WO2010100043A1 - Geodätisches vermessungssystem und verfahren zum identifizieren einer zieleinheit mit einem geodätischen vermessungsgerät - Google Patents
Geodätisches vermessungssystem und verfahren zum identifizieren einer zieleinheit mit einem geodätischen vermessungsgerät Download PDFInfo
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- WO2010100043A1 WO2010100043A1 PCT/EP2010/052130 EP2010052130W WO2010100043A1 WO 2010100043 A1 WO2010100043 A1 WO 2010100043A1 EP 2010052130 W EP2010052130 W EP 2010052130W WO 2010100043 A1 WO2010100043 A1 WO 2010100043A1
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- surveying device
- identification code
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Classifications
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01C—MEASURING DISTANCES, LEVELS OR BEARINGS; SURVEYING; NAVIGATION; GYROSCOPIC INSTRUMENTS; PHOTOGRAMMETRY OR VIDEOGRAMMETRY
- G01C1/00—Measuring angles
- G01C1/02—Theodolites
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- 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
- 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
- G01C15/02—Means for marking measuring points
- G01C15/06—Surveyors' staffs; Movable markers
Definitions
- the invention relates to a geodetic surveying system comprising a geodetic surveying device and a target unit as one of a plurality of target objects as well as a method for identifying a target unit with a geodetic surveying device according to the preamble of claim 12.
- geodetic surveying equipment include the theodolite, tachymeter and total station, also referred to as an electronic tachymeter or computer tachymeter.
- a prior art geodetic measuring device is described, for example, in the publication EP 1 686 350. Such devices have electrosensitive angular and distance measuring functions which allow direction and distance determination to a selected target. The angle or distance variables are determined in the inner reference system of the device and may need to be linked to an external reference system for an absolute position determination.
- Many geodetic applications measure points by placing specially designed targets. These usually consist of a pole with a targetable marking or a reflector for defining the measuring section or the measuring point.
- a central geodetic surveying device By a central geodetic surveying device thus a larger number of target objects can be measured, but this requires their identification.
- a number of data, instructions, language and other information between target object, in particular a hand-held data acquisition device on the part of the target - and the central measuring device are transmitted to control the measurement process as well as for the determination or registration of measurement parameters. Examples of such data are the identification of the target object, tilt of the pole, height of the reflector above ground, reflector constants, or measurements such as temperature or air pressure.
- Modern total stations as geodetic surveying equipment also have microprocessors for digital further processing and storage of acquired measurement data.
- the devices generally have a compact and integrated design, with mostly coaxial distance measuring elements and computing, control and storage units are present in a device.
- Depending on the configuration of the total station can also be a motorization of Anzielg. Sighting device and means for automatic target search and tracking be integrated.
- tracking devices for geodetic devices for tracking a target used as a target are described in EP 0 465 584, JP 05322569, JP 07103761 and DE 195 28 465.
- Devices for automatic - especially coarse target search for example, use a vertically and / or horizontally fanned laser beam emitted by the geodetic device, such as theodolite. If, during the movement of the theodolite, the reflector arranged at the target station is struck around the standing or tilting axis and thus part of the laser beam is retroreflected, a signal is generated by a receiving photodiode arranged in the telescope of the theodolite, with the aid of which the telescope is then driven is stopped.
- the disadvantage here is that the system may react to all located in the field of view reflectors, such as other existing, but not interesting target units or Störreflektoren as reflective films, reflectors of vehicles, windows or similar objects.
- a continuation of the above target search device for coarse determination of the target coordinates is described in CH 676 041.
- a combination with an optoelectronic device for fine measurement takes place.
- the actual target search device spans two compartments which are perpendicular to one another and with which the position of the target point is measured two-dimensionally, the subsequent fine measurement with the second device can then be carried out without a target search process.
- the search is supported manually via voice or data radio.
- an additional optical receiver unit attached to the target object is used to check whether the search beam of the tachymeter hits the target object.
- the target object transmits a hit message to the tachymeter via data radio, whereupon the search is stopped and fine-tuning takes place.
- the tachymeter starts to turn in the opposite direction after receiving the first hit message.
- feedback is again sent to the tachymeter. Based on the time elapsed between the two hits in the tachymeter electronic unit, a position of the target object is determined.
- a prism device with an additional receiving device for the optical transmission from a geodetic measuring device to the prism device is shown in US Pat. No. 6,295,174.
