DE4208635C1 - Telecentric objective lens with double Gaussian objective - couples lens contents into image conducting fibres with higher illuminating strength at picture edges - Google Patents

Abstract

The telecentric objective lens includes two meniscus lenses (2, 3) behind a diverging lens (1). These define an aperture (7) between their concave sides. Diverging lenses (4-6) are arranged after the meniscus lenses (2, 3). These deflect the main beam to the telecentre. At least one of them has a dispersion surface which also reduces spherical aberration. The meniscus lens (3) after the aperture (7) has a focal width less than double that of the objective lens. At least one strongly diverging lens is provided at a distance from the lens (5) behind the first three lenses. This satisfies d2 is less than 0.24f and f2 is less than f1. f2 and d2 are the focal width and thickness of the first meniscus lens (2). f is the objective focal width. f1 is the focal width of the first lens. USE/ADVANTAGE - For measuring and projection, especially for coupling picture contents into matrices or bundles of fibres. Improves illumination strength distribution over the whole picture for a uniform good quality picture.

Description

The invention relates to a telecentric lens according to the preamble of claim 1. The objective according to the invention is for measuring and projection purposes and in particular for the coupling of object-wise given Image content on matrices or image guide fiber bundles suitable.

Lenses with a telecentric beam path on the image side are used used on the one hand for measuring purposes (since the image size is Change in image plane remains constant), continue (in reverse Direction of use) for special projection purposes and also for the coupling of object-related image content on matrices or image guide fiber bundles.

In the latter case in particular, the optical system should an optimal telecentric main beam path and a have a large aperture on the image side in order to achieve a high, if possible to achieve lossless coupling of energy.

Powerful optical systems with telecentric on the image side Beam paths have become little known so far. Frequently becomes a telecentricity by means of a field lens close to the image plane manufactured, whereby the aberration correction suffers, so that only small opening ratios can be realized.

In EP 03 35 559 A2 a solution is described, whereby the telecentricity is established with a Fresnel lens. With such a field lens, however, it is impossible on top of that, on a structured recipient, a good one To achieve image quality.

The objectives specified in EP 02 99 474 A2 have the disadvantage that they have relative openings of a maximum 1: 8 are very faint and have small fields of view.

So-called relay systems are also telecentric on both sides, as used in endoscopic optical systems for image transmission however, these are for long transmission lengths designed and have only small image fields and moderate aperture ratios on.

The objective disclosed in DE-AS 12 55 944 represents an extended double Gaussian lens, of the type "Zeiss-Biotar". In the Patent literature includes extended double Gaussian lenses split last converging lens, for example in the Patent specifications GB 8 73 168 and US 35 60 079 are disclosed. These are suitable for aperture ratios up to 1: 1.4. As a result of extremely high apertures of such lenses exist within the oblique bundles on the image side also rays, which exit telecentrically. it's just a matter of Aperture position, such telecentrically exiting rays through let the center of the aperture run. This measure was essentially in the one described in DE-AS 12 55 944 Lens by shifting the diaphragm (pupil) to the taken towards the front focal point. With such a relative However, the simple solution has a number of disadvantages:

• - Even with a reduced lens compared to the original lens With an aperture of 1: 2, the lens is not vignetting-free, and it does there is a significant loss of illuminance at the edge of the Image field due to insufficient lens diameter in lens part on the image side as well as severe coma already in the given diameters.
• - An increase in the light flux in the upper image-side Lens part is not possible because of the specified Diameters already too strong curvatures of the convex Lens surfaces of the lenses arranged on the image side, which is shown in known whites leads to severe internal coma and distortion.
• - Because of the accumulation of exclusively positive refractive power in the The objective part on the image side is a correction of the pupillary aberration impossible, d. that is, the lens is only limited telecentric.

In DE 38 22 274 A1 is a relative bright and telecentric on the object side Projection objective described, which at an aperture of 0.18 (relative aperture approx. 1: 2.8) an image field of Zw = 46 ° excels. This lens has just like the one before mentioned the disadvantage that the illuminance in the Frame edge due to the natural Illuminance distribution in the image plane is relatively low and is not sufficient for certain applications.

