RU2564519C2 - Passively mode-locked fibre pulsed ring laser (versions) - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: passively mode-locked fibre pulsed ring laser comprises optically coupled pumping radiation source, fibre ring resonator having an amplifying fibre, a fibre spectral information module, a polarisation-dependent splitter, a polarisation-dependent insulator, first and second fibre ends which do not reflect laser radiation back to the fibre. First and second collimators are placed between the fibre ends. All fibre elements of the resonator support radiation polarisation. Between the collimators there are two radiation focusing optical elements, between which, at the laser radiation beam waist, there is an optical element with Kerr-type nonlinearity, having thickness greater than 0.5 mm with laser radiation transmitting surfaces, having an angle of inclination to the laser resonator axis of not less than 1 degree.

EFFECT: enabling generation of short-pulse radiation with a low noise level in a wide spectral range.

34 cl, 5 dwg

Description

The present invention relates to lasers - devices for the generation of coherent electromagnetic waves and is industrially applicable in devices and systems using laser radiation.

A fiber pulsed ring laser with passive mode locking (US Patent Application 20090003391 A1, Low-repetition-rate ring-cavity passively mode-locked fiber laser) is known in the art, in which a saturable absorber based carbon nanotubes or a semiconductor saturable absorber. The main disadvantage of saturating absorbers, including those based on carbon nanotubes, is their susceptibility to degradation when operating under conditions of high power density of the incident laser radiation required to achieve absorption saturation. In this regard, the typical life of saturable absorbers ranges from several hundred to several thousand hours. In addition, the preparation of a homogeneous matrix with carbon nanotubes and its deposition on a laser mirror or the manufacture of a semiconductor saturable absorber is a complex technological process, which is not always possible even in laboratory conditions.

Also known is a disk laser with synchronization of radiation modes using a Kerr lens in an optical element located in the laser cavity in the constriction of a laser beam (WO 2013050054 A1, Laser device with kerr effect based mode-locking and operation this). The disadvantage of this solution is that it is provided only for lasers with a disk active medium and does not provide for the use of the proposed radiation mode synchronization device in a fiber laser. In addition, the linear circuit of the laser resonator requires end mirrors of the resonator, which can limit the laser radiation spectrum and prevent the generation of the shortest pulses in duration. In addition, in the linear laser resonator there is the effect of “spatial burnout of dips” in the amplifying medium of the laser, which leads to the presence in the laser generation spectrum of weakly competing spectral components, the interaction of which with each other causes an increased level of noise of laser radiation intensity.

Closest to the claimed technical solution is a fiber pulsed ring laser with passive synchronization of radiation modes due to the effect of nonlinear evolution of radiation polarization in a resonator fiber that does not support radiation polarization (US Patent Application 2010/0220751 A1, All-normal-dispersion femtosecond fiber laser) . This solution has several drawbacks. Firstly, the radiation mode synchronization mode is started in it by tuning three phase plates (two quarter-wave phase plates and one half-wave) and there are algorithmic problems with the simultaneous tuning of all three of these plates: as a rule, the tuning of these plates is random until is the moment of radiation mode synchronization mode. Secondly, in a fiber laser with passive synchronization of radiation modes due to the effect of nonlinear evolution of polarization of radiation, various modes of synchronization of radiation modes can be realized (S. Smirnov et al. Three key modes of single pulse generation per round trip of all-normal-dispersion fiber lasers mode-locked with nonlinear polarization rotation. Optics Express, Vol. 20, Issue 24, pp. 27447-27453 (2012)), to characterize the obtained mode and determine the parameters of the pulses, it is necessary to use special measuring equipment after each procedure for setting the phase plates to run sync mode and radiation mode. Thirdly, fiber lasers with passive synchronization of radiation modes due to the effect of nonlinear evolution of polarization of radiation have a relatively high sensitivity to the ambient temperature and, when the temperature of the medium surrounding the fiber changes by several degrees, they require a new procedure for tuning phase plates to start the radiation mode synchronization mode .

The task to which the claimed inventions are directed is to create a fiber pulsed ring laser with a passive radiation mode synchronizer that does not require the use of complex expensive technologies and materials for its manufacture, which has an unlimited service life and a relatively low noise level of laser radiation intensity, while in the laser the emission spectrum is not limited to ensure generation of the shortest pulses in duration and there is the possibility of spectral tuning uu radiation in a wide spectral range.

