Source: https://patents.google.com/patent/DE102016119155A1/en
Timestamp: 2020-05-27 16:15:08
Document Index: 414295086

Matched Legal Cases: ['arts 8', 'arts 8', 'art 12', 'art 8', 'art 10', 'art 10', 'arts 8', 'arts 8', 'art 10', 'arts 8', 'art 8', 'art 12', 'art 12', 'art 10', 'art 8', 'art 8', 'art 10', 'art 8', 'art 10']

DE102016119155A1 - Laser scanner - Google Patents
DE102016119155A1
DE102016119155A1 DE102016119155.8A DE102016119155A DE102016119155A1 DE 102016119155 A1 DE102016119155 A1 DE 102016119155A1 DE 102016119155 A DE102016119155 A DE 102016119155A DE 102016119155 A1 DE102016119155 A1 DE 102016119155A1
DE102016119155.8A
2016-09-15 Priority to DE102016117431 priority Critical
2016-09-15 Priority to DE102016117431.9 priority
2016-10-07 Application filed by Zoller and Froehlich GmbH filed Critical Zoller and Froehlich GmbH
2018-03-15 Publication of DE102016119155A1 publication Critical patent/DE102016119155A1/en
Disclosed is a laser scanner in which scan data and logging files are stored only on a simple exchangeable internal data memory.
The basic structure of such laser scanner is for example in the DE 101 50 436 B4 disclosed. It describes a 3D laser scanner that can be used to measure measurement objects such as buildings, crime scenes, production facilities etc. with high accuracy. In such a scanner, the measuring beam emitted by a laser diode is deflected by a mechanical beam deflection system such that a comprehensive three-dimensional spatial environment measurement is made possible. The digitized measurement data are processed and stored via a computing unit and are available there for further processing and visualization of the measured object.
This 3D measurement is carried out by guiding the modulated laser light over the environment to be measured, wherein for different spatial directions, both the distance and the reflection value can be measured selectively. The arrangement of all measured spatial directions results in distance and reflectivity images. The distance images represent the geometry of the environment and the reflectivity images their visual representation, analogous to the grayscale images of a video camera. Both images correspond pixel by pixel and are largely independent of environmental influences due to the independent, active illumination with laser light.
In the known solution, the beam deflecting system is designed with a deflection mirror, which is mounted in a rotary head - referred to below as the rotor - of the laser scanner. This is rotationally rotatable about a first axis, preferably a horizontal axis rotatably mounted on a housing of the scanner, which in turn is at least 180 ° pivotable about an axis of rotation which is perpendicular to the axis of rotation, for example in the vertical direction. As mentioned, in such a 3D laser scanner, the image information is recorded in the form of 3D pixel clouds, which can then be converted into a gray scale image of the measurement object.
In many cases, a color image of the object to be measured is desired. The color information can be scanned via a camera, which is placed, for example, on the housing of the laser scanner. Solutions are also known in which the color information of the measurement object is detected via a camera mounted in the beam path of a mirror arrangement. The disadvantage of such a solution is that color distortion of the camera image can occur due to deflecting mirrors and any other optical elements present. Systems with a mounted on the housing of the laser scanner camera have the disadvantage that they require a considerable amount of space and also arise due to the different perspectives of the mounted camera and the actual laser scanner parallax errors, which must be eliminated by a complex Z-buffer calculation. To overcome this disadvantage is in the DE 10 2012 105 027 A1 described a laser scanner in which the color camera for detecting the color information of the measurement object is mounted on or in the measuring head / turret, so that the virtual optical centers of the camera and the measuring beam substantially coincide with us so a parallax error is avoided.
The concept of signal processing in laser scanners is in the DE 198 51 307 A1 the applicant explains.
Appropriate concepts can also be implemented in 2D laser scanners, in which the laser scanner is not pivotable about a vertical axis but is mounted on a mobile platform.
