Abstract: A hand-held device having a housing and a processor disposed within the housing, includes a camera and a temperature sensing element having an adjustable field of view. The camera is configured to generate an image of an object and to permit the user to frame the image at a portion of the object to determine the temperature of the framed portion. The temperature sensing element includes a plurality of temperature sensors and the processor is configured to select ones of the plurality of sensors to produce a field of view (FOV) of the temperature sensing element that is less than or equal to the frame in the image. The selected sensors are activated to generate signals corresponding to the temperature of the object in the FOV and the processor is configured to determine a sensed temperature based on the sensor signals.

Abstract: A micromechanical functional apparatus, particularly a loudspeaker apparatus, includes a substrate, at least one circuit chip mounted on the substrate, and an enveloping package in which the circuit chip is packaged. The functional apparatus further includes a micromechanical functional arrangement, particularly a loudspeaker arrangement having a plurality of micromechanical loudspeakers, which is mounted on the enveloping package. A covering device is mounted above the micromechanical functional arrangement, particularly the loudspeaker arrangement, opposite the enveloping package. A method is implemented to manufacture the micromechanical functional apparatus.

Abstract: A microelectromechanical system (MEMS) device includes a high density getter. The high density getter includes a silicon surface area formed by porosification or by the formation of trenches within a sealed cavity of the device. The silicon surface area includes a deposition of titanium or other gettering material to reduce the amount of gas present in the sealed chamber such that a low pressure chamber is formed. The high density getter is used in bolometers and gyroscopes but is not limited to those devices.

Abstract: In one embodiment, a sensor includes a rigid wafer outer body, a first cavity located within the rigid wafer outer body, a first spring supported by the rigid wafer outer body and extending into the first cavity, a second spring supported by the rigid wafer outer body and extending into the first cavity, and a first sensor structure supported by the first spring and the second spring within the first cavity.

Abstract: A resistive temperature sensor (thermistor) for a microelectromechanical system (MEMS) device provides local temperatures of MEMS sensors and other MEMS devices for temperature compensation. Local accurate temperatures of the sensors and other devices provide for temperature compensation of such sensors or devices. By incorporating the thermistor structure into a MEMS device, an accurate temperature is sensed and measured adjacent to or within the structural layers of the device. In one embodiment, the thermistor is located within a few micrometers of the primary device.

Abstract: A portable thermal imaging system includes a portable housing configured to be carried by a user, a bolometer sensor assembly supported by the housing and including an array of thermal sensor elements and at least one plasmonic lens, a memory including program instructions, and a processor operably connected to the memory and to the sensor, and configured to execute the program instructions to obtain signals from each of a selected set of thermal sensor elements of the array of thermal sensor elements, assign each of the obtained signals with a respective color data associated with a temperature of a sensed object, and render the color data.

Abstract: A method for fabricating a semiconductor device includes patterning a sacrificial layer on a substrate to define a bolometer, with trenches being formed in the sacrificial layer to define anchors for the bolometer, the trenches extending through the sacrificial layer and exposing conductive elements at the bottom of the trenches. A thin titanium nitride layer is then deposited on the sacrificial layer and within the trenches. The titanium nitride layer is configured to form a structural support for the bolometer and to provide an electrical connection to the conductive elements on the substrate.

Abstract: A sensor device includes a first CMOS chip and a second CMOS chip with a first moving-gate transducer formed in the first CMOS chip for implementing a first 3-axis inertial sensor and a second moving-gate transducer formed in the second CMOS chip for implementing a second 3-axis inertial sensor. An ASIC for evaluating the outputs of the first 3-axis inertial sensor and the second 3-axis inertial sensor is distributed between the first CMOS chip and the second CMOS chip.

Abstract: A Li-ion battery in one embodiment includes a lithium based compound in a cathode, a first porous silicon portion in an anode, and a layer of atomic layer deposited (ALD) alumina coating the first porous silicon portion and contacting the cathode.

Abstract: In one embodiment, a MEMS sensor includes a mirror and an absorber spaced apart from the mirror, the absorber including a plurality of spaced apart conductive legs defining a tortuous path across an area directly above the mirror.