The object of the invention is to create a powerful telecentric lens which, with an illuminance drop that is significantly better than cos ^1.5 w, has an illuminance distribution in the image plane that is ^{significantly better than the natural cos 4 law.}

According to the invention, this object is achieved by a telecentric Objective according to claim 1 solved. Advantageous embodiments of an objective according to the invention are listed in the subclaims 2 and 3.

The essence of the invention, consisting in the angle of view dependent Enlargement of the pupils, should be based on a comparison with the lens known from DE 38 22 274 A1 explained.

Formally, the objective according to the invention shows certain similarities with the lens according to the embodiment of the above. Offenlegungsschrift, d. i.e., there is a double Gaussian lens has a similar basic structure, in which the Aperture of two thick and their concave side of the aperture facing meniscus lens members is included and at furthermore, in particular on the image side to achieve the Telecentricity, a number of additional collecting elements is arranged. However, this alone does not generally result in any enlarged image of the pupil or a corresponding one To achieve enlargement of the aperture to the edge, as well as that Objective described in DE 38 22 274 A1 proven. In this case, the rear of the diaphragm is arranged thick collecting cemented meniscus, d. H. collecting those behind arranged lens is clearly biconvex, so also of strong collecting effect. This takes place shortly after the Aperture a strong constriction of the off-axis light beam compared to the axial, so that an increase in the aperture to the edge is not possible.

In contrast, in the lens according to the invention, the thick cemented meniscus 3 behind the diaphragm is dispersive, and the following lens 4 turns its less curved surface towards the diaphragm 7 , so that premature constriction of the off-axis bundle is avoided.

The diffusing cemented surface acts in the same way in the third converging lens element 5 arranged behind the diaphragm 7 . In contrast to the objective according to DE 38 22 274 A1, this is concave on the object side and is therefore closer to the diaphragm 1 with respect to the off-axis bundle than a correspondingly convex surface and thus causes a further enlargement of the off-axis aperture, which also remains effective in the larger air space that follows. The actual required collecting effect only begins seriously with the last lens element 6 , which is clearly positive and for this purpose has a strongly curved surface with a radius smaller than 1.6 _* f, where f is the focal length of the lens, towards the incident light. As a result of the redistribution of the collecting refractive power towards the image plane caused by this build-up of refractive power, a long focal length of more than 40% of the focal length of the lens is achieved, similar to lenses of the reverse telephoto lens type.

In the sense of an isoplanatic imaging, the same effect for the diaphragm imaging towards the object space must also occur with a distortion-free lens. The distortion-correcting and pupil-enlarging effect of the lens part arranged in front of the diaphragm 7, which corrects the distortion as the angle of view increases, should be emphasized on the basis of the comparison with known telecentric lens constructions: While in the lens according to DE 38 22 274 A1, the meniscus in front of the diaphragm is cemented, is very thick and because of the Thickness only slightly diffuses, with regard to the diaphragm image even collects (recognizable by the fact that its radius of the outer convex surface is smaller than the sum of the total meniscus thickness plus the amount of the radius of the inner concave surface), this meniscus 2 is thinner with a thickness in the present invention less than 0.24 _* f, and because of its focal length of less than 2 _* f in terms of magnitude, clearly diffusing, also with regard to the aperture image, which can be seen from the beam paths in FIGS. 1 and 2; ie the off-axis beam is enlarged compared to the axial. But that means nothing else than that for a given diaphragm diameter the extra-axial pupil diameter becomes larger than the axial.

Normally, the strong negative refractive power in front of the diaphragm 7 would lead to an undesired enlargement of the object-side angle of view and to barrel-shaped distortion. This is compensated for by reducing the disproportionately enlarged image angle by bending the beam in the opposite direction by means of a first converging lens 1 in front of this diffusing meniscus 2 . As can be seen, the pupil-enlarging effect for the larger image angles is mainly brought about by the air space between the first converging lens 1 and the subsequent diffusing meniscus 2 in front of the diaphragm 7 , which grows from the axis to the edge. The desired effect only occurs if the individual refractive powers of both lenses are sufficiently large and the focal length for the dispersing meniscus 2 is _{below 2 *} f in terms of magnitude. In terms of magnitude, the focal length of the first converging lens 1 is greater than that of the dispersing meniscus 2 , so that a negative total focal length results for the objective part on the object side, consisting of both lenses.

