RU2487317C1 - Laser gyroscope resonator - Google Patents

Abstract

FIELD: measurement equipment.

SUBSTANCE: laser gyroscope resonator comprises a quadrangular contour from four channels arranged in an optical block. Ends of adjacent channels exit into one of four areas of the optical block, and in the place of arrangement of optical block areas there are reflectors installed. The second channel is connected with a hole designed for installation of the first anode, the fourth channel is connected with the hole, designed for installation of the second anode, in the optical block there is a hole for installation of the cathode. In each of the second and fourth channels of the resonator there are several bores arranged in series along the channel length and having cylindrical shape, and the diameter of each bore is more than the diameter of the channel.

EFFECT: increased stability of frequency of optical oscillations of a laser gyroscope resonator.

7 cl, 1 dwg

Description

The invention relates to the field of measuring equipment, and in particular to devices for measuring angular velocity made on ring lasers.

A known resonator of a laser gyroscope [1], containing three channels made in the optical unit, lying in different planes.

The closest in technical essence is the resonator of a laser gyroscope [2], containing a quadrangular contour from the first, second, third and fourth channels located one after the other, made in the optical unit and filled with a gas mixture, the first ends of the first and second channels extending into the first region optical block, the second end of the second channel and the first end of the third channel go to the second region of the optical block, the second end of the third channel and the first end of the fourth channel go to the third region optical unit, the second ends of the first and fourth channels go into the fourth region of the optical unit, a first reflector is installed at the location of the first region of the optical unit, a second reflector is installed at the location of the third region of the optical unit, and a third reflector and an optical are installed at the location of the second region of the optical unit a prism, at the location of the fourth region of the optical unit, a fourth reflector is installed, the second channel is connected to an opening designed to install connected to the first-anode high-voltage direct current (IWPT) power source, the fourth channel is connected to an opening intended for installing the second anode connected to the IWPT, an opening is made in the optical unit for installing a cathode connected to the IWPT with the possibility of transmitting potential to the first and fourth regions of the optical unit , second and fourth channels.

The disadvantage of such a resonator of a laser gyroscope is the prerequisite for the occurrence of stratum plasma oscillations in a laser gyroscope, which change the frequency of optical radiation.

The technical result of the invention is to increase the stability of the frequency of the optical oscillations of the resonator of a laser gyro.

This technical result is achieved in the resonator of the laser gyroscope, containing a quadrangular contour from the first, second, third and fourth channels located one after the other, made in the optical unit and filled with a gas mixture, the first ends of the first and second channels extending into the first region of the optical unit, the second the end of the second channel and the first end of the third channel go to the second region of the optical block, the second end of the third channel and the first end of the fourth channel go to the third region of the optical of the block, the second ends of the first and fourth channels extend into the fourth region of the optical block, the first reflector is installed at the location of the first region of the optical block, the second reflector is installed at the location of the third region of the optical block, and the third reflector and optical are installed at the location of the second region of the optical block prism, at the location of the fourth region of the optical unit, a fourth reflector is installed, the second channel is connected to the hole intended for installation is connected the first anode, the fourth channel is connected to the hole intended for installation of the second anode connected to the IWFTC, an opening is made in the optical unit for installing the cathode connected to the IWCP with the possibility of transmitting potential to the first and fourth regions of the optical unit , the second and fourth channels, in that in each of the second and fourth channels of the resonator are made several arranged in series along the length of the channel and having a cylindrical shape swelling, the diameter of each of which is larger than the diameter of the channel.

In the first particular case, in the second channel, the first groove is located from the first region of the optical block at a distance of up to three channel diameters, the last groove is located from the hole intended for installation of the first anode at a distance of up to three channel diameters, in the fourth channel, the first groove is located from the fourth region of the optical block at a distance of up to three channel diameters, the last groove is located from the hole intended for installation of the second anode at a distance of up to three channel diameters.

In the second particular case, the distance between the grooves is up to three channel diameters.

In the third particular case, the diameter of the groove is from 1.2 to 1.5 times the diameter of the channel.

