KR20170054175A - Method and system for estimating a location of an unidentified submarine signal - Google Patents

Abstract

Provided is a method and system for estimating an underwater signal location. An embodiment of the method for estimating the position of the undetermined signal in accordance with the present invention includes the following steps: a reference frequency signal generator installed on the mobile ship generating a reference frequency signal; an underwater acoustic sensor measuring an underwater frequency signal; detecting the point at which the differential function of time for the frequency is 0 in each of the reference frequency signal and the specific frequency signal from the underwater frequency signal measured by a position estimator; and calculating the position at which the specific frequency signal is generated based on the detected times and the moving speed of the ship. According to the present invention, an unidentified signal position can be estimated by using an underwater acoustic sensor with less cost and a smaller quantity than a conventional fixed system.

Description

[0001] METHOD AND SYSTEM FOR ESTIMATING LOCATION OF AN UNIDENTIFIED SUBMARINE SIGNAL [0002]

The present invention relates to the underwater radiated noise of a ship, and more particularly to a method and system for estimating the position of a ship noise source.

When the underwater acoustic sensor measures the underwater radiated noise of the ship, various frequency signals are received in combination. These frequency signals also include fluid flow noise, but also the noise of machinery originating from the ship.

Once the underwater radiated noise of a ship is measured, it is possible to identify the frequency signal that exceeds the underwater radiated noise standard or the performance of the underwater sound of the ship among the frequency signals obtained through the measurement, (Source Identification).

FIG. 1 shows an example of a result of measurement of general underwater radiated noise. Referring to FIG. 1, in the portion denoted by A, a significantly higher noise can be found, and it can be seen that this noise is a single signal (Tone) identified at a specific frequency. However, even if the problematic frequency signal is identified as a single signal of this specific frequency, countermeasures can not be established if the noise source generating the frequency signal is not understood.

If the noise source generating the frequency signal is not found, it is processed by contractual fines and it is concluded that it is merely referred to as Un-known Signal in the analysis report.

A large number of vessels are equipped with many different types of equipment in different locations, and several units of the same type are installed in different locations. Therefore, it is very difficult to find the noise source that generates the corresponding frequency signal. However, if the source of the frequency signal is located in the ship, it will be very easy to find such a source.

Some developed countries have built a fixed underwater radiated noise measurement facility on the sea and are using beamforming to track their location. Such position tracking can be accomplished by arranging a plurality of underwater acoustic sensors in the longitudinal direction of the passage through which a ship such as a submarine or a ship may pass and by using the difference between the directional angle received by each sensor and the intensity received by each sensor, And checking the position of the frequency signal.

However, there is a problem that the cost of producing and maintaining a fixed test site is astronomical and the optimal underwater marine environment must be secured. So, it is very difficult to realistically secure, and it is common to build at the national level. At present, only a few specific countries such as the United States, Britain and France have their own, and several EU countries such as Germany and Norway have jointly invested in Norway, and only the member countries use it.

If the underwater radiated noise generated by the ship is a problem, there will be a big problem in relation to the ship contract. In the case of a commercial vessel, there is a problem in relation to a frequency of response to an aquatic organism, and in the case of a vessel, detection and performance of an enemy are deteriorated in relation to the underwater acoustic stealth performance.

KR 1242715 B1 KR 1047960 B1

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method and system for estimating an unspecified underwater signal position that can be constructed at a lower cost than a conventional fixed system and uses a small number of underwater acoustic sensors.

According to another aspect of the present invention, there is provided a method of estimating a position of an undetermined signal in an underwater vehicle, comprising: generating a reference frequency signal by a reference frequency signal generator installed in a mobile ship; Measuring an underwater frequency signal by an underwater acoustic sensor; And a position estimator for detecting from the measured underwater frequency signal a point in time at which a differential function of time with respect to frequency is zero in each of the reference frequency signal and the specific frequency signal, and based on the detected times and the moving speed of the ship And estimating a generation position of the specific frequency signal.

Preferably, the calculating step includes: calculating a time difference between the detected times; Calculating a distance between a position of the reference frequency signal generator and a position of the specific frequency signal by multiplying the time difference by the moving speed of the ship; And estimating a position distant from the position of the reference frequency signal generator by the calculated distance as a generation position of the specific frequency signal.

 According to an aspect of the present invention, there is provided a system for estimating an undetermined signal position of an underwater signal according to the present invention, comprising: a reference frequency signal generator installed in a mobile ship for generating a reference frequency signal; An underwater acoustic sensor for measuring an underwater frequency signal; And detecting a time when a differential function of time for the frequency signal is zero in each of the reference frequency signal and the specific frequency signal from the underwater frequency signal measured by the underwater acoustic sensor, And a position estimator for estimating a generation position of the specific frequency signal based on the velocity.

