KR100331182B1 - System for locating sound generation source - Google Patents

Abstract

Disclosed is a system for tracking the position of an actual sound source by measuring the time difference of arrival of sound waves reaching each detector when the positions of the sound wave detectors located in four places in space are known. The location tracking system of the present invention comprises a sound source detector consisting of a sound wave detector, a GPS receiver and a wireless transmitter, and a central control center for processing the data sent from a plurality of sound source detectors to track the location of the sound source. It is possible to secure the time synchronization and location information of the sound source detection unit by the GPS system, it is possible to automatically track the location of the sound source even if the sound source detection unit moves.

Description

Location system of sound source {System for locating sound generation source}

The present invention relates to a location tracking system, and more particularly to a location tracking system for automatically detecting the position of the sound source.

In the GPS (Global Positioning System) field, a user who has a wireless terminal used as a GPS receiver to determine his or her location is generally known. However, a method of tracking the location of a sound source at an unknown location using a GPS receiver radio terminal or the like is not known.

Although not in the GPS field, efforts to track the location of unknown sound sources have already been made in the field of rupture of transport pipes, such as water pipes. For example, U.S. Patent No. 5,058,419 issued to Nordstrom et al., Ruptures without digging ground by measuring the sound generated at the rupture of the pipeline at both ends of the water pipe and processing the signal in a specific range of frequency bands. Disclosing a technique for finding a location. However, this technique is limited in that it is applied only in one dimension.

Triangulation, which uses a base station in a cellular network to track the location of a frequency source, not only has the constraint of knowing exactly the distance between the base station from the source or the time difference at which the signal arrives between each base station at the source. There is a constraint that the base station is mostly fixed.

Therefore, the technical problem of the present invention is to provide a sound source location tracking system that can easily grasp the position of the sound source even if you do not know the exact distance from the sound source in the unknown position to the sound source detection means.

Another technical problem of the present invention is to provide a sound source position tracking system that can easily determine the position of the sound source even if the sound source detecting means moves.

1 is a block diagram showing the concept of a sound source location tracking system according to an embodiment of the present invention;

2 is a view showing an application example of the present invention.

In the position tracking system of the present invention for solving the above technical problems, and at least three sound source sensing means located in a place separated from each other; A GPS receiver installed at each of the sound source detecting means; In the position tracking system of the sound source having a central control center, each of the sound source detection means, means for detecting sound waves generated from an unknown sound source and time information and sound source detection means when detecting the sound wave from each of the GPS receiver Each transmission means for transmitting the respective location information to the central control center; Each of the GPS receivers receives a GPS satellite signal from a GPS satellite and a correction signal from a GPS reference station located at a known location, thereby generating position information of the sound source sensing means and canceling a receiver clock error from the GPS receiver time. Synchronizing the time of each of the sound source detecting means with GPS time, which is time; The central control center receives time information and position information at the time of detecting sound waves of each of the sound source sensing means from the transmitting means, and instead of obtaining an accurate distance between the sound source and the sound source sensing means, sound waves reach each sound source detecting means. Since the time required is different, the assumption is made of the sound wave generation time of the sound source, and the estimated travel time of the sound wave is multiplied by the sound velocity to generate a pseudorange, and the actual distance is a function of the position of the sound source and the sound source sensing means. Since distance is the sum of common error and pseudo-range common error, construct the system of equations from the pseudo-range and the position of the sound source sensing means and pseudo-distance relation (pseudo distance = actual distance + common error) and apply numerical solution. It is characterized by simultaneously estimating the pseudo-range common error and the location of the unknown sound source due to the assumption sound wave generation time. When using a GPS satellite signal, it may determine the location of the sound source detecting means in real time, it characterized in that the available at least one of the sound source movement sensing means.

Another aspect of the present invention is for the case where the sound source detecting means is fixed, and there is no need to use a GPS satellite signal. In this case, in the location tracking system of the sound source having at least three sound source detection means located in a site distributed from each other, the visual synchronization means installed in each of the sound source detection means by wires, and a central control center Each of the sound source detecting means includes a means for detecting sound waves generated from an unknown sound source, a time synchronized with a clock pulse provided from the time synchronizing means, and transmitting a time information for detecting sound waves to the central control center. Each wired transmission means; Each of the time synchronizing means transmits clock pulses to the respective sound source sensing means from one clock pulse generating means by wire to synchronize the time, and uses the counter to display the time information of each sound source detecting means by the number of clock pulses. Provide; The central control center receives the time information at the time of sound wave detection from the wired transmission means and obtains the correct distance between the sound source and the sound source sensing means, so that the sound waves reach the sound source sensing means differently so that the sound source is generated. Assuming the time, find the home travel time of sound waves, multiply the sound velocity to generate pseudorange, identify the sound source sensing means by hardware through wire transmission means, and read the location information of the sound source sensing means stored in memory In this paper, we construct a system of equations from the pseudo-ranges, the position of the sound source sensing means, and the pseudo-range relations (pseudo-real distance + common error) and apply a numerical solution to the common pseudo-ranges and unknowns due to the time of home sound wave generation. It is characterized by estimating the position of the sound source at the same time.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention.

