JP2001044537A - Optical medium, manufacture thereof, laser light generator, and optical amplifier - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a highly reliable laser, which has a spatially high-quality mode while maintaining expandability for exciting light introduction for side pumping and a high light condensing ability, and as a result, high output and high luminance. SOLUTION: One layer of belt-like multi-core fiber 1 is obtained by arranging preforms for silica optical fibers in an array and simultaneously fiber drawing the preforms. A plurality of cores (2), constituting the fiber 1, contains an active substance. The fiber 1 is cut into pieces having an appropriate length, and both end faces 1a and 1b of the cut pieces are connected to each other. At the connecting of both end faces 1a and 1b to each other, both ends 2a and 2b of the cores 2 of the cut pieces are connected, so that the connections are shifted by the amount of one core and the cores 2 may form one continuous optical path 3. The belt-like core fiber 1 is caused to generate laser light by making excitation light capable of being introduced to the fiber 1 from its side face.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical medium, a method for manufacturing the same, a laser light generator, and an optical amplifier, and more particularly to an optical medium suitable for use in an optical fiber laser oscillator or an optical waveguide laser oscillator.

[0002]

2. Description of the Related Art In recent years, an inexpensive high-power laser light generator has been desired in the field of optical communication or optical processing technology. By the way, conventionally, the optical fiber laser oscillator or the optical waveguide type laser oscillator increases the interaction between the laser active material and the light by confining the light at a high density and increases the interaction length by increasing the length. Since the mode has high efficiency and the mode is spatially limited as a guided mode, spatially high-quality laser light can be generated. Therefore, inexpensive and high-quality laser light can be obtained.

As a means of generating high-quality laser light utilizing the superiority of a laser fiber, by introducing excitation light from the side of the laser fiber, the expandability of the total input amount of excitation light is improved and the condensing property of output laser light is improved. Japanese Patent Application Laid-Open No. 10-135548 and Japanese Patent Application Laid-Open
-1990097.

According to these methods, when the excitation light is introduced from the side surface into the region (usually the core portion) where laser active ions or dyes or other luminescent centers are added, the addition of laser active ions or dyes or other luminescent centers is usually required. The waveguide length (L) is much longer than the diameter (d) of the region (usually the core), and L /
Since d> 10 ⁶ or more can be obtained, it becomes possible to introduce much more excitation energy into the fiber or the waveguide than the method of introducing the excitation light from the cross-sectional direction of the waveguide.

Moreover, since the laser light to be extracted is only the mode determined by the waveguide structure of the fiber, approximately the output light from the fiber can be focused up to the core diameter of the fiber. If the fiber transmits only a single mode, the extracted light can be collected to the diffraction limit.

[0006]

SUMMARY OF THE INVENTION The above-mentioned Japanese Patent Application Laid-Open No.
In the method disclosed in JP-A-135548 and JP-A-10-199007 (hereinafter, referred to as a structure-type fiber laser), a fiber manufactured in advance is basically wound or arranged in a continuous connection. Constitute. At this time, the required fiber length is several tens of meters or more, but it has been difficult to manufacture the fiber with good yield without cutting it.

[0007] In the case where a quartz fiber is not coated, its strength is greatly reduced due to a change with time, and there is a high risk of cutting, and a decrease in yield is expected. In addition, after winding and arranging are completed, steps such as filling the voids between the fibers with a resin or an inorganic transparent substance or fusing the fibers with the fibers are necessary, but even if defoaming, Even if a small amount of bubbles remain, the bubbles become scattering sources, which lowers the efficiency. Resins have relatively low heat resistance and laser power resistance, and thus have a problem that reliability is impaired.

A double-clad fiber laser having a rectangular cross section is also known, but since the number of cores cannot be increased, [cross-sectional area of core (total)] / [cross-sectional area through which excitation light propagates]
And the absorption length of the excitation light cannot be shortened.

An object of the present invention is to solve the above-mentioned problems of the prior art and to manufacture the semiconductor device with a high yield.
In addition, while maintaining the expandability of the side-pumped pumping light, it has a spatially high-quality mode, has high light-gathering ability, and as a result, can realize a high-output, high-brightness laser device with high reliability. To provide an optical medium, a method of manufacturing the same, a laser light generator, and an optical amplifier.