Preferably, the position estimator calculates a time difference between the detected time points, multiplies the time difference by the moving speed of the ship, and calculates a distance between the position of the reference frequency signal generator and the generation position of the specific frequency signal And estimates a position distant from the position of the reference frequency signal generator by the calculated distance as a generation position of the specific frequency signal.

According to the present invention, it is possible to estimate a position of an unidentified underwater signal by using an underwater acoustic sensor with less cost and a smaller quantity than a conventional fixed system. In addition, since the limitation on the kind of the reference frequency is small, it is possible to easily estimate the position of the unidentified underwater signal.

As a result of actually testing the present invention at sea, it can be confirmed that the estimation is accurate to an error of about 1 m.

FIG. 1 shows an example of a result of measurement of general underwater radiated noise.
2 is a block diagram of an embodiment of a system for estimating an undetermined signal position in water according to the present invention.
FIG. 3 is a graph illustrating a general concept of time-frequency analysis performed by the position estimator of FIG. 2;
4 is a flow chart of a method for estimating a position of an unidentified underwater signal according to the present invention.
FIG. 5 shows an example of a position where the reference frequency signal generator of FIG. 2 is installed on a ship.
FIG. 6 shows an example of an underwater frequency signal measured by the underwater acoustic sensor of FIG. 2 when a ship equipped with a reference frequency signal generator is moved to the position of FIG.
FIG. 7 is an enlarged view of a region of interest in the LoFAR analysis result for the underwater frequency signal of FIG. 6; FIG.
Fig. 8 shows the generation position of the specific frequency signal estimated from Fig.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to be illustrative of the present invention and not to limit the scope of the invention. Should be interpreted to include modifications or variations that do not depart from the spirit of the invention.

Although the terms used in the present invention have been selected in consideration of the functions of the present invention, they are generally used in general terms. However, the present invention is not limited to the intention of the person skilled in the art to which the present invention belongs . However, if a specific term is defined as an arbitrary meaning, the meaning of the term will be described separately. Accordingly, the terms used herein should be interpreted based on the actual meaning of the term rather than on the name of the term, and on the content throughout the description.

The drawings attached hereto are intended to illustrate the present invention easily, and the shapes shown in the drawings may be exaggerated and displayed as necessary in order to facilitate understanding of the present invention, and thus the present invention is not limited to the drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a detailed description of known configurations or functions related to the present invention will be omitted when it is determined that the gist of the present invention may be obscured.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram of an embodiment of a system for estimating an undetermined signal position in water according to the present invention. Referring to FIG. 2, the estimation system 100 includes a reference frequency signal generator 110, an underwater acoustic sensor 120, and a position estimator 130.

The reference frequency signal generator 110 generates a reference frequency signal. The reference frequency signal is an arbitrary frequency signal for comparison with a specific frequency signal in question, and can be used as reference position information using GPS. As the reference frequency signal generator 110, an underwater speaker, a projector, a solid noise generator (solid sound oscillator), or the like can be used.

The reference frequency signal generator 110 is not necessarily provided separately in order to generate the reference frequency signal. An identifiable frequency signal originating from an identified position within the vessel may also be used as a reference frequency signal, in which case the source of such frequency signal may be the reference frequency signal generator 110.

The reference frequency signal generator 110 is installed on a moving ship, and the reference frequency signal is used as a reference frequency signal in estimating the generation position of a specific frequency signal generated from the moving ship.

Hereinafter, the case where the specific frequency signal is a frequency signal exceeding a predetermined underwater radiation noise reference will be described. However, the specific frequency signal is not limited to such a frequency signal, and the frequency signal for which the generation position is to be estimated may be a specific frequency signal.

Even if only one reference frequency signal generator 110 is used, it is possible to estimate the generation position of a specific frequency signal, and a plurality of reference frequency signal generators 110 are not necessarily required.

The underwater acoustic sensor 120 measures the underwater frequency signal. The underwater acoustic sensor 120 is installed underwater as a hydrophone and measures the frequency signal received at the installed position. When the ship passes the underwater acoustic sensor 120, the underwater acoustic sensor 120 measures the underwater radiated noise of the ship.

At this time, when a specific frequency signal is generated at an unidentified position in the ship and a reference frequency signal generator 110 is installed on the ship, the specific frequency signal and the reference frequency signal are measured by the underwater acoustic sensor 120.

