JP2013096963A - Underwater video acquisition device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve the problems that miniaturization of a device is indispensable in order to load an underwater video acquisition device using ultrasonic waves on an independent type unmanned diving unit, and reduction of power consumption for extension of operation time, increase of frame rate for observation of a mobile object, and increase of resolution for observation of a small reflector become barriers to practical application.SOLUTION: Incoming waves are broken down in the vertical and horizontal directions only with an acoustic lens by providing an underwater video acquisition device with a spherical acoustic lens, or an acoustic lens which shows an equivalent effect as that of the spherical acoustic lens. An incoming direction of reflected waves is known to allow imaging by detecting ultrasonic waves after passing through the acoustic lens. In addition, the small acoustic lens with high resolution and wide viewing angle is provided. The underwater video acquisition device with low power consumption and high frame rate is further provided.

Description

  The present invention relates to an underwater image acquisition device (sona) equipped with a moving body such as a ship, a ship towing body, an autonomous unmanned submersible, and an acoustic lens that irradiates ultrasonic waves in water and receives the reflection. ).

  In water, ultrasonic waves are generally less attenuated than visible light and electromagnetic waves, and propagate in water with low transparency. Therefore, as a technique for recognizing the position, size, and shape of an object in water, an imaging technique (a sonar) using an acoustic technique has been studied. For example, in such a video acquisition device, it is installed on a ship or a towed body towed by a ship, and the reflection of the ultrasonic wave transmitted from the transmitter is received by the receiver while moving the position of the video acquisition device. There is a three-dimensional imaging sonar that acquires two-dimensional data and further acquires a three-dimensional image by processing in time series.

  Patent Document 1 discloses an underwater image acquisition apparatus that employs a frequency sweep method that enables steering of a transmitted beam by changing the frequency of an electrical signal input to the transmitter.

  The underwater image acquisition device described in Patent Literature 1 includes an acoustic lens that focuses reflection from a target in front of a receiver. In the frequency sweep method, the transmission beam can be steered only by inputting transmission electric signals having different frequencies in the transmission electric circuit 1ch to the electroacoustic transducers for transmitters arranged with the polarities reversed alternately. The frequency sweep method is a method in which the frequency varies depending on the transmission direction, and therefore, the received signal received by the receiver channel 1 can be separated in the azimuth direction only by Fourier transform.

  Patent Document 2 discloses a video acquisition device that can perform underwater visual inspection even in muddy water or at night, such as underwater work that is not affected by the turbidity and illuminance of water, monitoring for underwater security, and the like. In the video acquisition device described in Patent Document 2, a one-dimensional transducer array is used as a wave receiver, and an acoustic lens is provided on the entire surface. The acoustic lens decomposes the reflected wave from the object in the vertical direction, and receives the position information in the vertical direction of the object by receiving it with a wave receiving element corresponding to the direction. In other words, the ultrasonic wave is decomposed in the horizontal direction by the frequency sweep method, the ultrasonic wave is decomposed in the vertical direction by the acoustic lens, and the ultrasonic wave is decomposed in the depth direction by processing the received signal in time series. A dimensional image is acquired.

  In the frequency sweep method, the direction in which the reflected wave from the object returns needs to be uniquely associated with the transmission frequency. Since ultrasonic waves of different frequencies reflected from the other channels above exist as reverberation in the apparatus, a ghost appears in the captured image, particularly in the vertical direction. Patent Document 3 discloses a technique for reducing noise and ghost of an acoustic image in an underwater image capturing apparatus that employs a frequency transmission method.

Direction-of-arrival separation using a lens is not limited to one dimension. A Luneberg lens is known in the microwave antenna field as a lens that can separate an incoming wave for each direction of arrival, regardless of whether it is vertical or horizontal. The Luneberg lens described in Non-Patent Document 1 has a spherical shape, the refractive index is maximum at the center of the lens, and the refractive index is designed to continuously decrease from the center of the lens to the outside. Is. When the radius of the lens is R and the distance from the lens center is r, when the refractive index distribution n follows n = (2- (r / R) ² ) ^1/2 , the plane wave incident on this lens is A focal point is formed on the opposite sphere surface.

