CN108709542A - Method for fast measuring, system based on coordinate transform and device - Google Patents
Method for fast measuring, system based on coordinate transform and device Download PDFInfo
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- CN108709542A CN108709542A CN201810683217.5A CN201810683217A CN108709542A CN 108709542 A CN108709542 A CN 108709542A CN 201810683217 A CN201810683217 A CN 201810683217A CN 108709542 A CN108709542 A CN 108709542A
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- laser
- laser beam
- measurer
- camera
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S7/00—Details of systems according to groups G01S13/00, G01S15/00, G01S17/00
- G01S7/48—Details of systems according to groups G01S13/00, G01S15/00, G01S17/00 of systems according to group G01S17/00
- G01S7/4804—Auxiliary means for detecting or identifying lidar signals or the like, e.g. laser illuminators
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01C—MEASURING DISTANCES, LEVELS OR BEARINGS; SURVEYING; NAVIGATION; GYROSCOPIC INSTRUMENTS; PHOTOGRAMMETRY OR VIDEOGRAMMETRY
- G01C15/00—Surveying instruments or accessories not provided for in groups G01C1/00 - G01C13/00
- G01C15/002—Active optical surveying means
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S17/00—Systems using the reflection or reradiation of electromagnetic waves other than radio waves, e.g. lidar systems
- G01S17/02—Systems using the reflection of electromagnetic waves other than radio waves
- G01S17/06—Systems determining position data of a target
- G01S17/42—Simultaneous measurement of distance and other co-ordinates
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- Engineering & Computer Science (AREA)
- General Physics & Mathematics (AREA)
- Radar, Positioning & Navigation (AREA)
- Remote Sensing (AREA)
- Computer Networks & Wireless Communication (AREA)
- Electromagnetism (AREA)
- Optics & Photonics (AREA)
- Length Measuring Devices By Optical Means (AREA)
Abstract
The present invention relates to fields of measurement more particularly to a kind of method for fast measuring, system and devices based on coordinate transform.If the optical axis of camera and the laser beam of laser measurer are coplanar and non-coaxial, acquisition determinand is located at the optical axis center point on the distance of the ranging on the laser beam of laser measurer and camera to the first spacing of the laser beam emitting point on laser measurer;Ranging distance and the first spacing are substituted into arctan function, angle number is calculated;Camera shooting head-turned angle is adjusted according to the angle number, the optical axis on camera is made to intersect on the test object with the laser beam on laser measurer.Under different ranges, the laser facula of laser measurer is in the center of the video pictures of camera always, in the case where laser facula can not be seen clearly, pass through video pictures centre-lock target measurement position, and then complete to measure, solve the problems, such as that light is strong, not can determine that laser drop point site apart from remote etc..
Description
This case is so that application No. is 201710353551.X, the applying date is on May 18th, 2017, entitled《Measurement side
Method, system and device》Patent application be female case divisional application.
Technical field
The present invention relates to fields of measurement more particularly to a kind of method for fast measuring, system and devices based on coordinate transform.
Background technology
It is that each department is concerned about and the work taken a lot of trouble that ground investigation, house, which are measured, and the data surveyed zhang are the protections as property right
Object has legal effect.According to traditional measurement means, artificial race point is needed, is measured using tape measure or steel tape, though
So it can also meet basic demand, however in terms of long range measurements, such as survey floor height and be not easy in the measurement for reaching place, it deposits
The problems such as efficiency is low, low precision, the time is long, implements to operate hardly possible.
With the development of new and high technology, there is laser range finder, the instrument is especially suitable in building structure complexity
High-rise, long range house measurement.The instrument is using easy (can non-cpntact measurement), and measurement data is accurate, and working efficiency improves,
The method that a traditional root skin ruler (or steel tape) measures house has been abandoned completely, a zhang error is surveyed in reduction, and the amount of ensure that calculates precision,
Amount is calculated result and is more convinced.But current laser range finder, which still has, needs the aspect that improves, and such as light is too bright indoors, room
Outer sunlight leads to not see the laser point that laser range finder is sent out clearly, also can not will just swash too by force or in the case of long range
Luminous point is accurately positioned onto target object, at this time need to be by auxiliary appliances such as telescopes.
