JPH01196189A - Tunable optical fiber raman laser - Google Patents

Abstract

PURPOSE:To be small-sized, of excellent stability and of enhanced reliability by a method wherein an optical fiber end-face mirror is formed at the end face of a remaining part on one end side of all optical fiber coupler so that an induced Raman scattered beam reflected selectively by a variable optical fiber type grating can go back and forth between optical fiber end-face mirrors. CONSTITUTION:Out of induced Raman scattered beams generated, a beam with a width of 0.01Angstrom is reflected by an optical fiber grating 16 and is incident on a port (3) of an optical fiber coupler 13. The optical fiber coupler 13 transmits almost all of an induced Raman scattered beam in the whole wavelength region from the port (3) to a port (2); 97 % of optical power is reflected by an optical fiber end-face mirror 17 via the port (2) and an optical fiber 14. The reflected beam is transmitter from the port (2) of the optical fiber coupler 13 to the port (3); while it goes back and forth between the optical fiber grating 1 6 and the optical fiber endface mirror 17, it is amplified selectively by a beam from a light source 10, i.e. an excited beam; 3% of the high- intensity and narrow-spectrum induced Raman scattered beam is radiated from the optical fiber end-face mirror 17.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Application The present invention relates to a wavelength tunable and narrow spectrum optical fiber Raman laser.

(Prior art) As a wavelength tunable optical fiber Raman laser, for example, r
R, ni, Jain et al,, A high-ef
ficiency tunable CW Raman
oscillator,”Applied Phys.
ics Letters, vol.30. no, 3. P
2 is a diagram schematically showing the configuration of a conventional wavelength tunable optical fiber Raman laser. In FIG. 2, 1 is a light source consisting of an argon laser that emits excitation light with a wavelength of 5145A and an output of 4W, 2 is a mirror, 3, 5
4 is a lens with anti-reflection coating, core diameter 3.3 μm arranged between lenses 3 and 5, refractive index difference 0.36
%.

An optical fiber with a length of 100 m, 6 and 7 are prisms, 8 is a prism mirror, and 9 is a grating.

According to FIG. 2, the light emitted from the light source 1 passes through the mirror 2, and almost the entire power is incident on one end side of the optical fiber μ4 through the lens 3, propagates through the optical fiber 4, and becomes the optical fiber 4. The light is emitted from the other end. This emitted light is made into parallel light by a lens 5, a part of which is reflected by a prism 6, and enters a grating 9, and the remaining part passes through the prism 6 and is emitted into the atmosphere. On the other hand, in the optical fiber 4, the strong excitation light from the light source 1 generates stimulated Raman scattered light having a wavelength different from that of the excitation light. This stimulated Raman scattered light is reflected by mirror 2.
For example, 90% by the prism mirror 8 and 99% by the prism mirror 8.
The light is reflected by 8%, is further amplified by the excitation light while reciprocating between the mirror 2 and the prism mirror 8, is reflected by the prism 6, and enters the grating 9. grating 9
In this case, the excitation light and the stimulated Raman scattering light have different wavelengths, so they are emitted separately. Further, since the prism 6.7 and the prism mirror 8 can change the direction of propagation in response to a change in the wavelength of light, the prism 6.
7 and prism mirror 8, the wavelength of the stimulated Raman scattered light is adjusted over 80A, and the conventional typical spectral width was 2A and the conversion efficiency was 9%.

(Problem to be Solved by the Invention) However, the above configuration uses large optical parts such as the prism 6°7 or the grating 9 as its constituent elements, which leads to an increase in the size of the device. There was also the problem that there was a risk of displacement, resulting in a lack of stability, and the spectral width of one wavelength-adjusted beam was as wide as 2A.

SUMMARY OF THE INVENTION In view of the above-mentioned problems, an object of the present invention is to provide a wavelength tunable optical fiber Raman laser that is small, has excellent stability, and has a highly reliable narrow spectrum without using large optical components.

(Means for Solving the Problems) In order to achieve the above object, the present invention has an excitation light source, two ports on one end side, and one port on the other end side, and a an optical fiber coupler whose output light enters one port on the one end side; an optical fiber whose one end side is connected to a port on the other end side of the optical fiber coupler; and one end side or the other end side of the front distribution fiber. and a tunable optical fiber type grating connected to.

Furthermore, for reasons to be described later, it is effective to coat the end face of the remaining port on one end side of the optical fiber coupler or the end face of the optical fiber connected to this port to form an optical fiber end face mirror.

