Abstract: A surface elastic wave generator may include a substrate. A first conductivity type region is formed in the substrate. A second conductivity type doped region includes at least one doping pattern doped on surface of the first conductivity type region. Through applying reverse bias to junctions between the first conductivity type region and the second conductivity type doped region, a depletion capacitance region is formed. Also, through inputting signal to the first conductivity type region or the second conductivity type doped region, the surface elastic wave is generated on the substrate. In addition, a surface elastic wave transceiver and surface elastic wave generation method are also provided.

Abstract: A sensor assembly including one or more capacitive micromachined ultrasonic transducer (CMUT) microarray modules which are provided with a number of individual transducers. The microarray modules are arranged to simulate or orient individual transducers in a hyperbolic paraboloid geometry. The transducers/sensor are arranged in a rectangular or square matrix and are activatable individually, selectively or collectively to emit and received reflected beam signals at a frequency of between about 100 to 170 Hz.

Abstract: A MEMS arrangement is provided that has a top plane containing a rotatable element such as a mirror. There is a middle support frame plane, and a lower electrical substrate plane. The rotatable element is supported by a support frame formed in the middle support frame plane so as to be rotatable with respect to the frame in a first axis of rotation. The frame is mounted so as to be rotatable with respect to a second axis of rotation. Rotation in the first axis of rotation is substantially independent of rotation in the second axis of rotation.

Abstract: An all-silicon electrode capacitive transducer comprising: a movable silicon microstructure coupled to a glass substrate, the movable silicon microstructure having a movable silicon electrode, the glass substrate having a top surface and at least one recess, the movable silicon electrode having a first flat surface parallel to a plane of the top surface of the glass substrate, the movable silicon electrode having a first electronic work function; and a stationary silicon electrode coupled to a glass substrate, the stationary silicon electrode located adjacent to the movable silicon electrode, the stationary silicon electrode configured to sense or actuate displacement of the movable silicon microstructure, wherein the stationary silicon electrode has a second flat surface parallel to the first flat surface, the stationary silicon electrode having a second electronic work function equal to the first electronic work function.

Abstract: An ultrasonic transducer and ultrasonic diagnostic apparatus are provided. An ultrasonic transducer includes a substrate including a trench formed in a lower surface of the substrate; and a first element and a second element formed on an upper surface of the substrate and are located adjacent to each other, wherein the trench is positioned between the first element and the second element, wherein the first element and the second element each include a plurality of ultrasonic cells that are two-dimensionally arranged; wherein a first contour line of the first element and a second contour line of the second element, which are adjacent to each other, each form a zig-zag line which are complementary with each other, and the trench is formed in a zig-zag pattern between the first contour line and the second contour line.

Abstract: A MEMS vibrator includes: a substrate; a supporting portion which is connected to the substrate; a base portion which is connected to the supporting portion; and a plurality of vibration portions which is separated from the substrate and extends in different directions from each other from the base portion, and in which the adjacent vibration portions vibrate in a phase of a reverse direction to each other. In the vibration portion, the base portion has a vibration node, and at least a part of the supporting portion is overlapped with the vibration node in a planar view.

Abstract: Provided is an actuator formed in a substrate including a handle layer, an elastic body layer, and an insulating layer, the actuator including a movable portion supported to a support portion by an elastic body, a movable comb electrode formed on the movable portion, a fixed comb electrode supported by the support portion, and electrode wirings connected to the respective comb electrodes in which the elastic body supports the movable portion such that the movable portion is displaceable in a direction perpendicular to the substrate in accordance with voltages applied to the comb electrodes; the comb electrodes are made up of the handle layer, and the elastic body is made up of the elastic body layer; and a handle layer separation groove is provided to electrically separate between the handle layers of the support portions supporting the comb electrodes, and a structure reinforcing portion is formed across the separation groove.

Abstract: The energy harvester module of the capsule comprises: a primary oscillating structure subjected to an external low-frequency stress; a secondary oscillating structure comprising an elastic element and able to vibrate in high-frequency resonance; and an electrostatic structure with a first electrode coupled to the primary structure and a second electrode coupled to the secondary structure. The electrodes exert a mutual attraction between them driving the secondary structure away from its stable equilibrium position with tensioning of the elastic element, up to a limit beyond which the secondary structure is released by relaxation effect to vibrate at a resonance frequency. A transducer coupled to the secondary structure converts these high frequency vibration movements into electrical energy.