- radiation is coupled out by an optical path from the region of the reflector and transmitted to a receiving surface of the axially parallel receiver.
- Two LEDs lit in different colors indicate the reception status.
- EP 1 734 336 discloses a surveying system having a target unit comprising a reflector and an optical receiver and transmitter. It is proposed to use the optical transmitter of the target unit among other things to support the automatic target search process.
- the target object after receiving the search or measuring radiation own identification, such as For example, the reflector number or the reflector type, transmit using the transmitter of the target unit back to the surveying station.
- the surveying station can thus identify the searched target object and optimally configure itself with respect to the target object.
- EP 1 573 271 discloses a target unit with optical transmitter, wherein - after receiving measuring radiation of a surveying device - the target unit sends back an optical signal to which the own identity of the target unit is modulated.
- a major disadvantage of the previously known devices is an insufficient robustness against a false identification of the target unit in the case of several target units located in the field of vision.
- the elaborate transfer of the destination unit identities from the respective destination units to the surveying equipment proves to be disadvantageous.
- the surveying station receives an identity from each of the destinations.
- a disadvantageously high data processing effort is required on the part of the surveying device in order to evaluate the multiplicity of replies of the respective destination units and to search for the actually sought To filter and identify the target unit from the answers of all target units.
- a search for a specific target unit is to be simplified and, nevertheless, made possible as robustly as possible against misidentification.
- a lesser amount of data processing is required for the surveying device to identify the target unit from the target object set.
- the invention is achieved by generic surveying systems with active target units of the prior art, in which always the target units located in the field of view each themselves transmit their own identity upon detection of a search beam of the surveying device in response back.
- an optical beam emitted, in particular for automatic target search Surveying device already modulated an identification code of the searched target object as code to be searched for.
- the target unit has a receiver for the beam and an evaluation component for checking whether the code modulated on the received beam coincides with the own identification code.
- the destination unit transmits such a suitable reactive confirmation signal to the surveying apparatus that the destination unit can be identified by the surveying apparatus on the basis of the confirmation signal, in particular depending on a reception time thereof.
- the destination unit transmits a response signal exclusively only in the case of a detected match.
- the confirmation signal e.g. is transmitted optically or by radio, can represent a standard signal, so this does not necessarily have to carry again the identity of the answering destination unit. Due to the already selective search can still be a clear identification of the target unit based on the confirmation signal.
- a fault-prone identification of a searched target unit by the geodetic device is made possible without the need for the surveying device to process the identities of several answering target units during a target search.
- the search is already selectively designed so that the surveying device receives only a corresponding response from the one or more target units actually sought.
- the processing effort on the part of the surveying device are considerably reduced in terms of the identities received by different target units, since according to the invention selectively only that target unit already responds to the particularly vertically fanned-out search beam of the surveying device which is searched for and whose position is to be measured.
- an automatic search process for finding a target unit to be measured by a surveying device it emits a search laser beam to which the ID of the searched target is already modulated as code to be searched for.
- the search laser beam can be emitted, for example, as a fanned-out laser beam (search subjects) and swiveled and / or tilted to scan a field of view region, in particular within a certain angular range.
- a vertical, horizontal or inclined fanning of the search beam may be provided, the search beam e.g. can be rotated about a standing axis of the surveying device or about a horizontal axis.
- the target unit has, for example, an all-round prism as a reflector and an optical receiver, in particular an omnidirectional receiver with an omnidirectional reception area. If, during a search process, the search compartments now hit the destination unit, this is detected by the receiver and an evaluation component of the destination unit compares the compartment-modulated code with its own ID. In the case of agreement, the target unit reactively transmits, in particular with known temporal response delay, an acknowledgment signal to the surveying device. The return transmission of the reactive acknowledgment signal by the destination unit in the case of the determined identity of the IDs can take place here
- the surveying device receives the match signal, stops the search, and travels back to the target azimuth angle with the "correct" searched ID, particularly considering the known time delay for generating and transmitting the match signal.
- the verification of the IDs and the generation and retransmission of the match signal by the destination unit may take place as quickly as possible - i. immediately after receipt and checking of the search beam - take place and the time required for this as a response delay are currently recorded.
- a time delay of zero can also be fictitiously assumed as the response delay.
