RU2561340C1 - Four-mirror lens - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: lens includes a first mirror in the form of an off-axis fragment of a concave spherical converging mirror, facing the object plane with its concave side, a second mirror in the form of a convex spherical diverging mirror, facing the first mirror with its convex side, a third mirror in the form of an off-axis fragment of a concave aspherical converging mirror, facing a fourth mirror with its concave side, a fourth mirror in the form of a fragment of a concave aspherical converging mirror, facing the image plane with its concave side, and an aperture diaphragm. The centres of curvature of all optical surfaces lie on a common axis. In the meridian section, the second mirror is symmetrical relative to the optical axis, the first mirror lies below the optical axis, the third mirror is above the optical axis and the fourth mirror is above the third mirror. The aperture diaphragm coincides with the holder of the second mirror.

EFFECT: absence of central screening, high image quality and improved manufacturability.

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Description

The invention relates to optical instrumentation, namely to mirror lenses, and can be used in space telescopes.

Mirror optical systems are known that are close in technical essence to the proposed lens, consisting of four mirrors, differing in circuit design and degree of correction of aberrations. For example, a four-mirror lens in accordance with the USSR author's certificate No. 428341, IPC G02B 17/02, publ. 05/15/1974, which is a primary concave axisymmetric parabolic mirror, a secondary convex axisymmetric hyperbolic mirror and a compensator located in their rear segment, formed by a convex and concave spherical axisymmetric mirrors, the front focus of the first of which is combined with the rear focus of the primary and secondary mirrors and the back focus - with the front focus of the concave mirror of the compensator. The disadvantages of the considered optical scheme are the presence of central shielding, as well as a small angular field. The presence of two convex mirrors in the lens greatly complicates its assembly, alignment and control.

A known lens in accordance with the author's certificate of the USSR No. 1753442 A1, IPC G02B 17/06, publ. 08/07/92, which is a system of four mirrors, the first of which is convex spherical, the second, third and fourth are concave aspherical, while the first and fourth mirrors are made with central holes. The aperture diaphragm is not combined with any optical element, but is located between the second and third mirrors. The disadvantages of this lens include the convex annular spherical field of the image. Also, the presence of three aspherical surfaces and a convex mirror in the lens greatly complicates its assembly, alignment, and control.

Closest to the proposed invention is a four-mirror lens with an eccentrically located entrance pupil and an image field in accordance with US application No. 2009/0009897 A1 of 01/08/2009. The lens is a system of four mirrors with centers of curvature of all optical surfaces located on one common axis, consisting of four mirrors installed in series along the beam - the first, second, third and fourth. In this case, the first mirror is made in the form of an off-axis fragment of a concave positive aspherical mirror facing with a concavity to the plane of objects. The second mirror is made in the form of a convex off-axis aspherical negative mirror convex to the first mirror. The third mirror is a negative convex axisymmetric convex to the fourth mirror and made in the form of a fragment of an aspherical mirror. The fourth mirror is made in the form of an off-axis fragment of a concave positive aspherical mirror facing with a concavity to the image plane and an aperture diaphragm located on the third mirror. Moreover, in the meridional section of the lens, the first and second mirrors are located below the optical axis, the third - on the optical axis, and the fourth mirror - above the optical axis. The system has a wide field of 6 × 6 °, there is no central shielding. In this lens, three mirrors are off-axis, which leads to a complication of the mechanical design of the lens and difficulties in its assembly. The presence of four aspherical surfaces, two convex mirrors in the lens also greatly complicates its mechanical design, assembly, alignment and control.

The objective of the invention is to provide a four-mirror lens with enhanced performance.

EFFECT: creation of a four-mirror lens without central shielding with improved image quality within an angular field of 13 ° in a wide spectral range of 450-1700 nm and increased manufacturability.

This is achieved by the fact that in a four-mirror lens, consisting of a first mirror sequentially installed along the beam, made in the form of an off-axis fragment of a concave positive mirror facing concavity to the plane of objects, a second mirror made in the form of a convex negative mirror convex to the first mirror, the third mirror, made in the form of a fragment of an aspherical mirror, the fourth mirror, made in the form of a fragment of a concave positive aspherical mirror, turned by concavity to the image plane, and the aperture diaphragm, and the centers of curvature of all optical surfaces are located on one common axis, while in the meridional section of the lens the first mirror is located below the optical axis, and the fourth mirror is above the optical axis, in contrast to the known one, the first and the second mirror is made with spherical surfaces, in addition, the second mirror in the meridional section of the lens is symmetrical about the optical axis, the third mirror is concave positive, facing concave axis to the fourth mirror, off-axis and in the meridional section of the lens is located above the optical axis, the fourth mirror in the meridional section of the lens is located above the third mirror, and the aperture diaphragm coincides with the frame of the second mirror.

