Abstract: A multi-layer piezoelectric element having high durability of which amount of displacement is suppressed from varying even when operated continuously over a long period of time with a higher electric field under a high pressure is provided. The multi-layer piezoelectric element comprising a multi-layer structure in which a plurality of piezoelectric material layers and a plurality of metal layers are stacked alternately one on another, wherein the plurality of metal layers comprises internal electrodes and low-rigidity metal layer that has rigidity lower than those of the piezoelectric material layer and the internal electrode, wherein the low-rigidity metal layer comprises a plurality of metal parts that are separated from each other, and wherein at least one of the metal parts is bonded with only one piezoelectric material layer among the two piezoelectric material layers that adjoin in the stacking direction.

Abstract: A composite acoustic wave device (AWD) which is adapted for operation at high ambient pressures is provided. The AWD comprises two piezoelectric plates in back to back relationship, with electrodes disposed between the plates. The plates are bonded so as to neutralize the effects of external pressure. Further disclosed is a sensor utilizing the AWD and methods for utilizing such AWD for physical measurements in high pressure environments. An optional cavity formed between the piezoelectric plates offers the capability to measure the pressure and to further neutralize the residual effects of the pressure on measurement accuracy.

Abstract: An electroacoustic transducer assembly and probe for emitting and receiving acoustic radiation beams. The transducer assembly comprising an array of electroacoustic transducers composed of a plurality of individual transducer elements each one being composed of an electroacoustic element. A means for defocusing a radiation pulse emitted from the transducer element is associated with each transducer element. The defocusing means is constructed and arranged to cause the radiation pulse to generate a substantially cylindrical or spherical acoustic field.

Abstract: A device, especially a piezo stack (2) has a plurality of stacked actuator or sensor layers with electrodes (5) or piezo stack (2) contacts. A flexible lead frame (1) is electrically connected to the electrodes (5).

Abstract: The piezoelectric vibrator includes the piezoelectric bar having a plurality of piezoelectric plates alternately stacked and a plurality of vibration sectors divided vertically and horizontally with respect to the direction in which the piezoelectric plates are stacked. Electrode terminals are formed on each of surface regions of the piezoelectric plate, divided in a longitudinal direction thereof, and jump terminals corresponding to electrode terminals are formed on a surface of an adjacent one of the piezoelectric plates. On side surfaces of the piezoelectric plates, a plurality of side electrodes are formed, connecting the electrode terminals and the corresponding jump terminals to power the vibration sectors, by which a pair of the vibration sectors diagonally disposed from each other are simultaneously powered. The piezoelectric vibrator is small and easily manufactured and mass-produced with a simple structure.

Abstract: An acoustic transducer is disclosed in which a set of electrode arrays is arranged around a nominal centre point and comprising a set of circumferentially disposed electrode elements. A piezoelectric material is located between a common electrode and said electrode elements.

Abstract: A multi-layer piezoelectric element of high durability wherein the internal electrodes and the external electrodes do not break even when operated continuously over a long period of time under high electric field and high pressure is provided. The first multi-layer piezoelectric element according to the present invention comprises a stack formed by stacking piezoelectric layers and internal electrodes alternately one on another and external electrodes formed on a first side face and on a second side face of the stack, wherein one of the adjacent internal electrodes is connected to the external electrode formed on the first side face and the other internal electrode is connected to the external electrode formed on the second side face, and the external electrodes include an electrically conductive material and glass and is formed from a porous electrically conductive material that has a three-dimensional mesh structure.

Abstract: The invention relates to a piezoelectric actuator having a multi-layered structure of piezo-layers in a piezo element and inner electrodes that are arranged between the piezo-layers. The electrodes are alternatively supplied with an electric voltage of a different polarity in the direction of the layer structure of the piezoelectric element. The alternate lateral contacting of the inner electrodes is achieved via outer electrodes and/or a baked base metallic coating of the lateral surfaces. The respective outer electrodes include a bending coil which is wound from a contactable material. During baking of the base metallic coating the contactable material is applied together with at least parts of the bending coil to the coating in a conductive manner. A flexible sheet metal part that has first been provided with cut sections and/or pre-stamped sections can also be used as an outer electrode.

