Micro-electro-mechanical system (MEMS) devices are disclosed, including a MEMS device comprising a semiconductor die including integrated circuitry, a structure mounted on the semiconductor die and covering at least a portion of the circuitry, the structure defining a space between the structure and the at least a portion of the circuitry, and a transducer including a membrane, the transducer located outside of the space.

There is provided a dual-output microelectromechanical system (MEMS) resonator. The MEMS resonator can be operated selectively and concurrently in an in-plane mode of vibration and an out-of-plane mode of vibration to obtain respectively a first electrical signal having a first frequency, and a second electrical signal having a second frequency being less than the first frequency. The first and second electrical signals are mixed to obtain a third electrical signal having a third frequency, where the third frequency is proportional to a temperature of the MEMS resonator. The temperature is determined based on the third frequency. Values of the first and second frequencies can be adjusted based on the determined temperature to compensate for frequency deviations due to temperature deviations. There is also provided methods and systems for determining the temperature of the dual-output MEMS, for compensating the frequency, and a method of manufacturing the dual-output MEMS.

A micro-fluidic device is described. The micro-fluidic device includes a semiconductor substrate; at least one micro-reactor in the semiconductor substrate; one or more micro-fluidic channels in the semiconductor substrate, connected to the at least one micro-reactor; a cover layer bonded to the semiconductor substrate for sealing the one or more micro-fluidic channels; and at least one through-substrate trench surrounding the at least one micro-reactor and the one or more micro-fluidic channels.

Mounts for micro-mirrors are disclosed. A disclosed example apparatus includes a micro-mirror having a reflective surface area, and a movable mount to support and move the micro-mirror to direct light onto a printing area, where the movable mount includes a cross-sectional profile area that is at least 30% of the reflective surface area of the micro-mirror.

A method for detecting contamination of a microelectromechanical sensor element. The method includes the following steps: outputting heating control signals for controlling a heating device in order to heat the sensor element, receiving measuring signals that represent a physical variable that is measured with the aid of the heated sensor element, ascertaining, based on the measured physical variable, whether the sensor element has contamination or is free of contamination, outputting result signals that represent a result indicating whether the sensor element has contamination or is free of contamination. Moreover, a device is described.

A CMOS-based sensing device includes a substrate including an etched portion and a first region located on the substrate. The first region includes a membrane region formed over an area of the etched portion of the substrate, a flow sensor formed within the membrane region and a pressure sensor formed within the membrane region.

A package encapsulating electronic components of one or more Micro-Electro-Mechanical Systems (MEMS) devices has hermetic seal that enables the use of a frame with rough surface. That is, the frame surrounds the components and is affixed to a surface of the substrate with a frame adhering layer. A cover is affixed to the frame with a cover adhering layer. Each of the frame adhering layer and the cover adhering layer comprises a solder layer between metallic adhesion layers. The solder layer comprises reflowed solder balls. The package enables direct contact of a substrate with a heat sink.

Methods for determining and classifying by type aircraft air contaminants, and aircraft air contaminant analyzers, are disclosed.

A microelectromechanical system (MEMS) transducer for integration in a microphone assembly is designed to produce heat-generated acoustic signals. The MEMS transducer generally comprises a substrate having an aperture, a transduction element located at least partially over the aperture and coupled to the substrate, electrical contacts coupled to the transduction element, and a resistor integrated with the substrate or the transduction element. The resistor is coupled to electrical contacts that are electrically isolated from the contacts of the MEMS transducer or transduction element. The transduction element includes an insulating material coupled to the substrate. The transduction element comprises a fixed electrode and a movable electrode located at least partially over the aperture of the substrate. The fixed electrode or the moving electrode is formed on the insulating material. The resistor can be formed on the insulating material or suspended from the insulating material.

The present invention relates to an electronic system comprising an electronic system comprising an electromechanical microsystem and a hermetic box encapsulating said microsystem. The box includes a fastening plane. The electromechanical microsystem includes a sensitive part and at least two beams connecting the sensitive part to the fastening plane. The beams are thermally coupled to the sensitive part and are electrically coupled to one another. The system further includes a thermal regulator of the electromechanical microsystem including an electrical circuit including at least two ends connected to the beams, and a circuit controller able to generate an electrical current in the electrical circuit to modify the temperature of the sensitive part.