KR100261283B1 - A fiber laser using dispersion imbalanced nonlinear loop mirrors - Google Patents

Abstract

PURPOSE: An optical fiber laser using a dispersion imbalanced nonlinear amplifying loop mirror is provided which includes two optical fibers having different dispersion values in a nonlinear loop on the basis of the conventional Erbium-doped '8'-shaped optical fiber laser and induces passive mode locking, to generate short-length pulses. CONSTITUTION: An optical fiber laser using a nonlinear loop mirror is constructed of a nonlinear loop mirror(1) and a linear loop(2). The nonlinear loop mirror includes the first optical fiber(41) whose dispersion constant value corresponds to the minimum value of the wavelengths of the laser, the second optical fiber(42) having a dispersion constant value larger than the dispersion value of the first optical fiber, and the first and second polarization controllers(21,22) for controlling the polarization states of signals transmitted through the first and second optical fibers, respectively. The linear loop includes an optical isolator(31) for maintaining one-way oscillation of the laser and blocking continuous waves reflected from the nonlinear loop mirror, a polarization controller(23) for the polarization of an optical pulse whose continuous waves are blocked by the optical isolator, and an amplification medium optical fiber(43) for amplifying the optical pulse with a predetermined amplification medium. The linear loop further has a wavelength division optical fiber coupler(12) for multiplexing the wavelength of the optical pulse amplified by the optical fiber, a 980nm laser diode(51) for pumping the optical signal multiplexed by the coupler, and a 90:10 optical fiber(13) directional coupler for outputting laser of 10% of the pumped optical signal.

Description

Fiber Lasers Using Asymmetric Distributed Nonlinear Loop Mirrors

The present invention relates to a fiber laser, and in particular, based on a conventional "8" type fiber laser added by erbium, having two optical fibers having different dispersion constants in a nonlinear loop, and then inducing passive mode locking It relates to a fiber laser using a nonlinear loop mirror to generate a pulse of length.

1 schematically shows a laser of an optical fiber using a conventional nonlinear optical loop mirror.

As shown in FIG. 1, a conventional fiber laser using a nonlinear optical loop mirror is composed of a nonlinear amplifying loop mirror (NALM) 100 and a linear loop 200.

The nonlinear optical loop mirror 100 includes a 50:50 optical fiber directional coupler (Directional Coupler (DC) or Fiber Coupler (FC)) 11 and a wavelength division multipler fiber coupler (WDM FC) 12 ), Polarization Controller (PC) 21, Optical Isolator 31, Single Mode Fiber (SMF) 42, Erbium Transition Fiber Fiber (EDF) (43).

The linear loop 200 includes a wavelength division optical fiber coupler 12, a polarization controller 21, and a dispersion transition optical fiber 42.

Referring to the operation of the optical fiber laser using a conventional nonlinear optical loop mirror configured as described above is as follows.

First, the CW pump introduced through the wavelength division optical fiber coupler 12 passes through a 50:50 optical fiber directional coupler 11 and is distributed to the nonlinear amplified loop mirror 100 and the linear loop 200 to provide a clock. Proceed in the direction and counterclockwise.

At this time, the clockwise light waves that experience gain before the dispersion transitions respectively configured in the nonlinear amplification loop mirror 100 and the linear loop 200 pass through the optical fiber 42 proceed in the counterclockwise direction where the gain is experienced after the optical fiber progresses. Compared to the light waves, the nonlinear phase change is proportional to the peak power of the light waves.

In this way, the reflectance of the nonlinear loop can be adjusted by using the difference in phase change in the two directions, and the light waves having a high amplitude can be transmitted and the rest can be reflected. This means that the nonlinear loop can be used as a saturable absorber for mode locking. If the optical pulse passes through the nonlinear loop, the optical pulse can be shortened and amplified.

A nonlinear loop similar to the NALM 100 is a nonlinear optical loop mirror (NOLM).

The NOLM uses a non-symmetric optical fiber directional coupler having a coupling ratio of 50 to 50 instead of the 50:50 optical fiber directional coupler 11 to cause a difference in nonlinear phase change between light waves traveling in a clockwise and counterclockwise direction. do.

However, the conventional optical fiber laser using NALM has a problem that mode hopping may occur at high pumping power because light waves travel in both directions in the amplification medium.

In addition, the conventional optical fiber laser using the NOLM has a problem of using a long optical fiber or a high output optical pumping power when constructing a nonlinear loop serving as a saturated absorber to oscillate mode locking.