Abstract: A stacked piezoelectric element comprising a driving unit and a non-driving unit, and a vibration wave driving apparatus, which are capable of suppressing occurrences of deformation, particularly warping, that are generated during firing and polarization of the stacked piezoelectric element. A driving unit has a first conductive layer and a first piezoelectric layer consisting of a piezoelectric material, which is driven by an application of voltage to the first conductive layer to generate vibration on the stacked piezoelectric element. A non-driving unit has a plurality of second conductive layers and a plurality of second piezoelectric layers consisting of the piezoelectric material, which is arranged to have a thickness that enables generation of the vibration.

Abstract: A piezoelectric component with at least one fully active piezoelement has electrode layers and interposed piezoelectric layers. guided to a lateral edge of the piezoelement and contacted there. An insulating layer applied for electric contacting has an electric through-plating. An electrically conductive gas-phase deposition layer is applied directly to the electrode layer guided up to the lateral surface of the piezoelement by way of deposition from the gas phase in order to improve electric contacting. An external electrode is applied to the gas-phase deposition layer. In the case of several superposed stacked piezoelements (piezoactuator in multi-layer design), the external electrode functions as a collector electrode which connects the electrode layers to each other. The structure enables secure contacting of the electrode layers. A fully active piezoceramic multi-layer actuator with the described contacting may be used in automobile technology for activating fuel-injection valves.

Abstract: A piezoelectric-driven MEMS element includes a substrate, a beam, a fixed portion, a fixed electrode portion and a power source. The beam is provided with a lower electrode film, a lower piezoelectric film, a middle electrode film, an upper piezoelectric film and an upper electrode film. The fixed portion fixes one end of the beam onto the substrate so as to hold the beam with a gap above the substrate. The fixed electrode portion has a capacitive gap between the fixed electrode portion and the other end of the beam. In addition, at least one or two of the lower electrode film, the middle electrode film and the upper electrode film is thicker than the rest thereof.

Abstract: An optical apparatus includes a vibrated member and a piezoelectric element. The piezoelectric element vibrates the vibrated member at a predetermined vibration mode to remove a foreign substance adhered to a surface of the vibrated member. A drive electrode, a first vibration detection electrode and a second vibration detection electrode are provided on a first face of the piezoelectric element, and a ground electrode is provided on a second face of the piezoelectric element. The first vibration detection electrode and the second vibration detection electrode have an axis-symmetrical shape, and are arranged on the first face of piezoelectric element so as to be symmetrical with respect to an axis along which a predetermined vibration node occurs when the vibrated member vibrates at the predetermined vibration mode.

Abstract: A piezoelectric actuator for use in a fuel injector, the actuator comprising a stack of one or more piezoelectric elements for receipt within an accumulator chamber of the injector, distribution electrode means for generating an electric field within the stack and an electrical connector arrangement including a body member defining an external boundary and including a base portion and a stem portion projecting from the base portion. The base portion defines a base end face for abutment with an adjacent end face associated with the stack. Terminal means are provided for connection with an external power supply. The terminal means includes first and second terminal members disposed internal to the external boundary of the body member. The first and second terminal members are arranged side by side and disposed internal to the external boundary of the body member.

Abstract: A piezoelectric actuator comprises a co-fired stack of piezoelectric elements formed from a piezoelectric material and a plurality of positive internal electrodes interdigitated with a plurality of negative internal electrodes throughout the stack to define active regions of the piezoelectric material which are responsive to a voltage applied across the internal electrodes, in use. An external positive electrode connects with the positive internal electrodes and an external negative electrode connects with the negative internal electrodes. The actuator is characterised in that the stack further comprises means for deliberately creating artificial cracks within the stack at a location at which the artificial cracks do not give rise to a short circuit between the internal electrodes but serve to relieve stresses within the piezoelectric material.

