This invention was made without government funding.
None.
The present invention relates to underwater acoustic transducers and in particular to acoustic sources producing spiral wavefront for underwater navigation to determine bearing angle and for communication.
Underwater acoustic transducers are used in communications and to aid in determining the position and navigation of submerged objects. One such method to aid in navigation is to transmit a spiral wavefront consisting of a signal having a magnitude that is nominally constant but whose phase varies linearly as a function of azimuthal angle in a defined plane. Such a spiral wavefront signal can be compared with a reference signal of constant phase to determine the bearing angle. A beacon carrying such a transducer producing a spiral wavefront may be employed to transmit signals that can be detected by multiple objects or vehicles, thereby providing a cost effective navigation aid to determine bearing angle to the beacon. The challenge is to realize and effective transducer to accomplish this goal.
It is known to those skilled in the art, that one way to create a spiral wavefront is to employ a plurality of transducers arranged around in a cylindrical pattern around a rigid cylinder backing wherein each element is driven with an incremental phase bias that is retarded with respect a neighboring element in order to produce a spiral wavefront. It is also known to those skilled in the art, that a spiral wavefront transducer may be realized by employing a transducer or array of transducer elements arranged in a cylindrical-spiral pattern with each section or segment having an incremental radial offset with respect to its neighbor in order to create a spatial phase delay in the wavefront when driven by a common signal. This approach has a discontinuity when one full revolution is reached. These approaches are discussed in U.S. Pat. No. 7,406,001 by Dzikowicz and in the publication [Ref. Hefner and Dzikowicz J. Acoust. Soc. of Am.], in which a navigation method is proposed based on an underwater acoustic beacon comprising a transducer for producing a spiral wavefront signal and a transducer for producing a reference signal of constant phase aligned along a common central axis.
The subject invention relates to at least one electroacoustic transducer for producing a spiral wavefront having a phase that is a function of the azimuthal angle in the plane perpendicular to its axis of symmetry. In the preferred embodiment, the spiral wavefront transducer is comprised of at least one acoustic transducer that produces two spatially orthogonal acoustic dipoles each having a figure-of-eight directional response in a common plane that are electrically driven in phase quadrature, that is with a temporal phase bias of π/2 radians. Several variants are described that accomplish this objective.
In one embodiment, a spiral wavefront transducer is realized using a pair of electroacoustic transducers to form an acoustic dipole or doublet and a second pair of transducers to form a second acoustic dipole, where the main response axis of the first dipole element is arranged to be orthogonal to the main axis of the second dipole, and where each acoustic dipole is driven with a temporal phase bias of π/2 radians (90 degrees) or a suitable equivalent time delay. Methods of introducing the phase bias are well known to those skilled in the art. In this variant of the invention, the individual transducers may be comprised of cylinders, spheres, bars, or any suitable transduction element with any suitable transduction material.
In the preferred embodiment, the electroacoustic transducer is comprised of at least one hollow cylindrical piezoelectric transduction element for producing two orthogonal acoustic dipoles which are driven separately and phase biased in quadrature. Said elements are also known as piezoelectric cylinders, tubes, or rings. The at least one transducer can be comprised of piezoceramic elements that have inner and outer electrodes surfaces and may be radially polarized, or utilize narrow electrode stripes and be tangentially polarized on its inner and/or outer surfaces, or utilize a segmented cylinder comprised of piezoelectric wedges and/or bars with or without passive non-piezoelectric elements and glued to form a cylindrical piezoelectric element wherein said segmented cylindrical piezoelectric element is either circumferentially polarized or radially polarized. Further the transducer can be comprised of any suitable piezoceramic or piezocrystal material. Alternatively the transducer may be realized with any suitable magnetostrictive or electrostrictive material.
A single cylindrical transducer element may be utilized to produce both acoustics orthogonal dipoles and the reference signal. Alternatively a separate coaxially-aligned cylindrical element(s) may be used to produce either acoustic dipole or reference signal wherein the use of separate elements to produce the spiral wavefront and constant phase wavefront reference signal can have certain merits including the same resonance frequency and simplification in system design.