The DE 10 2014 109 432 A1 describes a laser scanner, which is additionally formed with a thermographic camera, so that the measurement result is a 3D scan (point cloud of the measurement object) with linked thermography data.
Since in the case of complex measurement objects the measurement takes place from different locations, such laser scanners can be designed with a navigation system, via which the respective scanner location and the scanner orientation are detected. Like in the DE 10 2016 102 607 A1 Described by the applicant, such integrated in the laser scanner navigation systems are designed so that they allow a GNSS (for example, GPS) -independent determination of the absolute position of the laser scanner or at least a relative position to a known location in the field. In this way, the measurement of interiors is made possible. These navigation data are stored for measurement signal processing in the internal memory of the laser scanner.
In particular, in the measurement of military objects or nuclear power plants or safety-related manufacturing facilities, there is a requirement that the measurement and evaluation takes place within the system and no data from the system may be transmitted or spent. In conventional laser scanners, this means that the entire 3D measurement within the system has been completed and evaluated must then be deleted and then the corresponding data on the hard disk of the arithmetic unit of the laser scanner and other external computer must be deleted. This means a considerable effort, since it must be ensured that all data are removed and a corresponding proof is to be led to the plant operator.
In contrast, the invention has for its object to provide a 2D or 3D laser scanner, which allows a reliable and easy removal of the registered and evaluated scan.
This object is achieved by a laser scanner with the features of claim 1.
The laser scanner according to the invention has a rotor which is rotatably held on a housing, wherein in the rotor, a beam deflection system is arranged to direct a emitted from a transmitter, such as a laser diode measuring beam to a measuring object or a reflected beam from this on a receiver. The laser scanner is designed with a computer unit for controlling the laser scanner and for data processing, which is provided with a data memory for storing measured data. According to the invention it is provided that the data storage is removably held in a receptacle of the housing. The term "removable" is to be understood that the holder is designed for easy and quick changing or removing the data storage, without the need for a costly disassembly of components. The arithmetic unit is preferably designed so that the relevant measurement data (scan data and logging files) can only be stored on this data memory.
In one variant, the operating system and the software for controlling the scanner can be stored on an internal memory, for example a flash memory. This is designed so that no measurement data can be created on it and is thus provided with a write protection.
Alternatively, the software required for the activation of the laser scanner and the operating system can be implemented on the data memory, so that the scanner is no longer functional after the removal of the data memory.
By the measure to store at least the measured data acquired during the measuring process (3D pixel cloud and associated color information, logging files) on the data memory, the conditions mentioned above can be fulfilled very easily by removing the data memory and leaving it on site or also erasing it.
In a preferred embodiment of the invention, the receptacle for the data memory is formed on the housing.
In the case in which the scanner does not have to meet any of the above-mentioned safety-related requirements, the internal data memory (for example, an internal SSD drive (SATADOM)) can also be permanently installed in a conventional manner. Then, an additional storage medium, for example. An SD card can be provided to which the data can be copied. This SD card can then be used in a manner known per se in an externally accessible slot of the housing.
The advantage of using a Sata Disc On Module as an internal data storage device is that it does not require its own power connection, as power is supplied via the Sata connection.
In one embodiment of the invention, the rotor is held between two housing parts, which are connected to one another by means of a housing intermediate part which tapers towards the latter - this is the typical structure of a 3D laser scanner.
In such laser scanners, the housing is rotatable about a rotational axis arranged perpendicular to the axis of rotation of the rotor by means of a rotary drive.
In one embodiment of the invention, it is provided that the rotary drive has a backlash-free transmission, which is preferably designed as a gear transmission, wherein an encoder is assigned to detect the respective angle of rotation of the laser scanner of the axis of rotation of the housing.