This problem is solved due to the fact that in the known fiber pulsed ring laser with passive synchronization of radiation modes, containing an optically coupled pump radiation source, a fiber ring resonator containing an amplifying fiber, at least one fiber spectral information module for introducing pump radiation into the amplifying fiber, at least one polarization-dependent coupler for outputting radiation from the resonator, a polarization-dependent radiation isolator to provide a unidirectional generator tion, the first and second ends of the fiber, not reflecting the laser radiation back into the fiber, located between the first and second ends of the fiber, the first and second collimators, according to the invention, all fiber elements of the resonator support polarization of radiation, between the first and second collimators there are two focusing radiation optical elements between which an optical element with a Kerr nonlinearity and a thickness of more than 0.5 mm with pass-throughs for laser radiation is located in the waist of the laser beam features having an angle of inclination to the axis of the laser cavity of at least one degree.

In particular, the surfaces of the collimators and optical elements focusing the radiation, which are passable for laser radiation, can have an antireflection coating.

In particular, the surfaces of an optical element with Kerr nonlinearity that are passable for laser radiation can have an antireflection coating.

In particular, the surfaces of an optical element with Kerr nonlinearity, which are passable for laser radiation, can be Brewster.

In particular, in a collimated radiation beam between the collimator and the focusing radiation optical element, a polarizer can be located with passable surfaces for laser radiation having an angle of inclination to the laser cavity axis of at least one degree.

In particular, passages for laser radiation of the surface of the polarizer may have an antireflection coating.

In particular, both glass optical fiber and glass optical fiber doped with rare-earth elements or alloyed with oxides of germanium, phosphorus, as well as their combination can be used as a reinforcing fiber, while the compound of the chemical element Si, N, Ga can be included in the oxide matrix , Al, Fe, F, Ti, B, Sn, Ba, Ta, Zr, Bi.

In particular, a Raman laser can be used as a source of pump radiation from a fiber laser when fiberglass doped with germanium, phosphorus, and a combination of them is used as an amplifying fiber, while the compound of the chemical element Si, N, Ga, Al, Fe can enter the oxide matrix , F, Ti, B, Sn, Ba, Ta, Zr, Bi, and the Raman laser cavity can be formed by two fiber Bragg gratings having perpendicular to the beam or inclined strokes and reflecting the radiation of the first Stokes components of the Raman laser.

In particular, the Raman laser resonator can be formed by four fiber Bragg gratings having perpendicular to the beam or inclined lines, two of which are reflective for the radiation of the first Stokes component of the Raman laser, and the other two are reflective for the radiation of the second Stokes component of the Raman laser.

This problem is solved due to the fact that in the known fiber pulsed ring laser with passive synchronization of radiation modes, containing an optically coupled pump radiation source, a fiber ring resonator containing an amplifying fiber, at least one fiber spectral information module for introducing pump radiation into the amplifying fiber, at least one polarization-dependent coupler for outputting radiation from the resonator, a polarization-dependent radiation isolator to provide a unidirectional generator tion, the first and second ends of the fiber, not reflecting the laser radiation back into the fiber, located between the first and second ends of the fiber, the first and second collimators, according to the invention, all fiber elements of the resonator support polarization of radiation, between the first and second collimators there are two focusing radiation optical elements between which an optical element with a Kerr nonlinearity and a thickness of more than 0.5 mm with pass-throughs for laser radiation is located in the waist of the laser beam By means of features having an angle of inclination to the axis of the laser resonator of at least one degree, a three-port circulator is located between the second end of the fiber and the amplifying fiber, connecting the laser resonator with a spectrally selective reflective element.

In particular, the surfaces of the collimators and optical elements focusing the radiation, which are passable for laser radiation, can have an antireflection coating.

In particular, the surfaces of an optical element with Kerr nonlinearity that are passable for laser radiation can have an antireflection coating.

In particular, the surfaces of an optical element with Kerr nonlinearity, which are passable for laser radiation, can be Brewster.

In particular, in a collimated radiation beam between the collimator and the focusing radiation optical element, a polarizer can be located with passable surfaces for laser radiation having an angle of inclination to the laser cavity axis of at least one degree.