The spiral wavefront transducer can be realized by utilizing a radially polarized hollow piezoelectric cylinder having inner and outer electrodes, the electrodes on the inner and/or outer surface being divided in four nominally equal-sized parts, thereby presenting a means to excite opposite sections of the element with electrical signals, where said signals are phase biased in quadrature, that is they differ in phase by nominally π/2 radians or equivalently 90 degrees. Each opposing pair of electrodes is driven in anti-phase (opposite polarity) so as to create spatially orthogonal acoustic dipoles, that is acoustic radiation patterns having a spatial dependence that may be described as a figure-eight pattern and that are perpendicular to each other. The largest acoustic output will occur at a frequency of excitation coinciding with the resonance of the first mode of vibration of said cylindrical element although the radiation pattern remains sufficiently independent of frequency for a large range of frequency from below to above this resonance. Thus the spiral wavefront beacon will operate over a very broad frequency range. The resulting acoustical radiation achieved is characteristic of an ideal dipole and may be defined by the trigonometric functions cosine (θ) and sine (θ), that is they present a pair of figure-eight patterns that are spatially orthogonal in the plane perpendicular to the axis of symmetry. The superposition of the pair of spatially orthogonal dipoles that are in time-phase quadrature produce a spiral wavefront. The signals may originate from one electrical source and be phase biased by widely known methods to those skilled in the art, or from two separates sources that are phase biased in quadrature. Multiple cylindrical elements may be coaxially aligned to increase signal strength or used to extend the aperture (height) of the transducer to realize a narrower radiation beamwidth. It follows to those skilled in the art that side stripe-electroded cylinders that are tangentially polarized may be substituted for radially polarized elements, said elements having merits of higher effective electromechanical coupling. Similarly segmented piezoelectric cylinders comprised of bar-like wedges to achieve circumferential or radial polarization may be utilized. It also follows that separate cylindrical elements may be used for each acoustic dipole. It also follows that the division of electrodes may be designed to be nominally 180 degrees, 90 degrees, or 60 degrees or in general any angle less than 180 degrees. It also follows that the method described herewith may be extended to a spherical transduction elements or an open-spherical transduction element. It also follows that a spiral wavefront transducer may be realized with two or more acoustical dipoles with prescribed symmetric spatial and temporal phase bias. For example three dipoles each phase modulated by π/3 radians will produce a spiral wavefront.
In another embodiment, two omnidirectional reference sources are used, one positioned equally above and one below the source producing the spiral wavefront, to enable the estimation of the vertical bearing angle of an incoming signal by measuring the phase difference. Said two omnidirectional reference sources can also improve the horizontal bearing angle estimation as the summation of the pair will have an acoustic center collocated with the source producing the spiral wavefront. in this embodiment a preferred burst sequence of acoustic pulses would be: omni-reference 1, a time delay, omni-reference 2, a time delay, and spiral wavefront signal. The phase difference between omni-reference 1 and omni-reference 2 signals can be processed to yield a vertical (depression) angle. Further, for a spiral source positioned between the two omni-reference sources, the horizontal bearing estimation derived from phase measurements can take into account the phase due to the vertical offset from the horizontal plane to improve bearing angle estimation accuracy.
The hollow cylindrical transducers may be air-backed, fluid-filled, or polyurethane-filled to achieve different levels of depth survivability. Further, according to an embodiment of the present invention, the resulting transducer may also be encapsulated and have means for its connection through a suitable base structure for attachment to a suitable enclosure containing necessary electronics for processing signals to determine bearing angles.
According to an aspect of the present invention, a cylindrical transducer used in connection with the spiral wavefront transducer in either the omnidirectional reference transmit mode or bidirectional dipolar transmit mode may also be used as a receiver to detect signals or commands or bearing angle or range by time of flight or other methods known to those skilled in the state of the art.