Abstract: A piezoelectric element that is capable of achieving a larger amount of displacement and in which migration between electrodes hardly occurs, is included in a piezoelectric pump. The piezoelectric pump includes a first excitation electrode opposed to a second excitation electrode via a first piezoelectric layer in a central area of a layered piezoelectric body, a third excitation electrode opposed to a fourth excitation electrode via a second piezoelectric layer and a third excitation electrode opposed to a fourth excitation electrode via the second piezoelectric layer in peripheral portions of the layered piezoelectric body.

Abstract: A composition of matter having multiple layers of different conductors separated by thin layers of dielectric materials has a high piezoelectric coefficient when the conductors are metals having a significant difference in work function and the dielectric materials have a low elastic modulus when the metal layers are connected to form a capacitive circuit. Alternatively, when the conductors are semi-conductors they should have a significant difference in Fermi levels.

Abstract: A probe for an ultrasonic diagnostic apparatus includes a backing layer including backing members, a first connector bonded between the backing members and including electrodes spaced from each other in an arrangement direction, and a piezoelectric member electrically connected to the electrodes. A method of manufacturing the same is also disclosed. The piezoelectric member is connected to the first connector or to first and second connectors via an electrode layer instead of using a complicated and laborious soldering operation, thereby enabling easy connection between the piezoelectric member and the connector while preventing deterioration in performance caused by defective connection therebetween and deterioration in performance of the piezoelectric member caused by heat during manufacturing operation.

Abstract: In an actuator including at least one active electrode disposed in an electrolyte and comprising at least two webs of an electrically conductive material with a plurality of geometrically anisotropic nanoparticles disposed thereon and oriented uni-directionally in a preferential direction with an electrically conductive connection between the nanoparticles and the webs and a potential difference with respect to ground can be applied to the active electrode by a voltage or current source, the nanoparticles are connected in each case to two webs and the connections are material-interlocking.

Abstract: An ultrasonic actuator may be provided in which generation of a stress is prevented in the connection face of the piezoelectric element between the electrodes and the conductive members. The ultrasonic actuator includes a piezoelectric element (P1) and flexible cables (F1). The piezoelectric element (P1) includes: a piezoelectric layer (1); a power supply electrode (2) provided on a principal surface of the piezoelectric layer (1); a counter electrode (3) provided to face the power supply electrode (2) with the piezoelectric layer (1) interposed therebetween; a power supply external electrode (4) which is provided on a short-side surface of the piezoelectric element (P1), and is electrically coupled to the power supply electrode (2); and a counter external electrode (5) which is provided on a short-side surface of the piezoelectric element (P1), and is electrically coupled to the counter electrode (3).

Abstract: A multilayered piezoelectric element in which braking to displacement of piezoelectric material layers is suppressed and insulating films suitable for thinning of the piezoelectric material layers are formed. A method of manufacturing the element includes the steps of: (a) forming a multilayered structure including piezoelectric material layers, at least one first electrode layer, and at least one second electrode layer; (b) discharging a liquid synthetic resin from a nozzle provided in a dispenser to apply it to an end portion of the first electrode layer in a first region within side surfaces of the multilayered structure and curing the liquid synthetic resin to form a first insulating film; and (c) discharging the liquid synthetic resin from the nozzle to apply it to an end portion of the second electrode layer in a second region and curing the liquid synthetic resin to form a second insulating film.

Abstract: A piezoelectric actuator for a fuel injection valve has an actuator body with a multiplicity of ceramic layers and a multiplicity of electrode layers which are arranged between the ceramic layers. In this case, an external electrode is provided which is connected to some of the electrode layers. The external electrode has a plurality of longitudinal wires, which run in the longitudinal direction of the actuator body, and a plurality of weft wires, wherein a weft wire is passed through the longitudinal wires in such a way that some of the longitudinal wires run above the weft wire and other longitudinal wires run beneath the weft wire.

