RU135869U1 - ONE-SIDED UNDERWATER RADIO COMMUNICATION SYSTEM - Google Patents

Abstract

1. A one-way radio communication system comprising a communication channel in the form of an air and water environment, a first and second surface objects, an underwater object, the first surface object comprising a message source, an encoder, a modulator and a radio transmitter, and an air antenna, a second surface object, connected in series contains aerial antenna connected in series, a radio receiver, a converter, a transmitter and a water antenna device, an underwater object comprises an antenna connected in series moreover, a radio receiver, a decoding device and a registrar, characterized in that the second surface-mounted object is provided with an additional output device, in which the input terminals are connected to the output of the transmitter, and the output terminals are equipped with a water antenna device, the underwater object is equipped with an additional input device, in which the input terminals connected to the antenna device, and the output terminals to the input of the radio receiver, and the additional output device contains serially connected input terminals, the first an objective two-terminal, an amplifying element, an output selective two-terminal, output terminals, the first selective four-terminal being made in the form of a parallel oscillatory circuit containing a capacitor and an inductor with a coupling winding, the terminals of which are connected to the input terminals of the device, the amplifying element contains two amplifiers with inputs connected to the potential points of the oscillatory circuit, and the outputs with the inputs of the second selective bipolar, which is made in the form of two parallel

Description

The utility model relates to radio engineering, in particular to one-way radio communication systems, to command radio links for connecting a ground object with an underwater object and using a communication channel in the form of air and water.

A known system of one-way radio communication using a communication channel in the form of an air medium and containing two objects. The first object contains a series-connected message source, encoder, modulator, radio transmitter and antenna.

The second object comprises an antenna, a radio receiver, a decoding device, a recorder, or a message recipient connected in series. Both objects are placed in the air [1]. A known system of one-way electromagnetic communication for communication surface object - a diver. The communication channel is made in the form of sea water. The one-way communication system contains a surface transmitter type SWL - 30 with an antenna located in the aquatic environment and a receiver SWL - 50 located in the aquatic environment and reinforced with nylon straps on a diver [2]. However, the communication range is not more than 100 m.

The closest in technical essence and combination of features is a system of unilateral underwater radio communications, the description of which is given in the patent of the Russian Federation No. 110575 [3].

The known one-way radio communication system using a communication channel in the form of air and water contains the first and second surface objects, an underwater object, while the first surface object contains a message source connected in series, an encoder, a modulator, a radio transmitter and an air antenna, the second surface object contains connected sequentially an air antenna, a radio receiver, a converter, a transmitter and a water antenna device.

The underwater object contains an antenna device, a radio receiver, a decoding device and a recorder connected in series, the underwater object contains an antenna device and an input device, in which the input terminals are connected to the antenna and the output terminals to the input of the radio receiver.

The objective of the utility model is to expand the arsenal of technical means for one-way radio communication of a surface object with an underwater one, using a communication channel in the form of air and water.

The technical result is an increase in reliability with long-distance radio communications.

The technical result is achieved by the fact that in a one-way radio communication system using a communication channel in the form of air and water, and containing the first and second surface objects, an underwater object, the first surface object contains a message source, encoder, modulator, radio transmitter connected in series an aerial antenna, the second surface object comprises an aerial antenna, a radio receiver, a converter, a transmitter and a water antenna device connected in series, underwater the object contains an antenna device, a radio receiver, a decoding device and a recorder connected in series, according to the proposal, the second surface object is equipped with an additional output device, in which the input terminals are connected to the output of the transmitter, and the output terminals are connected with a water antenna device, the underwater object is equipped with an additional input device, in which the input terminals are connected to the antenna device, and the output terminals are connected to the input of the radio receiver, and the additional output device is neighbors input terminals, a first selective two-terminal, an amplifying element, an output selective two-terminal, output terminals, the first selective four-terminal being made in the form of a parallel oscillatory circuit containing a capacitor and an inductor with a coupling winding, the terminals of which are connected to the input terminals of the device, an amplifying element contains two amplifiers in which the inputs are connected to potential points of the oscillatory circuit, and the outputs with the inputs of the second selective a two-terminal device, which is made in the form of two parallel circuits connected in series, with the midpoint connected to a common bus, and the potential terminals of the two-terminal device connected to the output terminals of the device; at the underwater object, the input device contains input terminals connected in series, an input selective four-terminal device, an amplifying element, an output selective quadrupole and output terminals, while the amplifying element is made in the form of a differential amplifier containing at the input the first and the second input, the output is the first and second output, the input selective four-terminal contains a circuit including a first contact, to which the first conclusions of the first and second capacitors are connected, the first output of the first two-terminal, the second contact, to which the first conclusions of the third and fourth capacitors are connected, the first the output of the second two-terminal network, with the second output of the first capacitor connected to the first input terminal, the second output of the second capacitor connected to the first input of the differential amplifier, the second output of the first the two-terminal is connected to a common bus, the second terminal of the third capacitor is connected to the second input terminal, the second terminal of the fourth capacitor is connected to the second input of the differential amplifier, the second terminal of the second two-terminal is connected to the common bus, the output four-terminal contains a third two-terminal, in which the first terminal is connected via the fifth capacitor with the first output of the differential amplifier, the second output of the two-terminal network through the sixth capacitor is connected to the second output of the differential amplifier Thus, each of the two-terminal circuits is made in the form of an inductance coil and a variable capacitor connected in parallel, the inductance coil of the third two-terminal circuit is equipped with a coupling winding, the terminals of which are connected to the output terminals of the device, respectively.

