RU118081U1 - Ocular with a remote pupil - Google Patents

Abstract

An eyepiece with a remote pupil containing a negative doublet, a positive meniscus, a positive doublet, a positive meniscus, with the menisci facing each other with their convex surfaces, the negative lenses of the negative and positive doublets are located first along the rays, the lenses of the doublets of the same sign are made of the same materials , the following relationships take place in the eyepiece:! φ1: φ2: φ3: φ4 = - (0.45 ÷ 0.65) :( 0.35 ÷ 0.55) :( 0.2 ÷ 0.4) :( 0.2 ÷ 0.4); ! R5≤-1.2; !,! where φ1, φ2, φ3, φ4 are the relative optical powers, respectively, of the negative doublet, positive meniscus, positive doublet and positive lens; ! R5 is the radius of the refractive surface of the positive meniscus, second in the course of the rays from the object plane of the eyepiece; ! f '- focal length of the eyepiece; ! - the focal length of the positive meniscus; ! - removal of the exit pupil from the last surface of the eyepiece.

Description

The proposed device relates to the field of optical instrumentation, namely to eyepieces with a remote pupil, and can be used in optical and optoelectronic devices requiring large removal of the exit pupil.

To observe the microdisplay image in optoelectronic devices, an eyepiece is required with an exit pupil removal of at least 50 mm, a visible magnification of at least 9 times, a linear field in the subject plane of at least 12.7 × 9 mm, and a mass of not more than 75 g in light diameters and high image quality.

Known eyepieces with distant pupils [Theory of optical systems / B.N. Begunov, N.P. Zakaznov, S.I. Kiryushin, V.I. Kuzichev. - M.: Mechanical Engineering, 1981. - S.218-220.]. The optical schemes of these eyepieces provide removal of the exit pupil, the value of which is approximately equal to or slightly different from the focal length of the eyepiece, by about 10-20%.

The disadvantage of these eyepieces - analogues is the small removal of the exit pupil compared with the focal length of the eyepiece.

The closest analogue to the claimed device by technical essence is an eyepiece with a pupil removed [Patent RU 2212700, 2003], containing a positive meniscus facing a concave surface to the subject plane, a positive doublet containing a positive and negative lenses, and a positive lens. All refractive surfaces of the eyepiece are spherical. The eyepiece has an angular field of 27 °, a relative aperture of 1: 3.5. The focal length of the eyepiece is 100 mm, the exit pupil is 259 mm. The eyepiece length along the axis from the subject plane to the last surface is 194 mm. Astigmatism at the edge of the field in the reverse is 2.2 mm. The mass of the eyepiece, calculated according to the parameters given in the patent, for the specified focal length is 8800 g, the volume of the glass of the lenses of the eyepiece is 2099 cm ³ .

In the patent [Patent RU 2212700, 2003], the parameters of an example of a specific embodiment are given for a focal length of 100 mm. Recalculating it taking into account the claims at the focal length required to obtain an exit pupil removal of 50 mm showed that in this case the increase is more than 9 times, but the linear field in the subject plane is less than the required. Recalculation to the focal length, providing a visible magnification of 9 times, showed that when the pupil is removed 50 mm and the required linear field is preserved while the features formulated as relations between the parameters are stored in the eyepiece, the eyepiece has a large mass and a decrease in image quality over the field due to increasing angular the field of the eyepiece is more than 27 °.

Thus, the drawback of the closest analogue is the impossibility of providing a combination of characteristics in it: removal of the exit pupil of at least 50 mm, a visible increase of at least 9 times, a linear field in the subject plane of at least 12.7 × 9 mm, and masses by light diameter of not more 75 g at high image quality.

The technical result consists in providing in the proposed eyepiece a combination of characteristics: a visible increase of at least 9 times, removal of the exit pupil of at least 50 mm, a linear field in the subject plane of at least 12.7 × 9 mm, a mass of light diameters of not more than 75 g and a high image quality.

