DE102010006105A1 - Apparatus and method for sequential pattern projection - Google Patents

Abstract

The present invention relates to an apparatus and a method for pattern projection for the optical measurement of a movable or immovable object to be measured (2), wherein a rotating, analog light modulator (4) is provided which spatially and temporally modulates light as a measurement pattern onto the object to be measured ( 2) by means of projection optics (5), wherein the projected measurement pattern is taken by a camera (6) for generating a data model of the measurement object.

Description

The invention relates to a device and a method for sequential pattern projection for the optical measurement of a movable or immovable object to be measured.

Conventional methods for optical measurement of measuring objects by means of triangulation are known. In this case, three-dimensional objects can be measured by means of measurement patterns which are sequentially projected onto the measurement object to be measured. The measurement pattern projected onto an object surface of the measurement object to be measured is recorded by means of one or more cameras for measuring the surface. The number of measurement patterns projected onto the surface of the object to be measured can generally be varied, and in general the achieved measurement accuracy increases with the number or rate of the projected measurement patterns. Conventional methods and devices use various types of light modulators.

The EP 0 660 078 B1 describes, for example, a device for generating strip-like light patterns. In this conventional device, a mask composed of partial surfaces is used as the light modulator, wherein the transparency or the brightness of the partial surfaces can be controlled. These sub-areas can be formed as electrodes of a liquid crystal display or as light-emitting diodes. Since all of these partial surfaces of the mask are to be controlled separately, the technical complexity in this conventional device for generating a measurement pattern is very high.

In the US Pat. No. 6,885,464 B1 is a 3D camera for marking a surface structure, for example, described in teeth. In this device, an analog light modulator is laterally displaceable by means of a piezo actuator. The disadvantage with this conventional device is that after a change of measurement pattern, the entire measurement pattern is displaced locally and stationary signal components can not be realized. However, such fixed signal components of a measuring pattern may be necessary as reference markings or reference marks. This conventional device with an electromechanically displaceable analog light modulator thus does not allow the provision of reference marks.

It is therefore an object of the present invention to provide a method and a device for sequential pattern projection for the optical measurement of a measurement object, which allows the provision of a stationary signal component within a measurement pattern with little technical effort.

This object is achieved by a device having the features specified in claim 1.

The invention provides a device for sequential pattern projection for the optical measurement of a measurement object, wherein a rotating, analog light modulator is provided which spatially and temporally modulates light as a measurement pattern sequence projected onto the measurement object to be measured.

The device according to the invention thus uses a rotating, analogue light modulator, which is, for example, a rotating analogue light mask, which can be designed as a rotating light mask disk or as a rotating light mask cylinder.

The device according to the invention allows the projection of a measurement pattern sequence consisting of several measurement patterns in a particularly fast sequence, that is to say with a high projection speed. This is particularly important if the measurement object to be measured is a moving measurement object. The device according to the invention allows a rapid pattern change, wherein the image or pattern change frequency can be more than 500 patterns per second.

Another advantage of the device according to the invention is that an intrinsic cooling takes place by rotation of the analog light modulator, so that the device is also suitable for illumination with high light output.

Compared to a conventional digital projection of a measuring pattern, the device according to the invention has the advantage, due to the use of an analog light modulator, that it offers a higher contrast, a higher resolution and a higher projection speed. In addition, it is very well miniaturized, d. H. to realize in a small space.

A further advantage of the device according to the invention is that the expense for producing the analog light modulator used is relatively low.

Another advantage of the device according to the invention is that the complexity and the minimum installation space of the control electronics are low.

In one embodiment of the device according to the invention, the rotating analog light modulator has a rotating, analog light mask, which is rotated by a rotating light mask A light mask disk or by a rotating light mask cylinder is formed.

In one embodiment of the device according to the invention, the light is generated by a lighting unit which has a light source, which is an LED, an arc lamp, an incandescent lamp or a laser.

The device according to the invention can thus have punctiform light sources, in particular lasers, as well as flat light sources for generating the light.

In one embodiment of the device according to the invention, the rotating light mask disc rotates between the illumination unit and a projection optics. The projection optics can be dispensed with if the light source is a punctiform light source, for example a laser light source. In this embodiment, a so-called shadow projection can take place.