JP 47-026160 JP2009-204471A JP 2009-250734 A

The Mathematical Theory of Optics, Univ. California Press, 1964

  An observation object of a conventional imaging sonar provided on a ship or the like is often a metric order stationary object. In this application, the size of the apparatus may be a size that can be mounted on a ship, and the power consumption may be prepared separately from the ship. Further, since the observation target is stationary, a high frame rate is not required.

  On the other hand, there are some problems in using an imaging sonar in an autonomous unmanned submersible for multi-purpose use. These include downsizing of imaging sonar, low power consumption, high resolution, high frame rate, and wide viewing angle.

In general, since a self-supporting unmanned submersible is smaller than a ship or the like, an imaging sonar mounted thereon must also be miniaturized.
In addition, if the power consumption of the imaging sonar itself is high, the operation time of the autonomous unmanned submersible is limited, so it is important that the power consumption is low.
Furthermore, since the observation target cannot be limited for use in multipurpose applications, a high frame rate is essential for observing not only stationary objects but also moving objects. Similarly, in order to be able to observe a reflector smaller than the conventional object, it is necessary to achieve high resolution.

  These problems can be achieved by limiting the observation area to be smaller than that of the conventional apparatus. However, in order to observe efficiently and without missing, rather, the observation area must be expanded.

  As described above, the present invention provides an imaging sonar that is small enough to be mounted on a self-supporting unmanned submersible, low power consumption, high resolution, high frame rate, and wide viewing angle.

  In order to achieve the above object, an underwater image acquisition device according to the present invention includes a wave transmission unit that transmits ultrasonic waves toward an underwater object, and an incident surface on which an ultrasonic wave reflected from the object is incident. A receiving surface on which the incident reflected wave is converged, and the sound wave incident surface and the sound wave receiving surface have the same central axis, each having a constant curvature, and at least two layers or more from different sound speed media A configured acoustic lens, a receiver that receives a reflected wave that has passed through the acoustic lens, a signal processing unit that performs signal processing on the reflected wave that is received by the receiver, and a signal process that is processed by the signal processing unit Display means for displaying an audio image based on the result.

  According to the present invention, by providing a spherical acoustic lens or an acoustic lens that exhibits an effect equivalent to that of a spherical acoustic lens, it is possible to decompose the incoming wave in the vertical and horizontal directions using only the acoustic lens. That is, it is possible to know the arrival direction of the reflected wave by detecting the ultrasonic wave after passing through the acoustic lens.

  Further, it is possible to provide an acoustic lens that is smaller, has a higher resolution, and has a wider viewing angle than a compound lens having a plurality of lenses.

  Furthermore, an imaging sonar with low power consumption and high frame rate can be provided.

The basic block diagram of the underwater image acquisition device which is an embodiment of the present invention One of the most suitable embodiments of the transmitter of the present invention The figure explaining the basic design concept of the acoustic lens of this invention Diagram explaining the homogeneous layer Luneberg lens One of the most suitable embodiments of the detection unit of the present invention The figure explaining the effect of the acoustic lens of this invention The figure explaining the effect of the acoustic lens of this invention The figure explaining the effect of the acoustic lens of this invention The figure explaining the effect of the acoustic lens of this invention The figure explaining the effect of the acoustic lens of this invention

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. The following embodiments do not limit the invention according to each claim, and all combinations of features described in the embodiments are not necessarily essential to the solution means of the invention. Absent.

  FIG. 1 is one of the most preferred embodiments of the present invention, and illustrates a block diagram inside an imaging sonar implemented by the present invention.

  The sonar includes a transmitter 100 that transmits ultrasonic waves to the outside, a receiver 102 that receives reflections of the transmitted sound waves from an object, an acoustic lens 101 that focuses the reflected sound waves on the receivers 102, and received reflections. An amplifier (AMP) 103 that amplifies an analog signal by waves, an A / D converter (ADC) 104 that converts an analog signal to a digital signal, a memory unit 105 that stores the digital signal, and an azimuth of an object from the digital signal Arithmetic processing unit 106 for generating an image by performing azimuth analysis, range azimuth analysis, distance analysis between the device and the object based on a transmission / reception time difference, an operation panel 107 for providing an interface between the device and the user, and setting A waveform generator 108 for generating an ultrasonic signal according to the specifications of the transmitted signal, and an amplifier 109 (amplifying the signal from the waveform generator 108) And MP), comprising an image display unit 110 for displaying an image generated as a result of the arithmetic processing. As the transmitter 100 and the receiver 102, an ultrasonic transducer in which a matching layer and a backing material are provided on a piezoelectric body such as PZT (lead zirconate titanate) is generally provided as a transmitter / receiver. is there.