The technical result is achieved in that the device of the eyepiece with the removed pupil is performed as follows: the eyepiece with the removed pupil contains a negative doublet, a positive meniscus, a positive doublet, a positive meniscus, menisci face each other with their convex surfaces, the negative lenses of the negative and positive doublets are located first in the course of the rays, the lenses of the doublet lenses of the same sign are made of the same materials, and in the eyepiece the following relationships hold:

where φ ₁ , φ ₂ , φ ₃ , φ ₄ are the relative optical powers of the negative doublet, positive meniscus, positive doublet, and positive lens, respectively;

R ₅ is the radius of the second along the rays from the subject plane of the eyepiece of the refracting surface of the positive meniscus;

f 'is the focal length of the eyepiece;

- the focal length of the positive meniscus;

- removal of the exit pupil from the last surface of the eyepiece.

The proposed implementation of the eyepiece device with a remote pupil allows us to provide the required technical result, which consists in providing a combination of the following characteristics: a visible increase of at least 9 times, removal of the exit pupil of at least 50 mm, a linear field in the subject plane of at least 12.8 × 9 mm, mass in light diameters of not more than 75 g and high image quality. This is ensured by the fact that with the indicated eyepiece and relations (1) - (3), the shape of the lens is such that they have a smaller volume, and, as a result, the mass of the eyepiece decreases, and at the same time, axial and off-axis aberrations are corrected primarily astigmatism, providing high image quality, while satisfying the requirements of apparent enlargement, linear field and pupil removal.

The authors are not aware of eyepieces with a distant pupil, in which a combination of the indicated features corresponding to the proposed device would be realized.

The proposed solution is illustrated by the following graphic materials:

figure 1 is an optical diagram of an eyepiece with a remote pupil;

figure 2 is a graph of astigmatism;

figure 3 - aberration in minutes behind the eyepiece for various points of the field.

The eyepiece with the pupil removed (Fig. 1) contains a negative doublet 1 located along the rays from the subject plane, a positive meniscus 2 facing the concave surface of the subject plane, a positive doublet 3, a positive lens 4 made in the form of a meniscus facing the exit to the concave surface pupil of the eyepiece. The negative doublet contains along the rays of the negative lens 5 and the positive lens 6. The positive doublet 3 contains along the rays of the negative lens 7 and the positive lens 8. The negative lenses 5 and 7 of the doublets are made of the same material. Positive lenses 6 and 8 of doublets are also made of the same material. The focal length of the positive lens 4 satisfy the relation (3). The relative optical powers of the negative doublet 1, the positive meniscus 2, the positive doublet 3, and the positive lens 4 satisfy relation (1). The radius of the second along the rays from the subject plane of the refracting surface of the positive meniscus 2 satisfies relation (2).

The proposed device operates as follows. The radiation coming from each point of the object plane by the components 1–4 of the eyepiece is directed to the exit pupil, the role of which is played by the pupil of the observer’s eye located at a remote distance along the optical axis from the last surface of the eyepiece. The components of the eyepiece 1-4 provide parallelism of the rays in the beams of rays emanating from each point of the subject plane. The magnitude of the aberration divergence of these beams of rays is significantly less than the resolution of the eye of the observer.

The implementation of the eyepiece with the pupil removed is confirmed by an example of a specific embodiment of the eyepiece with a pupil removal of 50 mm. The focal length of the eyepiece is 27 mm, its parameters are shown in table 1. The eyepiece is designed for visual observation of the image on the microdisplay screen with side dimensions of 12.78 × 9 mm (microdisplay 852 × 600, pixel pitch 0.015 mm). For ease of comparison with the analogue and the proposed ratios, the parameters in table 1 are shown for normalization by the magnitude of the focal length equal to 1. The mass value M is given for the focal length of 27 mm pupil removal 50 mm.

Table 1 Specific Performance Example Parameters Parameter Value f ' one 1.85 2y 0.57 D ' 0.285 φ ₁ -0.57 φ ₂ 0.40 φ ₃ 0.32 φ ₄ 0.27 R ₅ -1.4 L 1,56 M, g 75

The size of the object 2y and the focal length of the eyepiece f 'determine the magnitude of the angular field behind the eyepiece, equal to 32 °, i.e. more than the closest analogue. With a focal length of 27 mm, a visible magnification behind the eyepiece of 9.2 krata is provided.

