JP4984638B2 - Multistatic sonar and display method thereof - Google Patents

Description

  The present invention relates to a B-scope display method for an active sonar, and more particularly to a display method for a received signal in a multi-static sonar where the positions of transmission points and reception points are different.

  When the received signal is displayed in the B scope display of the active sonar, it is displayed in an orthogonal coordinate format in which the horizontal axis is the azimuth and the vertical axis is the distance, and the one shown in FIGS. 6 (a) and 6 (b) is known. It has been. In a conventional monostatic active sonar, a transmission point for transmitting a pulse and a reception point for receiving a reflected pulse from a target are set at the same position. That is, it is thought that the same path between the transmission point (and reception point) and the target is propagated back and forth, and the image when the reflected pulse from the target is received is swept along 1/2 of the sound velocity that is the propagation speed. By sweeping from the bottom to the top of the display screen uniformly at all speeds according to the timing of pulse transmission, it is displayed on the orthogonal coordinates corresponding to the azimuth distance of the target (reflection point).

In addition, in a multi-static active sonar where the transmission point and the reception point are in a different positional relationship and the reflected pulse from the target is received at a reception point at a position different from the transmission point, the monostatic active sonar The display form shown in FIG. 7 is known as a display form substantially similar to the B scope display, in which the received video signal is displayed in a rectangular coordinate format in which the horizontal axis is the azimuth and the vertical axis is the reception time. This is described in Patent Document 1. In FIG. 7, the horizontal axis represents the reception azimuth and the vertical axis represents the orthogonal coordinates of the reception time, and the numerical value in the coordinates and the curve corresponding to the numerical value indicate the distance from the reception point. As shown in FIG. 8, the distance from the reception point is calculated based on the relationship between the reception direction and the reception time, and indicates that the distance changes depending on the reception direction even at reception at the same time. The reception signal is sequentially displayed at each time for each direction, and the distance is obtained according to the reception direction and the reception time of the displayed reception signal. The calculation method is described in the specification of Patent Document 1.
JP 2001-74836 A

  In the multi-static sonar, the transmission point and the reception point are in a different positional relationship, and the reflection pulse from the target is received at the reception point at a position different from the transmission point.

  For this reason, if the sweep method in the B scope display used in the conventional monostatic active sonar is used as it is, the distance is obtained from the image of the displayed reception signal due to the characteristic that the distance varies depending on the reception direction even when receiving at the same time. It is impossible.

  Also, on the display screen, there is a method for displaying the received signal in each direction sequentially for each time in the orthogonal coordinate format with the vertical axis replaced with the received time, and obtaining the distance according to the received direction of the received signal and the received time. The distance is not uniform for each of the azimuth directions, and it is difficult to grasp the target positional relationship and movement as compared with the B scope display used in the conventional monostatic active sonar. For example, when reflected pulses from a plurality of targets are received and displayed, it is difficult to intuitively grasp the positional relationship between these targets. When a plurality of reflected pulses are supplementally tracked by multiple searches, it is difficult to intuitively grasp the movement of the target.

  An object of the present invention is to use a sweep method that takes into account the relationship between the reception direction and the reception time for a received signal at a reception point at a position different from the transmission point, and to receive a received image in the same manner as a B scope display of a conventional monostatic active sonar. It is an object of the present invention to provide a multi-static sonar in which a signal is displayed in an orthogonal coordinate format in which the horizontal axis is an azimuth and the vertical axis is a distance so that the position and movement can be easily visually recognized.

  In order to achieve the above object, a multistatic sonar according to the present invention includes a first means for controlling a transmission timing with the scheduled transmission time information as an input, and a second means for transmitting a pulse into water at the controlled transmission timing. And a third means for receiving an acoustic signal transmitted from the second means, and an azimuth and distance as viewed from the reception point of the acoustic signal. A fourth means for sweeping and displaying the video based on the acoustic signal on the orthogonal coordinates to be formed is provided.