- a defined response delay for the return transmission of the match signal can be fixed, so that the destination unit always transmits the acknowledgment signal exactly 0.05 seconds after the search fan has been received, if the match has been established. If, during the search process of the search compartments, additional target units which are positioned in the field of view of the surveying device arrive, then the target ID units also compare the modulated ID with their own ID. If the IDs do not match, either no response signal or a defined mismatch signal will be transmitted at all, and the surveying device's search operation will not be interrupted.
- a processing component of the surveying device can thus reliably identify the target unit sought.
- the ID sought may also be a beam emitted for electronic distance measurement, which may for example have a wavelength of 780 nm, or be modulated onto a beam emitted for automatic fine-tuning, which may for example have a wavelength of 780 nm.
- this can also ensure the identity of the destination unit based on the acknowledgment signal during an actual surveying operation.
- Suitable types of modulation for modulating the beam emitted by the surveying apparatus to code the identification code of the searched target object as code to be searched are known to the person skilled in the art. For example, a corresponding intensity modulation of the emitted beam can take place.
- a plurality of target objects of the target object quantity are designed as target units, which each have
- An evaluation component connected to the detector for checking whether the code modulated on the received beam matches the own identification code, and a transmitting component for transmitting a reactive confirmation signal to the geodetic surveying apparatus, if the evaluation component determines a match.
- FIG. 1 shows a geodetic surveying system according to the invention, wherein a confirmation signal is transmitted by radio from the destination unit to the surveying device;
- FIG. 2 shows a geodetic surveying system according to the invention, in which - due to a detected non-coincidence of the IDs - no response signal is transmitted from the target unit to the surveying device;
- FIG. 3 shows a geodetic surveying system according to the invention, wherein an acknowledgment signal with additional match information per
- FIG. 4 shows a geodetic surveying system according to the invention, wherein a response signal with non-coincidence information is transmitted by radio from the destination unit to the surveying device;
- FIG. 5 shows a geodetic surveying system according to the invention, wherein an optical signal as Confirmation signal is transmitted from the target unit to the surveying device;
- FIG. 6 shows a geodetic surveying system according to the invention, wherein both an optical signal and a radio signal are transmitted as confirmation signals from the destination unit to the surveying device;
- FIG. 8 shows a second example of an inventive automatic search and identification method in the context of a typical practical application in the field.
- FIG. 1 shows a geodetic surveying system 1 according to the invention with a geodetic surveying device 2 designed as a total station and a target unit 3, which represents one of several target objects of a target object set.
- a geodetic surveying device 2 designed as a total station
- a target unit 3 which represents one of several target objects of a target object set.
- the further target objects of the target object quantity, except the target unit 3 are not shown.
- the target objects each have a unique identification code, e.g. an ID number, assigned in such a way that the target objects can be distinguished from one another by means of the identification code.
- a unique identification code e.g. an ID number
- the surveying device 2 has a distance and angle measuring functionality for determining the position of the target objects and at least one - due to the perspective Representation in Figure 1 not directly apparent radiation source 21 for emitting an optical beam 22 in a defined spatial direction.
- the optical beam 22 is a vertically fanned laser beam of an automatic target search device of the surveying device 2, wherein the fan-shaped laser beam for scanning a field of view area about a vertical axis of the surveying device 2 is horizontally pivotable.
- the target unit 3 has a reflector 31, in particular an optical all-round retroreflector, and a detector 32 for receiving the optical beam 22.
- the reflector 31 and the detector 32 can be attached to a common surveying rod, in particular wherein the detector 32 is arranged above or below the reflector 31 at this subsequent.
- the detector 32 may also be integrated in the reflector 31, as is known from the prior art.
- the detector 32 is also designed as an all-round detector with a horizontal angle detection range of 360 °, for which purpose the detector 32 may, for example, have a multiplicity of detection elements arranged in a circle with radial orientation, such as CCD or CMOS sensor elements.
- the surveying device 2 is thus designed to emit the optical beam 22 in such a way that the
- Target object of the target object set is modulated as search code sID. This means that already the emitted search
- Subjects 22 carries a selective query, which is readable on the destination side.
- Figure 1 of the surveying device is the
- the destination unit 3 has an evaluation component connected to the detector 32.
- the evaluation component is designed to check whether the code sID modulated onto the beam 22 matches the own identification code ID4 of the destination unit 3.
- the target unit 3 transmits a reactive acknowledgment signal 35 to the surveying device 2.