In particular, passages for laser radiation of the surface of the polarizer may have an antireflection coating.

In particular, both glass optical fiber and glass optical fiber doped with rare-earth elements or alloyed with oxides of germanium, phosphorus, as well as their combination can be used as a reinforcing fiber, while the compound of the chemical element Si, N, Ga can be included in the oxide matrix , Al, Fe, F, Ti, B, Sn, Ba, Ta, Zr, Bi.

In particular, a Raman laser can be used as a source of pump radiation from a fiber laser when fiberglass doped with germanium, phosphorus, and a combination of them is used as an amplifying fiber, while the compound of the chemical element Si, N, Ga, Al, Fe can enter the oxide matrix , F, Ti, B, Sn, Ba, Ta, Zr, Bi, and the Raman laser cavity can be formed by two fiber Bragg gratings having perpendicular to the beam or inclined strokes and reflecting the radiation of the first Stokes components of the Raman laser.

In particular, the Raman laser resonator can be formed by four fiber Bragg gratings having perpendicular to the beam or inclined lines, two of which are reflective for the radiation of the first Stokes component of the Raman laser, and the other two are reflective for the radiation of the second Stokes component of the Raman laser.

In particular, the spectrally selective reflective element may be a fiber Bragg grating.

In particular, a spectrally selective reflective element can be a volume element connected to the laser cavity through the third collimator and the third fiber end, which is the fiber end of the bi-directional port of the three-port circulator and does not reflect the laser radiation back into the fiber.

In particular, a spectrally selective reflective element may be a bulk diffraction grating.

In particular, the spectrally selective reflective element may be a mirror with a given spectral reflection band.

In particular, the spectrally selective reflective element may be a prism in combination with a reflecting mirror or a Littrov prism with a reflective coating on the surface onto which the laser beam normally falls after refraction on the input Brewster surface of the prism.

This problem is solved due to the fact that in the known fiber pulsed ring laser with passive synchronization of radiation modes, containing an optically coupled pump radiation source, a fiber ring resonator containing an amplifying fiber, at least one fiber spectral information module for introducing pump radiation into the amplifying fiber, at least one polarization-dependent coupler for outputting radiation from the resonator, a polarization-dependent radiation isolator to provide a unidirectional generator tion, the first and second ends of the fiber, not reflecting the laser radiation back into the fiber, located between the first and second ends of the fiber, the first and second collimators, according to the invention, all fiber elements of the resonator support polarization of radiation, between the first and second collimators there are two focusing radiation optical elements between which an optical element with a Kerr nonlinearity and a thickness of more than 0.5 mm with pass-throughs for laser radiation is located in the waist of the laser beam By means of features having an angle of inclination to the axis of the laser resonator of at least one degree, between the second end of the fiber and the amplifying fiber there is a fiber spectrally selective element.

In particular, the surfaces of the collimators and optical elements focusing the radiation, which are passable for laser radiation, can have an antireflection coating.

In particular, the surfaces of an optical element with Kerr nonlinearity that are passable for laser radiation can have an antireflection coating.

In particular, the surfaces of an optical element with Kerr nonlinearity, which are passable for laser radiation, can be Brewster.

In particular, in a collimated radiation beam between the collimator and the focusing radiation optical element, a polarizer can be located with passable surfaces for laser radiation having an angle of inclination to the laser cavity axis of at least one degree.

In particular, passages for laser radiation of the surface of the polarizer may have an antireflection coating.

In particular, both glass optical fiber and glass optical fiber doped with rare-earth elements or alloyed with oxides of germanium, phosphorus, as well as their combination can be used as a reinforcing fiber, while the compound of the chemical element Si, N, Ga can be included in the oxide matrix , Al, Fe, F, Ti, B, Sn, Ba, Ta, Zr, Bi.

In particular, a Raman laser can be used as a source of pump radiation from a fiber laser when fiberglass doped with germanium, phosphorus, and a combination of them is used as an amplifying fiber, while the compound of the chemical element Si, N, Ga, Al, Fe can enter the oxide matrix , F, Ti, B, Sn, Ba, Ta, Zr, Bi, and the Raman laser cavity can be formed by two fiber Bragg gratings having perpendicular to the beam or inclined strokes and reflecting the radiation of the first Stokes components of the Raman laser.