(Function) According to the present invention, light emitted from a light source is incident on one port on one end of the optical fiber coupler, and this incident light is incident on a port on the other end of the optical fiber coupler and enters the optical fiber. do. After that, the light propagated in the optical fiber, that is, the excitation light from the light source, generates light with a certain wavelength width different from that of the light source light by stimulated Raman scattering,
The excitation light from the light source is emitted from the output end face of the variable optical fiber grating connected to the other end of the optical fiber. On the other hand, of the stimulated Raman scattered light generated in the optical fiber, only light with a wavelength selected by the variable optical fiber grating is output. In addition, by forming an optical fiber end face mirror on the end face of the remaining port on one end side of the optical fiber coupler or the end face of the optical fiber connected to this port, stimulated Raman scattering that is selectively reflected by the tunable optical fiber type grating. Light can be sent back and forth between the variable optical fiber type grating and the optical fiber end mirror.

(Embodiment) FIG. 1 is a diagram showing an embodiment of a wavelength tunable optical fiber Raman laser according to the present invention. In the figure, 10 is a light source such as an argon laser, and 11 is a lens that collects the light emitted from the light source and couples it to one end of the optical fiber 12.

1,3 has a light output port on both ends.■

An optical fiber coupler with ■, ■, and ■, the other end side of the optical fiber 12 is connected to the port
One end of an optical fiber 15 is connected to one end of the optical fiber 4 and port (2) by a fusion splicing method.

FIG. 3 is a diagram for explaining the structure of the optical fiber coupler 13. According to FIG. 3, the optical fiber coupler 13 is constructed by arranging single mode optical fibers 13a and 13b in parallel, and fusion-stretching the central portions of the optical fibers 3a and 13b. Normally, in a single mode optical fiber, the power of the propagating light is transmitted through the core and cladding (for example, the normalized frequency V
= 2.0λ: Wavelength, 2a: Core diameter, n Nicore refractive index.

(2) As n2 (refractive index of the cladding) becomes smaller, the optical power leaking from the core to the cladding increases.

For this reason, the value of the normalized frequency V, more specifically the core diameter 2a, is small in the fusion-stretching part, so that the light incident from the port ■, for example, is transmitted through the ports ■ and port ■, that is, the optical fibers 13a-, 13b. − is combined with Figure 4 shows port ■ when light of different wavelengths is input from port ■.
This is a diagram showing the relationship between the output from the wavelength and the wavelength, with the horizontal axis representing the wavelength and the vertical axis representing the coupling rate P = sin 2 (cλ + φ) (where λ is the wavelength and C2φ is a constant). As shown in Fig. 4, by adjusting the outer diameter and length of the fused and stretched portion and appropriately selecting the above constants C and φ, the excitation light from the light source 1° is transferred from port ■ to port ■, and vice versa. The wavelength of the light from the light source 10 is different from that of the light source 10, so that almost all of the stimulated Raman scattered light having a certain wavelength width can be propagated from port (2) to port (2).

16 is a tunable optical fiber grating (hereinafter referred to as an optical fiber (referred to as a grating), one end of which is fusion-spliced to the other end of the optical fiber 5, and the other end is coated with anti-reflection coating, and serves as the output end face of the wavelength-tunable optical fiber Raman laser.

Such an optical fiber grating 16 is made by using an apparatus as shown in FIG. incident on ,
It was created by creating a standing wave in the optical fiber 21 and changing the optically induced refractive index.
t,, Vol, 32. no, 10. PP, B47-8
49.1978), in Fig. 5, 22 is a variable attenuator;
23 is a half mirror, 124 is a lens, 25 is a quartz clamp, 26 is a v groove magnetic mount, 27.2
8 is a detector, and 29 is an absorber.

Optical fiber grating 1 produced in this way
6 has strong wavelength selectivity, 01inchλ~0.3A
In order to make the spectral width variable, the temperature of the optical fiber grating 16 can be controlled, or the optical fiber grating can be mounted on a material that has an electrostrictive effect to heat it. Alternatively, it can be done by electrically changing the period of the grating, or it can also be stretched mechanically. Furthermore, since the linear expansion coefficient of quartz is 5.4 x 10-7/°C, when the temperature is changed between 0 and 1000°C and the Raman center wavelength is approximately 0.5 μm, the variable wavelength range is approximately It is IA.

16 is an optical fiber end face mirror in which the ratio of reflected light (97%) and transmitted light (3%) is set by coating the end face on the other end side of the optical fiber 14.

Next, to explain the operation of the above configuration, first, the light source 1
The light emitted from the optical fiber 12 is condensed by a lens 11 and enters one end of an optical fiber 12, propagates through this optical fiber 12, and enters a port (3) of an optical fiber coupler 13. This incident light is coupled to the optical fiber 13a-, exits from the port (2), and enters the optical fiber 15. optical fiber 15
The incident light generates stimulated Raman scattered light in the optical fiber pipe 5. In a silica-based optical fiber, as shown in FIG. 6, the strongest stimulated Raman scattered light is at a wavelength shifted by about 440 cm-1 relative to the light from the light source 10, but the wavelength width of the Raman scattered light is 300 cm-1. ' (peak intensity range of about -20 dB).