Abstract: A thin-film actuator that deforms a diaphragm to generate force includes a lower electrode disposed on the diaphragm, a first piezoelectric layer disposed on the lower electrode, an intermediate electrode disposed on the first piezoelectric layer, a second piezoelectric layer disposed on the intermediate electrode, and an upper electrode disposed on the second piezoelectric layer.

Abstract: A piezoelectric actuator for a fuel injection valve has an actuator body with a plurality of ceramic layers and a plurality of electrode layers between the ceramic layers. There is a connection area between an electrode layer and a ceramic layer adjacent to the electrode layer, where the adhesive strength between the electrode layer and the ceramic layer is reduced in parts of the connection area to provide for a predetermined breaking point within the actuator body. This allows for a controlled rupture of layers within the actuator body with high forces, in particular high shear forces such as those that occur with stress due to shock.

Abstract: In an ultrasonic probe in which individual wires led out from multilayered piezoelectric elements are arranged in a staggered manner, short-circuit is prevented. Each of the elements includes: a multilayered structure in which piezoelectric material layers and at least one internal electrode are stacked; first and second flat electrodes; first and second side electrodes; an insulating film formed at a second side surface side of the multilayered structure; a wiring member bonded to the first flat electrode on the one end of the multilayered structure by using a conducting adhesive material; and the wiring member is provided at the second side surface side of the multilayered structure and the insulating film electrically separates the second side electrode and the conducting adhesive material in a first element, and the wiring member is provided at a first side surface side of the multilayered structure in a second element.

Abstract: A driving system in accordance with embodiments of the present invention includes a structure and a vibration system. The structure has at least one point to frictional couple to and drive a movable element in one of at least two directions. The structure also has at least two bending modes which each have a different resonant frequency. The vibration system applies two or more vibration signals which are at a vibration frequency to each of the bending modes of the structure. The vibration frequency is substantially the same as one of the resonant frequencies. At the vibration frequency one of the bending modes of the structure is vibrating substantially at resonance and the other of the bending modes of the structure is vibrating at partial resonance. The vibration system adjusts a phase shift between the two or more applied vibration signals to control which one of the at least two directions the moveable element is moved.

Abstract: A multilayered piezoelectric element in which first internal electrodes include first exposed portions formed at the end portion of a first piezoelectric material. And the second internal electrodes include second exposed portions formed at the end portion of a second piezoelectric material.

Abstract: The electronic apparatus comprises a display portion and a quartz crystal oscillator at least, and said electronic apparatus comprises at least one quartz crystal oscillator. Also, the at least one oscillator comprises a quartz crystal oscillating circuit comprising an amplification circuit and a feedback circuit. The feedback circuit is constructed by a flexural mode, quartz crystal tuning fork resonator or a length-extensional mode quartz crystal resonator and for example, the quartz crystal tuning fork resonator comprising tuning fork tines and tuning fork base that are formed integrally, is shown with novel shape and electrode construction. Also, the quartz crystal tuning fork resonator, capable of vibrating in a fundamental mode and having a high frequency stability can be provided with a small series resistance and a high quality factor, even when the tuning fork resonator is miniaturized.

Abstract: An article comprises first and second electrically responsive elements having a cutting plane which is perpendicular to an x-dimension for separating the elements. The conductive elements of the conductive layers are alternatingly exposed to one of the two opposing faces of the conductive element.

Abstract: A piezoelectric actuator includes external conductors formed on an outer surface of a piezoelectric component. The external conductors each include a thick-film conductor and a conductive reinforcer. The thick-film conductor is provided with a first thick-film conductor formed on the outer surface of the piezoelectric component, second thick-film conductors which are formed on part of an outer surface of the first thick-film conductor and which are in surface-contact with the outer surface of the first thick-film conductor. The conductive reinforcer is attached to outer surfaces of the second thick-film conductors.

