Abstract: System and methods for silicon on insulator MEMS pressure sensors are provided. In one embodiment, a method comprises: applying a doping source to a silicon-on-insulator (SOI) silicon wafer having a sensor layer and an insulating layer comprising SiO2 material; doping the silicon wafer with Boron atoms from the doping source while controlling an injection energy of the doping to achieve a top-heavy ion penetration profile; and applying a heat source to diffuse the Boron atoms throughout the sensor layer of the SOI silicon wafer.

Abstract: A sensor system is adapted for use with an article of footwear and includes an insert member including a first layer and a second layer, a port connected to the insert and configured for communication with an electronic module, a plurality of force and/or compression sensors on the insert member, and a plurality of leads connecting the sensors to the port.

Abstract: Disclosed herein are contact sensors having a conductive composite material formed of a polymer and a conductive filler. In one particular aspect, the composite materials can include less than about 10 wt % conductive filler. The composite material of the contact sensors can have physical characteristics essentially identical to the polymer, while being electrically conductive with the electrical resistance proportional to the load on the sensor. Also disclosed herein are novel force/pressure sensors that include conductive polymer elements.

Abstract: A force-sensing device for measuring a traction- and/or pressure force load in a structure, for example, in a container-locking bolt is provided. The force-sensing device is constructed shaped like a rod and a sensor section detects expansions and/or compressions of the structure.

Abstract: An industrial roll includes: a substantially cylindrical core having an outer surface; a polymeric cover circumferentially overlying the core outer surface; and a sensing system. The sensing system includes: a first signal carrying member serially connecting a first set of sensors; a second signal carrying member serially connecting a second set of sensors; and a signal processing unit operatively associated with the first and second signal carrying members and configured to selectively monitor the signals provided by the first and second set of sensors.

Abstract: A force sensor includes: a planar piezoelectric member whose impedance varies according to an impressing force exerted from an outside; a pair of electrode patterns film-formed on both surfaces of the piezoelectric member; a wiring pattern that is film-formed integrally with the pair of electrode patterns, and connected to the pair of electrode patterns; a power feeding side coil that is provided without contact with the pair of electrode patterns, and connected to an alternating-current source; and a detector that detects variation in impedance of the piezoelectric member, as the impressing force, wherein at least a part or the entirety of one electrode pattern between the pair of electrode patterns is formed volutely extending from the wiring pattern, and is a coil pattern electromagnetically coupled with the power feeding side coil.

Abstract: A sensor element includes a piezoelectric substrate made of a trigonal single crystal and an electrode arranged on the piezoelectric substrate. The substrate surface of the piezoelectric substrate includes an electrical axis of crystal axes. An angle ? formed by the substrate surface and a plane including the electrical axis and an optical axis of the crystal axes is 0°<?<20°.

Abstract: An apparatus for sensing a force. The apparatus includes a nanostructure being suitable for emitting electrons and a collector. The collector is proximately positioned with respect to the nanostructure so as to receive the emitted electrons and define a gap therebetween. The gap is partially dependent upon the applied force and the emission and reception of the electrons are indicative of the applied force.

Abstract: There are provided a pressure sensor and an input device including the same. The pressure sensor includes: a first conductive substrate having flexibility; a second conductive substrate disposed in parallel with the first conductive substrate; and an elastic dielectric layer disposed between the first and second conductive substrates and including a plurality of structures having a pyramidal shape, wherein the structures of the elastic dielectric layer are deformed according to pressure applied to the first conductive substrate to generate a change in capacitance between the first and second conductive substrates. Accordingly, the pressure sensor is capable of efficiently sensing a small amount of pressure.

Abstract: A sensor concept for capacitive pressure measurement yields reliable measurement results and is for aggressive particle-bearing measuring environments. This sensor element is a micromechanical sensor element, whose structural elements are implemented in a layered structure. The sensor element includes two pressure connections separated from each other, a deflectable carrier element for at least one deflectable measuring electrode, and at least one stationary counter electrode for the measuring electrode. The carrier element spans a closed cavity in the layered structure. The carrier element is spanned by a cap structure, and is suspended on the cap structure via a suspension web functioning as a rocker bearing. The two pressure connections are connected to the carrier element's top side which is divided by the suspension web into two separated pressure connection zones. The measuring electrode is on the carrier element's underside and the counter electrode is on the cavity's opposite wall.

