CN111552054A - Overall design and adjustment method of off-axis three-mirror optical system - Google Patents

Abstract

The invention provides a general design and adjustment method of an off-axis three-mirror optical system, belonging to the technical field of off-axis reflection imaging optical systems, wherein the off-axis three-mirror optical system comprises a primary mirror, a secondary mirror, a first reflector, a second reflector, a color separation sheet, a first plane mirror and a second plane mirror, the non-reflecting surfaces of the primary mirror, the secondary mirror, the first plane mirror and the second reflector are processed into polishing surfaces, the secondary mirror is arranged in a positioning frame of the secondary mirror, the other mirrors are arranged in respective positioning adjusting devices, the mounting surface of the positioning adjusting device of the primary mirror is selected as a reference plane, the relative height difference between the centers of the other mirrors and the reference plane and the positioning size of the center reference point of each mirror are determined, the positioning frame of the secondary mirror and the mounting surface and the positioning hole of the positioning adjusting device of the other mirrors are determined by processing, and then self-collimation is carried out by matching with an internal, the lens adjusting device has the advantages that real-time adjustment and accurate positioning of each lens are achieved, and the purposes of quickly adjusting, reducing adjusting difficulty and saving adjusting time are achieved.

Description

Overall design and adjustment method of off-axis three-mirror optical system

Technical Field

The invention belongs to the technical field of off-axis reflection imaging optical systems, and particularly relates to a general design and adjustment method of an off-axis three-mirror optical system.

Background

The off-axis three-mirror imaging optical system is an important component of a space remote sensing measurement system, but due to the characteristics that the off-axis three-mirror imaging optical system has high utilization rate of convex high-order aspheric lenses, each lens is relatively independent and has large span, and the adjustable freedom of each lens space is high, when the off-axis three-mirror imaging optical system is assembled and adjusted, the phenomena that the relatively accurate position of each lens is difficult to determine, the lens space posture is difficult to accurately adjust, the lens space posture is discontinuous, and the like occur.

Disclosure of Invention

In view of the above disadvantages, the present invention provides a method for designing an overall off-axis three-mirror optical system, which includes a primary mirror, a secondary mirror, a first mirror, a second mirror, a dichroic filter, a first plane mirror, and a second plane mirror, wherein non-reflective surfaces of the primary mirror, the secondary mirror, the first mirror, and the second mirror are processed into polished surfaces, the secondary mirror is placed in a positioning frame of the secondary mirror, the other lenses are arranged in respective positioning adjusting devices, the mounting surface of the positioning adjusting device of the main mirror is selected as a reference plane, determining the positions of the mounting surface of the positioning frame of the secondary mirror and the mounting surfaces of the positioning adjusting devices of the other lenses except the primary mirror according to the height difference between the mounting surface of the positioning frame of the secondary mirror and the mounting surfaces of the positioning adjusting devices of the other lenses except the primary mirror and the reference plane, and secondarily processing the mounting surface of the positioning frame of the secondary mirror and the mounting surfaces of the positioning adjusting devices of the other lenses to ensure the mounting accuracy; and taking the projection point of the intersection point of the reflection or transmission surface of each lens and the central line of the lens on the corresponding mounting surface as the center of the positioning hole of each lens, and secondarily machining the positioning frame mounting surface positioning hole of the secondary lens and the mounting surface positioning holes of the other lens positioning adjusting devices to ensure the positioning accuracy so as to mount the positioning frame of the secondary lens and the other lens positioning adjusting devices.

Preferably, the positioning and adjusting device comprises a mirror frame and a flange seat with a support, a first fine adjustment knob is arranged below the mirror frame, the mirror frame is suspended on the flange seat, the mirror frame can deflect within +/-3 degrees through the first fine adjustment knob, and the deflection axis of the mirror frame passes through the intersection point of the reflection or transmission surface of a lens in the mirror frame and the central line of the lens; the center of the bottom surface of the flange seat is provided with a positioning column, the side surface of the flange seat is provided with a fine adjustment mechanism consisting of a worm wheel and a worm, the flange seat can deflect within +/-3 degrees through a second fine adjustment knob at the end part of the worm, and the projection of the intersection point of the reflection or transmission surface of the lens in the lens frame and the central line of the lens on the bottom surface of the flange seat is superposed with the center of the bottom surface of the flange seat.