In one possible embodiment of the device according to the invention, the rotating light mask disc consists of a masked glass pane.

In an alternative embodiment of the device according to the invention, the rotating light mask disk consists of a masked metal disk or a masked art disk.

In an alternative embodiment of the device according to the invention, the rotating, analog light modulator is a rotating, analog light mask, which consists of a rotating light mask cylinder. This rotating light mask cylinder preferably has a peripheral surface which modulates the light generated or generated by the illumination unit to a projection optics. In this case, the generated light is preferably reflected by the rotating light mask cylinder.

In one possible embodiment of the device according to the invention, the rotating light mask has a plurality of measurement pattern segments corresponding to the number of measurement patterns of the projected measurement pattern sequence.

In one possible embodiment of the device according to the invention, the measurement pattern segments of the rotating analog light mask are designed such that they modulate the light gradually.

In an alternative embodiment of the device according to the invention, the measurement pattern segments of the rotating, analogue light mask are designed such that they modulate the light in a binary manner.

In one embodiment of the device according to the invention, the measurement pattern segments of the rotating, analogue light mask have surfaces with different optical properties for modulating the light.

These optical properties can be a transmissivity, a reflectivity and an absorption of the respective surface.

In one embodiment of the device according to the invention, integration of light during the rotation of the rotating, analogue light mask results in a gradual modulation of the light intensity of the light.

In one embodiment of the device according to the invention, for gradual modulation of the light through a measurement pattern segment located on the rotating, analogous light mask disk along a circular arc of the light mask disk provided at a radial position, the ratio of the light intensity (I) of the modulated light to a maximum light intensity (I _max ) of the light proportional to the ratio of an optically active circular arc distance (S _A ) to a maximum arc gap (S _max ) of the respective Meßmustersegmentes.

In one embodiment of the device according to the invention, for the gradual modulation of the light in a measurement pattern segment located on the rotating, analog light mask cylinder along an axial position cylinder arc of the light mask cylinder, the ratio of the light intensity (I) of the modulated light to a maximum light intensity (Im ) of the light proportional to the ratio of an optically active cylinder arc length (S _A ) to a maximum cylinder arc length (S _max ) of the respective measurement pattern segment.

In one embodiment of the device according to the invention, at least one camera is provided, which records the measurement pattern sequence projected onto the measurement object.

In one embodiment of the device according to the invention, the measurement pattern segments of the rotating, analogue light mask are designed in such a way that over a period of exposure of the camera, a temporally modified modulation of the light intensity is produced, which corresponds in time-integrated form to the measurement pattern of the measurement pattern sequence to be projected.

In one embodiment of the device according to the invention, a synchronization unit is provided which synchronizes a rotation of the light modulator with the recording of the projected measurement pattern sequence by the camera.

In one embodiment of the device according to the invention, the synchronization unit scans optical synchronization marks, which are mounted on the rotating light modulator, by means of a scanning unit.

This scanning unit preferably has a reflex light barrier, a fork light barrier or at least one photocell.

In one embodiment of the device according to the invention, the rotating, analog light modulator has a centering mark, a plurality of optical synchronization marks, a plurality of optical measurement pattern segments and transition regions between the optical measurement pattern segments, wherein the light is not modulated in the transition regions.

In one embodiment of the device according to the invention, a detection unit is provided which detects an angular position of the rotating, analog light modulator.

In one embodiment of the device according to the invention, the detection unit detects the angular position of the rotating, analog light modulator by means of a track, which is located on the light modulator for encoding the angular position of the rotating analog light modulator.

In one embodiment of the device according to the invention, the detection unit detects the angular position of the rotating analog light modulator by means of an incremental encoder or by means of Hall sensors.

In one possible embodiment of the device according to the invention, the rotating, analog light modulator has a further track for synchronization with exposure periods of an associated camera.

The invention further provides a method for performing a sequential pattern production for the optical measurement of a measurement object,
wherein light is spatially and temporally modulated by means of a rotating, analog light modulator as a measurement pattern sequence is projected onto the measurement object to be measured.

