SU1034097A1 - Cathode-ray code converting device - Google Patents

Abstract

ELEKTRONNSSHUCHEVOE KODOPRBOBRAZUSCHEE USTROYaStaO comprising electron-kodopreobrazuk auyu tube, which are sequentially arranged an electron gun, two pairs otklondaidagh plates for deflecting the electron beam in columns and rows, respectively, and an electron multiplier comprising a cathode and a system of diodes and Ts1kzhe load electronic umaozhitel and the generator step-nap. Oia, the output of which is directly connected to the second pair of deflecting plates, o. In order to expand the functional capabilities of the device at the same time; convert the code parameters by duration, phase and amplitude, the cathode is made of arrays of insulated emitters forming a dihedral angle, the top of which is turned to the side the electron gun, and the linear dimensions of the isolation intervals and discrete emitters of each matrix are different in columns and equal in rows, with the first pair of deflecting plates for the deflection (L of the electron beam in columns connected to the input generator of steps via the Differentiation circuit С / д 4: О СО

Description

The invention relates to communication technology and can be used in the development and creation of a coding device for systems with pulse code modulation. It is known that the use of a binary Yes-No code for transmitting various levels (or amplitudes) of a signal makes the communication system with pulse code modulation highly effective and noise-resistant, allowing for the regeneration of pulses upon repeated retransmission and thereby eliminating the accumulation of distortions. In particular, for high-quality transmission of information, when the amount of distortion should not exceed 1%, the required number of pulses in a code sequence group must be at least seven, which provides a display of more than one hundred levels of the dynamic range of the signal. To convert a single pulse of information into a pulsed binary system, a numerical value that corresponds to the amplitude of the information impulse was suggested by many different schemes that were not applicable in systems with a large number of channels because of their complexity and low throughput. This circumstance stimulated the search for and development of technical solutions that ensure the efficient conversion of signals into radio channels by code pulse modulation based on unified instruments. Encoding devices are known for communication systems with pulse code modulation based on an electron beam tube containing a guide grid and a selector electrically orifices arranged irregularly according to the law of variation of the speed of electron beam motion through electrode C 1. This is characterized by the complexity of the structural composition and the need for an additional channel to enhance the signal. . The closest to the present invention is an electron-beam code-transformer device containing an electron-beam code-transformer search tube, in which an electron gun, two pairs of deflecting plates, are successively located; for deflecting the electron beam along the columns and rows, respectively, an electron multiplier, including a cathode and a system, as well as a load of the electron multiplier, and a generator of stepwise voltages, the output of which is directly connected With a second pair of deflecting plates 2. The disadvantage of the device is that the efficiency of code conversion of the signal is limited by the fixed value of the integral gain of the electron multiplier and the magnitude of the feedback voltage applied to the deflection plates through the delay line with a fixed delay time. The latter circumstance does not allow pri-. change this device to convert the code with a variable pause between pulses. In addition, the placement of a pause-formation collector in the code group in front of the dynode multiplier system reduces the efficiency of its use and creates constructive redundancy in it. The purpose of the invention is to expand the functionality of the device due to the simultaneous conversion of the code parameters by duration, phase and amplitude. The goal is achieved by the fact that, in an electron beam code-conversion device containing an electron beam; a code-converting tube in which an electron gun is sequentially arranged, two pairs of deflecting plates for deflecting an electron beam along columns and rows, respectively, and an electron multiplier, including a cathode and a dynode system, as well as a load of an electron multiplier and a step voltage generator, the output of which is directly connected to the second a pair of deflecting plates, the cathode is made of arrays of insulated emitters that form a dihedral angle, the top of which faces the electron gun, a. The linear dimensions of the isolation intervals and discrete emitters of each matrix are different in columns and equal in rows, with the first pair of deflecting plates for deflecting an electron beam in columns connected to the input of a step voltage generator through a differentiating circuit. Fig, 1 shows a possible variant of the device; in fig. 2 — one of the cathode faces for the model of a five-matrix J-matrix of six isolated emitters in each column (indicated by hatching). In the static mode, when there is no voltage sweep and a signal of the code being converted, electron gun 1 is functionally connected through signal plates 2 and horizontal scan plates 3 by means of a primary stream of 4 electrons with a dielectric section at the apex of the two Horned angle of the matrix cathode 5 of the electron multiplier 6, into a common circuit the anodes of which are connected to the load resistance 7 R, while the signal plates 2 through the output 8 of the differentiating circuit are connected to the input of the 9-stage voltage generator, the output of which is connected to the plates. 