RU2649675C1 - Hydroacoustic control method of torpedo - Google Patents

Abstract

FIELD: acoustics; weapons and ammunition.

SUBSTANCE: hydroacoustic control method of torpedo, containing discharge of torpedo that emits probing signals at fixed intervals, reception of echo signals by hydrolocator of lightning of near scenario, allocation of classification features, definition of object class, generation of command signal, two torpedoes are simultaneously used exhaust to the target, the first of which begins to emit probing signals at fixed intervals after the release of the second torpedo in the direction of the target, which is controlled by wires, the receiving path of the second torpedo receives echo signals reflected from the target, transmits it to the hydrolocator of near scenario, which corrects the movement of the second torpedo.

EFFECT: hydroacoustic method of torpedo control is proposed.

1 cl, 1 dwg

Description

The invention relates to the field of hydroacoustics and can be used to build control systems for the movement of torpedoes using sonar stations for lighting near situations.

Modern torpedoes are self-propelled autonomous uninhabited vehicles that are used on modern submarines to destroy a detected object. Hydroacoustic stations are installed on modern torpedoes, which allow autonomously detecting an object and carrying out its destruction. However, modern sonar systems installed in submarines detect a moving torpedo and destroy it on the way and, in addition, they use sonar countermeasures and install simulators that are detected as objects. In this situation, the sonar complex of the torpedo is not able to detect a real object and then use the sonar station for lighting the near situation, which controls the torpedo through the wires (VV Surin, Yu.N. Pelevin, VL Chulkov. “Anti-submarine vehicles of foreign fleets” M .: Moscow, 1991, pp. 63-80).

Known sonar system according to patent No. 2501038, which contains NGAS OBO, including the antenna system, pre-processing path, DAC-1 and DAC-2, a unit for processing direct propagation signals from a torpedo, a unit for determining the coordinates of the position of the torpedo relative to the navigation station and relative to the target, block definitions of control commands for the movement of a torpedo, a generator and an antenna for emitting control commands, a classification system for echo signals received from the radiation of a sonar of a torpedo, a control unit for the movement of a torpedo rows comprising a receiver with an antenna, a decoder and the actuator elements to influence the movement of the torpedo.

The closest analogue in terms of the number of common features is the method implemented by the system according to the patent No. 2501038. In accordance with this method, a torpedo emits a probe signal at fixed intervals, NGAS OBO receives echoes reflected from the target, determines the coordinates of the detected target, determines the position of the moving torpedo, measures the classification signs of the detected target, determines the deviation of the torpedo from the direction of movement to the target, generates torpedo movement control signals and emits these signals. The torpedo acoustic system receives control signals, decodes torpedo control signals, turns on torpedo control actuators and corrects the movement of the torpedo.

The disadvantage of this method, implemented in a hydroacoustic system, according to patent No. 2501038, is that when torpedoes are used at large distances, the echo signals from the target will decay, therefore it will be impossible to detect the target, classify and control the torpedo for its intended purpose.

Solving the problem of multiclass automatic recognition of echo signals from a torpedo sonar under conditions of a priori uncertainty is quite laborious and in most cases impossible. To solve this problem, not only good technical means are needed that will provide sonar armament with high tactical and technical characteristics. Autonomous torpedo sonars do not have such characteristics and cannot effectively cope with the solution of the problem of automatic detection, and even more so of classification, of detected targets with the required reliability against the background of unsteady interference caused by a complex noise-signal situation. It is impossible to equip a torpedo with a good sonar active-passive complex and to improve the noise-signal situation at the inlet of the torpedo sonar receiving path, which arises for objective reasons related to the movement of the torpedo and the presence of surface and bottom reverberation when the sounding signal is emitted. The noise level of the torpedo movement significantly exceeds the level of interference during the movement of a submarine carrier sonar complex. Currently, existing torpedoes can be used at long distances, so the echo signals from the detected target will attenuate, which will not allow to reliably classify the detected targets in the conditions of hydroacoustic counteraction with the setting of simulators. Therefore, the method proposed in the prototype method does not provide high-quality detection and classification at long distances and accurate guidance of the torpedo.

The objective of the present invention is to increase the effectiveness of the functionality of the sonar method of detecting targets and controlling a torpedo, based on the use of a torpedo and sonar lighting near the situation.

The technical result from the use of the present invention is to increase the efficiency of detection and classification of the detected target using autonomous guided torpedoes at large distances to the target.

The specified technical result can be achieved if, in a method containing the release of the first torpedo towards the target emitting sounding signals at fixed intervals, receiving echo signals from the target by the hydro-acoustic lighting station of the near situation, highlighting the classification features of the echo signal from the target, determining the class targets, the formation of torpedo control signals, new signs have been introduced, namely, when the first torpedo starts emitting sounding signals towards the target, the second torpedo is fired, control pulled along the wires in the direction of the target, the receiving path of the second torpedo receives the echo signals reflected from the target emitted by the first torpedo, amplifies the received echo signals, converts them into a digital code and transmits them via a wire control line to the input of the near acoustic lighting station, by which receive a digital signal, form the directivity characteristics of the receiving hydroacoustic antenna, determine the position of the target relative to the direction of movement of the second torpedo, determine the position of the whether relative to the direction of the first torpedo’s movement, the classification signs of the target are distinguished and the class of the target, the distance to the target are determined, and a signal for deviating the direction of movement of the second torpedo from the target’s position is formed, after which a control signal is transmitted by wire to the second torpedo, upon receipt of each next probe adjust the direction of movement of the guided second torpedo to achieve the goal.