Invention content
The technical problem to be solved by the present invention is to:It is precisely right to provide one kind realization in the case where measuring environment is bad
The measurement method based on coordinate transform, system and device burnt, accurately measure.
In order to solve the above-mentioned technical problem, the first technical solution that the present invention uses for:
A kind of measurement method based on coordinate transform, including focusing step:
If the optical axis of camera and the laser beam of laser measurer are coplanar and non-coaxial, obtain determinand and be located at Laser Measuring
The optical axis center point in ranging distance and camera on the laser beam of measuring device is to the laser beam emitting point on laser measurer
The first spacing, the connecting line and laser of optical axis center point and the laser beam emitting point on laser measurer on the camera
The laser beam of measuring appliance is perpendicular;
Ranging distance and the first spacing are substituted into arctan function, angle number is calculated;
Camera shooting head-turned angle is adjusted according to the angle number, makes swashing on the optical axis and laser measurer on camera
Light beam intersects on the test object.
The second technical solution that the present invention uses for:
A kind of measuring system based on coordinate transform, including Focusing module;
The Focusing module includes first acquisition unit, the first computing unit and adjusting unit;
The first acquisition unit, if being coplanar and non-same for the optical axis of camera and the laser beam of laser measurer
Axis, acquisition determinand are located at the optical axis center point on the distance of the ranging on the laser beam of laser measurer and camera to laser
First spacing of the laser beam emitting point on measuring appliance, the laser on optical axis center point and laser measurer on the camera
The connecting line of beam launch point and the laser beam of laser measurer are perpendicular;
Angle is calculated for ranging distance and the first spacing to be substituted into arctan function in first computing unit
Number;
The adjusting unit makes the optical axis on camera for adjusting camera shooting head-turned angle according to the angle number
Intersect on the test object with the laser beam on laser measurer.
The third technical solution that the present invention uses for:
A kind of measuring device based on coordinate transform, including measurement end;The measurement end includes laser measurer, camera
And recliner;The connecting line and Laser Measuring of optical axis center point and the laser beam emitting point on laser measurer on the camera
The laser beam of measuring device is perpendicular;The recliner is connect with camera, and the angle for adjusting camera makes the light on camera
Axis intersects on the test object with the laser beam on laser measurer.
The beneficial effects of the present invention are:
Measurement method, system and device provided by the invention based on coordinate transform, by establishing the optical axis of camera, swashing
It is several between the first spacing between the laser beam of flash ranging measuring device and the optical axis center of camera and the laser beam of laser measurer
What angular relationship is calculated and both is located at the optical axis of camera with the laser beam of laser measurer when intersecting in object to be measured
The angle number of degrees, and camera shooting head-turned angle is adjusted according to the angle number of degrees, realize precisely focusing, under different ranges,
The laser facula of laser measurer is in the center of the video pictures of camera always, the case where can not see laser facula clearly
Under, it by video pictures centre-lock target measurement position, and then completes to measure, solving that light is strong, distance is remote etc. cannot be true
The problem of determining laser drop point site.
Description of the drawings
Fig. 1 is the focusing flow chart of steps of the measurement method based on coordinate transform of the present invention;
Fig. 2 is the measuring process flow chart of the measurement method based on coordinate transform of the present invention;
Fig. 3 is the coordinate transform schematic diagram of the measurement method based on coordinate transform of the present invention;
Fig. 4 is the structural schematic diagram of the measuring system based on coordinate transform of the present invention;
Label declaration:
1, laser measurer;2, camera;3, recliner.
Specific implementation mode
To explain the technical content, the achieved purpose and the effect of the present invention in detail, below in conjunction with embodiment and coordinate attached
Figure is explained.