According to another aspect of the present invention, radially polarized cylindrical piezoelectric elements having a height to diameter aspect ratio less than unity may be utilized to increase the effective electromechanical coupling coefficient and useable power factor bandwidth when producing circumferential vibrations. Alternatively radially polarized cylindrical piezoelectric elements having a height to diameter aspect ratio greater than about unity may be utilized to increase the effective electromechanical coupling coefficient and useable power factor bandwidth when vibrating at higher frequency upper-branches inducing axial and circumferential vibrations. In this variant, the omnidirectional reference signal can be produced at or near the vicinity of the frequency of the electromechanical resonance mode corresponding to the first axial resonance or “upper-branch” of the cylindrical transduction element and in a preferred embodiment the resonance frequency of this upper-branch mode is nominally the same as the frequency of the resonance of the acoustic dipole modes of the spiral wavefront on a separate transducer. This variant has the advantage that the frequency response, and in particular the phase response, will be more closely matched over a wider frequency range.
Another object of the preferred embodiment of the invention is to substantially mechanically isolate the ends of the hollow cylindrical piezoelectric elements from their cap and base, or from each other when multiple elements are utilized, while maintaining an air backed cavity in order to improve the vibration response of said cylindrical elements. In the preferred embodiment the transducer element is air backed, said elements having a base and a cap that are mechanically detached from the piezoelectric cylinder by means of a compliant spacer.
Still another aspect of the invention is realized by including an internal cylindrical supporting structure connecting the cap and the base of the transducer in order to increase the operational depth capabilities of the device and to reduce axial loading on the piezoelectric elements thereby maintaining the ability of the distal ends of the cylindrical elements to freely vibrate.
According to another aspect of the present invention, a method of electrical connection is included to allow individual elements or sections of electrodes of said cylindrical elements to be excited separately or simultaneously to produce desirable modes of vibration and corresponding acoustic radiation patterns.
According to another aspect of the present invention, individual elements may be selectively excited in the fundamental lowest order (zero) mode of extensional vibration and/or the next lowest order (first) mode of extensional vibration.
According to another aspect of the present invention, the spiral wavefront transducer may consist of thin walled hollow piezoelectric cylindrical or spherical elements, wired separately or together in parallel or in series, and encapsulated or molded or booted as a single structure and made electrically insulated from the fluid of immersion.
According to another aspect of the present invention, the spiral wavefront transducer may be attached to a mobile submersible vehicle, a platform, mooring, buoy, or floatation device.
According to another aspect of the present invention, the cylindrical transducer has an intermediate electrical mounting element to provide a means for joining the electrode of the piezoelectric elements) to the electrical wires carrying signals for excitation, wherein the electrical mounting element is mechanically isolated from the piezoelectric cylinders but within the transducer housing, encapsulation, molding or booting.
According to another aspect of the present invention, individual thin-walled hollow cylindrical piezoelectric elements may be made sufficiently thin such that the ratio of the thickness to radius is less than 0.15 to increase acoustic bandwidth while permitting useable operational depth in a submersed fluid.
According to another aspect of the present invention, the broadband transducer may be operated in transmit, receive or in duplex (both) modes of operation.
According to another aspect of the invention, the transducer is comprised of individual cylindrical elements that permit the interior of the hollow cylindrical transduction elements to be used for housing accompanying electrical elements such as but not limited to inductive tuning elements.
Further features, advantages and details of the present invention will be appreciated by those of ordinary skill in the art from a review of the figures and a careful reading of the detailed description of the preferred embodiments that follow, such description being merely illustrative of the present invention.
The present invention now will be described more fully hereinafter with reference to the accompanying drawings and mathematics to fully convey the scope of the invention to those skilled in the art.
