Abstract: An integrated circuit includes pads formed on a back end of the line surface, and decoupling capacitor stacks monolithically formed about the pads. Solder balls are formed on the pads and connect to metal layers within the decoupling capacitor stacks to reduce noise and voltage spikes between the solder balls.

Abstract: A fabric-based item such as a fabric glove may include force sensing circuitry. The force sensing circuitry may include force sensor elements formed from electrodes on a compressible substrate such as an elastomeric polymer substrate. The fabric may include intertwined strands of material including conductive strands. Signals from the force sensing circuitry may be conveyed to control circuitry in the item using the conductive strands. Wireless circuitry in the fabric-based item may be used to convey force sensor information to external equipment. The compressible substrate may have opposing upper and lower surfaces. Electrodes for the force sensor elements may be formed on the upper and lower surfaces. Stiffeners may overlap the electrodes to help decouple adjacent force sensor elements from each other. Integrated circuits can be attached to respective force sensing elements using adhesive.

Abstract: Flexible implantable subcutaneous heart device (HD) structure, including a flexible device body, at least one flexible lead and at least one respective transition unit, the transition unit for respectively coupling each flexible lead to the flexible device body, the flexible device body including a plurality of inner components and a respective plurality of hollow outer units, the hollow outer units for encasing and protecting the inner components, each one of the hollow outer units including at least one hollow rigid element and a hollow flexible element, the hollow flexible element coupled with the hollow rigid element for enabling the outer unit a degree of flexibility, wherein the hollow flexible element is covered with a covering and wherein the flexible device body is covered with a polymer.

Abstract: A method of manufacturing a feedthrough dielectric body for an active implantable medical device includes the steps of forming a ceramic body in a green state, or, stacking discrete layers of ceramic in a green state upon one another and laminating together. The ceramic body has a first side opposite a second side. At least one via hole is formed straight through the ceramic body extending between the first and second sides. At least one via hole is filled with a conductive paste. The ceramic body and the conductive paste are then dried. The ceramic body and the conductive paste are isostatically pressed at above 1000 psi to remove voids and to form a closer interface for sintering. The ceramic body and the conductive paste are sintered together to form the feedthrough dielectric body. The feedthrough dielectric body is hermetically sealed to a ferrule.

Abstract: An electronic smoke comprises a puff detection sub-assembly module. The puff detection sub-assembly comprises a first conductive surface, a second conductive surface and an insulated ring spacer separating the first and the second conductive surfaces at an effective separation distance. The first conductive surface, the second conductive surface and the insulated ring spacer are housed inside a metallic can. The first conductive surface is electrically connected to the metal can by a first conductive ring which is disposed between the first conductive surface and a ceiling portion of the metal can. The second conductive surface is electrically connected to an output terminal through a second conductive ring, the second conductive ring elevating the puff detection sub-assembly above a floor portion of the metal can and urging the first conductive ring against a ceiling portion of the metal can.

Abstract: A resistor includes a resistive element, a protective film, and a pair of electrodes. The resistive element is made of a metal plate. The protective film is formed on the upper surface of the resistive element. The plated layers are formed to cover the electrodes. The electrodes are separated from each other with the protective film therebetween and are formed at both ends of the upper surface of the resistive element. The electrodes are formed by printing metal-containing paste.

Abstract: An electronic device is described wherein the electronic device comprises a substrate with a first conductive metal layer and a second conductive metal layer. A first microphonic noise reduction structure is in electrical contact with the first conductive metal layer wherein the first microphonic noise reduction layer comprises at least one of the group consisting of a compliant non-metallic layer and a shock absorbing conductor comprising offset mounting tabs with a space there between coupled with at least one stress relieving portion. An electronic component comprising a first external termination of a first polarity and a second external termination of a second polarity is integral to the electronic device and the first microphonic noise reduction structure and the first external termination are adhesively bonded by a transient liquid phase sintering adhesive.

Abstract: A surface mount electronic component includes an element including a dielectric layer that includes a first main surface and a second main surface, a first external electrode disposed on the first main surface, a second external electrode disposed on the second main surface, a first metal terminal connected to the first external electrode, a second metal terminal connected to the second external electrode, and an exterior material covering at least a portion of the element, the first and second external electrodes, and the first and second metal terminals. Upper and lower surfaces of the exterior material are flat or substantially flat.