The invention further provides a measuring device for the three-dimensional measurement of a measurement object which has a device for sequential pattern projection for the optical measurement of the measurement object,
wherein in the device at least one rotating, analog light modulator is provided which spatially and temporally modulates an electromagnetic radiation as a measurement pattern sequence projected onto the measurement object to be measured.

This measuring device can be used to measure a moving object or a fixed object to be measured.

In the following, possible embodiments of the device according to the invention and the method according to the invention for the sequential pattern projection for the optical measurement of a measurement object will be described with reference to the attached figures.

Show it:

1 a block diagram of a possible embodiment of the inventive device for sequential pattern projection;

2A . 2 B possible embodiments of the sequential pattern projection apparatus according to the invention;

3A . 3B Examples of measurement pattern sequences of a light modulator for the gradual and binary modulation of light;

4 an embodiment of a usable in the inventive device light mask disk for the binary modulation of light;

5 an embodiment of a usable in the inventive device light mask disk for the gradual modulation of light;

6 a diagram illustrating a developed peripheral surface of a usable in the inventive device, the light mask cylinder;

7 a diagram illustrating the operation of a possible embodiment of the device according to the invention.

How to get out 1 can recognize, the device of the invention 1 for the sequential pattern projection for the optical measurement of a measurement object 2 preferably a lighting unit 3 on, which generates or generates light. At the lighting unit 3 it can be a punctiform light source, for example a laser or a planar light source. The lighting unit 3 For example, LEDs, a Arc lamp or have a light bulb. The lighting unit 3 preferably generates visible light. The lighting unit 3 can also generate light in non-visible frequency ranges. The device 1 also contains a light modulator 4 , which spatially and temporally modulates the generated light or the electromagnetic radiation via a projection optics 5 on the measuring object to be measured 2 projected. Is it the light source of the lighting unit 3 around a point light source, the projection optics can 5 omitted and there is a so-called shadow projection. The light modulator 4 is in the device according to the invention 1 an analog light modulator or an analog light modulator. This light modulator 4 rotates about a rotation axis. The rotation of the light modulator 4 is preferably carried out continuously with a constant adjustable rotational speed. This is the light modulator 4 preferably driven by an electric motor. This electric motor is preferably controlled by a control unit, so that the rotational speed is adjustable. The rotational speed of the rotating, analog light modulator 4 the device according to the invention 1 is relatively high and in one possible embodiment may for example be 5000 rpm. Due to this high rotational speed, the device according to the invention is suitable 1 as they are in 1 is shown, also for measuring moving DUTs 2 for example, measuring a person's hand or measuring facial expression of a person's face. Alternatively, the device according to the invention 1 also for measuring a non-moving measurement object 2 , For example, a product to be produced or prototypes are used.

2A shows an embodiment of the device according to the invention 1 according to the invention. In this embodiment, the projection of the measurement pattern sequence takes place with the aid of a rotating analog light mask disk. This rotating analog light mask disc forms the rotating analog light modulator 4 , The light pattern or the measurement pattern sequence formed in this way is transmitted via the projection optics 5 on the measuring object to be measured 2 projected. How to get in 2 can detect, the rotating light mask disc rotates 4 in this embodiment, between the lighting unit 3 and the projection optics 5 , In one possible embodiment, the rotating light mask disk is 4 around a masked glass. In an alternative embodiment, the rotating mask is disc 4 around a masked metal disc. In a further possible embodiment, the rotating light mask disk is 4 around a masked plastic or plastic disc. The on the measuring object to be measured 2 Projected measurement patterns of the measurement pattern sequence are processed by a camera 6 added.

2 B shows a further embodiment of the device according to the invention 1 for the sequential pattern projection for the optical measurement of a measurement object 2 , In this embodiment, the rotating, analog light mask 4 formed by a rotating, masked Lichtmaskenzylinder. The light mask cylinder 4 has a peripheral surface that of the lighting unit 3 generated light for a projection optics 5 modulated by preferably reflecting the incident light.