Abstract: According to one embodiment, an energy conversion device comprises a nuclear battery, a light source coupled to the nuclear battery and operable to receive electric energy from the nuclear battery and radiate electromagnetic energy, and a photocell operable to receive the radiated electromagnetic energy and convert the received electromagnetic energy into electric energy. The nuclear battery comprises a radioactive substance and a collector operable to receive particles emitted by the radioactive substance.

Abstract: Micro-Electro-Mechanical System (MEMS) structures, methods of manufacture and design structures are provided. The method of forming a MEMS structure includes forming a wiring layer on a substrate comprising actuator electrodes and a contact electrode. The method further includes forming a MEMS beam above the wiring layer. The method further includes forming at least one spring attached to at least one end of the MEMS beam. The method further includes forming an array of mini-bumps between the wiring layer and the MEMS beam.

Abstract: An electret-structure encompasses a fluorine-resin film 21, an electrode 22 formed on one surface of the fluorine-resin film 21, and a silica layer 21 formed on another surface of the fluorine-resin film 21. The silica layer 21 is implemented by a plurality of island-shaped silica regions 201 for covering the fluorine-resin film 21 in a topology such that the island-shaped silica regions 201 are isolated from each other. And negative charges are deposited on the island-shaped silica regions 201. The static-induction conversion element with the electret-structure 1 can be mounted on a substrate by reflow-process through Pb-free solder.

Abstract: An object of this invention is to create an actuator in which the amount of deformation is maintained and no displacement in the reverse direction occurs, even when a constant voltage is continuously applied for a long period of time. As a means for achieving the above object, the invention provides a conductive thin film comprising a polymer gel containing at least one organic molecule selected from the group consisting of electron-donating organic molecules and electron-withdrawing organic molecules, a nano-carbon material, an ionic liquid, and a polymer.

Abstract: The present invention relates to a method and a device for converting energy using a change of a contact area and a contact angle of liquid and, more specifically, to a method and a device for converting mechanical energy into electric energy by applying a reciprocal phenomenon of electrowetting, wherein liquid and gas are positioned between two facing substrates and energy is converted by using a volume change of a fluid, such that the present invention has the advantages of preventing channel-blocking without requiring all facing electrodes to be patterned, simplifying a device configuration, implementing easy control, and removing the need to apply an external power source.

Abstract: Provided is an ion conducting actuator that easily allows reduction in size and integration thereof, compared to existing one, and gives a large generating force. The columnar ion conducting actuator includes a tubular member serving as a first electrode, an ion-supplying material disposed inside the tubular member, and linear second electrodes disposed inside the tubular member. The ion-supplying material lies between the inner wall of the tubular member and the second electrodes and includes a polymer gel containing positive ions and negative ions. The tubular member contains a plurality of the second electrodes. Either the positive ions or the negative ions contained in the polymer gel move toward the plurality of second electrodes side and the other ions move toward the inner wall side of the tubular member by applying a voltage between the tubular member and the plurality of the second electrodes to elongate the ion conducting actuator.

Abstract: Megasonic cleaning systems and methods of fabricating and using the same are provided. In one embodiment, the system comprises a plurality of Micro-Electromechanical System (MEMS) transducers, each transducer including a movable membrane with a membrane electrode coupled to a first potential disposed above and spaced apart from an upper surface of a die including a cavity electrode coupled to a second potential, the membrane including multiple layers including a polysilicon layer between a top silicon nitride layer and a bottom silicon nitride layer, and the membrane electrode includes the polysilicon layer; a chuck on which a target workpiece is positioned; and a fluid to couple sonic energy from the plurality of MEMS transducers to the target workpiece. Other embodiments are also provided.

Abstract: Some examples include at least one capacitive micro-electro-mechanical transducer (cMUT). For instance, the cMUT may include a substrate, a plate, and a resilient structure therebetween. In some examples, an integrated circuit may be formed on or integrated with the plate or other portion of the cMUT. Furthermore, in some examples, two cMUTs may be arranged in a stacked configuration. For instance, one cMUT may be operable for transmission, while a second cMUT may be operable for reception.