Abstract: The present invention provides a method for manufacturing a secondary cell having a plurality of unit cells 21 that are connected in parallel, including, a step to prepare sheet-shaped unit cells each having a structure that a first electrode layer, a metal oxide semiconductor layer, a charging layer, and a second electrode layer are layered, a step to form a cell sheet by connecting the laminated unit cells in parallel, a step to measure a capacity of the cell sheet, and a step to connect a unit cell for capacity adjustment to the cell sheet in parallel when the capacity is smaller than a specification value.

Abstract: An MEMS microphone is disclosed, which comprises a substrate and a vibrating diaphragm and a back electrode which are located above the substrate, a plurality of comb tooth parts are formed in edge positions of the vibrating diaphragm, and the plurality of comb tooth parts are distributed in a peripheral direction of the vibrating diaphragm at intervals, wherein a position between every two adjacent comb tooth parts on the vibrating diaphragm is connected to the substrate via an insulating layer; and the comb tooth parts on the vibrating diaphragm are at least partially overlapped with the substrate, and a clearance exists between the comb tooth parts and the substrate and is configured as an airflow circulation channel. The microphone of the present invention has better impact resistance and can avoid intrusion of dust.

Abstract: A mounted structure includes an electronic component including external electrodes, a wiring substrate including lands, and joint portions composed of a solder joint material and configured to join the external electrodes and the lands. The external electrodes respectively include coatings that cover a principal surface of a body, which is opposed to the wiring substrate, and coatings that cover end surfaces of the body, which are opposed to each other in the length direction. A distance De between the coatings in the length direction and a distance Dl between the lands in the length direction satisfy a condition of 0.91?Dl/De?1.09.

Abstract: A high precision high reliability and quick response thermosensitive chip and manufacturing method thereof is provided, including a thermosensitive ceramic semiconductor substrate; glass protective layers are alternately spray-coated and sintered on the two surfaces of the thermosensitive ceramic semiconductor substrate; and the two surfaces of the thermosensitive ceramic semiconductor substrate having the glass protective layers are printed with metal electrode layers. The thermosensitive chip achieves quick response, accurate control of resistance precision and has high precision; in addition, the glass protective layers thereof enable the thermosensitive chip to have high reliability.

Abstract: A microphone includes: a substrate configured to have a through hole formed at a central portion thereof; a vibration membrane disposed to cover the through hole on the substrate to include a slit pattern in which slit patterns are arranged in a plurality of lines along a circular edge thereof; a fixed membrane separately mounted at an upper portion of the vibration membrane with an air layer therebetween to have a plurality of air inlets that extend therebetween in a direction of the air layer; and a support layer configured to support the fixed membrane separately mounted on the vibration membrane.

Abstract: A multi-layer ceramic capacitor includes a body. The body includes a capacitance forming unit, a cover, and a side margin. The capacitance forming unit includes ceramic layers laminated in a first direction and internal electrodes disposed between the ceramic layers. The cover covers the capacitance forming unit from the first direction. The side margin covers the capacitance forming unit from a second direction orthogonal to the first direction. The capacitance forming unit includes a surface layer portion adjacent to the cover. Ends of the internal electrodes in the second direction in the surface layer portion are curved toward the cover.

Abstract: An electrode foil that progresses an enlargement of the surface area of a dielectric film and that barely causes cracks which would even break a core part at the time of winding, a winding capacitor obtained by winding the electrode foil, an electrode foil manufacturing method, and a winding capacitor manufacturing method are provided. An electrode foil is formed of a belt-like foil, and has a surface enlarged part, a core part, and a plurality of separation parts. The surface enlarged part is formed on the surface of the foil, and the core part is a part remained when excluding the surface enlarged part within the foil. The separation part extends in a width direction of the belt in the surface enlarged part, dividing the surface enlarged part. The plurality of separation parts share bending stress when the electrode foil is wound, preventing concentration of stress.