  According to the present invention, the transmission timing is controlled with the scheduled transmission time information as an input, and the pulse is transmitted underwater at the controlled transmission timing. At a reception point different from the transmission point, an underwater acoustic signal based on the pulse is received, and an image based on the acoustic signal is swept and displayed on orthogonal coordinates formed by the reception direction and distance viewed from the reception point.

  As described above, according to the present invention, the received signal is displayed on a display screen in an orthogonal coordinate format in which the horizontal axis is the azimuth and the vertical axis is the distance, using a sweep method that considers the relationship between the received azimuth and the reception time. To display, the received signal, which is a reflected pulse from the target at the receiving point at a position different from the transmitting point, is displayed according to the azimuth and distance seen from the receiving point, and the positional relationship can be easily visually confirmed. it can.

  When reflected pulses from a plurality of targets are received and displayed, the positional relationship between these targets can be intuitively grasped. In addition, in the state where there is movement at the reception point or the target, when the reflected pulse from the target is supplementally tracked by multiple searches, it is possible to intuitively grasp the movement of the target.

  Next, the best mode for carrying out the invention will be described in detail with reference to the drawings.

(Embodiment 1)
As shown in FIG. 1, in the first embodiment of the present invention, the transmission platform 1 is arranged at the position of the transmission point, and the reception platform 2 is arranged at the reception point at a position different from the transmission point.

  As shown in FIG. 1, the transmission platform 1 includes a communication unit 11, a specification input / output unit 12, and a transmission unit 13.

  The communication unit 11 of the transmission platform 1 communicates with the communication unit 21 on the reception platform 2 side, and outputs the scheduled transmission time information from the communication unit 21 on the reception platform 2 side to the specification input / output unit 12 And a function of outputting the position information of the transmission platform 1 at the transmission time input from the specification input / output unit 12 to the communication unit 21 on the reception platform 2 side.

  The specification input / output unit 12 receives the position and time information of the transmission platform 1 from the outside, and the position information of the transmission platform 1 at the transmission time by using the scheduled transmission time information from the communication unit 11 as an input. And the function of outputting the scheduled transmission time information from the communication unit 11 and the time information acquired from the outside to the transmission unit 13.

  The transmission unit 13 has a function of transmitting the pulse underwater in accordance with the time set in the scheduled transmission time information by using the time information from the specification input / output unit 12 and the scheduled transmission time information as inputs.

  As shown in FIG. 1, the reception platform 2 includes a communication unit 21, a specification input / output unit 22, a reception unit 23, a control unit 24, a calculation unit 25, and a display unit 26.

  The communication unit 21 of the reception platform 2 communicates with the communication unit 11 on the transmission platform 1 side, and outputs the scheduled transmission time information input from the specification input / output unit 22 to the communication unit 11 on the transmission platform 1 side. And a function of acquiring position information of the transmission platform 1 at the transmission time output from the communication unit 11 on the transmission platform 1 side.

  The specification input / output unit 22 inputs the sound speed information, the function of acquiring the position and time information of the receiving platform 2 from the outside, and the position information of the transmitting platform 1 at the transmission time from the communication unit 21, and receives the position information. It has a function of outputting to the calculation unit 25 and a function of outputting the scheduled transmission time information input from the control unit 24 to the communication unit 21.

  The receiving unit 23 has a function of receiving an acoustic signal for each azimuth, converting the received signal into a video signal, and outputting the video signal to the display unit 26.

  The control unit 24 has a function of inputting scheduled transmission time information from outside and outputting the scheduled transmission time information to the calculation unit 25 and a function of outputting the scheduled transmission time information to the specification input / output unit 22. .

  The calculation unit 25 is the scheduled transmission time information input from the control unit 24, the sound speed information input from the specification input / output unit 22, the position information of the transmission platform 1 at the transmission time, and the position information of the reception platform 2 at the transmission time. Is used to calculate a sweep speed for each reception azimuth to create a sweep control signal and output the sweep control signal to the display unit 26.

