Gas detection system using intracavity fiber laser with loop cavity having saturated absorption fiber

摘要

A gas detection system with an inner ring cavity fiber laser using saturated absorption optical fiber is provided. The system comprising a ring fiber laser consisted of a pump source, a wavelength division multiplexer, a first active optical fiber, a first coupler, a fiber Bragg grating and a second coupler connected successively; an optical isolator coupled between said first active optical fiber and said first coupler; a second active grating connected between said fiber Bragg grating and said first coupler; a detection gas chamber connected between said first coupler and said second coupler; a first photoelectric detector for detecting the laser intensity outputted from said ring fiber laser to generate a first light intensity signal; a second photoelectric detector for receiving the intensity measuring beam passing through the detection gas chamber to generate a second light intensity signal; and a feedback control unit.

主权项

1. A gas detection system comprising:
a ring fiber laser comprising a pump source, a wavelength division multiplexer connected to the pump source, a first active optical fiber connected to the wavelength division multiplexer, a first coupler, a fiber Bragg grating and a second coupler; an optical isolator coupled between the first active optical fiber and the first coupler, for preventing reverse light from transmitting in the first active optical fiber; a second active optical fiber connected between the fiber Bragg grating and the first coupler as a saturated absorber; a detection gas chamber connected between the first coupler and the second coupler; a first photoelectric detector connected to the output of the first coupler; a second photoelectric detector connected to the second coupler; a feedback control unit connected to the first photoelectric detector and the second photoelectric connector, wherein the first coupler is configured to receive a laser light isolated by the optical isolator, divide the laser light into a first detection beam and a first intensity measuring beam according to a first power ratio, and output the first detection beam and the first intensity measuring beam; wherein the detection gas chamber is configured to receive gas to be detected, and receive the first detection beam outputted from the first coupler, such that he first detection beam passes through the gas to be detected to generate and output a second detection beam to the second coupler; wherein the second coupler is configured to divide the second detecting beam outputted from the detection gas chamber into a feedback beam and a second intensity measuring beam according to a second power ratio, and output the feedback beam and the second intensity measuring beam; wherein the first photoelectric detector is configured to receive the first intensity measuring beam from the first coupler, generate a first light intensity signal, and output the first light intensity signal; wherein the second photoelectric detector is configured to receive the second intensity measuring beam from the second coupler, generate a second light intensity signal, and output the second light intensity signal; and wherein the feedback control unit is configured to receive the first light intensity signal outputted from the first photoelectric detector and the second light intensity signal outputted from the second photoelectric detector, and generate at least one feedback control signal to adjust the pump source and the fiber Bragg grating.