Please refer to Fig. 1, a kind of measurement method based on coordinate transform provided by the invention, including focusing step:
If the optical axis of camera and the laser beam of laser measurer are coplanar and non-coaxial, obtain determinand and be located at Laser Measuring
The optical axis center point on ranging distance L and camera on the laser beam of measuring device is to the laser beam emitting point on laser measurer
The first spacing H, the connecting line of the optical axis center point on the camera and the laser beam emitting point on laser measurer with swash
The laser beam of flash ranging measuring device is perpendicular;
Ranging distance and the first spacing are substituted into arctan function, angle number arctan (H/L) is calculated;
Camera shooting head-turned angle is adjusted according to the angle number, makes swashing on the optical axis and laser measurer on camera
Light beam intersects on the test object.
Measurement method provided by the invention based on coordinate transform, by establishing the optical axis of camera, laser measurer
Geometric angle relationship between the first spacing between the laser beam of the optical axis center and laser measurer of laser beam and camera,
It is calculated and the optical axis of camera both is located to when intersecting in object to be measured angle degree with the laser beam of laser measurer
Number, and camera shooting head-turned angle is adjusted according to the angle number of degrees, realize precisely focusing, under different ranges, laser measurer
Laser facula be in the center of video pictures of camera always and pass through video in the case where laser facula can not be seen clearly
Picture centre-lock target measurement position, and then complete to measure, it solves light and not can determine that laser drop point position by force, apart from remote etc.
The problem of setting.
If Fig. 2 and Fig. 3 further include further measuring process:
When the starting point of object to be measured is located at the optical axis center point of camera, the focusing step of first time is executed, makes to take the photograph
As the optical axis on head intersects with the laser beam on laser measurer in the starting point of object to be measured, the starting of object to be measured is obtained
First distance of the point to the laser beam emitting point on laser measurer;
Using the laser beam of laser measurer as Z coordinate axis, the first coordinate system of three dimensions is established, is obtained according to the first distance
To first coordinate value of the starting point under the first coordinate system of object to be measured;
In the present embodiment, pass through the laser facula of the video pictures centralized positioning laser measurer of camera to mesh to be measured
Target starting point P, using laser measurer as origin Ow, it is Z with laser beamwAxis establishes the first coordinate system of three dimensions XwYwZw, lead to
Cross laser measurer obtain starting point to laser measurer distanceLength Z1w, starting point P is obtained in the first coordinate
It is XwYwZwUnder coordinate be (0,0, Z1w), it is assumed that the terminating point Q of object to be measured is in the first coordinate system X at this timewYwZwUnder coordinate
For (X2w, Y2w, Z2w)。
When the terminating point of object to be measured is located at the optical axis center point of camera, secondary focusing step is executed, makes to take the photograph
As the optical axis on head intersects with the laser beam on laser measurer on the terminating point of object to be measured, the termination of object to be measured is obtained
Second distance of the point to the laser beam emitting point on laser measurer;
Using the laser beam of laser measurer as Z coordinate axis, the second coordinate system of three dimensions is established, is obtained according to second distance
To second coordinate value of the terminating point under the second coordinate system of object to be measured;
In the present embodiment, using the starting point of object to be measured as reference point, laser beam rotates vertical angle α, level angle β
The terminating point Q for reaching object to be measured afterwards, equally using laser measurer as origin Ow', it is Z with laser beamw' axis, establishes three dimensions
Second coordinate system Xw′Yw′Zw', pass through the distance of laser measurer acquisition terminating point to laser measurerLength Zrw,
Terminating point Q is obtained in the second coordinate system Xw′Yw′Zw' under coordinate be (0,0, Zrw)。
According to the transformational relation of the first coordinate system and the second coordinate system, by the terminating point of object to be measured under the second coordinate system
The second coordinate value be converted to the third coordinate value under the first coordinate system;Or according to the first coordinate system and the second coordinate system
First coordinate value of the starting point of object to be measured under the first coordinate system is converted under the second coordinate system by transformational relation
Three coordinate values;
In the present embodiment, from the first coordinate system XwYwZwTo the second coordinate system Xw′Yw′Zw', coordinate origin does not move
(i.e. OwWith Ow' overlap), it only carries out around x-axis and around the transformation of y-axis, so spatial point Q is in coordinate system XwYwZwWith coordinate system Xw′
Yw′Zw' between transformation meet following relationship:
Wherein, R (x, α) is around OwXwThe transformation matrix form of axis rotation alpha degree indicates that R (y, β) is around OwYwAxis rotation β degree
Transformation matrix form indicate.Due to α, β, ZrwFor known quantity, then spatial point Q can be calculated in the first coordinate system XwYwZwUnder
Coordinate (X2w, Y2w, Z2w);
According to the first coordinate value and third coordinate value under the first coordinate system, starting point and the end of object to be measured is calculated
The distance between stop.Or according to the second coordinate value and third coordinate value under the second coordinate system, object to be measured is calculated
Starting point and the distance between terminating point.