The proposed transducers for generating spiral wavefront transducer may be further understood with the aid of a little mathematics. Consider the acoustic field represented by two acoustic dipoles denoted as i=1,2 having pressure amplitude Pi, harmonic frequency fo, field observation location defined by a radial distance r from the acoustic center of the source and an azimuthal angle θ defined relative to a reference angle, said angle residing in a plane perpendicular to the axis of symmetry of the transducer(s). Further consider that the response of one dipole is biased in temporal phase by φ radians, as may be synthesized electronically or introduced by a retarded time, where in the preferred embodiment consisting of two acoustic dipoles said phase is φ=π/2 radians relative to the excitation frequency and resulting acoustic frequency as the transduction elements are linear in response. Thus the superposition of such signals in the submerged medium results in an acoustic signal described by
p=P1 cos θ[ej2πft]+P2 sin θ[ej(2πft+φ)] (1)
where the use of complex notation has been adopted for the time dependence and under the conditions that the pressure amplitudes are equal P1=P2=P=A/√r, A being an arbitrary constant dependent on drive level and r being the range in the horizontal plane, the phase bias in quadrature φ=π/2, and noting relations j=√{square root over (−1)} and ej(π/2)=j, we arrive at
p=Pej2πft[cos θ+j sin θ]=Pej2πftejθ=Pej(2πft+θ), (2)
which is the expression of a traveling wave with a spiral wavefront having phase linearly dependant on azimuthal angle. Taking the real part we arrive at
p=P cos(2πft+θ) (3)
The magnitude of the spiral wavefront is independent of azimuthal angle as shown in
An illustration of the spiral wavefront and constant phase wavefront reference ar shown in
There are several variants of the present invention and the preferred embodiments are based on the use of hollow cylindrical piezoelectric elements.
There are several other variants of a single piezoelectric cylindrical element that will realize two spatial orthogonal dipoles and the resulting spiral wavefront transducer. Alternatively the outer electrode surface may be left undivided and connected as common (ground) and the two inner electrodes 8-4 and 2-6 may be used to excite corresponding dipoles. Still alternatively the inner electrode surface may be continuous or electrode parts may be connected in common and the corresponding opposite outer pairs of electrodes may be energized to excite orthogonal dipoles. Still another variant may be realized utilizing a radially polarized element having alternating quadrant polarization, for example where quadrant I and III are radially polarized in one direction (e.g. outward) and quadrants H and IV are radially polarized in the opposite direction (e.g. inward). In this variant a uniform radial electric field will induce acoustic dipoles.
In another variant one piezoelectric cylinder is used to create one acoustic dipole by suitable division of the electrodes in suitable sectors (180 degrees or less) and a second piezoelectric cylinder is used to create a second acoustic dipole with similarly divided electrodes. In yet another variant, multiple similar cylinders may be aligned axially and wired in parallel to increase signal levels and to narrow the vertical beamwidth of the resulting radiation. In still another variant one cylinder may have its electrodes span approximately 120 degrees of circumferential coverage with symmetric separations between electrodes of approximately 60 degrees, such a design having certain advantages in the effective electromechanical coupling and frequency response of the cylinders, resulting in broader acoustic bandwidth of the device.
In another variant the piezoelectric cylinders are realized with tangentially polarized elements by using stripe-electrodes arranged vertically on the inner and outer surfaces of the piezoelectric element. A selective grouping of said electrodes can be made to excite sections of the piezoelectric cylinder in opposite polarity and consequently produce the acoustic dipole or dipoles. The benefit of using such a stripe-electroded tangentially polarized design is an increase in the effective electromechanical coupling factor and useable bandwidth over that of the radially polarized cylindrical piezoelectric element with the tradeoff of additional cost and increased electrode separation and hence higher voltage requirement.
In yet another variant the piezoelectric cylinders are realized with circumferentially polarized elements, which is typically accomplished by employing bar-wedge staves glued together circumferentially and electroded on their width or through the thickness to excite piezoelectric activity, and with the selective division of electrodes, said cylinder can be made to excite an acoustic dipole or pair of dipoles. The benefit of using such a segmented design is further increases in the effective electrical mechanical coupling factor and bandwidth.
An advantage of using cylindrical piezoelectric elements to create the acoustic dipoles includes the additional source level by operating at a natural resonance frequency of the transducer. To illustrate the benefits of operating at or near resonance in the preferred embodiment, the frequency response of a representative cylindrical transduction element is shown in
Another advantage of using cylindrical piezoelectric elements to create the orthogonal acoustic dipoles is that they are inherently aligned sharing the same acoustic center and axis of symmetry, and the radiation surface is inherently cylindrical free of any discontinuities and well suited for creating a cylindrical wavefront.