  The display unit 26 receives the video signal for each direction input from the reception unit 23 based on the sweep control signal input from the calculation unit 25 and the reception direction and distance viewed from the reception point by the sweep speed controlled for each reception direction. It has a function of sweeping and displaying an image on the orthogonal coordinates formed by

  Here, the control unit 24, the specification input / output unit 25, the communication units 11 and 21, and the specification input / output unit 12 constitute a first means for controlling the transmission timing with the scheduled transmission time information as an input. The transmission unit 13 constitutes a second means for transmitting a pulse into the water at the controlled transmission timing. The receiving unit 23 constitutes a third unit that is present at a position different from the second unit and receives an acoustic signal transmitted from the second unit. The input / output units 12 and 22, the communication units 11 and 21, the control unit 24, the calculation unit 25, and the display unit 26, on the orthogonal coordinates formed by the azimuth and distance viewed from the reception point of the acoustic signal, A fourth means for sweeping and displaying an image based on the acoustic signal is configured.

  Next, the operation of Embodiment 1 of the present invention will be described in detail with reference to FIG.

  In step S1 of FIG. 2A, the control unit 24 of the reception platform 2 obtains transmission scheduled time information from the outside, and controls the transmission timing of pulse transmission by the transmission unit 13 of the transmission platform 1 based on the information. Information to be transmitted to the input / output unit 22.

  2A, when the communication unit 21 of the reception platform 2 receives the scheduled transmission time information from the specification input / output unit 22, the communication unit 11 of the transmission platform 1 transmits the planned transmission time information. Send to.

  In step S3 of FIG. 2A, the specification input / output unit 12 acquires the position and time information of the transmission platform 1 from the outside, the scheduled transmission time information from the communication unit 11, and the time information acquired from the outside. Are output to the transmitter 13.

  In step S4 of FIG. 2A, when receiving the transmission scheduled time information and the time information from the specification input / output unit 12, the transmission unit 13 transmits a pulse together with the scheduled transmission time information.

  In step S5 of FIG. 2A, when the transmission unit 13 transmits a pulse, the specification input / output unit 12 outputs position information of the transmission platform 1 at the transmission time at which the pulse is transmitted to the communication unit 11. When the communication unit 11 of the transmission platform 1 receives the position information of the transmission platform 1, the communication unit 11 transmits the position information to the communication unit 21 of the reception platform 2.

  The specification input / output unit 22 obtains sound speed information and the position and time information of the receiving platform 2 from the outside, inputs the position information of the transmitting platform 1 at the transmission time from the communication unit 21, and calculates the position information. To 25.

  In step S6 of FIG. 2B, the receiving unit 23 receives an acoustic signal for each direction, converts the received signal into a video signal, and outputs the video signal to the display unit 26.

  In step S7 of FIG. 2B, the calculation unit 25, the scheduled transmission time information input from the control unit 24, the sound speed information input from the specification input / output unit 22, and the position information of the transmission platform 1 at the transmission time, Using the position information of the reception platform 2 at the transmission time, the calculation unit 25 generates a sweep control signal for sweeping and displaying the video signal on the orthogonal coordinates formed by the reception azimuth and distance as viewed from the reception point. create.

  The sweep control signal is transmitted at the transmission time obtained from the transmission scheduled time information obtained from the control unit 24 and from the outside in the specification input / output unit 12 and obtained through the communication unit 11, the communication unit 21, and the specification input / output unit 22. Based on the position information of the platform 1, the position and time information of the receiving platform 2 obtained by inputting from the outside in the specification input / output unit 22, and the position information of the receiving platform 2 at the transmission time obtained from the scheduled transmission time information The distance from the transmission point to the reception point at the transmission time is obtained, and further, the sweep distance with respect to time is calculated for each reception azimuth based on the sound velocity information that is the propagation speed of the pulse obtained by inputting from the outside in the specification input / output unit 22. And create.

  In step S8 of FIG. 2B, the display unit 26 uses the sweep speed controlled for each reception azimuth based on the sweep control signal input from the calculation unit 25 for each azimuth video signal input from the reception unit 23. The image is swept and displayed on the orthogonal coordinates formed by the reception direction and distance viewed from the reception point.