In the present embodiment, the distance L of 2 points of P, Q in space can be calculated according to formula;
Further, further include:
Operational order is received, respective operations are executed;The operational order includes focusing instruction and measurement instruction.
The present invention also provides a kind of measuring system based on coordinate transform, including Focusing module;The Focusing module packet
It includes first acquisition unit, the first computing unit and adjusts unit;
The first acquisition unit, if being coplanar and non-same for the optical axis of camera and the laser beam of laser measurer
Axis, acquisition determinand are located at the optical axis center point on the distance of the ranging on the laser beam of laser measurer and camera to laser
First spacing of the laser beam emitting point on measuring appliance, the laser on optical axis center point and laser measurer on the camera
The connecting line of beam launch point and the laser beam of laser measurer are perpendicular;
Angle is calculated for ranging distance and the first spacing to be substituted into arctan function in first computing unit
Number;
The adjusting unit makes the optical axis on camera for adjusting camera shooting head-turned angle according to the angle number
Intersect on the test object with the laser beam on laser measurer.
Measuring system provided by the invention based on coordinate transform, by establishing the optical axis of camera, laser measurer
Geometric angle relationship between the first spacing between the laser beam of the optical axis center and laser measurer of laser beam and camera,
It is calculated and the optical axis of camera both is located to when intersecting in object to be measured angle degree with the laser beam of laser measurer
Number, and camera shooting head-turned angle is adjusted according to the angle number of degrees, realize precisely focusing, under different ranges, laser measurer
Laser facula be in the center of video pictures of camera always and pass through video in the case where laser facula can not be seen clearly
Picture centre-lock target measurement position, and then complete to measure, it solves light and not can determine that laser drop point position by force, apart from remote etc.
The problem of setting.
Further, further include measurement module;The measurement module includes second acquisition unit, first establishing unit,
Three acquiring units, second establish unit, converting unit and the second computing unit;
The second acquisition unit, for when the starting point of object to be measured is located at the optical axis center point of camera, executing
The focusing step of first time, make the optical axis on camera with the laser beam on laser measurer the phase in the starting point of object to be measured
It hands over, obtains the first distance of the laser beam emitting point in the starting point to laser measurer of object to be measured;
The first establishing unit, for using the laser beam of laser measurer as Z coordinate axis, establishing the first of three dimensions
Coordinate system obtains first coordinate value of the starting point of object to be measured under the first coordinate system according to the first distance;
The third acquiring unit, for when the terminating point of object to be measured is located at the optical axis center point of camera, executing
Secondary focusing step, make the optical axis on camera with the laser beam on laser measurer the phase on the terminating point of object to be measured
It hands over, obtains the second distance of the laser beam emitting point on the terminating point to laser measurer of object to be measured;
Described second establishes unit, for using the laser beam of laser measurer as Z coordinate axis, establishing the second of three dimensions
Coordinate system obtains second coordinate value of the terminating point of object to be measured under the second coordinate system according to second distance;
The converting unit, for the transformational relation according to the first coordinate system and the second coordinate system, by the end of object to be measured
Second coordinate value of the stop under the second coordinate system is converted to the third coordinate value under the first coordinate system;
Second computing unit, for according to the first coordinate value and third coordinate value under the first coordinate system, calculating
To the distance between the starting point of object to be measured and terminating point.
