RU2594950C1 - Method for determining error of geodetic instruments for irregularity of journals shape and side bending of telescope - Google Patents

Abstract

FIELD: surveying.

SUBSTANCE: method for determining error of geodetic devices for irregularity for journals shape and side bending of telescope includes fixing the reflecting mirror at an angle of 45° to axis of sight on the objective end of the test device telescope, arrangement the test device on the horizontal axis of telescope rotation. Reflecting mirror is oriented to deflect the axis of sight in direction, approximately parallel to the horizontal axis of the test device, and so that the mark image is in the field of view during telescope rotation around its axis. Then, the mirror is directed on the mark and its position relative to cross grid of the telescope are measured at different inclination distances of the telescope in reception at "circle left" and "circle right". Error is calculated according to obtained data.

EFFECT: technical result is decreased labor intensity, high reliability and accuracy of determining error of geodetic devices for irregularity for journals shape and side bending of telescope.

1 cl, 9 dwg

Description

The invention relates to the field of applied geodesy and is intended for use in determining the error in measuring horizontal angles for the irregular shape of the pins and lateral bending of the telescope with geodetic instruments (theodolites, tacheometers, etc.) used for geodetic works in industrial and civil engineering, creation of reference geodetic networks, in mine surveying and geodetic astronomy.

A known method for determining the error of geodetic instruments for the irregular shape of the pins proposed by A.A. Ilinich [V. Litvinov, V. Lobachev, N. N. Voronkov Geodetic instrumentation. - M .: Nedra, 1971. - 328 p. (P. 157-165)], including mounting on the objective end of the telescope of the geodetic instrument (theodolite) under study a mirror deflecting the sight axis by approximately 90 ° so that it is directed at the intersection of the horizontal and vertical axes of the other measuring theodolite with the telescope which is precisely directed through the mirror onto the grid of the studied theodolite’s threads at different zenith distances of its telescope, counted along the horizontal and vertical circles of the measuring theodolite and used about Accounts for calculation using the error formulas at different zenith distances.

This method has the following disadvantages:

- to implement the method, in addition to the instrument under study, one more (measuring) theodolite is required;

- the accuracy of the measuring theodolite should not be lower than the required accuracy of determining the error of the studied theodolite;

- when pointing with a measuring theodolite, both horizontal and vertical reference circles are used, the readings of which are then processed, although the purpose of the research is to determine the measurement error of only horizontal angles;

- additional readings on a vertical reading circle, having their own errors, reduce the accuracy of the study;

- the need for counting on both reference circles provides for measurements pointing at the middle of the grid of the studied theodolite immediately with both threads of the measuring theodolite, i.e. combination of images of the grid centers of both theodolites, despite the fact that both images are rotated relative to each other at different positions of the telescope along the height of the studied theodolite. Such guidance is significantly lower in accuracy compared to pointing to a point with only one thread - horizontal or vertical. As a result, we have another source of research error due to the reduced accuracy of guidance;

- additional readings on a vertical reading circle increase the volume and duration of research;

- the measurement processing technique is cumbersome and not intuitive.

There is a method of determining the error of geodetic instruments for the irregular shape of the pins and lateral bending of the telescope [Zhelko Ch.N. A method for determining corrections for the irregular shape of the trunnions of the horizontal axis and lateral bending of the telescope // News of universities. Geodesy and aerial photography. 1984. - No. 3. - S. 44-50 (prototype)], including fixing on the objective end of the telescope of the studied device a reflecting mirror at an angle of 45 ° to the sight axis, placing a brand with a luminous dot on the extension of the horizontal axis of rotation of the telescope of the studied device, the orientation of the reflecting mirror in this way so that it deflects the line of sight in a direction approximately parallel to the horizontal axis of the instrument under study and when the telescope rotates around its axis, the image of the luminous point does not leave the field of view, SIC at a luminous point and measuring its position relative to the crosshairs of the telescope grid at different zenith distance of the telescope in the reception at "circle left" and "right circle" and the calculation error of the formulas.