A prototype transducer was fabricated using a radially polarized piezoelectric cylinder with inner and outer electrodes divided in four quadrants and opposed pairs of electrodes connected to form orthogonal dipoles that were driven by two signals from two function generators that were maintained in phase quadrature according to
The illustration of
The
The method of excitation of a spiral wavefront using orthogonal quadrature phase biased dipoles generated from a cylindrical piezoelectric transducer enables an improved underwater acoustic communications transducer with greater bandwidth. It is widely known that a cylindrical transducer can be excited in multiple modes of vibration with the excitation of the lowest zero-order resonant mode of extensional vibration being the most common. The cylindrical transducer is most widely used in transmit mode at frequencies in the vicinity of this extensional resonance. The useable bandwidth may be further extended by excitation of orthogonal and quadrature phase biased acoustic dipole modes to create a spiral wavefront arising from the superposition of extensional resonances corresponding to the first-mode of vibration. Whereas the excitation of one dipole produces a bidirectional ‘figure-eight” response, the excitation of two orthogonal dipoles with the quadrature phase bias produces an omnidirectional response in magnitude thereby substantially increasing the useable acoustic bandwidth of the device as two resonant modes are exploited. The bandwidth of the transducer can be further increased by operation at or in the vicinity of a third electromechanical resonance mode corresponding to the first axial resonance “upper-branch” of the cylindrical transduction element, the dependence of the resonance frequency on height-to-diameter aspect ratio known to those skilled in the art and for the limiting case of a very short cylinder (or ring) occurs at a nominal frequency equal to the ratio of the speed of sound of the piezoelectric material to twice the cylinder height. The calculation of the actual resonance frequency is beyond the scope of this specification but also known to those skilled in the art. Under the conditions that the distal ends of cylindrical piezoelectric elements of finite height remain relatively free to vibrate, said axial vibrations are transformed into radial vibrations which in turn produce an effective omnidirectional radiation in the plane orthogonal to the axis of symmetry of the cylinder. Under these conditions is advantageous to utilize a cylinder having a height-to-diameter aspect ratio larger than about ½ so that the resonances of the extensional zero-order mode, dipole mode, and axial upper-branch modes are sufficiently spaced so as to exploit greater coverage in frequency. Thus the excitation of the three modes of vibration enables a triply resonant cylindrical transducer with omnidirectional radiation characteristics in at least one plane.
A spiral wavefront can be generated by a transducer using more than two symmetrically spaced and phase biased dipoles. For example, an underwater acoustic beacon for generating a acoustic signal having a spiral acoustic wavefront can be realized with at least one electroacoustic transducer to create three spatially equally spaced acoustic dipoles producing characteristic figure-eight radiation response with angle each spaced symmetrically 120 degrees apart as illustrated in
One variant of the proposed transducer is realized using a cylindrical piezoelectric element as in
Similarly, another variant of the underwater electroacoustic transducer may be realized by utilizing at least one hollow cylindrical piezoelectric element with inner and/or outer electrode surfaces divided in at least three parts, thereby defining N sectors, each sector having electrical connections of opposite polarity for the transmission or reception of sound, where the transducer is enabled by the addition of a switch for the selective excitation or reception of any one or more combinations of adjacent or opposing sectors. In one embodiment of the transducer, the phase of signals from neighboring sectors pr combinations of sectors of the cylindrical piezoelectric element may be measured to determine the direction of an incoming sound signal. The angle of incidence may be determined by methods known to those skilled in the art as is done with pairs of hydrophones used in ultra-short baseline methods. The advantage in the present invention is that one cylindrical transducer with divided electrodes can replace multiple hydrophone units while still having its additional functionality.
It is apparent to those skilled in the art that an acoustic dipole may be realized using an acoustic doublet wherein two small omnidirectional sources are separated by less than a half wavelength and excited in anti-phase, that is 180 degrees out-of-phase. The new invention proposed the addition of a second dipole spatially orthogonal that is further phase biased by π/2 radians together with the first dipole to produce the spiral wavefront. Thus it follows that a compact array of four small (where small means smaller than the acoustic wavelength) acoustic sources that are each phase biased by 90 degrees relative to its nearest neighbor is identical to a pair of orthogonal acoustic doublets that are phase biased in quadrature. In this variant there is no centrally located cylindrical rigid body or backing material behind the transducers and the transducer elements are assumed to be small enough that diffraction effects are negligible. Also it is noted that a 180 degree phase bias is realized simply by reversing the polarity of the excitation signal by reversing the wiring polarity.
