DE3119823A1 - Method and device for compensating geometrical distortion errors in optical imaging systems - Google Patents

Abstract

In order to correct geometrical distortions in an optical imaging system, a deformable mirror (2) is inserted between the object plane (O) and the aperture stop (EP), whose surface inclination can be varied locally by a multiplicity of actuators (23) that can be operated independently of one another. The distortion correction is intended, in particular, for optoelectronic imaging systems, in order to correct distortions which are produced in the optoelectronic interfaces (image-converter tubes, monitors). <IMAGE>

Description

Method and device for compensating geometric distortion errors in optical imaging systems The invention relates to a method for compensation geometric distortion error in optical imaging systems and a device to carry out the procedure.

Distortion is understood to be an imaging error in optical systems, in which the image scale is different for different points in the image field Has values; well-known phenomena of this error are the barrel-shaped or pincushion distortion. These errors can be purely optical when carefully constructed Systems, e.g. B. with aerial photography lenses, reduced to negligible values will. The situation is different with optical-electronic systems in which an optical image with image converter devices (e.g. television cameras) and / or Playback monitors is broadcast; at these optical-electronic interfaces distortion errors are introduced, which are also of the order of magnitude in good systems 1% of the image height.

This value is intolerable for many applications where there is an urgent need Need for the use of optical-electronic image processing devices consists. Examples include: Recording of an "electronic" image with a television camera and evaluation of this image using electronic methods, z. B. for length or area measurement in process automation facilities; Subtraction of two electronically recorded images to examine for image differences, for example two recorded at a time interval X-rays of a patient; Addition of two images by electronic overlay, z. B. a measurement image and a reference grid; Recursive image processing in which a Image signal cyclically through an optoelectronic recording and playback system is sent.

To correct the distortion error in such opto-electronic Systems have so far mainly been investigated digital and electronic processes. With digital correction, the electronic image is digitized, the distortion measured and corrected using suitable algorithms. With the electronic Correction, high-precision deflection systems are used for image converter tubes and monitors, which also automatically correspond to the respective distortion error present are electronically correctable. However, all of these procedures require a great deal of effort high effort; the digital correction is also very time-consuming.

The object of the present invention is therefore to provide a method and to specify a device for correcting the geometric distortion error, which are particularly suitable for optical-electronic imaging systems and with simple means can be realized.

This object is characterized by that in claims 1 and 6 Invention solved; Refinements of the invention are characterized in the subclaims.

According to the teaching of the invention, a locally deformable mirror is used between the object to be imaged and the entrance pill of the imaging system built into the beam path and deformed in such a way that those arising in the imaging system Distortion errors are just being compensated.

The use of deformable mirrors to correct aberrations is a technique known from so-called "adaptive optics"; Details of this Technology are, for example, in issue 3 of the Journal of the Optical Society of America, Hand 67, 1977. In the case of institutions proposed there, the deformable mirror arranged in the aperture of the imaging system and can therefore can only be used for the use of spatially invariant imaging errors. Such Errors occur, for example, in the astronomical image due to the turbulent one Atmosphere and make sicE1 noticeable as a blurring of the entire picture. To the These systems can correct veto distortion errors as required here adaptive optics cannot be used, as the image to be corrected is ideally sharp, but is depicted in a distorted manner and therefore a local correction (location-variant) is made got to.

With the method proposed here, it is possible to eliminate distortion errors improve by an order of magnitude from around 2% of the image height (0.2%); at a The corrected distortion then corresponds to a screen of 500 x 500 pixels just a maximum of one image element and no longer interferes with image processing in development. The process works its optical, requires an Ehr @@ - fingen Effort, can be used and made possible for coherent and incoherent images also a simple and, if necessary, real-time correction to be carried out the distortion. The method can also be used for purely uptic systems, their optical components not with the highest possible precision for cost reasons can be executed.

An embodiment of the invention will now be based on drawings explained in more detail; The figures show: FIG. 1A the basic structure and the imaging beam path a device for compensating for distortion errors, FIG. 1B shows the beam path 1A in the unfolded state, FIG. 2 shows an adjustable element of the deformable Mirror.

In FIG. 1A, an object (here an arrow cross) is supposed to be in an object plane 0 can be mapped onto the image plane B in a television camera 4. The sampled Electronic image can then be fed to further devices for image processing be e.g. B. for electronic image evaluation or for display on a monitor. Distortion errors occur when scanning the image plane B, as well as in later ones optical-electronic interfaces (e.g. monitors).