As another aspect of the present invention, the present invention provides an adjusting method of an off-axis three-mirror optical system, including the following steps:

step 1, determining a reference optical axis and theoretical positions of a primary mirror, a secondary mirror and a second reflecting mirror;

respectively placing a reference theodolite and an internal focusing telescope on two sides of a primary mirror and a secondary mirror for auto-collimation and cross-collimation, and ensuring that the optical axes of the reference theodolite and the internal focusing telescope are collinear and determined as a reference optical axis; keeping the states of the reference theodolite and the internal focusing telescope unchanged, respectively placing a positioning adjusting device of the primary mirror and a positioning frame of the secondary mirror, rotating and heightening the positioning frame of the secondary mirror to enable the reference theodolite to finish auto-collimation through the secondary mirror, adjusting the positioning adjusting device of the primary mirror to enable the internal focusing telescope to finish auto-collimation through the primary mirror, and realizing the coaxiality of the primary mirror and the secondary mirror, wherein the positions of the primary mirror and the secondary mirror are the theoretical positions of the primary mirror and the secondary mirror; a positioning adjusting device of a second reflector is arranged between the primary mirror and the inner focusing telescope, the pitching and azimuth angles of the inner focusing telescope are kept unchanged, the inner focusing telescope is translated by 1.4mm perpendicular to a reference optical axis, the positioning adjusting device of the second reflector is adjusted to enable the inner focusing telescope to finish auto-collimation, and at the moment, the position of the second reflector is the theoretical position of the second reflector, and meanwhile, the state of the reference theodolite is kept unchanged;

step 2, determining the theoretical position of the color separation sheet;

placing a first theodolite on one side of the reflecting surface of the color separation sheet, ensuring that the optical axis of the first theodolite is consistent with the optical axis height of the reference theodolite, respectively enabling the reference theodolite and the first theodolite to deflect by a certain angle and then perform auto-collimation and mutual collimation, recording the deflection angle α of the reference theodolite during mutual collimation, and enabling the first theodolite to deflect by the angle α again₁Wherein α₁Adjusting a positioning adjusting device of the color separation piece to change the position state of the color separation piece, enabling the first theodolite to finish auto-collimation through the color separation piece, enabling the position of the color separation piece to be the theoretical position of the color separation piece, and simultaneously restoring the reference theodolite to the state before deflection;

step 3, determining the theoretical position of the first reflector;

placing a second theodolite on one side of the non-reflecting surface of the first reflector, ensuring that the optical axis of the second theodolite is consistent with the optical axis height of the reference theodolite, respectively deflecting the reference theodolite and the second theodolite by a certain angle for auto-collimation and cross-collimation, recording the deflection angle β of the reference theodolite during cross-collimation, and enabling the second theodolite to deflect an angle β again₁Thereafter, β therein₁90- β, the light passing the optical axis of the second theodolite and the theoretical position of the first reflectorThe axes are overlapped; adjusting a positioning adjusting device of the first reflector to change the position state of the first reflector, so that the second theodolite performs auto-collimation through the first reflector, and the position of the first reflector at the moment is the theoretical position of the first reflector, and meanwhile, the reference theodolite is restored to the pre-deflection state;

step 4, determining the theoretical position of the first plane mirror;

respectively placing a third theodolite, a fourth theodolite and a fifth theodolite, ensuring that the optical axes of the third theodolite, the fourth theodolite and the fifth theodolite are all consistent with the optical axis height of the reference theodolite, arranging the third theodolite and the reference theodolite at the same side, arranging the fifth theodolite and the inner focusing telescope at the same side, positioning the fourth theodolite at one side of a non-reflecting surface of the first reflector, enabling the reference theodolite to rotate 90 degrees anticlockwise, enabling the third theodolite and the reference theodolite to rotate 90 degrees anticlockwise after self-collimation mutual collimation, then performing self-collimation mutual collimation with the fifth theodolite, enabling a horizontal light path formed by the third theodolite and the fifth theodolite to be parallel to the reference optical axis, and enabling the theoretical position of the first plane mirror to be in the horizontal light path; simultaneously restoring the reference theodolite to a pre-deflection state; respectively deflecting the fifth theodolite and the fourth theodolite by a certain angle, then carrying out auto-collimation cross-sight, recording the deflection angle gamma of the fifth theodolite during cross-sight, and then deflecting the angle gamma again by the fourth theodolite₁Wherein γ is₁The optical axis of the fourth theodolite is made to coincide with the optical axis of the theoretical position of the first plane mirror by 180-40.8-gamma; adjusting a positioning adjusting device of the first plane mirror to change the position state of the first plane mirror, so that the fourth theodolite completes auto-collimation, the position of the first plane mirror at the moment is the theoretical position of the first plane mirror, and meanwhile, the state of the fifth theodolite when the optical axis is parallel to the optical axis of the reference theodolite is recovered;

