RU2446566C1 - Radio communication method - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: radio communication method involves modulation of a transmitted radio signal and emission thereof by an antenna, electric excitation of ions of the radio signal propagation medium with subsequent reception of the signal by a radio-receiving antenna and is also characterised by that, the radio signal is emitted by several antennae arranged into a circle, which are powered by phase-shifted currents, which causes precession of the emitted electric and magnetic vectors of the electromagnetic field of antenna radiation and precession of the axis of rotation of the ions (dipoles) of the radio wave propagation medium.

EFFECT: high information capacity of the communication channel.

4 cl, 5 dwg

Description

The invention relates to radio communications in ionized environments and can be used for radio communications with underwater objects.

The known method of underwater radio communication, Russian patent No. 2117399 for class H04B 31/00. The method involves modulating an informative signal and the radiation of a transmitting antenna of extra-long waves, the passage of the latter through an aqueous medium and their reception by a receiving antenna. The main disadvantages of the method are the small informative capacity of the communication channel and the large size of the antennas used. These shortcomings are due to the use of extra-long waves.

The closest in technical essence and the achieved result to the claimed method is an underwater radio communication method described in the journal Navigation and time, No. 1, 2, St. Petersburg, 1993. - p.20 - prototype. The method includes modulating the transmitted radio signal and its emission by the transmitting antenna, electrically exciting the ions of the propagation medium of the radio signals, followed by receiving the signal from the radio receiving antenna.

The main disadvantage of the prototype is the small informative capacity of the communication channel. The disadvantage is due to the need to use ultra-low frequencies of the radio signal, high-speed modulation of which is impossible, which does not allow the transfer of significant amounts of information. Hence the small informative capacity of the communication channel.

The technical problem, the solution of which the invention is directed, is to increase the informative capacity of the communication channel.

To solve the problem in a radio communication method, including modulation of the transmitted radio signal and its emission by the transmitting antenna, electrical excitation of ions of the propagation medium of the radio signals with subsequent reception of the signal by the radio receiving antenna, according to the invention, several transmitting antennas are arranged around the circumference and energized by phase-shifted currents, thereby exciting the precession of the electric and magnetic vectors of the electromagnetic field of the antenna radiation and the precession of the axes of rotation of the ions (dipoles) of the medium Transmission of radio signals.

The precession of the ionization vectors of ions (dipoles) of the propagation medium is carried out by a uniform phase shift between the currents flowing in the transmitting antennas evenly spaced around the circumference.

In this case, the phase shift of the currents in the antennas can be performed both at the carrier frequency of the transmitted radio signal and at the frequency of the additional modulation signal. In this case, the radio signal is received at a frequency of additional modulation.

The precessing electromagnetic field emitted by the transmitting antenna excites the precession of the electric moments of the ions of the propagation medium, which is transmitted from ion to ion until it reaches the receiving antenna. Since the energy consumption for the excitation by the electromagnetic field of the precession of the electric moments of the ions is much less than the movement of the ions themselves, the radio frequency can be significantly increased. Increasing the carrier frequency of the radio signal allows you to increase the data transfer speed and the informative capacity of the communication channel.

The use of additional modulation of an electromagnetic field with a frequency lower than the carrier frequency of the radio signal to obtain a precession of the electromagnetic field makes it possible to increase the frequency of the radio signal with respect to the precession frequency and proportionally reduce the size of the transmitting antennas while maintaining their effectiveness.

All of this together allowed to significantly increase the informative capacity of the communication channel, increase its range and reduce the size of the antennas, without reducing their effectiveness, which resulted in a significant technical and economic effect.

Description of the drawings.

Figure 1. Phase-shifted antenna system.

Figure 2. Excitation of the precession field.

Figure 3. The precession field in the plane normal to the vector E of the radio signal.

Figure 4. Excitation of an ion by the precessing field of the antenna system.

