SU711410A1 - Device for measuring optical system characteristics - Google Patents

Description

(54) DEVICE FOR MEASUREMENT

CHARACTERISTICS OF OPTICAL SYSTEMS

It is united with the second output of the sync generator.

The drawing shows a block diagram of the proposed device comprising a kinescope 1 with deflecting coils 2, the optical system 3 under study, a photoelectric converter 4, an amplifier 5, a VCU b, an error output unit 7, an electronic signal simulator 8, a deflecting current generator 9 and a synchronous generator ten.

The device works as follows.

On the phosphor screen of the kinescope 1, a two-dimensional display of the test object is highlighted, each element of which is sequentially formed in time due to the screen being bombarded by an electron beam of an electronic spotlight of the kinescope modulated by density (current) according to the type of test object potential) applied to the control the entrance to the kinescope (to its cathode or modulator). The parameters and the shape of this potential Uj (I) are a priori known and are determined by an electronic signal simulator. At the same time, the deflection of the electron beam in the horizontal and vertical directions is carried out as usual in kinescopes using deflecting coils 2. Through the probe optical system 3, the element every point of the test object, for example, is transmitted sequentially in time in space. type of strokes. The output of the photoelectric converter 4 (this converter is made, for example, on the basis of a photomultiplier) produces an electrical signal | j, (- t).

Since the distribution of the luminance of the test object on the kinescope screen corresponds to a one-dimensional distribution and (i), then according to the posterior measured electrical distribution and (-b) removed from amplifier 5 (the purpose of amplifier 5 is the matching of the photoelectric converter 4 with the load). judged by the MTF of the investigated optical system 3 and its other parameters. The electrical signal and 2 (-fc) is input from the first output of the amplifier 5 to the input of the control unit 6 and the response of the optical system 3 being recorded. From the second output of the amplifier 5, the signal U2 (-b) is fed to the first input of the output unit, error 7, to the second input which, the signal Ij (t) comes from the second output of the electronic signal simulator 8. The error output unit 7 compares the reference test signal and (i) and the C-b signal) and outputs it in analog or digital form suitable for its supply to the digital computer, error signal: geometric, contrast, halftone, contrast-frequency, and

other distortions that the optical system 3 introduces. By means of preliminary calibration of the block, errors 7 compensate for the known distortions introduced by the device itself for measuring the characteristics of optical systems.

The electronic signal simulator (EIS 8 is synchronized by pulses of the horizontal and frame frequencies of the synchronous generator 10 arriving at the input of the EIS 8 from the second output of the synchronous generator 10. The source of the currents flowing through the deviation of the coil 2 is the alternating current generator 9, the input of which receives clock pulses from the first output of the clock generator 10,

The use of a space-modulated modulated electron beam and a spot-like scanning light stimulated by it allowed us to simplify the device for measuring the characteristics of optical systems, made it possible to determine the TFM more easily and with more confidence. optical systems and to expand its functionality due to the fact that the proposed device allows, in addition to MTF, to measure the geometric, halftone and contrasting distortions of the optical system.

Claims (2)

1.Novik F.S. and others. Filming optics. M., Art, 1968. 2. Samoilov V.F. and others. Television, M., Sv z, 1975, p. 175 (prototype). / g