Further, further include measurement module;The measurement module includes second acquisition unit, first establishing unit,
Three acquiring units, second establish unit, converting unit and the second computing unit;
The second acquisition unit, for when the starting point of object to be measured is located at the optical axis center point of camera, executing
The focusing step of first time, make the optical axis on camera with the laser beam on laser measurer the phase in the starting point of object to be measured
It hands over, obtains the first distance of the laser beam emitting point in the starting point to laser measurer of object to be measured;
The first establishing unit, for using the laser beam of laser measurer as Z coordinate axis, establishing the first of three dimensions
Coordinate system obtains first coordinate value of the starting point of object to be measured under the first coordinate system according to the first distance;
The third acquiring unit, for when the terminating point of object to be measured is located at the optical axis center point of camera, executing
Secondary focusing step, make the optical axis on camera with the laser beam on laser measurer the phase on the terminating point of object to be measured
It hands over, obtains the second distance of the laser beam emitting point on the terminating point to laser measurer of object to be measured;
Described second establishes unit, for using the laser beam of laser measurer as Z coordinate axis, establishing the second of three dimensions
Coordinate system obtains second coordinate value of the terminating point of object to be measured under the second coordinate system according to second distance;
The converting unit, for the transformational relation according to the first coordinate system and the second coordinate system, by rising for object to be measured
First coordinate value of the initial point under the first coordinate system is converted to the third coordinate value under the second coordinate system;
Second computing unit, for according to the second coordinate value and third coordinate value under the second coordinate system, calculating
To the distance between the starting point of object to be measured and terminating point.
Further, further include receiving module, for receiving operational order, execute respective operations;The operational order
Including focusing instruction and measurement instruction.
Such as Fig. 4, the present invention also provides a kind of measuring device based on coordinate transform, including measurement end;The measurement end
Including laser measurer 1, camera 2 and recliner 3;The laser on optical axis center point and laser measurer on the camera
The connecting line of beam launch point and the laser beam of laser measurer are perpendicular;The recliner is connect with camera, is taken the photograph for adjusting
As the angle of head, the optical axis on camera is made to intersect on the test object with the laser beam on laser measurer.Camera is adopted in real time
The image for collecting object to be measured and laser facula realizes the size of video pictures scaling adjustment acquisition image by focusing.
Recliner is connect with camera, the angle for adjusting camera, under different ranges the optical axis of camera with swash
The laser beam of flash ranging measuring device forms different geometric angle relationships so that the laser facula in target falls the optical axis in camera
On.Laser measurer ranging obtains the laser facula in target to the distance L of laser measurer, camera and laser measurer
Physics spacing is H, as long as the optical axis of recliner adjustment camera and the laser beam of laser measurer are at an angle of arctan (H/L),
Laser facula in target can be fallen on the optical axis of camera.After the completion of calibration, locked at a distance by video pictures center
Position is measured, video pictures center shows and visually aims at the bull's-eye, and carrys out secondary locking and measures position at a distance.
Further, the measurement end further includes processor, holder and the angular transducer being arranged on holder;It is described to take the photograph
As head, laser measurer and recliner are arranged on holder;The processor by communication bus or signal wire respectively with laser
Measuring appliance, camera, holder, recliner are connected with angular transducer;
In the present embodiment, holder drives laser measurer to be rotated with camera, and holder is detected by angular transducer
The angle of rotation.Processor by communication bus or signal wire respectively with laser measurer, camera, holder, recliner and angle
Spend sensor connection.Processor controls these interface units, for example, control holder is rotated, obtains angular transducer detection
Cloud platform rotation angle, control camera execute image scaling, control recliner adjustment camera angle, control laser measurement
Device, which executes, measures operation.
The measuring device based on coordinate transform further includes the terminal of server-side and at least more than one;The server-side
It is connect respectively with measurement end and terminal by network.