3 line scan. dynamic mode, when the plates are affected by the voltage of the signal V represented, for example, by a group of unipolar. pulses in binary code, the primary electron flux deviates from the initial position, running along the first column of one face of the matrix cathode, away from its top. When this occurs, the angle of incidence of the V beam of electrons to discrete isolated areas of the multiplier cathode increases, which contributes, after amplification in its cascades, to the formation in load 7 of a group of voltage pulses of various duration and pause, the amplitude of which is determined from the relation: V.KJR exp - Bcos f- (U) j. (i; where K is the integral gain factor of the multiplier f I is the current strength in the primary electron beam; the current value of the angle of incidence of the electron beam on the surface of the cathode; A and B are constant values. At the same time, the input of the 9 step step generator the voltage from the output 8 of the differentiating circuit is given a positive field signal that holds the generator in a stalled mode. By the first input pulse of the code group to be transformed, the electron beam performs the inverse scan of the first digit matrices, creating an inverse sequence of pulses in load 7, whose amplitude is determined by the ratio 1. In this case, a negative polarity output from the output 8 of the differential circuit of the circuit is fed to reliepaTop 9, ensuring that a step voltage is formed at its output until plates 2 and the differentiating circuit will not receive the next impulse of the code being transformed, under the action of which the beam again makes a direct and reverse viewing movement, but already along a different column of matrixes with a positional number depending on t interval of pause in the source code As a result, in the load 7 two groups of pulses with and inverse codes will be created again, the parameters of which are different from the previous ones; the control codes and are governed by the structure of the corresponding column. If it is necessary to force the replacement of the code group structure into the process of converting the original signal, it is enough to change the quantization interval of the horizontal scanning line voltage by 2 pL, where n is a positive integer, d is the diameter of the electron beam, bipolar pulses are present in the source code, then the procedure for converting them is carried out in a similar way using column groups of two cathode matrix edges in accordance with polarity voltage signal. The parameters of the transformed code are governed by the structure of the columns of the matrix cathode, and the possible number of code groups with different combinations of pulse sequences is determined by the ratio of the linear dimension of the matrix along the line to the diameter d of the cross section of the cathode-focused electron beam. Under the conditions of practically achievable values of 1 cm, dg 100 µm, taking into account the isolation interval between the columns not less than d Q, the number of different code groups is 50. This circumstance allows, if necessary, fast reconfiguration of the channel for transmitting information from - using one or several possible variants of code groups of dihedral matrices. This increases the privacy, immunity, and reliability of the communication system. Thus, the proposed technical solution provides for combining the process of amplifying and converting a code of a pulsed (or continuous) signal in duration, phase and amplitude in the monoblock design of the device, which expands its functionality while simplifying the structure, allows for essentially and quickly transforming the spectrum of the transmitted signal following a certain law, thereby accompanying it with selective signs to isolate the additive mixture with noise and interference, helping to increase reliability and the robustness of the communication system to interferences of various origins. For the technical implementation of the invention, it is sufficient to combine in the vacuum volume the structural elements of commercially available electronic components

NOJ RJiraKM, deflection plates and electron multiplier, the cathode of which must be performed, for example, in accordance with FIG. 1 .and FIG. 2

The technical efficiency of the proposed device consists in ensuring simultaneous code conversion by three parameters in a monoblock design. .

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Claims (1)

ELECTRON BEAM CODE CONVERTER DEVICE containing an electron beam code conversion tube in which an electron gun is arranged in series, two pairs of deflecting plates for deflecting an electron beam in columns and rows, respectively, and an electron multiplier including a cathode system of diodes, as well as the load of an electronic multiplier and a voltage multiplier generator the output of which is directly connected to the second pair of deflecting plates, about. Including the fact that, in order to expand the functionality of the device by simultaneously converting the code parameters in duration, phase, and amplitude, the cathode is made of matrices of isolated emitters forming a dihedral angle, the vertex of which is turned into side of the electron gun, and the linear dimensions of the insulation intervals; and discrete emitters of each matrix are different in columns and equal in rows, with the first pair of deflecting plates for deflecting an electron beam in columns connected to the input of the step voltage generator through a Differentiating circuit.