RU2729225C1 - Method of measuring range - Google Patents

Abstract

FIELD: radio engineering; measurement.SUBSTANCE: method of measuring range relates to radio equipment for measuring distance. Novelty in the method of measuring range is using simultaneously two channels of transmitting information. Reference low-frequency signal is transmitted from one end of the measuring path to the other by modulation, transmission and demodulation of the radio-frequency signal. Radio frequency modulated signal is emitted and received above the water surface. By means of this channel on both ends of measurement route in-phase continuous low-frequency oscillations are formed. Basic information channel is an acoustic communication channel organized by acoustic transducers located under the water surface. Actually, the phase shift of acoustic waves is an information parameter for determining the distance. Successive variation of frequency of continuous oscillations of low frequency and accompanying measurement of phase difference of signals in modulated radio-frequency and acoustic channels are used for uniquely determine range in local navigation system.EFFECT: method can be used, for example, to measure distances in local navigation systems when controlling the movement of surface objects when controlling their movement in the coastal zone, entering and passing along the cove, and organizing automatic docking.2 cl, 2 dwg

Description

The invention relates to the field of technology of radio-technical means for measuring distance and can be used, for example, for measuring ranges in local navigation systems when controlling the movement of surface objects while controlling their navigation in the coastal zone, entering and passing along the bay, organizing automatic docking.

Known amplitude methods for measuring range (see, for example, the book. Handbook on the basics of radar technology / ed. VV Druzhinin. - M .: Military. Publishing house, 1967.) However, amplitude methods for measuring range have a large error.

The closest in technical essence to the proposed invention is a method for measuring range, described in Patent for invention No. 2657016, Russia, IPC G01S 15/08.

, при этом непрерывные колебания подают одновременно на вход передающей рамочной магнитной антенны и на вход передающего акустического преобразователя, оба из которых располагают на одном конце измерительной трассы, и излучают, таким образом, в направлении объекта, расстояние до которого необходимо измерить, одновременно переменное магнитное поле и акустическую волную. На другом конце измерительной трассы переменное магнитное поле улавливают приемной рамочной магнитной антенной, а акустическую волну улавливают приемным акустическим преобразователем, оба из которых располагают на другом конце измерительной трассы. После этого измеряют и фиксируют разность фаз

между непрерывными колебаниями, формируемыми на выходе приемной рамочной магнитной антенны и на выходе приемного акустического преобразователя. После этого генерируют непрерывные колебания с известной фиксированной частотой

и повторяют всю процедуру излучения, приема переменного магнитного поля и акустической волны, а также измеряют и фиксируют разность фаз

между непрерывными колебаниями, формируемыми на выходе приемной рамочной магнитной антенны и на выходе приемного акустического преобразователя. Далее определяют разность фаз

, при этом расстояние между передающим акустическим преобразователем и приемным акустическим преобразователем определяют по формуле:This range measurement method generates continuous oscillations with a known fixed frequency

, while continuous vibrations are fed simultaneously to the input of the transmitting loop magnetic antenna and to the input of the transmitting acoustic transducer, both of which are located at one end of the measuring path, and thus emit an alternating magnetic field in the direction of the object, the distance to which is to be measured and an acoustic wave. At the other end of the measuring path, the alternating magnetic field is captured by the receiving loop magnetic antenna, and the acoustic wave is captured by the receiving acoustic transducer, both of which are located at the other end of the measuring path. Then the phase difference is measured and recorded

between continuous vibrations formed at the output of the receiving loop magnetic antenna and at the output of the receiving acoustic transducer. After that, continuous oscillations are generated with a known fixed frequency

and repeat the entire procedure of radiation, reception of an alternating magnetic field and acoustic wave, and also measure and record the phase difference

between continuous vibrations formed at the output of the receiving loop magnetic antenna and at the output of the receiving acoustic transducer. Next, the phase difference is determined

, while the distance between the transmitting acoustic transducer and the receiving acoustic transducer is determined by the formula:

,

,

— скорость звука в среде распространения, причем место размещения передающей и приемной рамочных магнитных антенн не имеет значения.Where

- the speed of sound in the propagation medium, and the location of the transmitting and receiving loop magnetic antennas does not matter.