With such a lens structure, relative openings can be made of 1: 2 and more with field angles of Zw = 46 °. on the other hand are also larger field angles up to 2w = 55 ° with restricted Aperture or with a certain vignetting possible.

Below are two exemplary embodiments of an inventive Lens described in connection with the drawings. In it shows

Fig. 1 shows an inventive objective for infinite object distance with the construction data of Table 1,

2 shows an objective according to the invention for a finite object distance with the design data according to Table 2 and FIG

FIG. 3 shows the entrance pupils for the image center and the image edge of the objective shown in FIG. 1.

Since the sequence of the elements in FIGS. 1 and 2 is identical, for the sake of clarity, only the reference numerals for the elements have been entered in FIG. 1, while in FIG. 2 only the values r, d and l were attracted.

Fig. 1 with the associated design data in Table 1 shows a lens according to the invention with a relative aperture of 1: 2 and a field angle of 2w = 50 °, which is corrected for an infinite object distance. Its mode of operation has been explained in detail in the presentation of the essence of the invention.

In Fig. 3, the entrance pupils for the center of the image and the edge of the image field are shown for this specific objective. The pupil enlargement depending on the angle of view can be seen too clearly after the edge. The area of the entrance pupil for the image edge is larger by a factor of 1.33 compared to that in the center of the image. This means that the lens has an illuminance at the edge of the image field of approx. 90% compared to the center of the image. With a vignetting-free lens known from the prior art, on the other hand, one would get only 67% illuminance at the edge of the image field due to the cos⁴ law. Thus, Figure follows a expressed in cos potencies illuminance distribution in the image plane of cos ^1.2 w.. 2 with the associated design data in Table 2 shows an inventive lens which accordingly when an image-side aperture of 0.23 (with a relative aperture of ca 1: 2) is provided for an image scale of 1: 5 and defines an image part of 2w = 46 ° with high contrast. This lens has an even more favorable illuminance distribution, which is proportional to cos w.

Claims (3)

1.Telecentric lens with a construction similar to a double Gaussian lens, in which two meniscus lens members ( 2, 3 ) are provided behind a converging lens element (1 ) which enclose a diaphragm (7 ) between their concave sides and which converge lens elements ( 4-6 ), which cause a uniform deflection of the main ray up to telecentricity and of which at least one has a diffusing cemented surface which additionally reduces the spherical aberration of the pupil image, whereby the foremost dispersing cemented surface of the converging lens elements ( 4-6 ) , which are arranged downstream of the meniscus lens elements ( 2, 3 ) enclosing the diaphragm ( 7 ), is concave on the object side, the meniscus lens element ( 3 ) downstream of the diaphragm (7 ) is dispersive and the converging lens element downstream of it faces its less curved surface and
that the meniscus lens element (2 ) arranged in front of the diaphragm ( 7 ) has a focal length which is less than twice the focal length of the objective, characterized in that
that the lens element (5 ) arranged behind the first three lens elements and with the most object-side dispersing cemented surface at a greater distance is followed by at least one strongly converging lens element, and
that the following conditional equations are fulfilled: d₂ <0.24 f | f₂ | <| f₁ | with
f₂ or d₂ = focal length or thickness of the meniscus lens element (2 ) arranged in front of the diaphragm (7 ),
f = lens focal length,
f₁ = focal length of the first lens element. 2. Telecentric lens according to claim 1, characterized by the following design data: Table 1 Focal length: f = 1.00; Back focus: s ′ = 0.43
relative opening 1: 2; Field of view: 2w = 50 ° 3. Telecentric lens according to claim 1, characterized by the following design data: Table 2 Focal length: f = 1.00; Image scale: 1: 5
relative opening 1: 2; Field of view: 2w = 46 °
Image-side focal length at the picture scale 1: 5: s' = 0.64