Abstract: A bearing device for bearing a shaft having a bearing, a supporting structure for supporting the bearing and at least on piezoresistive sensor incorporated in the supporting structure in an integrated manner which is arranged in the flux region of the bearing apparatus is provided. The electrical resistance of the sensor is influenced by the vertical force of the bearing having effect on the sensor such that the vertical force of the bearing may be electrically tapped on the sensor. A corresponding method for determining the static and/or dynamic vertical bearing forces of the shaft bearing of a shaft and a rotor system for determining the vertical bearing force of a shaft bearing are provided.

Abstract: One or more techniques and/or systems are disclosed for generating a linearized pressure sensor pattern for a pressure sensor. Force may be applied to a pressure sensor sample, comprising the pressure sensor without conductors. A patch, comprising an area of contact between a top and bottom surface of the sensor sample, can be measured, which corresponds to the applied force. Patch measurements can be made for respective applied force intervals, resulting in one or more indications of applied force, respectively corresponding to an indication of a patch measurement. The linearized pressure sensor pattern can be generated using the one or more force indications and corresponding patch measurement indications.

Abstract: The invention makes it possible to determine a force vector that is applied to a tip of a minimally invasive surgical instrument. The force acts upon the housing, is directed to the base, and causes a deformation there in special beam structures. Said deformation is detected by tension-sensitive/extension-sensitive resistors whose changes are a measure for the applied force vector. The inventive measuring element comprises special mounting elements so as to be integrated into tube-type instruments such as guiding wires, fastening zones for additional components, an overload protection, and a head shape that is adapted to the treatment process.

Abstract: A sensing material for use in a sensor is disclosed. Such a sensing material includes a polymer base and a piezoresistive nanocomposite embedded into the polymer base in a continuous pattern. The nanocomposite comprises a polymer matrix and a plurality of conductive nanofillers suspended in the matrix. The conductive nanofillers may be one or a combination of nanotubes, nanowires, particles and flakes. The density of the plurality of nanofillers is such that the nanocomposite exhibits conductivity suitable for electronic and sensor applications.

Abstract: According to aspects of the embodiments, an apparatus and method is proposed to detect nip width by use of at least one piezoelectric (PZT) crystal embedded into a roll at both the inboard and outboard ends. A piezoelectric (PZT) crystal generates a charge when subjected to a load and when the load is released. The PZT generate signal is channeled to the ends of the roller such as with a brush contact to be processed and used within machine control. The duration measure from application and released of the load is indicative of the dwell time and the amplitude PZT generate signal is a function of the pressure. The time and amplitude of the PZT signal can be calibrated to correlate directly to nip width or pressure and tracked in machine control.

Abstract: A sensor array for sensing the magnitude and position of a force in a first direction is provided. The sensor array includes a compressible layer, an electrically grounded layer, and an electrically active layer comprising a plurality of transmitter electrodes and a plurality of receiver electrodes. Each of the transmitter electrodes is configured to capacitively couple to a receiver electrode, and the compressible layer is positioned between the electrically grounded layer the electrically active layer.

Abstract: In various embodiments, a dosimeter is employed to passively record a peak pressure (e.g., a peak blast pressure) and/or a maximum acceleration experienced by the dosimeter.

Abstract: A flexible pressure sensor has a first set of substantially parallel conductors in the x direction, a second set of substantially parallel conductors in the y direction, and a composite material disposed between the first set and second set of conductors. The composite material is capable of returning to substantially its original dimensions on release of pressure. The composite material includes conductive particles at least partially embedded in an elastomeric layer that have no relative orientation and are disposed within the elastomeric layer for electrically connecting the first set and second set of conductors in the z direction under application of sufficient pressure there between.

Abstract: A pressure detection unit includes a first substrate and a second substrate which are disposed in opposition to each other and subject to load from the outside, a pressure detection portion having a pair of electrodes provided between the first substrate and the second substrate and in the first substrate and the second substrate, and electrically conductive pressure-sensitive ink disposed between the pair of electrodes and having electrical characteristics which varies according to the load, and a load transmission member disposed between the first substrate and the pressure detection portion and/or between the second substrate and the pressure detection portion, the load transmission member transmitting the load to the pressure detection portion in a concentrated manner.