In order to enable a measurement independent of an external power supply, laser scanners are often provided with a battery. These batteries have a relatively high weight, which must be moved via the aforementioned rotary drive. To reduce the moment of inertia is proposed according to the invention that a plurality, for example, two batteries are arranged symmetrically in a comparatively small distance from the aforementioned axis of rotation. In this case, it is further preferred if these batteries are arranged as close as possible to the support of the laser scanner in order to also allow a tilting moment minimize. In addition, these batteries are aerodynamically optimized with respect to the outer geometry in order to minimize the air resistance during pivoting about the vertical axis. In this way, the measurement errors in the measurement of measurement objects can be further reduced.
It is preferred in a variant of the invention, when the batteries complement each other with a cover of the respective housing part to a structural unit.
The operation of the laser scanner is particularly simple if a touch display is arranged on a housing part. This touch display is arranged according to an embodiment in portrait format.
The measuring accuracy can be further improved if the laser scanner is operated according to the measuring principle of the phase shift with three measuring frequencies.
The removable data memory can be accessible, for example, with the battery removed.
The applicant reserves the right to make independent claims on the arrangement of the batteries or the use of three measuring frequencies or the use of a backlash-free gearbox, which may be further pursued in divisional applications.
1 a three-dimensional representation of an embodiment of a 3D laser scanner;
2 and 3 a rear view and a front view of the laser scanner according to 1 ;
4 a side view of the laser scanner;
5 a section along the line AA in 4 ;
6 a section along the line BB in 3 ;
7 and 8th Views of the laser scanner according to 1 with removed housing covers and
9 a detailed representation of a recording of a data memory of the laser scanner according to 1 ,
1 shows a three-dimensional representation of an embodiment of a 3D laser scanner 1 , This has a measuring or rotary head, hereinafter rotor 2 called, around a horizontal axis of rotation 4 (see also 2 . 3 ) rotatably on a housing 6 of the laser scanner 1 is held. This case 6 has - similar to the known solutions described above - two housing parts 8th . 10 between which is the rotor 2 extends. In the picture according to 1 below the rotor 2 are the two housing parts 8th . 10 via a housing intermediate part 12 connected to each other, which in a conventional manner to the rotor 2 tapered to minimize shading during the survey.
The housing 6 is via an adjustable mounting flange 14 on a stand or a movable platform, such as a handcart, as offered by the applicant under the trademark SCADDY ® supported. In the illustrated embodiment, the in 1 right housing part 8th with two handles 16 . 18 to simplify handling.
On the other housing part 10 is a vertical format touch display 20 arranged over which the laser scanner 1 can be operated and on the measurement results are visually displayed.
As explained in more detail below, is in this housing part 10 an arithmetic unit recorded, the data storage is inventively held in a receptacle that it can be easily removed. We will illustrate this in the following 9 explained. The playful basis 9 described in more detail internal data storage (SATADOM) can be secured in a suitable manner, so that an accidental or unauthorized removal is difficult.
In one embodiment of the invention, one of a cover 23 covered slot 22 for receiving an additional storage medium, for example. An SD card 24 trained, can be copied to the measurement data. However, this variant does not comply with the abovementioned safety-relevant conditions and is not required for scanners that have to meet these requirements.
Turning the laser scanner on and off 1 via a switch 25 , The in 1 illustrated laser scanner 1 is furthermore for a network-independent operation with two batteries 26 . 28 Running flush with the respective housing parts 8th . 10 are used and thereby in a relatively small distance from the mounting flange 14 are arranged to minimize a tilting moment.
To reduce the mass moment of inertia are the two batteries 26 . 28 also in the smallest possible distance to a rotation axis 30 arranged around the the entire laser scanner 1 is rotatable, so that when pivoting about the axis of rotation 30 at around the axis of rotation 4 rotating rotor 2 the entire surrounding space can be measured.
In the illustration according to 1 You can also see a power connection 32 and a LAN connection 34 so that the laser scanner 1 can also be operated with an external power supply and the measuring signals via the LAN connection 34 to a satellite computer located in the field for the registration and / or evaluation of the scan are transferable.
Of course, this registration and evaluation also on the laser scanner 1 yourself.
The procedure for such a registration and evaluation are described in the DE 10 2016 102 607 A1 the applicant explains.