However, the range measurement by this method can be carried out in a limited range, since the alternating magnetic field generated by the transmitting loop magnetic antenna decreases inversely with the cube of the distance, while the acoustic signal can propagate over a much greater distance. The actually measured range has a certain limit, calculated in hundreds of meters. At the same time, it is highly desirable to control the movement of a surface object at distances of several kilometers.

The aim of the present invention is to increase the range of the system for measuring the range of surface objects when organizing their movement in the coastal zone, entering and passing along the bay, organizing automatic docking.

This goal is achieved as follows.

1. A method for measuring range, including generating continuous low frequency vibrations, emitting a low frequency acoustic wave, receiving a low frequency acoustic wave, measuring the phase difference of low frequency continuous vibrations, sequentially changing the frequency of continuous vibrations,

, при этом непрерывные колебания низкой частоты подают одновременно на вход модуляции радиочастотного передатчика, к выходу которого подключают передающую радиочастотную антенну, которую располагают над водной поверхностью, и на вход передающего акустического преобразователя, который располагают под водной поверхностью, оба из которых располагают на одном конце измерительной трассы или измерительной станции, и излучают, таким образом, в направлении объекта, расстояние до которого необходимо измерить, одновременно модулированный сигналом низкой частоты радиочастотный сигнал, распространяемый над водной поверхностью, и акустическую волну, распространяемую под водной поверхностью, после чего на другом конце измерительной трассы модулированный радиочастотный сигнал улавливают приемной радиочастотной антенной, которую располагают над водной поверхностью, а акустическую волну улавливают приемным акустическим преобразователем, который располагают под водной поверхностью, при этом приемную радиочастотную антенну и приемный акустический преобразователь располагают на другом конце измерительной трассы или на объекте, расстояние до которого необходимо измерить, после чего принятый радиочастотной антенной радиочастотный сигнал демодулируют в радиочастотном приемнике и выделяют на его выходе демодуляции исходный сигнал с исходной низкой частотой

, после чего измеряют и фиксируют разность фаз

между непрерывными колебаниями низкой частоты, формируемыми на выходе демодуляции радиочастотного приемника и на выходе приемного акустического преобразователя, после чего генерируют непрерывные колебания с известной фиксированной низкой частотой

и повторяют всю процедуру модуляции, излучения, приема, демодуляции радиочастотного сигнала и акустической волны, а также измеряют и фиксируют разность фаз

между непрерывными колебаниями низкой частоты, формируемыми на выходе демодуляции радиочастотного приемника и на выходе приемного акустического преобразователя, после чего определяют разность фаз

, при этом расстояние между передающим акустическим преобразователем и приемным акустическим преобразователем определяют по формуле:characterized in that it initially generates continuous oscillations with a known fixed low frequency

, while continuous low frequency vibrations are fed simultaneously to the modulation input of the radio frequency transmitter, to the output of which a transmitting radio frequency antenna is connected, which is located above the water surface, and to the input of the transmitting acoustic transducer, which is located under the water surface, both of which are located at one end of the measuring path or measuring station, and thus emit in the direction of the object, the distance to which is to be measured, simultaneously modulated by a low-frequency signal, a radio-frequency signal propagating over the water surface and an acoustic wave propagating under the water surface, after which at the other end of the measuring path the modulated radio frequency signal is captured by the receiving radio frequency antenna, which is located above the water surface, and the acoustic wave is captured by the receiving acoustic transducer, which is located under the water surface, while the receiving radio is and the frequency antenna and the receiving acoustic transducer are located at the other end of the measuring path or on the object, the distance to which must be measured, after which the radio frequency signal received by the radio frequency antenna is demodulated in the radio frequency receiver and the original signal with the initial low frequency is extracted at its demodulation output