Abstract: Pressure-sensitive amplifier stage comprising four unipolar pressure-sensor transistors each including a piezoresistive current path. The pressure-sensor transistors are connected as a pressure-measuring bridge having two bridge legs each comprising first and second pressure-sensor transistors which are connected in series. Two unipolar control transistors each has a control terminal and a current path arranged between a further first and a further second terminal. The respective first and second terminals of the two control transistors are connected in pairs, and the control terminals each is connected to a node between the pressure-sensor transistors. The interconnected second terminals are connected to the control terminals of the second pressure-sensor transistors of the two bridge legs.

Abstract: The present invention is directed to novel contact sensors. The contact sensors of the invention include a conductive composite material formed of a polymer and a conductive filler. In one particular embodiment, the composite materials can include less than about 10 wt % conductive filler. Thus, the composite material of the contact sensors can have physical characteristics essentially identical to the polymer, while being electrically conductive with the electrical resistance proportional to the load on the sensor. If desired, the sensors can be formed of the same polymeric material as the bearing that is being examined. The sensors can provide real time dynamic contact information for joint members under conditions expected during use. In one particular embodiment, the sensors can be used to examine dynamic wear characteristics of artificial joint bearings such as artificial knee, hip, or shoulder bearings.

Abstract: According to aspects of the embodiments, an apparatus and method is proposed to detect nip width by use of at least one piezoelectric (PZT) crystal embedded into a roll at both the inboard and outboard ends. A piezoelectric (PZT) crystal generates a charge when subjected to a load and when the load is released. The PZT generate signal is channeled to the ends of the roller such as with a brush contact to be processed and used within machine control. The duration measure from application and released of the load is indicative of the dwell time and the amplitude PZT generate signal is a function of the pressure. The time and amplitude of the PZT signal can be calibrated to correlate directly to nip width or pressure and tracked in machine control.

Abstract: An input device that is capable of sensing how hard a user is pressing when contacted is disclosed. The input device includes a pressure sensing unit generating an electrical signal in accordance with pressure applied on one surface of the pressure sensing unit and a fixed resistance making a parallel electrical connection with the pressure sensing unit. Thus, not only can the input device receive a form of information that is changed proportionally in accordance with the pressure applied by the user, but the deviation in electrical characteristics that may occur during the manufacturing of different products can also be reduced. Also, by adjusting the resistance value of the fixed resistance, the sum of the resistance values by the parallel connection between the fixed resistance and the pressure sensitive resistance can be adjusted so that the electrical signal generated by the input device through pressing can be adjusted.

Abstract: Two electrode wires longitudinally provided along the inner surface of an elastic insulating member having a hollow portion are exposed from said elastic insulating member, the resistive element comprising a resistor body and the resistive element's lead wires is formed into a U-letter shape, said two electrode wires exposed from said elastic insulating member and said resistive element's lead wires are electrically connected via one metal plate, and a portion wherein one of said two electrode wires and one of the lead wires extending from both ends of said resistor body are electrically connected and a portion wherein the other one of said two electrode wires and the other one of the lead wires extending from both ends of said resistor body are electrically connected are separated by cutting said one metal plate.

Abstract: A method for manufacturing a piezoresistive material, a piezoresistive composition and a pressure sensor device are provided. The piezoresistive composition includes a conductive carbon material, a solvent, a dispersive agent, an unsaturated polyester and a crosslinking agent. The conductive carbon material is selected from a group consisting of multi-wall nanotube, single-wall carbon nanotube, carbon nanocapsule, graphene, graphite nanoflake, carbon black, and a combination thereof. The solvent is selected from a group consisting of ethyl acetate, butyl acetate, hexane, propylene glycol mono-methyl ether acetate and a combination thereof. The dispersive agent includes block polymer solution with functional groups providing the affinity. The unsaturated polyester is selected from a group consisting of an ortho-phthalic type unsaturated polyester, an iso-phthalic type unsaturated polyester, and a combination thereof.