This method has the following disadvantages:

- the accuracy of determining the error is influenced by the error of pointing to the brand and the errors of the readings in a horizontal circle (or in the ocular micrometer), which reduces the accuracy of determining the error;

- for technical theodolites and theodolites of medium accuracy, it is impossible to obtain an accuracy of determining the error above the accuracy of its reading device, for example, for a theodolite of the T5 type, for which the standard error of measuring angles is 5 ″, the accuracy of determining the correction for incorrect trunnions and lateral bending of the pipe will also be close to 5";

- for optical theodolites, it is impossible to detect measurement errors during erroneous installation of the telescope in height.

The objective of the invention is to simplify, accelerate and improve the accuracy of determining the error of geodetic instruments for the irregular shape of the pins and lateral bending of the telescope.

The technical result of the invention is to reduce the complexity, cheaper, increase the reliability and accuracy of determining the error of geodetic instruments for the irregular shape of the pins and lateral bending of the telescope, as well as providing the possibility of using new and expired geodetic instruments in production that have errors higher than those allowed by their accuracy class .

The technical result is achieved by the fact that in the method for determining the error of geodetic instruments for the irregular shape of the pins and lateral bending of the telescope, which includes attaching a reflective mirror at an angle of 45 ° to the sight axis on the objective end of the telescope, placement of the target instrument mark with a luminous dot, the orientation of the reflecting mirror so that it deflects the line of sight in a direction approximately parallel m of the horizontal axis of the instrument under study, and when the telescope was rotated around its axis, the image of the luminous point did not go out of sight, pointing at the luminous point and measuring its position relative to the crosshair of the telescope grid at different zenith distances of the telescope in the reception with a “circle to the left” and "circle right" and the calculation of the error by the formulas, the reflecting mirror is fixed with the possibility of adjusting the angle of deviation of the sighting axis by 2-3 ° in horizontal and vertical planes, the stamp is made in the form a thin plate with two luminous points A and B with a diameter of 0.3-0.5 mm, located on the horizontal axis at a distance of 12-25 mm from each other, and set perpendicularly and coaxially to the axis of rotation of the telescope at a distance of 10-20 m from the studied of the device, at the ocular end of the telescope, a digital photorecorder is installed with the ability to cover the field of view of the telescope and digitally record the field of view of the telescope at different zenith distances in the reception, and for each digital photo image the coordinates of points A and B and randomly taken on the vertical filament of the grid above and below the crosshairs of the grid of points 1 and 2, the coefficients of the equations of two straight lines AB and 1-2 are calculated using the formulas

where a _AB , b _AB , a _1-2 and b _1-2 are the coefficients of the equations of two straight lines AB and 1-2 in the photo image;

x _A , y _A , x _B , y _B , x ₁ , y ₁ , x ₂ and y ₂ - the coordinates of the points A, B, 1 and 2 in the photo image in the rectangular right coordinate system,

and the coordinates of the point of intersection of straight lines A-B and 1-2 according to the formulas

and then determine the error for the irregular shape of the pins and lateral bending of the telescope for each of its zenith distances in the reception according to the formula

where α _z is the average angle between the middle of the segment AB and the vertical filament of the telescope grid in the images obtained at the same zenith distance z of the telescope in the reception, respectively, with the “left circle” and “right circle”, determined by the formula

α ₀ - average weighted horizontal angle for all zenith distances z _{i of the} telescope in the reception between the directions to the middle of the segment AB and the axis of rotation of the telescope, determined by the formula

n is the number of zenith distances z of the telescope in half reception (with a “circle left” or “circle right”);

i is the measurement number (zenith distance of the telescope) in the half-reception (i = 1, 2, ... n);

c is the distance between points A and B on the mark;

ρ ″ is the number of seconds in one radian, ρ ″ = 206265 ″;

D is the distance from the axis of the investigated geodetic instrument to the mark;

и

- расстояния от середины прямой линии A-B до точки пересечения прямых линий A-B и 1-2 на фотоизображениях, полученных при одинаковом зенитном расстоянии z зрительной трубы в приеме соответственно при "круге лево" (верхний индекс L) и "круге право" (верхний индекс R), определяемые по формуле

and

- the distance from the middle of the straight line AB to the intersection of the straight lines AB and 1-2 on the images obtained with the same zenith distance z of the telescope in the reception, respectively, with a “left circle” (upper index L) and a “right circle” (upper index R ) defined by the formula