step 5, determining the theoretical position of the second plane mirror;

a sixth warp and weft instrument is arranged on one side of the reflecting surface of the second plane mirror, and the height of the optical axis of the sixth warp and weft instrument is ensured to be consistent with that of the optical axis of the reference theodolite; and rotating the fifth longitude and latitude instrument by 90 degrees anticlockwise, performing auto-collimation cross-aiming on the fifth longitude and latitude instrument and the sixth longitude and latitude instrument, deflecting the sixth longitude and latitude instrument by an angle again, wherein the angle is 180-38.88-90 degrees, enabling the optical axis of the sixth longitude and latitude instrument to be superposed with the optical axis of the theoretical position of the second plane mirror, adjusting a positioning adjusting device of the second plane mirror to change the position state of the second plane mirror, enabling the sixth longitude and latitude instrument to complete auto-collimation, and enabling the position of the second plane mirror at the moment to be the theoretical position of the second plane mirror.

The present invention also includes other devices, components or steps that enable the general design and setup of the off-axis three-mirror optical system to be used as is conventional in the art. In addition, means, components or steps that are not limited in this invention are taken to be conventional in the art.

The invention has the advantages that the micro adjustment of each lens in the off-axis three-mirror optical system is realized through the positioning adjusting device, and the adjusting difficulty is reduced; the precision of the mounting surface and the positioning hole of the positioning adjusting device is ensured through secondary processing, and the relative precise position of each lens is favorably determined; the lenses are placed in the positioning adjusting device, so that the multi-degree-of-freedom adjustment and positioning of the lenses in the space are realized, and the debugging of the off-axis three-mirror optical system is facilitated; the off-axis three-mirror optical system is simpler to adjust and more convenient to install and adjust.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic diagram of an optical system of the present invention;

FIG. 2 is a schematic diagram of the overall design structure of the present invention;

FIG. 3 is a schematic view of the structure of the mounting surface of the positioning adjustment device for all the lenses in the present invention;

FIG. 4 is a schematic view of a single positioning adjustment device of the present invention;

fig. 5 is a schematic view of the arrangement of the components in the adjustment method of the present invention.

Detailed Description

The present invention will be described more clearly with reference to the accompanying drawings, which are included to illustrate and not to limit the present invention. All other embodiments, which can be obtained by those skilled in the art without any inventive step based on the embodiments of the present invention, should be included in the scope of the present invention.

Example 1

As shown in fig. 1 to 4, the present invention provides a method for designing an overall off-axis three-mirror optical system, which includes a primary mirror 1, a secondary mirror 2, a first reflecting mirror 3, a second reflecting mirror 4, a dichroic filter 7, a first plane mirror 5 and a second plane mirror 6, wherein non-reflecting surfaces of the primary mirror 1, the secondary mirror 2, the first reflecting mirror 4 and the second reflecting mirror 4 are processed into polished surfaces, the secondary mirror 2 is placed in a positioning frame of the secondary mirror, so that the other lenses are placed in respective positioning adjustment devices, an installation surface of the positioning adjustment device of the primary mirror 1 is selected as a reference plane 13, and positions of an installation surface of the positioning frame of the secondary mirror 2 and installation surfaces 14 of the positioning adjustment devices of the other lenses except the primary mirror 1 are determined according to a height difference between the installation surface of the positioning frame of the secondary mirror 2 and the reference plane 13 and the installation surfaces 14 of the positioning adjustment devices of the other lenses except the primary mirror 1, the mounting surface of the positioning frame of the secondary mirror 2 and the mounting surfaces of the positioning adjusting devices of the other lenses are machined for the second time to ensure the mounting precision; and taking the projection point of the intersection point of the reflection or transmission surface of each lens and the central line of the lens on the corresponding mounting surface as the center of the positioning hole 8 of each lens, and secondarily processing the mounting surface positioning hole of the positioning frame of the secondary mirror 2 and the mounting surface positioning holes 8 of the other lens positioning adjusting devices to ensure the positioning precision so as to mount the positioning frame of the secondary mirror 2 and the other lens positioning adjusting devices.