, after which the phase difference is measured and recorded

between continuous low frequency oscillations formed at the output of the demodulation of the radio frequency receiver and at the output of the receiving acoustic transducer, after which continuous oscillations are generated with a known fixed low frequency

and repeat the entire procedure of modulation, emission, reception, demodulation of the radio frequency signal and acoustic wave, and also measure and record the phase difference

between continuous low-frequency oscillations formed at the output of the demodulation of the radio-frequency receiver and at the output of the receiving acoustic transducer, after which the phase difference is determined

, while the distance between the transmitting acoustic transducer and the receiving acoustic transducer is determined by the formula:

,

,

— скорость звука в среде распространения, причем место размещения передающей и приемной радиочастотных антенн не имеет значения, при этом получают значение измеряемой дальности на самом контролируемом объекте.Where

- the speed of sound in the propagation medium, and the location of the transmitting and receiving radio-frequency antennas does not matter, while the value of the measured range at the controlled object itself is obtained.

2. The method for measuring range according to claim 1,

подают одновременно на вход модуляции радиочастотного передатчика и на первый вход измерителя разности фаз, при этом, принятый на другом конце измерительной трассы или на контролируемом объекте радиочастотный сигнал демодулируют, и получаемые с выхода демодуляции радиочастотного приемника непрерывные колебания низкой частоты

затем усиливают и подают на вход передающего акустического преобразователя, который располагают под водной поверхностью, который устанавливают на другом конце измерительной трассы или контролируемом объекте, и излучают, таким образом, акустическую волну, распространяемую в направлении измерительной станции, после чего акустическую волну улавливают приемным акустическим преобразователем, который располагают под водной поверхностью, который устанавливают на первом конце измерительной трассы или на измерительной станции, после чего сигнал с приемного акустического преобразователя подают на второй вход измерителя разности фаз, после чего измеряют и фиксируют разность фаз

между непрерывными электрическими колебаниями низкой частоты, формируемыми на выходе генератора непрерывных электрических колебаний низкой частоты, и на выходе приемного акустического преобразователя, после чего генерируют непрерывные электрические колебания с известной фиксированной низкой частотой

и повторяют всю процедуру модуляции излучения, приема, демодуляции радиочастотного сигнала и акустической волны, а также измеряют и фиксируют разность фаз

между непрерывными электрическими колебаниями, формируемыми на выходе генератора непрерывных электрических колебаний и на выходе приемного акустического преобразователя, после чего определяют разность фаз

, при этом расстояние между передающим акустическим преобразователем, установленным на контролируемом объекте, и приемным акустическим преобразователем, установленным на измерительной станции, определяют по формуле:characterized in that the primary formed continuous oscillations with a known fixed low frequency

is fed simultaneously to the modulation input of the radio frequency transmitter and to the first input of the phase difference meter, while the radio frequency signal received at the other end of the measurement path or at the controlled object is demodulated, and continuous low frequency oscillations obtained from the demodulation output of the radio frequency receiver

then amplified and fed to the input of the transmitting acoustic transducer, which is located under the water surface, which is installed at the other end of the measuring path or controlled object, and thus emit an acoustic wave propagating in the direction of the measuring station, after which the acoustic wave is captured by the receiving acoustic transducer , which is located under the water surface, which is installed at the first end of the measuring path or at the measuring station, after which the signal from the receiving acoustic transducer is fed to the second input of the phase difference meter, after which the phase difference is measured and recorded

between continuous electrical oscillations of low frequency, formed at the output of the generator of continuous electrical oscillations of low frequency, and at the output of the receiving acoustic transducer, after which continuous electrical oscillations with a known fixed low frequency are generated

and repeat the entire procedure for modulating radiation, receiving, demodulating the radio frequency signal and acoustic wave, and also measure and record the phase difference

between continuous electrical oscillations formed at the output of the generator of continuous electrical oscillations and at the output of the receiving acoustic transducer, after which the phase difference is determined

, while the distance between the transmitting acoustic transducer installed on the controlled object and the receiving acoustic transducer installed at the measuring station is determined by the formula:

,

,

— скорость звука в среде распространения, при этом получают значение измеряемой дальности на измерительной станции.Where

- the speed of sound in the propagation medium, while the value of the measured range at the measuring station is obtained.