At the in 2A In the illustrated embodiment, the projection is carried out by means of a rotating light mask radially, while in the in 2 B illustrated embodiment, the projection by means of a rotating light mask takes place axially. In a possible embodiment of the device according to the invention 1 has the rotating light mask 4 a plurality of measurement pattern segments corresponding to the number of measurement patterns of the measurement pattern sequence to be projected or projected. The rotating light mask or the rotating, analog light modulator 4 may comprise a number of measurement pattern segments corresponding to the number of patterns of the measurement pattern sequence to be projected. The optical modulation or structuring of the individual segments is preferably designed in such a way that over each one exposure period of the camera 6 a time-varying intensity modulation takes place, which corresponds to the measurement pattern to be projected in time-integrated form. As a result of the rotation, a measurement pattern to be projected has a modulatable dimension, for example a one-dimensional sine pattern. The device according to the invention 1 thus provides one-dimensionally modulated measurement patterns for measuring the measurement object 2 ready. The modulation of the light through the different measurement pattern segments of the rotating analog light modulator 4 can be gradual or binary. The measurement pattern segments of the rotating analog light modulator 4 are configured to gradually modulate the light in one embodiment and binary in another embodiment. Advantageous production method for the light mask or the light modulator 4 , such as a chromium coating of a glass substrate, allow partially only a binary optical modulation.

The measurement pattern segments M _{i of} the rotating, analogue light mask 4 have surfaces with different optical properties for modulating the light. In one possible embodiment, the optical property is a different transmissivity, that is, the surfaces are either transparent or absorbent concerning the light. In an alternative embodiment, the optical property is a different reflectivity of the different areas, that is, the areas are either transparent or reflective. In a further embodiment of the device according to the invention 1 the areas are different in their absorption behavior with respect to the light, that is, they are either reflective or absorbing. The rotating, analog light modulator 4 thus has active and passive surfaces or partial surfaces, these active and passive partial surfaces having different optical properties for modulating the light.

In one embodiment of the device, the analog light modulator used has 4 transparent partial surfaces as active surfaces and absorbent partial surfaces as passive surfaces.

In a further embodiment of the device according to the invention 1 owns the used analog light modulator 4 transparent partial surfaces as active partial surfaces and reflective partial surfaces as passive partial surfaces.

In a further embodiment of the device according to the invention 1 indicates the used analog light modulator 4 reflecting partial surfaces as active partial surfaces and absorbing partial surfaces as passive partial surfaces.

In a possible embodiment of the device according to the invention 1 can be a binary structured analog light modulator 4 also be used for the gradual modulation of the light. This is done by integrating light during the rotation of the rotating analog light modulator 4 a gradual modulation of the light intensity I of the light performed. For example, during the rotation of the light modulator 4 generates a gradual brightness variation around a segment angle.

It corresponds to the in 2A illustrated embodiment for a respective radial position along a circumference, the desired relative brightness and the intensity I of the light the ratio of the optically active distances of a circular arc to the total distance of a circular arc. For gradual modulation of the light through a measurement pattern segment of the light mask 4 corresponds to a measurement pattern segment M _i , that on the rotating, analog light mask disk 4 is provided along a provided at a radial position r circular arc, the ratio of the light intensity I of the modulated light to a maximum light intensity I _{max of} the light the ratio of an optically active arc gap S _A to a maximum circular arc length S _{max of} the respective measurement pattern segment.

At the in 2 B For the respective axial position along the circumference of the cylinder, the desired relative brightness or intensity I of the light for gradual modulation corresponds to the ratio of active and passive paths. In a measurement pattern segment, which is located on the rotating, analog light mask cylinder along a cylindrical arc of the light mask cylinder provided at an axial position 4 is, the ratio of the light intensity I of the modulated light to a maximum light intensity I _{max of} the light preferably corresponds to the ratio of an optically active cylinder arc length S _A to a maximum cylinder arc length S _{max of} the respective measurement pattern segment.

The 3A . 3B show examples of different measurement pattern sequences, as they can be used in the inventive method.

The 3A shows a measurement pattern sequence consisting of four measurement patterns M1, M2, M3, M4. Each of the in 3A shown measurement pattern has a spatial extent in the x and y directions. For example, the extent of a measurement pattern segment Mi in the x direction is 10 mm. Other dimensions or dimensions are possible. In the 3A shown measurement pattern sequence causes a one-dimensional gradual modulation of the light.