To correct this distortion error are in the beam path a first deformable mirror 2 between the object plane 0 and the camera 4 and a second flat mirror 3 installed, preferably at an angle 450 to the optical axis. The deformable mirror 2 consists of an elastic, provided with a reflective coating thin plate 22, the local surface inclination (Gradient) by a plurality of individual actuators 23a, 23b, ... varied can be. The actuators are arranged on a base plate 21, for example in an 8 x 10 matrix. The distance between object plane 0 and the deformable mirror is denoted by l1, the distance between the deformable and flat mirror with Q2 and its distance from the lens 5 of the television camera 4 with In 1A is the area of mirror 2 and the mirror 3 chosen so large that not this, but the diaphragm of the television camera 4 as an aperture stop or entrance pupil EP acts. The imaging cone defined by this aperture stop G is shown in FIG. 1A for a point on the optical axis. To reduce of aberrations caused by the interposition of the deformable mirror 2 arise, this water is preferred in the vicinity of the object level 0 and in large Distance from the effective aperture stop arranged. The one to the mirror 2 honlpklnare Mirror 3 IllaC} at- reverses the mirror inversion that occurs at mirror 2; disturbs if this is not the case, mirror 3 can be omitted.

To compensate for the distortion errors occurring in camera 4 the actuators 23 are adjusted individually so that at the output of the camera 4 results in a distortion-free electronic image. To simplify the adjustment is expediently the output signal generated by camera 4 with the electronic Equivalent of the test image in object level 0 compared (e.g. by.

Subtraction). The calibration process can be configured accordingly of the actuators 23 also take place in a closed control loop, the Output signal of the television camera 4 is supplied. big. 1B shows the effects of the deformable mirror 2 on the optical image. The beam path in Fig. 1B was unfolded on the two mirror surfaces 2 and 3 in order to clarify the representation simplify. The distance between the object and the deformable mirror is as in 1A denotes the distance between the deformable mirror S and the aperture plane EP with Q, where Q = l2 + l3.

If the (flat) mirror 2 is not deformed, an object point 01 is imaged into an image point B1 through the lens 5 of the television camera. In the imaging system under consideration, the camera diaphragm is the effective aperture diaphragm which, in FIG. 1B, is assumed to coincide with the mount of the lens 5 and has the diameter A. On the mirror plane S, the imaging bundle for the object point 01 has the diameter a, where: l1 a =. A (1) l1 + l If the corresponding mirror element with diameter a is tilted by a (small) angle f / 2, a virtual object point 01 'results, which is shifted by the distance #x = l1 # # (2) and a pixel B1 'is generated, which is also shifted with respect to the original pixel B1. The angle of view of this new point B1 'has changed from the original by the amount Aw = Ax (3) (+ £). The order of magnitude of the displacement of the image point B1 'required for distortion compensation can be determined from the requirement that a maximum of two percent distortion should be corrected. The total angle of view of a television camera with a photosensitive surface of diameter d and a focal length f of the taking lens 5 is d Wmax = f (4) The combination of equations (2) and (3) results in the maximum required deformation of the mirror surface Al ' max the expression 0.002 d l1 + l ## max = # (5) f l1 In a practically implemented imaging system, for example, the following values resulted: d = 1 2 mm f = 50 mm -2 41 = 1000 mm t from this it follows that Q '10 Q = 1000 mm The required deformations of the mirror surface are therefore small and lie within the limits of elastic deformations of thin glass plates, metal plates or plastic panes, which can be achieved without great forces.

The following considerations are used to determine the optimal location of the mirror in relation to object plane 0 and television camera. It's the two of them here To distinguish borderline cases in which the deformable mirror once close to the camera (l1 >> l) and once close to the object plane (l1 << l) is. In the first case, ## max (1) = 0.02. d / f (6) For the second case (l1 << l), on the other hand, is ## max (2) >> ## max (1) (7) The required mirror deformations are therefore small if the mirror is close to the camera (i.e. the effective one Aperture diaphragm) and become larger with increasing distance from it. On the on the other side result from an arrangement of the deformable mirror in the Significant aberrations in the vicinity of the aperture diaphragm. To such Image errors To keep it small, the line shown in Fig.