и

- длины прямой линии A-B на фотоизображениях, полученных при одинаковом зенитном расстоянии z зрительной трубы в приеме соответственно при "круге лево" (верхний индекс L) и "круге право" (верхний индекс R), определяемые по формуле

and

- the lengths of the straight line AB in the images obtained with the same zenith distance z of the telescope in reception, respectively, with a “left circle” (upper index L) and a “right circle” (upper index R), determined by the formula

Formulas (4-6) provide for the compensation of the error for the possible multiscale photo images along two mutually perpendicular axes, when the circle is depicted on the photo images by an ellipse.

Fixing the reflecting mirror with the possibility of adjusting the angle of deviation of the sighting axis by 2-3 ° in the horizontal and vertical planes simplifies, shortens and increases the accuracy of bringing the sighting axis of the telescope of the surveyed geodetic instrument to the desired position.

The installation of a digital photorecorder at the ocular end of the telescope with the possibility of covering the field of view of the telescope allows you to make photo or video recording of the field of view of the telescope at its various zenith distances and makes it possible to take the coordinates of points A and B on photo images.

раз по сравнению с измерениями по одной точке.The implementation of the mark in the form of a rigid plate with two luminous points A and B with a diameter of 0.3-0.5 mm, located on the horizontal axis at a distance of 12-25 mm from each other: guarantees the preservation of the position of the mark relative to the survey instrument and two luminous points A and B on the mark relative to each other and the hit of these points in the field of view of the telescope when it is pointed at the mark; allows you to determine the scale of the images on the line AB; allows you to control the removal of coordinates of points A and B and the correct installation of the telescope of the surveyed geodetic instrument at the desired zenithal distance; improves the accuracy of determining its error in

times compared to single point measurements.

Setting the mark perpendicularly and coaxially to the axis of rotation of the telescope of the surveyed geodetic instrument at a distance of 10-20 m from the investigated instrument provides the opportunity to conduct surveys of geodetic instruments in a room that has small dimensions.

Digital photo-registration of the field of view of the telescope of the geodetic instrument under study simplifies and speeds up the measurement reception, increases the accuracy and reliability of the results of determining the error of geodetic instruments for irregular trunnions and lateral bending of the telescope, and makes it possible to automate the processing of the results of surveying surveying instruments.

The proposed formulas (1-8) provide the ability to calculate the error of geodetic instruments for the irregular shape of the pins and lateral bending of the telescope and the automation of these calculations.

Thus, the combination of these distinctive features provides a new positive effect and is the essence of the invention.

Explanations of the claimed method for determining the error of geodetic instruments for the irregular shape of the pins and lateral bending of the telescope and one of the design options for the device for implementing this method are schematically shown in the drawing, where:

FIG. 1 is a schematic diagram of a device for implementing a method for determining the error of geodetic instruments for irregular shape of pins and lateral bending of the telescope;

FIG. 2 is a general view of a special nozzle with a reflecting mirror and a device for adjusting the angle of deviation of the line of sight of the geodetic instruments in horizontal and vertical planes;

FIG. 3 is a view A of a device for adjusting the angle of deviation of the sighting axis in horizontal and vertical planes;

FIG. 4 - view B on the device adjusting the angle of deviation of the sighting axis in the horizontal and vertical planes;

FIG. 5 - brand appearance;

FIG. 6 - field of view of the telescope of geodetic instruments;

FIG. 7 is a photo image of the field of view of the telescope induced on the brand;

FIG. 8 is a graph of the error of the optical theodolite model 3T2KP head. No. 133362 for the irregular shape of the trunnions and lateral bending of the telescope at various zenith distances of the telescope in the reception;

FIG. 9 is a graph of the error of the total station model Leica TS 06 head. No. 1321778 for the irregular shape of the trunnions and lateral bending of the telescope at various zenith distances of the telescope in the reception.