Accordingly, an object of the present invention is to provide a short mode pulse by inducing passive mode locking after two optical fibers having different dispersion values in a nonlinear loop based on a conventional "8" type fiber laser added by erbium. To provide a fiber laser using an asymmetric distributed nonlinear loop mirror to generate.

Means for achieving the object of the present invention is a fiber laser using a nonlinear loop mirror composed of a linear loop and an eight-shaped nonlinear loop mirror connected to a 50:50 optical fiber directional regulator, the nonlinear loop mirror is a dispersion constant A polarization state of a first optical fiber having a minimum value among wavelengths of a laser, a second optical fiber having a dispersion constant larger than a dispersion constant value of the first optical fiber, and an optical signal passing through the first and second optical fibers Consists of the first and second polarization controller to control the

The linear loop includes an optical isolator for maintaining the unidirectional oscillation of the laser and blocking the continuous wave reflected from the nonlinear loop mirror, a polarization controller for controlling the polarization of the light pulse in which the continuous wave is blocked in the optical isolator, and the polarization controller. An amplification medium optical fiber for amplifying the optical pulse of which polarization is controlled by a predetermined amplification medium, a wavelength division optical fiber coupler for multiplexing the wavelength of the optical pulse amplified by the amplification medium optical fiber, and an optical signal multiplexed in the wavelength division optical fiber coupler And a 980 optical pumping laser diode for pumping a 90: 10 optical fiber directional coupler for outputting a laser of 10 percent of the optical signal pumped to the 980 optical pumping laser diode.

1 is a block diagram of a fiber laser using a conventional nonlinear optical loop mirror.

2 is a block diagram of a fiber laser using a nonlinear loop mirror according to an embodiment of the present invention.

(Symbol description for main parts of drawing)

11: 50:50 fiber directional coupler 12: wavelength division fiber coupler

13: 90:10 Optical fiber directional coupler 21,22,23: Polarization controller

31: optical isolator 41: dispersion transition optical fiber

42: single mode fiber 43: fiber with boom

51: 980 Light Pumping Laser Diode

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram of a fiber laser using a nonlinear loop mirror according to an embodiment of the present invention.

As shown in FIG. 2, a fiber laser using a nonlinear loop mirror according to an embodiment of the present invention is connected to a 50:50 optical fiber directional coupler 11 and has a "8" shape. Mirror: DINLM) (1) and linear loop (2).

The DIMLM 1 has a dispersion constant value of a single mode optical fiber (SMF) 41 having a minimum dispersion wavelength among laser wavelengths and a dispersion constant value larger than the dispersion constant value of the single mode optical fiber 41. Dispersion Shifter Fiber (DSF) 42 having, and a polarization regulator 21, 22 for controlling the polarization state of the optical signal passing through the single-mode optical fiber 41 and the dispersion transition optical fiber 42 And first and second output terminals 111 and 112 of the 50:50 optical fiber directional coupler 11 for outputting the optical signal adjusted by the polarization regulators 21 and 22.

The dispersion transition optical fiber 41 has a laser oscillation wavelength of 1550 nm, a dispersion constant D ₂ of 1.2 ps / nmkm, a zero dispersion point wavelength of 1532 nm, and a length of 50 m. The single mode optical fiber 42 has a laser oscillation wavelength of 1550 nm and a dispersion constant D ₂ of 17 ps / nm km and a length of 50 m.

The linear loop 2 comprises an optical isolator 31, a polarization controller 23, an amplifying medium optical fiber 43, a 90:10 optical fiber directional coupler 13, and a 980 light pumping laser diode. 51 and a wavelength division optical fiber coupler 12;

The amplification medium optical fiber 43 is a single mode optical fiber 43 to which erbium is added and has a length of about 12 m. The 980 light pumping laser diode 51 has a maximum output of 70 mW at a wavelength of 980 nm. The wavelength division optical fiber coupler 12 multiplexes the wavelength to 980 nm and 1550 nm.

The optical isolator 31 operates irrespective of the polarization input to the linear loop 2 to maintain the unidirectional oscillation of the laser and to block the continuous wave component reflected from the nonlinear loop mirror 1.

The operation of the fiber laser using the nonlinear loop mirror according to the embodiment of the present invention configured as described above will be described in detail.

First, when the optical pulses are distributed half and half through the 50:50 optical fiber directional regulator 11 and input to the nonlinear loop mirror 1, the anti-clockwise optical pulses incident on the dispersion transition optical fiber 41 are distributed dispersion fiber 41 The low dispersion constant of) causes the single mode optical fiber 42 to pass through without experiencing peak power reduction due to pulse spreading.