The position estimator 130 receives the underwater frequency signal measured by the underwater acoustic sensor 120 and performs a time-frequency analysis on the specific frequency signal and the reference frequency signal identified from the underwater frequency signal.

FIG. 3 is a graph illustrating a general concept of time-frequency analysis performed by the position estimator 130 of FIG. Generally, a Doppler curve is shown when a noise source in a ship passes through an underwater acoustic sensor. FIG. 3 shows such a Doppler curve.

Doppler effect (Doppler effect, Doppler shift phenomenon) refers to a phenomenon in which the frequency and wavelength are changed depending on the wave source of a wave and the relative velocity of the observer. In the case of waves moving through the medium, such as sound, the effect varies depending on the relative velocity to the medium of the observer and the wave source.

In the case of moving only the wave source, when the wave source approaches the observer for one period T of the wave at the speed of v _s , the wave source becomes close to v _s T, so λ '= λ-v _s T. Here, f '= (v / (vv _s )) f is obtained by substituting λ' = v / f ', λ = v / f and T = Here, f is the actual frequency of the wave, f is the frequency observed by the observer, v is the velocity in the medium of the wave, v _s is the velocity of the source relative to the medium, to be.

In other words, according to the Doppler effect, when the wave source moves, the frequency of the front part of the wave source is shortened due to the shortening of the wavelength of the sound source, but the frequency is lowered due to the longer wavelength at the rear part. In such a case, it can be deduced that the sound source is on the side at a point in time before the frequency becomes low and becomes high. The state where the sound source is on the side corresponds to the state where the distance between the sound source and the observer is the shortest.

Therefore, in the graph of Figure 3 it can be deduced that the side of the noise source is underwater acoustic sensors at the time of T _s. This point of time is when the differential function of time for frequency becomes zero.

The position estimator 130 estimates the position of each of the specific frequency signal and the reference frequency signal identified from the underwater frequency signal on the side of the underwater acoustic sensor 120, A time point when the differential function of time with respect to frequency is zero is detected.

The position estimator 130 estimates the generation position of the specific frequency signal based on the detected times and the moving speed of the ship. Specifically, the position estimator 130 calculates a time difference between detected times, multiplies the calculated time difference by the movement speed of the ship, and calculates a distance D _i between the position of the reference frequency generator and the generation position of the specific frequency signal , estimates a position away by a distance D _i from the position of the reference frequency signal generator to generate position L _i of the specific frequency signal.

That is, when the time point detected in the reference frequency signal is T ₀ , the time point detected in the specific frequency signal is T _i , the moving speed of the ship is v, and the position of the reference frequency signal generator is L ₀ , The distance D _i = v (T _i -T ₀ ) between the generation position of the frequency signal and the generation position L _i = D _i + L ₀ of the specific frequency signal.

The position estimator 130 may be implemented as an apparatus including a computer processor and a memory. For example, the position estimator 130 may be implemented by a computer such as a PC.

4 is a flowchart of a method 200 for estimating an unidentified underwater signal position according to the present invention. Referring to FIG. 4, the reference frequency signal generator 110 generates a reference frequency signal (S210).

The reference frequency signal generator 110 is installed in the mobile ship. The user of the estimation method 200 first installs the reference frequency signal generator 110 on the ship and the ship passes the underwater acoustic sensor 120 while the reference frequency signal generator 110 is generating the reference frequency signal do.

FIG. 5 shows an example of a position where the reference frequency signal generator 110 of FIG. 2 is installed on a ship. Referring to FIG. 5, a first reference frequency signal generator and a second reference frequency signal generator, which are two reference frequency signal generators 110, are installed at a first position P ₁ and a second position P ₂ , respectively, have. Since the first reference frequency signal generator and the second reference frequency signal generator are installed by the user, the user knows the precise location of the first reference frequency signal generator and the second reference frequency signal generator installed in the ship.

The underwater acoustic sensor 120 measures the underwater frequency signal while the ship passes the underwater acoustic sensor 120 (S220). The first reference frequency signal generator and the second reference frequency signal generator continue to generate the reference frequency signal while the ship passes the underwater acoustic sensor 120. [

FIG. 6 shows an example of the underwater frequency signal measured by the underwater acoustic sensor 120 of FIG. 2 when the ship on which the reference frequency signal generator 110 is installed moves to the position of FIG. Referring to FIG. 6, a specific frequency signal 300 occurring at an unidentified position in a ship, a first reference frequency signal 310 generated by a first reference frequency signal generator, The second reference frequency signal 320 generated by the underwater acoustic sensor 120 is measured.

