DE1218750B - Five-part, seven-element, bright Gaussian lens - Google Patents

Description

Five-unit, seven-element, high-speed Gaussian objective The invention relates to a five-element, seven-element Gaussian lens, in which the two are used for Aperture hollow meniscus inner members are cemented with two lenses and are on the object side two converging menisci, a biconvex converging lens on the image side and at Furthermore, the refractive indices of the first, sixth and seventh lens are higher than 1.7, 1.72 and 1.7 are respectively.

In such an objective, the first and second members, seen from the long to the short conjugate objective side, each consist of a single meniscus converging lens L,., L2, the concave side of which faces the diaphragm. The third member is a dispersive meniscus combination on the same diaphragm side as the first and second members, the concave side also facing the diaphragm; it consists of the biconvex lens L3 and the biconcave lens L4. The fourth link is a meniscus combination of low diopters on the opposite side of the diaphragm, with the concave side also facing the diaphragm here. It consists of the biconcave lens L5 and the biconvex lens L ,. The fifth link is formed by a single biconvex lens L 7 .

Lenses of this type with a relative aperture up to F / 1.2 and a field angle 2 co of 40 ° are known.

There is also another lens of this type with a relative aperture of F / 1.2 and a field angle of 2 co of 30 °. Both calculated in it However, photographic lenses are not higher than the former lens Luminous intensity at a lower field angle.

The aim of the present invention, however, is to create an objective of the type mentioned with an even higher light intensity while maintaining a good state of correction in a flat field of view of about 40 °.

According to the invention, this objective is achieved with an objective, which is characterized by the following data in arbitrary units, with a maximum of ± 10% deviation in the lens thickness, based on the focal length, 10% deviation in the surface refractive power, based on the total refractive power, with Q0.03 deviation of the refractive indices and :: L5 units of the v-values f = 100; F / 1.1 Lens radius of curvature Lens thickness Refractive index Abbe or distance (d line) number r, = 111.5 L1 d, = 9.515 n, = 1.7201 v1 = 50.3 r2 = 352.6 d2 = 0.1 - - r3 = 65.7 L2 d 3 = 8.545 n2 = 1.7342 v 2 = 51.0 r4 = 104.1 d4 = 097 - - rs = 53.4 L3 d5 = 22.8 n3 = 1.6422 v3 = 58.1 r6 = -329.1 L4 d6 = 4.175 n4 = 1.7184. v4 = 29.5 r7 = 28.0 d7 = 22.235 - - f = 100; F / 1.1 Lens radius of curvature Lens thickness Refractive index Abbe or distance (d-line) number - r8 - -44.4. , L5 - d8 = 1.8 n6 = 1.5481 vs = 45.9 r9 = 808 L 6 d9 = 11.36 n0 = 1.7440 v0 = 44.9 _ - rio = -754 _ dio = 0.1 - ril = 150.4 L7 dl, = 7.96 n7 = 1.7342 v7 = 51.0 r12 = -106.5 Another embodiment of the objective according to the invention is characterized by the following data in any units, with a maximum of Q100 / 9 deviation of the length; related to the focal length, 4-100 / 9 deviation of the surface power, related to the total refractive power, with ± 0.03 deviation of the refractive indices and 4-5 units of the v-values: f = 100; F / 0.95 Lens radius of curvature Lens thickness Refractive index Abbe or distance (d-line) number - ri = 136.1 di - = 10.175 ni = 1.7550 vl = 53.5 r2 = 482.9 d2 = 0.2 @. - r3 = 698 L2 - d3 = 9.31 n2 = 1.7885 v2 = 50.45 r4 = 105.6 d4 = 0.93 - - _ r6 = 58.1 Ls d 5 = 26.13 n3 = 1.6516 v3 = 58.5 r0 = -215.7 L4 d 6 = 4.12 n4 = 1.7215 v4 = 29.3 -r7 = 29.8 d7 = 246 _ - rs = -41.1 L6 d8 = 1; 73 ns = 1.5235 vs = 50.9 L0 r9 = 92.0 d9 = 10.57 ne = 1.7440 v0 = 44.9 . _ rio = -71.4 dio = 0.2 - - rü = 136.1 L7. dü = 8.24 n7 = 1.7550 v7 = 53.3 rl _ -105.6 The drawing serves to explain the invention. F i g. 1 serves to explain the first mentioned embodiment of the invention; F i g. 2 is used to explain the second embodiment; _.