  The operation panel 107 is composed of, for example, a mouse and a keyboard. The user sets specifications of the transmission signal, analysis conditions, image display conditions, and the like via the operation panel 107.

  As a general signal processing in the sonar, the arithmetic processing unit performs processing such as speed correction, oblique distance correction, fluctuation correction, envelope detection, etc., in addition to the above, on the signal after A / D conversion. . The order of processing is arbitrary, and there may be other signal processing such as a scan converter and a band pass filter, or a combination thereof. In other words, the arithmetic processing unit performs any processing internally as long as the purpose of generating the sound image and sound image represented by luminance is achieved by cutting out the finally processed received signal in time series. It does not matter.

  The characteristics of the acoustic lens 101 according to the present invention will be described below, and the effects when this lens is used will be described.

  The most basic feature of the acoustic lens 101 in the present invention is that two-dimensional phasing is possible only with the acoustic lens without using signal processing such as a circuit. One of the two-dimensional beam forming spheres is a sphere. By combining the spherical acoustic lens with the two-dimensional receiving element array, the sound wave can be divided in the vertical direction and the horizontal direction as follows. First, a reflected wave from an object is focused by a spherical acoustic lens and received by a receiving element array arranged two-dimensionally along the lens shape. At this time, before and after passing through the acoustic lens, the direction of arrival of the reflected sound wave and the receiving element are associated one-to-one. The reflected sound wave received by each element can constitute a two-dimensional image with reference to this correspondence. In addition, by expressing the arrival delay time of the reflected sound wave as the depth of the sonar observation area, a three-dimensional image of vertical, horizontal, and depth can be acquired.

  An imaging sonar that uses a frequency sweep method to perform beam forming requires a special transmission circuit and a circuit for frequency analysis of the received signal, and an imaging sonar that uses a phased array method. Then, many delay circuits are necessary. The acoustic lens 101 according to the present invention can perform two-dimensional phasing with only the lens, and does not require a circuit essential for the frequency sweep method or the phased array method, so that power consumption can be suppressed.

  In addition, by using the acoustic lens according to the present invention, the configuration of the transducer can be simplified and the power consumption can be reduced.

  In the frequency sweep method, since the transmission beam is steered by frequency, transmission signals for the used frequency band are required. For this reason, both the transmitter and the receiver are required to have a wide band characteristic to cover the used frequency band. When transmitting broadband noise as a broadband signal that transmits the frequency band to be used, since multiple frequency signals are superimposed, the transmission power increases, exceeds the allowable input power of the transmitter, and the scale of the electronic circuit increases. . In addition, when transmitting a linear FM as a wideband signal for transmitting the used frequency band, the frequency is monotonously and continuously increased or decreased, so that the transmission direction continuously changes and sufficient transmission energy cannot be secured. The acquired sound image becomes unclear. Furthermore, in the transmitter using the frequency sweep method, since the transmission array is inclined, a certain pulse width is required to secure sufficient transmission energy, but the distance resolution increases as the pulse width increases. Becomes worse.

  On the other hand, in this method, there is no restriction like the frequency sweep method. The transducer may have narrow band characteristics. The transmitter in the present invention may be an omnidirectional transmitter 200 as shown in FIG. 2, and may be a pulse wave 201 or a chirp wave with a short pulse width. A transducer can be configured with low power consumption.

  In addition, the acoustic lens according to the present invention has an effect that it can be made smaller than a composite acoustic lens having a plurality of lenses made by combining spherical and aspherical lenses.

  Details of the description that has the effect that the present invention can be miniaturized will be described below. In general, since there is a correlation between lens size and direction-of-arrival decomposition, there is a limit to miniaturization. As the lens is made smaller, the spread of the focal point due to diffraction increases. That is, if the lens is made too small, the arrival direction of the reflected sound wave and the receiving element cannot be associated one-to-one, resulting in degradation of the arrival direction resolution, that is, degradation of the resolution in image display.