In the fourth particular case, the length of the groove is up to two channel diameters.

In the fifth particular case, the diameters of the grooves in each of the channels are equal, as well as the length of the grooves in each of the channels.

In the sixth particular case in both resonator channels, the distances between the grooves, the diameters of the grooves, their length and the distance of the grooves from the nearest areas of the optical unit and from the holes for mounting the anodes are equal.

When performing in each of the second and fourth channels of the resonator several grooves arranged consecutively along the length of the channel and having a cylindrical shape, the diameter of each of which is larger than the channel diameter, the frequency of the optical oscillations of the resonator of the laser gyroscope is increased due to the elimination of areas of local increase in the electric potential, leading to striations in a column of electric discharge in a gaseous medium.

Figure 1 presents a General view of the resonator of a laser gyro.

The resonator of the laser gyroscope (Fig. 1) contains an optical unit 1, in which a quadrangular contour is made of first, second, third, third, fourth and fourth, 5 channels, one after the other, filled with a helium-neon gas mixture. The first ends of the first 2 and second 3 channels go into the first region 6 of the optical block 1, the second end of the first channel 2 and the first end of the third channel 4 go into the second region 7 of the optical block 1. The second end of the third channel 4 goes into the third region 8 of the optical block 1 and the first end of the fourth channel 5, the second ends of the first 2 and fourth 5 channels extend into the fourth region 9 of the optical block 1. At the location of the first region 6 of the optical block 1, the first reflector 10 is installed, the second reflector 11 is located at the location of the of the third region 8 of the optical block 1. At the location of the second region 7 of the optical block 1, a third reflector 12 and an optical prism 13 are installed. A fourth reflector 14 is installed in the fourth region 9 of the optical block 1. The second channel 3 is connected to an opening 15 for mounting connected to IVPTT of the first anode. The hole 16 connected to the fourth channel 5 is intended for installation of the second anode connected to the IVPTT. The hole 17 in the optical unit 1 for installing the cathode connected to the IWFTC is formed with an exit to the first channel 2, in order to provide the possibility of transmitting the potential to the first region 6 and the second channel 3, as well as to the fourth region 9 and the fourth channel 5. In the second channel 3 are formed grooves 18 ', 18 ″ ... 18 ⁽ⁿ⁾ , and in the fourth channel 5, grooves 19', 19 ″ ... 19 ⁽ⁿ⁾ having a cylindrical shape with a diameter d ₁ ranging from 1.2 to 1.5 diameters d ₂ channels . The grooves 18 ', 19' are respectively spaced from the entrances to the first region 6 of the optical block 1 and to the second region 7 of the optical block 1 at a distance l _{1 of} up to 3d ₂ . The grooves 18 ⁽ⁿ⁾ , 19 ⁽ⁿ⁾ are at a component l of up to 3d ₂ distance l ₂ from the holes 15 and 16, respectively. Each of the grooves 18 ', 18 ″ ... 18 ⁽ⁿ⁾ , 19', 19 ″ ... 19 ⁽ⁿ⁾ is separated from the neighboring groove at a distance l _{3 of} up to 3d ₂ . The length l _{4 of} each of the grooves 18 ', 18 ″ ... 18 ⁽ⁿ⁾ , 19', 19 ″ ... 19 ⁽ⁿ⁾ is up to 2d ₂ .