3B shows the transformation of in shown measurement pattern sequence in a binary measurement pattern sequence. This, in contrast to the gradual measurement pattern sequence of 3A no grayscale, but still provides a gradual modulation due to the rotation of the rotating analog light modulator 4 on which the measurement pattern segments M _i are located. The measurement patterns to be projected for a method of structured illumination are generally available or readable in an orthogonal Cartesian coordinate system. In the device according to the invention 1 the one-dimensional modulation of the light takes place through measurement patterns, as in 2A shown in radial or, as in 2 B shown, in the axial direction. In the radial modulation, the measurement patterns used are preferably first transformed into a corresponding shape. This transformation process corresponds to a "winding" of the measurement pattern about a center point of the rotating disk.

4 shows the structuring of an analog light mask disc 4 , as in the embodiment according to 2A can be used. 5 shows a further embodiment of a light mask disk 4 as in the case of 2A illustrated embodiment can be used.

4 puts an analog light mask disc 4 which modulates the incident light purely binary, that is, the in 4 illustrated light mask disc 4 has no gray levels and the active faces are for example either completely opaque or completely transparent. The light mask disc 4 is circular and has a certain diameter of, for example, about 90 mm. In the 4 illustrated analog light mask disc 4 In the illustrated embodiment, there are four measurement pattern segments 7-1 . 7-2 . 7-3 . 7-4 on. The different measurement pattern segments 7-i are at the in 4 illustrated embodiment configured such that it from the lighting unit 3 modulate originating light binary. In the in 4 In the illustrated embodiment, the black areas correspond to absorbing areas and the white areas correspond to transparent areas. The measurement pattern segments 7-i are separated by transition areas where the light is not modulated. These spaces or transition areas provide in at least one angular position of the light modulator 4 a modulation-free, projected image or pattern ready to ensure a smooth transition between two measurement patterns. Furthermore, the light mask or the light modulator 4 Centering marks Z for centering the light mask or light mask disk 4 on. Furthermore, the light mask 4 Have sync markers for camera sync. The camera 6 takes the measurement pattern sequence which is on the measurement object 2 is projected on. The pattern segments 7-i the rotating, analog light mask 4 are designed so that over an exposure period of the camera 6 a temporally modified modulation of the light intensity I is caused, which corresponds in time integrated form to be projected measurement pattern of the measurement pattern sequence. For this purpose, a synchronization unit can be provided, which is a rotation of the light modulator 4 with the recording of the projected measurement pattern sequence by the camera 6 synchronized. This camera synchronization unit KS scans the on the rotating light modulator 4 attached optical synchronization marks, as in 4 are shown, preferably by means of a scanning unit. This scanning unit may have a reflected light barrier, a fork light barrier or at least one photocell.

The light mask 4 can, as in 4 optionally additionally have a placeholder for an optical calibration pattern for calibrating a projector.

5 shows an example of an analog light mask 4 in accordance with the embodiment in 4 , in which in 5 illustrated embodiment, however, the incident light is gradually modulated, that is, the light modulator 4 indicates at the in 5 illustrated embodiment on grayscale.

In the device according to the invention 1 used optical light modulator 4 becomes the one-dimensional brightness or light intensity modulation of a measurement pattern sequence to be projected by transformation or winding of a Cartesian measurement pattern into polar coordinates of a rotationally symmetrical, analog light modulator 4 reached. The direction modulated in a Cartesian pattern forms a principal direction H, where the direction of constant light intensity may be referred to as a secondary direction N. In the 3A . 3B the main direction H and the secondary direction N are shown for the different measurement patterns M _i . For those on the rotating or rotating analog light modulator 4 located measurement pattern 7-i is in the 4 . 5 also the main direction H and the secondary direction N shown. The main direction H extends in the radial direction, while the secondary direction N extends in the circumferential direction. The transformation of Cartesian measurement patterns, as in 3A . 3B are shown in the polar coordinates of the radial direction is such that along the circumferential direction, the ratio of the optical properties selected for modulation of the luminous flux corresponds to a relative value of the desired brightness or intensity I to the modulation. An average brightness or intensity of the modulated light is achieved, for example, by an equal ratio between transmission and absorption along the circumferential direction. A maximum intensity I _max or brightness of the modulated light is determined, for example, by a line or distance of the measurement pattern segment 7-i achieved, which is transparent or active in the circumferential or tangential direction exclusively.

