative Photonic Solutions, Inc.
Inventors:
Scott L. Rudder, Joseph B. Gannon, Robert V. Chimenti, Benjamin L. Carlin, John C. Connolly
Abstract: A hybrid external cavity laser and a method for configuring the laser having a stabilized wavelength is disclosed. The laser comprises a semiconductor gain section and a volume Bragg grating, wherein a laser emission from the semiconductor gain section is based on a combination of a reflectivity of a front facet of the semiconductor gain section and a reflectivity of the volume Bragg grating and the reflectivity of the semiconductor gain section and the volume Bragg grating are insufficient by themselves to support the laser emission. The hybrid cavity laser further comprises an etalon that provides further wavelength stability.
Type:
Grant
Filed:
February 24, 2014
Date of Patent:
October 2, 2018
Assignee:
Innovative Photonic Solutions, Inc.
Inventors:
John C. Connolly, Donald E Ackley, Scott L. Rudder, Harald R. Guenther
Abstract: A hybrid external cavity laser and a method for configuring the laser having a stabilized wavelength are disclosed. The laser comprises a semiconductor gain section and a volume Bragg grating, wherein a laser emission from the semiconductor gain section is based on a combination of a reflectivity of a front facet of the semiconductor gain section and a reflectivity of the volume Bragg grating and the reflectivity of the semiconductor gain section and the volume Bragg grating are insufficient by themselves to support the laser emission. The hybrid cavity laser further comprises an etalon that provides further wavelength stability.
Type:
Grant
Filed:
January 31, 2016
Date of Patent:
February 21, 2017
Assignee:
Innovative Photonic Solutions, INc.
Inventors:
John C. Connolly, Donald E Ackley, Scott L. Rudder, Harald R. Guenther
Abstract: A compact Raman probe integrated with a wavelength-stabilized laser source is disclosed. The output beam of the laser source has an elongated cross-section that is focused onto a target of interest. Raman and Rayleigh scattered light is collected, collimated, and filtered by free-space optics to form a beam that is coupled to the input of a multimode optical fiber having an elongated core that is aligned to edge slits of an optical spectrometer.
Type:
Application
Filed:
February 5, 2015
Publication date:
December 3, 2015
Applicant:
INNOVATIVE PHOTONIC SOLUTIONS, INC.
Inventors:
Robert V. Chimenti, Scott L. Rudder, Harald R. Guenther, Joseph B. Gannon, John C. Connolly
Abstract: Disclosed are systems and methods for using a semiconductor optical amplifier (SOA) as an optical modulator for pulsed signals. In accordance with the principles of the invention, the SOA can be biased with a negative voltage to suppress transmission and improve modulator extinction and biased with a positive pulsed signal with sufficient amplitude to forward bias the amplifier (SOA), both transmitting the carrier and increasing its amplitude by means of a gain provided by the SOA under forward biased conditions. In addition, the forward bias voltage may be selected to compensate for losses within the SOA.
Type:
Grant
Filed:
September 11, 2013
Date of Patent:
March 3, 2015
Assignee:
Innovative Photonic Solutions, Inc.
Inventors:
John C. Connolly, Donald E Ackley, Scott L Rudder, Harald R. Guenther