A distinctive feature of the proposed one-way communication system is that the second surface-mounted object is equipped with an output device connected between the output of the transmitter and the input of the water antenna system, and the fact that the underwater object is equipped with a highly selective input device connected between the output of the antenna device and the input of the radio receiver, the underwater object, the antenna device contains an input device in which the input terminals are connected to the antenna and the output terminals to the radio input, while the input device The property contains input terminals connected in series, an input selective four-terminal, an amplifying element, an output selective four-terminal, and output terminals, while the amplifying element is made in the form of a differential amplifier containing the first and second input at the input, the first and second output, and the selective selective four-terminal at the output contains a circuit including a first contact, to which the first terminals of the first and second capacitors are connected, a first terminal of the first two-terminal network, and a second terminal to which the first terminals of the third and fourth capacitors are connected, the first terminal of the second two-terminal, the second terminal of the first capacitor connected to the first input terminal, the second terminal of the second capacitor connected to the first input of the differential amplifier, the second terminal of the first two-terminal connected to the common bus, the second terminal of the third capacitor is connected with the second input terminal, the second terminal of the fourth capacitor is connected to the second input of the differential amplifier, the second terminal of the second two-terminal is connected to a common another, the output four-terminal contains a third two-terminal, in which the first terminal through the fifth capacitor is connected to the first output of the differential amplifier, the second terminal of the two-terminal through the sixth capacitor is connected to the second output of the differential amplifier, each of the two-terminal is made in parallel inductance coil and a capacitor of variable capacitance, the inductance coil of the third bipolar is equipped with a coupling winding, the terminals of which are connected to the output terminals of the device Twa respectively.

The essence of the utility model is that the second surface-mounted object is equipped with an output device connected between the output of the transmitter and the input of the water antenna of the system, and also that the underwater object is equipped with a highly selective input device connected between the output of the antenna device and the input of the radio receiver.

Figure 1 shows the functional diagram of the proposed system of one-way radio, figure 2 shows the structural diagram of the output device of the second surface object, figure 3 shows the structural diagram of the input device of the underwater object.

The one-way radio communication system (see FIG. 1) comprises a first ground object 1, a second ground object 2 and an underwater object 3.

The first ground-based object 1 comprises a series-connected message source 4, an encoder 5, a modulator and a radio transmitter 6 and an air antenna 7. The second ground-based object 2 comprises a series-connected air antenna 8, a radio receiver 9, a converter 10, a transmitter 11, an output device 12 and a water antenna system 13. The underwater object 3 comprises a series-connected antenna system 14, an input device 15, a radio receiver 16, a decoding device 17 and a recorder 18.

Figure 2 shows the structural diagram of the output device 12.

The output device 12 contains input terminals 19 and 20, to which the leads of the communication winding of the input resonant oscillatory circuit 21 are connected. The outputs of the circuit 21 are connected to the inputs of the amplifiers 22 and 23. The outputs of the amplifiers are connected to the output terminals of the device 24 and 25. The device contains a circuit containing oscillatory circuits 26 and 27 connected in series. The findings of the circuit are connected to the output terminals of the device. Each oscillating circuit is made in the form of a two-terminal circuit containing an inductor and a capacitor connected in parallel. The midpoint of the circuit is connected to a common bus 28. Loops 21, 26, and 27 are tuned to the carrier frequency of the transmitter 11.

Figure 3 shows the structural diagram of the input device 15.