6 shows a diagram illustrating a developed cylinder circumferential surface of a rotatable Lichtmaskenzylinders 4 as he at the in 2 B illustrated embodiment of the device according to the invention 1 can be used. How to get in 6 can detect, the analog light modulator points 4 several measurement pattern segments 7-1 . 7-2 . 7-3 . 7-4 and intermediate opaque transition areas. Furthermore, a track may be provided for a centering mark Z. Furthermore, in the in 6 illustrated embodiment, two optical brands provided for camera synchronization.

wobei K ein Proportionalitätsfaktor ist. Die maximale Kreisbogenstrecke S_max ist die Summe aus der aktiven Kreisbogenstrecke S_a und der passiven Kreisbogenstrecke S_P des jeweiligen Messmustersegmentes M_i. Wie man aus 7 erkennen kann, folgt auf eine optisch aktive, beispielsweise transparente, Strecke des jeweiligen Kreismustersegmentes eines passive, beispielsweise opake, Strecke des jeweiligen Kreismustersegmentes. Durch das Streckenlängenverhältnis kann das Licht durch den Lichtmodulator 4 aufgrund seiner Rotation graduell moduliert werden, selbst wenn die verschiedenen Strecken bzw. Streckenabschnitte S_A, S_P selbst ständig aktiv bzw. ausschließlich transparent und vollständig passiv bzw. ausschließlich opak sind, das heißt nur eine binäre Abstufung und keine graduellen Abstufungen bzw. Grauwerte aufweisen. Daher ist es möglich, auch Lichtmodulatoren 4 für eine graduelle Modulation zu verwenden, die rein binär strukturierte Teil- bzw. Mess-Mustersegmentflächen aufweisen. Diese binären optischen Lichtmodulatoren lassen sich einfacher und mit weniger Aufwand herstellen. 7 schematically shows the configuration of a rotating light mask disk 4 for the gradual modulation of light in a binary structured light modulator. How to get out 7 can recognize, is the ratio of the desired desired light intensity of the modulated light to a maximum light intensity I _{max of} the same or proportional to the ratio of an optically active circular arc length S _A to a maximum circular arc length S _{max of} the respective measurement pattern segment M _i at a specific radius or a specific radial position r of the respective circumference

where K is a proportionality factor. The maximum circular arc distance S _max is the sum of the active circular arc distance S _a and the passive circular arc distance S _{P of} the respective measurement pattern segment M _i . How to get out 7 can recognize, follows an optically active, for example, transparent, distance of the respective circular pattern segment of a passive, such as opaque, distance of the respective circular pattern segment. Due to the track length ratio, the light can pass through the light modulator 4 are gradually modulated due to its rotation, even if the different sections or sections S _A , S _P themselves are constantly active or exclusively transparent and completely passive or exclusively opaque, that is to say having only a binary gradation and no gradual gradations or gray values , Therefore, it is also possible to use light modulators 4 for a gradual modulation having purely binarized part or measurement pattern segment surfaces. These binary optical light modulators are easier and less expensive to produce.

In the in the 4 . 5 . 6 illustrated embodiments, the rotating light modulator 4 four light pattern segments 7-i on. In an alternative embodiment, the light modulators 4 a different number of sample segments, for example 8 or 16 sample segments.

In a possible embodiment of the device according to the invention 1 has this a detection unit, which is an angular position of the rotating, analog light modulator 4 detected. In one possible embodiment, this has the rotating, analog light modulator 4 a trace in which the angular position of the light modulator 4 is coded. In one possible embodiment, the detection of the angular position of the rotating analog light modulator takes place 4 by means of an incremental encoder or by means of Hall sensors. In another possible embodiment, the rotating, analog light modulator 4 another track for synchronization with the exposure intervals or exposure periods of the camera 6 on.

