DE1572823C3 - Optical aperture - Google Patents

Description

The invention relates to an optical diaphragm for an image of a format with a first relative long and a second narrow extension perpendicular to it by means of a lens in an image plane.

Most lenses used for imaging purposes have significant spherical aberrations for light rays incident at an angle, which significantly reduces the contrast of the image. Since that Tangent image is much worse than the image in the plane of the direction perpendicular to the tangent image, im Also called the sagittal direction in the following, vignetting is used to improve the tangent image However, this reduces the illumination of the image field, and although for many imaging and recording purposes as little as 25 to 30% relative illumination is required in some In some cases, strong lighting is also necessary, for example in the case of insensitive image recording surfaces, that require strong exposure. In these cases, any loss of brightness has a critical effect.

In order to obtain a sharp image together with high relative illumination, the spherical aberration Getting corrected. If the spherical aberration of a lens is corrected, im

in general, the tangent image is more improved than the sagittal image. The sagittal error becomes zero is reduced, the tangent image is usually overcompensated. Since the manufacturing costs with the

Degree of correction of spherical aberration increase, the correction is normally only driven so far that the tangential spherical Aberration is generally optimally compensated, while a certain residual sagittal deviation is still present is.

The present invention is based on the object of improving the spherical Aberration in the case of oblique incidence of light causes imaging errors with high image illumination at the same time and at low cost.

This object is achieved according to the invention with an optical diaphragm of the type mentioned at the beginning a first panel section with a length in the direction of the long dimension of the format to be imaged fenden edge, which is arranged near the lens substantially perpendicular to the optical axis is, and by a second diaphragm section with one in the direction of the long extension of the to be imaged Format extending edge in the same plane perpendicular to the optical axis as the first Aperture portion, but is arranged on the opposite side with respect to the optical axis.

The invention ensures that the passage is offset from the tangential plane Sagittal ray of the object on the image plane is prevented, while the tangential rays between the first and second diaphragm sections pass through the diaphragm and an illumination of the Image plane with reduction of spherical aberrations and astigmatism by outside the Sagittal rays running optical axis is guaranteed. Besides the advantage of a good correction of the spherical aberration will simultaneously increase the image illumination compared to the previously comparable Image illumination achieved. Furthermore, these advantages can be achieved with extremely cheap means, namely only can be achieved by the appropriate choice of aperture.

The invention can be used both in photographic lenses and in any imaging system, where lenses are used. A particularly good correction of the spherical Aberration is achieved when the diaphragm according to the invention in conjunction with a Lens is used whose tangential spherical aberration is already optimally compensated.

In the following, the invention will be described in more detail with reference to preferred exemplary embodiments shown in the drawing explained. Show in the drawing

1 shows the perspective illustration of the beam path from a point light source through the lens arrangement provided with a central diaphragm;

Fi g. 2 the perspective view of the beam path from the point light source through a sagittal diaphragm and a lens system that is connected to a central aperture is provided;

3 shows the front view of a sagittal diaphragm for Limitation of the illumination in the image plane;

F i g. 4 shows the front view of another embodiment of a sagittal diaphragm and a lens and

F i g. 5 shows the front view of another exemplary embodiment of a sagittal diaphragm, which via the optical Axis of a lens system can be moved.

The aperture to reduce the sagittal image by controlling part of the sagittal rays, which act on the image plane is referred to below as a sagittal diaphragm

In Fig. 1, a lens system is shown, which consists of a first objective lens 10 and a second objective lens 12, the light rays in a Focus on the image plane. Between the two lenses 10 and 12, an inner diaphragm 14 is provided, the Opening 15 delimiting the beam path for controlling the beam guided by the system onto the image plane The light beam 13 is shown from the object point 16 outside the central optical axis 18. This light beam is guided through the diaphragm 15 and onto the image point 20 focused

On the lenses 10 and 12 are the tangential axis 22 and the sagittal axis 24 for the given Shown object point they lie on the front and back surface of each lens. It should be noted that as a result of the dispersion of the light rays emanating from an object from the area of the optical axis the image generated with these rays in an objective lens system has stronger aberrations and the like. through Astigmatism and spherical aberration is exposed than those near the central axis or the Light rays running in a tangential plane. Therefore, many rays of light run above and below the Tangential plane of the lens system and meet in reality not in the point 20, but in one from this different point, but close to it, although in FIG. 1 only the Image point 20 is shown. This phenomenon caused by aberrations in the lens system is caused a blurred representation of the image point 20, which therefore does not appear as a single point. This is the resolution and contrast of the multi-dot image deteriorates.