The input device 15 comprises series-connected input terminals 29 and 30, an input selective four-terminal 31, a differential operational amplifier 32, an output selective four-terminal 33, in which the output is connected to the output terminals 34 and 35.

The selective selective four-terminal input 31 contains a first contact 36, which is connected to the input terminal 29 through the first capacitor 37, connected to the first input 39 of the differential amplifier 32, and to the first output of the first two-terminal, which is made in the form of inductors 40 connected in parallel a variable capacitor 41. The second terminal of the first two-terminal is connected to a common bus 42. The four-terminal 31 contains a second contact 43, which is connected via a third capacitor 44 n with an input terminal 30, through a fourth capacitor 45 connected to the second input 46 of the differential amplifier 32, and to the first output of the second two-terminal, which is made in parallel connected inductance coil 47 and a capacitor of variable capacitance 48. The second output of the second two-terminal is connected to a common bus 42 .

The selective output four-terminal 33 contains a third two-terminal, which is made in parallel in the form of a variable capacitor 49 and an inductor 50, which is equipped with a coupling winding 51. The first output of the third two-terminal through the fifth capacitor 52 is connected to the first output 53 of the differential amplifier 32. The second output of the third two-terminal through the sixth capacitor 54 is connected to the second output 55 of the differential amplifier 32.

The conclusions of the communication winding 51 are connected to the output terminals 34 and 35, respectively.

As an amplifying element 32, a differential amplifier made on the AD 8351 microcircuit from ANALOG DEVICES can be used.

The capacitance of capacitors 41, 48, and 49 is changed synchronously. The first, second, and third two-terminal devices are tuned to the carrier frequency of the received signal.

The terminals of antenna 14 are connected to terminals 14 and 15.

The input device operates as follows.

At terminals 29 and 30, there is a signal received by antenna 14 with level E.

The input of the four-terminal 31 is connected to the terminals 29 and 30, which at the input contains the first and second parallel oscillatory circuits connected in series and connected to the input terminals of the device 29 and 30 by means of capacitors 37 and 44. The midpoint of the two-terminal connection is connected to the common bus 42.

In the proposed device, there is no shunting of each of the circuits by the resistance of the antenna.

Both circuits are tuned to the frequency of the received signal. In practice, the voltage on each of the circuits will be equal to U = E / 2 × Q, where E is the voltage in the antenna, Q is the effective quality factor of the circuit. For the first oscillatory circuit, the second oscillatory circuit is a communication element, and vice versa, for the second oscillatory circuit, the first oscillatory circuit is a communication element.

The reactance of the first oscillatory circuit Roe1 is shunted by a circuit consisting of a capacitor 37 connected in series, the resistance of the antenna 14, the capacitor 44 and the reactance of the second oscillatory circuit R o 2.

The degree of shunting depends on the resistance of the antenna. The greatest will be with resistance close to zero. At zero, the reactance of the first oscillatory circuit will be practically equal to Roe 1/2. The magnitude of the reactance determines the selectivity of the circuit.

Similarly for the reactance of the second oscillatory circuit. Actually parallel to the first input of the differential amplifier 32 is turned on the reactance of the first oscillatory circuit, and parallel to the second input is the reactance of the second oscillatory circuit.

From the outputs of the differential amplifier 32, the amplified signal is fed to the input of the output selective four-terminal 33 and then to the output terminals 34 and 35.

If the input device contained only one parallel oscillatory circuit, then it would be shunted by the resistance of the antenna 14, which is practically small. In this case, the oscillatory circuit will not have resonance properties. The input circuit will not attenuate interfering signals other than the frequency of the received signal. To obtain selectivity, it is necessary to have an additional coupling winding at the inductance coil of the input circuit, which will lead to a significant decrease in the signal transfer coefficient.

In the proposed device, there is no shunting of each of the circuits by the resistance of the antenna.

This proposal considers two options for implementing the system. The first option - the aquatic environment is made in the form of fresh water. The second option - the aquatic environment is made in the form of sea water. In the first embodiment, the second ground object 2 contains a transmitter 11, to the outputs of which a water antenna system 12 is connected, containing the first element, the role of which is played by a flexible metal conductor covered with a dielectric insulation layer and connected to the potential output terminal of the transmitter 11, and the second element, the role which performs a stainless steel metal electrode connected to a low-potential output terminal of the transmitter 11.

In a metal conductor, the outer diameter of the insulation is equal to or more than four conductor diameters.

The second option - the aquatic environment is made in the form of sea water.