The advent of piezoelectric relaxor single crystal materials (piezocrystals for brevity) with high electromechanical coupling, high compliance and low sound speed, and high piezoelectric d-constants offers additional utility to the proposed navigation and communication transducers and methods as well as for cylindrical transducer variants for other purposes. A hollow cylindrical piezoelectric transducer can be realized with single crystal materials by cementing, gluing, or epoxying bar or wedge prisms in a cylindrical pattern wherein individual or combinations of piezocrystals can be transverse (through thickness) or longitudinal (through width) polarized, or alternatively stripe-electroded and tangentially polarized. Further the segmented cylinder or ring can include both active piezoelectric elements and passive prismatic bars or wedges, the combination affording the opportunity to tailor the diameter and resonance frequency of the cylinder and offering certain advantages by increasing the radiation loading from increasing its size. In the preferred embodiment, the passive elements are the same nominal thickness but stiffer being made from a material having a significantly higher elastic modulus. The effect on the electromechanical induced vibrations and piezoelectric energy conversion of the segmented cylinder are minimized when utilizing passive elements that are stiffer than the active piezocrystal elements. Utilizing stiffer passive elements reduces the lowering of the effective electromechanical coupling coefficient, the piezoelectric modulus or d-constant (d33 or d31), and the effective compliance of the cylinder. Utilizing stiffer passive elements increases the axial resonance frequency therein reducing deleterious effects of coupled electromechanical vibrations. For the axial vibration of mechanical elements in parallel, the stiffness of the (passive) element is dominant. For lateral vibration of mechanical elements in series, such as for circumferential deformations in the segmented cylinder, the compliance of the (active) element is dominant. Still further the segmented cylinder or ring can be comprised of active piezoelectric elements in the shape of prismatic bars with uniform rectangular cross-section having either transverse or longitudinal polarization through the width or thickness where said prismatic bars have a polarization that is oriented in prescribed relation to the crystallographic axis of the piezocrystal elements. Further, the segmented ring may have the combination of active piezoelectric bar prisms of rectangular cross-section glued to passive prisms of trapezoidal cross-section as illustrated in
Lattice planes and directions are typically described by using a Miller Index to specify specific planes, orientation and polarization of a crystal. In the cubic lattice system, the [jkl] direction defines a unit vector normal to surface of a particular plane or facet as indicated in the
The segmented cylinder or ring may be comprised of piezocrystal prisms of rectangular bar or wedge cross-section arranged for transverse piezoelectric excitation of extensional circumferential vibration of the cylinder in the so called 31-mode of operation where 3 indicates the direction of polarization as radial direction (r) and 1 indicates the direction of strain as circumferential (θ) wherein the piezocrystal prisms have a crystallographic symmetry described by [110] or its equivalents [011, etc.] in relation to the polarization. This combination produces a maximum strain in the circumferential direction of the cylinder comprised of said bars or wedges due to its excitation by the transverse piezoelectric effect when utilizing the [011] crystal symmetry and polarization direction. The descriptions of [011] crystal symmetry is well known to crystallographers and those skilled in the art. The description of transverse polarization induced vibration denoted by (31) mode is well known to those skilled in the art of transducers. An ambiguity exists in that the prescribed transverse polarization induced strain may also be denoted as (32) mode for a long thin rectangular bar and such notation may be adopted as well, but we will use the (31) notation as is conventional and commonly used for cylindrical transducers, the bars being an intermediate step for their realization.
It follows that the segmented cylinder comprised of transversely polarized (31) mode piezocrystal prismatic bar or wedge elements having [011] crystal symmetry will be arranged so that the piezocrystal elements are electroded and accessible on the inner and outer surfaces of the segmented cylinder, and further said segmented cylinder may be comprised of the active piezoelectric elements or both active (piezoelectric) and passive (non-piezoelectric) elements, wherein the combination of both active and passive elements both may have wedge prisms with trapezoidal cross-sections, or alternatively either the active or passive elements only may have wedge prisms with trapezoidal cross-sections.