2 shows a rear view of the laser scanner according to 1 , Accordingly, in the rotor 2 for capturing image / color information of the measurement object, a color camera 36 (Visible here is strictly only a camera window) recorded. To capture this image information with sufficient quality is the rotor 2 with a light unit 38 trained, over which the image field can be illuminated. This light unit 38 has four LEDs in the illustrated embodiment, in the peripheral region of the color camera 36 are arranged to ensure optimum illumination. Details of this light unit are in the parallel application DE 10 2016 117 431 the applicant explains.
In the illustration according to 2 you can see very clearly the integration of the two batteries 26 . 28 in the housing parts 8th . 10 , The attachment of the housing 6 at the in 2 not shown mounting flange 14 takes place via three fixing pins lying on a partial circle 40 , of which in the illustration according to 2 only one is provided with a reference numeral.
According to the front view in 3 is on the rotor 2 the output or input of the laser optics arranged; this one is from a diagonally put on protective glass 42 covered, as in the aforementioned DE 101 50 436 B4 is described.
As from the pictures according to the 1 to 3 can be seen, is the case 6 of the laser scanner 1 smooth surface, for example, formed without cooling fins or the like, so that the outer contour is also aerodynamically optimized and as little resistance to wind or during rotation / rotation of the laser scanner 1 offers.
In the representations according to the 2 and 3 is also a reference module 44 shown for the distance measurement.
4 shows a side view of the housing part 10 on which the touch screen 20 is arranged. Underneath is the battery 28 arranged.
The batteries 26 . 28 are removable on the housing parts 8th . 10 stored so that they can be charged via an external charging station. When connected to the mains via the power connection 32 Charging the batteries 26 . 28 over the laser scanner 1 ,
5 shows a section along the line AA in 4 , In this illustration you can see quite clearly the two batteries 26 . 28 , each as a battery pack with a variety of rechargeable batteries 46 are formed and in a recording 48 . 50 of the respective housing part 8th . 10 be used.
In the section according to 5 you can see the basic principle of a rotary drive 52 over which the case 6 for pivoting about the axis of rotation 30 is driven. The housing 6 is about the intermediate housing part 12 on a cup-shaped base projecting downwards 54 stored, wherein the intermediate housing part 12 via a drive hub 56 in the base 54 dips and there in the radial direction via a bearing assembly 58 as well as a central axis 60 is guided.
The drive hub 56 is with an external toothing 62 running, with a drive pinion 64 it meshes with a motor shaft of an engine 66 is driven at the base 54 is supported. The drive pinion 64 and the external teeth 62 form a gear transmission, which is executed without play.
The respective angle of rotation of the housing 6 and thus the angular position of the color camera 36 and the laser beam is transmitted through an in 5 indicated encoder 68 detects the angle of rotation with respect to the central axis 60 scans. The play-free design of the gear transmission allows a high accuracy of the encoder 68 and thus an exact angle of rotation determination. Usually, such encoders are on the engine 66 arranged so that the rotational angle position of the housing 2 is only indirectly recorded.
As mentioned, the Applicant reserves the right to provide a backlash-free transmission, preferably a gear transmission and on Determining the angle of rotation by means of an encoder arranged on the axis, to set its own claim.
In the illustration according to 5 is also the aforementioned, in the housing part 10 recorded arithmetic unit 70 with the operation of the laser scanner 1 required control modules visible. As based on the 9 explained in more detail, has this arithmetic unit 70 (CPU) an internal flash memory that is not accessible from the outside. This flash memory is the operating system and other software for operating the laser scanner 1 stored. Writing the flash memory to data is not possible because there is write protection.
The scan data and the logging files reside on an internal drive which can be removed according to the invention, further details are given 9 explained.
The above-described SD card serves - as mentioned - only to copy the data stored on the drive. However, this option with the additional SD card memory can be omitted. For applications with lower security requirements, it is not necessary to provide the internal drive (SATADOM) replaceable. In this case, however, the option with the SD card is implemented to simplify the processing of the data on external computers and the data backup.