In FIG. 1 is a schematic diagram of a four-mirror lens, and FIG. 2 - modulation transfer function (MPF) for the extreme point of the field.

The lens (Fig. 1) consists of sequentially, along the beam of the installed first mirror 1, second mirror 2, third mirror 3, fourth mirror 4, aperture diaphragm 5. The first mirror 1 is made in the form of an off-axis fragment of a concave spherical positive mirror, facing concavity to plane of objects. The second mirror 2 is made in the form of an axisymmetric convex spherical negative mirror, convex to the first mirror. The third mirror 3 is positive and is made in the form of an off-axis fragment of a concave aspherical mirror facing with a concavity to the fourth mirror. The fourth mirror 4 is made in the form of an off-axis fragment of a concave positive aspherical mirror facing with a concavity to the image plane. The centers of curvature of all optical surfaces are on one common axis, and the aperture diaphragm 5 is located on the second mirror 2. In the meridional section of the lens, the first mirror 1 is located below the optical axis, the second mirror 2 is on the optical axis, and the third mirror 3 and the fourth mirror 4 are higher than the optical axis, the fourth mirror 4 being higher than the third mirror 3.

In FIG. Figure 2 shows the polychromatic MPF of the lens in the spectral range (0.45 ÷ 1.7) μm for the edge of the angular field.

The lens works as follows. The light from the radiation source enters the first mirror 1, then, subsequently reflected from the mirrors 2, 3, 4, focuses in the image plane.

In accordance with the proposed technical solution, a lens is calculated whose design parameters are given in table 1.

* axisymmetric aspherical mirror surfaces are described by the following formula:

Where

x, y, z - coordinates of a point on the mirror surface relative to the center O on the axis of symmetry Oz,

R - радиус при вершине асферической поверхности, может быть как положительным, так и отрицательным, указывая направление относительно оси z положения центра кривизны асферической поверхности,

R is the radius at the apex of the aspherical surface, can be both positive and negative, indicating the direction relative to the z axis of the position of the center of curvature of the aspherical surface,

K is a conical constant,

C _i are aspherical constants.

The values given in table 1 correspond to a lens with the following characteristics:

- Focal length: 1000 mm.

- Relative hole: 1: 4.5.

- The angular field in the meridional direction is ωy _{0 =} 6 °, ω _ymax = 9 °.

- The angular field in the sagittal direction 2ω _x = 13 °.

The lens has the following aberrations for a wavelength of λ = 656.3 nm:

- Transverse spherical aberration of wide inclined beams within the entire angular field of not more than 0.003 mm.

- The meridional astigmatic segment is not more than 0.036 mm.

- Sagittal astigmatic segment of not more than 0.023 mm.

- Distortion of not more than 0.2%.

Thus, a four-mirror lens without central shielding was created, which has good image quality within an angular field of 13 ° in a wide spectral range of 450-1700 nm, in which central shielding can be avoided due to the eccentrically located image field, the use of off-axis fragments of axisymmetric mirrors and a special arrangement aperture diaphragm.

Claims (1)

A four-mirror lens, consisting of a first mirror sequentially installed along the beam, made in the form of an off-axis fragment of a concave positive mirror facing concavity to the plane of objects, a second mirror made in the form of a convex negative mirror, convex to the first mirror, and a third mirror made in the form a fragment of an aspherical mirror, the fourth mirror, made in the form of a fragment of a concave positive aspherical mirror, facing concavity to the square image velocity, and the aperture diaphragm, and the centers of curvature of all optical surfaces are located on one common axis, while in the meridional section of the lens the first mirror is located below the optical axis, and the fourth mirror is above the optical axis, characterized in that the first and second mirrors are made with spherical surfaces, in addition, the second mirror in the meridional section of the lens is symmetrical about the optical axis, the third mirror is concave positive, facing concavity to the fourth mirror, in The e-axis and in the meridional section of the lens are located above the optical axis, the fourth mirror in the meridional section of the lens is located above the third mirror, and the aperture diaphragm coincides with the frame of the second mirror.

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