A device for implementing the method for determining the error of geodetic instruments for the irregular shape of the pins and lateral bending of the telescope consists of a reflecting mirror 1, a digital photorecorder 2, grade 3 and the surveyed geodetic instrument 4.

Reflecting mirror 1 using a special nozzle 5 is mounted on the objective end 6 of the telescope 7 of the investigated geodetic instrument 4 with the possibility of adjusting the angle of deviation of the sighting axis 8 of the telescope by 2-3 ° in the horizontal and 2-3 ° in the vertical planes.

A digital photo recorder 2 is mounted on the ocular end 9 of the telescope 7 with the possibility of covering its field of view. Photorecorder 2 has photo and video recording modes.

The telescope 7 of the investigated geodetic instrument 4 has the ability to rotate relative to the axis of rotation 10 in the pins 11 and set at various zenith distances according to counts on the vertical reference circle 12 of the studied geodetic instrument 4.

Mark 3 is made in the form of a rigid plate with two luminous points A and B with a diameter of 0.3-0.5 mm, located on the horizontal axis at a distance of 12-25 mm from each other (or 2-4 ′ in an angular measure), and installed perpendicularly and coaxially to the axis of rotation 10 of the telescope 7 at a distance of D = 10-20 m from the survey instrument 4.

Luminous points A and B can be made, for example, in the form of two holes in the brand with a diameter of 0.3-0.5 mm, equipped with LEDs.

Mark 3 can be mounted, for example, on a tripod, a special bracket or on the wall of a building.

The ability to control the angle of deviation of the sighting axis 8 of the telescope 7 in the horizontal and vertical planes is provided by installing a reflective mirror 1 in the nozzle 5 with the possibility of rotation in horizontal and vertical planes.

The ability to rotate the reflecting mirror 1 in horizontal and vertical planes can be provided, for example, using a hinge device consisting of a rigid plate 13 having a spherical pin 14, and a spherical hub 15, fixedly mounted on the cover 16 of the nozzle 5. The plate 13 is fixed in the original the position of the micrometer screw 17 with a compression spring 18 placed on the vertical axis, and the micrometer screw 19 with a compression spring 20 placed on the horizontal axis of the plate 13. For the initial position of the plate 12 pr Niemann position parallel to the lid 16, which is installed at an angle of 45 ° to the nozzle axis 5. The reflecting mirror 1 is fixedly secured to plate 13.

At the ocular end 9 of the telescope 7 there is a crosshair of the grid 21 and a vertical thread 22.

To simplify the adjustment of the initial position of the surveyed geodetic instrument 4 and to control the position of the telescope 7, the vertical and horizontal axes and inclined lines are plotted on mark 3 with a step of 15 °, starting from an angle of 45 °.

The method for determining the error of geodetic instruments for the irregular shape of the pins and lateral bending of the telescope is as follows.

Mark 3 is installed perpendicularly and coaxially to the axis of rotation 10 of the telescope 7 at a distance of D = 10-20 m from the survey instrument 4.

At the objective end 6 of the telescope 7 of the surveyed geodetic instrument 4, a reflecting mirror 1 is mounted using a special nozzle 5 at an angle of approximately 45 ° to the sight axis.

Using micrometer screws 17 and 19, the position of the reflecting mirror 1 in the vertical and horizontal planes is adjusted so that the sight axis 8 of the telescope 7 passes approximately through the middle of the segment AB between the luminous points A and B of mark 3 with two horizontal positions of the telescope 7: "circle left" and "circle right." In this case, the position of the surveyed geodetic instrument 4 is taken as the “circle to the left” when the reference vertical circle 12 is located on the left relative to the eyepiece end 9 of the telescope 7, and for the “circle right” when the reference vertical circle 12 is located on the right relative to the eyepiece end 9 of the telescope 7 .

At the ocular end 9 of the telescope 7 of the investigated geodetic instrument 4, a digital photorecorder 2 is fixed with the possibility of covering the field of view of the telescope 7.

Then the telescope 7 of the surveyed geodetic instrument 4 is sequentially transferred to different zenith distances along its reference vertical circle 12 or along inclined lines on the mark 3 and using digital photorecorder 2, digital photo or video recording of the field of view of the telescope 7 is performed at all its zenith distances reception.