In the in 5 overhead area of the laser scanner 1 is the aforementioned rotor 2 arranged. In between is lying as a laser radar measuring system 72 designated unit, the computing unit 70 opposite and in the housing part 8th is included. This laser radar measuring system 70 contains, inter alia, at least one detector for detecting the signals reflected by the measurement object.
The of the color camera 36 captured image data are via a liftable slip ring assembly 74 to the arithmetic unit 70 transfer. The function of this slip ring arrangement 74 is in the aforementioned DE 10 2012 105 027 A1 explained. Accordingly, this slip ring assembly 74 engaged in the distance measurement by means of the laser, so that the friction during the distance measurement is minimal. In order to acquire the image data, the slip ring arrangement is then brought into operative engagement following the distance measurement, so that the color camera then uses it 36 captured image data to the arithmetic unit 70 be transmitted.
With the reference number 69 is in the illustration according to 5 a tilt measuring device 69 provided, via the inclination of the laser scanner 1 is detectable, so that the measured values can be corrected according to this inclination.
The beam guidance of the distance measuring system is based on 6 explains that a section along the line BB in 3 shows.
One recognizes in this sectional representation the actual color camera 36 whose lens 80 approximately parallel to the axis of rotation 4 is arranged. The color camera 36 may be, for example, a chip camera, in which on a board, the actual recording chip and the lens 80 are arranged. The light beams carrying the color information of the object to be measured pass through a camera window 78 in the rotor 2 a and are over a camera mirror 76 towards the lens 80 the color camera 36 diverted. The transmission of the color information is then via the described slip ring assembly 74 to the computing unit 70 ,
The drive of the rotor 2 via a DC motor 82 which in turn is an encoder for detecting the rotational angular position of the rotor 2 assigned. The basic structure of such a rotor drive is in the DE 10 2012 105 127 A1 explained.
The laser beam or the laser beams used in a multi-wavelength / frequency measuring system is / are in each case emitted via a commercially available laser diode, wherein the divergent beam of the laser diode is transmitted via a collimator 84 is collimated. This collimated beam then passes in a conventional manner via a channel of a mirror body to a beam output mirror 86 and becomes from this towards a device for beam rejuvenation 88 deflected, which is carried out with a Galilean telescope. The resulting laser beam / measuring beam is then passed over a plane inclined mirror 90 deflected in the direction of the object to be measured and passes through the aforementioned protective glass 42 through the rotor 2 out. The beam reflected by the test object passes through the protective glass accordingly 42 through the rotor 2 one and gets over the plan inclined mirror 90 deflected towards the mirror body, which has a beam entrance mirror 92 through which the reflected rays toward the detector of the laser radar measuring system 72 (please refer 5 ) are redirected. The basic structure of such a beam guidance is known, so that further explanations are unnecessary.
In the illustration according to 6 is still a focusing device 94 shown, over which in the near range focusing with intensity adjustment is possible. This focus is from the outside accessible, if according to 7 and 8th a cover of the housing part 8th is removed.
7 shows the housing part 10 with the cover removed, which includes the touch screen 20 wearing. When you remove this cover are then accordingly the arithmetic unit 70 (CPU), the DC motor 82 and also the slip ring arrangement 74 accessible. In the illustration according to 7 is also the battery 28 taken, so that the appropriate intake 48 with the electrical contacts 96 is visible.
8th shows the housing part 8th with the cover removed. This is the focusing device 94 and the above-described beam guide (with the mirrors 86 . 92 and the device for beam rejuvenation 88 ) accessible. Below this beam guide is the laser radar measuring system 72 arranged. In the illustration according to the 7 and 8th is also the storage 98 . 100 of the rotor 2 visible, noticeable.