Comparison of the proposed invention with the already known methods and prototype shows that the proposed method exhibits new technical properties, consisting in the possibility of measuring the increased range of surface objects.

These properties of the proposed invention are new, since in the prototype method, due to its inherent disadvantages, which consist in the use of loop magnetic antennas operating at the same low frequencies for transmitting a low-frequency synchronization signal, distance measurement is possible only at a limited distance not exceeding hundreds of meters in reality. ...

This method of ranging can be implemented using the device shown in FIG. 1 (claim 1) and FIG. 2 (claim 2 of the claims).

The range measuring device according to claim 1 of the claims (Fig. 1) consists of a continuous low frequency oscillator 1, a radio frequency transmitter 2, a transmitting radio frequency antenna 3, a receiving radio frequency antenna 4, a radio frequency receiver 5, a transmitting acoustic transducer 6, a receiving acoustic transducer 7 , continuous oscillation phase difference meter 8. RF antennas are installed above the water surface, and acoustic transducers are installed under the water surface.

The output of the continuous oscillator of low frequency 1 is connected to the modulation input of the radio frequency transmitter 2 and to the input of the transmitting acoustic transducer 6, while the output of the radio frequency transmitter 2 is connected to the input of the transmitting radio frequency antenna 3, and the output of the receiving radio frequency antenna 4 is connected to the input of the radio frequency receiver 5, the output demodulation of which is connected by the first input of the continuous vibration phase difference meter 8, and the output of the receiving acoustic transducer 7 is connected to the second input of the continuous vibration phase difference meter 8.

The range measuring device according to claim 2 of the claims (Fig. 2) consists of a continuous low frequency oscillator 1, a radio frequency transmitter 2, a transmitting radio frequency antenna 3, a receiving radio frequency antenna 4, a radio frequency receiver 5, a transmitting acoustic transducer 6, a receiving acoustic transducer 7 , continuous oscillation phase difference meter 8, low frequency amplifier 9.

RF antennas are installed above the water surface and acoustic transducers are installed below the water surface.

The output of the continuous oscillator of low frequency 1 is connected to the modulation input of the radio frequency transmitter 2 and the first input of the continuous oscillation phase difference meter 8, while the output of the radio frequency transmitter 2 is connected to the input of the transmitting radio frequency antenna 3, and the output of the receiving radio frequency antenna 4 is connected to the input of the radio frequency receiver 5 , the demodulation output of which is connected to the input of the low frequency amplifier 9, the output of which is connected to the input of the transmitting acoustic transducer 6, and the output of the receiving acoustic transducer 7 is connected to the second input of the continuous vibration phase difference meter 8.

Devices that implement the inventive methods for measuring the range are in operation as follows.

, начальной фазой

и амплитудой

Using the generator of continuous low-frequency oscillations 1, continuous oscillations with a known frequency are initially generated

, the initial phase

and amplitude

. (1)

... (1)

The frequency of these vibrations is chosen low. The frequency of these vibrations lies in the audio wavelength range.

These oscillations are fed to the modulation input of the radio frequency transmitter 2. In this case, the type of modulation can be arbitrary: it can be amplitude, frequency or phase modulation. With pure tone modulation, which is the case in this case, frequency and phase modulation on the receiving side cannot be distinguished. In this case, it is correct to talk about the angular modulation of the radio frequency signal.

, модулированный сигналом низкой частоты

. Здесь и далее примем обозначение модуляции сигналов как

. Модулированные радиочастотные колебания распространяются от передающей радиочастотной антенны 3 к приемной радиочастотной антенне 2. Эти колебания при распространении на радиочастоте определенно получают известный набег фазы, но этот набег фазы не имеет значения, поскольку он не принимается в расчет в процессе демодуляции сигнала.Using the transmitting radio-frequency antenna 3, a radio-frequency signal with a frequency is emitted towards the other end of the measurement path

modulated by low frequency signal

... Hereinafter, we will use the designation of signal modulation as

... The modulated RF waves propagate from the transmitting RF antenna 3 to the receiving RF antenna 2. These RF waves will definitely get a known phase incursion, but this phase incursion is irrelevant since it is not taken into account in the signal demodulation process.