[0010]

According to a first aspect of the present invention, there is provided an optical medium having a plurality of light guides and a cladding for covering a side surface of the light guide as a waveguide structure for guiding a laser beam. At one end of the medium of the optical medium, one end of the light guide of each light guide is disposed, and at the other end of the medium of the optical medium, the other end of the light guide of each light guide is disposed. At least one light guide from one of the light guide ends of the light guide portion, through each of the plurality of light guide portions, to one of the light guide other ends of the light guide portions at the other end portion of the medium. One end of the medium and the other end of the medium are connectable or connected so as to form one continuous optical path, and at least a part of the light guide section forming the optical path contains an active substance. It is an optical medium characterized by the following.

[0011] Since a plurality of light guides are connected to form a continuous light path, they are wound or arranged in comparison with a case where a single long light guide is originally produced as a single connection. Is also unlikely to be cut, and can be manufactured with high yield.

According to a second aspect of the present invention, in the first aspect, a clad that covers the side surface of each of the light guides is integrated and transmits an excitation light for exciting the active material. An excitation light introduction unit for introducing excitation light into the cladding, and an excitation light reflection unit for reflecting the excitation light around the clad so that the excitation light incident from the excitation light introduction unit is repeatedly absorbed by the active material. And an optical medium having: By having the excitation light reflecting portion, the excitation light can be confined within the region in the cladding including each light guide portion,
Side excitation can be performed efficiently.

[0013] In a third aspect based on the first aspect, the excitation light is provided between the claddings that cover side surfaces of the plurality of light guide sections and transmit the excitation light for exciting the active material. Each of the claddings is optically connected so as to be able to move back and forth, and has a pumping light introducing portion for introducing pumping light to at least one of the claddings on a side surface, and pumping light incident from the pumping light introducing portion. Is an optical medium provided with an excitation light reflecting portion that reflects excitation light so as to collectively cover the claddings so that the active material is repeatedly absorbed. Since the excitation light reflecting portion that reflects the excitation light is provided so as to cover each clad at a time, the excitation light can be confined in each clad including the light guide portion or in the region including each clad, and the efficiency can be improved. Side excitation can be performed well.

A fourth invention is the optical medium according to the first to third inventions, wherein the light guide is a core of an optical fiber. When the light guide is composed of an optical fiber having a core and a clad integrated with each other, an optical medium having excellent light collecting properties can be obtained.

A fifth invention is an optical medium according to the fourth invention, wherein the optical fiber is a glass fiber, and the side surfaces of the optical fiber are fused to each other. Since the sides of the optical fiber are fused together, unlike the case where they are not fused, after winding and arranging are completed, the gap between the fiber and the fiber is filled with resin or an inorganic transparent substance, A process such as fusing the fiber becomes unnecessary. For this reason, defoaming is difficult due to the above-mentioned process, which is a scattering source, and the efficiency is reduced. In addition, heat resistance and laser power resistance of resin are relatively low, and reliability is not deteriorated.

According to a sixth aspect of the present invention, in the first to fifth aspects, the plurality of light guides are arranged in a band shape, and one light guide end and the other light guide end of each light guide are aligned. An optical medium in which one end of the medium and the other end of the medium are connectable or connected in a state where one end of the light guide and the other end of the light guide of each of the light guide sections are shifted by one from the position. By simply shifting the light guide one end and the light guide other end of each light guide unit one by one and connecting the medium one end and the medium other end, a continuous optical path can be easily formed.

In a seventh aspect based on the sixth aspect, the one end portion and the other end portion are wound in a state where a plurality of light guide portions arranged in a belt shape are wound and twisted the number of times. The connected optical medium. Since the one end and the other end of the medium are connected in a twisted state, the distortion is eliminated when the medium is wound around the object to be wound such as a cylinder after the connection.

An eighth invention is the optical medium according to any one of the first to seventh inventions, further comprising an optical component, wherein the one end and the other end are connected via the optical component. By inserting optical components such as optical switches in the middle of the optical path,
A function such as polarization plane control can be provided while maintaining the form of an optical medium for a laser light emitting device or the like.

A ninth invention is a method for manufacturing an optical medium according to the fifth invention, wherein a plurality of glass preforms for optical fibers are arranged, and the plurality of preforms are simultaneously drawn to fuse their side surfaces with each other. Make the optical fiber in a state,
Cutting the optical fiber to obtain an optical medium is a method for manufacturing an optical medium. By arranging a plurality of glass preforms and drawing them at the same time to obtain a single layered multi-core fiber, the whole can be easily integrally formed with glass. If the obtained fiber is cut into a suitable length and both end faces are connected so that the core forms a continuous optical path, the production of an optical medium is easy.

