DE4027328A1 - Stereo camera for surface structure esp. of teeth - projects two beams from equal and opposite angles for illumination of surface monitored by image sensor - Google Patents

Abstract

Light from two LEDs or other sources (18) is projected by prisms (21) through slots (22,23) in a screen (24), and focused by lenses (L3,L4) on to the surface of a tooth (15). Linear reference patterns are generated by liq. crystal devices or gratings (19,20) in respective beams (13,14). Central rays (25,26) enclose an acute angle (beta) bisected by the optical axis (27) along which a reflected ray passes through a third slot in the screen (24) to a frame transfer CCD image sensor (17). ADVANTAGE - All details of surface structure can be represented and measured with two beams projected from different directions.

Description

From US-PS 45 75 805 a 3D camera is known with which a surface structure of a subject can be detected with respect to differences in height or depth. This known 3D camera has a projection and an observation beam path, which take an angle to an optical axis of the 3D camera. A light source for emitting a light beam in the direction of a recording object is arranged in the projection beam path. The light reflected from the object is directed through the observation beam to an image sensor of the 3D camera. The signals of the image sensor can be fed to an evaluation unit, so that an image of the surface structure can be created on a display device. This 3-D camera is particularly suitable for detecting a cavity of a tooth.

Such a 3D camera is also known from EP-02 50 993 A 2 .

To determine the height and depth differences of the upper surface structure are means of generating a reference pattern provided such that the reference pattern on the surfaces structure is projectable. Based on the surface structure reflected light that strikes the image sensor and in connection with evaluation electronics for execution one explained in more detail in the documents mentioned above, with "phase-shifting triangulation" method, can the surface structure in terms of height or depth Differences calculated and on a monitor as a pseudo three dimensional image.  

Shiny spots with an unfavorable surface structure surface measurement structure impossible at this point, because it is very reflective tated light to overdrive the image converter in one Area where this light strikes. You can also Object surfaces whose normal is perpendicular to the optical axis of the Projection and observation beam path are aligned, cannot be detected because they are in the optical shadow. Also Artefacts result from edges in the 3D measurement data the one-sided lighting result.

The object of the invention is therefore a 3D camera of the beginning mentioned type so that the surface structure of a Recording object well represented in all details and he is graspable. So it should be a correct measurement of the waiter surface structure are made possible.

According to the invention, the object is achieved by a 3D camera setting of surface structures, especially for dental medi interest purposes, by means of which a first and a second beam of light can be generated, the first Beams of light over a first projection beam path from a first direction and the second light beam via a second projection beam path from a second Direction towards a recording object is steerable and with a Observation beam path that receives an image sensor of the light reflected by the subject, solved.

A major advantage of the invention is that two projects tion beam paths are provided so that a subject can be illuminated from different directions. All Details of the structure of the surface of the subject are therefore well and clearly representable and thus detectable.

To measure the surface structure of the subject  it is advantageous if means for generating a reference pattern are provided in at least one projection beam are switchable, such that the reference pattern on the Surface structure is projectable.

Is provided by the means for generating a reference pattern preferably a grid is projected onto the surface structure, so the accuracy of capturing a structural area depends and the height information of the structure area from the grid period of the grid. With a given grid period can only a certain height range of the surface structure be clearly recorded. It is therefore advantageous if the Means for generating a reference pattern are designed that different reference patterns on the surface structure are projectable. This will make the size of the uniqueness area, d. H. the area where the height of a structure can be clearly determined, significantly increased. In particular the cavity of a tooth can be detected particularly precisely, so that a restoration body can be created that is optimal, d. H. into the cavity with the smallest gap size fits. This can be done in particular for each projection beam a means for generating a reference pattern is provided be.

A particularly fast image construction can be achieved if the image sensor is designed as a frame transfer CCD converter.

A particularly compact structure of the 3D camera is achieved if the first and the second projection beam path the take the same angle to a central axis through the Bisector of the angle defined by the project beam paths to each other. Here is the Observation beam path preferably parallel to or on the Center axis aligned. In this embodiment the 3D Camera can optimally compensate for optical aberrations will.

A beam path of a 3D camera according to the prior art and on the basis of FIG

Fig explained. 2 and 3 according to the invention.

Fig. 4 is used for explanation.