  As described above, according to the first embodiment of the present invention, the received signal is swept in consideration of the relationship between the reception direction and the reception time on the display screen of the orthogonal coordinate format in which the horizontal axis is the azimuth and the vertical axis is the distance. In order to display the received signal, the received signal, which is a reflected pulse from the target at the receiving point at a position different from the transmitting point, is displayed according to the azimuth and distance viewed from the receiving point, and the positional relationship is easily It can be visually recognized.

  When reflected pulses from a plurality of targets are received and displayed, the positional relationship between these targets can be intuitively grasped. In addition, in the state where there is movement at the reception point or the target, when the reflected pulse from the target is supplementally tracked by multiple searches, it is possible to intuitively grasp the movement of the target.

(Embodiment 2)
FIG. 3 is a block diagram showing Embodiment 2 of the present invention. The second embodiment of the present invention shown in FIG. 3 is characterized in that a detector 27 is provided in the configuration of the receiving platform 2 of the first embodiment shown in FIG.

  In Embodiment 2 of the present invention, instead of inputting the sound velocity value from the outside, the direct wave of the pulse transmitted in the transmission unit 13 is received by the reception unit 23, and the transmission point and the reception point are determined from the reception time of this direct wave. The direct propagation time is obtained, and the sound speed is derived from the distance between the transmission point and the reception point.

  That is, in the specification input / output unit 22 shown in FIG. 3, the information obtained from the outside is only the position and time information of the receiving platform 2, and the sound speed information is not inputted.

  The detection unit 27 is connected to the specification input / output unit 22, the reception unit 23, the control unit 24, and the calculation unit 25, and the location information of the transmission platform 1 at the transmission time and the reception platform at the transmission time from the specification input / output unit 22. 2 is input, a transmission time notification is input from the control unit 24, a reception signal is input from the reception unit 23, a direct wave of a transmitted pulse is detected and the time is extracted, and a transmission point and reception are received. The direct propagation time between the points is obtained, the sound speed is calculated from the distance obtained from the position information of the transmission point and the reception point, and the calculated sound speed information is output to the calculation unit 25.

  According to the second embodiment of the present invention, it is possible to create a sweep control signal by directly obtaining a sound speed value on-site sequentially without providing a means for inputting sound speed information from the outside, and an error in the displayed target distance. It has the advantage that can be suppressed.

  Next, operations of the first and second embodiments of the present invention will be described in detail using specific examples.

  In the first embodiment of the present invention shown in FIG. 1, information on the scheduled transmission time tx is inputted from the outside by a keyboard or the like in the control unit 24 of the receiving platform 2, and the information is input to the specification input / output unit 22 as scheduled transmission time information. The data is output and distributed to the transmission unit 13 via the communication unit 21, the communication unit 11, and the specification input / output unit 12. In addition, the time information tn input from the outside in the specification input / output unit 12 is sequentially output to the transmission unit 13, and when the time information tn = scheduled transmission time tx in the transmission unit 13, a pulse is transmitted underwater.

  The specification input / output unit 12 inputs the position information of the transmission platform 1 from the outside in pairs with the time information tn, and the transmission time, that is, the time information tn = the position S of the transmission platform 1 at the scheduled transmission time tx is the communication unit. 11, the communication unit 21, the specification input / output unit 22, and the data is distributed to the calculation unit 25.

  Similarly, the position input / output unit 22 inputs the position information of the receiving platform 2 from the outside in a pair with the time information tn, and the transmission time, that is, the time information tn = the position R of the receiving platform 2 at the transmission scheduled time tx is calculated. 25. Further, the information input / output unit 22 inputs information on the sound speed value from the outside, and distributes the information on the sound speed value to the calculation unit 25.

  The receiving unit 23 of the receiving platform 2 receives an underwater acoustic signal, converts the received signal for each direction into a video signal, and outputs the video signal to the display unit 26.

  Here, the relationship between the reception direction of the target reflected pulse and the reception time and the distance to the target viewed from the reception point will be described with reference to FIG.