Abstract: A multilayer ceramic electronic component includes a ceramic body in which dielectric layers and internal electrodes are alternately disposed. Ceramic-metal compound layers are disposed on interfaces between the internal electrodes and the dielectric layers. Additionally, in some examples, spaces between adjacent internal electrodes are fully occupied by the dielectric layers and the dielectric layers contain a ceramic-metal compound containing metal particle. The ceramic-metal compound layer may have an embossing type configuration or a dendrite type configuration.

Abstract: A method of coating film in a roll. A film is wound into a roll with gaps between the layers of the film in the roll. A fluid is forced through the roll such that the fluid deposits a coating on at least one side of the film.

Abstract: A method of manufacturing a multilayer ceramic electronic component includes forming external electrodes on end surfaces of a ceramic body, and more particularly, to forming external electrodes by attaching a sheet for forming an external electrode on a ceramic body. A multilayer ceramic electronic component thus formed has external electrodes with a thin and uniform thickness.

Abstract: The invention relates to an electronic component. The electronic component 2 has an electrical assembly 3 having two electrical connections 4, 5 that are each formed on opposing faces of the assembly. For each connection 4, 5, the component has at least one electrically conductive connection element 9, 10 having a mounting foot 14, 15 for connection to a circuit carrier 22. According to the invention, the connection element 8, 9 has at least two metal layers 10, 11, 12, 13 at least on one section, wherein the metal layers are each formed from different metals and integrally connected to one another. Preferably, one metal layer 12, 13 from the metal layers has greater thermal conductivity than the other metal layer 10, 11.

Abstract: Embodiments of the present disclosure provide methods and apparatus for providing feed forward equalization to a communication line by providing a resistance and a capacitance to the communication line. The method includes determining the resistance based on a desired value of feed forward equalization to provide to a communication line, determining the capacitance based on the desired value of feed forward equalization to provide to the communication line, providing a layer of resistive material between a first conductor and a second conductor of the communication line, wherein a dimension of the layer of resistive material is determined based on the determined resistance and providing a layer of dielectric material between the first conductor and the second conductor, wherein a dimension of the layer of dielectric material is determined based on the determined capacitance.

Abstract: A capacitor assembly is providing for adapting a replacement capacitor to an existing circuit board layout. The capacitor assembly has an adapter with a plate and the replacement capacitor affixed thereto, and the adapter has terminals which are connected to the leads of the replacement capacitor. The adapter further has leads, such as pins, extending downward from the plate, to electrically connect the capacitor assembly to the circuit board.

Abstract: A composite sheet includes a ceramic green sheet having a lengthwise direction and a conductor film printed on the ceramic green sheet. The conductor film has a shape that has a longitudinal dimension extending in the lengthwise direction and a lateral dimension perpendicular or substantially perpendicular to the longitudinal direction. The conductor film includes a plurality of thickness-varied regions arranged in a row or a plurality of rows extending in the lengthwise direction while being dispersed in the lengthwise direction. The thickness-varied regions have a thickness that is different from a thickness of a portion of the conductor film excluding the thickness-varied regions.

Abstract: A transfer head array includes a base substrate, an interlayer isolation layer, plural transfer heads, and at least one shielding layer. The interlayer isolation layer is disposed on the base substrate, and the interlayer isolation layer has a flat top surface facing away from the base substrate. The transfer heads are arranged on the interlayer isolation layer. The shielding layer is disposed in the interlayer isolation layer.

Abstract: The present disclosure relates to a telecommunications jack including a housing having a port for receiving a plug. The jack also includes a plurality of contact springs adapted to make electrical contact with the plug when the plug is inserted into the port of the housing, and a plurality of wire termination contacts for terminating wires to the jack. The jack further includes a circuit board that electrically connects the contact springs to the wire termination contacts. The circuit board includes a multi-zone crosstalk compensation arrangement for reducing crosstalk at the jack.

Abstract: An aerosol delivery device is provided. The aerosol delivery device comprises a control component and a humidity sensor. The humidity sensor is configured to measure a property thereof that is variable with relative humidity in an environment of the aerosol delivery device to which the humidity sensor is exposed. The humidity sensor is also configured to generate a corresponding signal that indicates a value of the property from which the relative humidity is calculable. The control component, or the humidity sensor, is configured to calculate the relative humidity from the value indicated by the corresponding signal, and control operation of at least one functional element of the aerosol delivery device based on the relative humidity so calculated, including output of the relative humidity for presentation by a display.