The positioning adjusting device comprises a mirror frame 16 and a flange seat 18 with a support, a first fine adjustment knob 17 is arranged below the mirror frame 16, the mirror frame 16 is suspended on the flange seat 18, the mirror frame 16 can deflect within +/-3 degrees through the first fine adjustment knob 17, and the deflection axis of the deflection knob passes through the intersection point of the reflection or transmission surface of a lens in the mirror frame 16 and the central line of the lens; the center of the bottom surface of the flange seat 18 is provided with a positioning column 19, the side surface of the flange seat is provided with a fine adjustment mechanism consisting of a worm wheel 20 and a worm 22, the flange seat 18 can deflect within +/-3 degrees through a second fine adjustment knob 21 at the end part of the worm, and the projection of the intersection point of the reflection or transmission surface of the lens in the lens frame 16 and the central line of the lens on the bottom surface of the flange seat 18 is superposed with the center of the bottom surface of the flange seat 18.

Example 2

As shown in fig. 5, the present invention provides an adjusting method of an off-axis three-mirror optical system, comprising the following steps:

step 1, determining a reference optical axis and theoretical positions of a primary mirror 1, a secondary mirror 2 and a second reflecting mirror 4;

respectively placing a reference theodolite 23 and an internal focusing telescope 24 on two sides of a primary mirror 1 and a secondary mirror 2 for auto-collimation and cross-collimation, ensuring that the optical axes of the reference theodolite 23 and the internal focusing telescope 24 are collinear and determined as a reference optical axis; keeping the states of the reference theodolite 23 and the internal focusing telescope 24 unchanged, respectively placing a positioning adjusting device of the primary mirror 1 and a positioning frame of the secondary mirror 2, rotating and heightening the positioning frame of the secondary mirror 2 to enable the reference theodolite 23 to finish auto-collimation through the secondary mirror 2, adjusting the positioning adjusting device of the primary mirror 1 to enable the internal focusing telescope 24 to finish auto-collimation through the primary mirror 1, realizing the coaxiality of the primary mirror 1 and the secondary mirror 2, and enabling the positions of the primary mirror 1 and the secondary mirror 2 to be the theoretical positions of the primary mirror 1 and the secondary mirror 2 at the moment; a positioning adjusting device of the second reflecting mirror 4 is arranged between the main mirror 1 and the inner focusing telescope 24, the pitching and azimuth angles of the inner focusing telescope 24 are kept unchanged, the inner focusing telescope 24 is translated by 1.4mm in vertical reference optical axis (the distance is the designed distance between the reference optical axis in the optical path system and the horizontal optical path formed by the third theodolite 27 and the fifth theodolite 29 in the step 4), the positioning adjusting device of the second reflecting mirror 4 is adjusted to enable the inner focusing telescope 24 to finish self-collimation, and at the moment, the position of the second reflecting mirror 4 is the theoretical position of the second reflecting mirror 4, and meanwhile, the state of the reference theodolite 23 is kept unchanged;

step 2, determining the theoretical position of the color separation sheet 7;

one side of the reflecting surface of the color separation plate 7 is provided with a first theodolite 25, the optical axis of the first theodolite 25 is ensured to be consistent with the optical axis height of the reference theodolite 23, the reference theodolite 23 and the first theodolite 25 are enabled to deflect a certain angle and then to carry out auto-collimation mutual collimation, the deflection angle α of the reference theodolite 23 during mutual collimation is recorded, and the first theodolite is enabled to be25 angle α again₁Wherein α₁Adjusting a positioning adjusting device of the color separation sheet 7 to change the position state of the color separation sheet 7, so that the first theodolite 25 finishes self-collimation through the color separation sheet 7, the position of the color separation sheet 7 is the theoretical position of the color separation sheet 7, and the reference theodolite 23 is restored to the state before deflection at the same time;

