SU673881A1 - Device for image quality control of optical system - Google Patents

Description

(54) DEVICE FOR MONITORING THE QUALITY OF THE OPTICAL SYSTEM IMAGE image quality simultaneously in two mutually perpendicular directions and improving the accuracy of determining the position of the focal plane during astigmatism, the test object is made in the form of two mutually perpendicular transparent strokes, and to increase the efficiency of control in the device, the receiver The images are made in the form of a television system with video signal level discrimination. FIG. Figure 1 shows the optical design of the proposed device; in fig. 2 is a plot of the function of scattering when transforming an image of a dough while isolating an isophote. A device for controlling the image quality of an optical system consists of a source of light 1, a condenser 2,. centrally symmetric photometric wedge 3, slit diaphragm 4, collimator 5, microscopes 6 and 7, television camera 8, transmitting tube 9 and television receiver 1O. On .. fig. 1, besides, are designated: 11 - the system is carried; 12 - the image plane of the slit. Light from source 1 through condenso 2 and photometric wedge 3 falls on a slit diaphragm 4 located at the focus of the collimator 5. The optical system is installed behind the collimator. Informing image of the slit 12. This image, enlarged by microscopes 6 and 7, is transferred by the lens of the television camera 8 to photocathode television transmitting tube 9, and then on the television channel. After discriminating and isolating the isophotes, in the form of a graph is reproduced on the screen of the television receiver 10. The graph of the scatter function on the television screen is obtained as follows (see Fig. 2). In the slit izofazheniya (see Fig. 2) a, constructed by the system under study, the distribution of the illumination across the image (in the direction of the left and Y) is determined by the scattering function of the studied optical system f (Y). In the absence of a wedge, the nature of the distribution of illumination 6 with a cross section is maintained regardless of the position of the cross section along the X coordinate. With the introduction of a wedge, (see Fig. 26), there is a decrease in all values of the maximum illuminations E., ... in accordance with the change in the transmission of the wedge by the values of T,, Tj .ts, ..., tq. Essentials in each section and all other values are reduced. Thus, the illumination level along the X axis (along the slit image) changes in accordance with the change in the wedge transmission. If Construct a line of equal illumination level (isophote) of such an image, then this line will represent the graph of the function of the distribution of illumination in axis x and y. The isophote is distinguished as a black and white border in the image on the screen of a television set tuned to high contrast mode. Since the proposed device allows obtaining a graph of the scattering function of the system under study directly at the time of measurement, the time required to obtain this information is eliminated, and the measurement process with the help of the proposed installation acquires an exceptional efficiency, while the laboriousness of the measurement decreases sharply. The possibility of continuously observing the graph of the scattered function directly in the process of restructuring the system under study (for example, its focusing, adjusting, etc.) creates qualitatively new possibilities for fast and directional acquisition of the required scattering function during reorganizations, i.e., the required image quality . With BT, since the control over image quality during adjustment of the system is not carried out at certain points, but continuously, the measurement with the aid of the proposed setup is characterized by high reliability; in addition, the device makes it possible to drastically improve the accuracy of adjustments and other relays of systems (for example, adjusting the astronomical mirror unloading during its processing and control, focusing lenses, etc. Strictly linear transmission of the logarithm of equipment is also provided and maintained in a wide range of up to 4 pores dkov, sufficient light output in the optical-measuring system, the independence of the accuracy of the transfer of the apparatus function from the size of the scanning spot and the independence of accuracy, the measured function from the parameter Characteristics in the photodetector, except

the steepness that is maintained at the maximum.

Claims (4)

1. A device for controlling the image quality of an optical system, containing a sequentially installed light source, a test object, a collimator, the focal plane of which is combined with the test object, and an image receiver, distinguished by the fact that in order to increase the accuracy and reliability of the control, a centrally symmetric photometric wedge is installed in the plane of the test object from the side of the light source, combined with its center with the optical axis. 2. The device according to claim 1, which is so that, for the purpose of controlling simultaneously in two mutually perpendicular 5x planes, the test object is executed in the form of two mutually perpendicular transparent strokes. 3. The device according to p. I, of which is, in order to increase the operational efficiency of the monitor, the image receiver is implemented in the form of a television system with discrimination of the video signal level. Sources of information taken into account in the examination 1. Maksutov PP Production and research of astronomical optics. ., Tostekhizdat, 1948. 2. Zverev, V.A., et al. Optical-mechanical industry, 1976, No. 8, with. 14. 3. Patent IWR No. 1185398, cl. 42 h 35/01, 1967. 4. CLAPS.Mygol K. Opftica LS1a, 1971, N9 2. ig.1 f-y Sh but