Time until the direct wave of the pulse transmitted at the transmission position S reaches the reception position R from the distance (direct wave propagation distance) Dsr and the sound velocity value C between the transmission position S and the reception position R at the scheduled transmission time t _x (direct wave propagation time) _{t d} is determined by (1).
t _d = Dsr / C (1)

In addition, the time from when the pulse is reflected at the target T to the reception position R after transmission at the transmission position S is t, the propagation time from the transmission position S to the target T is t _st , and the pulse is reflected at the target T T _tr , the time from the target T to the reception position R, D _tr , and the direction of the target T viewed from the reception position R as θ.
t = t _st + t _tr (2)
t _st = {(t _d −t _tr × cos θ) ² + (t _tr × sin θ) ² } ^(1/2) (3)
(2) to (3) by substituting the equation solved for t _tr if ^{_{t tr = (t 2 -t d}} 2) / {2 × (t-t d × cosθ)} (4)
Here, the distance D _tr between the target T and the receiving position R is
D _tr = t _tr × C (5)
Substituting equation (4) into equation (5), D _tr = [(t ² −t _d ² ) / {2 × (t−t _d × cos θ)}] × C (6)
The distance D _tr from the reception position R to the target T is the time T from the transmission at the transmission position S until the pulse is reflected by the target T and reaches the reception position R, and the target T as viewed from the reception position R. It is obtained by a function of the direction θ of

  In other words, when it is apparent that a pulse is transmitted from the reception point, the apparent propagation speed viewed from the reception point indicates a change with time and direction.

In the calculation unit 25 shown in FIG. 1, a sweep control signal is created for each reception direction received by the reception unit 23 based on the equation (6), and the horizontal axis is the reception direction as shown in FIGS. The vertical axis is formed with the distance from the receiving point and the display screen is formed with orthogonal coordinates, and the control is performed to sweep the distance according to the time every reception azimuth θ1, θ2, θ3. By receiving and sweeping the image of the received signal for each direction in the unit 26, the received reflected pulse signal is displayed on the display screen having the horizontal axis as the reception direction and the vertical axis as the orthogonal coordinates formed by the distance from the reception point. .

  Next, the operation of Embodiment 2 of the present invention shown in FIG. 3 will be specifically described. In the specification input / output unit 22 in Embodiment 2 of the present invention shown in FIG. 3, the information obtained from the outside is only the position and time information of the receiving platform 2, and no sound speed information is input.

  The detection unit 27 is connected to the specification input / output unit 22, the reception unit 23, the control unit 24, and the calculation unit 25.

The transmitter 13 transmits a pulse underwater when time information tn = scheduled transmission time tx. In the detection unit 27, the signal received by the reception unit 23 is input, the direct arrival wave of the transmitted pulse is detected, and the direct arrival time t _d2 is obtained from the time information input from the specification input / output unit 22, Further, the direct propagation time t _sr from the transmission position S to the reception position R is obtained from the scheduled transmission time t _x input from the control unit 24.

Further, in the detection unit 27, the distance d _sr between the transmission position S and the reception position R is obtained from the transmission position S and the reception position R at the transmission time input from the specification input / output unit 22, and the direct propagation time t _sr is obtained. The speed of sound C (C = d _sr / t _sr ) is obtained, and information on the obtained speed of sound C is output to the calculation unit 25. These operations are performed each time transmission is performed, and other operations are the same as those of the first embodiment of the present invention.

  By such an operation, without providing a means for inputting sound velocity from the outside, it is possible to create a sweep control signal by directly obtaining sound velocity values at the site, and to suppress errors in the displayed target distance. It becomes possible.

  As described above, according to the present invention, in an active sonar that transmits a pulse underwater, receives a reflected pulse from a target, and searches for an underwater object or uses it for position localization, it is reflected at a reception point at a position different from the transmission point. The present invention can be applied to applications such as a received signal display device at a receiving point of a multi-static sonar that receives pulses.