In a preferred embodiment of the device according to the invention 1 is the optical light modulator 4 interchangeable. In a further possible embodiment of the device according to the invention 1 this can be relative to the measured object to be measured 2 together with the camera 6 be moved to images or projections from different angles of the measurement object 2 to be able to generate. For example, the device according to the invention 1 around the measuring object to be measured 2 moved around to measure it from all sides. The device according to the invention 1 projects at least one measurement pattern sequence onto the measurement object to be measured 2 , Out of the camera 6 recorded measurement pattern sequences is in a preferred embodiment automatically a three-dimensional data model of the measurement object 2 generated. In one possible embodiment, depending on the generated three-dimensional data model of the measurement object 2 a copy of the measured object measured 2 produced by a manufacturing facility. At the measuring object 2 it may, for example, be a prototype of a product to be manufactured. In this embodiment, the measurement object is 2 a static measurement object.

The device according to the invention 1 is also suitable for measuring moving objects. For example, by means of the device according to the invention 1 a pattern projection on a moving hand of a person and the hand done by means of a camera 6 be recorded. Furthermore, by means of the device according to the invention 1 a pattern projection on a person's face to generate a 3D data model of the face. Since a person's hand position or facial expression can change relatively quickly, in a preferred embodiment, the sequential pattern projection takes place at a high rotational speed of the rotating analog light modulator 4 , That way the camera can 6 record the projected light pattern within a short period of time, within which the hand or the face is moved less than would be the case with a longer recording period. The high rotational speed of the analog light modulator 4 thus increases the accuracy of the measurement of the measurement object 2 , in particular with a movable object to be measured 2 , The various three-dimensional data models or data records of a measurement object 2 , in particular a movable measurement object, may be in a memory unit of the device 1 be stored or cached. By evaluating a sequence of three-dimensional data models of the movable measurement object 2 For example, a person's gesture or hand-displayed command may be determined and used for control purposes.

The device according to the invention 1 for sequential pattern projection for the optical Measurement of a DUT 2 is in one possible embodiment in a hand-held, three-dimensional measuring device for measuring a measurement object 2 integrated.

The optical light modulator 4 in the device according to the invention 1 can be produced in different ways. These production methods include coating, printing, etching and pasting methods. In one possible embodiment, the optical light modulator is 4 for various applications in the device according to the invention 1 interchangeable. In a possible embodiment, the device according to the invention 1 for sequential pattern projection, not just a rotating analog light modulator 4 but several rotating analog light modulators 4 of the same or different type. In a possible embodiment of the device according to the invention 1 take several cameras 6 at the same time an image of the projected measurement pattern sequence. The device according to the invention 1 is preferably integrated in a projector or in a projector device. This projector preferably has a lighting unit 3 , a rotatably mounted analog light modulator 4 and an electric motor for driving the light modulator 4 on. Furthermore, the projection device preferably contains a projection optics 5 , The projection device can contain further units, in particular a synchronization unit which controls the rotation of the light modulator 4 with the camera 6 synchronized. Furthermore, the projection device can have a detection unit which detects an angular position of the rotating analog light modulator. The projection device may be a stationary device, but also a hand-held device or a hand-held measuring device. In the projection device can also be a memory for storing or caching the generated 3D data models of the measured measurement object 2 be present, which is readable via an interface. The projection device can have its own power supply. At the camera 6 it is a digital camera. The device according to the invention 1 is suitable for the three-dimensional measurement of any objects or objects, for example, for chassis measurement in automobiles. In a preferred embodiment, the rotational frequency or rotational speed of the rotatably mounted rotating, analog light modulator 4 adjustable as a function of the application via a user interface.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 0660078 B1 [0003]
• US 6885464 B1 [0004]

Claims (21)