  When configuring an imaging sonar using a composite acoustic lens composed of multiple spherical and aspherical lenses, the focusing and aberration characteristics from each direction of arrival are the same as in spherical acoustic lenses. Must design. In order to make the focusing characteristics and aberration characteristics the same regardless of the arrival direction, it is necessary to increase the number of compound lenses and cancel the aberrations caused by the lens elements. However, since the total thickness of the lens increases as the number of acoustic lenses increases, there is a side effect that the acoustic energy passing through the lens is attenuated and the image intensity is reduced. When a composite acoustic lens is constructed by combining two or three acoustic lenses, for example, when there is no significant decrease in image intensity, a plurality of convergence characteristics, aberration characteristics, and aberration characteristics from one arrival direction are simultaneously selected. It is difficult to optimize for direction. For this reason, in order to make the focusing characteristics from each direction of arrival the same, it is necessary to design the focal diameters to some extent, so that the lens tends to be large in order to improve the direction-of-arrival resolution.

  On the other hand, the spherical lens of the present invention can be applied to all directions of arrival if the optimum design is performed on the cross section passing through the center of the sphere, and therefore the focal point can be made smaller than that of the compound lens. Therefore, it can be made smaller than the compound lens.

  The basic shape and the effect of the acoustic lens in the present invention have been described above. Hereinafter, specific examples of the acoustic lens shape, configuration examples, design methods, and embodiments thereof will be mainly described.

  First, the basic design concept of the spherical lens will be described.

Sound refraction follows Snell's law. Snell's law can be expressed as [Equation 1] where the sound velocity of a medium A is c _A , the sound velocity of a medium B is c _B , and the incident and refraction angles from A to B are θ _A and θ _A , respectively. .

  In a general aspherical acoustic lens, since a single material such as acrylic is used as a lens material, it is necessary to change the incident angle in [Equation 1] in order to refract a sound wave. This corresponds to changing the shape of the lens. In the design, the lens shape is determined so that the principle of constant sound path length and Abbe's sine condition are satisfied with respect to the sound ray incident on the lens surface.

  On the other hand, in the spherical lens which is one of the present invention, since the lens shape is already determined as “sphere”, the sound speed needs to be changed in [Equation 1] in order to refract the sound wave. In order to change the sound speed, it is necessary to make a spherical lens into a layer structure using a plurality of materials having different sound speeds, and to create a sound speed distribution in the lens. Since the material is finite, that is, the sound velocity value is finite, the design freedom is not high considering the design only by changing the sound velocity value, but if the layer thickness is changed, the incident angle of the sound wave incident on the layer also changes, so the sound velocity value Design should be considered both in terms of changes and layer thickness changes.

  FIG. 3 shows a configuration of a spherical lens having a three-layer structure and a basic design conceptual diagram as an example. In the example, the acoustic lens 300 is composed of three types of media having different sound speeds, and these sound speeds are different from the sound speed of the surrounding medium of the acoustic lens 300. The graph below the acoustic lens 300 in FIG. 3 shows the sound velocity distribution of the acoustic lens 300, the vertical axis represents the sound velocity 301 of the medium, and the horizontal axis represents the distance 302 from the lens center.

  The plane wave 303 coming from a certain direction undergoes a refraction phenomenon at the interface between the acoustic lens 300 and the surrounding medium. An arrow in the acoustic lens 300 in FIG. 3 represents one of the sound wave propagation paths 304. In refraction due to the difference in sound speed, the refraction is refracted in the direction where the refraction angle is smaller than the incident angle at the boundary surface where the sound speed is slow, and the refraction is refracted in the direction where the refraction angle is larger than the incident angle.

  A sound wave that is focused while being refracted repeatedly at the boundary between the media is received by the wave receiving element array 305 that is two-dimensionally arranged along the lens shape. If the plane wave 303 arriving from a certain direction is designed to be focused on only one receiving element 306 on the extension line of the arrival direction 307 by the acoustic lens 300, the arrival direction 307 of the plane wave 300 can be known. Thus, if the sound velocity distribution can be designed so that each sound wave arrival direction and each receiving element have a one-to-one correspondence, two-dimensional beam forming can be performed before and after passing through the acoustic lens 300.

  The basic design concept of the spherical lens has been described above. Next, a specific sound speed distribution of the spherical lens will be described.