- the target unit 3 has a transmitting component which is assigned to Transmission of such a confirmation signal 35 is formed. That is, in case of a detected coincidence of the IDs, the destination unit 3 sends the said confirmation signal 35 to the surveying apparatus 2 in response to the selective search request.
- the reactive confirmation signal 35 is transmitted from the target unit 3 to the surveying device 2 with a known time delay after the detection of the optical beam 22.
- the sending component of the destination unit may e.g. as a radio module for transmitting a radio signal as the reactive
- Confirmation signal 35 may be formed.
- the identification code ID4 read from the search box coincides with the own identity ID4 of the shown target unit 3, so that the target unit 3 becomes reactive on the selective query the corresponding confirmation signal 35 is transmitted by radio to the surveying device 2.
- the surveying device 2 receives the reactive acknowledgment signal 35 e.g. by means of a receiving unit, which is designed to expect the confirmation signal 35 within a predetermined time window during and / or after the emission of the beam 22, and can by means of a processing component 23, the desired target unit 3 from the target amount based on the confirmation signal 35, in particular depending on a reception time of the confirmation signal 35 identify.
- a receiving unit which is designed to expect the confirmation signal 35 within a predetermined time window during and / or after the emission of the beam 22, and can by means of a processing component 23, the desired target unit 3 from the target amount based on the confirmation signal 35, in particular depending on a reception time of the confirmation signal 35 identify.
- the surveying apparatus 2 is equipped with an automatic target search function and designed to detect portions of the fan-shaped search beam 22 respectively reflected at target objects of the target object quantity as reflections, wherein the reflections are assigned a measured angle and in particular a measured distance.
- the evaluation unit 23 can now assign the identification code ID4 of the destination unit 3, which represents the searched and also found target object, depending on the time of reception of the confirmation signal 35 - one of the detected reflexes and thus link the corresponding reflex with the identification code ID4.
- FIG. 2 illustrates an application example in which the target unit 3 shown does not represent the target object sought by the surveying device 2.
- the fan-shaped search beam 22 has an identification code ID2 different from the identification code ID4 of the shown target unit 3 modulated as the code sID to be searched.
- the search fan 22 hits the target unit 3 positioned in the field of vision of the surveying device 2, then the modulated code sID is compared with its own identification code ID4. Due to the mismatch of the IDs, no response signal is transmitted and the search operation of the surveying device 2 is not interrupted.
- the reflex detected in the course of the automatic target search which is generated by the search fan 22 when the destination unit 3 is scanned and registered by the surveying apparatus 2, can be identified on the part of the surveying apparatus 2, for example as an interference reflex or as a "non-searched" target object, or alternatively Likewise, further reflexes can be handled by further "unsearched" target objects for which the surveying device 2 does not receive a reactive acknowledgment signal and thus obviously not the actual target object.
- FIG. 3 shows a further example of application, wherein - as in FIG. 1 - the depicted target unit 3 again represents the target object sought by the surveying device 2.
- the target unit 3 is configured such that the reactive confirmation signal 35 contains additional information.
- the confirmation signal 35 returned in response may again have the identification code ID4 of the destination unit 3, so that an over-determined identification is made possible and thus the susceptibility to errors can be reduced.
- the radio-transmitted reactive acknowledgment signal 35 may also include data such as the current time delay between detecting the search fan 22 and returning the confirmation signal 35, tilt of the pole, height of the reflector 31 over ground, reflector constants, and / or Target unit 3 recorded measured values such as temperature or air pressure.
- FIG. 4 similar to FIG. 2, another application example is shown in which the depicted target unit 3 does not represent the target object sought by the surveying device 2.
- the fan-shaped search beam 22 is therefore in turn modulated on the identification code ID2, which differs from the identification code ID4 of the destination unit 3 depicted here, as a code sID to be searched for. If the search unit 22 of the surveying device 2 encounters the destination unit 3 positioned in the field of view during the search operation, then the code sID which has been modulated is compared with its own identification code ID4 and a mismatch is detected. In FIG. 4, the target unit 3 is now designed in such a way that in the case of non-coincidence, a negative response signal 39, ie a defined mismatch signal, is transmitted to the surveying device 2.
- FIGS. 5 and 6 show, similar to FIGS. 1 and 3, further application examples in which the depicted target unit 3 represents exactly the target object sought by the surveying device 2.
- the target unit 3 in FIG. 5 has a transmission component 34 designed as a light source for transmitting the confirmation signal 35.