In the second embodiment, the second ground object 2 contains a transmitter 11, the outputs of which are connected to a water antenna system containing the first element, the role of which is played by the first metal electrode connected by a conductor to the potential output terminal of the transmitter 11, and the second element, which is played by the second metal electrode connected by a conductor with a low-potential output terminal of the transmitter 11. The electrodes are made of stainless steel and placed in sea water.

Underwater object 3 contains a waterborne antenna system 13.

The antenna system 13 includes an antenna made in the form of two metal electrodes connected to the input terminals 14 and 15 of the input device.

The electrodes are made of stainless steel and placed in sea water. The technical result of the proposal is to increase the reliability of long-distance communications.

Information sources:

1. I.M.Teplyakov et al., Radio links of space information transmission systems. - M .: Owls. Radio, 1975 p. 6

2. N. A. Stoptsov et al., Communication under water. - L.,: Shipbuilding, 1990.

3. RF patent No. 110575, IPC Н04В 13/00, published on November 20, 2011 Bull. Number 32

Claims (3)

1. A one-way radio communication system comprising a communication channel in the form of an air and water environment, a first and second surface objects, an underwater object, the first surface object comprising a message source, an encoder, a modulator and a radio transmitter, and an air antenna, a second surface object, connected in series contains aerial antenna connected in series, a radio receiver, a converter, a transmitter and a water antenna device, an underwater object comprises an antenna connected in series moreover, a radio receiver, a decoding device and a registrar, characterized in that the second surface-mounted object is provided with an additional output device, in which the input terminals are connected to the output of the transmitter, and the output terminals are equipped with a water antenna device, the underwater object is equipped with an additional input device, in which the input terminals connected to the antenna device, and the output terminals to the input of the radio receiver, and the additional output device contains serially connected input terminals, the first an objective two-terminal, an amplifying element, an output selective two-terminal, output terminals, the first selective four-terminal being made in the form of a parallel oscillatory circuit containing a capacitor and an inductor with a coupling winding, the terminals of which are connected to the input terminals of the device, the amplifying element contains two amplifiers with inputs connected to the potential points of the oscillatory circuit, and the outputs with the inputs of the second selective bipolar, which is made in the form of two parallel ntur connected in series, with the midpoint connected to a common bus, and the potential terminals of the bipolar connected to the output terminals of the device, at the underwater object, the additional input device contains series-connected input terminals, an input selective four-terminal, an amplifying element, an output selective four-terminal and output terminals, this amplifier element is made in the form of a differential amplifier containing at the input the first and second input, at the output - the first and second output , the input selective four-terminal network contains a circuit including a first contact to which the first terminals of the first and second capacitors are connected, a first terminal of the first two-terminal networks, a second contact to which the first terminals of the third and fourth capacitors are connected, the first terminal of the second two-terminal networks, and the second terminal of the first capacitor connected to the first input terminal, the second terminal of the second capacitor is connected to the first input of the differential amplifier, the second terminal of the first two-terminal is connected to a common bus, the second the output of the third capacitor is connected to the second input terminal, the second output of the fourth capacitor is connected to the second input of the differential amplifier, the second output of the second two-terminal is connected to a common bus, the output four-terminal contains a third two-terminal, in which the first output is connected via the fifth capacitor to the first output of the differential amplifier, the second the output of the two-terminal by means of the sixth capacitor is connected to the second output of the differential amplifier, each of the two-terminal is made in ide inductor and a capacitor connected in parallel with the variable capacitor, the third two-pole inductor is provided with a winding connection terminals which are connected to output terminals of the device, respectively. 2. The one-way radio communication system according to claim 1, characterized in that for fresh water at the second surface object, the waterborne antenna device comprises a flexible metal conductor coated with a dielectric insulation layer, the outer diameter of the insulation being equal to or more than four conductor diameters, with the ends of the conductor connected to the output terminals of the output device, at the underwater object, the water antenna device contains an antenna made in the form of a flexible metal conductor, covered with a layer of insulation from a dielectric, p Moreover, the outer diameter of the insulation is equal to or more than four diameters of the conductor, the ends of the conductor are connected to the input terminals of the input device, respectively. 3. The one-way radio communication system according to claim 1, characterized in that for sea water at the second surface object, the water antenna device is made in the form of two metal electrodes connected by means of conductors to the output terminals of the output device, the water antenna device at the underwater object contains an antenna, made in the form of two metal electrodes connected by means of conductors to the input terminals of the input device.

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