  First, in order to clarify the characteristics of the acoustic lens in the present invention, a Luneberg lens will be described as a comparison. A Luneberg lens is known in the microwave antenna field as a lens that can separate an incoming wave for each direction of arrival, regardless of whether it is vertical or horizontal. The Luneberg lens has a spherical shape, the refractive index is maximum at the center of the lens, and is designed so that the refractive index continuously decreases from the center of the lens toward the outside. If the radius of the lens is R, and the distance from the center of the lens is r, the refractive index distribution is represented by n [Equation 2].

When the refractive index distribution follows [Equation 2], the plane wave incident on this lens forms a focal point on the spherical surface opposite to the incident.

  It is not easy to make such a Luneberg lens as a lens for acoustic imaging. First, since it is difficult to manufacture a lens whose refractive index changes continuously, a plurality of homogeneous layer lenses whose refractive index changes stepwise are overlapped and approximated. However, unless the condition that there are a plurality of media having sound speeds corresponding to the refractive index distribution of [Equation 2], the difference in acoustic impedance of these media is small, and the absorption attenuation by each medium is small is not satisfied. Don't be. FIG. 4 shows the result of simulation of sound wave propagation using [Equation 1] for the homogeneous layer Luneberg lens 400 obtained by dividing the refractive index distribution of [Equation 2] into 100. Looking at the focusing region 402, it can be seen that the plane wave 401 incident on the homogeneous layer Luneberg lens 400 is gathered on the surface opposite to the incident side, but at the same time it is not completely focused. The smaller the focal diameter, the better the direction-of-arrival resolution, that is, the resolution of image display. However, the 100-segment homogeneous Luneberg lens 400 as shown in FIG. 4 has a large focal diameter and does not satisfy the resolution performance for imaging.

  The acoustic lens in the present invention is the same as the Luneberg lens in that it has a spherical shape, but the refractive index distribution does not follow [Equation 2].

  FIG. 5 is a view showing one of the most preferred embodiments of the acoustic lens in the present invention. The spherical acoustic lens shown in FIG. 5 has a two-layer structure, but it may have two or more layers. Since the refractive index at the center of the Luneberg lens is 1 / √2 times that of the lens surrounding medium, the sound velocity of the acoustic lens central medium 500 in the present invention is 1 / √2 times that of the lens surrounding medium. It is desirable to be slower. For example, when the lens surrounding medium is water and the sound speed is 1500 m / sec, the speed of the central medium 500 is desirably 1060 m / sec or less. The sound speed of the intermediate medium 501 may be lower than that of the lens surrounding medium and higher than that of the central medium 500, and the thickness of the intermediate medium 501 may be determined so that a plane wave incident on the lens forms a focal point.

  In the case of a spherical acoustic lens having a two-layer structure as shown in FIG. 5A, the propagation path of a plane wave incident on the lens can be classified into three. A propagation path 502 that does not pass through the central medium 500, a propagation path 503 that forms a focal point through the central medium 500, and a propagation path 504 that passes through the central medium 500 but does not contribute to the formation of the focal point. Among these, the propagation path 504 that passes through the central medium 500 but does not contribute to the formation of the focal point is more refracted closer to the end of the central medium 500 with respect to the sound wave traveling direction, and therefore greatly varies when reaching the receiving surface. . In the propagation path 503 that forms a focal point through the central medium 500, a refraction phenomenon occurs near the front of the central medium 500 with respect to the sound wave traveling direction, so that the difference in refraction between them is small and gathers at substantially the same place on the receiving surface. For this reason, the sound pressure at the receiving surface of the propagation path 504 that passes through the central medium 500 but does not contribute to the formation of the focal point is so small that it can be ignored compared to the propagation path 503 that forms the focal point through the central medium 500. However, the propagation path 502 that does not pass through the central medium 500 forms a focal point different from the propagation path 503 that forms the focal point through the central medium 500 on the reception surface, and causes a false image.

  Therefore, as shown in FIG. 5B, by disposing the sound wave reflector or absorber 505 on a part of the lens incident surface, it is possible to exclude sound waves that are not focused on the extension line in the plane wave incident direction. The excluded sound wave may be a part or all of the propagation path 502 that does not pass through the central medium 500 and the propagation path 504 that passes through the central medium 500 but does not contribute to the formation of a focal point. At this time, if there is no sound wave reflector or absorber 505 on the propagation path 503 that forms a focal point through the central medium 500, the symmetry of the propagation path is not lost no matter which direction the sound wave arrives. The angle range of the double arrow as shown in FIG. 5C is the viewing angle 506 of the imaging sonar using this lens.