In this case, the whole range of zenith distances of the telescope 7, which is possible for observation, is taken as a “circle to the left” from the lowest to the highest position, then to the other side with a “circle to the right” from the highest to the lowest position.

In particular, if the vertical reading circle 12 of the survey instrument 4 is calibrated from 0 ° to 360 ° and the reading is 0 °, when the telescope 7 is directed to the zenith, then measurements can be taken at any intervals: in one direction in the range of readings 135 ° to 45 °, then to the other side in the range of readings from 315 ° to 225 °. For example, for an interval of 15 ° the telescope 7 is installed on samples 135 °, 120 °, 105 °, 90 °, 75 °, 60 °, 45 ° in one direction and 315 °, 300 °, 285 °, 270 °, 255 ° , 240 °, 225 ° - in the other direction.

According to the received digital photos:

- determine the coordinates of points A and B and randomly taken on the vertical thread 22 of the grid above and below the crosshairs of the grid 21 points 1 and 2. Coordinates x _A , y _A , x _B , y _B , x ₁ , y ₁ , x ₂ and y ₂ points A, B, 1 and 2 on the photo images are determined using any graphic editor in any rectangular right-handed coordinate system with arbitrary orientation, position of the origin and scale;

- calculate:

the coefficients a _AB , b _AB , a _1-2 and b _{1-2 of the} equations of two straight lines AB and 1-2 according to formulas (1) and (2);

the coordinates x ₀ and y _{0 of the} point of intersection of straight lines AB and 1-2 according to formulas (3);

и

прямой линии A-B на фотоизображениях, полученных при одинаковом зенитном расстоянии z зрительной трубы 7 в приеме соответственно при "круге лево" (верхний индекс L) и "круге право" (верхний индекс R), по формуле (8);lengths

and

a straight line AB in the images obtained at the same zenith distance z of the telescope 7 in the reception, respectively, with a “left circle” (upper index L) and a “right circle” (upper index R), according to formula (8);

и

от середины прямой линии A-B до точки пересечения прямых линий A-B и 1-2 на фотоизображениях, полученных при одинаковом зенитном расстоянии z зрительной трубы 7 в приеме соответственно при "круге лево" (верхний индекс L) и "круге право" (верхний индекс R), по формуле (7). При вычислении расстояний

и

знак после извлечения корня в формуле (7) принимают равным знаку, получаемому в скобках первого выражения формулы (7);distances

and

from the middle of the straight line AB to the intersection of the straight lines AB and 1-2 in the photographs obtained with the same zenith distance z of the telescope 7 in the reception, respectively, with a “circle left” (upper index L) and “circle right” (upper index R) , by the formula (7). When calculating distances

and

the sign after extracting the root in the formula (7) is taken equal to the sign obtained in brackets of the first expression of the formula (7);

the average angle α _z between the middle of the segment AB and the vertical filament of the grid 22 of the telescope 7 in the images obtained at the same zenith distance z of the telescope 7 in the reception, respectively, with the “left circle” and “right circle”, determined by the formula (5). When calculating the average angle α _z in the brackets of formula (5), the sign “+” is taken if the photo image is rotated 180 ° when transferring the telescope 7 through the zenith, or the “-” sign if the camera does not rotate the photo image by zenith 7 180 °;

the average weight horizontal angle α ₀ for all zenith distances z _{i of the} telescope 7 in the reception between the directions to the middle of the segment AB and the axis of rotation of the telescope 7 according to the formula (6);

the error Δ _{z of} the survey instrument 4 for the irregular shape of the pins 11 and lateral bending of the telescope 7 for each zenith distance z of the telescope 7 in the reception, respectively, with the "left circle" and "right circle", according to the formula (4).

To confirm the accuracy of the results obtained, the following measurement controls are performed:

- the lengths of the straight line A-B, calculated by the formula (8), for all guidance in the reception should not differ from each other by more than 2%;

- the difference between the zenith distances z of the telescope 7 established and calculated from the coordinates of points A, B, 1 and 2 according to formula (9) should not exceed 3 °.