In particular, the Raman laser resonator can be formed by four fiber Bragg gratings having perpendicular to the beam or inclined lines, two of which are reflective for the radiation of the first Stokes component of the Raman laser, and the other two are reflective for the radiation of the second Stokes component of the Raman laser.

In particular, the fiber spectral selective element may be a Fabry-Perot fiber interferometer or a Mach-Zehnder fiber interferometer.

In particular, the fiber spectrally selective element may be a fiber birefringent spectral filter.

The technical result provided by the given set of features is the possibility of achieving an extremely short pulse duration of the output radiation of the fiber laser with the possibility of tuning the emission spectrum with a relatively low noise level of the laser radiation intensity and ensuring the stability of the obtained radiation parameters for unlimited time. The possibility of achieving an extremely short duration of output radiation pulses is provided by both the “mirrorless” design of the laser resonator (ring configuration), which does not limit the radiation spectrum for generating extremely short pulses, and by implementing the radiation mode synchronization mode using the Kerr effect (quadratic electro-optical effect ), providing relatively fast nonlinear response of the medium with a characteristic response time of the order of 10 ^-14 -10 ^-15 s. The Kerr effect leads to a change in the refractive index of the optical material in proportion to the square of the applied electric field, which, in the case of an axisymmetric Gaussian beam of radiation or the like, having a transverse distribution of radiation intensity, "falling down" to the edges of the beam, leads to the formation of the so-called Kerr lenses "- the distribution of the value of the refractive index acting on the beam of transmitted radiation as a lens. For most optical materials with Kerr nonlinearity (quartz, multicomponent glass of the TF class, sapphire, calcite and others), this lens is positive. The formation of a fast Kerr lens in the laser cavity allows you to create a resonator configuration in which a high-intensity laser pulse has low optical loss, and a long pulse or continuous radiation has large optical loss. The combined action of the Kerr lens in an optical element with Kerr nonlinearity and spatial mode filtering (when radiation is introduced into the fiber), corresponding to the emission of pulses with the highest peak power, leads to the selection of the generation mode of short radiation pulses with high peak power.

It should be noted that no single device taken gives the effect that gives a combination of the claimed features. Prior to filing this application, it was not obvious that the combination of the claimed features would solve the problem of creating a fiber pulsed ring laser with a passive radiation mode synchronizer that does not require the use of complex expensive technologies and materials for its manufacture, which has an unlimited service life and a relatively low noise level of laser radiation intensity, in this case, the laser spectrum is not limited to provide the generation of the shortest pulse durations and there is the possibility l spectral tuning of the emission line in a wide spectral range.

The invention is illustrated by the following schemes. In FIG. 1 shows a diagram of a fiber pulsed ring laser with passive synchronization of radiation modes: 1 — a pump radiation source, 2 — an amplifying fiber, 3 — a spectral information fiber module for introducing pump radiation into the resonator, 4 — a polarization-dependent coupler for outputting radiation from the resonator, 5 - fiber for output radiation output, 6 - polarization-dependent radiation insulator for unidirectional generation, 7 - first fiber end, 8 - first collimator, 9 - first optical focusing radiation optical element, 10 — an optical element with Kerr nonlinearity, 11 — a second radiation focusing optical element, 12 — a second collimator, 13 — a second fiber end, 14 — passages for laser radiation of the surface of an optical element with a Kerr nonlinearity, having an angle of inclination to the axis of the laser resonator not less than one degree.

In FIG. Figure 2 shows a diagram of a fiber pulsed ring laser with passive mode-locking, in which the Raman laser is the source of pump radiation from the fiber laser, and the Raman laser cavity is formed by two fiber Bragg gratings 17 having perpendicular to the beam or inclined lines and reflecting the radiation of the first Stokes component of the Raman laser .

In FIG. 3 is a diagram of a fiber pulsed ring laser with passive mode-locking, in which a three-port circulator 15 is located between the second fiber end 13 and the amplifying fiber 2, connecting the laser resonator with a spectrally selective reflective element 16.

In FIG. 4 is a schematic diagram of a fiber pulsed ring laser with passive mode locking in which the spectrally selective reflecting element 16 is a prism in combination with a reflecting mirror.