To reduce the aberrations, especially the oblique spherical aberration, which cause the loss Cause dissolution, is in the case of FIG. The arrangement shown in FIG. 2 does not significantly affect the light intensity reducing sagittal diaphragm is used. This method of reducing the aberrations is thereby It is advantageous that, in contrast to other methods, there are no expensive lens systems or smaller aperture openings must be used with reduced light intensity. Becomes a large one in an optical system Light intensity is required, so the oblique spherical aberration is reduced by small diaphragms undesirable while on the other hand the production of expensive lenses because of the costs involved Difficult to Carry Out The present invention resides in an inexpensive, easy to manufacture arrangement to reduce the oblique spherical aberration without significantly reducing the Light intensity or the additional requirement of expensive equipment for the lens system. The sagittal diaphragm can be machine made or stamped from cheap fabrics.

The light beam emanating from an object point 16 is generated by a system as shown in FIG. 1 shown Art that with a sagittal diaphragm 26 in F i g. 2 is passed through. It should be noted that the beam in Direction of the sagittal axis 24 is masked, while it is not in the direction of the tangential axis 22 is impaired, whereby a maximum light intensity is ensured while undesirable aberrations due to the shielded object rays 27 in the Sagittal direction can be reduced. The sagittal diaphragm itself is shown in the form of two parallel edges, that of the central axis 18 of the optical system

equidistant and in the direction of the axis 18 consist of an opaque material. The edges don't have to be parallel or symmetrical run and need not have the same distance from the optical axis. The illustrated case 5 serves only as an example of a preferred embodiment.

The light from the object point 16 can only be between the edges 28 and 30 of the sagittal diaphragm step through. It should be noted that the sagittal diaphragm can be provided between the object and the lens system can, as shown in Fig.2, or it is located between the lenses or between the lens system and the image, the result being the same image in each case

These various embodiments will be at the same i _S if particularly as the beam 32 shown in Figure 2 covered by the basic idea, only the effective light beam from the point light source 16 of the existing by from Sagittalblende, aperture and lens system is to its Figure 20, Gelei - is ao tet.

In Figure 3, another embodiment of a sagittal diaphragm is shown, which not only to reduce the oblique spherical aberration and the Astigmatism is used, but also the relative illumination of the image plane of the optical system influenced. Because of the shape of the in FIG. 3 illustrated sagittal diaphragm is the illumination of the image plane in Center stronger than on the edges. This can be beneficial for slide projectors in which the projected image surrounding background is dark as the human eye has a gradual increase in Illumination within the field of view feels more favorable than a drastic difference to the Edges of the projection image which, when the edges are illuminated, have the same strength as the central part would occur. The in F i g. 3 illustrated sagittal diaphragm is fastened within a frame 40 and consists made up of two opaque parts 42 and 44, each with a coincidentally shaped curved Edge are provided which have the same distance from the center line of the frame 40. It is a flat surface 41 made of transparent fabric such as e.g. B. glass provided, which better support the Arrangement within the frame 40 enables the edge 46 of the panel part 42 and the edge 48 of the Aperture parts 44 are similarly bent so that the greatest distance between them in the geometric center of the device and the smallest Distance is present at their circumference

Another embodiment of a sagittal diaphragm is shown in FIG and 56 which are equidistant from the tangential axis 52 of the lens. The shape of the diaphragm or of the opaque parts 54 and 56 is anchor-shaped as seen from the front of the lens 50. In this way, uniform illumination of the image surface of a uniformly illuminated object is achieved in that the normally brighter center is attenuated in ^{relation to the edges of an image of a uniformly illuminated object in accordance with the known cos 4 law.}

The sagittal diaphragm has the advantage over the known aperture diaphragms that it is attached to each any point of the lens system can be arranged, so close to the system, between the lens elements or in the same plane as the aperture stop. The sagittal diaphragm can be designed in such a way that it brings about any desired relative illumination of the image plane of the optical system Lens system, but not arranged adjacent, acts like a field stop if the size of the Object is increased with respect to its axis. However, if a very small format is chosen and lies for example, as with facsimile devices, the field width of the order of 0.25 or 0.13 mm, the sagittal diaphragm can be arranged very close to the object or the image. The axis of the Sagittal stop usually, but not necessarily, coincides with the optical axis of the system.