step 3, determining the theoretical position of the first reflector 3;

a second theodolite 26 is arranged on one side of the non-reflecting surface of the first reflector 3, the optical axis of the second theodolite 26 is ensured to be consistent with the optical axis height of the reference theodolite 23, the reference theodolite 23 and the second theodolite 26 are respectively enabled to deflect for a certain angle for auto-collimation and cross-collimation, the deflection angle β of the reference theodolite 23 during cross-collimation is recorded, and the second theodolite 26 is enabled to deflect for a second time for an angle β₁Thereafter, β therein₁Adjusting the positioning adjusting device of the first reflector 3 to change the position state of the first reflector 3, so that the second theodolite 26 performs auto-collimation through the first reflector 3, and then the position of the first reflector 3 at the moment is the theoretical position of the first reflector 3, and simultaneously, the reference theodolite 23 is restored to the state before deflection;

step 4, determining the theoretical position of the first plane mirror 5;

a third theodolite 27, a fourth theodolite 28 and a fifth theodolite 29 are respectively placed, the optical axes of the third theodolite 27, the fourth theodolite 28 and the fifth theodolite 29 are all consistent with the optical axis height of the reference theodolite 23, the third theodolite 27 and the reference theodolite 23 are arranged at the same side, the fifth theodolite 29 and the inner focusing telescope 24 are arranged at the same side, the fourth theodolite 28 is positioned at one side of the non-reflecting surface of the first reflector 3, the reference theodolite 23 rotates 90 degrees anticlockwise, the third theodolite 27 and the reference theodolite 23 rotate 90 degrees anticlockwise after auto-collimation cross is carried out, then the third theodolite 27 and the fifth theodolite 29 carry out auto-collimation cross, then the horizontal light path formed by the third theodolite 27 and the fifth theodolite 29 is parallel to the reference optical axis, the theoretical position of the first plane mirror 5 is positioned at the reference opticalOn the horizontal light path; while restoring the reference theodolite 23 to a pre-deflection state; the fifth theodolite 29 and the fourth theodolite 28 are respectively deflected by a certain angle for auto-collimation crosshair, the deflection angle gamma of the fifth theodolite 29 during crosshair is recorded, and then the fourth theodolite 28 deflects the angle gamma again₁Wherein γ is₁180 ° -40.8 ° - γ, wherein 40.8 ° is a design value of an angle between the first plane mirror 5 and the reference optical axis, such that the optical axis of the fourth theodolite 28 coincides with the optical axis of the theoretical position of the first plane mirror 5; adjusting the positioning adjustment device of the first plane mirror 5 to change the position state of the first plane mirror 5, so that the fourth theodolite 28 completes auto-collimation, and then the position of the first plane mirror 5 at the moment is the theoretical position of the first plane mirror 5, and simultaneously, the state when the optical axis of the fifth theodolite 29 is parallel to the optical axis of the reference theodolite 23 is recovered;

step 5, determining the theoretical position of the second plane mirror 6;

a sixth theodolite 30 is arranged on one side of the reflecting surface of the second plane mirror 6, so that the height of the optical axis of the sixth theodolite 30 is consistent with that of the optical axis of the reference theodolite 23; and rotating the fifth theodolite 29 by 90 degrees counterclockwise, performing auto-collimation cross aiming on the fifth theodolite 29 and the sixth theodolite 30, deflecting the sixth theodolite 30 by an angle again, wherein the angle is 180-38.88-90 degrees, 38.88 degrees is a design value of an included angle between the second plane mirror 6 and a reference optical axis, enabling the optical axis of the sixth theodolite 30 to coincide with the optical axis of the theoretical position of the second plane mirror 6, adjusting a positioning adjusting device of the second plane mirror 6 to change the position state of the second plane mirror 6, enabling the sixth theodolite 30 to complete auto-collimation, and enabling the position of the second plane mirror 6 at the moment to be the theoretical position of the second plane mirror 6.

The invention realizes the micro adjustment of each lens in the off-axis three-mirror optical system through the positioning adjusting device, thereby reducing the adjusting difficulty; the precision of the mounting surface of the positioning adjusting device and the positioning hole 8 is ensured through secondary processing, and the relative position of each lens is favorably adjusted; the lenses are placed in the positioning adjusting device, so that the multi-degree-of-freedom adjustment and positioning of the lenses in the space are realized, and the debugging of the off-axis three-mirror optical system is facilitated; the off-axis three-mirror optical system is simpler to adjust and more convenient to install and adjust.