In a specific embodiment, the present apparatus further includes server-side and terminal.Server-side is logical with measurement end and terminal respectively
Cross network connection.Server-side provides the communication interface between measurement end and terminal, and server-side, which receives to come from/send, goes to measurement end
Or the electric signal of terminal.Terminal shows visual output, including the text message of video pictures, measurement process/result, figure to user
Shape information and its arbitrary combination.Terminal receives the control input of user, sends control signal to measurement end, performance objective measures.
In conclusion measurement method, system and device provided by the invention based on coordinate transform, by establishing camera
Optical axis, between first between the laser beam of laser measurer and the optical axis center of camera and the laser beam of laser measurer
The geometric angle relationship away between is calculated the optical axis of camera and the laser beam of laser measurer being located at phase in object to be measured
The angle number of degrees both when friendship, and camera shooting head-turned angle is adjusted according to the angle number of degrees, precisely focusing is realized, in difference
Under range, the laser facula of laser measurer is in the center of the video pictures of camera always, can not see laser facula clearly
In the case of, it by video pictures centre-lock target measurement position, and then completes to measure, solves light is strong, distance is remote etc.
Not the problem of not can determine that laser drop point site.
Example the above is only the implementation of the present invention is not intended to limit the scope of the invention, every to utilize this hair
Equivalents made by bright specification and accompanying drawing content are applied directly or indirectly in relevant technical field, include similarly
In the scope of patent protection of the present invention.
Claims (6)
1. a kind of method for fast measuring based on coordinate transform, which is characterized in that including step of focusing:
If the optical axis of camera and the laser beam of laser measurer are coplanar and non-coaxial, obtain determinand and be located at laser measurer
Laser beam on ranging distance and optical axis center point on camera to the of the laser beam emitting point on laser measurer
One spacing, the connecting line and laser measurement of optical axis center point and the laser beam emitting point on laser measurer on the camera
The laser beam of device is perpendicular;
Ranging distance and the first spacing are substituted into arctan function, angle number is calculated;
Camera shooting head-turned angle is adjusted according to the angle number, makes the laser beam on the optical axis and laser measurer on camera
Intersect on the test object;
The method for fast measuring based on coordinate transform, further includes measuring process:
The focusing step for executing first time makes laser beam the rising in object to be measured on the optical axis and laser measurer on camera
Intersect on initial point, obtains the first distance of the laser beam emitting point in the starting point to laser measurer of object to be measured;
Using the laser beam of laser measurer as reference axis, the first coordinate system of three dimensions is established, is waited for according to the first distance
Survey first coordinate value of the starting point of target under the first coordinate system;
Secondary focusing step is executed, makes the laser beam on the optical axis and laser measurer on camera at the end of object to be measured
Intersect on stop, obtains the second distance of the laser beam emitting point on the terminating point to laser measurer of object to be measured;
Using the laser beam of laser measurer as reference axis, the second coordinate system of three dimensions is established, is waited for according to second distance
Survey second coordinate value of the terminating point of target under the second coordinate system;
According to the transformational relation of the first coordinate system and the second coordinate system, by the terminating point of object to be measured under the second coordinate system
Two coordinate values are converted to the third coordinate value under the first coordinate system;
According to the first coordinate value and third coordinate value under the first coordinate system, the starting point and terminating point of object to be measured is calculated
The distance between;
Alternatively, further including measuring process:
The focusing step for executing first time makes laser beam the rising in object to be measured on the optical axis and laser measurer on camera
Intersect on initial point, obtains the first distance of the laser beam emitting point in the starting point to laser measurer of object to be measured;
Using the laser beam of laser measurer as reference axis, the first coordinate system of three dimensions is established, is waited for according to the first distance
Survey first coordinate value of the starting point of target under the first coordinate system;
Secondary focusing step is executed, makes the laser beam on the optical axis and laser measurer on camera at the end of object to be measured
Intersect on stop, obtains the second distance of the laser beam emitting point on the terminating point to laser measurer of object to be measured;
Using the laser beam of laser measurer as reference axis, the second coordinate system of three dimensions is established, is waited for according to second distance
Survey second coordinate value of the terminating point of target under the second coordinate system;
According to the transformational relation of the first coordinate system and the second coordinate system, by the starting point of object to be measured under the first coordinate system
One coordinate value is converted to the third coordinate value under the second coordinate system;
According to the second coordinate value and third coordinate value under the second coordinate system, the starting point and terminating point of object to be measured is calculated
The distance between.