In FIG. 5 is a schematic diagram of a fiber pulsed ring laser with passive mode-locking, in which a fiber-optically selective element 18 is located between the second fiber end 13 and the amplification fiber 2.

The device operates as follows:

the pump radiation generated by the optical pump radiation source 1 through the fiber module 3 of the spectral information 3 enters the amplifying fiber 2, translating the amplifying medium of the laser into an active state; laser generation is carried out in a ring “mirrorless” resonator, the unidirectional generation mode in which is set by a polarization-dependent radiation isolator 6. The unidirectional radiation generation mode allows the laser radiation to be output in one direction through the coupler 4. In addition, the unidirectional traveling wave mode eliminates the effect " spatial burnout dips "inherent in linear lasers. The ends of the fibers 7 and 13 do not reflect the laser radiation back into the fiber due to the fact that they have either a cleaving angle of at least 8 degrees, or the end ends with fiber without a core (coreless fiber). The radiation exiting from the ends of the fiber is collimated by collimators 8 and 12. The radiation is focused on the optical element with Kerr nonlinear 10 by the optical elements 9 and 11 focusing the radiation. Both lenses and lenses can be used as collimators and optical radiation focusing elements. The use of a coupler 4 with polarization discrimination in combination with fiber elements of the resonator supporting polarization of the radiation allows the generation of linearly polarized radiation inside the laser cavity and eliminates the effect of nonlinear evolution of radiation polarization, which could occur if the laser generated non-polarized radiation. Polarization discrimination of radiation inside the laser cavity can be enhanced by a polarizer located in a collimated radiation beam between the collimator and the optical element focusing the radiation. Passing surfaces for laser radiation of the polarizer surface have an angle of inclination to the axis of the laser resonator of at least one degree in order to prevent possible spurious generation when the radiation is reflected from the passage surfaces for laser radiation of the polarizer. The elimination of the effect of nonlinear evolution of radiation polarization (spurious in this case) is necessary to realize radiation mode synchronization only based on the Kerr effect, which changes the refractive index of the optical material in proportion to the square of the applied electric field strength. Kerr effect provides a fast nonlinear response of the medium with a characteristic response time of the order of 10 ^-14 -10 ^-15 with that makes use of this effect to generate extremely short pulses of radiation, the duration of which can be only one period of the electromagnetic field oscillations. The Kerr lens can degrade or improve the tuning of the laser cavity by changing the focus of the radiation. For example, a change in the distance between the radiation focusing optical elements 9 and 11 leads to a mismatch of the optical system located between the ends of the fibers 7 and 13, and to an increase in optical radiation losses during the passage of the system, however, the action of the Kerr lens in the optical element 10 can restore the optical system setting. located between the ends of the fibers 7 and 13, and to reduce the optical radiation loss during the passage of the system. Accordingly, a short high-intensity laser pulse will have less optical loss in such a "detuned" optical system than a long pulse or continuous radiation. That is why in a laser with an initially slightly detuned optical system located between the ends of the fibers 7 and 13, the radiation mode synchronization mode due to the Kerr effect is preferable, since pulsed laser radiation in this mode has lower optical losses.

All reflective surfaces of the elements of the laser resonator should not reflect radiation back into the resonator, otherwise the radiation reflected from these surfaces can initiate spurious generation, which is unable to solve the problem of the claimed invention. The ends of the fibers 7 and 13 do not reflect the laser radiation back into the fiber due to the fact that they have either a cleaving angle of at least 8 degrees, or the end ends with fiber without a core (coreless fiber). The surfaces of an optical element with Kerr nonlinearity, which are passed through for laser radiation, have an angle of inclination to the axis of the laser cavity of at least one degree. To reduce the optical radiation loss during the passage of collimators focusing the radiation of optical elements, an optical element with Kerr nonlinearity, and a polarizer, their passages for laser radiation can have an antireflection coating.

The synchronization of radiation modes based on the Kerr lens compares favorably with the synchronization of modes based on saturable absorbers in that the Kerr lens has an unlimited service life, operates in a wide spectral range, the threshold for its use in terms of radiation power density is limited only by the threshold for the destruction of the material itself.