As explained, according to the invention, the scan data and logging files resulting from the measurement are stored on an internal drive (SSD, SATADOM). 104 the arithmetic unit 70 stored. This is the laser scanner 1 according to 9 designed so that this internal data memory can be removed, whereby the operating system and program are stored on an internal flash memory and are not accessible from the outside or can be overwritten. The internal drive 104 is in the embodiment in 9 with removed battery 28 accessible. In the recording 48 is a flap 102 provided, for example, locked or screwed. With the flap open 102 then can the internal drive 104 With the scan data and the logging files are removed - because of the write protection of the internal flash memory, it is not possible that the laser scanner 1 contains more data. This ensures that the collected data remains in the system and does not leak to the outside.
As explained in the introduction, the operating system and the program on the removable memory / drive can in principle be provided 104 arrange so that the laser scanner 1 after removing this drive 104 "Dead" is - a conclusion on previous measurements is then no longer possible.
Of course, the internal drive 104 also in the area of the computing unit 70 in the housing part 10 be included.
According to the invention, it can further be provided that the laser scanner is operated with three measurement frequencies, so that the measurement accuracy is significantly improved over conventional solutions with two measurement frequencies.
As mentioned above, the laser scanner is preferably implemented with a navigation unit which enables determination of the position even if there is no GNSS / GPS signal.
As explained above, other essential features of the laser scanner described are seen in addition to the increase in security by providing a removable internal drive in the play-free drive the vertical axis of rotation and the arrangement of the batteries and in the operation of the laser scanner with more than two measurement frequencies.
Disclosed is a laser scanner in which scan data and logging files are stored only on a simple replaceable data memory.
Rotor / rotary head
Beam output levels
Device for beam rejuvenation
Beam input levels
DE 10150436 B4 [0002, 0050]
DE 102012105027 A1 [0005, 0064]
DE 19851307 A1 [0006]
DE 102014109432 A1 [0008]
DE 102016102607 A1 [0009, 0047]
DE 102016117431 [0048]
DE 102012105127 A1 [0068]
Laser scanner ( 1 ) with a rotor ( 2 ) rotatably mounted on a housing ( 6 ), wherein an optical system is provided for directing a measuring beam emitted by a transmitter onto a measuring object or a beam reflected by it onto a detector, wherein a computer unit ( 70 ) is provided for controlling the laser scanner and for data processing, which has an internal data memory ( 104 ), on which the of the arithmetic unit ( 70 ) processed scan data are stored, characterized in that the data memory ( 104 ) removable in a housing of the housing ( 6 ) is held.
Laser scanner according to claim 1, wherein the receptacle after removal of a cover or a functional component of the laser scanner ( 1 ) is accessible.
Laser scanner according to claim 1 or 2, wherein the rotor ( 2 ) between two housing parts ( 8th . 10 ), which by means of a to the rotor ( 2 ) tapered housing intermediate part ( 12 ) are connected to each other.
Laser scanner according to one of the preceding claims, wherein the housing ( 6 ) about a perpendicular to a rotation axis ( 4 ) of the rotor ( 2 ) arranged rotary axis ( 30 ) is rotatable by means of a rotary drive.
Laser scanner according to claim 4, wherein the rotary drive has a backlash-free transmission, preferably a toothed gearing, and the angular position of the housing ( 6 ) over one on an axis ( 60 ) of the housing ( 6 ) arranged encoder ( 68 ) is detectable.
Laser scanner according to one of the preceding claims, wherein on each housing part ( 8th . 10 ) a battery ( 26 . 28 ) is held and the housing parts ( 8th . 10 ) and the batteries ( 26 . 28 ) are designed so that the rotating masses and outer geometries is approximately balanced with respect to the axis of rotation and that a tilting moment with respect to a support of the laser scanner is minimal.
Laser scanner according to claim 6, wherein the batteries ( 26 . 28 ) with a cover ( 23 ) of the respective housing part ( 8th . 10 ) to form a structural unit.
Laser scanner according to one of the preceding claims, wherein on a housing part ( 8th ) a vertically arranged touch display ( 20 ) is arranged.