Abstract: A multi-element piezoelectric actuator and driver is presented that allows greater control over the dynamic displacement response of a piezoelectric actuator. A system comprises a piezoelectric driving apparatus configured to transmit a plurality of waveform signals to a corresponding plurality of piezoelectric elements of a piezoelectric actuator. The piezoelectric driving apparatus comprises a waveform generator to generate a waveform configured to operate a piezoelectric element, a plurality of channels coupled to the waveform generator and configured to be electrically coupled the piezoelectric elements of the piezoelectric actuator, a channel comprising an input configured to receive a waveform, a driving amplifier electrically coupled to the input and configured to amplify the waveform, and an output configured to transmit the waveform and configured to be electrically coupled to a piezoelectric element.

Abstract: A piezoelectric drive unit and a piezoelectric drive element are provided, which are compact and lightweight, and able to be stably displaced and positioned, in addition, efficiently driven even at low voltage. One end of a rod is fixed to an approximate center of a main surface of a piezoelectric drive element (drive element). The drive element is in a configuration where two element structures are incorporated by dividedly forming part of internal electrodes being alternately layered with a plurality of pieces of piezoelectrics, and has two regions divided with the center of the element as an origin. When signal are inputted into the internal electrodes via terminal electrodes such that a phase is shifted by 90 degrees between the two regions, the rod is rotated. When a tip of the rod is biased to be disposed by a spring such that it is pressed to a side face of a shaft for guiding a sliding frame of a lens, the lens slides along the shaft with rotation of the rod.

Abstract: A piezoceramic multilayer actuator has a first sub-stack (12, 14, 16) with a plurality of piezoceramic layers (22) and at least one internal electrode (24, 26), the piezoceramic layers (22) and the at least one internal electrode (24, 26) being laminated in an alternating manner, a second sub-stack (12, 14, 16) has a plurality of piezoceramic layers (22) and at least one internal electrode (24, 26), the piezoceramic layers (22) and the at least one internal electrode (24, 26) being laminated in an alternating manner, and a connection layer (40) arranged between the first sub-stack (12, 14, 16) and the second sub-stack (12, 14, 16), wherein the connection layer (40) is set up by a multitude of single connection points or connection lines (44) or other connection regions.

Abstract: A linear electromechanical translation apparatus is provided of the type comprising first and second clamps fixed to a support, first and second elongate movable members each extending through one of the clamps, and an extension actuator connected between the movable members and adapted to move each one of the elongate movable members longitudinally relative to the other member as the extension actuator is extended or retracted. The apparatus is characterized in that the first elongate movable member has a rear end connected to a front end of the extension actuator, and the second movable member has a rear end connected to a rear end of the actuator and has a forwardly extending elongate portion which lies beside and parallel to the first elongate movable member. Both the clamp assemblies may be located forwardly of the front end of the actuator.

Abstract: When a piezoelectric ceramic sheet is divided into two equal parts in a longitudinal direction and two equal parts in a width direction to form four regions, internal electrodes are disposed over each region and are disposed so that surface areas occupied in each region are substantially the same, and a longitudinal vibration is detected based on a potential difference between the internal electrodes.

Abstract: An ultrasonic array transducer having an array of piezoelectric elements may be made with a curvature which may enable the piezoelectric elements to control the way in which ultrasonic energy is focused by the transducer. A substrate that has a set of element electrodes on a surface of the substrate may be created. Each element electrode may be electrically isolated from the others and configured to correspond to the location of one of the piezoelectric elements. A piezoelectric component which includes piezoelectric material may be bonded to the substrate such that each element electrode is juxtaposed next to the piezoelectric component. The surface of the substrate and/or to the piezoelectric material may have the curvature while they are separated and prior to the bonding. The bonding may be performed in a manner that results in the array of piezoelectric elements having the curvature.