Abstract: A method for making an actuator device includes forming a substantially planar structure having a stage resiliently supported for movement within a plane of the structure, an actuator coupled to an outer periphery of the stage and operable to apply a force acting in the plane and tangentially to the stage when actuated, the actuator comprising a fixed frame and a moving frame resiliently supported for reciprocal movement relative to the fixed frame by a motion control flexure, and an outer frame surrounding and supporting the stage and the actuator. The moving frame is moved to a deployed position that is coplanar with, parallel to and spaced apart from the fixed frame at a selected distance, and the moving frame is then fixed at the deployed position for substantially rectilinear, perpendicular movement relative to the fixed frame.

Abstract: Electricity generated by a vibration power generator 200 can be extracted efficiently by providing the vibration power generator 200, a rectifier circuit bridge 205, an output controlling circuit 201, a load detecting circuit 202 and a frequency detecting circuit 204 and detecting a frequency of the vibration power generator 200 and then controlling an impedance of an output controlling circuit 101 depending on the frequency.

Abstract: A micro rotary machine may include a micro actuator and a micro shaft coupled to the micro actuator. The micro shaft comprises a horizontal shaft and is operable to be rotated by the micro actuator. A micro tool is coupled to the micro shaft and is operable to perform work in response to motion of the micro shaft.

Abstract: The present invention relates to an electromechanical transducer capable of arbitrarily varying the amount of deflection of a vibrating membrane for every element. The electromechanical transducer includes a plurality of elements including at least one cell that includes a first electrode and a second electrode opposed to the first electrode with a gap sandwiched therebetween and a direct-current voltage applying unit configured to be provided for each element and to separately apply a direct-current voltage to the first electrodes in each element. The first electrodes and the second electrodes are electrically separated for every element.

Abstract: This invention is related with electrical energy conversion device, which uses built-in potential of metal-to-metal junctions from repeating movements with random frequencies, speeds and amplitudes at the medium of the device. The device using the method does not rely on a resonant frequency, besides, it can convert the kinetic energy to electrical energy even at low frequencies. Furthermore, its application to the real life situations is economic and beneficial because of the efficient working principle and simple structure. Unique design of the device enables direct wiring of the outputs of identical or similar devices together for the purpose of power scaling without the need of using another device, which may cause energy losses and increase the total cost.

Abstract: A nanopositioning system for producing a coupling interaction between a first nanoparticle and a second nanoparticle. A first MEMS positioning assembly includes an electro-static comb drive actuator configured to selectively displace a first nanoparticle in a first dimension and an electrode configured to selectively displace the first nanoparticle in a second dimensions. Accordingly, the first nanoparticle may be selectively positioned in two dimensions to modulate the distance between the first nanoparticle and a second nanoparticle that may be coupled to a second MEMS positioning assembly. Modulating the distance between the first and second nanoparticles obtains a coupling interaction between the nanoparticles that alters at least one material property of the nanoparticles applicable to a variety of sensing and control applications.

Abstract: A torque measurement system that includes a rotor device and a stator device can perform automatic tuning to improve the initial tuning performed during design and assembly. The stator device can include a variable capacitive element and a micro-controller configured to adjust a capacitance value of the variable capacitive element. Additionally or alternatively, the rotor device can include a variable capacitive element and a micro-controller configured to adjust a capacitance value of the variable capacitive element. The adjustment of the capacitive elements can be based on the quality of signal detected at either the rotor device or stator device.

Abstract: An electrostatic transformer includes: a first fixed electrode; a second fixed electrode; a movable electrode displaceably supported by a flexible member within a space between the first fixed electrode and the second fixed electrode; and permanently charged films disposed on electrode surfaces of the movable electrode. And: an AC output voltage corresponding to a change in an electric charge induced at the second fixed electrode by displacing the movable electrode in response to an AC input voltage applied between the first fixed electrode and the movable electrode is extracted; and a ratio of the AC input voltage and the AC output voltage is determined based upon a ratio of an electromechanical coupling factor at an input-side electrostatic actuator, configured with the first fixed electrode and the movable electrode, and an electromechanical coupling factor at an output-side electrostatic actuator, configured with the second fixed electrode and the movable electrode.

Abstract: A triboelectric power system includes a triboelectric generator, a rechargeable energy storage unit and a power management circuit. The rechargeable energy storage unit is associated to the triboelectric generator. The power management circuit is configured to receive an input current from the triboelectric generator and to deliver an output current corresponding to the input current to the rechargeable battery so that the output current has a current direction and a voltage that will recharge the rechargeable battery.