Having described embodiments of the present invention, the foregoing description is intended to be exemplary, not exhaustive, and not limited to the disclosed embodiments. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the illustrated embodiments.

Claims (3)

1. An overall design method of an off-axis three-mirror optical system is characterized by comprising the following steps: the off-axis three-reflection optical system comprises a primary mirror, a secondary mirror, a first reflecting mirror, a second reflecting mirror, a color separation sheet, a first plane mirror and a second plane mirror, wherein non-reflecting surfaces of the primary mirror, the secondary mirror, the first reflecting mirror and the second reflecting mirror are processed into polished surfaces, the secondary mirror is placed in a positioning frame of the secondary mirror, the other lenses are placed in respective positioning adjusting devices, the mounting surface of the positioning adjusting device of the primary mirror is selected as a reference plane, the positions of the mounting surface of the positioning frame of the secondary mirror and the mounting surfaces of the positioning adjusting devices of the other lenses except the primary mirror are determined according to the height difference between the mounting surface of the positioning frame of the secondary mirror and the reference plane, and the mounting surfaces of the positioning frame of the secondary mirror and the mounting surfaces of the positioning adjusting devices of the other lenses except the primary mirror are secondarily processed to ensure the mounting accuracy; and taking the projection point of the intersection point of the reflection or transmission surface of each lens and the central line of the lens on the corresponding mounting surface as the center of the positioning hole of each lens, and secondarily machining the mounting surface positioning hole of the positioning frame of the secondary lens and the mounting surface positioning holes of the other positioning adjusting devices of each lens to ensure the positioning accuracy so as to install the positioning frame of the secondary lens and the other positioning adjusting devices of each lens.

2. The method of claim 1 wherein the method comprises the steps of: the positioning and adjusting device comprises a picture frame and a flange seat with a support, a first fine adjustment knob is arranged below the picture frame, the picture frame is suspended on the flange seat, the picture frame can deflect within +/-3 degrees through the first fine adjustment knob, and the deflection axis of the picture frame passes through the intersection point of the reflection or transmission surface of a lens in the picture frame and the central line of the lens; the center of the bottom surface of the flange seat is provided with a positioning column, the side surface of the flange seat is provided with a fine adjustment mechanism consisting of a worm wheel and a worm, the flange seat can deflect within +/-3 degrees through a second fine adjustment knob at the end part of the worm, and the projection of the intersection point of the reflection or transmission surface of the lens in the lens frame and the central line of the lens on the bottom surface of the flange seat is superposed with the center of the bottom surface of the flange seat.

3. An adjustment method of an off-axis three-mirror optical system designed based on the overall design method of the off-axis three-mirror optical system as claimed in claim 1 or 2, comprising the steps of:

step 1, determining a reference optical axis and theoretical positions of a primary mirror, a secondary mirror and a second reflecting mirror;

respectively placing a reference theodolite and an internal focusing telescope on two sides of a primary mirror and a secondary mirror for auto-collimation and cross-collimation, and ensuring that the optical axes of the reference theodolite and the internal focusing telescope are collinear and determined as a reference optical axis; keeping the states of the reference theodolite and the internal focusing telescope unchanged, respectively placing a positioning adjusting device of the primary mirror and a positioning frame of the secondary mirror, rotating and heightening the positioning frame of the secondary mirror to enable the reference theodolite to finish auto-collimation through the secondary mirror, adjusting the positioning adjusting device of the primary mirror to enable the internal focusing telescope to finish auto-collimation through the primary mirror, and realizing the coaxiality of the primary mirror and the secondary mirror, wherein the positions of the primary mirror and the secondary mirror are the theoretical positions of the primary mirror and the secondary mirror; a positioning adjusting device of a second reflector is arranged between the primary mirror and the inner focusing telescope, the pitching and azimuth angles of the inner focusing telescope are kept unchanged, the inner focusing telescope is translated by 1.4mm perpendicular to a reference optical axis, the positioning adjusting device of the second reflector is adjusted to enable the inner focusing telescope to finish auto-collimation, and at the moment, the position of the second reflector is the theoretical position of the second reflector, and meanwhile, the state of the reference theodolite is kept unchanged;