Contraption ( 1 ) for the sequential pattern projection for the optical measurement of a measurement object ( 2 ), wherein at least one rotating, analog light modulator ( 4 ), the light spatially and temporally modulated as a measurement pattern sequence on the measurement object to be measured ( 2 ) projected. Device according to claim 1, wherein the rotating analog light modulator ( 4 ) has a rotating, analogue light mask which is formed by a rotating light mask disk or by a rotating light mask cylinder. Apparatus according to claim 1 or 2, wherein the light is transmitted through a lighting unit ( 3 ) having a light source, in particular an LED, an arc lamp, an incandescent lamp or a laser. Apparatus according to claim 2 and 3, wherein the rotating light mask disc between the illumination unit ( 3 ) and a projection optics ( 5 ) rotates. Apparatus according to claim 4, wherein the rotating mask ( 4 ) comprises a glass sheet, a metal disk or a plastic disk. Device according to claim 2, wherein the rotating light mask cylinder ( 4 ) has a peripheral surface that that of the lighting unit ( 3 ) generated light for a projection optics ( 5 ) modulates. Device according to claims 1-6, wherein the rotating analogue light modulator ( 4 ) has a plurality of measurement pattern segments (M _i ) corresponding to the number of measurement patterns (M _i ) of the projected measurement pattern sequence. Apparatus according to claim 7, wherein the measuring pattern segments (M _i ) of the rotating, analog light modulator ( 4 ) are designed such that they modulate the light gradually or binary. Apparatus according to claim 8, wherein the measuring pattern segments of the rotating, analog light modulator ( 4 ) Have surfaces with different optical properties for modulating the light, the optical properties being transmissivity, reflectivity and absorption of the respective surface. Apparatus according to claim 8 and 9, wherein by integration of light during a rotational movement of the rotating, analog light modulator ( 4 ) a gradual modulation of the light intensity of the light takes place. Apparatus according to claim 10, wherein for gradually modulating the light through a measuring pattern segment (M _i ) located at a circular arc provided at the light mask disk at a radial position (r), the ratio of the light intensity (I) of the modulated one Light to a maximum light intensity (I _max ) of the light is proportional to the ratio of an optically active circular arc distance (S _a ) to a circular arc distance of the respective Meßmustersegmentes (M _i ), which is the sum of an active arc gap and a passive circular arc distance of the respective Meßmustersegmentes (M _i ) is. Apparatus according to claim 10, wherein for the gradual modulation of the light through a measuring pattern segment (M _i ) which is located at an axial position cylinder arc of the Lichtmaskenzylinders, the ratio of the light intensity (I) of the modulated light to a maximum light intensity (I _max ) of the light is proportional to the ratio of an optically active cylinder arc length (S _a ) to a maximum cylinder arc length (S _max ) of the respective measurement pattern segment (M _i ). Device according to claims 1-12, wherein at least one camera ( 6 ) is provided, which the on the measuring object ( 2 ) receives projected measurement pattern sequence. Apparatus according to claim 12, wherein the measurement pattern segments of the rotating analog light modulator ( 4 ) are designed such that over an exposure period of the camera ( 6 ), a temporally modified modulation of the light intensity is produced, which corresponds in time-integrated form to the measurement pattern of the measurement pattern sequence to be projected. Device according to claims 1-14, wherein a synchronization unit is provided, which is a rotation of the light modulator ( 4 ) with the recording of the projected measurement pattern sequence by the camera ( 6 ) synchronized; wherein the synchronization unit comprises optical synchronization marks located on the rotating analog light modulator ( 4 ) are scanned by means of a scanning unit having a reflected light barrier, a fork light barrier or at least one photocell. Device according to claims 1-15, wherein the rotating analogue light modulator ( 4 ) has a centering mark (Z), a plurality of optical synchronization marks, a plurality of optical measurement pattern segments (Mi) and transition regions between the optical measurement pattern segments (M _i ), wherein the light is not modulated in the transition regions. Device according to claims 1-16, wherein a detection unit is provided, which detects an angular position of the rotating, analog light modulator ( 4 ) detected. Apparatus according to claim 17, wherein the rotating analogue light modulator ( 4 ) another track for synchronization with exposure periods of the camera ( 6 ) having. Method for carrying out a sequential pattern projection for the optical measurement of a measurement object ( 2 ), whereby by means of a rotating, analog light modulator ( 4 ) Light spatially and temporally modulated as a measurement pattern on the measurement object to be measured ( 2 ) is projected. Measuring device for measuring a measuring object ( 2 ), which is a device ( 1 ) according to claims 1-18. Use of the measuring device according to claim 20 for measuring a movable or immovable object to be measured ( 2 ).

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