Abstract: A piezoelectric actuator for use in a fuel injection system of an internal combustion engine, the actuator comprising a stack of ferroelectric layers; an encapsulation for protecting the stack from the ingress of liquid; and oxygenation means for providing oxygen to the ferroelectric layers, the means positioned between the encapsulation and stack. The oxygenation means is preferably impregnated in a fabric which forms a layer between the encapsulation and the stack.

Abstract: A vibration plate, an insulating layer and a plurality of piezoelectric layers, connected to each other, are connected to an upper face of a flow passage unit. Between the plurality of piezoelectric layers, there is provided an intermediate electrode having; opposing portions opposed to center portions of pressure chambers; and connecting portions for connecting the opposing portions at a region opposed to connection portion with the flow passage unit. Between the insulating layer and one of the piezoelectric layers, there is provided a lower electrode extending across the entire region not opposed to the intermediate electrode, including regions opposed to regions of the pressure chambers located outside the center portions thereof. At an upper face of the other piezoelectric layer, upper electrodes are located to be opposed to the pressure chambers. A shielding electrode is arranged between the vibration plate and the insulating layer across the entire regions thereof.

Abstract: In a method for manufacturing a piezoelectric actuator, a ceramic sintered body is prepared and a size of the ceramic sintered body is adjusted in a thickness direction defined below by grinding piezoelectric ceramic layers, included in the ceramic sintered body, located outermost in the thickness direction. In the ceramic sintered body, internal electrodes are each disposed between piezoelectric ceramic layers. The thickness direction is defined as the direction along the thickness of the piezoelectric ceramic layer. Each of the inert sections are disposed on at least one side of the active section, for driving the piezoelectric actuator, in the thickness direction. Dummy internal electrodes are arranged in the inert sections such that each of the dummy internal electrodes are each located between ceramic layers. The thickness of the piezoelectric ceramic layers disposed between the dummy internal electrodes increases with distance from the active section.

Abstract: The invention relates to a method for producing a piezoelectric actuator in which a metallization paste is applied to a sintered piezoelectric stack and a flexible metal electrode is arranged on top of the paste. In a subsequent baking or firing step, a base metallic coating is formed from the metallization paste, whereby the base coating is permanently connected to the piezoelectric stack and to the flexible metal electrode. Alternatively, the metallization paste can be applied to a green body which is subsequently sintered so that a first layer of a base metallic coating is formed in the sintering step. A metallization paste is applied to the first layer in a similar manner and a flexible metal electrode is arranged thereon, whereby the metal electrode becomes fixed during a second baking step.

Abstract: A multi-layer piezoelectric element having high durability which allows it to increase the amount of displacement of a piezoelectric actuator under high voltage and high pressure and does not undergo a change in the amount of displacement during continuous operation in a high electric field and under a high pressure over a long time period is provided. The multi-layer piezoelectric element comprises a stack of at least one piezoelectric layer and a plurality of internal electrodes consisting of first and second internal electrodes placed one on another, a first external electrode formed on a first side face of the stack and connected to the first internal electrode and a second external electrode formed on a second side face of the stack and connected to the second internal electrode, wherein the bonding strength between the piezoelectric layer and the internal electrode is weaker than the bending strength of the piezoelectric layer.

Abstract: The disclosed is a piezoelectric phase shifter, which comprises: an input part for inputting input voltages; an output part for outputting output voltages; and a control part for tuning phase difference between the output and input voltages, which are made of a piezoelectric ceramic plate. Further, the input, output and control parts are separated by insulting gaps respectively. The wide phase shift range and good ability to manage high power and relatively high energy transmission efficiency may be obtained by the disclosure.