The resonator laser gyroscope (figure 1) works as follows. When optical oscillations are generated in the resonator due to inhomogeneity of the gaseous medium and technological errors in the resonator, plasma oscillations, called striations, occur, characterized by alternating light layers with dark gaps along the length of four to five channel diameters in the electric discharge column in the gas medium. Since the appearance of striations begins in the part of the second channel 3 facing the cathode in the region where the electric potential increases, in the presence of a groove 18 'in this region, due to a local increase in the plasma volume in the region of the groove 18', the electron concentration decreases. For this reason, the conditions for increasing the electric potential in the area of the groove 18 'are eliminated, which eliminates the prerequisites for the nucleation of striations. Thus, on the length of the second channel 3 from its entrance into the first region 6 of the optical unit 1 to the groove 18 ″ in the second channel 3, the formation of striations does not occur. Similarly, at the location of the 18 ″ groove, the place of a possible increase in the electric potential, due to a local increase in the plasma volume, the electron concentration decreases, which prevents the increase of the electric potential in the region of the 18 ″ groove and then to the next groove in the second channel 3. Now already on the length of the second channel 3 from its entrance into the first region 6 of the optical unit 1 to the next groove after the groove 18 ″ in the second channel 3 does not occur the formation of striations. If there are grooves 18 ', 18 ″ ... 18 ⁽ⁿ⁾ in the second channel 3 along its entire length, conditions for the formation of striations are not created. Similarly, conditions are not created for the formation of striations in the fourth channel 5, in which grooves 19 ', 19 ″ ... 19 ^{(n) are formed} .

The absence of striations in the electric discharge column in a gaseous medium in the second 3 and fourth 5 channels of the resonator of the laser gyroscope eliminates the process of the appearance of local inhomogeneities of the electric potential in the electric discharge column, causing instability of the frequency of optical oscillations. Thus, when the conditions for the formation of striations are removed, the stability of the frequency of optical oscillations in the cavity of the laser gyro increases.

Information sources

1. US patent No. 4627732, cl. G01C 19/64, NKI 356/350. Mode Discrimination Apparatus. 1986 year

2. RF patent No. 2364837 C1, cl. G01C 19/66. Laser gyroscope. 2008 year

Claims (7)

1. The resonator of the laser gyroscope, containing a quadrangular contour from one after the other of the first, second, third and fourth channels, made in the optical unit and filled with a gas mixture, the first ends of the first and second channels go into the first region of the optical unit, the second end of the second channel and the first end of the third channel goes into the second region of the optical block, the second end of the third channel and the first end of the fourth channel goes into the third region of the optical block, the second ends of the first and fourth the channels go into the fourth region of the optical block, the first reflector is installed at the location of the first region of the optical block, the second reflector is installed at the location of the third region of the optical block, the third reflector and the optical prism are installed at the location of the second region of the optical block, at the location of the fourth region of the optical unit, a fourth reflector is installed, the second channel is connected to an opening intended for installation of a high-voltage power supply connected to a source direct current (IWPT) of the first anode, the fourth channel is connected to the hole intended for installation of the second anode connected to the IWPT, an opening is made in the optical unit for installing the cathode connected to the IWP with the possibility of transmitting potential to the first and fourth regions of the optical unit, the second and fourth channels characterized in that in each of the second and fourth channels of the resonator, several grooves are arranged successively along the channel length and having a cylindrical shape, the diameter of each of which ryh more than the diameter of the channel. 2. The resonator of the laser gyroscope according to claim 1, characterized in that in the second channel, the first groove is located from the first region of the optical unit at a distance of up to three channel diameters, the last groove is located from the hole for installation of the first anode at a distance of up to three channel diameters, in the fourth channel, the first groove is located from the fourth region of the optical unit at a distance of up to three channel diameters, the last groove is located from the hole intended for installation of the second anode at a distance and up to three channel diameters. 3. The resonator of the laser gyroscope according to claim 1, characterized in that the distance between the grooves is up to three channel diameters. 4. The resonator of the laser gyroscope according to claim 2, characterized in that the diameter of the groove is from 1.2 to 1.5 of the diameter of the channel. 5. The resonator of the laser gyroscope according to claim 3, characterized in that the length of the groove is up to two channel diameters. 6. The resonator of the laser gyroscope according to claim 4, characterized in that the diameters of the grooves in each of the channels are equal, as well as the length of the grooves in each of the channels. 7. The resonator of the laser gyroscope according to claims 1 and 5, characterized in that the distances between the grooves, the diameters of the grooves, their length and the distance of the grooves from the nearest areas of the optical unit and from the holes for mounting the anodes are equal in both channels of the resonator.