Abstract: A ceramic electronic component includes a body, a first external electrode, and a second external electrode. The body includes a first end surface and a second end surface that face each other, surfaces each extending between the first end surface and the second end surface, an outer edge that is provided along the surfaces and includes recesses, the recesses extending from the first end surface and the second end surface along ridges of the surfaces, and a functional unit that is disposed inward relative to the outer edge. The first external electrode and the second external electrode respectively cover the first end surface and the second end surface and extend to come close to each other from the first end surface and the second end surface along the surfaces and the recesses.

Abstract: Disclosed herein is a multilayer capacitor comprising: a laminate in which a plurality of first sheets and second sheets are alternately laminated, wherein the first sheets and the second sheets are disposed in a direction perpendicular to a mounting surface; a first inner electrode formed on the first sheets, wherein the first electrode is exposed through upper, lower, and first lateral surfaces of the laminate; a second inner electrode that is formed on the second sheets and has a horizontally symmetrical shape with respect to the first inner electrode; a sealing portion encapsulating the first and second inner electrodes exposed through two lateral surfaces of the laminate; and an external electrode that is electrically connected to the first and second inner electrodes exposed through the upper and lower surfaces of the laminate.

Abstract: A ceramic-wound-capacitor includes a first-electrically-conductive-layer, a dielectric-layer, a second-electrically-conductive-layer, and a protective-coating. The dielectric-layer is formed of lead-lanthanum-zirconium-titanate (PLZT). The protective-coating has a thickness of less than ten micrometers (10 ?m) and provides electrical isolation between the first-electrically-conductive-layer and the second-electrically-conductive-layer of the ceramic-wound-capacitor.

Abstract: The invention is directed to a method of bonding a hermetically sealed electronics package to an electrode or a flexible circuit and the resulting electronics package that is suitable for implantation in living tissue, for a retinal or cortical electrode array to enable restoration of sight to certain non-sighted individuals. The hermetically sealed electronics package is directly bonded to the flex circuit or electrode by electroplating a biocompatible material, such as platinum or gold, effectively forming a plated rivet-shaped connection, which bonds the flex circuit to the electronics package. The resulting electronic device is biocompatible and is suitable for long-term implantation in living tissue.

Abstract: A capacitor with a first voltage layer guided around the capacitor structure, so that the first voltage layer and the second planar electrode of the capacitor form an overlap region in which the first voltage layer and the second planar electrode are arranged, parallel to one another and separated from one another by a gap, on a base side of the capacitor directly one above the other, wherein the first voltage layer is arranged on an outer side of the second planar electrode, which outer side is averted from the capacitor structure).

Abstract: A multi-layer ceramic capacitor includes: a body, a first external electrode, and a second external electrode. The body includes a first end surface and a second end surface that face each other, a side surface that extends between the first end surface and the second end surface, a first recess that extends along a first ridge of the first end surface and the side surface, a second recess that extends along a second ridge of the second end surface and the side surface, a first internal electrode that is drawn to the first end surface and the first recess, and a second internal electrode that faces the first internal electrode and is drawn to the second end surface and the second recess. The first external electrode covers the body from the first end surface. The second external electrode covers the body from the second end surface.

Abstract: An integrated circuit includes pads formed on a back end of the line surface, and decoupling capacitor stacks monolithically formed about the pads. Solder balls are formed on the pads and connect to metal layers within the decoupling capacitor stacks to reduce noise and voltage spikes between the solder balls.

Abstract: An improved solid electrolytic capacitor, and method of making the solid electrolytic capacitor, is described. The solid electrolytic capacitor comprises a pressed powder anode and a braided lead wire extending from the anode. A dielectric is on the anode and a cathode is on the dielectric.