Abstract: A piezoelectric sensor for bending moment measurements has measuring elements separating at their axes and electrically connecting both halves with their opposing directions of polarization. Such a sensor, mounted with its axis on the neutral bending axis of a machine structure, thus measures concurrently both tension and compression of the machine on both sides of the axis thereof.

Abstract: A system for locating impacts comprises at least one array of a plurality of carbon nanotubes, each carbon nanotube operable to emit electrical activity when compressed. The system also comprises at least one sensor coupled to the at least one array configured to detect emitted electrical activity from the plurality of carbon nanotubes. Furthermore, a computer is configured to determine the location of an impact on the at least one array in response to the detected emitted electrical activity from the plurality of carbon nanotubes.

Abstract: An occupant sensing system for a vehicle includes a pressure sensitive material installed in one or more pressure sensing zones in or around at least one vehicle seat. The pressure sensitive material of each zone is configured to provide an electrical signal to a controller when pressure is applied. The controller determines at least one of occupant presence, position, and classification based on the electrical signal. The pressure sensitive material has at least one of a variable resistance and a variable capacitance based on the amount or type of pressure that is applied to the material. The at least one of a variable resistance and a variable capacitance changes characteristics of the electrical signal.

Abstract: A sensor concept for capacitive pressure measurement yields reliable measurement results and is for aggressive particle-bearing measuring environments. This sensor element is a micromechanical sensor element, whose structural elements are implemented in a layered structure. The sensor element includes two pressure connections separated from each other, a deflectable carrier element for at least one deflectable measuring electrode, and at least one stationary counter electrode for the measuring electrode. The carrier element spans a closed cavity in the layered structure. The carrier element is spanned by a cap structure, and is suspended on the cap structure via a suspension web functioning as a rocker bearing. The two pressure connections are connected to the carrier element's top side which is divided by the suspension web into two separated pressure connection zones. The measuring electrode is on the carrier element's underside and the counter electrode is on the cavity's opposite wall.

Abstract: The present invention is directed to novel contact sensors. The contact sensors of the invention include a conductive composite material formed of a polymer and a conductive filler. In one particular embodiment, the composite materials can include less than about 10 wt % conductive filler. Thus, the composite material of the contact sensors can have physical characteristics essentially identical to the polymer, while being electrically conductive with the electrical resistance proportional to the load on the sensor. If desired, the sensors can be formed of the same polymeric material as the bearing that is being examined. The sensors can provide real time dynamic contact information for joint members under conditions expected during use. In one particular embodiment, the sensors can be used to examine dynamic wear characteristics of artificial joint bearings such as artificial knee, hip, or shoulder bearings.

Abstract: An apparatus for sensing a force. The apparatus includes a nanostructure being suitable for emitting electrons and a collector. The collector is proximately positioned with respect to the nanostructure so as to receive the emitted electrons and define a gap therebetween. The gap is partially dependent upon the applied force and the emission and reception of the electrons are indicative of the applied force.

Abstract: The invention relates to a load gauge, comprising at least two coils, which are fixed in relation to each other, for detecting the movement and/or the position of an electrically conductive and/or magnetic element that is movable relative to the coils and against the force of a spring device. Each coil is placed in a dedicated electrical measuring circuit.

Abstract: A force sensor apparatus and method of forming the same. The apparatus includes a force sense element that can be attached to a substrate. An actuator disposed in a hole formed within the cap is operably coupled to the force sense element for transferring force to the sense element in response to receiving a force from an external source. The force sense element is configured to sense the external force and generate an output signal representing the force. Preferably, one or more bond pads, associated with the force sense element and the substrate, can be electrically connected via wire bonding. A cover associated with an integrated flexible membrane can be mounted on the substrate in order to protect internal components associated with the force sensor apparatus from an external environment.

Abstract: An input device that is capable of sensing how hard a user is pressing when contacted is disclosed. The input device includes a pressure sensing unit generating an electrical signal in accordance with pressure applied on one surface of the pressure sensing unit and a fixed resistance making a parallel electrical connection with the pressure sensing unit. Thus, not only can the input device receive a form of information that is changed proportionally in accordance with the pressure applied by the user, but the deviation in electrical characteristics that may occur during the manufacturing of different products can also be reduced. Also, by adjusting the resistance value of the fixed resistance, the sum of the resistance values by the parallel connection between the fixed resistance and the pressure sensitive resistance can be adjusted so that the electrical signal generated by the input device through pressing can be adjusted.