1 is a block diagram showing the concept of a location tracking system of a sound source according to an embodiment of the present invention.

Referring to FIG. 1, sound waves generated in the sound source 10 are detected by at least three or more sound source detection units 20. Theoretically, four or more sound source sensing units 20 are required to determine the position of the sound source. However, if only three sound source detecting units are used when altitude is not required as a variable such as flat terrain in the city, do. Each sound source detecting unit 20 is provided with a sound wave detector 22, a GPS receiver 24, and a wireless transmitter 26.

The sound wave detector 22 detects only pulse sound waves having a predetermined intensity or more and a predetermined duration time among sound waves generated from the various sound sources 10. These pulsed waves are realistic gunshots, explosions, and emergency alarms. However, the sound wave sensor does not necessarily detect only the pulsed sound wave, but if the typical waveform of the sound wave generated from the sensing object is set in advance in the detector, accurate and fast sound wave detection can be achieved.

The GPS receiver 24 uses a calibration satellite navigation system (DGPS) that receives GPS satellite signals and correction signals 30 from satellites and reference stations, respectively. Corrected satellite navigation system (DGPS) is a system that can obtain position accuracy and accurate time information of several meters by compensating GPS pseudo-range common error calculated at the reference station located at the known location in the user receiver. The GPS receiver 24 generates position information and GPS time information of the sound source detecting unit 20. In this case, the GPS time is defined as a time when the receiver clock error is eliminated from the GPS receiver time, and the time of the sound source sensor 20 is synchronized with the GPS time because it provides an accurate GPS system time.

If the sound wave generated in the sound source 10 is already set in the sound wave detector 22, the wireless transmitter 26 centers the position information and the GPS time information of the sound source sensor 20 at the moment of sound wave detection from the GPS receiver. The central control center 40 receives the location information and GPS time information of each sound source detecting unit 20 at the time of sound wave detection from the wireless transmitting device 26, and the sound wave generation time of the sound source. It is assumed that the movement time of the sound wave is calculated and multiplied by the sound velocity to generate a pseudo distance from the sound source 10 to each sound source detection unit 20. Assuming that the sound source generation time of the sound source first reaches the sound source detection unit, the difference in time of arrival of the sound source reaching the sound wave for the first time from the sound source detection unit and the remaining sound source detection unit becomes the home movement time. It is possible to track the absolute position of the sound source 10 by solving the relationship between the pseudorange and the position information of each sound source detection unit 20.