Abstract: Piezoactuator comprising a multiplicity of piezolayers, between each of which a layer electrode is arranged, the layer electrodes being alternately connected to a respective connection electrode. A protective resistor is provided between at least one connection electrode and the layer electrodes connected to said connection electrode.

Abstract: A piezoelectric multilayer component has a base body including a stack of dielectric layers, electrode layers and at least one predetermined breaking layer. The predetermined breaking layer is arranged at least for the most part in an inactive zone of the multilayer component and cracks under specific tensile loads.

Abstract: A stacked piezoelectric device 1 includes a ceramic laminate 15 formed by laminating a plurality of piezoelectric ceramic layers 11 and a plurality of inner electrode layers 13 and 14 alternately and a pair of side electrodes 17 and 18 formed on side surfaces thereof. The inner electrode layers 13 and 14 are connected electrically to either of the side electrodes. The ceramic laminate 15 has absorbing portions 12 formed in slit-like areas recessed inwardly from the side surfaces thereof. The stress absorbing portions are easier to deform than the piezoelectric ceramic layers 11. Adjacent two of the inner electrode layers 13 and 14 interleaving the stress absorbing portion 12 therebetween are both connected electrically to the positive side electrode 17.

Abstract: To provide an electromechanical conversion element, a vibration actuator, a vibration actuator driving device, a lens barrel and a camera, which facilitate the achievement of the desired drive characteristics. An electromechanical conversion element comprising: a piezoelectric body having a polarization part polarized in a certain direction; and a plurality of separately formed electrodes on a continuous region of the polarization part.

Abstract: A method of manufacturing an acoustic wave device includes: forming a conductive pattern on a wafer made of a piezoelectric substrate having an acoustic wave element, the conductive pattern including a first conductive pattern being continuously formed on a cutting region for individuating the wafer, a second conductive pattern being formed on an electrode region where a plated electrode is to be formed and being connected to the acoustic wave element and a third conductive pattern connecting the first conductive pattern and the second pattern; forming an insulating layer on the wafer so as to have an opening on the second conductive pattern; forming the plated electrode on the second conductive pattern by providing an electrical current to the second conductive pattern via the first conductive pattern and the third conductive pattern; and cutting off and individuating the wafer along the cutting region.

Abstract: An electrical component includes a body made from a stack of ceramic layers. The body has a cavity that is accessible external to the body. The cavity is defined by a wall. A contact surface is on the wall. A contact device is electrically connected to the contact surface. At least part of the contact device is external to the body. The contact device includes a connection part and a spring. The spring is between the body and the connection part. The spring is for exerting a spring force on the contact surface.

Abstract: A piezoelectric multilayer component has a base body with a stack of piezoceramic layers and electrode layers arranged one on top of the other in an alternating manner. Neighboring layers of the stack are braced against one another such that stresses run perpendicular to the stacking direction.

Abstract: Disclosed herein is a piezoelectric transformer having a pinwheel-type electrode. The piezoelectric transformer of the present invention includes a body, an upper electrodes and a lower electrode. The body is formed in a circular planar shape and is made of a piezoelectric material. The upper electrodes are formed to be adjacent to one of first and second planes corresponding to upper and lower surfaces of the body, formed in the same planar shape as that of the body, and formed to be separated in the shape of a pinwheel. In the upper electrodes, input voltage is applied to some of separate electrodes, and output voltage is obtained from the remaining electrodes. The lower electrode is adjacent to a plane opposite the plane on which the upper electrode is formed, the lower electrode being formed in the same planar shape as that of the body.

Abstract: A piezoelectric thin-film resonator includes a substrate, a lower electrode arranged on the substrate, a piezoelectric film arranged on the lower electrode, and an upper electrode arranged on the piezoelectric film. A region in which the upper electrode overlaps with the lower electrode through the piezoelectric film has an elliptical shape, and a condition such that 1<a/b<1.9 is satisfied where a is a main axis of the elliptical shape, and b is a sub axis thereof.