The diameter of the exit pupil D 'and the focal length of the eyepiece f' define a relative aperture of 1: 3.5, i.e. the relative aperture is maintained the same as in the closest analogue.

The values of the parameters of the example of a specific implementation justify the claimed distinctive features formulated in the form of ratios. So, the optical powers of components 1-4 have the following relationships: φ ₁ : φ ₂ : φ ₃ : φ ₄ = -0.57: 0.4: 0.32: 0.27, which corresponds to relation (1). The radius R ₅ , the second along the rays from the subject plane of the eyepiece of the refracting surface of the positive meniscus, is minus 1.4, which is less than minus 1.2, i.e. the relation (2) is observed. The focal length of the positive meniscus 4 with the accepted normalization is 1 / 0.27 = 3.7, i.e. exceeds the size of the exit pupil removal by 3.7 / 1.85 = 2 times, which corresponds to relation (3).

The length L between the object plane and the last surface of the eyepiece along the axis is 1.56 of the magnitude of the focal length of the eyepiece, which is 1.94 / 1.56 = 1.24 times less than in the closest analogue, which contributes to the rest of the distinctive signs of decreased eyepiece mass.

All refractive surfaces of the eyepiece are spherical. Specific values of the design parameters are provided by standard optimization, which is part of any modern optical program for calculating optical systems, subject to the indicated optical forces and ratios.

As indicated earlier, in the closest analogue is an example of a specific design for normalization to the focal length of 100 mm. A comparison with the closest analogue in terms of the volume of the glass material and the mass should be correctly carried out at the same focal lengths, fields of view, relative aperture, and pupil removal. Our estimates show that when converted to the required set of characteristics, the closest analogue in terms of light diameters has a mass of about 20-30% higher than the proposed eyepiece.

Figure 2 shows a graph of sagittal (s) and meridional (m) astigmatic segments, and figure 3 shows the shapes and sizes of the angular aberrations of wide inclined beams behind the eyepiece.

On the ordinate axis in figure 2 shows the angles of inclination of the main rays behind the eyepiece in degrees. Astigmatism does not exceed 0.3 diopters.

Evaluation of image quality by the rms dimensions of the angular aberrations of wide beams, taking into account the effect of all aberrations on the quality of the aberration correction, shows that the axis does not exceed 0.5 minutes, for the middle of the field of view - 1.2 minutes, for the edge of the field of view - 1.8 minutes.

Thus, in the example of a specific embodiment of the eyepiece, there is a technical result, the achievement of which the claimed device is aimed at: a combination of characteristics is provided: a visible increase of at least 9, removal of the exit pupil of at least 50 mm, a linear field in the subject plane of at least 12.7 × 9 mm, mass no more than 75 g in light diameters and high image quality.

Thus, the implementation of the technical advantages of the proposed eyepiece with a remote pupil allows you to create an eyepiece that satisfies the totality of requirements, for use in optoelectronic devices.

Literature

1. Theory of optical systems / B.N. Begunov, N.P. Zakaznov, S.I. Kiryushin, V.I. Kuzichev. - M.: Mechanical Engineering, 1981. - 432 p.

2. Patent RU 2212700, 2003.

Claims (1)

An eyepiece with a removed pupil containing a negative doublet, a positive meniscus, a positive doublet, a positive meniscus, with the menisci facing each other with their convex surfaces, the negative lenses of the negative and positive doublets are located first along the rays, the lenses of the doublets with the same sign are made of the same materials , in the eyepiece there are the following relationships: φ ₁ : φ ₂ : φ ₃ : φ ₄ = - (0.45 ÷ 0.65) :( 0.35 ÷ 0.55) :( 0.2 ÷ 0.4) :( 0.2 ÷ 0, four); R ₅ ≤-1,2;

, where φ ₁ , φ ₂ , φ ₃ , φ ₄ are the relative optical powers of the negative doublet, positive meniscus, positive doublet, and positive lens, respectively; R ₅ is the radius of the second along the rays from the subject plane of the eyepiece of the refracting surface of the positive meniscus; f 'is the focal length of the eyepiece;

- the focal length of the positive meniscus;

- removal of the exit pupil from the last surface of the eyepiece.