The user knows that the generation position of the first reference frequency signal 310 is P ₁ and the generation position of the second reference frequency signal 320 is P ₂ , I can not.

The position estimator 130 receives the underwater frequency signal measured by the underwater acoustic sensor 120 and determines the position of the specific frequency signal 300, the first reference frequency signal 310, The Doppler pattern is checked for each of the signals 320 to estimate the generation position of the specific frequency signal 300 (S230).

For this purpose, the position estimator 130 performs LoFAR (Low Frequency Analysis and Recording) analysis on the underwater frequency signal to grasp characteristics of each frequency.

FIG. 7 is an enlarged view of a region of interest in the LoFAR analysis result for the underwater frequency signal of FIG. 6; FIG. Referring to FIG. 7, the position estimator 130 may calculate a position T _s of a time derivative of a time with respect to a frequency in a Doppler pattern 400 of a specific frequency signal 300, a Doppler pattern of a first reference frequency signal 310, A point in time T ₂ at which the differential function of time for the frequency is 0 in the Doppler pattern 320 of the second reference frequency signal 320 and a point of time T _{2 in} which the differential function of time for the frequency is 0 are detected . 7, T _s is 60 seconds, T ₁ is 50 seconds, and T ₂ is 68 seconds.

Then, the position estimator 130 calculates the time difference between the detected time points. In FIG. 7, the time difference (T _s -T ₁ ) between T _s and T ₁ is 10 seconds, and the time difference (T _s -T ₂ ) between T _s and T ₂ is 8 seconds.

The position estimator 130 calculates the distance between the positions P ₁ and P ₂ of the reference frequency signal generator and the generation position of the specific frequency signal 300 by multiplying the calculated time difference by the moving speed of the ship.

Assuming that the ship has moved to 10 knots, the moving speed of the ship moving at 10 knots is 5 m / s since the moving distance of the ship per second is 0.5 m when 1 knots is converted to 1.8 km / h. Thus, between the distance _{D 1 = 5 [m / s} ] * 10 [s] = 50 m , and, P ₂ and the occurrence of a specific frequency signal 300 is located between P ₁ and the generation of a specific frequency signal 300 is located The distance D ₂ = 5 [m / s] * 8 [s] = 40 m.

Position estimator 130 is separated by a D ₁ = 50 m from P ₁ and D ₂ estimates a position separated by 40 m from the P = ₂ as the generation position of the specific frequency signal 300.

Fig. 8 shows the generation position of the specific frequency signal 300 estimated from Fig. Referring to Figure 8, the generation position P _s of the specific frequency signal 300 estimated by the position estimator (130) is separated by a D ₁ = 50 m from P _1, and are spaced apart by D ₂ = 40 m from P _2.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments of the present invention described above can be implemented separately or in combination.

Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

100: Estimation system of unidentified underwater signal position
110: Reference frequency signal generator
120: Underwater acoustic sensor
130:

Claims (5)

Generating a reference frequency signal by a reference frequency signal generator installed in the mobile ship;
Measuring an underwater frequency signal by an underwater acoustic sensor; And
The position estimator detects a time point when the differential function of time for the frequency is zero in each of the reference frequency signal and the specific frequency signal from the measured underwater frequency signal, and based on the detected times and the moving speed of the ship And estimating a generation position of the specific frequency signal.
2. The method of claim 1, wherein the calculating comprises:
Calculating a time difference between the detected times;
Calculating a distance between a position of the reference frequency signal generator and a position of the specific frequency signal by multiplying the time difference by the moving speed of the ship; And
And estimating a position distant from the position of the reference frequency signal generator by the calculated distance as a generation position of the specific frequency signal.
The method of claim 1, wherein the specific frequency signal is a frequency signal exceeding a predetermined underwater radiated noise reference.
A reference frequency signal generator installed in the mobile ship for generating a reference frequency signal;
An underwater acoustic sensor for measuring an underwater frequency signal; And
A time point when a differential function of time with respect to frequency is 0 in each of the reference frequency signal and the specific frequency signal is detected from the underwater frequency signal measured by the underwater acoustic sensor, And a position estimator for estimating a generation position of the specific frequency signal based on the estimated position of the specific frequency signal.
5. The apparatus of claim 4, wherein the position estimator calculates a time difference between the detected time points, multiplies the time difference by the moving speed of the vessel, and calculates a distance between a position of the reference frequency signal generator and a generation position of the specific frequency signal And estimates a position distant from the position of the reference frequency signal generator by the calculated distance as a position where the specific frequency signal is generated.

Images