- the light source has a plurality of LEDs or laser diodes aligned in different spatial directions, so that the optical radiation - as the reactive confirmation signal 35 - is emitted omnidirectionally.
- the optical radiation can have such a characteristic that it can be clearly distinguished from interfering reflections and / or sunlight by the surveying device 2 during the detection.
- the reflector 31, the detector 32 and the light source of the target unit 3 may, for example, in the vertical direction be arranged linearly successive on the Verresssstange 36, wherein the arrangement order of the components can also be arbitrarily chosen differently than shown in Figure 5.
- the evaluation component can be integrated, for example, in a housing of the detector 32 or the transmission component 34.
- the detector and / or the light source can also be integrated in the reflector, which is designed, for example, as a wrap-around prism.
- the target unit 3 depicted in FIG. 6 has both a light source and a radio module 37 integrated into the peripheral device 38 as transmitting components 34 for transmitting both an optical acknowledgment signal 35 'and an acknowledgment signal 35 "by radio.
- a radio module 37 integrated into the peripheral device 38 as transmitting components 34 for transmitting both an optical acknowledgment signal 35 'and an acknowledgment signal 35 "by radio.
- FIGS. 7 and 8 show examples of an automatic search and identification method according to the invention in the context of a typical practical field application in each case.
- the method according to the invention is carried out with at least one target unit 3, which represents one of a plurality of target objects 11 of a target object set, and with a geodetic surveying device 2, which has a distance and angle measurement functionality.
- the target objects 11 are each assigned a unique identification code ID1-ID7, so that the target objects 11 can be clearly distinguished from each other on the basis of the identification code ID1-ID7.
- the surveying device 2 emits an optical beam 22 in a defined spatial direction, in particular a vertically fanned-out laser beam, which is swiveled around a standing axis 24 of the surveying device 2 for searching a field of view. If the optical beam 22 hits the target unit 3, it is detected by the target unit 3.
- an identification code ID2 of a searched, to-be-measured target object 11 of the target object set is modulated onto the optical beam 22 as a code sID to be searched for.
- the target unit 3 demodulates the detected beam 22 and checks whether the code sID modulated on the received beam 22 matches the own identification code ID2. If the evaluation component 33 determines a match, the target unit 3 transmits a reactive confirmation signal 35 to the geodetic surveying device 2. In particular, the reactive acknowledgment signal 35 can be sent to the surveying device 2 with a known temporal response delay after receiving the optical beam 22.
- the surveying device 2 can identify the desired target unit 3 on the basis of the reactive acknowledgment signal 35, in particular based on a time of reception of the reactive acknowledgment signal 35.
- the optical beam 22 emitted by the surveying device 2 can be used in particular for scanning a Field of view of the surveying device 2 are inclined within a defined angular range and / or pivoted about a standing axis 24 of the surveying device 2.
- part of the incident optical beam 22 can be reflected back in the direction of the surveying device 2 by the target unit 3, in particular by a reflector of the target unit 3.
- the geodetic surveying device 2 can thus receive parts of the beam 22 reflected at target objects 11 and detect them as reflections 12, wherein the reflections 12 are assigned a measured angle and in particular a measured distance. Shown schematically in FIG. 7 are reflections 12 that are generated when the search fan 22 impinges on the target objects 11 and when it impinges on further reflective surfaces located in the field of vision.
- the reflexes 12 can be registered by the surveying device 2 dependent on the angle.
- the corresponding reflex 12 is then selected from the set of detected reflexes 12 and linked to the identification code ID2 of the target unit 3 as a function of the acknowledgment signal 35, in particular as a function of the reception time of the acknowledgment signal 35.
- the linking of the selected reflex 12 with the destination unit 3 or with the identification code ID2 of the destination unit 3 taking into account the known temporal response delay as well as dependent on
- Identification code ID2 of the searched target object 11 is modulated as code sID, which in the case shown is represented by the destination unit 3 held by a user. Therefore, the target unit 3 automatically transmits reactive to the search fan 22, the confirmation signal 35 based on the designed as a radio module 37 transmitting component 34 to the surveying device 2, so that the surveying device 2 can assign that reflex 12 of the target unit 3 sought, the time - taking into account the response delay - The confirmation signal 35 corresponds.
- the target object 11 is searched with the identification code ID3, which is why the search fan 22 this identification code ID3 is modulated as a search code sID.