The obtained error Δ _{z of the} surveyed instrument is shown on the graph of the error for the irregular shape of the trunnions and lateral bending of the telescope at various zenith distances z of the telescope and is taken into account in the measurement results of horizontal angles with this instrument and, thus, increase the accuracy of the results of measurements with geodetic instruments.

Experimental tests of the described invention, carried out on six electronic tacheometers and three optical theodolites, confirmed that it simplifies, accelerates and improves the accuracy of bringing the line of sight of the telescope of the surveyed geodetic instruments to the desired position, reduces the size of the space required for research of geodetic instruments, increases the reliability of the registration results field of view of the telescope at various zenith distances of the telescope, increases the reliability and accuracy of determining decisiveness of geodetic instruments for the irregular shape of the pins and lateral bending of the telescope, creates the conditions for automating the determination of the error of geodetic instruments and provides a certain practical and economic effect.

Claims (1)

A method for determining the error of geodetic instruments for the irregular shape of the pins and lateral bending of the telescope, which includes attaching a reflective mirror at an angle of 45 ° to the sight axis on the objective end of the telescope of the telescope, placing a mark with a luminous dot on the extension of the horizontal axis of rotation of the telescope of the studied instrument, orientation reflecting mirrors so that it deflects the line of sight in a direction approximately parallel to the horizontal axis of the instrument under study, and n When the telescope rotated around its axis, the image of the luminous point did not go out of sight, pointing at the luminous point and measuring its position relative to the crosshair of the telescope grid at different zenith distances of the telescope in the reception with a “left circle” and a “right circle” and error formulas, characterized in that the reflecting mirror is fixed with the possibility of adjusting the angle of deviation of the target axis by 2-3 ° in the horizontal and vertical planes, the mark is made in the form of a rigid plate with two points A and B with a diameter of 0.3-0.5 mm, located on the horizontal axis at a distance of 12-25 mm from each other, and set perpendicularly and coaxially to the axis of rotation of the telescope at a distance of 10-20 m from the studied device, on the ocular at the end of the telescope, a digital photorecorder is installed with the ability to cover the field of view of the telescope and digitally record the field of view of the telescope at all its zenith distances in reception, and for each digital photo image obtained, coordinates are determined points A and B and arbitrarily taken at a vertical filament mesh grid above and below the crosshair points 1 and 2, calculating the coefficients of the two straight lines A-B and 1-2 by the formulas

where a _AB , b _AB , a _1-2 and b _1-2 are the coefficients of the equations of two straight lines AB and 1-2 in the photo image;
x _A, x _B, y _A, y _B, x _1, x _2, y ₁ and y ₂ - coordinates of points A, B, 1 and 2 in a still image in the right rectangular coordinate system,
and the coordinates of the point of intersection of straight lines AB and 1-2 according to the formulas

and then determine the error for the irregular shape of the pins and lateral bending of the telescope for each of its zenith distances in the reception according to the formula
Δ _z = α _z -α ₀ ,
where α _z is the average angle between the middle of the segment AB and the vertical filament of the telescope grid in the images obtained at the same zenith distance z of the telescope in the reception, respectively, with the “left circle” and “right circle”, determined by the formula

α ₀ - average weighted horizontal angle for all zenith distances z _{i of the} telescope in the reception between the directions to the middle of the segment AB and the axis of rotation of the telescope, determined by the formula

n is the number of zenith distances z of the telescope in half reception with a “left circle” or a “right circle”;
i is the measurement number (zenith distance of the telescope) in the half-reception (i = 1, 2, ... n);
c is the distance between points A and B on the mark;
ρ ″ is the number of seconds in one radian, ρ ″ = 206265 ″;
D is the distance from the axis of the investigated geodetic instrument to the mark;

and

- the distance from the middle of the straight line AB to the intersection of the straight lines AB and 1-2 in the images obtained at the same zenith distance z of the telescope in the reception, respectively, with a “left circle” (upper index L) and a “right circle” (superscript R), determined by the formula

and

- the lengths of the straight line AB in photographic images obtained at the same zenith distance z of the telescope in reception, respectively, with a “left circle” (upper index L) and a “right circle” (upper index R), determined by the formula

Images