Laser scanner according to one of the preceding claims, wherein this is operated according to the measuring principle of the phase shift with three measurement frequencies.
Laser scanner according to one of the preceding claims, wherein the outer surfaces of the housing ( 6 ) are formed substantially smooth surface.
Laser scanner according to one of the preceding claims, wherein the arithmetic unit ( 70 ) has an internal memory, on which the operating system and the control software for the laser scanner is stored, this internal memory is provided with a write protection.
Laser scanner according to one of the claims 1 to 10, wherein an operating system and software for controlling the laser scanner are stored on the data memory.
Laser scanner according to one of the preceding claims, wherein the removable internal data memory ( 104 ) is an SSD memory, in particular a SATADOM memory.
DE102016119155.8A 2016-09-15 2016-10-07 Laser scanner Pending DE102016119155A1 (en)
DE102016117431 2016-09-15
DE102016117431.9 2016-09-15
PCT/EP2017/072365 WO2018050516A1 (en) 2016-09-15 2017-09-06 Laser scanner
EP17761897.2A EP3513217A1 (en) 2016-09-15 2017-09-06 Laser scanner
EP17765400.1A EP3513216A1 (en) 2016-09-15 2017-09-06 Laser scanner having a lighting unit
PCT/EP2017/072347 WO2018050512A1 (en) 2016-09-15 2017-09-06 Laser scanner having a lighting unit
DE102016119155A1 true DE102016119155A1 (en) 2018-03-15
ID=61247461
DE102016119155.8A Pending DE102016119155A1 (en) 2016-09-15 2016-10-07 Laser scanner
DE102017114617.2A Pending DE102017114617A1 (en) 2016-09-15 2017-06-30 Laser scanner with light
EP (2) EP3513217A1 (en)
DE (2) DE102016119155A1 (en)
WO (2) WO2018050516A1 (en)
CN109521497A (en) * 2018-10-29 2019-03-26 成都市克莱微波科技有限公司 A kind of rifling tubbiness formula scanning device
DE19851307A1 (en) 1998-10-08 2000-04-13 Z & F Zoller & Froehlich Gmbh System for determination of one or more physical quantities especially for use with a AMCW laser type system has means for determination of phase of amplitude of mission signal
DE102012105127A1 (en) 2011-08-17 2013-02-21 Wan-Yu Li Foldable legrest
DE102016102607A1 (en) 2015-02-13 2016-08-18 Zoller + Fröhlich GmbH Scan arrangement and method for scanning an object
DE202013001538U1 (en) * 2013-02-19 2013-03-19 Ulrich Clauss Arrangement for recording geometric and photometric object data in space
EP2860550B1 (en) * 2013-10-09 2016-03-02 Hexagon Technology Center GmbH Scanner for spatial measurement
2016-10-07 DE DE102016119155.8A patent/DE102016119155A1/en active Pending
2017-06-30 DE DE102017114617.2A patent/DE102017114617A1/en active Pending
2017-09-06 WO PCT/EP2017/072365 patent/WO2018050516A1/en unknown
2017-09-06 EP EP17761897.2A patent/EP3513217A1/en active Pending
2017-09-06 EP EP17765400.1A patent/EP3513216A1/en active Pending
2017-09-06 WO PCT/EP2017/072347 patent/WO2018050512A1/en unknown
EP3513216A1 (en) 2019-07-24
WO2018050516A1 (en) 2018-03-22
EP3513217A1 (en) 2019-07-24
WO2018050512A1 (en) 2018-03-22
DE102017114617A1 (en) 2018-03-15
CN103119466B (en) 2015-09-23 For carrying out the device of optical scanning and measurement to environment
FI96902C (en) 1996-09-10 Optoelectronic angle sensor device, method for this and optoelectronic measuring system
US10070116B2 (en) 2018-09-04 Device and method for optically scanning and measuring an environment
US20130201470A1 (en) 2013-08-08 Target apparatus and method