Here, the light from the light source 10 enters the optical fiber grating 16 fusion spliced to the other end of the optical fiber 15,
The light propagates through the optical fiber grating 16 and is emitted from the output end face. However, among the generated stimulated Raman scattered light,
0 corresponding to the reflected light of the optical fiber grating 16
．． The light having a width of 01 i is reflected by the optical fiber grating 16 and enters the port (2) of the optical fiber coupler 13 via the optical fiber 15. Optical fiber coupler 13
almost all of the stimulated Raman scattered light in the entire wavelength range is transmitted from port (2) to port (2), and 97% of the optical power is reflected by the optical fiber end mirror 17 via port (2) and the optical fiber 14. The reflected light propagates from port ■ to port ■ of the optical fiber coupler 13, and while traveling back and forth between the optical fiber grating 16 and the optical fiber end mirror 17, the light source 10
It is selectively amplified by the light from the optical fiber, that is, the excitation light, and 3% of the high-intensity, narrow-spectrum stimulated Raman scattering light is emitted from the optical fiber end mirror 17.

Furthermore, the wavelength of this emitted light can be changed by changing the grating period as described above.

According to this embodiment, except for the light source 10, an optical fiber coupler and a grating made of optical fibers are used, so there is no need to use large optical components, and the device can be made smaller and more stable. A wavelength tunable optical fiber Raman laser with excellent performance and reliability can be realized.

In this example, the variable wavelength range is described as being about 1, but by heating the softening point of the optical fiber to about 1600°C and stretching it, a wider variable wavelength range of about 1006 can be obtained. be able to.

Furthermore, the light emitted from the light source 10 is input to the optical fiber coupler 13 via the lens 11 and the optical fiber 12.
Further miniaturization and stability can be achieved by directly coupling an optical fiber coupler to the light source. In addition, the optical fiber 14 is fusion-spliced to the port (2), and the optical fiber end mirror 17 is formed on the other end side of the optical fiber 14. Of course, it may be formed.

(Effects of the Invention) As explained above, according to the present invention, the excitation light source has two ports on one end side and one port on the other end side, and the emitted light from the light source an optical fiber coupler that enters one port on the one end side, an optical fiber whose one end side is connected to a port on the other end side of the optical fiber coupler, and a - end side connected to the other end side of the optical fiber coupler. Since it is equipped with a variable optical fiber type grating, everything except the light source is composed of optical fibers, so there is no need for large optical components, and the input and output end faces of each member can be connected to each other using methods such as fusion splicing. This has the advantage of providing a wavelength tunable optical fiber Raman laser that can be connected, the device can be miniaturized, and is optically stable and highly reliable. It can also be applied as a variable light source or in the spectroscopic field.

In addition, by forming an optical fiber end face mirror on the end face of the remaining port on one end side of the optical fiber coupler or the end face of the optical fiber connected to this port, stimulated Raman scattering that is selectively reflected by the tunable optical fiber type grating. Since light can be sent back and forth between the tunable optical fiber type grating and the optical fiber end mirror, stimulated Raman scattered light can be amplified even with a short optical fiber.
This has the advantage of further downsizing.

[Brief explanation of the drawing]

Fig. 1 is a diagram showing an embodiment of the wavelength tunable optical fiber Raman laser according to the present invention, Fig. 2 is a diagram showing a conventional wavelength tunable optical fiber Raman laser, and Fig. 3 is for explaining the structure of the optical fiber coupler. Figure 4 shows the relationship between the output from the optical fiber coupler and the wavelength, Figure 5 shows the optical fiber grating manufacturing device, and Figure 6 shows the spectrum and shift amount of Raman scattered light. It is a diagram. In the figure, 10... light source, 13... optical fiber coupler,
15... Optical fiber, 16... Tunable optical fiber type grating (optical fiber grating). Patent: Yasushi Hatake Agent, Nippon Telegraph and Telephone Corporation
Yoshi, Patent Attorney 1) Takashi Sei Wavelength (, am) Diagram 4, diagram 5 showing the relationship between output and growth from an optical fiber coupler

Claims (2)

[Claims] (1) An excitation light source, and an optical fiber coupler having two ports on one end side and one port on the other end side, and the light emitted from the light source enters the one port on the one end side. and an optical fiber having one end connected to a port on the other end of the optical fiber coupler, and a variable optical fiber type grating having one end connected to the other end of the optical fiber. Tunable fiber Raman laser. (2) Claim 1, wherein an optical fiber end face mirror is formed by coating the end face of the remaining port on one end side of the optical fiber coupler or the end face of the optical fiber connected to the port.
The wavelength tunable optical fiber Raman laser described above.