Theoretically, this is as follows. The speed of sound depends on the medium and also on the condition of the medium. In general, however, the speed is constant regardless of the pitch or frequency of the sound. The product of the speed of sound and the arrival time of the sound wave is closely related to the distance between the sound source 10 and the sound wave detection position. Using this, the position of the sound source 10 generating sound waves can be obtained. That is, when sound waves occur in one sound source, the time to detect them differs depending on the distance from the sound source to the sound wave detection position. Therefore, when sound waves are detected in several places (for example, in three places in a flat terrain without considering altitude), Each pseudodistance can be calculated assuming each sound wave arrival time difference and sound wave generation time. That is, in case of a flat terrain, when the sound wave detection position and sound velocity are known, the actual distance is a function of the position of the sound source and the position of the sound source detection means, and the pseudo distance is the sum of the common distance and the pseudo distance common error. In the case of common error), there are three unknowns of the common distance (the difference between the pseudo distance and the actual distance) due to the positional coordinate value of the sound source and the time when the sound wave is generated. Therefore, if only three pseudo distances are generated, the numerical method The location of the sound source can be determined. Hereinafter, the calculation process for locating the sound source at the central control center will be described in detail with reference to equations. The pseudo distance is the sound wave generation of the sound source at the actual distance between the sound source and the sound source detection means. Since we don't know the time, it is the form of the error term that assumes this, and the error term is the error that is common to all pseudoranges. . There can be various ways of generating pseudo distance. Here, the difference of arrival time is calculated based on the sound wave detection time of the sound source detection means that the sound wave arrives first, and it is assumed that the time it takes for the sound wave to reach the sound source detection means first. Calculate the pseudo travel time of the sound wave and multiply it by the speed of sound to generate a pseudo distance. ) Can be expressed as the sum of the actual distance and the common error, and is expressed as Equation 1. [Equation 1] = Home travel time of sound waves * sound velocity = = = Where a = sound velocity, = Home travel time it takes for sound waves to reach the sound source detection means first (common to all pseudoranges), = difference in arrival time between the sound source detecting means j and the first sound source detecting means, = Actual distance between the sound source and the j sound source detection means, ( ) = The location of the sound source, ( ) = j is the position of the sound source sensing means, B = the common error term, where the subscript j denotes the jth sound source sensing means and assumes that measurements have been made at m sound source sensing means. Four or more measurement equations are required to determine the location of the three-dimensional sound source, and three or more measurement equations are required to obtain the location of the two-dimensional sound source. In Equation 1, the pseudo distance is returned to the right side and rearranged as shown in Equation 2. [Equation 2] Here, Equation (2) is expressed in Equation (3). here, : In Equation 3 consisting of common coordinates of positional coordinates and pseudorange of sound source Guess Taylor series expansion in the vicinity of Equation (4). The higher order term can be ignored and can be expressed as Equation 5. [Equation 5] here, And, using the least square method Is obtained as shown in Equation 6. Equation 6 Thus, the value you want to find silver to be. But to eliminate the effects of higher order terms Repeat the above process until the norm of converges to the specified reference value, even if you don't know the exact sound velocity, but you can find the position using the home sound velocity. If the concept is reversed, it can be used to find the correct sound velocity if the location of the sound source is known correctly. In this case, the difference between the actual sound wave generation time and the home sound wave generation time and the sound velocity are unknown. In this embodiment, although the GPS receiver 24 which receives the GPS satellite signal is used for time synchronization of the sound wave detector 22, Accordingly, the sound wave detector may be connected to the central control center by wire and the clock pulse may be sent from each clock pulse generating unit to each sound wave detector to synchronize the time between the sound wave detectors 20. In this case, the clock pulse and the counter are used to provide time information by the number of counters. In other words, time is obtained by multiplying the counter of the clock pulse by the period of the clock pulse. The sound wave detector transmits the number of counters at one time, that is, time information, to the central control center through a wired transmission means, and obtains the position of the sound source using the above-described method. The inventors of the present invention constitute a high-precision location tracking system using TCXO (clock pulse generating means) as a handset unit of a telephone, an acoustic wave detector, an industrial PC as a central control center, and a means for generating time synchronization and time information. There is a bar.

The invention can also be used to track the position of an object that generates ultrasonic waves with a specific pattern intentional, which is particularly useful for location tracking in water.

In addition, this concept can be applied to radio waves other than sound waves. In this case, the radio wave of a specific frequency can be detected, and the time difference of the radio waves can be obtained by comparing the signals from which the carrier is removed. The position of the radio transmitter can be obtained by using the pseudorange generated by multiplying the speed and the position of the radio detector.

Using this concept, the position of the moving object that generates PRN (Pseudo Random Noise) gold code can be obtained like a GPS satellite. In other words, the GPS channel, the position of the GPS receiver and the PRN gold code sent from the mobile device are sent to the control center through the radio transmitter, and the cross-correlation at the control center is determined. The cross-correlation technique can be used to determine the time difference of arrival of the propagation, so that the position of the moving object can be determined.

Next, an application example of the present invention will be described with reference to FIG. 2.

Referring to FIG. 2, four patrol cars 220 patrol between buildings 210 in the city area. Each patrol car 220 is equipped with a sound wave detector 222, a GPS receiver 224 and a radio transmitter 226. The GPS receiver 224 receives the GPS satellite signal 245 from the GPS satellite 240 and also receives the position correction signal 255 from the reference station 250 of the known location that receives the GPS satellite signal 245. The patrol car 220 allows to hold its location information and GPS time information.