Is an optical system corrected for oblique spherical aberrations in the tangential plane for a Fixed light intensity on a fixed image area adjusted so that a correct exposure and image takes place on the image surface and the relative light intensity of the system is fixed in a predetermined manner / increased, which would overexpose the image, a sagittal diaphragm can be inserted ν, which reduces the light intensity while reducing the image quality without the Requirement of a variable iris diaphragm and the associated complicated facilities and without changing the lenses improves. This advantage can also be realized for an optical system, in which two or more image areas of different sensitivities are used. Is the system is set to the lower sensitivity and then a more sensitive image plate is used, so can the additional illumination required for this by inserting a sagittal diaphragm between the Light source and the image plate are hidden. This is a change in the lens elements or a variable iris diaphragm is not required. The holding device for the lenses can have depressions or Be provided with slots so that the sagittal diaphragm is similar to that shown in FIG. 3 are attached in the manner shown can. Another application example for a sagittal diaphragm for easy control of the light intensity is a device in which two magnifications are used, with a reduction in the Image size means an increase in light intensity.

In the practical application of a sagittal diaphragm in a lens system, the lenses should be of this type be carried out that the imaging errors caused by spherical aberration are compensated as well as possible in the tangential plane, after which a Sagittal diaphragm is inserted, which the aberrations caused by spherical aberration in the Sagittal direction compensated, whereby both directions in the image plane with regard to aberrations are effectively corrected. The sagittal diaphragm not only reduces the oblique spherical aberration in Sagittal direction, but also the lateral astigmatism in the sagittal plane, i.e. H. it reduces the height of the blurred images around the main ray of the object in the sagittal plane.

In Figure 5 a special embodiment is a Sagittal diaphragm shown, which is suitable for a system in which the light intensity is to be compensated. the Edges of the parts forming the sagittal diaphragm are not parallel, so that they gradually change the Effect the face of the diaphragm in the direction of the edge length.

Therefore, by moving the sagittal diaphragm sideways over the aperture diaphragm of the lens system, the through the amount of light reaching the image can be influenced.

The side parts 70 and 72 of the sagittal diaphragm are each provided with an edge 74 and 76. the effective aperture of the system is denoted by 78 The light rays from an object to an image through the sagittal diaphragm and the effective diaphragm opening 78 are through above and below the area between the edges 74 and 76 of the sagittal diaphragm and on the sides through the circular opening the aperture stop 78 is intended to increase the amount of light conducted through the optical system the sagittal diaphragm using a suitable mechanism, that of a rack 80, a gear 81, a bidirectional motor 82 and Guide rails 84 for the correct position of the frame 86 are moved. Because of the location of the edges 74 and 76 of the diaphragm parts 70 and 72 during a movement of the sagittal diaphragm within the frame 86 the area lying between the edges 74 and 76 within the circular opening 78 becomes to the right enlarged, which also increases the amount of light transmitted. This possibility of the lateral Movement of the sagittal diaphragm to change the amount of light guided through the optical system allows the Using a simple mechanism to manipulate this amount of light in the image plane of a optical system for a given amount of input light.

In the case of the in FIG. 5 shown sagittal diaphragm must be on a certain proportion of the achieved with the invention Compensation can be dispensed with, since the image has more oblique sagittal rays on one side than on the other the other side receives what through the increasing size of the sagittal aperture formed with the two edges However, this is not critical and practical optical application will reduce the image quality in terms of automatic or minor manual change of the aperture to influence the ones directed through the optical system The amount of light does not matter.

