CN202550277U - Double-wavelength optical fiber laser device - Google Patents

Abstract

The utility model discloses a dual-wavelength optical fiber laser, the laser pumping source of which is connected with the a port of the wavelength division multiplexer, the c port of the wavelength division multiplexer is connected with one end of the erbium-doped optical fiber, and the other end of the erbium-doped optical fiber is connected with the second end of the erbium-doped optical fiber The d port of a coupler is connected, the f port of the first coupler is connected with the output port of the isolator, the input port of the isolator is connected with the 2 port of the second coupler, and the 4 port of the second coupler is connected with the built-in dual wavelength The λ2 end of the FBG pair is connected, the 3-port of the second coupler is connected to one end of the polarization controller, the other end of the polarization controller is connected to the λ1 end of the embedded dual-wavelength FBG pair, and the 1-port of the second coupler is connected to the WDM The b ports of the multiplexer are connected; the connections between the above components are all connected by optical fiber fusion. The utility model overcomes the shortcomings of the existing dual-wavelength fiber lasers, such as unstable output wavelength power and unstable wavelength, and can obtain stable dual-wavelength output.

Description

Dual Wavelength Fiber Laser

technical field

The utility model relates to a dual-wavelength optical fiber laser.

Background technique

Dual-wavelength fiber laser is defined according to the number of output laser wavelength channels. As the name implies, it refers to a laser that can provide laser output at two wavelength positions and uses optical fiber as the transmission medium. Among them, the dual wavelength is usually obtained by using an optical filter device (such as a fiber grating) or a special structure, but the utility model uses an embedded Sagnac ring structure for filtering.

Due to the characteristics of simple structure, low cost, small size and simple maintenance, fiber lasers have broad application prospects in high-speed and large-capacity wavelength division multiplexing optical fiber communication systems, high-precision optical fiber sensing technology, and high-power lasers. Huge technological advantage. The rapid development of optical fiber communication requires excellent light sources to support, so light sources play an extremely important role in optical fiber communication systems. As a light source, the laser is a key device in optical fiber communication. It provides the optical carrier required in optical fiber communication. Its performance directly affects the overall performance of the optical fiber communication system. In recent years, with the deepening of research in the field of optical communication technology, dual-wavelength fiber lasers are used in the research of soliton pulse generation, heterodyne interference ranging, optical sensing, microwave radio frequency signals and high repetition rate ultrashort pulse generation. as the initial light source. However, the current dual-wavelength fiber laser has shortcomings such as unstable output wavelength power and unstable wavelength.

Contents of the invention

Aiming at the shortcomings of existing dual-wavelength fiber lasers such as unstable output wavelength power and unstable wavelength, the utility model provides a dual-wavelength erbium-doped fiber ring laser with a Sagnac ring structure based on an embedded FBG pair, which can obtain stable Dual wavelength output.

The utility model adopts the following technical scheme: a dual-wavelength fiber laser, including a laser pump source (1), a wavelength division multiplexer (2), an erbium-doped optical fiber (3), a first coupler (4), an isolator (5 ), the second coupler (6), the polarization controller (7), the embedded dual-wavelength FBG pair (8), the laser pump source (1) is connected to the a port of the wavelength division multiplexer (2), and the wavelength division The c port of the multiplexer (2) is connected with one end of the erbium-doped fiber (3), and the other end of the erbium-doped fiber (3) is connected with the d port of the first coupler (4), and the first coupler (4) The f port is connected to the output end of the isolator (5), the input end of the isolator (5) is connected to the 2 port of the second coupler (6), and the 4 port of the second coupler (6) is connected to the embedded dual-wavelength FBG The λ2 terminal of the pair (8) is connected, the 3-port of the second coupler (6) is connected with one end of the polarization controller (7), and the other end of the polarization controller (7) is connected with the embedded dual-wavelength FBG pair (8) The λ1 end is connected, and the 1 port of the second coupler (6) is connected with the b port of the wavelength division multiplexer (2); the connections between the above-mentioned components all adopt optical fiber fusion splicing.

Preferably, the laser pumping source (1) is a 980nm laser pumping source.

Preferably, the erbium-doped fiber (3) is a 12m-long erbium-doped fiber.

Preferably, the coupling ratio of the first coupler (4) is 90:10.

Preferably, the second coupler (6) is a 3dB coupler.

The utility model is a Sagnac ring structure dual-wavelength erbium-doped fiber (EDF) ring laser based on an embedded fiber Bragg grating (FBG) pair, which can realize stable dual-wavelength output of 1554.92nm and 1555.2nm, and its side mode suppression ratio Up to 65dB, power stability better than 0.2dB, wavelength stability better than 0.02nm. Based on these advantages, the dual-wavelength fiber laser of the utility model has broad application prospects in DWDM systems, distributed optical fiber sensing, and photogenerated microwave/millimeter wave/terahertz wave systems.

In addition, the utility model adopts an all-optical fiber structure, which has low loss, low cost, and is easy to integrate with an optical fiber system.

Description of drawings

Fig. 1 is a schematic structural diagram of a Sagnac ring interferometer filter embedded with a dual-wavelength fiber grating.

Figure 2 is the reflection spectrum of the grating pair.

Fig. 3 is a schematic structural diagram of a dual-wavelength fiber laser.