step 2, determining the theoretical position of the color separation sheet;

placing a first theodolite on one side of the reflecting surface of the color separation sheet, ensuring that the optical axis of the first theodolite is consistent with the optical axis height of the reference theodolite, respectively enabling the reference theodolite and the first theodolite to deflect for a certain angle and then performing auto-collimation and mutual collimation, recording the deflection angle α of the reference theodolite during mutual collimation, and enabling the first theodolite to be used for re-collimation againDeflection angle α₁Wherein α₁Adjusting a positioning adjusting device of the color separation piece to change the position state of the color separation piece, enabling the first theodolite to finish auto-collimation through the color separation piece, enabling the position of the color separation piece to be the theoretical position of the color separation piece, and simultaneously restoring the reference theodolite to the state before deflection;

step 3, determining the theoretical position of the first reflector;

placing a second theodolite on one side of the non-reflecting surface of the first reflector, ensuring that the optical axis of the second theodolite is consistent with the optical axis height of the reference theodolite, respectively deflecting the reference theodolite and the second theodolite by a certain angle for auto-collimation and cross-collimation, recording the deflection angle β of the reference theodolite during cross-collimation, and enabling the second theodolite to deflect an angle β again₁Thereafter, β therein₁Adjusting a positioning adjusting device of the first reflector to change the position state of the first reflector, so that the second theodolite performs auto-collimation through the first reflector, the position of the first reflector is the theoretical position of the first reflector, and the reference theodolite is restored to the state before deflection;

step 4, determining the theoretical position of the first plane mirror;

respectively placing a third theodolite, a fourth theodolite and a fifth theodolite, ensuring that the optical axes of the third theodolite, the fourth theodolite and the fifth theodolite are all consistent with the optical axis height of the reference theodolite, arranging the third theodolite and the reference theodolite at the same side, arranging the fifth theodolite and the inner focusing telescope at the same side, positioning the fourth theodolite at one side of a non-reflecting surface of the first reflector, enabling the reference theodolite to rotate 90 degrees anticlockwise, enabling the third theodolite and the reference theodolite to rotate 90 degrees anticlockwise after self-collimation mutual collimation, then performing self-collimation mutual collimation with the fifth theodolite, enabling a horizontal light path formed by the third theodolite and the fifth theodolite to be parallel to the reference optical axis, and enabling the theoretical position of the first plane mirror to be in the horizontal light path; simultaneously restoring the reference theodolite to a pre-deflection state; respectively make the fifth warp and weft instrument,The fourth theodolite deflects for a certain angle and then carries out auto-collimation cross-sight, the deflection angle gamma of the fifth theodolite during cross-sight is recorded, and then the fourth theodolite deflects for the second time₁Wherein γ is₁The optical axis of the fourth theodolite is made to coincide with the optical axis of the theoretical position of the first plane mirror by 180-40.8-gamma; adjusting a positioning adjusting device of the first plane mirror to change the position state of the first plane mirror, so that the fourth theodolite completes auto-collimation, the position of the first plane mirror at the moment is the theoretical position of the first plane mirror, and meanwhile, the state of the fifth theodolite when the optical axis is parallel to the optical axis of the reference theodolite is recovered;

step 5, determining the theoretical position of the second plane mirror;

a sixth warp and weft instrument is arranged on one side of the reflecting surface of the second plane mirror, and the height of the optical axis of the sixth warp and weft instrument is ensured to be consistent with that of the optical axis of the reference theodolite; and rotating the fifth longitude and latitude instrument by 90 degrees anticlockwise, performing auto-collimation cross-aiming on the fifth longitude and latitude instrument and the sixth longitude and latitude instrument, deflecting the sixth longitude and latitude instrument by an angle again, wherein the angle is 180-38.88-90 degrees, enabling the optical axis of the sixth longitude and latitude instrument to be superposed with the optical axis of the theoretical position of the second plane mirror, adjusting a positioning adjusting device of the second plane mirror to change the position state of the second plane mirror, enabling the sixth longitude and latitude instrument to complete auto-collimation, and enabling the position of the second plane mirror at the moment to be the theoretical position of the second plane mirror.

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