Abstract: The present invention is directed to novel contact sensors. The contact sensors of the invention include a conductive composite material formed of a polymer and a conductive filler. In one particular embodiment, the composite materials can include less than about 10 wt % conductive filler. Thus, the composite material of the contact sensors can have physical characteristics essentially identical to the polymer, while being electrically conductive with the electrical resistance proportional to the load on the sensor. If desired, the sensors can be formed of the same polymeric material as the bearing that is being examined. The sensors can provide real time dynamic contact information for joint members under conditions expected during use. In one particular embodiment, the sensors can be used to examine dynamic wear characteristics of artificial joint bearings such as artificial knee, hip, or shoulder bearings.

Abstract: The invention makes it possible to determine a force vector that is applied to a tip of a minimally invasive surgical instrument. The force acts upon the housing, is directed to the base, and causes a deformation there in special beam structures. Said deformation is detected by means of tension-sensitive/extension-sensitive resistors whose changes are a measure for the applied force vector. The inventive measuring element comprises special mounting elements so as to be integrated into tube-type instruments such as guiding wires, fastening zones for additional components, an overload protection, and a head shape that is adapted to the treatment process.

Abstract: The invention relates to a pressure sensor which can be incorporated into textile products. The pressure sensor includes a multilayer thread having a pressure sensitive layer exhibiting a pressure-dependent electrical resistance, and a conductive layer in contact with the pressure sensitive layer. Further, the sensor includes conductive threads in contact with the multilayer thread.

Abstract: A detection device comprises a case formed by at least a first and second part able to move with respect to one another between a first and second operating position. Said device comprises an electric contact comprising at least two electric states, closed or open, each electric state being associated with one of the operating positions of the first and second parts, and securing means designed to fix said case onto an external support. Said securing means comprise locking means designed to perform holding of the two parts of the case in one of the two operating positions, fixing of the case onto the support by the securing means rendering the locking means inoperative.

Abstract: A system for locating impacts comprises at least one array of a plurality of carbon nanotubes, each carbon nanotube operable to emit electrical activity when compressed. The system also comprises at least one sensor coupled to the at least one array configured to detect emitted electrical activity from the plurality of carbon nanotubes. Furthermore, a computer is configured to determine the location of an impact on the at least one array in response to the detected emitted electrical activity from the plurality of carbon nanotubes.

Abstract: The ability of a person to grasp an object and at the same time to feel, as well as to determine mechanical and geometric parameters of the comprehended object, makes him or her irreplaceable for many tasks, i.e. in production or in surgery. The translation of this ability into a technological system has often failed up to now due to lack of special adjusted sensors. The object of this invention is a sensory device, which fulfills the requirements for a tactile sensor system and at the same time affords a cost-effective and simple manufacturing alternative to other sensor principles. The layer structure of the sensor element is so constructed that by effect of an external force of the current by a resistive layer a path is disposed to narrowing or enlargement. The voltage drop over this resistive layer is dependent upon the acting external force and serves as signal sensor.

Abstract: Disclosed is a tactile sensory system consisting of set of sensors that work by measuring impedance among plurality of electrodes. The electrodes are deployed on a substantially rigid structure that is protected form the direct contact with external objects by overlying deformable structures. These mechanical structures have similarities to the biological relationships among the distal phalanx, overlying finger pulp and covering skin and nail. Signal information is extracted form these sensors that is related to canonical physical representations used to describe stimuli to be sensed.

Abstract: A force sensor (200) and nanoidenation system (300) using such force sensor (200), wherein the force sensor (200) comprise a movable membrane (207) attached to a fixed bulk structure (210) with springs (201, 202, 203, 204) formed between the membrane (207) and bulk structure (210); the springs (201, 202, 203, 204) may be provided two on each side of a rectangular membrane(207) and each in the form of a U-shape with displacing elements (801) formed perpendicular to each open end of each U-shaped spring (800). The force sensor further comprises electrodes (206) for detecting capacitive changes between the movable membrane (207) and the electrodes (206) in order to measure a movement in relation to an applied force. The membrane (207) further comprises a probe holding structure (214) for providing a solution for interchangeable probes (211).