It follows that the segmented cylinder may be comprised of longitudinally polarized (33) mode piezocrystal prismatic bars or wedge elements having [100] crystal symmetry or their equivalent with or without inter-dispersed passive bar or wedge elements arranged so that the piezocrystal elements are electroded on surfaces within the segmented cylinder located between neighboring elements. Further said segmented cylinder may be composed of both active (piezoelectric) and passive (non-piezoelectric) elements, wherein the active elements have rectangular cross-section and the passive elements have trapezoidal cross-sections and electrodes are attached by a suitable means as known to those skilled in the art.
Further it follows that the electrodes of the segmented cylinder comprised of transversely or longitudinally polarized piezocrystal elements with polarization in either the [110] or [100] crystal directions may be divided and grouped and energized to excite different modes of extensional vibrations including but not limited to the lowest zero-mode having uniform displacement, the first-mode having displacement described by cos(θ) which produces an acoustic dipole, their combination 1+cos(θ) which produces a cardioid pattern, orthogonal first-mode dipoles cos(θ) and sin(θ), orthogonal and quadrature phase biased orthogonal modes and their combination producing the spiral wavefront, and higher nth-order modes, several combinations of which may be excited by energizing a part of the segmented cylinder. It follows that the segmented single crystal cylinder transducer may be used in transmit or receive mode.
Further the segmented cylinder comprised of transversely or longitudinally polarized piezocrystal elements to realize a cylindrical transducer may have a part of its outside or inside surface acoustically shielded or baffled to prevent acoustic radiation or reception of sound or to induce unidirectional radiation patterns. The cylindrical conformal acoustic baffle may be comprised of a tube-like structure having an inner and outer diameter elastic structure that may be fitted or pressed over the cylindrical transducer surface, thereby permitting only part of the cylindrical transducer to be exposed to a fluid medium.
Further it follows that the segmented piezocrystal hollow cylinder may be comprised of both piezocrystal active bars or wedges and piezoceramic active bars or wedges, wherein the piezoceramic elements may be substituted for the passive elements in the previously described designs wherein it is noted that the modulus of elasticity of piezoceramic elements is much higher (often by a factor of 2 to 3 times) than piezocrystal materials such as that known as PMN-PT and PIN-PT compositions to those skilled in the art.
Further it follows that a hollow spherical shell transducer or hollow spherical shell with open holes at each polar location may be realized by employing a mosaic of piezocrystal plates polarized through their thickness in either the [100] or [110] crystal orientations or their equivalents so as to excite the shell by transverse planar piezoelectric effect. Further it follows that said piezocrystal plates may be of triangular, rectangular, trapezoidal or combinations of such shapes. Further it follows that the spherical elements will have internal and external surface electrodes and that comprising mosaic elements will be connected electrically. Still further it follows that said electrode elements may be divided in sectors, such as in hemispheres, or quadrants, octants, sectants, or at prescribed longitudinal parallels, thereby permitting the means for excitation of extensional modes of vibration of nth order or their combinations. Further it follows that the single crystal hollow spherical element may have a part of its outside or inside surface acoustically shielded or baffled to prevent acoustic radiation or reception of sound at that location or to induce unidirectional radiation patterns.
In yet another variant, it follows that a compliant conformal acoustic baffle having a tube-like structure comprised of a compliant acoustic baffle may be fitted around a cylindrical acoustic transducer to permit directional radiation or reception of sound, wherein said baffle causes a reduction of the radiation or reception of sound do to its acoustical properties. In such a variant, the conformal acoustic baffle has a cylindrical conformal opening to permit the radiation or reception of sound without restriction. In a preferred embodiment the tube-like baffle structure has an inner diameter that permits the placement around a cylindrical acoustic transducer such but not limited to those explained in this specification. Still further the acoustic baffle with tube-like structure may be removable and placed in use when directionality is needed.
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Number | Date | Country | |
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20120236689 A1 | Sep 2012 | US |
Number | Date | Country | |
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Parent | 12616254 | Nov 2009 | US |
Child | 13236321 | US |