Abstract: A micro machine may be in or less than the micrometer domain. The micro machine may include a micro actuator and a micro shaft coupled to the micro actuator. The micro shaft is operable to be driven by the micro actuator. A tool is coupled to the micro shaft and is operable to perform work in response to at least motion of the micro shaft.

Abstract: A micromechanical device includes a substrate, a micromechanical structure supported by the substrate and configured for overtone resonant vibration relative to the substrate, and a plurality of electrodes supported by the substrate and spaced from the micromechanical structure by respective gaps. The plurality of electrodes include multiple drive electrodes configured relative to the micromechanical structure to excite the overtone resonant vibration with a differential excitation signal, or multiple sense electrodes configured relative to the micromechanical structure to generate a differential output from the overtone resonant vibration.

Abstract: A MEMS vibrator includes a substrate, a lower electrode provided on a main surface of the substrate, a fixed portion provided on the main surface, and an upper electrode which is separated from the substrate and is supported by the fixed portion. The upper electrode is a vibrating body having a region overlapping the lower electrode when the substrate is seen in plan view, and includes a weight portion in a region provided with an antinode portion of vibration of the upper electrode as the vibrating body.

Abstract: Disclosed are a micro electro mechanical systems (MEMS) device and an apparatus for compensating for a tremble. The MEMS device includes a substrate; a driven member moving relative to the substrate; an elastic member connected to the driven member and the substrate; a driving member fixed to the substrate for driving the driven member; and a dynamic stopper fixed to the substrate and latched to the driven member.

Abstract: According to one embodiment, an electrostatic actuator includes a substrate, an electrode unit, a film body unit, and an urging unit. The electrode unit is provided on the substrate. The film body unit is provided to oppose the electrode unit and is conductive. The urging unit is configured to support the film body unit and includes a connection unit connected to the substrate and an elastic unit provided between the connection unit and the film body unit. A contacting state and a separated state are possible for the electrode unit and the film body unit according to a voltage applied to the electrode unit. The elastic unit has a branch portion between one end of the elastic unit connected to the connection unit and multiple one other ends of the elastic unit connected to the film body unit.

Abstract: The device comprises a first actuating bump made from electrically conducting material with a first contact surface. A second actuating bump made from electrically conducting material is facing the first actuating bump. An electrostatic actuating circuit moves the actuating bumps with respect to one another between a first position and another position. The actuating circuit comprises a device for applying a higher potential on the second actuating bump than on the first actuating bump. A film of electrically insulating material performs electric insulation between the first and second bumps. The electrically insulating material film comprises an interface with a positive ion source and is permeable to said positive ions.

Abstract: An ultrasonic transducer and a method of manufacturing the same. The ultrasonic transducer includes a substrate, a supporting unit that is disposed on the substrate and comprises a through-hole, a thin-film disposed over the substrate in a region corresponding to the through-hole, wherein the thin-film is separated from the substrate and the supporting unit, and a connection unit that connects the supporting unit to the thin-film. In the method of manufacturing the ultrasonic transducer, a plurality of SOI wafers and a Si wafer are bonded without performing an aligning process.

Abstract: An system for manufacturing a field emission structure is provided that involves a magnet supplying device and a magnet placement device for placing each of a plurality of magnets at a corresponding location of a plurality of locations of the field emission structure. The corresponding location and a corresponding orientation of each of the magnets relative to each other are defined in accordance with a code that specifies at least one magnet of the plurality of magnets having a first polarity orientation and at least one other magnet of the plurality of magnets having a second polarity orientation that is opposite from the first polarity orientation.

Abstract: A Micro Electro Mechanical Systems (MEMS) device comprising: a rotor, comprising a first plurality of rotor teeth and a second plurality of rotor teeth, formed in at least two layers of silicon-on-insulator (SOI) substrate, wherein each rotor tooth belonging to the first plurality of rotor teeth is formed in a first layer and each rotor tooth of the second plurality of rotor teeth is formed in a second layer; and a stator comprising a first plurality of stator teeth and a second plurality of stator teeth, formed in at least two layers of SOI substrate, wherein each stator tooth belonging to the first plurality of stator teeth is formed in a first layer, and each stator tooth of the second plurality of stator teeth is formed in a second layer.