Abstract: The invention provides a process for making ceramic film capacitors, the process comprising supplying a flexible substrate, depositing a first electrode on a first region of the flexible substrate, wherein the first electrode defines a first thickness, overlaying the first electrode with a dielectric film; and depositing a second electrode on the ceramic film, wherein the second electrode defines a second thickness. Also provided is a capacitor comprising flexible substrate, a first electrode deposited on said flexible substrate, a dielectric overlaying the first electrode; and a second electrode deposited on said dielectric.

Abstract: An electronic component includes a body including a capacitance portion having dielectric layers formed of a dielectric material, internal electrodes and a cover portion covering at least one surface of the capacitance portion, the cover portion including cover layers formed of a dielectric material, the cover portion including a plurality of first and second cover layers that are stacked alternately, and an external electrode disposed on the body, the external electrode connected to the internal electrodes, wherein average diameters of dielectric grains included in the first and second cover layers are different from each other.

Abstract: A high density energy storage system including a giant-colossal dielectric thin film material electrically insulating between two electrodes configured to have increased overlapping surface area.

Abstract: An AIMD includes a conductive housing, an electrically conductive ferrule with an insulator hermetically sealing the ferrule opening. A conductive pathway is hermetically sealed and disposed through the insulator. A filter capacitor is disposed on a circuit board within the housing and has a dielectric body supporting at least two active and two ground electrode plates interleaved, wherein the at least two active electrode plates are electrically connected to the conductive pathway on the device side, and the at least two ground electrode plates are electrically coupled to either the ferrule and/or the conductive housing. The dielectric body has a dielectric constant less than 1000 and a capacitance of between 10 and 20,000 picofarads. The filter capacitor is configured for EMI filtering of MRI high RF pulsed power by a low ESR, wherein the ESR of the filter capacitor at an MRI RF pulsed frequency or range of frequencies is less than 2.0 ohms.

Abstract: A multilayer ceramic capacitor includes a ceramic body which is unlikely to be cracked. A dimension in a length direction L is referred to as L0. A distance in the length direction L is referred to as L1 between an end in the length direction L of a portion of a first external electrode located on a first principal surface and an end of a second internal electrode closer to the first end surface. The ratio L1/L0 is about 0.05 to about 0.35.

Abstract: Provided is a surface mount resistor that can be stably mounted without the need for lead wires to be to flattened. The surface mount resistor includes a first resistive element and a second resistive element arranged in parallel, the first resistive element having first lead wires at opposite ends thereof, and the second resistive element having second lead wires at opposite ends thereof. The first resistive element and the second resistive element are integrated by being covered with a sheath. The first lead wires and the second lead wires are arranged such that they protrude outward in a direction of an axis beyond the sheath. The first lead wires and the second lead wires are bent alongside surfaces and a bottom surface of the sheath.

Abstract: A method of forming a stacked electronic component, and an electronic component formed by the method wherein the method includes: providing a multiplicity of electronic components wherein each electronic component comprises a first external termination and a second external termination; providing a first lead frame plate and a second lead frame plate wherein the first lead frame plate and the second lead frame plate comprises barbs and leads; providing a molded case comprising a cavity and a bottom; and forming a sandwich of electronic components in an array between the first lead frame plate and the second lead frame plate with the barbs protruding towards the electronic components and the leads extending through the bottom.

Abstract: A three terminal capacitor includes a capacitor element including first through sixth surfaces, first-side and second-side outer electrodes, a center outer electrode between the first-side and second-side outer electrodes, and conductor layers. The conductor layers include a pair of outermost conductor layers that are respectively nearest to the fifth and sixth surfaces, and thicknesses of the pair of outermost conductor layers are greater than a thickness of a center conductor layer nearest to a center of the capacitor element in a width direction.

Abstract: A multilayer ceramic capacitor includes: a pair of external electrodes; a first internal electrode containing a base metal and coupled to one of the external electrodes; a dielectric layer stacked on the first internal electrode and containing a ceramic material and the base metal; and a second internal electrode stacked on the dielectric layer, containing the base metal, and coupled to another one of the external electrodes, wherein a concentration of the base metal in each of five regions, which are equally divided regions of a region between locations 50 nm away from the first and second internal electrodes in a stacking direction between the first and second internal electrodes, is within ±20% of an average of the concentrations of the base metal in the five regions, and the dielectric layer has a thickness of 0.6 ?m or less.

