RU60795U1 - TUNABLE LASER - Google Patents

Abstract

The utility model relates to laser technology and can be used in the development of tunable lasers.

The objective of the utility model is to create a wavelength tunable laser with an increased tuning range, radiation power, and a stable axis of the radiation pattern (ODN) that is resistant to mechanical and climatic influences.

The technical result is achieved by using the "O" th order of radiation of the diffraction grating, minimizing intracavity losses and ensuring a stable spatial position (ONE).

The laser contains a resonator located in the housing 1, including an active medium 2, an output mirror 5, a diffraction grating 4 and a dull mirror 3. The diffraction grating 4 is connected via an adjustment mechanism 7 to the free end of the movable arm 8, the second end of which is fixed by spherical bearings 9 in "-Shaped flange 10 and through a second alignment mechanism 11 is connected to the laser housing 1, and the free end of the movable arm 8 is kinematically connected with a micrometer screw 17. The output mirror 5 is located on the diffraction side nd lattice 4 and through the third adjustment mechanism 14 is connected to a bracket 13 which is rigidly connected to the free end of the movable arm 8, the plane reflection mirror 5 and the output of the diffraction grating 4 are directed towards each other and coincide with the axis of rotation of «O ₁ -O ₂ »Of the movable arm passing through the spherical supports 9, and opposite to the diffraction grating in the resonator there is a highly reflective (“ deaf ”) 3 laser mirror.

Description

The utility model relates to laser technology and can be used in the development of tunable wavelengths of lasers and spectrometric devices based on them.

A tunable laser is known that contains an active element with a Brewster window, an optical resonator including a spectrally selective element with the possibility of rotation or longitudinally angular movement, for laser reconstruction along the lines of the spectrum. (See PCT No. 86/04746, class H 01 S 3/1055, publ. 08/14/86)

Despite the high accuracy of tuning, the laser has such a drawback as the complexity of the tuning process associated with the use of a whole group of additional measuring instruments, comparison circuits, and signal processing.

Known tunable laser containing an active medium, a resonator including a spectrally selective element (diffraction grating), mounted with the possibility of changing the spatial - angular position and intracavity adjustable aperture diaphragm. The laser further comprises a profiled pusher kinematically connected to a spectrally selective element, and the diaphragm is equipped with a drive lever kinematically connected to the profiled pusher. (See Pat. RF No. 2046482, CL H 01 S 3/13, publ. 10/20/95)

The disadvantages of the laser include the following: during operation, the drive lever linearly moves (slides) to a considerable extent in a curly and / or straight groove. As a result of this, increased and uneven wear of the contacting surfaces occurs and the accuracy and reproducibility of the choice of wavelength during the tuning process deteriorates, and the reliability and stability of the tunable laser under mechanical and climatic conditions are reduced.

In addition, in the process of tuning according to wavelengths (a change in the spatial - angular position of a spectrally selective element), uncontrolled

and a nonmonotonic change in the frequency of the laser radiation, which prevents tuning to maximum radiation power.

Closest to the proposed utility model is a tunable laser containing a resonator located in the housing, including an active medium, an output mirror, and a spectrally selective element (diffraction grating) connected through the first alignment mechanism to the free end of the movable arm, the second end of which is fixed with spherical bearings in An “U” -shaped flange and through the second adjustment mechanism are connected to the laser housing, and the free end of the movable arm is kinematically connected with micrometric Kim screw. (See Pat. RF №2244368, class. N 01 S 3/1055, publ. 10.01.2005, the prototype)

The disadvantages of the prototype include the following: when the radiation is output through the output mirror, radiation of the "0" th order of the diffraction grating is not used, due to which a part of the radiation, which is a few percent, is lost, and an increase in intracavity losses leads to a decrease in the tuning range and the output radiation power .

The use of the "O" th order of radiation of the diffraction grating in the prototype is in principle impossible, due to a change in the angular position of the axis of the radiation pattern in the process of tuning and using an output mirror that does not have stable characteristics in a wide spectral range of tuning.

The objective of the utility model is to create a wavelength tunable laser with an increased tuning range, radiation power, and a stable axis of the radiation pattern (ODN) that is resistant to mechanical and climatic influences.

The technical result will be obtained through the use of the "O" th order of radiation of the diffraction grating, minimizing intracavity losses and ensuring a stable spatial position of the ODN.