On the contrary, the clockwise light pulse passing through the single mode optical fiber 42 is gradually lowered by the high dispersion constant of the single mode optical fiber 42 due to the pulse spread, and the dispersion transition is maintained in such a state. It passes through the optical fiber 41.

Therefore, optical pulses traveling clockwise and counterclockwise will experience nonlinear phase shift differences as in nonlinear optical loop mirrors (NOLMs).

In addition, the polarization regulators 21 and 22 are respectively inserted between the dispersion transition optical fiber 41 and the single mode optical fiber 42 and the 50:50 optical fiber directional regulator 11, so that the polarization is not maintained. The polarization state of the optical pulses passing through the dispersion transition optical fiber 41 and the single mode optical fiber 42 is adjusted to generate a mode locked pulsed laser light, a mode locked pulsed soliton laser light, and a continuous wave laser light.

As a result of the pulse oscillation of this embodiment, the length of the mode locking pulse was about 1.2 ps, and the line width was about 2.9 to 3.5 nm. In addition, the half-width ratio was about 1.58 MHz, and the maximum average power was about 2.0 mW at 70 mW pumping.

In this embodiment, the nonlinear loop mirror of the conventional 8-type fiber laser is made by connecting two optical fibers having a dispersion constant value close to the dispersion zero region and two optical fibers having a relatively high dispersion constant value, and passive mode locking. It can be implemented as an ultra-short pulsed fiber laser by using it as a nonlinear saturable absorber which is essential for generating the

According to the present invention, a mode locking laser is constructed using DINLM using dispersion, and mode locking can be oscillated at a lower pump threshold power or a shorter resonator length than a conventional NOLM, and a nonlinear loop mirror using dispersion can be used to generate an amplification medium. Since the linear loop includes only one direction, laser oscillation wavelength instability due to mode hopping does not occur, thereby generating a light pulse source having a stable wavelength. Therefore, there is an effect that can improve the performance of the nonlinear loop mirror used in the conventional all-optical fiber ultra-short pulse laser.

Claims (6)

In a fiber laser using a nonlinear loop mirror composed of a linear loop and an eight-shaped nonlinear loop mirror connected to a 50:50 optical fiber directional regulator, The nonlinear loop mirror may include: a first optical fiber having a dispersion constant value having a minimum value among laser wavelengths; A second optical fiber having a dispersion constant value larger than a dispersion constant value of the first optical fiber; Consists of the first and second polarization controller for adjusting the polarization state of the optical signal passing through the first and second optical fiber, The linear loop comprises an optical isolator for maintaining a unidirectional oscillation of the laser and for blocking the continuous wave reflected from the nonlinear loop mirror; A polarization controller for controlling the polarization of the light pulse in which the continuous wave is blocked in the optical isolator; An amplification medium optical fiber for amplifying a light pulse whose polarization is controlled by the polarization controller with a predetermined amplification medium; A wavelength division optical fiber coupler for multiplexing wavelengths of the optical pulses amplified in the amplification medium optical fiber; A 980 optical pumping laser diode for pumping the optical signal multiplexed in the wavelength division optical fiber coupler; And a 90:10 optical fiber directional coupler for outputting a 10 percent laser of the optical signal pumped to the 980 optically pumped laser diode. The method of claim 1, The first optical fiber is a dispersion transition optical fiber having a laser oscillation wavelength of 1550 nm, a dispersion constant of 1.2 ps / nmkm, a zero dispersion point wavelength of 1532 nm, and a length of 50 m. . The method of claim 1, The first and second polarization controllers are asymmetrical dispersion nonlinear loop, characterized in that to generate a mode-locked pulsed laser light by adjusting the polarization state of the optical pulses respectively passed through the first and second optical fibers that do not maintain polarization. Fiber laser with mirror. The method of claim 1, The first and second polarization controllers generate an asymmetric distributed nonlinear loop mirror, characterized in that for generating a mode-locked soliton laser beam by controlling the polarization state of the light pulses which have passed through the first and second optical fibers that do not maintain polarization. Used fiber laser. The method of claim 1, The first and second polarization controllers are optical fiber lasers using asymmetric distributed nonlinear loop mirrors, characterized in that to generate a continuous wave laser light by controlling the polarization state of the light pulses passing through the first and second optical fibers that do not maintain polarization. . The method of claim 1, The first and second polarization controllers adjust the polarization state of light pulses passing through the first and second optical fibers that do not maintain polarization, respectively, to change the continuous wave laser, the laser beam of the mode locked pulse, and the center wavelength of the laser. An optical fiber laser using an asymmetric distributed nonlinear loop mirror, characterized in that to generate light.

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