According to a tenth aspect, there is provided the optical medium according to any one of the first to eighth aspects, and an excitation light source for introducing excitation light from a side surface of the light guide provided in the optical medium. Excitation light is guided to the optical medium to excite the active substance,
This is a laser light generator configured to output laser light from a light guide unit. According to this, the reliability is high, and more excitation light is incident from the light guide side surface of the optical medium.
A laser device having a configuration with excellent power resistance can be constructed.

According to an eleventh aspect of the present invention, there is provided the optical medium according to any one of the first to eighth aspects, and an excitation light source for introducing excitation light from a side surface of the light guide provided in the optical medium. Excitation light is guided to the optical medium to excite the active substance,
It is an optical amplifier that amplifies and outputs light guided by the light guide unit. Since more excitation light is incident from the side of the light guide section of the optical medium, a highly reliable laser device having a high amplification degree can be constructed.

[0022]

Embodiments of the present invention will be described below.

An obstacle to the production of a structure-type fiber laser is that the fibers are folded to form an integrated type while keeping the fibers connected. The fact that they are folded in a series places relatively small restrictions on the overall scale. For example, if you do not fold, if it is a series, this is a single line of fiber,
Basically, there is no scale limit. This means that even in a bundle shape in which a plurality of fibers are bundled without being folded, the same scale is not applied. In a form without scale limitation, the same product (part) can be easily mass-produced by producing a long product and cutting it into an arbitrary length.

In the embodiment, first, a plurality of (two or more) laser fiber preforms run in parallel by arranging a plurality of laser fiber preforms side by side in an array, and simultaneously forming the fibers while fusing them together in a drawing furnace. A one-layer strip-shaped multi-core fiber or a tape-shaped multi-core bundle (optical medium) having a doped core (light guide) 2 is produced (FIG. 1). The side surface of the doped core 2 is covered with a clad and has a waveguide structure in which the core guides laser light. The cladding is transparent to laser light and excitation light guided by the core. Here, the clads covering the respective cores are fused and integrated with each other, but the respective clads may be optically connected so that excitation light can flow between the respective clads.

FIG. 1 (a) shows this single-layer multicore fiber 1 (one layer in the thickness direction). Then, as shown in FIG. 1B, both end surfaces (one end portion of the medium and the other end portion of the medium) 1a and 1b are connected to one end (light guide one end) 2a of the core 2 and the other end (light guide other end) of the core. ) 2b are connected so as to be shifted by one. The connection can be any of a butt connection, an adhesive connection, and a fusion connection, and a fiber array connection technique can be used. When connected, the core 2 becomes a continuous optical path 3 as a whole. Independent feed fibers 4 for extracting output light are connected to the cores 2 having no connection partner at both end surfaces 1a and 1b. If a reflecting mirror (not shown) is attached to one end face 4a of the feed fiber 4, a laser light emitting device that emits light only from the other end face 4b is formed. If an input port (not shown) for signal light is provided on one end face 4a of the feed fiber 4, it functions as an optical amplifier that outputs amplified signal light from the other end face 4b.

As shown in FIG. 2, the band-shaped multi-core fiber 1 corresponding to the excitation light absorbing portion can be wound around a support base 7 such as a support cylinder or column. This winding may be performed after or before connection. But,
When winding after connection, it is necessary to twist the fiber 1 in advance by the number of times of winding.

The band-shaped multi-core fiber 1 shaped by winding or the like is provided with an appropriate pumping light introduction port 5 for side pumping. In FIG. 2, in order to input the excitation light, a plurality of excitation light introducing strip fibers 8 are provided on the side surface of the wound strip multi-core fiber 1 in accordance with the number of turns.

FIG. 3 shows a cross section of the strip-shaped multi-core fiber 1 at a portion where the pumping light introduction port 5 is provided. Excitation light A introduced from the excitation light introduction port 5
Is absorbed by the active material in the core 2 while propagating in the clad 11, and the laser light or the signal light B is generated or amplified in the core 2.