The invention consists in the following: with the help of two torpedoes it is possible to spread the radiation and reception. In this case, the radiation occurs at a distance close to the detected target, and at this distance the probing signal does not have time to significantly weaken. In addition, the second torpedo is not affected by the reverberation that follows the emission of the probe signal, which limits the duration of the emitted signal and, accordingly, the radiated energy and the associated detection range. The reflected echo propagates to a shorter distance and is received by the receiving antenna of the second torpedo against the background of noise of its own movement, and not against the background of surface reverberation. This allows you to increase the information content of the classification and the accuracy of the second torpedo control, which is used for its intended purpose.

The invention is illustrated in FIG. 1, which shows a block diagram of a system that implements the proposed method.

The system (Fig. 1) contains a torpedo 1 with a sonar emitting sounding signals, a torpedo 2 receiving echo signals, which includes a block 3 for receiving echo signals and a block 4 for receiving control signals. Hydroacoustic station 5 for lighting the near environment, which includes an input information receiving unit 6, a spatial processing unit 7, a temporary processing unit 8, classification feature extraction unit 9, a decision-making class decision unit 10, an operator display and control unit 11, a unit 12 determine the coordinates of the object, block 13 generating control signals, block 14 for transmitting control signals.

The hydro-acoustic lighting station of the near environment is a known device that is used in the prototype, can be implemented according to the patents of the prototype.

Currently, almost all hydroacoustic equipment is performed on special processors that convert the acoustic signal into a digital form and digitally generate directivity characteristics, multichannel processing and spectral processing, interference measurement, signal detection and comparison with a threshold, time and frequency processing, and deciding on a goal. For a high-quality solution to the problems of processing sonar information in modern ship sonar equipment (stations), special processors based on a digital computer system are used, which have high performance, functional reliability and small dimensions. Using special algorithmic and software, special processors can solve all the problems of generating and processing received hydroacoustic signals, detecting echo signals, measuring their parameters, including determining the spatial and temporal characteristics of an echo signal (Yu.A. Koryakin, S.A. Smirnov, G.V. Yakovlev. “Shipboard sonar equipment”, St. Petersburg: “Nauka”, 2004, p. 281).

Telecontrolled wire torpedoes that are used for their intended purpose are well-known devices widely used in modern fleets (V.V. Surin, Yu.N. Pelevin, V.L. Chulkov. “Antisubmarine assets of foreign fleets.” M.: Military Publishing House , 1991) As a torpedo with the sound of the probe signal, a conventional torpedo can be used, in which minor changes are made to the operating mode associated with controlling the sequence of radiation of the probe signal.

Using the proposed system, the claimed method is implemented as follows.

After a decision has been made to detect a submarine at a great distance, a torpedo 1 with a sonar with the emission of sounding signals is released. In the direction of the intended target, the torpedo 1 first moves without radiation, and at a certain distance it starts emitting sounding signals. The time of movement of the first torpedo without radiation is selected by the operator depending on the estimated distance of the detected target. With the beginning of the emission of the sounding signals of the first torpedo, a second torpedo 2 with a control system for wires and a receiving unit 3 reflected from the detected target when the sounding signals of the torpedo 1 is emitted is received. The echo signals received by the unit 3 are amplified and transmitted via wire communication to the input of the near acoustic sonar station 5 the setting. Based on the received digital information, spatial processing is performed in block 6, which allows you to generate narrow directivity characteristics and determine the spatial parameters of the detected target and its deviation from the motion path. In block 7, the received information is temporarily processed and the time classification signs, distance and target speed are selected. In block 9, classification features are selected according to the measured spatial and temporal information, based on which, in block 10, a decision is made about the class of the detected target. In block 11, all information is evaluated by the operator and a decision is made to adjust the direction of movement of the second torpedo relative to the detected target, the coordinates of which are determined in block 12. In block 13, signals are generated that should correct the movement of the second torpedo to the selected target. Through the signal transmission unit 13, the correction information is transmitted to the dashboard 2 by wire to the control signal receiving unit 4, after which specific control signals are received to the actuators existing on the remote control dashboard.

Thus, using diversity radiation and reception, which ensures the absence of surface reverberation at the input of the receiving antenna, and using the energy potential of the processing system of the hydroacoustic station for lighting underwater situations, it can be increased the efficiency of controlling the use of torpedo weapons for their intended purpose.

Claims (1)

Hydroacoustic method of controlling a torpedo, comprising releasing the first torpedo towards the target emitting sounding signals at fixed intervals, receiving echo signals from the target by the hydroacoustic station for lighting the near situation, highlighting the classification of the echo signal from the target, determining the class of the target, generating torpedo control signals characterized in that when the first torpedo starts emitting sounding signals towards the target, a second torpedo is launched, guided by wires in a direction and to the target, the receiving path of the second torpedo receives the echo signals reflected from the target emitted by the first torpedo, amplifies the received echo signals, converts them into a digital code and transmits them via a wire line to the input of the near-acoustic sonar station, through which the digital signal is received form the directivity characteristics of the receiving sonar antenna, determine the target position relative to the direction of movement of the second torpedo, determine the target position relative to the direction of movement The first torpedo displays the classification of the target and determines the class of the target, the distance to the target, and also generates a signal for deviating the direction of movement of the second torpedo from the position of the target, after which they transmit a control signal by wire to the second torpedo, and upon receiving each next sounding signal, they correct the direction of movement guided second torpedoes to achieve the goal.

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