2. the method for fast measuring according to claim 1 based on coordinate transform, which is characterized in that further include:
Operational order is received, respective operations are executed;The operational order includes focusing instruction and measurement instruction.
3. a kind of Fast measurement system based on coordinate transform, which is characterized in that including Focusing module;The Focusing module includes
First acquisition unit, the first computing unit and adjusting unit;
The first acquisition unit obtains if being coplanar and non-coaxial for the optical axis of camera and the laser beam of laser measurer
Take optical axis center point in the ranging distance and camera that determinand is located on the laser beam of laser measurer to laser measurement
First spacing of the laser beam emitting point on device, the laser beam hair on the optical axis center point and laser measurer on the camera
The connecting line of exit point and the laser beam of laser measurer are perpendicular;
Angle number is calculated for ranging distance and the first spacing to be substituted into arctan function in first computing unit;
The adjusting unit, for adjusting camera shooting head-turned angle according to the angle number, making the optical axis on camera and swashing
Laser beam on flash ranging measuring device intersects on the test object;
The Fast measurement system based on coordinate transform, further includes measurement module;The measurement module includes that the second acquisition is single
Member, first establishing unit, third acquiring unit, second establish unit, converting unit and the second computing unit;
The second acquisition unit, the focusing step for executing first time, makes on the optical axis and laser measurer on camera
Laser beam intersect in the starting point of object to be measured, obtain in the starting point to laser measurer of object to be measured laser beam hair
First distance of exit point;
The first establishing unit, for using the laser beam of laser measurer as reference axis, establishing the first coordinate of three dimensions
System, first coordinate value of the starting point of object to be measured under the first coordinate system is obtained according to the first distance;
The third acquiring unit makes for executing secondary focusing step on the optical axis and laser measurer on camera
Laser beam intersect on the terminating point of object to be measured, obtain on the terminating point to laser measurer of object to be measured laser beam hair
The second distance of exit point;
Described second establishes unit, for using the laser beam of laser measurer as reference axis, establishing the second coordinate of three dimensions
System, second coordinate value of the terminating point of object to be measured under the second coordinate system is obtained according to second distance;
The converting unit, for the transformational relation according to the first coordinate system and the second coordinate system, by the terminating point of object to be measured
The second coordinate value under the second coordinate system is converted to the third coordinate value under the first coordinate system;
Second computing unit, for according to the first coordinate value and third coordinate value under the first coordinate system, being calculated and waiting for
Survey the distance between starting point and the terminating point of target;
Alternatively, further including measurement module;The measurement module includes second acquisition unit, first establishing unit, third acquisition list
Member, second establish unit, converting unit and the second computing unit;
The second acquisition unit, the focusing step for executing first time, makes on the optical axis and laser measurer on camera
Laser beam intersect in the starting point of object to be measured, obtain in the starting point to laser measurer of object to be measured laser beam hair
First distance of exit point;
The first establishing unit, for using the laser beam of laser measurer as reference axis, establishing the first coordinate of three dimensions
System, first coordinate value of the starting point of object to be measured under the first coordinate system is obtained according to the first distance;
The third acquiring unit makes for executing secondary focusing step on the optical axis and laser measurer on camera
Laser beam intersect on the terminating point of object to be measured, obtain on the terminating point to laser measurer of object to be measured laser beam hair
The second distance of exit point;
Described second establishes unit, for using the laser beam of laser measurer as reference axis, establishing the second coordinate of three dimensions
System, second coordinate value of the terminating point of object to be measured under the second coordinate system is obtained according to second distance;
The converting unit, for the transformational relation according to the first coordinate system and the second coordinate system, by the starting point of object to be measured
The first coordinate value under the first coordinate system is converted to the third coordinate value under the second coordinate system;
Second computing unit, for according to the second coordinate value and third coordinate value under the second coordinate system, being calculated and waiting for
Survey the distance between starting point and the terminating point of target.