- All target units 3 positioned in the field of vision read the modulated code sID when the search fan 22 strikes and compare it with the respective own identification code ID1, ID2, ID3, ID4.
- the sought-after destination unit 3 with the correct identification code ID3 again reactively transmits an acknowledgment signal 35.
- the confirmation signal 35 is transmitted optically by a light source present on the target unit side.
- the further target units 3 positioned in the field do not reactively transmit a response signal to the impinging search fan 22, since they do not detect a match of the code sID modulated onto the search fan 22 with the respective own identification code ID1, ID2, ID4.
- the search beam emitted by the surveying apparatus can also be used to modulate a plurality of identification codes of several target units from the target object set as codes to be searched for, so that exactly the target units sought each time a reactive fan encounters the search fan Send the confirmation signal back to the surveying device. If the confirmation signal emitted on the destination side additionally carries the respective identity of the respective target unit, then the surveying device can uniquely identify the target units.
- the "unsearched" target units remain “silent" from the target object set and do not also send their identity as an answer upon impact of the search beam, whereby the effort on the part of the surveying device with respect to processing the answers of the target units significantly reduced can be .
- the term "geodetic surveying equipment” is to be understood as always referring to a measuring instrument, for example a theodolite or a total station, which has devices for measuring or checking data with spatial reference
- a measuring instrument for example a theodolite or a total station
- other devices such as satellite-based components may be used
- Location determination eg GPS, GLONASS or GALILEO
- GLONASS Globalstar Navigation Satellite Navigation
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Priority Applications (6)
Application Number | Priority Date | Filing Date | Title |
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EP10705589.9A EP2404137B1 (de) | 2009-03-06 | 2010-02-19 | Geodätisches vermessungssystem und verfahren zum identifizieren einer zieleinheit mit einem geodätischen vermessungsgerät |
CA2754573A CA2754573A1 (en) | 2009-03-06 | 2010-02-19 | Geodetic measuring device |
CA2770260A CA2770260C (en) | 2009-03-06 | 2010-02-19 | Geodesic measurement system and method for identifying a target unit having a geodesic measurement device |
AU2010220492A AU2010220492B2 (en) | 2009-03-06 | 2010-02-19 | Geodesic measurement system and method for identifying a target unit having a geodesic measurement device |
US13/145,551 US8553212B2 (en) | 2009-03-06 | 2010-02-19 | Geodesic measurement system and method for identifying a target unit having a geodesic measurement device |
CN2010800099642A CN102341671B (zh) | 2009-03-06 | 2010-02-19 | 具有大地测量装置的用于识别目标单元的大地测量系统和方法 |
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
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EP09154556A EP2226610A1 (de) | 2009-03-06 | 2009-03-06 | Geodätisches Vermessungssystem und Verfahren zum Identifizieren einer Zieleinheit mit einem geodätischen Vermessungsgerät |
EP09154556.6 | 2009-03-06 |
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WO2010100043A1 true WO2010100043A1 (de) | 2010-09-10 |
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PCT/EP2010/052130 WO2010100043A1 (de) | 2009-03-06 | 2010-02-19 | Geodätisches vermessungssystem und verfahren zum identifizieren einer zieleinheit mit einem geodätischen vermessungsgerät |
Country Status (6)
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US (1) | US8553212B2 (de) |
EP (2) | EP2226610A1 (de) |
CN (1) | CN102341671B (de) |
AU (1) | AU2010220492B2 (de) |
CA (2) | CA2754573A1 (de) |
WO (1) | WO2010100043A1 (de) |
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US9377885B2 (en) | 2010-04-21 | 2016-06-28 | Faro Technologies, Inc. | Method and apparatus for locking onto a retroreflector with a laser tracker |
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Also Published As
Publication number | Publication date |
---|---|
EP2226610A1 (de) | 2010-09-08 |
EP2404137B1 (de) | 2015-04-01 |
CA2770260C (en) | 2015-12-01 |
US20120008136A1 (en) | 2012-01-12 |
CN102341671A (zh) | 2012-02-01 |
AU2010220492B2 (en) | 2013-07-11 |
CA2770260A1 (en) | 2010-09-10 |
CN102341671B (zh) | 2013-08-21 |
US8553212B2 (en) | 2013-10-08 |
EP2404137A1 (de) | 2012-01-11 |
AU2010220492A1 (en) | 2011-08-11 |
CA2754573A1 (en) | 2010-09-10 |
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