Abstract: A tunable tilting device is described. The device includes a tilting element and a suspension structure that has one or more flexures coupled to the tilting element. The suspension structure has a variable bending stiffness and configured to bend due to a tilting motion of the tilting element around a pivot axis. The suspension structure is responsive to a tuning force actuating a variation of an extension stress or a compression stress of the suspension structure, and thereby can vary the bending stiffness of the suspension structure.

Abstract: In one embodiment, a device is provided that includes: a cascaded electrostatic actuator defining a stack in a substrate having a plurality of gaps between parallel plate electrodes; and a controller configured to drive the cascaded electrostatic actuator to open and close selected ones of the gaps.

Abstract: A system for electro-hydrodynamically extracting energy from wind includes an upstream collector that is biased at an electric potential and induces an electric field. An injector introduces a particle into the electric field. The wind drag on the particle is at least partially opposed by a force of the electric field on the particle. A sensor monitors an ambient atmospheric condition, and a controller changes a parameter of the injector in response to a change in the atmospheric condition.

Abstract: A MEMS vibrator according to the invention includes: a first electrode fixed to a surface of a substrate; and a second electrode having a beam portion including a second face facing a first face of the first electrode, and a supporting portion supporting the beam portion and fixed to the surface of the substrate. The beam portion has a first portion whose length in a normal direction of the first face of the beam portion monotonically decreases toward a tip of the beam portion.

Abstract: On an upper surface of a fixed substrate, a plurality of strap-shaped base electrodes are arranged in parallel to each other. On each of the base electrodes, an electret is formed. The electret has a width wider than the width of each base electrode, and the electret covers an exposed surface of the base electrode. A movable substrate is disposed in parallel to and facing the surface of the fixed substrate where the electrets and others are formed. The movable substrate is movable relatively to the fixed substrate. On a facing surface of the movable substrate, strip-shaped counter electrodes are each formed so as to face each base electrode.

Abstract: An electrostatic (ES) device is described with electrodes that improve its performance metrics. Devices include ES generators and ES motors, which are comprised of one or more stators (stationary members) and one or more rotors (rotatable members). The stator and rotors are configured as a pair of concentric cylindrical structures and aligned about a common axis. The stator and rotor are comprised of an ensemble of discrete, longitudinal electrodes, which are axially oriented in an annular arrangement. The shape of the electrodes described herein enables the ES device to function at voltages significantly greater than that of the existing art, resulting in devices with greater power-handling capability and overall efficiency. Electrode shapes include, but are not limited to, rods, corrugated sheets and emulations thereof.

Abstract: Electrostatic generator/motor electrode assembly designs are provided that both minimize the rotor drag forces and increase the power output relative to older designs. In one of the new designs, both the rotor and the stator electrodes are encapsulated in a dielectric that forms smooth surface discs or cylinders that result in minimal fluid drag losses on the rotors and also increases the voltage-breakdown potentials between the rotor and stator elements. In the second of the new designs, the disc or cylinder geometry is maintained for both rotor and stator but the rotor has no embedded electrodes. Instead it is made up of an assembly of dielectric elements that alternate between a high dielectric constant and a low dielectric constant forming a smooth surface disc of surface.

Abstract: A two-dimensional comb-drive actuator and manufacturing method thereof are described. The two-dimensional comb-drive actuator includes a supporting base, a frame and a movable body. The supporting base has first comb electrodes and the frame has internal comb electrodes and external comb electrodes. The external comb electrodes of the frame are interdigitated to the first comb electrodes of the supporting base. The movable body has second comb electrodes which are interdigitated to the internal comb electrodes of the frame. The thicknesses of the second comb electrodes of the movable body are unequal to the internal comb electrodes of the frame and the external comb electrodes of the frame are unequal to the first comb electrodes of the supporting base. The two-dimensional comb-drive actuator utilizes a conducting layer for the above-mentioned comb electrodes in order to increase the rotation angle and operation frequency thereof.

Abstract: A ball-electric power generator is provided, in which triboelectric power can be generated by friction when balls made of one of triboelectric series having different shapes of spheres, sheets, rods, wires and the like move and hit layers or substrates made of one of the triboelectric series in a chamber defined by the layers or substrates and a spacer connecting the layers.