The pumping light introduction port 5 for side pumping
It is easy to add more. Excitation light introduction strip fiber 8
In addition to the connection, the use of a lens duct to input the excitation light,
There are methods such as installation of a prism. The installation location can also be set from the side surface (thin side, that is, the surface having a large surface area) of the band-shaped multi-cover fiber 1.

The shape of the core 2 is hardly deformed by drawing the excitation light absorbing portion and forming it by the stretching method.
Since the number of scattering sources such as bubbles can be easily reduced, the propagation loss of the excitation light can be reduced. In addition, even if it has the same aspect ratio as the conventional double-clad fiber laser having a rectangular cross section, the present invention increases the number of cores, so that [cross-sectional area of core (total)] / [excitation light Propagating cross section]
Is several times larger, so that the excitation light absorption length can be shortened.
In addition, since a long object can be easily manufactured, it can be said that the present invention is a technique particularly suitable for obtaining a single-mode laser output having a small core size. Therefore, it is particularly effective in the field of ultrafine processing and the field of optical communication.

By the way, an advanced technique has been established for the connection technology of the fiber array at present, and it is possible to make the loss at the connection portion at the end face small enough to be ignored. At this time, for example, as shown in FIG.
An optical component 9 such as an isolator can be inserted.

According to the present invention, an optical component such as a waveguide component such as an optical switch, a polarizer, a saturable absorber,
By inserting a second harmonic generation crystal, an electro-optical element, or the like, Q switching, mode locking, polarization plane control, wavelength conversion, and the like can be performed.

In the present invention, "at least one continuous optical path" means that an active branch waveguide, that is, an element capable of changing the coupling efficiency to a branch by voltage control is connected to the connection portion, and the continuous optical path is formed. Including cases where two or more can be performed. A waveguide-type ring laser and a structure-type fiber laser are coupled by an active branch waveguide element. First, a branch gate is opened to form a ring, and when sufficient energy is stored in the ring, the branch is performed. Reverse the gate to extract energy, Q
It can be used by performing a switch operation or the like.

The optical medium may be in a flexible state like an optical fiber, may be covered with a material having a lower refractive index than the clad to maintain the flexible state, One part may be flexible so that the unit and the other end of the medium can be connected directly or through an optical component. Also, the one end of the medium and the other end of the medium are connected directly or through an optical component. After that, the material may be hardened with a material such as a resin that transmits excitation light and has light resistance.

By making the material covering the cladding a material having a lower refractive index than that of the cladding, the excitation light can be totally reflected at the interface between the material and the cladding. An excitation light reflecting portion for confining the excitation light in the cladding, such as covering the cladding with a low refractive index substance, can be provided. When the excitation light reflecting portion is integrated with the cladding covering each core, when the cladding surrounding each core is optically connected so that excitation light can flow to each other around the cladding, It is preferable to provide them so as to cover each clad collectively.

[0036]

[Example] (Example 1) Core diameter 1.6 mm, clad diameter 4.0 ×
Ten preform rods for silica glass fiber with a numerical aperture of 0.2 with a numerical aperture of 0.2 and a core of 4.0 mm rectangular cross section and doped with 0.5 at% Nd3 ⁺ ions are arranged in parallel, and the silica fiber drawing furnace is placed in contact with each other. Heat and stretch with a thickness of 125μ
A strip-shaped multicore fiber having a width of 1.25 mm and a length of 1.25 mm was manufactured to about 800 m. The entire surface of the strip-shaped multi-core fiber is coated with a protective coating. From this fiber
3 m was cut out, and both end faces were polished obliquely (10 °). After twisting this fiber four times, both ends were connected. At this time,
The connection was performed such that the core row was shifted by one. At the time of connection, a fiber with a cladding diameter of 125 × 125 μm rectangular cross section and a core diameter of 50 μm is connected in advance with the cladding closely attached to the widthwise end of the strip-shaped multi-core fiber, and the light is emitted while monitoring the amount of light transmitted through the core of the strip-shaped multi-core fiber. It was fused by a CO ₂ laser where the light intensity was at a maximum.

After that, as shown in FIG. 2, the support base 7 was wound around a metal cylinder having an outer diameter of 65 mm and fixed with an adhesive. A slit 10 having a width of 10 mm is provided vertically in the cylinder. Coatings on all four surfaces of the wound band-shaped multi-core fiber 1 corresponding to the slit portions are removed to obtain a thickness of 100 μm, a width of 1.0 mm, Excitation light introducing fibers 8 having a numerical aperture of 0.15 were fused to the four side surfaces where the coating was removed at a contact angle of 15 °. The excitation light introducing fiber 8 has a wavelength of 810n narrowed down by a cylindrical lens.
When 20 m of LD light was introduced into each, 20 W of laser light with a wavelength of 1.06 μm with a total of 32 W was obtained from the end faces of the two output light extraction fibers 4.