Fig. 1 shows a basic illustration of a light source 1 for emitting a light beam, which is steerable via a projection beam path 2 to a recording object 3 . The light path leads here via optical lens systems L 1 , L 3 and L 4 , a ver adjustable in the projection beam path 2 grating 4 for generating a linear reference pattern, a prism 5 and a first opening 6 of a two-hole aperture 7th The light reflected by the object 3 can be directed through an observation beam path 8 to an image sensor 9 . In the observation beam path 8, a prism 10, the optical lens system L 3, L 4, and the two-hole aperture 7 are arranged, wherein the light path of the light reflected by the recording object 3 light lead through a second opening 11 of the two-hole aperture. 7 The prisms 5 , 10 are used to divide the light beam of the projection and observation beam path 2 , 8 and are so directed that the projection beam path 2 and the observation beam path 8 form an angle alpha to one another. An optical axis 12 of this arrangement is defined by the angle bisecting the angle alpha. The surface structure of the recording object 3 is thus both representable and calculable by the "phase shifting triangulation" method.

A basic beam path of a 3D camera according to the inven tion is shown in FIG. 2 as an embodiment.

This exemplary embodiment is characterized and in contrast to the prior art by a first and second projection beam path 13 , 14 for guiding a light beam that can be generated from different directions to a recording object 15 . The light reflected by the recording object 15 can be directed to an image sensor 17 via an observation beam path 16 . The output signals of the image sensor 17 are fed to a computing device known from the prior art for providing an image of the surface structure of the recording object 15 .

In the exemplary embodiment, each projection beam path 13 , 14 has means 18 for generating the light beam, which consist, for example, of an LED in conjunction with an optical system. Of course, only a single means 18 for generating a light beam can also be provided, in which case the light beam can then be steered either into one or the other projection beam path 13 , 14 via a deflection element (not shown). In the first and two th projection beam path 13 , 14 , optical elements (not shown in more detail), for example optical lens systems L 1 to L 4 , can be arranged for directing the light beam if this is necessary.

A means for generating a reference pattern is provided in the light path of each projection beam path 13 , 14 , which is designed, for example, as an LCD arrangement or as a grating 19 , 20 for generating a line pattern. Through a prism 21 , which is also provided in the light path of each projection beam path 13 , 14 , the light beam of the first projection beam path 13 through a first opening 22 and the light beam of the second projection beam path 14 through a second opening 23 of a three-hole aperture 24 from different directions On the object 15 steered. The central beam of the light beam of the first projection beam path 13 should be identified by the reference symbol 25 and the central beam of the light beam of the second projection beam path 14 should be identified by the reference symbol 26 . It is shown that the central rays 25 , 26 of the light beams are at an angle beta to one another. The bisector of the angle beta defines an optical axis 27 of this arrangement. In the exemplary embodiment, the central beam of the observation beam path 16 is congruent with the optical axis 27 .

The light beam of the first or second projection beam path 13 , 14 can optionally be used to illuminate the surface structure of the recording object 15 . Of course, both light beams can be directed simultaneously bunch at the subject 15th As a result, the surface structure of the recording object 15 is illuminated particularly well, so that details and details can be represented well.

A frame transfer CCD image sensor can be used particularly advantageously to detect the differences in height and depth and to provide an image of the surface structure of the recording object 15 . These image sensors are used in field operation (even and odd frames), the entire sensor area, which is formed by individual photocells, being active during a field. Two fields differ from one another in half a photo cell due to an offset in the column direction of the image sensor. Such image sensors have a good signal / noise ratio, a good resolution and the signals from the photocells can be read out quickly.

During the measuring phase, the means 18 for generating the light beam of the first and second projection beam paths 13 , 14 are alternately switched on and the respective grating 19 , 20 is moved continuously by one grating period. A lower susceptibility to interference can he be sufficient that only the grating 19 or 20 is adjusted, which is arranged in the projection beam path 13 or 14 , the means 18 for generating the light beam is activated, while the other grating 19 or 20 is stationary . Here, for example, the object 15 reflected by the recording object of the light beam of the first projection beam path 13 from the even frame and the object 15 reflected by the light beam of the second projection beam path 14 from the odd frame of the image sensor 17 is detected. During the readout phase of the signals of the image sensor 17 , the means 18 for generating the light beam are inactive, ie, no light beam is transmitted. Four fields are thus created, from which a separate “height image” (even height image and odd height image) of the surface structure of the recording object 15 can be calculated and created using the “phase shifting triangulation” method known from the prior art .

With the height images calculated in this way, the entire object area can be covered, ie the entire surface structure can be detected. Shadow areas and glossy areas that lead to overriding an area of the image sensor 17 in one elevation image can be detected by the other elevation image.

