SU523360A1 - Optical spectrum analyzer - Google Patents

Description

one

The design relates to radio measuring technology and can be used to create devices for parallel spectral analysis of electrical signals in real time.

Optical spectrum analyzers 1 are known, containing a projection system, a reference transparency and a reading system.

However, such analyzers have low resolution and contrast.

Strobe spectral analyzers 2 are known, comprising a cathode ray tube, a projection system, a reference transparency, a raster of photodiodes, and a readout and indication system. However, they have a limited range of analyzed frequencies, and, in addition, the reference transnaunt needs mechanical rotation.

The purpose of the invention is to expand the range of analyzed frequencies and simplify.

This is achieved by the fact that the proposed optical spectrum analyzer is equipped with a matching raster placed between the reference transparency and the photodiode raster, the reference transparency being made in the form of a matrix of fixed spatial frequency filters, and the projection system is made in the lens.

The drawing shows the scheme of the proposed analyzer.

The analyzer contains a cathode-ray tube 1, a projection system (lens raster) 2, a reference transparency 3, a matching raster 4, a raster of 5 photodiodes, a system 6 for reading and indicating.

The analyzer works as follows. The signal under investigation modulates the intensity of the beam of the cathode ray tube 1 and expands in time along the base X. The cylindrical raster 2 images from tube 1 are multiplied along the X axis onto the reference transparency 3, whereby the size of the image projected onto the transparency 3 corresponds to the size of the filter along the X axis transparency 3. From each filter of the matrix of the transparency 3 by a matching raster 4, the light flux is collected on the photodiodes of the raster 5. At the output of the raster of 5 photodiodes with the help of system 6, temporary integration and indication are performed This is the result of spectral analysis in a capacitive or amplitude form. A luminance maximum or amplitude maximum is observed in that frequency channel in which the spatial structure of the image on the screen of the cathode ray tube 1

coincides with the spatial structure

3 matrix transparency filter in time

sweep progress equal to accumulation.

Claims (2)

The pitch of the lenticular screen 2 is equal to the size of the frequency channel on the transparency 3, made in the form of a matrix of non-fixed spatial frequency filters. This matrix is a sequential recording in a density form at equal intervals along the X axis of different spatial frequencies, the spatial frequency being proportional to the channel dimension. Frequency channels are consecutive line by line recorded throughout the frame. The resolution of the analyzer is determined by the maximum number of periods in the last filter of the matrix of the transparency 3 and is equal to the number of frequency channels. Since the reference transparency 3 is made in the form of a matrix of fixed filters, the range of analyzing frequencies is determined only by the duration of the sweep on the electron-beam tube 1 and the constant time at the output of the photodetectors and can reach several megahertz. Claim 1. An optical spectrum analyzer comprising a cathode ray tube, a projection system, a reference transparency, a photodiode raster and a readout and indication system, characterized in that it is equipped with a matching raster placed between the reference transparency and raster photodiodes. 2. The analyzer according to claim 1, wherein the reference transparency is made in the form of a matrix of fixed spatial frequency filters, and the projection system is made in the form of a lens raster. Sources of information taken into account in the examination. 1.S. B. Gurevich, V. K. Sokolov. Problems and tasks of optical information processing. Materials of the V All-Union School on Holography, L., 1973, pp. 150-159 (analog). 2.L. P. Lazarev. Infrared and light - devices for homing and pointing aircraft, M., 1966, p. 312-314 (prototype). - / mTP ex. /