The specified technical result in the implementation of the utility model is achieved by the fact that in a tunable laser containing a resonator located in the housing, including an active medium, an output mirror, a diffraction grating connected via an adjustment mechanism to the free end of the movable arm, the second end of which is fixed with spherical bearings in "P" -shaped flange and through the second adjustment mechanism is connected to the laser housing, and the free end of the movable arm is kinematically connected with a micrometer screw The output mirror is arranged in the cavity by the diffraction grating and through the third adjustment mechanism is connected to a bracket that is rigidly connected

with the free end of the movable arm, while the reflection planes of the output mirror and the diffraction grating are directed towards each other and the line of their intersection coincides with the axis of rotation of the movable arm passing through the spherical supports, and a highly reflective (“deaf”) laser mirror is located in the cavity opposite to the diffraction grating.

The placement of the output mirror on the bracket, and the diffraction grating on the free end of the movable arm, the rigid connection of the arm with the movable arm, the alignment of the reflection planes of the output mirror and the diffraction grating directed towards each other, until they intersect with the axis of rotation of the movable arm, provide reflection "O" - the order of radiation of the diffraction grating to the output mirror of the laser and the invariance of the spatial position of the ODN of the output radiation and the use of a highly reflective (“deaf”) mirror, located nnogo opposite to the diffraction grating in the cavity, eliminate the losses increase radiation power and range of adjustment.

The analysis of the prior art by the applicant, including a search by patent and scientific and technical sources of information and identification of sources containing information about analogues of the claimed utility model, allowed to establish that the applicant did not find an analogue characterized by features identical to all the essential features of the claimed utility model, and the definition from the list of identified analogues of the prototype, as the closest in the totality of the characteristics of the analogue, allowed to identify the set of essential in relation to claimed by the applicant the technical result of the distinguishing features in the claimed object set forth in the claims.

Therefore, the claimed utility model meets the requirement of "novelty" under current law.

Figure 1 shows a General view of the tunable laser.

Figure 2 presents a view of the movable lever fixed in the "P" -shaped flange.

Figure 3 shows the alignment mechanism.

The laser contains a resonator located in the housing 1, including an active medium 2, on one side of which a (“blank”) highly reflective mirror 3 is placed, and on the other, a spectrally selective element 4 (diffraction grating) and an output mirror mounted on the side of the diffraction grating 4 5. The diffraction grating 4, located in the frame 6, through the adjustment mechanism 7 is connected to the free end of the movable arm 8. The second end of the movable arm 8 is fixed

spherical bearings 9 in the "P" -shaped flange 10, which through the adjustment mechanism 11 and the supporting element 12 is connected to the laser housing 1. The movable lever 8 is rigidly connected with the bracket 13, with which through the adjustment mechanism 14 is connected, fixed in the frame 15, reflecting the output mirror 5, while the reflection plane of the output mirror 5 and the diffraction grating 4 are directed towards each other and coincide with the axis of rotation O ₁ - O ₂ (FIG. 2) of the movable arm 8 passing through the spherical bearings 9. The free end of the movable arm 8 is kinematically connected through the arm 16 with a micrometer screw 17, including the rod 18. All quotation mechanisms 7, 11, 14 are made similarly and contain wines t-rack 19 with a deformable neck 20 and three quotation screws 21 located at an angle of 120 ° relative to each other.

The tuning of the radiation wavelength is as follows:

The rotation of the micrometer screw 17 leads to the translational movement of the rod 18, which, in turn, causes the rotation of the kinematic coupling lever 16, the movable lever 8 and the bracket 13 rigidly connected to the latter, as well as the frames 5 attached to them with a diffraction grating 4 and the output mirror 5 in the frame 15. The lever 16 is in constant elastic contact engagement with the rod 18. The rotation of the movable lever 8 is relative to the axis O ₁ -O ₂ passing through the centers of the spherical bearings 9. Spherically e bearings 9 are fixed in a "P" -shaped flange 10, which is elastically - plastic through the adjustment mechanism 11 is connected to the bearing element 12 of the laser housing 1, which ensures alignment of the axis of rotation O ₁ -O ₂ using screws 21 relative to the axis of the resonator. The diffraction grating 4 is pre-aligned so that its strokes are strictly parallel to the axis of rotation of O ₁ -O ₂ . This condition is necessary and sufficient to exclude misalignment of the lines of the diffraction grating 4 relative to the optical axis of the resonator during the process of tuning according to wavelengths. As a result, the alignment of the “U” -shaped flange 10 (i.e., the axis of rotation O ₁ -O ₂ ) relative to the optical axis of the resonator provides the necessary alignment of the diffraction grating 4 and its preservation during rotation (i.e., tuning according to wavelengths).