Preferably, the grids 19 , 20 generate line patterns with different grating periods. As a result, since the conversion factor depends on the phase measured in height information on the grid period, the grid period also determining the uniqueness range that the height difference between two object points when using the first grid with a first grid period is calculated in the calculation from, for example, the even height image does not differ, it differs when using the second grating with a second grating period in the calculation from, for example, the odd height image by the percentage difference of the two grating periods. With the help of the even and the odd elevation image, the height difference can be clearly measured beyond the area of clarity of an elevation image. The multiplication of the area of clarity is reciprocal to the percentage difference of the respective grid periods. For example, if the grid periods differ by 20%, the uniqueness range is increased by a factor of 5. For an explanation, reference is made to FIG. 4. The height difference between two object points is identified with the reference symbol h. Because of the measurement and calculation method, only the area a ₁ can be uniquely detected with a first grating g ₁ with a grating period x. For areas a ₂ to a ₄ , the values that were already determined for area a _{1 are} repeated. With a grating g ₂ with a grating period y that is greater than x, the range b ₁ can be detected unambiguously, however, with less precision. For areas b ₂ to b ₃ again the values are obtained which have already been determined in area b ₁ . Due to the fact that the area a _{2 is assigned} a certain value range c ₁ from the values of b, the area a ₃ another value range c ₂ from b and the area a ₄ another value range c ₃ from b, by means of this the Grid g ₁ , g ₂ the total height difference h can be detected.

This goal can also be achieved analogously if the grids g ₁ , g ₂ are selected the same, but, as shown in FIG. 3, the central beam 25 of the first projection beam path 13 has a first angle gamma ₁ and the central beam 26 of the second projection beam path 14 a second angle gamma ₂ , which is different from the angle gamma ₁ , to the optical axis 27 . The parallax angles of the projection beam paths 13 , 14 are therefore chosen differently. Otherwise, elements which have already been explained in FIG. 2 have the same reference symbols in FIG. 3.

According to the invention, it is also possible to optimally match the observation beam path, for example, only to the first projection beam path 13 . The second projection beam path 14 is activated when object areas, for example due to glossy areas or shadow areas, cannot be detected by the first projection beam path 13 .

According to the invention, it is possible to use an LCD arrangement Generation of a reference pattern in only one projection arrange beam path. With this LCD arrangement you can Generated reference patterns with different grating periods will. Then this projection beam path is used for the first the elevation of an object structure, the other Projection beam path can be used for illustration, for example the surface structure can be activated.

In a further exemplary embodiment, in a project tion beam path a first static grating with a first Lattice period and another, in this projection rays adjustable grating with a different grating period to be ordered. Through the process of "static" and the "phase shifting triangulation" can be a big difference in altitude two object points can be clearly recorded.

Furthermore, the light beam of the projection beam paths 13 , 14 can also be guided by an optical fiber to the receiving object 15 . The bundle of light rays can then be coupled in, for example, after the gratings 19 , 20 by suitable means into the respective optical fiber of the first or second projection beam path 13 , 14 . The prisms 21 , 22 , the three-hole aperture 24 and the optical lens system L 3 can thus be dispensed with.

Claims (8)

1. 3D camera for recording surface structures, in particular for dental purposes,
with means ( 18 ) through which a first and a second light beam can be generated, the first light beam del via a first projection beam path ( 13 ) from a first direction and the second light beam via a second projection beam path ( 14 ) from a second direction a recording object ( 15 ) is steerable, and
With an observation beam path ( 16 ) which has an image sensor ( 17 ) for receiving the light reflected by the object ( 15 ). 2. 3D camera according to claim 1 with means ( 19 , 20 ) for generating a reference pattern, which can be switched in at least one projection beam path ( 13 , 14 ), such that the reference pattern can be projected onto the object ( 15 ). 3. 3D camera according to claim 1 or 2, wherein the means ( 19 , 20 ) for generating a reference pattern are designed so that different reference patterns can be projected onto the object ( 15 ). 4. 3D camera according to one of claims 1 to 3, wherein for each projection beam path ( 13 , 14 ) a means ( 19 , 20 ) is provided for generating a reference pattern. 5. 3D camera according to one of claims 1 to 4, wherein the image sensor ( 17 ) is designed as a frame transfer CCD. 6. 3D camera according to one of claims 1 to 5, wherein the first and the second projection beam path ( 13 , 14 ) take the same angle to a central axis ( 27 ), which is defined by the bisector of the angle that the projection beam paths ( 13 , 14 ) to each other. 7. 3D camera according to claim 1, 2 and 4, 5, wherein both projection beam paths ( 13 , 14 ) form a slightly different angle to the observation beam path ( 16 ). 8. 3D camera according to one of claims 1 to 7, wherein the observation beam path ( 16 ) is aligned with the central axis ( 27 ).