Abstract: A multilayer ceramic electronic component and a method of manufacturing the same are provided. The multilayer ceramic electronic component includes a ceramic body including dielectric layers, and internal electrodes alternately disposed on the dielectric layers and containing a ceramic additive disposed therein; and external electrodes formed on an outer portion of the ceramic body and electrically connected to the internal electrodes. The ceramic additive is disposed in the internal electrode at a position spaced apart from a boundary between the internal electrode and the dielectric layer by a predetermined distance.

Abstract: A capacitor includes a pair of electrodes and a metalized dielectric layer disposed between the pair of electrodes, in which the metalized dielectric layer has a plurality of metal aggregates distributed within a dielectric material. The distribution is such that a volume fraction of metal in the metalized dielectric layer is at least about 30%. Meanwhile, the plurality of metal aggregates are separated from one another by the dielectric material. A method for forming a metal-dielectric composite may include coating a plurality of dielectric particles with a metal to form a plurality of metal-coated dielectric particles and sintering the plurality of metal-coated dielectric particles at a temperature of at least about 750° C. to about 950° C. to transform the metal coatings into discrete, separated metal aggregates.

Abstract: A sound transducer structure includes a membrane and a counter electrode. The membrane includes a first main surface in a sound transducing region made of a membrane material, and an edge region. The counter electrode includes a second main surface arranged in parallel to the first main surface of the membrane on a side of a free volume opposite the first main surface of the membrane. A plurality of elevations extend in the sound transducing region from the second main surface of the counter electrode into the free volume. The membrane and the counter electrode are arranged to provide a capacity therebetween. The membrane comprises a corrugation groove extending in the sound transducing region from the first main surface of the membrane into the free volume.

Abstract: A resuscitator has a patient airway interface device, a bag, a flow passage coupled between the bag and patient airway interface device, and a sensor assembly. The patient airway interface device may be a mask or an endotracheal tube. The sensor assembly has a display, at least one sensor coupled to the flow passage and configured to provide a measurement of at least one parameter, and a processor coupled to the display and the at least one sensor. The processor is configured to receive the measurement from the sensor and provide information on the display based on the received measurement. The information may include a current breath rate, a pressure-vs-time curve, and guidance to the user to assist in achieving a target breath rate.

Abstract: A multilayer ceramic capacitor includes an external electrode that is unlikely to be peeled. First and second external electrodes each include base layers provided over a ceramic body and including a metal and glass, and Cu plated layers provided over the base layers. The multilayer ceramic capacitor includes a reactive layer. The reactive layer contains about 5 atomic % to about 15 atomic % of Ti, about 5 atomic % to about 15 atomic % of Si, and about 2 atomic % to about 10 atomic % of V.

Abstract: The electronic device sheet comprises a pair of electrode layers, a dielectric layer provided between the pair of electrode layers, and one or more insulation patch members provided on one of principal surfaces of the dielectric layer, wherein the number of the insulation patch members is 1 or more and 1000 or less per 1 cm2 of the principal surface, and the total area of the insulation patch members is 10 ?m2 or larger and 3 mm2 or smaller per 1 cm2 of the principal surface.

Abstract: A sachet includes a first wing made of a flexible material and having a first perimeter region circumscribing a first central region; a second wing made of the flexible material; a hinge connecting the first and second wings along a common boundary; an adhesive material applied to the perimeter region on the first wing; a first electrically conducting electrode formed on the first wing within the central region of the perimeter region; a second electrically conducting electrode formed on the second wing in a region that is opposed to and in alignment with the first contact area on the first wing; an array of contact pads formed on at least one of the first and second wings; first and second conducting traces electrically connecting first and second groups of one or more contact pads among the array of contact pads to the first and second electrodes, respectively.

Abstract: A fabrication method of an acoustic wave device includes: forming a metal layer between regions that are located on a piezoelectric substrate and in which acoustic wave chips are to be formed, at least a part of a region of the metal layer extending to an extension direction of a dicing line for separating the acoustic wave chips; and scanning the dicing line of the piezoelectric substrate by a laser beam so that the at least a part of the region of the metal layer is not irradiated with the laser beam.