  FIG. 6 is a view showing one of the most preferred embodiments of the acoustic lens in the present invention. The spherical acoustic lens shown in FIG. 6 has a two-layer structure, but may have two or more layers. In the present invention, the sound speed of the central medium 600 of the acoustic lens is slower than the sound speed of the lens surrounding medium, and the sound speed of the outermost shell medium 601 is preferably higher than that of the lens surrounding medium.

  When the sound velocity of the outermost shell medium 601 of the acoustic lens as shown in FIG. 6A is faster than the sound velocity of the lens surrounding medium, the traveling direction of the sound wave becomes a diffusion direction due to the refraction phenomenon due to the convex shape of the surface of the outermost shell medium 601. Since it travels, the propagation path of the plane wave incident on the lens can be classified into four. Propagation path 602 in which the total reflection phenomenon occurs on the outermost shell medium surface, propagation path 603 that does not pass through the central medium 600, propagation path 604 that forms a focal point through the central medium 600, and passes through the central medium 600 but contributes to the formation of the focal point This is a propagation path 605 that does not. Among these, the propagation path 605 that passes through the central medium 600 but does not contribute to the formation of the focal point is more refracted as it is closer to the end of the central medium 600 with respect to the sound wave traveling direction, and therefore greatly varies when it reaches the receiving surface. . In the propagation path 604 that forms a focal point through the central medium 600, a refraction phenomenon occurs near the front of the central medium 600 with respect to the traveling direction of the sound wave. For this reason, the sound pressure at the receiving surface of the propagation path 605 that passes through the central medium 600 but does not contribute to the formation of the focal point is so small that it can be ignored compared to the propagation path 604 that forms the focal point through the central medium 600.

  Further, in an acoustic lens having a structure in which the sound velocity of the outermost shell medium 601 is faster than the sound velocity of the lens surrounding medium, a false image is not provided without providing a sound wave reflector or absorber as shown in FIG. Can be excluded.

  If the wave receiver 606 does not exist on the propagation path 604 that forms a focal point through the central medium 600, the symmetry of the propagation path is not lost regardless of the direction from which the sound wave arrives. The angle range of the double arrow as shown in (2) is the viewing angle 607 of the imaging sonar using this lens.

  Alternatively, for example, when the outermost shell is made by uniting hemispherical shells, an adhesive surface 608 is generated, so that the adhesive surface is formed on a propagation path 604 that forms a focal point through the central medium 600 as shown in FIG. The angle range where 608 does not exist is the viewing angle 607 of the imaging sonar using this lens.

  FIG. 7 is a view showing one of the most preferred embodiments of the acoustic lens in the present invention. The acoustic lens shown in FIG. 7 has a two-layer structure, but it may have two or more layers. As shown in FIG. 7, the outermost shell medium of the acoustic lens may be different between the sound wave incident surface 700 and the sound wave receiving surface 701 as long as they share the same central axis. Even if the two media are different, the symmetry of the sound wave propagation path is not lost.

  As described with reference to FIG. 6, if the sound speed of the sound wave incident surface 700 of the outermost shell of the acoustic lens is higher than that of the lens surrounding medium, the sound wave incident surface 700 of the outermost shell functions as a diffuser, and a false image. Can be excluded. However, in a medium with a high sound speed, the wavelength becomes long and diffraction is likely to occur, so that the spread of the focus on the sound wave receiving surface 701 increases.

  Therefore, by selecting a material whose sound velocity is slower than that of the sound wave incident surface 700 as the medium of the sound wave receiving surface 701, it is possible to reduce the focal spread due to diffraction and improve the spatial resolution during imaging.

  Further, by selecting a material having an acoustic impedance close to that of the piezoelectric element as the medium of the sound wave receiving surface 701, reflection at the boundary between the sound wave receiving surface 701 and the receiver can be suppressed, and sensitivity can be improved. Can do.

  Further, as shown in FIG. 7B, the sound wave propagation surface 700 and the sound wave reception surface 701 of the outermost shell of the acoustic lens are different in the medium, and the symmetry of the sound wave propagation path is maintained even if they are not hemispherical shells. It does n’t matter.