There are many optical materials that have Kerr nonlinearity and are transparent in a wide spectral range - quartz, multicomponent TF glasses, sapphire, calcite, and others. The Kerr lens can be formed in elements of these materials in a wide spectral range, which makes it possible to use such elements for lasers tunable by the radiation wavelength and for lasers with different radiation wavelengths. Since the Kerr effect is a nonlinear optical effect that causes changes in the refractive index of the optical material in proportion to the second degree of applied electric field strength, it manifests itself most strongly at a high radiation power density, which is ensured by the arrangement of the optical element with Kerr nonlinearity in the radiation focus. The sharp focusing of laser radiation with a relatively short-focus element with a focus of 30–50 mm makes it possible to form a noticeable Kerr lens in optical elements with Kerr nonlinearity with a thickness of more than 0.5 mm.

The claimed invention can be implemented using a wide range of reinforcing fibers - fibers doped with rare earth ions, such as erbium (Er ³⁺ ), neodymium (Nd ³⁺ ), ytterbium (Yb ³⁺ ), thulium (Tm ³⁺ ), holmium ( Ho ³⁺ ), bismuth (Bi ³⁺ ) and others, as well as Raman fibers.

When using a Raman laser as a fiber laser pump radiation source, the spectrum of the fiber laser gain band corresponds to either the spectrum of the first Stokes component of a Raman laser (without using additional Bragg gratings) or the spectrum of the second Stokes component of a Raman laser (when using two Bragg gratings that block radiation the first Stokes component), or the spectrum of the third Stokes component of a Raman laser (when using four Bragg solutions c, two of which are "locked" radiation of the first Stokes component of the Raman laser and the other two "lock" the radiation of the second Stokes component of the Raman laser). The described circuits correspond to a single-stage, two-stage, and three-stage Raman laser. The use of a Raman laser as a source of radiation from a fiber laser pump allows the generation of the inventive laser in the ultra-wide spectral range, including in those parts of the spectrum in which the fibers doped with rare-earth ions do not provide amplification.

The number of cascades of a Raman laser used as a fiber laser pump radiation source can be more than three, however, the conversion efficiency of the Raman laser radiation decreases with the number of stages, therefore, the pump wavelength of a Raman laser is usually chosen as close as possible to the required spectral range of generation in order to minimize the number of cascades of the Raman laser and provide greater efficiency of the laser system.

The possibility of using fibers doped with rare-earth ions as well as Raman fibers in combination with the possibility of smoothly tuning the emission spectrum and the Kerr “all-wave” element of radiation mode synchronization allows the generation of short pulses of the inventive laser in the ultra-wide spectral range corresponding to the intersection of the transparency regions used in a laser of optical materials.

For spectral tuning of a wide spectrum of laser radiation, spectrally selective reflecting elements can be used (Figs. 3 and 4), which are connected to the laser ring resonator using a three-port circulator 15. Through this circulator, both fiber and volume spectral selective reflective elements - prisms, diffraction gratings, etc.

For spectral tuning of a wide spectrum of laser radiation, pass-through fiber spectral-selective elements (Fig. 5) based on Fabry-Perot or Mach-Zehnder fiber interferometers or birefringent fiber spectral filters can also be used.

Claims (34)

