SU1012290A1 - Signal recognition device - Google Patents

Abstract

A device for spreading signals and signals, containing a converter & a converter connected to an amplifier connected to the detector, scanners and memory, and a series-connected limiter, the KOTcqjoro input is the first input of the device, the key whose input is connected to the pulse distributor, the first HHTerpaTqp, the input is connected to the distributed pulses, the comparison unit and the second integrator, the input of which is connected to the pulse distributor, and the output connected to the scanner and to the inputs ks lmut-. tori, characterized in that, with a recognition recognition reliability level, it contains -feets and & tezgrator, one input of which is the second input of the device, others are connected to the pulse distributor and the cpaBHeiraa unit, and the output is connected to another input of the comparison unit , ep & cops whose inputs are connected. to the pulse distributor and to you (L moves of the corresponding switches, and the outputs of the memory elements are connected to the functional converter, and the fourth integrator, one input of the core of which is connected to the detector, and the other connected to the pulse distributor. Yu | C

Description

The invention relates to automation in computing technology, in particular, to devices for recognizing signals. A device for recognizing signals is known, comprising a normalization unit, a scanner unit, a Polytron-type cathode ray tube, a derivative sign forming unit, a discrete-storage unit, an operational amplifier. and adder 1. The disadvantage of this device is low accuracy. Closest to the invention & A device containing a cathode-ray tube connected to scanners, a memory and an amplifier connected to the detector, and subsequently connected a limiter, a key and a neat integrator connected to a pulse splitter, a comparison unit, switches and logical block 2. This device is not sufficiently reliable. The purpose of the invention is to increase the reliability of the device. The goal is achieved by the fact that, in a device containing a functional converter connected to an amplifier connected to the detector, to scanners and memory, and the series-connected limiter whose input is the first input of the device, the key whose input is connected. The first integrator, whose input is connected to the pulse distributor, the emergency unit, and the second integrator, whose input is connected to the pulse distributor, and the output connected to the pa3Bepi unit and the inputs of the switches, are introduced to the pulse distributor , one input of which is the second input of the device, the others are connected to the pulse distributor and to the comparison unit, and the output is connected to another input of the comparison unit, the memory elements, whose inputs are connected to the pulse distributor and the outputs new switches, and the outputs of the memory elements are connected to a functional converter, and the fourth integrator, one input of which is connected to the detector, and the other connected to the pulse distributor. The drawing shows a block diagram of the proposed device. The device includes a limiter 1, a key 2, a first integrator 3, a block 4 of comparison, a second integrator 5, switches 6, memory elements 7, functional plates 8 of a cathode ray tube (CRT) functional converter 9, a third integrator 1O, a sweep block 11, block 12 memory, collector plates 13 CRT, amplifier 14, detector 15, fourth integrator 16 and distributor 17 pulses. The device works as follows. At the input, two identical signals are received successively at times. The first signal is used to determine and memorize its duration, as well as to synchronize the device. The second signal after transformation is compared with the standard. And according to the decision we can judge about the belonging of the presented signals to a particular class. Input. the signal arrives at limiter 1, which generates rectangular pulses equal to the duration of the signal. These pulses through the key 2, which is open a certain point in time, arrive at the first integrator 3, the output of which is formed linearly. increasing voltage. At the first moment of time, the key 2 breaks the input circuit of the integrator 3 and fixes a constant voltage to the third moment of time and its output, which is fed to the comparison unit 4. At the second time point, the third integrator 10 begins to integrate the DC voltage applied to its input. When the voltage at the output of the integrator 10 is compared with the voltage at the first input of block 4, the down-coupler 10 is reset to zero and again begins to integrate the input voltage. The output voltage from the integrator 5 is supplied in parallel to the control inputs of the switches 6, where it is compared with one of the specified DC voltages respectively. The memory elements in the ZLT receive voltages corresponding to the area bounded by the signal passing through the corresponding. switch 6. Block 11 is a large-scale amplifier, the gain of which and the initial offset to which

This means that the electron beam is deflected by the CRT plates that are supplied under all of the func- tional pasteinamic (AF-) as the voltage increases at the output of the integrator 5. The vertical offset of each of the FCs is detected by a change in current from the collector plates of the CRT.

The differential amplifier 14 performs an algebraic summation of the signal from the two collector plates. The total signal is sent to the detector 15 and then to the integrator 16, which stores the voltage corresponding to the total ("at the signal and qpaBmroaeT with a threshold value. The distance between the threshold value and the proportional ratio between the threshold signal from the 12 n pref The called input signal makes a decision on the class to which the signal is studied. The integrator 1 is connected to the distributor 17 and operates from a sync pulse in the interval between the third and second time points.

Thus, the introduction of new nodes and blocks, as well as new designs of linkage, can significantly increase the reliability of recognition of the device.

Claims (1)

A SIGNAL RECOGNITION DEVICE, comprising a functional converter connected to an amplifier connected to a detector, to scan and memory units, and a limiter connected in series, the input of which is the first input of the device, the key whose input is connected to a pulse distributor, the first integrator whose input sub— 'keys to the pulse distributor, a comparison unit and a second integrator, the input of which is connected to the pulse distributor, and the output' is connected to the scan unit and to the inputs of the commutator characterized in that, in order to increase recognition reliability, it contains a third integrator, one input of which is the second input of the device, the other is connected to a pulse distributor and to the comparison unit, and the output is connected to another input of the comparison unit, memory elements, the inputs of which are connected - g, are to the pulse distributor and to the outputs of the corresponding switches, and the outputs of the memory elements are connected to the functional converter, and the fourth integrator, one input of which is connected to the detector and the other is connected pulse distributor.