It is a figure which shows the structure of Embodiment 1 of this invention. (A), (b) is a flowchart explaining operation | movement of Embodiment 1 of this invention. It is a figure which shows the structure of Embodiment 2 of this invention. It is a figure which shows the specific example of operation | movement of Embodiment 1 of this invention. It is a figure which shows the example of a display of receiving direction versus distance in Embodiment 1 of this invention, and sweep operation. (A) is a figure which shows B scope display of the conventional monostatic active sonar, (b) is a figure which shows sweep operation | movement. It is a figure which shows the display of the conventional bistatic active sonar. It is a figure which shows the positional relationship in a bistatic active sonar, and the relationship between receiving time and receiving distance.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Transmission platform 11 Communication part 12 Specification input / output part 13 Transmission part 2 Reception platform 21 Communication part 22 Specification input / output part 23 Transmission part 24 Control part 25 Calculation part 26 Display part 27 Detection part

Claims (4)

In a multi-static sonar that transmits a transmission pulse from a transmission point toward a target and receives a reflected pulse from the target at a reception point at a position different from the transmission point.
A transmission platform and a reception platform;
The sending platform is
The time information and the information on the scheduled transmission time transmitted from the receiving platform are input, and when the time information and the scheduled transmission time match, the location information of the transmitting platform is distributed to the receiving platform. Former input / output unit,
A transmission unit that transmits a pulse when the time information matches the scheduled transmission time,
The receiving platform is
A specification input / output unit for outputting a pair of time information and position information of the receiving platform, position information of the transmitting platform, and information of sound velocity values;
A receiving unit that receives the reflected pulse reflected by the target and converts the received signal for each direction into a video signal, and outputs the video signal to the display unit;
Based on the information output from the specification input / output unit, the time from transmission of the distance from the reception position of the pulse to the target viewed at the transmission position until the pulse is reflected by the target and reaches the reception position And the target azimuth function viewed from the reception position, and based on the result, the horizontal axis is the reception azimuth and the vertical axis is the orthogonal coordinate formed by the distance from the reception point. And sweeping the distance according to the time and displaying the image of the received signal for each azimuth on the display unit, the horizontal axis is the reception azimuth and the vertical axis is the distance from the reception point. A multi-static sonar comprising: an arithmetic unit for displaying a received reflected pulse signal on a display screen having coordinates . The receiving platform has a detector;
The detection unit receives a signal received by the reception unit, detects a direct arrival wave of the transmitted pulse, and obtains a direct wave arrival time from time information input from the specification input / output unit. The multi-static sonar according to claim 1, wherein the direct propagation time from the transmission position to the reception position is further obtained based on the scheduled transmission time input from the control unit.   Further, the detection unit obtains the distance between the transmission position and the reception position based on the transmission position and the reception position at the transmission time input from the specification input / output unit, and determines the sound velocity based on the obtained distance and the arrival propagation time of the direct wave. The multi-static sonar according to claim 2, wherein: In a display method of transmitting a transmission pulse from a transmission point toward a target, receiving a reflected pulse from the target at a reception point at a position different from the transmission point, and displaying the target on the screen of the multi-static sonar,
Using a multi-static sonar with a sending platform and a receiving platform,
In the transmission platform,
With the time information and the information of the scheduled transmission time transmitted from the receiving platform as inputs, when the time information and the scheduled transmission time match, the position information of the transmitting platform is distributed toward the receiving platform, Sending a pulse when the time information and the scheduled transmission time match,
In the receiving platform,
Receive the reflected pulse reflected by the target at the target, convert the received signal for each direction into a video signal, output the video signal to the display unit,
Based on the pair of the time information and the position information of the receiving platform, the position information of the transmitting platform, and the information of the sound velocity value, the distance from the receiving position of the pulse to the target viewed at the transmitting position is transmitted. The time from when the pulse is reflected to the target until it reaches the reception position and the target azimuth as seen from the reception position, the horizontal axis is the reception azimuth and the vertical axis is the distance from the reception point. By performing a control to sweep the distance according to the time every reception azimuth on the display screen formed as orthogonal coordinates formed by and by sweeping and displaying the image of the reception signal for each azimuth on the display unit, the horizontal axis A display method of a multi-static sonar, wherein the received reflected pulse signal is displayed on a display screen having an orthogonal coordinate formed by a reception azimuth and a vertical axis a distance from the reception point .

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