Abstract: A microelectromechanical system (MEMS) device includes a high density getter. The high density getter includes a silicon surface area formed by porosification or by the formation of trenches within a sealed cavity of the device. The silicon surface area includes a deposition of titanium or other gettering material to reduce the amount of gas present in the sealed chamber such that a low pressure chamber is formed. The high density getter is used in bolometers and gyroscopes but is not limited to those devices.

Abstract: A method of fabricating a semiconductor device comprises forming a dielectric layer above a substrate, the dielectric layer including a fixed dielectric portion and a proof mass portion, forming a source region and a drain region in the substrate, forming a gate electrode in the proof mass portion, and releasing the proof mass portion, such that the proof mass portion is movable with respect to the fixed dielectric portion and the gate electrode is movable with the proof mass portion relative to the source region and the drain region.

Abstract: In one embodiment, a method of forming a MEMS device includes providing a silicon wafer with a base layer and an intermediate layer above an upper surface of the base layer. A first electrode is defined in the intermediate layer and an oxide portion is provided above an upper surface of the intermediate layer. A cap layer is provided on an upper surface of the oxide portion and a second electrode is defined in the cap layer. The method further includes etching the oxide portion to form a cavity such that when the second electrode and the cavity are projected onto the intermediate layer, the projected second electrode encompasses the projected cavity.

Abstract: A micromechanical functional apparatus, particularly a loudspeaker apparatus, includes a substrate having a top and an underside and at least one circuit chip mounted on the underside in a first cavity. The apparatus further includes a micromechanical functional arrangement, particularly a loudspeaker arrangement, having a plurality of micromechanical loudspeakers mounted on the top in a second cavity. A covering device is mounted above the micromechanical functional arrangement on the top. An appropriate method is implemented to manufacture the micromechanical functional apparatus.

Abstract: A microelectromechanical system (MEMS) microphone has a substrate including a backside trench, and a flexible membrane deposited on the substrate extending over the backside trench. The flexible membrane includes a first electrode. A silicon spacer layer is deposited on a perimeter portion of the flexible membrane. The spacer layer defines an acoustic chamber above the membrane and the backside trench. A silicon rich silicon nitride (SiN) backplate layer is deposited on top of the silicon spacer layer extending over the acoustic chamber. The backplate defines a plurality of opening into the acoustic chamber and includes a metallization that serves as a second electrode.

Abstract: A metamaterial includes a first continuous layer formed with a first material by atomic layer deposition (ALD), a first non-continuous layer formed with a second material by ALD on first upper surface portions of a first upper surface of the first continuous layer, and a second continuous layer formed with the first material by ALD on second upper surface portions of the first upper surface of the first continuous layer and on a second upper surface of the first non-continuous layer.

Abstract: In one embodiment, a method of deforming a MEMS structure includes providing a base layer, providing a first piezoelectric slab operably connected to a surface of the base layer, determining a desired deformation of the base layer, applying a first potential to a first electrode operably connected to the first piezoelectric slab, applying a second potential to a second electrode operably connected to the first piezoelectric slab, and deforming the base layer with the first piezoelectric slab using the applied first potential and the applied second potential based upon the determined desired deformation.

Abstract: A method of fabricating a semiconductor device includes forming an absorber on a substrate, and supporting a cap layer over the substrate to define a cavity between the substrate and the cap layer in which the absorber is located. The method further includes forming a lens layer on the cap layer. The lens layer is spaced apart from the cavity and defines a plurality of grooves and an opening located over the absorber.

Abstract: A system and method for forming a sensor device includes defining an in-plane electrode in a device layer of a silicon on insulator (SOI) wafer, forming an out-of-plane electrode in a silicon cap layer located above an upper surface of the device layer, depositing a silicide-forming metal on a top surface of the silicon cap layer, and annealing the deposited silicide-forming metal to form a silicide portion in the silicon cap layer.

Abstract: In one embodiment, A MEMS sensor assembly includes a substrate, a first sensor supported by the substrate and including a first absorber spaced apart from the substrate, and a second sensor supported by the substrate and including (i) a second absorber spaced apart from the substrate, and (ii) at least one thermal shorting portion integrally formed with the second absorber and extending downwardly from the second absorber to the substrate thereby thermally shorting the second absorber to the substrate.