1A drawn in mirror surface a, which is for the imaging cone 10 of the object point 01 is effective, the same deformation everywhere have a benaciabartes Abbi @ dungsbünde 1 11, that of a bell-adjacent mirror ment is reflected with different but constant deformations thus only become effective for an object point 02 which is a distance x min from the first Has object point 01. In the case of the illustration, therefore, in areas that correspond to the subject area x min, no changes in the distortion occur, i.e. H. the distortion must be a soft function of the place.

In order to keep the size x min small, the distance l1 must be between the object plane and deformable mirror S be small compared to the distance of the mirror from the aperture stop (l1 l). This requirement contradicts equation (6), which must be fulfilled if large distortions are to be corrected with small deformations.

In practice, the distance l1 will be chosen to be so large that straight No imaging errors occur yet, but the distortion is in the desired area is corrected. In any case, the imaging system must ensure that that the aperture A is small enough.

The tolerance allowed here results from the imaging quality of the Television system: Wave aberration is generated by the deformed mirror. The resulting imaging errors should be smaller than the imaging errors of the Fernschsystem. If one develops the mirror surface in a power series, then the linear term corresponds to the G @@ services, i.e. H. the desired tilt. That quadratic term results in (undesired) defocusing, etc. The non-linear Portions can be reduced by stopping down.

For the qualitative understanding of the location-variant distortion correction it should be noted that in the arrangement of the deformable mirror between the object and aperture the main rays emanating from different object points from different points of the mirror are reflected.

With the device for distortion correction proposed here distortion fields that do not contain any rotation components can be corrected; Rotation-like distortions can, however, be achieved without difficulty by a dreloung correct the receiver around the optical axis.

Other types of distortion that are also not rotation-free, z. B. Orthogonality errors are generally minor or may be otherwise (e.g. electronically) corrected.

Fig. 2 shows a section of the deformable mirror with actuators 23a, 23b, which are anchored in a carrier plate 21, and the deformable mirror 22 hold. In the illustrated embodiment, the actuators are screws 24, which engage in eyelets 25; the mirror is glued to the eyelets. For backlash-free storage, there are 25 spiral springs between the carrier plate 21 and the eyelets 26 attached. With a total size of about 20 x 15 cm of the mirror surface 8 x 10 actuators 23 are attached in the carrier plate 21 in a matrix-like arrangement.

The small deformations required to correct the distortion the mirror surface also make it possible, instead of the mechanical ones described above To use actuators of other variants, for example piezoelectric, electrostatic, inductive or pneumatic links.

In the case of partial consideration, the deformable and the flat Mirror arranged coplanar and at the same angle (e.g. 45 °) to the optical axis. However, different arrangements of coplanar mirrors are also possible, e.g. 103. if perspective-like distortions have to be compensated (according to Scheimpflug rectification in photography).

Claims (9)

P A T E N T A N S P R Ü C H E 1. Procedure for correcting geometrical Distortion errors in optical imaging systems, characterized in that A mirror in the imaging beam path between the object (0) and the aperture diaphragm (P) (2) is attached, the surface of which corresponds to the distortions to be corrected is locally deformed. 2. The method according to claim 1, characterized in that the deformable Mirror (2) is attached at a distance from the aperture diaphragm (EP) which is large is compared to the distance of the deformable mirror (2) full of the object plane (O). 3. The method according to any one of claims 1 or 2, characterized in that that between the deformable mirror (2) and the aperture diaphragm (EP) is a flat mirror (3) is attached in a coplanar arrangement to the deformable mirror (2). 4. The method according to claim 3, characterized in that the two Mirror (2, 3) arranged at the same angle (z. B. 45 °) to the optical axis will. Method according to claim 3, characterized in that the two Mirrors (2, 3) are arranged at different angles to the optical axis. 6. Device for performing the method according to one of the claims 1 to 5, characterized in that under a deformable mirror surface (22) a matrix-shaped arrangement of actuators (23) is provided. 7. Device according to claim 6, characterized in that as deformable Mirror surface (22) a plastic film with reflective support is provided. 8. Device according to one of claims 6 or 7, characterized in that that as actuators (23) mechanically operated threaded screws (24) in a base plate (21) used in threaded sleeves (25) on the back of the deformable Engage the mirror surface (22) and tighten by twisting (26) between the threaded sleeve (25) and support plate (21) are kept free of play. 9. Device ndc one of claims 6 to 8, characterized by their use in an optoelectronic imaging system.