при распространении радиочастотного модулированного сигнала c частотой

на расстояние

от радиочастотной антенны 3 до приемной радиочастотной антенны 4, можно сказать, получают набег фазы

, где

— скорость света. При низких частотах

звукового диапазона и при малых дальностях

, составляющих сотни метров, длина волны электромагнитного излучения оказывается много больше измеряемой дальности

. Так, например, при частоте звукового сигнала 1 кГц и длине трассы 1 км набег фазы низкочастотного сигнала составит всего 1,2°. И этот сдвиг фазы остается постоянным во времени. Другими словами его можно учесть при калибровке системы, и этим набегом фазы

можно пренебречь и можно утверждать, что непрерывные колебания, формируемые на выходе демодуляции радиочастотного приемника, являются синфазными, по отношению к непрерывным колебаниям, поступающим на вход модуляции радиочастотного передатчика. Эти колебания описываются одним и тем же выражением (1). Причем место установки передающей и приемной радиочастотных антенн не принципиально. Непрерывные колебания на входе модуляции радиочастотного передатчика и на выходе демодуляции радиочастотного приемника всегда будут синфазны, в первом приближении. Правомерность использования такого подхода подтверждена полномасштабными теоретическими и экспериментальными исследованиями и нашла отражение в научных трудах и патенте РФ автора № 2595247.On the other hand, electrical vibrations with a low modulation frequency

when propagating a radio frequency modulated signal with a frequency

at a distance

from the radio frequency antenna 3 to the receiving radio frequency antenna 4, one can say, receive a phase incursion

where

Is the speed of light. At low frequencies

sound range and at short ranges

constituting hundreds of meters, the wavelength of electromagnetic radiation turns out to be much greater than the measured range

... So, for example, with a sound signal frequency of 1 kHz and a path length of 1 km, the phase incursion of the low-frequency signal will be only 1.2 °. And this phase shift remains constant over time. In other words, it can be taken into account when calibrating the system, and this phase incursion

can be neglected and it can be argued that the continuous waveforms generated at the output of the demodulation of the RF receiver are in phase with respect to the continuous waveforms generated at the modulation input of the RF transmitter. These fluctuations are described by the same expression (1). Moreover, the place of installation of the transmitting and receiving radio frequency antennas is not important. Continuous oscillations at the modulation input of the RF transmitter and the demodulation output of the RF receiver will always be in phase, to a first approximation. The legitimacy of using this approach is confirmed by full-scale theoretical and experimental research and is reflected in scientific works and the author's RF patent No. 2595247.

Further, the operation of the devices according to claim 1 and claim 2 of the formula are slightly different from each other.

при распространении на расстояние

от передающего акустического преобразователя 6 до приемного акустического преобразователя 7 также получает свой набег фазы

, где

— скорость звука в среде распространения. Значением этого набега фазы пренебречь нельзя, поскольку его величина может достигать нескольких тысяч фазовых циклов величиной

каждый. Таким образом, на выходе приемного акустического преобразователя 7 формируются непрерывные колебания According to claim 1 of the claims, the signal from the output of the generator of continuous low frequency oscillations 1 is also fed to the input of the transmitting acoustic transducer 6 installed at the measuring station and under the water surface, and is emitted with its help in the direction of the other end of the measuring path, in the direction of the controlled object to which is installed under the water surface receiving acoustic transducer 7, an acoustic wave. Acoustic wave with frequency

when propagating to a distance

from the transmitting acoustic transducer 6 to the receiving acoustic transducer 7 also receives its phase incursion

where

Is the speed of sound in the propagation medium. The value of this phase incursion cannot be neglected, since its value can reach several thousand phase cycles with the value

every. Thus, at the output of the receiving acoustic transducer 7, continuous oscillations are formed

. (2)

... (2)

. Другими словами измеритель разности фаз формирует сигнал, пропорциональный некоторой величине

