SU1281952A1 - Device for measuring lens spectral transmittance factor - Google Patents

Abstract

) The invention relates to optical instrumentation and makes it possible to ENHANCE accuracy and expand the operational capabilities of the device by reducing the size limit of the tested lenses. The auxiliary lens 3 and a flat mirror 4 are mounted behind the light divider 2 along the light beam. Making the mirror 4 rotatable 90 about an axis allows the radiation beam to be alternately directed to the rotating lens 6 and to the spherical mirror 8 whose center of curvature is aligned with the focus of the lens 3. The beams of rays reflected from the turned lens 6 and the mirror 8, by the mirror 4 and the beam splitter 2 are directed to the lens 9. Focused on the sensitive area of the photoreceiver 10, the beams cause the appearance And etstvenno signal and the reference signal, and. . 3 pillars The spectral transmittance is calculated from these signals. 1 il. f | - T / fi - / (L

Description

The invention relates to optical measuring instruments, in particular to optical devices for measuring the spectral transmittance of lenses.

The purpose of the invention is to expand the operational capabilities by reducing the size limit of the tested lenses, increasing the measurement accuracy.

The drawing shows the optical layout of the console.

The attachment contains a series of aperture diaphragm 1, a beam splitter 2 and an auxiliary lens 3, behind which a flat mirror 4 is installed, which can be rotated around an axis of the auxiliary lens 3 passing through the optical axis. In addition, the attachment includes a mandrel 5 for attaching a rotating lens 6, a flat mirror 7 located behind it and a spherical mirror 8 with a center of curvature aligned with the focus of the auxiliary lens 3, while the angles formed by the axis of rotation of the flat mirror 4 with but Malia to the mirror 7 and the optical axis of the spherical mirror 8 are equal. Between the beam splitter 2 and the auxiliary lens 3, outside the light beam emitted by the aperture diagram 1, an auxiliary lens 9 is installed, in the focus of which the photodetector 10 is located.

The prefix works as follows.

A parallel monochromatic radiation beam coming out of the collimator passes through the aperture diaphragm 1, the diameter of which is equal to the light diameter of the auxiliary lens 3. Passing the beam splitter 2 and the auxiliary lens 3, the beam of radiation by the rotating mirror 4 is alternately directed first to the turnable lens 6, entering into the measuring channel of the attachment, then onto the spherical mirror 8, which is part of the reference channel.

When the flat mirror 4 is rotated to a position in which the normal to it lies in the same plane with the optical axis of the auxiliary lens 3 and normal to the flat mirror 7, a parallel beam of rays after the lens 6 being turned, fixed in the frame 5 so that its focus is aligned with the focus of the auxiliary lens 3 is reflected by the mirror 7 in the opposite direction.

Once again the turning lens 6, the beam of rays is reflected from the mirror 4, the auxiliary lens 3 passes and, reflected from the beam splitter 2, collects the auxiliary object BOM 9 on the sensitive area of the photodetector 10, causing a signal and |.

When turning the mirror 4 to a position in which the normal to it lies in the same plane as the optical

the axes of the auxiliary lens 3 and the spherical mirror 8, the radiation flux after the auxiliary lens 3 and the mirror 4 is reflected from the spherical mirror 8 and, again

A mirror 4 and an auxiliary lens 3, as well as in the measuring channel, are reflected by the beam splitter 2 to the auxiliary lens 9 and the photodetector 10, causing a signal and supports.

Transmitting the splitter 3 for the measuring and reference channels, due to the location of these channels on one side. From the splitter equal to each other and with equal reflection coefficients of the mirrors 7, and 8, the spectral coefficient i; the turning of the lens to be turned is determined by the formula

.40

45

The diameter of the collimated radiation beam that fills the aperture diaphragm 1 is related to the sizes of the auxiliary objects 3 and 9 and the lens 6 being turned on by the ratio

 D, D,

f .D

new

f:

fishing

where D is the diameter of the aperture diaphragm /

D is the diameter of the auxiliary lens 3;

D - diameter of the auxiliary lens 9

G1 is the diameter of the turned lens i

the focal distance of the lens being turned;

fj is the focal distance of the auxiliary lens 3.

It can be seen from the above relation that the dimensions of the main optical elements, including the beam splitter 2 and the spherical mirror 8, could be made g / f.j the number of times smaller than the diameter of the lens being turned, which is especially important when monitoring lenses of large light diameters.

Thus, in comparison with the known, the proposed prefix has a greater accuracy of measurements and smaller dimensions.

Claims (1)

Invention Formula A device for measuring the spectral transmittance of objectives, containing aperture diaphragm and a beam splitter, a mirror behind it, as well as an auxiliary lens installed behind the beam splitter, in the focal plane of which a photodetector is mounted, differs with the following: in order to reduce its operational capabilities by reducing the size limit of the tested lenses and increasing the measurement accuracy , the neg are additionally placed along the light beam behind the beam splitter of the second auxiliary lens and a flat mirror, which can be rotated on an axis passing through the optical axis sec th auxiliary lens, and the spherical mirror, the center of curvature of which is aligned with the focal point of the second auxiliary lens, the flat / with the mirror is set at an angle of 45. to the optical axis of the spherical mirror.