(Embodiment 2) The general outline is the same as that of Embodiment 1, but in Embodiment 1, the mode of the output laser light is multi-mode, whereas in this embodiment, the output laser light is single-mode emission. Is different. Five 1m silica glass fiber preform rods with a core diameter of 500μm and a cladding diameter of 8.0 × 8.0mm, with a numerical aperture of 0.2 and a core of 0.2atm, doped with 0.5at% Nd3 ⁺ ions, are arranged in parallel. While being in contact, it was heated and stretched in a quartz fiber drawing furnace to form a band-shaped multi-core fiber 125 μm thick and 625 μm wide.
1700m was produced. At this time, the core diameter per core is about 8
μm, and becomes completely single mode at the oscillation wavelength of 1.06 μm. In addition, an ultraviolet curable resin having a refractive index of 1.38 was coated in-line. 120 m was cut out from this fiber, wound around a metal cylinder having an outer diameter of 100 mm, and both end surfaces were polished obliquely (10 °).

At the time of connection, a fiber having a cladding diameter of 125 × 125 μm and a core diameter of 8 μm is connected to the end of the band-shaped multi-core fiber in advance with the cladding closely contacted, and the amount of light transmitted through the core of the band-shaped multi-core fiber is monitored. While bonding was performed at the point where the amount of emitted light was maximized, the optical adhesive was used. At this time, connection was performed such that the core row was shifted by one.

After that, the coating on one side of the wound multi-core fiber was removed at two intervals of 60 cm, and the excitation light introducing fiber having a thickness of 125 μm, a width of 0.5 mm and a numerical aperture of 0.15 was formed at a contact angle of 15 °. The connection was made using an optical resin. When the LD light with a wavelength of 810 nm, which was narrowed down by a cylindrical lens, was introduced into the excitation light introduction fiber by 20 W, a laser output with a wavelength of 1.06 μm was obtained at a total of 16 W from the end faces of the two output light extraction fibers. Was.

When a 99.9% reflecting mirror was set on one of the output tapping fibers, an output of 14 W was obtained from the other. The output laser light was completely single mode (M ² = 1). Also remove the mirror and input 10dB
When a signal light having a wavelength of 1.06 μm was input, a signal light output of about 30 dBm was obtained from the other end face.

(Embodiment 3) In this embodiment, a polarizing plate is incorporated in the form of Embodiment 2. 0.5at% N inside core with 500μm core diameter, 8.0 × 8.0mm clad diameter rectangular cross section
d ³ side by side silica glass fiber preform rod 1m having a numerical aperture of 0.2 which is doped with ions to five parallel, while contacting each other, heating a quartz fiber line drawing furnace, the thickness of 125μm by stretching, the width 625μm A strip-shaped multi-core fiber was manufactured at about 1700 m. At this time, the core diameter per core is about
8 μm, and becomes completely single mode at the oscillation wavelength of 1.06 μm. In addition, an ultraviolet curable resin having a refractive index of 1.38 was coated in-line. 120 m was cut out from this fiber, wound around a metal cylinder having an outer diameter of 100 mm, and both end faces were vertically polished. As shown in FIG. 4, a polarizing element as a thin-film type optical component 9 is sandwiched at the time of connection.
The connection was made so as to be shifted by an amount. After that, the coating on two sides of the wound strip-shaped multi-core fiber was removed at intervals of 60 cm, and the thickness was 125 μm and the width was 0.5 m.
An excitation light introducing fiber having an aperture of 0.15 m and a numerical aperture of 0.15 was connected at a contact angle of 15 ° using an optical resin. A 810 nm LD laser with an output of 20 W was supplied to the pumping light introducing fiber. As a result, single-polarization single-mode laser oscillation with a total output of 6 W was confirmed.