Figure 5. Interaction of the precession fields of the electric moments of the ions of the propagation medium of radio signals with the coincident and orthogonal arrangement of their ionization vectors.

Figure 1 shows the antenna system, including three evenly spaced antennas A1, A2 and A3, an electric energy source e (t) and two phase shifters φ1 and φ2 connected between the second and third antennas, while the electric energy source is connected to the first antenna.

The antenna system works as follows. Under the influence of the signal e (t) in the antennas, electric oscillations with the frequency of the exciting signal will be excited. Since the electrical vibrations in each of the antennas will differ in phase in the plane normal to the axes of the antennas, a precession field will arise.

The occurrence of electric field vectors exciting the precession field is shown in FIG. 2. Here, E1, E2, and E3 are the phase-shifted vectors of the electrical component of the radiation field of antennas A1, A2, and A3, respectively. E1-E2 and E2-E3 are electric vectors of the radiation field arising due to a phase shift between the vectors E1, E2 and E3 emitted by the antennas A1, A2 and A3, respectively.

Figure 3 shows the projection of the vectors of the electrical component of the radiation field of the antennas on a plane perpendicular to the direction of their axes. Here, A1, A2 and A3 are the projections of the antennas and the projections of the vectors E1-E2 and E2-E3 on the indicated plane and Epr resulting from the phase shift of the precession field.

Figure 4 shows the effect of the precessing electromagnetic field emitted by the antennas on the electric moment of the dipole ion. Here, γ is the angle of the precession of the electric field vector of the ion (dipole) under the influence of the precession field Epr.

Figure 5 shows the interaction of the precessing vector of the electric moment of the ion 1 with ions with a coinciding 2 and orthogonal 3 arrangement of the vectors of their electric moments.

Two types of motion are inherent in ions in electrolytes:

- chaotic Brownian motion resulting from temperature exposure;

- rotation around its own axis - spin, due to which there is an electric moment and an ionization vector of molecules.

Attempts to regulate the Brownian motion of ions and make it synchronous with the transmitted electromagnetic radiation requires large amounts of energy and leads to significant losses of the radio signal. Therefore, a radio communication method is implemented as follows. Using an electric energy generator e (t) (FIG. 1), in the antennas A1-A3 evenly spaced around the circumference, electric oscillations with a relative phase shift φ are excited. Such excitation leads to a difference in the amplitudes of the vectors E and H radiated by the antennas at any time. This will give the projection of the vectors E on a plane perpendicular to the axes of the antennas (figure 2) and excite in it the precession field Epr (figure 3). The arisen circular field of precession will force the precessed vectors E and H of the resulting electromagnetic field emitted by the antennas.

As a result of the precession, the interaction of the radiation field with the ions of the medium of propagation of radio signals in the near and far radiation zones will be different.

In the near zone, both the plane electromagnetic wave and the precession field will affect the electric moments of the solution ions. As a result of the action of a plane wave, the electric moments of ions (dipoles) in the near radiation zone will be oriented in the direction of the vector E. Their orientation will require considerable effort, which will lead to significant losses of energy of the plane wave. As it follows from the formula

where α is the loss in dB / m, f is the frequency in Hz, σ is the specific conductivity of water in mho / m.

The boundaries of the near zone are determined by a sphere whose radius depends on the penetration depth of a plane wave, determined by the thickness of the skin layer, according to the formula

where δ is the thickness of the skin layer, π is the number of pi, f is the frequency, μ is the magnetic permeability, and σ is the specific conductivity of the propagation medium of the radio signal.

Thus, in the near zone, the radius of which depends on the depth of the skin layer, a plane wave will propagate with losses determined by formula (1). This wave is not suitable for underwater radio communications due to significant losses. Its advantage for organizing radio communications is that in the near zone a plane wave will orient a large number of ion dipoles in the direction of the vector E and all of them will have a precession of electric moments synchronous with the emitted signal.

