SU627461A1 - Microfilm readout device - Google Patents

Description

The invention relates to information technology and can be used to read and process information from microfilms.

A device for reading information from microfilms is known, which contains an electron-beam indicator connected via amplifiers with digital-to-analogue converters and optically coupled to the phototransmitter unit 1.

The closest to the technical essence of the invention is a device containing an electron beam indicator, optically coupled through a first and second collimators installed in series with a photodetector unit, connected to an analog-to-digital converter connected to a data processing unit, connected via serially connected digital-analog converters and amplifiers to the electron-beam indicator 2.

However, these devices are characterized by insufficient reliability of reading information at different optical densities of microfilms.

The aim of the invention is to increase the reliability of reading the yctroduct for reading microfilms.

The goal is achieved by the fact that the device for reading microfilms contains an optical transparency with variable density, a light source, an additional photodetector and an amplifier, the light source being optically connected to a photomultiplier connected through an amplifier to an optical transparency with variable density,

which is set in the microfilm plane between the first and second collimators.

The invention is illustrated in the drawing. A microfilm reading device contains a data processing unit 1, the output of which is connected via digital-analog converters 2 and through amplifiers 3 to an electron-beam indicator 4, which is optically connected in series through a first collimator 5, a variable-density optical transparency 6, a second film 7 and a second collimator 8 with a block of 9 photodetectors, which is connected to the analog-to-digital converter 10.

In addition, the device contains a light source 11, optically coupled to an additional photodetector 12, which is connected via an additional amplifier 13 to an optical transparency 8 with variable density, and the output of the analog-to-digital converter 10 is connected to the input of the processing unit 1.

A device for reading microfilm information operates as follows.

Before scanning the information field of microfilm 7, the luminous flux from the source I of the light passes through the optical transparency 6, the control field of microfilm 7 and enters the additional photodetector 12.

In this way, the device performs a photometric measurement of the total transmittance of the optical transparency 6 and the readable microfilm 7.

If the optical density of the transparency 6 and microfilm 7 corresponds to a certain reference value, i.e., the converted electrical signal at the output of the additional photodetector 12 is equal to the base voltage of the additional amplifier 13, the voltage at the output of the amplifier 13 does not change, and, consequently, the coefficient the transmission of the optical transparency 6 is unchanged.

. After a fixed length of time required to perform the photometric operation, scanning of the information field of microfilm 7 begins, during which the position of the beam is outputted by coordinates "X and" Y to output the data from microfilm 7 from block 1. The last. using digital-to-analog converters 2 and amplifiers are converted into proportional analog signals that affect the deflection system of the electron-beam indicator 4.

The image of the light spot at the output of the electron beam indicator 4 is transferred by the first collimator to the plane of the microfilm 7 and through the second collimator 8 to the input of the block 9 of photodetectors. The optical signal converted by the photodetector unit 9 and the analog electrical signal are encoded using an analog-to-digital converter 10 and fed to the data processing unit 1 for further processing. When changing the microfilm 7, the photometric operation is performed again. If the optical density of the microfilm 7 changes, for example, decreases, then the voltage from the output of the additional photoconductor 12 increases in comparison with the base voltage.

In accordance with this change at the output of the additional amplifier 13, the voltage increases to reduce the transmittance of the optical transparency 6 to a value when the total optical density of the optical transparency 6 and the microfilm 7 correspond to the reference value. By increasing

The optical density of the readable microfilm 7 in the device is the reverse process, thereby ensuring the stability of the amplitude characteristic of the CD reading.

The optical transparency b itself can be performed, for example, on liquid crystals.

Claims (2)

1. Kovalevsky, V.A., ND. Digital tracking system of the reading automaton. “Automation and Instrumentation, 1960, № I. 2. Grishin, MP, et al. Automatic 0 forging and processing photographic images on a computer. M., 1976, p. 78