  FIG. 8 is a diagram showing one of the most preferred embodiments of the acoustic lens in the present invention. The acoustic lens shown in FIG. 8 has a two-layer structure, but it may have two or more layers. As shown in FIG. 8B, as long as the same central axis is shared, the curvature on the sound wave incident surface 800 side and the curvature on the sound wave reception surface 801 side may be different in the outermost shell of the acoustic lens. . Even if both have different curvatures, the symmetry of the sound wave propagation path is not lost.

  In FIG. 8A, if the radius of the outermost shell of the acoustic lens is R, the distance between adjacent wave receiving elements 802 is L, and the distance from the sound wave incident surface 800 of the acoustic lens to the object 803 is r. The distance between two points on the extension line of the wave element 802 and the same distance from the acoustic lens can be expressed by [Equation 3].

  In FIG. 8B, the radius of the outermost shell on the sound wave incident surface 801 side of the acoustic lens is R, the radius of the outermost shell on the sound wave receiving surface 801 side is R ′ (> R), and adjacent wave receiving elements. If the distance between 802 is L and the distance from the sound wave incident surface 800 of the acoustic lens to the object 803 is r, the distance between two points on the extension line of the wave receiving element 802 and on the same distance from the acoustic lens is [several 4].

  Here, θ ′ <θ and δ ′ <δ from R ′> R. That is, when the radius of the sound wave receiving surface 801 is larger than the radius of the sound wave incident surface 800 of the outermost shell, there is an effect of improving the spatial resolution.

  At this time, the sound wave incident surface 800 and the sound wave reception surface 801 may or may not have a hemispherical shell shape. For example, as shown in FIG. 8C, the symmetry of the sound wave propagation path is maintained even if a part of the sound wave receiving surface 801 is cut. That is, the acoustic lens may be cut in any way as long as the symmetry of the sound wave propagation path is maintained.

  FIG. 9 is a view showing one of the most preferred embodiments of the acoustic lens in the present invention. Although the acoustic lens shown in FIG. 9 has a two-layer structure, it may have two or more layers. As shown in FIG. 9, the central layer medium 900 of the acoustic lens is preferably a liquid. By making the central layer medium 900 liquid, there is an advantage that the central layer medium 900 does not have to be processed. For example, in the case of the shape as shown in FIG. 9A, if the central layer medium 900 is an individual, it is necessary to perform spherical processing. Similarly, in FIGS. 9B and 9C, if the central layer medium 900 is an individual, it is necessary to perform processing along the shape of the outermost shell. On the other hand, if the central layer medium 900 is a liquid, the innermost layer medium 900 automatically reaches the inside regardless of the shape of the outermost shell.

  Further, when the central layer medium 900 is a liquid, there is an advantage that exchange is easy. An imaging sonar using an acoustic lens may be operated in a place with different environments such as season, region, and depth. When the water temperature change with respect to the environmental change is large, it is considered that the sound collection characteristic change of the acoustic lens becomes large. At this time, by selecting the center layer medium 900 having a sound speed suitable for the environment, it is possible to minimize the change in the sound collection characteristic with respect to the environmental change. For example, since silicone oil has a sound speed of 870 m / sec to 1000 m / sec due to a difference in kinematic viscosity, if several types of silicone oil having different kinematic viscosities are prepared in advance, it can cope with many environments.

  In addition, the temperature of the liquid can be controlled to a temperature suitable for the surrounding environment by installing a device such as a thermostat in the central layer medium 900 that is not on the propagation path that forms the focal point.

  FIG. 10 is a view showing one of the most preferred embodiments of the acoustic lens in the present invention. FIG. 10 shows a structure in which the liquid medium 1002 is filled between the acoustic lens 1000, the wave receiver array 1001, and the sealed medium 1005 in FIG. 6B. Not limited to this example, the acoustic lens 1000 is configured such that two or more media having a constant curvature surface have the same central axis, and on the constant curvature curved surface 1003 having the same central axis as the acoustic lens 1000. As long as the receiver array 1002 is installed and the liquid medium 1002 is filled between the acoustic lens 1000 and the receiver array 1002, any configuration may be used.