F i g. 3 to 5 show the aberration curves for the lens according to FIG. 1; F i g. 6 to 8 show the curves of the aberrations and Image errors for the lens according to FIG. 2. The data for the two shown Embodiments can be found in the two lists above. The ones in the F i g. 3 to 5 or 6 to 8 depicted aberrations of the lenses the F i g. 1 and 2 were determined for the d-line of the spectrum. They are spherical aberration and the deviation from the sine condition, the astigmatism and the distortion shown.

Claims (1)

Claims: 1. Five-element, seven-element Gaussian lens, in which the two menisci inner elements, which are hollow to the diaphragm, are cemented with two lenses and there are two converging menisci on the object side, a biconvex converging lens on the image side, and in which the refractive indices of the first, sixth and seventh lenses are higher than 1.7, 1.72 and 1.7 are characterized by the following data in any units with a maximum of ± 100/9 deviation of the lens thickness, based on the focal length, 1L100 / 0 deviation of the surface powers, based on the total refractive power, with ± 0.03 deviation of the refractive indices and ± 5 units of the v-values: f = 100 Lens radius of curvature Lens thickness Refractive index Abbe or distance (d-line) number r1 = 111.5 LI d, = 9.515 n1 = 1.7201 v1 = 50.3 r2 = 352.6 d2 = 0.1 - - r3 = 65.7 L2 d3 = 8.545 n2 = 1.7342 v2 = 51.0 r4 = 104.1 d4 = 0.97 - - r5 = 53.4 L3 d 5 = 22.8 n3 = 1.6422 v 3 = 58.1 r8 = -329.1 L4 de = 4.175 n4 = 1.7184 v4 = 29.5 r7 = 28.0 d7 = 22.235 - - r3 = -44.4 L6 d $ = 1.8 n6 = 1.5481 v 5 = 45.9 r0 = 80.8 L8 d9 = 11.36 ne = 1.7440 va = 44.9 rlo = -75.4 dlo = 0.1 - - ru = 150.4 L7 dl, = 7.96 n7 = 1.7342 v7 = 51.0 r12 = -106.5 2. Lens according to the preamble of claim 1, characterized by the following data in any units with a maximum of zL100 / e deviation of the lens thickness, based on the focal length, -E100 / 0 deviation of the surface powers, based on the total refractive power, with Q0.03 deviation of the Refractive indices and: E5 units of the v-values: f = 100 Lens Krünnnungsraäius Lens thickness Refractive index Abbe or distance (d-line) number r1 = 136.1 L1 dl = 10.175 n1 = 1.7550 v1 = 53.5 r2 = 482.9 d2 = 0.2 r3 = 69.8 L2 d 3 = 9.31 n2 = 1.7885 v2 = 50.45 r4 = 105.6 d4 = 0.93 - - r5 = 58.1 L3 d, = 26.13 n3 = 1.6516 v 3 = 58.5 r0 = -215.7 L4 de = 4.12 n4 = 1.7215 v4 = 29.3 r7 = 29.8 d7 = 24.6 - - rs = -41.1 L6 d 8 = 1.73 nfi = 1.5235 v6 = 50.9 ro = 92.0 L 6 d 9 = 10.57 ne = 1.7440 v8 = 44.9 rlo = -71.4 d0 = 0.2 - - r11 = 136.1 L7 dl = 8.24 n7 = 1.7550 v7 = 53.3 r12 = -105.6 Documents considered: German Auslegeschrift No. 1073 765; USA: Patent No. 2,836,102.