1. A passive-mode fiber pulsed ring laser containing optically coupled pump radiation source, a fiber ring resonator containing amplifying fiber, at least one fiber spectral information module for introducing pump radiation into the amplifying fiber, at least one polarization-dependent coupler for outputting radiation from the resonator, a polarization-dependent radiation insulator to provide unidirectional generation, the first and second ends of the fiber, not reflecting from laser radiation back into the fiber, located between the first and second ends of the fiber, the first and second collimators, characterized in that all fiber elements of the resonator support polarization of radiation, between the first and second collimators there are two optical elements focusing the radiation, between which in the waist of the laser beam an optical element with a Kerr nonlinearity and a thickness of more than 0.5 mm is located with passable surfaces for laser radiation having an angle of inclination to the axis of the resonator EPA is not less than one degree. 2. The laser according to claim 1, characterized in that the surfaces of the collimators and optical elements focusing the radiation through the radiation for the laser have an antireflection coating. 3. The laser according to claim 1, characterized in that the surfaces of the optical element with Kerr nonlinearity, which are passed through for laser radiation, have an antireflection coating. 4. The laser according to claim 1, characterized in that the surfaces of the optical element with Kerr nonlinearity, which are passed through for laser radiation, are Brewster. 5. The laser according to claim 1, characterized in that in the collimated beam of radiation between the collimator and the focusing radiation optical element there is a polarizer with passable surfaces for laser radiation having an angle of inclination from the laser cavity axis of at least one degree. 6. The laser according to claim 5, characterized in that the surfaces of the polarizer passable for laser radiation have an antireflective coating. 7. The laser according to claim 1, characterized in that both the glass optical fiber and the glass optical fiber doped with rare earth elements or doped with germanium and phosphorus oxides, as well as a combination thereof, are used as the reinforcing fiber, while the oxide matrix may include compound of a chemical element Si, N, Ga, Al, Fe, F, Ti, B, Sn, Ba, Ta, Zr, Bi. 8. The laser according to claim 1, characterized in that the fiber laser pump is a Raman laser when using fiberglass doped with germanium and phosphorus oxides as an amplifying fiber, as well as a combination thereof, while the compound of the chemical element Si can enter the oxide matrix , N, Ga, Al, Fe, F, Ti, B, Sn, Ba, Ta, Zr, Bi, and the Raman laser cavity is formed by two fiber Bragg gratings having perpendicular to the beam or inclined lines and reflecting for the radiation of the first ksovoy components of the Raman laser. 9. The laser according to claim 8, characterized in that the Raman laser cavity is formed by four fiber Bragg gratings having perpendicular to the beam or inclined lines, two of which are reflective for the radiation of the first Stokes component of the Raman laser, and the other two are reflective for the radiation of the second Stokes components of a Raman laser. 10. A passive-mode fiber pulsed ring laser containing an optically coupled pump radiation source, a fiber ring resonator containing an amplification fiber, at least one fiber spectral information module for introducing pump radiation into the amplification fiber, at least one polarization-dependent coupler for outputting radiation from the resonator, a polarization-dependent radiation insulator to provide unidirectional generation, the first and second ends of the fiber, not reflecting and laser radiation back into the fiber, located between the first and second ends of the fiber, the first and second collimators, characterized in that all fiber elements of the resonator support polarization of radiation, between the first and second collimators there are two optical elements focusing the radiation, between which in the waist of the laser beam an optical element with a Kerr nonlinearity and a thickness of more than 0.5 mm is located with passable surfaces for laser radiation having an angle of inclination to the axis of the resonator a grain of at least one degree, between the second end of the fiber and the reinforcing fiber there is a three-port circulator connecting the laser resonator with a spectrally selective reflective element. 11. The laser according to claim 10, characterized in that the surfaces of the collimators and optical elements focusing the radiation through the radiation of the laser have an antireflection coating. 12. The laser according to claim 10, characterized in that the surfaces of the optical element with Kerr nonlinearity, which are passed through for laser radiation, have an antireflection coating. 13. The laser according to claim 10, characterized in that the surfaces of the optical element with Kerr nonlinearity, which are passed through for laser radiation, are Brewster. 14. The laser according to claim 10, characterized in that in the collimated beam of radiation between the collimator and the focusing radiation optical element there is a polarizer with passable surfaces for laser radiation having an angle of inclination from the laser cavity axis of at least one degree. 15. The laser according to claim 10, characterized in that the surfaces of the polarizer passable for laser radiation have an antireflection coating. 