  As described above, when the space between the acoustic lens 1000 and the receiver array 1001 is filled with the liquid medium 1002, the plane wave 1004 that has passed through the acoustic lens 1000 is efficiently sent to the receiving elements on the receiver array 1001. Can do. If the acoustic lens 1000 and the receiver array 1001 are in contact with each other, if air or the like is mixed between the two due to poor contact, the plane wave may be reflected by the air layer and the sensitivity may deteriorate. . However, this possibility disappears if the space between the two is filled with the liquid medium 1002.

  In addition, by selecting a material with a very slow sound speed (about 700 m / sec) as the liquid medium 1002 as a liquid such as a fluorine-based inert liquid, it is possible to reduce the spread of the focal point due to diffraction. In this case, the spatial resolution can be improved.

DESCRIPTION OF SYMBOLS 100 Transmitter 101 Receiver 102 Acoustic lens 103 Amplifier 104 A / D converter 105 Memory part 106 Operation processing part 107 Operation panel 108 Waveform generator 109 Amplifier 110 Image display part 200 Transmitter 201 Pulse wave 300 Acoustic lens 301 Sound velocity of medium 302 Distance from lens center 303 Plane wave 304 Sound wave propagation path 305 Receiver element array 306 Receiver element 307 Arrival direction 400 Homogeneous layer Luneberg lens 401 Plane wave 402 Focal region 500 Central medium 501 Intermediate medium 502 Does not pass through central medium Propagation path 503 Propagation path that forms a focal point through the central medium 504 Propagation path that passes through the central medium but does not contribute to the formation of the focal point 505 Acoustic reflector or absorber 506 Viewing angle 600 Central medium 601 Outer shell medium 602 Outer shell medium All on the surface Propagation path where reflection phenomenon occurs 603 Propagation path that does not pass through the central medium 604 Propagation path that forms the focal point through the central medium 605 Propagation path that passes through the central medium but does not contribute to formation of the focal point 606 Receiver 607 Viewing angle 608 Adhesive surface 700 Sound wave incident surface 701 Sound wave receiving surface 800 Sound wave incident surface 801 Sound wave receiving surface 802 Wave receiving element 803 Object 900 Center layer medium 1000 Acoustic lens 1001 Wave receiver array 1002 Liquid medium 1003 Curved constant curved surface 1004 Plane wave 1005 Sealed medium

Claims (10)

A transmission unit that transmits ultrasonic waves toward an underwater object;
An incident surface on which an ultrasonic reflected wave from the object is incident; and a receiving surface on which the incident reflected wave is converged; and the sound wave incident surface and the sound wave receiving surface have the same central axis and are respectively curved. Is an acoustic lens composed of a medium having different sound speeds and having at least two layers,
A receiver for receiving a reflected wave passing through the acoustic lens;
A signal processing unit that performs signal processing on the reflected wave received by the receiver;
An underwater video acquisition apparatus comprising: a display unit configured to display an audio video based on a signal processing result obtained by processing the signal by the signal processing unit.   The underwater image acquisition device according to claim 1, wherein the acoustic lens has a reflector or an absorber on a part of the incident surface.   The underwater image acquisition device according to claim 1, wherein the acoustic lens has a diffuser inside the lens and excludes sound waves that are not focused on an extension line in an incident direction.   The underwater image acquisition device according to any one of claims 1 to 3, wherein the acoustic lens is a concentric sphere having two or more layers.   The underwater image acquisition device according to any one of claims 1 to 3, wherein the acoustic lens has two or more layers in which the outermost shell material is different between the sound wave incident surface and the sound wave receiving surface, and the inner shell material is spherically symmetric. An underwater image acquisition device, characterized by being a sphere. The underwater video acquisition device according to any one of claims 1 to 3, wherein the acoustic lens is
An underwater image acquisition device comprising two or more media having the same central axis and a curved surface with a constant curvature. The underwater video acquisition device according to any one of claims 1 to 3, wherein the acoustic lens is
An underwater image acquisition device, characterized in that it is a concentric cylinder having two or more layers.   The underwater image acquisition device according to any one of claims 1 to 7, wherein a medium of a central layer of the acoustic lens is a liquid.   The underwater image acquisition apparatus according to claim 8, wherein the acoustic lens has a function of maintaining a liquid temperature at a constant temperature. 2. The underwater image acquisition device according to claim 1, wherein a space between the acoustic lens and the receiver is filled with a liquid.