Figure 4 shows the output wavelength spectrum of the laser.

Figure 5 shows five measurements of the output wavelength over a 10-minute period.

Detailed ways

Below in conjunction with accompanying drawing, the utility model embodiment is described in detail.

Referring to Figures 1 and 3, the dual-wavelength fiber laser includes a 980nm laser pump source 1, a wavelength division multiplexer 2, a 12m-long erbium-doped fiber 3, a coupler 4 with a coupling ratio of 90:10, an isolator 5, and a A 3dB coupler 6, a polarization controller (PC) 7 and a Sagnac ring interferometer filter composed of an embedded dual-wavelength FBG pair 8. Wherein, the laser pump source 1 of 980nm is connected with the a port of the wavelength division multiplexer 2, the c port of the wavelength division multiplexer 2 is connected with one end of the 12m long erbium-doped optical fiber 3, and the 12m long erbium-doped optical fiber 3 The other end is connected to the d port of the coupler 4 of 90:10. When the 980nm laser pump source 1 passes through the wavelength division multiplexer 2 and the erbium-doped fiber 3, a broadband optical gain of 1550nm band is generated in the fiber. The e port of the 90:10 coupler 4 is connected to the spectrometer, the f port of the 90:10 coupler 4 is connected to the output end of the isolator 5, and the input end of the isolator 5 is connected to the 2 port of the 3dB coupler 6, Port 4 of the 3dB coupler 6 is connected to the λ2 end of the embedded dual-wavelength FBG pair 8, port 3 of the 3dB coupler 6 is connected to one end of the polarization controller (PC) 7, and the other end of the polarization controller (PC) 7 is connected to The λ1 end of the embedded dual-wavelength FBG pair 8 is connected, and the 1 port of the 3dB coupler 6 is connected with the b port of the wavelength division multiplexer 2 . All of the above use optical fiber fusion splicing.

The output of the dual-wavelength fiber laser of the utility model is a stable dual-wavelength in the 1550nm band, and the principle of the Sagnac ring interferometer filter structure it adopts is: the Sagnac ring interferometer filter can convert the reflection spectrum of the FBG into a transmission spectrum, such as As shown in Figure 1, the incident light beam entering the 3dB coupler from port 1 will output optical signals with equal power and phase difference of π/2 at port 3 and port 4. When the spectrum of the input light is not within the reflection bandwidth of the grating, the two beams of light will pass through the FBG, travel around the circle clockwise and counterclockwise, and then enter the coupler and interfere, and the two beams introduced by the coupler The secondary phase differences cancel each other, so that all the interfered light is output from port 1. When the input light is exactly within the reflection bandwidth of the grating, both rays will be reflected by the FBG. The two beams of light are reflected back separately and interfere in the coupler. The two beams of reflected light will introduce a repeated phase difference through the coupler, and all the light will eventually output from port 2.

After passing through the Sagnac ring interferometer filter, a dual-wavelength laser is generated, of which 10% of the laser is used as output, and 90% provides positive feedback in the laser resonator cavity. Among them, the isolator is used to eliminate reflected light in the cavity and reduce noise.

The stable dual-wavelength fiber lasers of 1554.92 nm and 1555.2 nm obtained in this embodiment have a side mode suppression ratio of about 65 dB. The power stability of the laser output is better than 0.2dB, and the wavelength stability is better than 0.02nm.

Those of ordinary skill in the art should recognize that the above embodiments are only used to illustrate the utility model, rather than as a limitation to the utility model, as long as within the scope of the utility model, the changes and modifications of the above embodiments are all Will fall within the scope of protection of the present utility model.

Claims (5)

1. Dual-wavelength fiber laser is characterized in that it comprises a laser pump source (1), a wavelength division multiplexer (2), an erbium-doped fiber (3), a first coupler (4), an isolator (5), the first Two couplers (6), a polarization controller (7), an embedded dual-wavelength FBG pair (8), the laser pump source (1) is connected to the port a of the wavelength division multiplexer (2), and the wavelength division multiplexer The c port of (2) is connected with an end of the erbium-doped fiber (3), and the other end of the erbium-doped fiber (3) is connected with the d port of the first coupler (4), and the f port of the first coupler (4) is connected with the The output end of the isolator (5) is connected, the input end of the isolator (5) is connected to the 2-port of the second coupler (6), and the 4-port of the second coupler (6) is connected to the embedded dual-wavelength FBG pair (8 ), the λ2 end of the second coupler (6) is connected to one end of the polarization controller (7), and the other end of the polarization controller (7) is connected to the λ1 end of the embedded dual-wavelength FBG pair (8) , port 1 of the second coupler (6) is connected to port b of the wavelength division multiplexer (2); the connections between the above-mentioned components all adopt optical fiber fusion splicing. 2. The dual-wavelength fiber laser according to claim 1, characterized in that: the laser pumping source (1) is a 980nm laser pumping source. 3. The dual-wavelength fiber laser as claimed in claim 1, characterized in that: the erbium-doped fiber (3) is a 12m-long erbium-doped fiber. 4. The dual-wavelength fiber laser according to claim 1, characterized in that: the coupling ratio of the first coupler (4) is 90:10. 5. The dual-wavelength fiber laser according to claim 1, characterized in that: the second coupler (6) is a 3dB coupler.

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