4. the Fast measurement system according to claim 3 based on coordinate transform, which is characterized in that further include receiving mould
Block executes respective operations for receiving operational order;The operational order includes focusing instruction and measurement instruction.
5. a kind of rapid measurement device based on coordinate transform, which is characterized in that including measurement end;The measurement end includes laser
Measuring appliance, camera and recliner;Optical axis center point on the camera and the laser beam emitting point on laser measurer
The laser beam of connecting line and laser measurer is perpendicular;The recliner is connect with camera, the angle for adjusting camera,
The optical axis on camera is set to intersect on the test object with the laser beam on laser measurer;
The measurement end further includes processor, holder and the angular transducer being arranged on holder;The camera, laser measurement
Device and recliner are arranged on holder;The processor by communication bus or signal wire respectively with laser measurer, camera,
Holder, recliner are connected with angular transducer;
The processor is used to execute the focusing step of first time, makes the laser beam on the optical axis and laser measurer on camera
Intersect in the starting point of object to be measured, obtains of the laser beam emitting point in the starting point to laser measurer of object to be measured
One distance;Using the laser beam of laser measurer as reference axis, the first coordinate system of three dimensions is established, is obtained according to the first distance
First coordinate value of the starting point of object to be measured under the first coordinate system;
Secondary focusing step is executed, makes the laser beam on the optical axis and laser measurer on camera at the end of object to be measured
Intersect on stop, obtains the second distance of the laser beam emitting point on the terminating point to laser measurer of object to be measured;
Using the laser beam of laser measurer as reference axis, the second coordinate system of three dimensions is established, is waited for according to second distance
Survey second coordinate value of the terminating point of target under the second coordinate system;
According to the transformational relation of the first coordinate system and the second coordinate system, by the terminating point of object to be measured under the second coordinate system
Two coordinate values are converted to the third coordinate value under the first coordinate system;
According to the first coordinate value and third coordinate value under the first coordinate system, the starting point and terminating point of object to be measured is calculated
The distance between;
Alternatively, executing the focusing step of first time, make the laser beam on the optical axis and laser measurer on camera in mesh to be measured
Intersect in target starting point, obtains the first distance of the laser beam emitting point in the starting point to laser measurer of object to be measured;
Using the laser beam of laser measurer as reference axis, the first coordinate system of three dimensions is established, is waited for according to the first distance
Survey first coordinate value of the starting point of target under the first coordinate system;
Secondary focusing step is executed, makes the laser beam on the optical axis and laser measurer on camera at the end of object to be measured
Intersect on stop, obtains the second distance of the laser beam emitting point on the terminating point to laser measurer of object to be measured;
Using the laser beam of laser measurer as reference axis, the second coordinate system of three dimensions is established, is waited for according to second distance
Survey second coordinate value of the terminating point of target under the second coordinate system;
According to the transformational relation of the first coordinate system and the second coordinate system, by the starting point of object to be measured under the first coordinate system
One coordinate value is converted to the third coordinate value under the second coordinate system;
According to the second coordinate value and third coordinate value under the second coordinate system, the starting point and terminating point of object to be measured is calculated
The distance between;
Wherein, the focusing step includes:
If the optical axis of camera and the laser beam of laser measurer are coplanar and non-coaxial, obtain determinand and be located at laser measurer
Laser beam on ranging distance and optical axis center point on camera to the of the laser beam emitting point on laser measurer
One spacing, the connecting line and laser measurement of optical axis center point and the laser beam emitting point on laser measurer on the camera
The laser beam of device is perpendicular;
Ranging distance and the first spacing are substituted into arctan function, angle number is calculated;
Camera shooting head-turned angle is adjusted according to the angle number, makes the laser beam on the optical axis and laser measurer on camera
Intersect on the test object.
6. the rapid measurement device according to claim 5 based on coordinate transform, which is characterized in that described to be become based on coordinate
The rapid measurement device changed further includes the terminal of server-side and at least more than one;The server-side by network respectively with measurement
End is connected with terminal.
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