16. The laser according to claim 10, characterized in that both the glass optical fiber and the glass optical fiber doped with rare earth elements or doped with germanium and phosphorus oxides, as well as a combination thereof, are used as the reinforcing fiber, while the oxide matrix may include compound of a chemical element Si, N, Ga, Al, Fe, F, Ti, B, Sn, Ba, Ta, Zr, Bi. 17. The laser according to claim 10, characterized in that the Raman laser is the source of the laser pump radiation when using fiberglass doped with germanium and phosphorus oxides as an amplifying fiber, as well as their combination, while the compound of the chemical element Si can enter the oxide matrix , N, Ga, Al, Fe, F, Ti, B, Sn, Ba, Ta, Zr, Bi, and the Raman laser cavity is formed by two fiber Bragg gratings having perpendicular to the beam or inclined lines and reflecting the radiation of the first oksovoy components of the Raman laser. 18. The laser according to claim 17, characterized in that the Raman laser cavity is formed by four fiber Bragg gratings having perpendicular to the beam or inclined lines, two of which are reflective for the radiation of the first Stokes component of the Raman laser, and the other two are reflective for the radiation of the second Stokes components of a Raman laser. 19. The laser according to claim 10, characterized in that the spectrally selective reflective element is a fiber Bragg grating. 20. The laser according to claim 10, characterized in that the spectrally selective reflective element is a volume element connected to the laser cavity through the third collimator and the third fiber end, which is the fiber end of the bi-directional port of the three-port circulator and does not reflect the laser radiation back into the fiber. 21. The laser according to claim 20, characterized in that the spectrally selective reflective element is a bulk diffraction grating. 22. The laser according to claim 20, characterized in that the spectrally selective reflective element is a mirror with a given spectral reflection band. 23. The laser according to claim 20, characterized in that the spectrally selective reflective element is a prism in combination with a reflecting mirror or a Littrov prism with a reflective coating on the surface onto which the laser beam normally incident after refraction on the input Brewster surface of the prism. 24. Passive-mode fiber pulsed ring laser containing an optically coupled pump radiation source, a fiber ring resonator containing an amplification fiber, at least one fiber spectral information module for introducing pump radiation into the amplification fiber, at least one polarization-dependent coupler for outputting radiation from the resonator, a polarization-dependent radiation insulator to provide unidirectional generation, the first and second ends of the fiber, not reflecting and laser radiation back into the fiber, located between the first and second ends of the fiber, the first and second collimators, characterized in that all fiber elements of the resonator support polarization of radiation, between the first and second collimators there are two optical elements focusing the radiation, between which in the waist of the laser beam an optical element with a Kerr nonlinearity and a thickness of more than 0.5 mm is located with passable surfaces for laser radiation having an angle of inclination to the axis of the resonator a grain of not less than one degree, between the second end of the fiber and the reinforcing fiber is a fiber spectrally selective element. 25. The laser according to claim 24, characterized in that the surfaces of the collimators and optical elements focusing the radiation through the radiation of the laser have an antireflection coating. 26. The laser according to claim 24, characterized in that the surfaces of the optical element with Kerr non-linearity, passing through for laser radiation, have an antireflection coating. 27. The laser according to claim 24, characterized in that the surfaces of the optical element with Kerr nonlinearity, which are passed through for laser radiation, are Brewster. 28. The laser according to claim 24, characterized in that in the collimated radiation beam between the collimator and the focusing radiation optical element, there is a polarizer with surfaces that pass through for laser radiation, having an angle of inclination from the laser resonator axis of at least one degree. 29. The laser according to claim 24, characterized in that the surfaces of the polarizer passable for laser radiation have an antireflective coating. 30. The laser according to claim 24, characterized in that both the glass optical fiber and the glass optical fiber doped with rare earth elements or doped with germanium and phosphorus oxides, as well as a combination thereof, are used as the reinforcing fiber, while the oxide matrix may include compound of a chemical element Si, N, Ga, Al, Fe, F, Ti, B, Sn, Ba, Ta, Zr, Bi. 31. The laser according to claim 24, characterized in that the radiation source of the fiber laser pump is a Raman laser when using fiberglass doped with germanium oxides and phosphorus as an amplifying fiber, as well as a combination thereof, while the compound of the chemical element Si can enter the oxide matrix , N, Ga, Al, Fe, F, Ti, B, Sn, Ba, Ta, Zr, Bi, and the Raman laser cavity is formed by two fiber Bragg gratings having perpendicular to the beam or inclined lines and reflecting the radiation of the first oksovoy components of the Raman laser. 32. The laser according to claim 31, characterized in that the Raman laser resonator is formed by four fiber Bragg gratings having perpendicular to the beam or inclined lines, two of which are reflective for the radiation of the first Stokes component of the Raman laser, and the other two are reflective for the radiation of the second Stokes components of a Raman laser. 33. The laser according to claim 24, wherein the fiber spectrally selective element is a Fabry-Perot fiber interferometer or a Mach-Zehnder fiber interferometer. 34. The laser according to claim 24, wherein the fiber spectral selective element is a fiber birefringent spectral filter.

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