When a sudden gunshot or an explosion occurs in the patrol area, a strong pulse sound wave 230 emitted from the sound source S is captured by the sound wave detector 222 of the patrol car 220. As the sound wave detector 222 detects the sound wave 230, the wireless transmitter 226 transmits the GPS time information of the time and the position information 265 of the patrol car to the central control center 270. The central control center 270 can track the location of the sound source in the same manner as described in the above embodiment, and the tracked position is transmitted from the central control center 270 to allow the patrol car to take appropriate countermeasures. .

The sound source location tracking system of the present invention can be applied to various situations. For example, in the mountainous terrain, a fixed sound source detector can be installed to detect illegal hunting.In the event of an armed spy, the sound source detector can be attached to a balloon or a hot air balloon. You can also determine the exact location.

In addition, if the sound source detector is configured by installing a GPS receiver on a buoy and installing a sound wave detector in the water, it can be used to track the position of an underwater object such as a submarine. This configuration can be useful for underwater ecological observation. When diving, install a sound source detector on the buoys around the observation area, install a control center on a nearby ship, and attach an ultrasonic generator to the body of the diver. In addition to keeping track of the location of the sound, divers may receive information about emergencies or other situations in the case of different types of sounds.

If the sound source detection unit is installed on the buoy or guard ship at the coast, nearby vessels can be used to request a rescue situation by informing them of the crisis and their location through a strong sounding device when an urgent situation occurs.

Furthermore, it may be an alternative to overcome surveillance blind spots in a parking lot or the like monitored by a surveillance camera.

The present invention can be used in the field of tracking the position of a sound source in relation to sound waves. Because of the nature of sound waves can be applied in the atmosphere and underwater, it has the advantage that it can be easily used for emergencies without regard to the place.

Claims (5)

At least three sound source sensing means located in a space separated from each other; A GPS receiver installed at each of the sound source detecting means; In the location tracking system of a sound source having a central control center having a processing processor, Each of the sound source detection means, Means for detecting sound waves generated from an unknown sound source, and respective transmission means for transmitting time information at the time of sound wave detection from each GPS receiver and position information of each of the sound source sensing means to the central control center; Each of the GPS receivers, The GPS satellite signal is received from a GPS satellite and a correction signal is received from a GPS reference station located at a known location, thereby generating location information of the sound source sensing means and canceling the receiver clock error from the GPS receiver time. Synchronize the time of each of the sensing means; The central control center uses the operation processor, Instead of receiving the time information and the positional information at the time of detecting the sound waves of each of the sound source sensing means from the transmitting means, and obtaining the exact distance between the sound source and the sound source sensing means, the time at which the sound waves reach the respective sound source sensing means is different. Assuming the sound wave generation time of the sound source, obtain the home travel time of the sound wave and multiply it by the sound velocity to generate a pseudorange.The actual distance is a function of the position of the sound source and the sound source sensing means, and the pseudo distance is the actual distance and the pseudo distance. Since it is the sum of common errors, it is assumed by constructing a system of equations and applying a numerical solution from the relation between the generated pseudoranges and the position of the sound source sensing means when detecting sound waves, that is, the pseudorange is the sum of the real distance and the common error. Simultaneously estimate the pseudo-range common error and the location of the unknown sound source by the sound wave generation time The positioning system of the source. Claim 2 has been deleted. Claim 3 has been deleted. The system of claim 1, wherein at least one of the sound source detecting means is movable. In the location tracking system of the sound source having at least three sound source detection means located in a distributed place of each other, the visual synchronization means installed in each of the sound source detection means by wire, and a central control center having a processing processor , Each of the sound source detection means, Means for detecting sound waves generated from an unknown sound source, and each wired transmission means for synchronizing the time with a clock pulse provided from the time synchronization means, and transmitting time information at the time of sound wave detection to the central control center; Each of the time synchronization means, Sending clock pulses to the respective sound source sensing means from one clock pulse generating means by wire to synchronize the time, and providing time information of each sound source sensing means by the number of clock pulses using a counter; The central control center uses the operation processor, Instead of receiving the time information when the sound wave is detected from the wired transmission means and obtaining the exact distance between the sound source and the sound source detection means, the time at which the sound wave reaches the sound source detection means is different so that the sound wave generation time of the sound source is assumed. Obtain the home travel time and multiply the sound velocity to generate pseudorange, identify the sound source detection means in hardware through wired transmission means, read the location information of the sound source detection means stored in memory, and generate the pseudorange And the distance equation of the sound source sensing means, that is, the pseudo distance is the sum of the actual distance and the common error, and construct a system of equations, and apply numerical solution to the pseudo distance common error and unknown sound source Positioning system of the sound source, characterized in that for estimating the position at the same time.