Abstract: The present invention relates to a sensor capable of sensing temperature or force applied by a user. According to an aspect of the present invention, the tactile sensor includes a polymer layer having a concave portion and a membrane on a lower portion, wherein the membrane is formed by a concave portion, a resistant layer formed on a part of the polymer layer, and a conduction layer formed around the resistant layer. According to another aspect of the present invention, the tactile sensor includes a first polymer layer, a resistant layer formed on a part of the first polymer layer, a conduction layer formed around the resistant layer, a second polymer layer provided over the conduction layer and having a concave portion formed therein, and a base layer connected to the second polymer layer.

Abstract: A force measuring apparatus includes first fixed electrodes disposed in one direction in one plane so as to be distant from each other; second fixed electrodes disposed in the one direction in a plane opposed to the one plane, so as to be distant from each other and opposed to the respective first fixed electrodes; and movable electrodes movable in the one direction. The apparatus further includes a force receiving portion to receive an external force and thereby move the movable electrodes in the one direction so as to change the overlapped area between each first fixed electrode and the corresponding movable electrode and the overlapped area between each second fixed electrode and the corresponding movable electrode. The apparatus measures the magnitude of the force applied to the force receiving portion based on the changes in the capacitance values of the capacitance elements.

Abstract: A piezoelectric sensor for bending moment measurements has measuring elements separating at their axes and electrically connecting both halves with their opposing directions of polarization. Such a sensor, mounted with its axis on the neutral bending axis of a machine structure, thus measures concurrently both tension and compression of the machine on both sides of the axis thereof.

Abstract: A portable electronic device includes a housing, a display device exposed by the housing, an input device for receiving user-input, a plurality of sensors on the housing for detecting touches on the portable electronic device, and functional components housed in the housing. The functional components include a memory device and a processor operably connected to the sensors, the display device the input device, and the memory device.

Abstract: Grounded, circular movable electrode and divided electrodes, formed on a surface of a circular printed board, are opposed to each other via a double-face tape, functioning also as a spacer, with a slight gap interposed therebetween. As a pad is struck with a stick, the gap between the movable electrode and the divided electrodes changes so that capacitance between the movable electrode and the divided electrodes changes, in response to which signals are output from the divided electrodes. The divided electrodes are sandwiched between the grounded movable electrode and a grounded shielded electrode and thus are not influenced from external disturbances.

Abstract: A system for preloading piezoelectric actuators includes a fixture, a preloading mechanism configured to apply a mechanical force to a piezoelectric element supported by the fixture, and a sensor configured to sense an electrical property induced by the mechanical force in an electrical circuit having the piezoelectric element therein. A control device is coupled with the sensor and configured to generate a signal based on the sensed electrical property. A method of setting or testing preload includes applying a mechanical force to a piezoelectric element, and correlating an electrical property induced by the mechanical force with a magnitude of the mechanical force. Closed loop control allows preload to be set highly accurately.

Abstract: Magnetic or electric field sensors are mounted against a material surface and used for stress, strain, and load monitoring of rotating components such as vehicle drive trains. The stationary sensors are mounted at multiple locations around the component and used assess the stress on the component at multiple rotational positions. The sensor response is typically converted into a material property, such as magnetic permeability or electrical conductivity, which accounts for any coating thickness that may be present between the sensor and mounting surface. The sensors are not in direct contact with the rotating component and are typically mounted on an annular material or ring that encircles the rotating component. Measurements of the annular material properties, such as the stress, are related to the stress on the rotating component and discrete features on the component.

Abstract: The invention relates to a force sensor having a layer sequence for determining a force acting on the layer sequence along a predefined force axis. The layer sequence includes, arranged successively in a vertical direction, a first magnetic layer with a first magnetization direction, a separating layer and a second magnetic layer with a second magnetization direction. Here, the first magnetization direction is secured with respect to the layer sequence. The second magnetic layer has a magnetostriction constant that is different from zero and a uniaxial magnetic anisotropy with an anisotropy axis. The uniaxial magnetic anisotropy is generated using shape anisotropy. The second magnetization direction encloses an angle of more than 0° and less than 90° with the force axis in the quiescent state, and the anisotropy axis encloses an angle of more than 0° and less than 90° with the force axis.