, которая связана с реальным набегом фазы

соотношением Continuous oscillations from the output of demodulation of the radio frequency receiver 5, described by expression (1) and from the output of the receiving acoustic transducer 7, described by expression (2), are fed to the inputs of the continuous oscillation phase difference meter 8, at the output of which a signal is generated proportional to the phase difference of signals (1 ) and 2). However, the meter of the phase difference of continuous oscillations 8 is able to adequately display the measured phase difference if the value of this phase difference lies in the range from 0 to

... In other words, the phase difference meter generates a signal proportional to some value

, which is associated with the real phase incursion

ratio

, (3)

, (3)

— некоторое целое число, которое может достигать нескольких тысяч и более. Другими словами появляется неоднозначность определения дальности.Where

- some integer, which can reach several thousand or more. In other words, there is an ambiguity in determining the range.

фиксируют, после чего изменяют значение частоты непрерывных колебаний до некоторой известной величины

и повторяют всю процедуру излучения и приема модулированного радиочастотного сигнала и акустических волн и вновь измеряют разность фаз

непрерывных колебаний на выходе демодуляции радиочастотного приемника 5 и на выходе приемного акустического преобразователя 7, которую вновь фиксируют. После чего определяют разность фаз

и вычисляют дальность по формулеTo solve this problem, the specified measured value

fix, then change the value of the frequency of continuous vibrations to a certain known value

and repeat the entire procedure for emission and reception of the modulated radio frequency signal and acoustic waves and again measure the phase difference

continuous oscillations at the output of the demodulation of the radio frequency receiver 5 and at the output of the receiving acoustic transducer 7, which is again fixed. Then the phase difference is determined

and calculate the range by the formula

. (4)

... (4)

In this case, the value of the range is obtained at the most controlled object.

не должно приводить к изменению разности фаз сигналов на величину бóльшую, чем

. Другими словами It is important to remember that changing the frequency

should not lead to a change in the phase difference of the signals by an amount greater than

... In other words

.

...

при распространении на то же расстояние

от передающего акустического преобразователя 6 до приемного акустического преобразователя 7 также получает тот же набег фазы

. Таким образом, на выходе приемного акустического преобразователя 7 формируется непрерывные колебания, описываемые тем же выражением (2), что и по п. 1 формулы. According to claim 2, the signal from the output of the continuous oscillation generator of low frequency 1 is fed simultaneously to the modulation input of the radio frequency transmitter and to the first input of the continuous oscillation phase difference meter 8. At the same time, the signal from the demodulation output of the radio frequency receiver 5 is fed to the input of the low frequency amplifier 9 and Further, from the output of this amplifier 9, the signal is fed to the input of the transmitting acoustic transducer 6 installed on the monitored object and under the water surface, and thereby emitted in the direction of the measuring station, the direction of the receiving acoustic transducer 7 installed at the measuring station under the water surface, an acoustic wave. Acoustic wave with frequency

when propagating the same distance

from the transmitting acoustic transducer 6 to the receiving acoustic transducer 7 also receives the same phase incursion

... Thus, at the output of the receiving acoustic transducer 7, continuous oscillations are formed, described by the same expression (2) as in claim 1 of the formula.

The signal from the output of the receiving acoustic transducer 7 is fed to the second input of the continuous vibration phase difference meter 8, at the output of which the same signal is obtained, which is described by the formula (3).

до

с промежуточными фиксациями измеренных разностей фаз

и

с дальнейшим определением разности фаз

и вычислением дальности по формуле (4).As before, the ambiguity in measuring the phase difference and, accordingly, the ambiguity in determining the range is eliminated by successive changes in the frequency of the initial low-frequency oscillations with

before

with intermediate fixations of the measured phase differences

and

with further determination of the phase difference

and calculating the range using the formula (4).

In this case, the range value is obtained at the measuring station.

The national economic effect of using the proposed invention is associated with the emergence of the possibility of measuring the increased range of surface objects, more than a hundred meters. In this case, the measurement of the increased range of surface objects is provided by the implementation of the transmission channel of the reference low-frequency signal by modulating the RF transmitter signal with this low-frequency signal, followed by transmission, reception and demodulation of the RF signal at the controlled object. In this case, the range of the radio-frequency communication channel can significantly exceed the range of the acoustic communication channel, with the help of which the range of the controlled object is measured.