Outside the near zone, the dipole moments of ions excited by the antennas, in turn, will interact with ions in the far zone with a force determined by Coulomb's law

where F is the interaction force between ion charges, q ₁ and q ₂ are ion charges, ε is the dielectric constant of the propagation medium of radio signals, r is the distance between the ions.

The distance between the ions will depend on the force required to excite the precession of their dipole moments and on their relative orientation. If the directions of the vectors of electric polarization of ions coincide, this distance will be maximum (dipoles 1 and 2 in FIG. 5). With an increase in the angle between them, the interaction distance will quickly decrease and, with the orthogonal arrangement of the electric polarization vectors, the ion interaction will tend to zero (dipoles 1 and 3 in FIG. 5). Next, the precession will be transmitted from ion to ion until it reaches the receiving antenna and excites electric vibrations in it, synchronous with the transmitted signal.

The range of radio communication in the proposed method significantly increases due to the following reasons:

- to excite the precession of the electric moments of the ions requires significantly less energy than to excite the oscillations of ions with the frequency of the transmitted signal. An ionized molecule can be considered as a gyroscope rotating around an axis formed by an electric vector of an ion. It is known from mechanics that the gyroscope is very resistant to the preservation of the plane of rotation, and considerable efforts are required to change it. However, it is not difficult to make the precessed axis of its rotation with light periodic jerks;

- precession is excited mainly in the ions of the same type with equally oriented vectors of electric moments. The energy consumption for the excitation of the remaining ions is minimal. This reduces the number of excited ions and, accordingly, energy consumption and radio signal loss.

- precession energy is able to accumulate. Therefore, the amplitude of the precession of the excited ion will increase until its energy reaches the energy level of the pathogen ion. And so on the whole chain, from the transmitting antenna to the receiving.

In the proposed method, radio communication is carried out in two stages.

In the near zone, the emitted plane wave orients the electric dipole moments of the ions in the direction of its electric vector. This ensures synchronization of the precession of the axes of rotation of a large number of ions in the near field and their synchronous interaction with dipoles outside the near zone. On this, the functions of the plane wave end.

Outside the near field, by the forces of electrical interaction, the precession is transmitted from ion to ion until it reaches the receiving antenna. In this case, ions of the same type are excited mainly with identically oriented vectors of dipole moments. Therefore, outside the near zone, the energy of the radio signal is consumed very economically, and the communication range is significantly increased. Such an organization of radio communications allows it to be carried out at higher frequencies and significantly increase its informative capacity and data transfer rate.

The precession of the vectors of the electromagnetic field emitted by the antenna system can be excited both at the carrier frequency and at the frequency of additional modulation. The use of additional modulation ions with a frequency below the carrier frequency to excite the precession vectors of the dipole moment vectors allows increasing the carrier frequency, reducing the size of the antennas, and increasing their efficiency. In this case, the radio signal is received at a frequency of additional modulation.

All this together gives a significant technical and economic effect from the use of the proposed method of radio communication.

Claims (4)

1. A radio communication method, including modulation of the transmitted radio signal and its emission by the transmitting antenna, electrical excitation of the ions of the propagation medium of the radio signals, followed by reception of the signal by the radio receiving antenna, characterized in that the radiation of the radio signal is produced by several circumferentially arranged antennas, which are fed by phase-shifted electric currents than excite the precession of the electric and magnetic vectors of the electromagnetic field of the radiation of the antennas and the precession of the axes of rotation of the ions (di Olay) radio propagation environment. 2. The method according to claim 1, characterized in that the antennas are evenly spaced along the circumference and energized with electrical signals with a uniform phase shift of the currents in the antennas. 3. The method according to claim 1 or 2, characterized in that the phase shift of the currents in the antennas is carried out at the frequency of the radio signal carrier. 4. The method according to claim 1 or 2, characterized in that the radio signal is additionally modulated, and the phase shift of the electric currents in the transmitting antennas is carried out at an additional modulation frequency, while the radio signal is received at an additional modulation frequency.

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