Abstract: Systems and methods for providing increased CMUT imaging performance are disclosed. The system can comprise CMUT electronics with integrated or derived gap feedback. In this manner, the response of the CMUT membrane can be linearized to improve pressure output and/or harmonic distortion. The system can comprise a CMUT with series resistance to improve linearity. The system can also comprise a CMUT with series induction-resistance for improved linearity at reduced voltages. A method for linearizing CMUT response is also disclosed. The method can comprise providing a signal to the CMUT that is inversely proportional the gap between the CMUT membrane and the substrate on which the CMUT is fabricated.

Abstract: A method for making an actuator includes forming a substantially planar actuator device of an electrically conductive material, the device incorporating an outer frame, a fixed frame attached to the outer frame, a moveable frame disposed parallel to the fixed frame, a motion control flexure coupling the moveable frame to the outer frame for coplanar, rectilinear movement relative to the outer frame and the fixed frame, and an actuator incorporating a plurality of interdigitated teeth, a fixed portion of which is attached to the fixed frame and a moving portion of which is attached to the moveable frame, moving the moveable frame to a deployed position that is coplanar with, parallel to and spaced at a selected distance apart from the fixed frame and fixing the moveable frame at the deployed position for substantially rectilinear, perpendicular movement relative to the fixed frame.

Abstract: A vibration power generator includes a first substrate, a first electrode on the first substrate, a second substrate spaced from and opposite the first substrate, and a second electrode on the second substrate. The first electrode vibrates with respect to the second substrate, and the first electrode and the second electrode include a film retaining electric charges. The vibration generator includes a third electrode with a film retaining electric charges on the first substrate, and a fourth electrode with a film retaining electric charges on the second substrate. The third electrode and the fourth electrode are arranged so that the first substrate is retained in a predetermined position when an external force does not act on the first substrate, while an electrostatic force for returning the first substrate to a predetermined position acts on the first substrate and the first substrate moves with respect to the second substrate.

Abstract: A MEMS device (20) includes a movable element (20) suspended above a substrate (22) by a spring member (34) having a spring constant (104). A spring softening voltage (58) is applied to electrodes (24, 26) facing the movable element (20) during a powered mode (100) to decrease the stiffness of the spring member (34) and thereby increase the sensitivity of the movable element (32) to an input stimulus (46). Upon detection of a stiction condition (112), the spring softening voltage (58) is effectively removed to enable recovery of the movable element (32) from the stiction condition (112). A higher mechanical spring constant (104) yields a stiffer spring (34) having a larger restoring force (122) in the unpowered mode (96) in order to enable recovery from the stiction condition (112). A feedback voltage (56) can be applied to feedback electrodes (28, 30) facing the movable element (32) to provide electrical damping.

Abstract: An electrostatic induction generator has a first substrate and a second substrate that can move relative to each other while remaining opposed to each other, an electret provided in the first substrate, and a first electrode and a second electrode provided on a surface side opposed to the electret in the second substrate. A positional relationship between the electret and the first electrode and a positional relationship between the electret and the second electrode change in association with a change of relative positions between the first substrate and the second substrate, whereby an electrostatic capacitance between the electret and the first electrode and an electrostatic capacitance between the electret and the second electrode change to output an electric power. A structure that decreases the electrostatic capacitance between the first electrode and the second electrode is provided between the first electrode and the second electrode.

Abstract: A method of operating by pulse width modulation a micromirror device is disclosed. In one aspect, the method includes providing a micromirror device having a micromirror element electrostatically deflectable around a rotation axis between a first and second position. The micromirror element is controllable by applying voltage signals to a first and second electrode on one side of the rotation axis and a third and fourth electrode on the other side. The method includes associating an intermediate value of intensity to the micromirror element during a time frame, the intensity being between a first value corresponding to the first position and a second value corresponding to the second position. The method includes switching the micromirror element between the first and second position. The intermediate value corresponds to the ratio of periods in the time frame in which the micromirror element is in the first or second position.

Abstract: A micro-electro-mechanical transducer (such as a cMUT) having two electrodes separated by an insulator with an insulation extension is disclosed. The two electrodes define a transducing gap therebetween. The insulator has an insulating support disposed generally between the two electrodes and an insulation extension extending into at least one of two electrodes to increase the effective insulation without having to increase the transducing gap. Methods for fabricating the micro-electro-mechanical transducer are also disclosed. The methods may be used in both conventional membrane-based cMUTs and cMUTs having embedded springs transporting a rigid top plate.