Another aspect of increasing the efficiency from the use of the proposed invention is associated with the ability to measure the range with increased accuracy, while the ambiguity of measurements is eliminated.

Claims (6)

1. A method for measuring range, including generating continuous low frequency vibrations, emitting a low frequency acoustic wave, receiving a low frequency acoustic wave, measuring the phase difference of low frequency continuous vibrations, sequentially changing the frequency of continuous vibrations, characterized in that initially continuous vibrations are generated with a known fixed low frequency

, while continuous low frequency vibrations are fed simultaneously to the modulation input of the radio frequency transmitter, to the output of which a transmitting radio frequency antenna is connected, which is located above the water surface, and to the input of the transmitting acoustic transducer, which is located under the water surface, both of which are located at one end of the measuring path or measuring station, and thus emit in the direction of the object, the distance to which is to be measured, simultaneously modulated by a low frequency signal, a radio frequency signal propagating over the water surface, and an acoustic wave propagating under the water surface, after which at the other end of the measuring path the modulated radio frequency signal is captured by the receiving radio frequency antenna, which is located above the water surface, and the acoustic wave is captured by the receiving acoustic transducer, which is located under the water surface, while the receiving radio and the frequency antenna and the receiving acoustic transducer are located at the other end of the measuring path or on the object, the distance to which must be measured, after which the radio frequency signal received by the radio frequency antenna is demodulated in the radio frequency receiver and the original signal with the initial low frequency is extracted at its demodulation output

, after which the phase difference is measured and recorded

between continuous low frequency oscillations formed at the output of the demodulation of the radio frequency receiver and at the output of the receiving acoustic transducer, after which continuous oscillations are generated with a known fixed low frequency

and repeat the entire procedure of modulation, emission, reception, demodulation of the radio frequency signal and acoustic wave, and also measure and record the phase difference

between continuous low-frequency oscillations formed at the output of the demodulation of the radio-frequency receiver and at the output of the receiving acoustic transducer, after which the phase difference is determined

, while the distance between the transmitting acoustic transducer and the receiving acoustic transducer is determined by the formula:

, Where

- the speed of sound in the propagation medium, and the location of the transmitting and receiving radio-frequency antennas does not matter, while the value of the measured range at the controlled object itself is obtained. 2. A method for measuring range, including generating continuous low frequency vibrations, emitting a low frequency acoustic wave, receiving a low frequency acoustic wave, measuring the phase difference of low frequency continuous vibrations, sequentially changing the frequency of continuous vibrations, characterized in that the initially formed continuous vibrations with a known fixed low frequency

is fed simultaneously to the modulation input of the radio frequency transmitter and to the first input of the phase difference meter, while the radio frequency signal received at the other end of the measurement path or at the controlled object is demodulated, and continuous low frequency oscillations obtained from the demodulation output of the radio frequency receiver

then amplified and fed to the input of the transmitting acoustic transducer, which is located under the water surface, which is installed at the other end of the measuring path or controlled object, and thus emit an acoustic wave propagating in the direction of the measuring station, after which the acoustic wave is captured by the receiving acoustic transducer , which is located under the water surface, which is installed at the first end of the measuring path or at the measuring station, after which the signal from the receiving acoustic transducer is fed to the second input of the phase difference meter, after which the phase difference is measured and recorded

between continuous electrical oscillations of low frequency, formed at the output of the generator of continuous electrical oscillations of low frequency, and at the output of the receiving acoustic transducer, after which continuous electrical oscillations with a known fixed low frequency are generated

and repeat the entire procedure for modulating radiation, receiving, demodulating the radio frequency signal and acoustic wave, and also measure and record the phase difference

between continuous electrical oscillations formed at the output of the generator of continuous electrical oscillations and at the output of the receiving acoustic transducer, after which the phase difference is determined

, while the distance between the transmitting acoustic transducer installed on the controlled object and the receiving acoustic transducer installed at the measuring station is determined by the formula:

, Where

- the speed of sound in the propagation medium, while the value of the measured range at the measuring station is obtained.

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