The output mirror 5, which is rigidly connected with the movable lever 8, is mounted and pre-aligned in such a way that its working surface provides a mirror image of the "O" th radiation order of the diffraction grating 4, while the planes of the surfaces of the output mirror 5 and diffraction grating 4 pass through the axis of rotation O ₁ -O ₂ that provides a stable spatial position of the axis

radiation patterns during the adjustment according to wavelengths.

The output of the intracavity radiation of the tunable laser through the "O" diffraction order allows the use of a highly reflective mirror as an output element. As a result, intracavity losses are reduced, the tuning range and the radiation power increase. The refusal to use a partially transmitting mirror makes it possible to eliminate losses from absorption in the substrate material and to eliminate the influence of uneven spectral characteristics of its beam splitting coating.

The tunable laser provides high accuracy and reproducibility of the choice of the radiation wavelength due to the preservation of the alignment of the diffraction grating under conditions of mechanoclimatic effects. Separate and independent adjustment of the dispersion plane of the diffraction grating relative to the axis of rotation of the movable arm and the latter relative to the optical axis of the resonator is provided by separate adjustment mechanisms. In this case, the optical axis of the resonator and the axis of rotation of the movable arm are mutually perpendicular and do not lie in the same plane (i.e., spaced apart in space), the dispersion plane of the diffraction grating is strictly perpendicular to the axis of rotation of the movable arm, and the strokes, respectively, are strictly parallel to it.

The simultaneous and constant coincidence of reflective surfaces, rigidly interconnected between the diffraction grating and the output mirror, with a common axis of rotation of O ₁ -O ₂ , ensures the invariance of the spatial position of the ODN of the output radiation in the process of tuning according to wavelengths.

We give an example of a concrete implementation of a utility model.

A tunable LCD-5 WGT-M laser contains a discharge channel formed by ceramic plates and metal-dielectric electrodes. The active medium (a working mixture of CO ₂ : N ₂ : He: Xe gases) is excited by an RF capacitive discharge. In a resonator formed by a highly reflecting mirror with a reflection coefficient of ≥99% in the region of 9.2–10.8 μm and a threaded reflective diffraction grating with a constant of 150 pc / mm and a reflection coefficient of “1”, the order of ~ 95%, lasing occurs at a wavelength corresponding to the angle of autocollimation according to the Littrov scheme. The "O" order of the radiation of the diffraction grating is reflected by the output highly reflective mirror. By changing the angle of the diffraction grating, laser radiation of the required wavelength is achieved. Moreover, the value (indication) of the scale of the micrometer screw uniquely corresponds to a certain value of the wavelength (can be set in accordance with the calibration

table). The micrometer screw has a total stroke of 25 mm and, with an equivalent length of the transfer lever of ~ 90 mm, provides the necessary range of angular displacement of the diffraction grating (~ 13 ° -14 °) and, accordingly, adjustment of wavelengths (9.2-10.8 μm). The geometric dimensions of the discharge channel (2.2 × 2.2) provide a single-mode regime for generating laser radiation. The laser housing is made of a seamless "P" -shaped channel made of aluminum alloy type AD-31. The active element is made on the basis of a laser of the type LCD-10 WG with replacing the translucent resonator mirror with a “deaf” one and a “deaf” one with a Brewster communication window from ZnSe. The details of the wavelength adjustment unit are made of X18H10T stainless steel. The decorative parts of the laser housing are made of aluminum alloys of the AMg type. The laser can be cooled with running water, or with built-in fans (air).

Therefore, the claimed utility model meets the requirement of "industrial applicability" under applicable law.

Claims (1)

A tunable laser comprising a resonator located in the housing, including an active medium, an output mirror, a diffraction grating connected via an adjustment mechanism to the free end of the movable arm, the second end of which is fixed by spherical supports in a U-shaped flange and connected to the laser housing through a second adjustment mechanism, moreover, the free end of the movable lever is kinematically connected with a micrometer screw, characterized in that the output mirror is located on the side of the diffraction grating and through h the third adjustment mechanism is connected to the bracket, which is rigidly connected with the free end of the movable arm, while the reflection planes of the output mirror and the diffraction grating are directed towards each other and coincide with the axis of rotation of the movable arm passing through the spherical supports, and opposite to the diffraction grating in the resonator is located highly reflective ("dull") laser mirror.