[0043]

According to the present invention, the optical medium is composed of a plurality of light guides, and both ends of the medium are connectable or connected so that the plurality of light guides form a continuous optical path. Therefore, an optical medium can be manufactured with a higher yield than that in which an optical path is formed from a single long light guide.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram of an optical medium according to an embodiment;
(A) is a plan view of a single layer multi-core fiber,
(B) is a perspective view of an optical medium in which both end surfaces of a single band multi-core fiber are connected to each other so that the core is shifted by one core, and the core as a whole is a continuous optical path.

FIG. 2 is a configuration diagram of a laser light generator according to an embodiment, which is produced by being wound around a support base such as a cylinder, in which a plurality of excitation light introduction fibers are provided to supply excitation light.

FIG. 3 is a cross-sectional view of a strip-shaped multi-core fiber in a portion provided with an excitation light introduction port according to an embodiment.

FIG. 4 is an explanatory diagram of another optical medium according to the embodiment, in which an optical component such as an isolator is inserted into a connection portion.

[Explanation of symbols]

 Reference Signs List 1 strip-shaped multi-core fiber (optical medium) 1a one end face of strip-shaped multi-core fiber (one end of medium) 1b other end face of strip-shaped multi-core fiber (other end of medium) 2 doped core (light guide) 2a one end of core (light guide one end) 2b The other end of the core (the other end of the light guide) 3 A continuous optical path

Claims (11)

[Claims] 1. An optical medium comprising a plurality of light guides and a cladding for covering a side surface of the light guide as a waveguide structure for guiding a laser beam, wherein one end of the medium of the optical medium is provided. Has one light guide end of each light guide,
The other end of the light guide of the optical medium is provided at the other end of the medium, and one of the light guides of the light guide at the one end of the medium is provided with the plurality of light guides. Through the other end of the light guide unit at the other end of the medium, one end of the medium and the other end of the medium can be connected so as to form at least one continuous optical path. Alternatively, the optical medium is connected, and at least a part of the light guide forming the optical path contains an active substance. 2. A pump according to claim 1, wherein a clad covering a side surface of each of said light guide portions is integrated and transmits an excitation light for exciting said active substance, and said excitation light is introduced into said side surface to said clad. A light introducing part, comprising: an exciting light reflecting part that reflects the exciting light around the cladding so that the exciting light incident from the exciting light introducing part is repeatedly absorbed by the active material. 2. The optical medium according to 1. 3. Each of the claddings covers the side surface of each of the plurality of light guides, and each of the claddings is optically coupled between the claddings that transmit the excitation light for exciting the active substance. And an excitation light introducing portion for introducing excitation light to at least one of the claddings on a side surface, so that the excitation light incident from the excitation light introducing portion is repeatedly absorbed by the active material. 2. The optical medium according to claim 1, further comprising: an excitation light reflecting portion that reflects the excitation light so as to collectively cover the claddings. 4. The optical medium according to claim 1, wherein the light guide is a core of an optical fiber. 5. The optical fiber is a glass fiber,
The optical medium according to claim 4, wherein side surfaces of the optical fiber are fused to each other. 6. A light guide one end of each light guide section from a position where one end of each light guide section is aligned with the other end of the light guide section. The optical medium according to any one of claims 1 to 5, wherein the one end of the medium and the other end of the medium are connectable or connected with the other end of the light guide being shifted one by one. . 7. The one end and the other end are connected in a state in which a plurality of light guides arranged in a belt shape are wound and twisted the number of times of winding. Item 7. The optical medium according to Item 6. 8. The optical device according to claim 1, further comprising an optical component, wherein one end of the medium and the other end of the medium are connected via the optical component. Medium. 9. A method for manufacturing an optical medium according to claim 5, wherein a plurality of glass preforms for optical fibers are arranged, and the plurality of preforms are simultaneously drawn to fuse their side surfaces to each other. A method for producing an optical medium, comprising producing an optical fiber and cutting the optical fiber to obtain an optical medium. 10. An optical medium according to any one of claims 1 to 8, and an excitation light source for generating excitation light for exciting an active substance contained in a light guide provided in the optical medium. The excitation light output from the excitation light source is guided to the optical medium, enters the light guide from the side of the light guide, excites the active substance, and outputs laser light from the light guide. Laser light generator. 11. An optical medium according to claim 1, further comprising: an excitation light source for generating excitation light for exciting an active substance contained in a light guide provided in the optical medium. The excitation light output from the excitation light source is guided to the optical medium, enters the light guide from the side of the light guide, excites the active substance, and amplifies the laser light guided by the light guide. Output optical amplifier.