The change in the effective diaphragm opening in the device according to FIG. 5 can be done in any way possibly also automatically to any extent either electrically or mechanically or both Species can be achieved.

It should be noted that in all of the sagittal diaphragms described, those forming the diaphragm opening Edges can be punched out, so that there is a diaphragm opening for the in the respective system Sagittal diaphragm to be used is required

For this purpose 2 sheets of drawings 709514/151

Claims (16)

Patent claims: 1. Optical aperture for an image of a format with a first relatively long and a second narrow extension perpendicular thereto by means of a lens in an image plane by a first diaphragm section (42,54) with one in the direction of the long extension of the format to be imaged running edge (46), the near the lens (z. B. 10) substantially is arranged running perpendicular to the optical axis (18), and through a second diaphragm section (44, 56) with one running in the direction of the long extension of the format to be mapped Edge (48) in the same plane perpendicular to the optical axis (18) as the first diaphragm section (42), but is arranged on the opposite side with respect to the optical axis. 2. Optical diaphragm according to claim 1, characterized in that the first (42) and the second Aperture section (44) are firmly connected to one another and with their edges (46, 48) a gap-shaped Form opening (41). 3. Optical diaphragm according to claim 1 or 2, characterized in that the first (42) and the second screen section (44) are arranged in a frame (40), the two sections (42, 44) in in a fixed position. 4. Optical diaphragm according to one of claims 1 to 3, characterized in that the the The edges (46, 48) of the diaphragm sections (42, 44) delimiting the beam path are each identical Distance from the optical axis (18) of the lens (e.g. 10). 5. Optical diaphragm according to one of claims 1 to 4, characterized in that the diaphragm sections between the lens elements of an optical System are arranged. 6. Optical diaphragm according to one of claims 1 to 4, characterized in that the diaphragm sections are arranged on the object side of an optical system. 7. Optical diaphragm according to one of claims 1 to 4, characterized in that the diaphragm sections are arranged on the image side of an optical system. 8. Optical diaphragm according to one of claims 1 to 7, characterized in that the edges (46, 48) of the diaphragm sections (42, 44) are designed in such a way that the relative illumination can be controlled the image plane can be reached. 9. Optical diaphragm according to claim 8, characterized in that for stronger illumination of the Edge areas of an image compared to the center of the image, referred to through the optical System depicted evenly illuminated object the edges of the diaphragm sections (54,56) form an anchor-shaped opening (50). 10. Optical diaphragm according to claim 8, characterized in that the edges (46, 48) of the Aperture sections (42, 44) are bent towards one another in this way towards their outer ends are carried out that the image of a uniformly illuminated object after the figure through the optical system in the center of the image plane is more strongly illuminated than at the edges. 11. Optical diaphragm according to claim 8, characterized characterized in that the edges (28, 30) of the Aperture sections run parallel to one another. 12. Optical diaphragm according to one of claims 1 to 11, characterized in that the maximum Distance of the diaphragm sections (42, 44) from the lens (10) inversely proportional to the first long Extension of the object format is. 13. Optical diaphragm according to one of claims 1 to 12, characterized in that the edges (74, 76) of the diaphragm sections (70, 72) to these associated with parallel surfaces with edges running perpendicular to the edges of the diaphragm sections which form with them an opening (78) for controlling the overall illumination of the image plane, and that the diaphragm sections (70, 72) and the surfaces at the point of the aperture stop of the optical System are provided. 14. Optical diaphragm according to claim 13, characterized in that the surfaces with the to the Edges (74, 76) of the diaphragm sections perpendicular edges have a curved shape. 15. Optical diaphragm according to one of claims 1 to 14, characterized in that the diaphragm sections (70, 72) with drive devices (80, 81, 82) for moving the diaphragm sections in Direction of the first long extension of the format to be mapped are connected. 16. Optical diaphragm according to claim 15, characterized in that the edge (74) of the first Panel section (70) together with the edge Γ76) of the second panel section (72) over the Opening panel (78) expanding in the direction of the first long extension of the format Forms opening, whereby when moving at least one of the diaphragm sections (70) in the direction of the long expansion of the format a change in the amount of light transmitted is achieved.