One or more heating elements are provided to heat a MEMS component (such as a resonator) to a temperature higher than an ambient temperature range in which the MEMS component is intended to operate—in effect, heating the MEMS component and optionally related circuitry to a steady-state “oven” temperature above that which would occur naturally during component operation and thereby avoiding temperature-dependent performance variance/instability (frequency, voltage, propagation delay, etc.). In a number of embodiments, an IC package is implemented with distinct temperature-isolated and temperature-interfaced regions, the former bearing or housing the MEMS component and subject to heating (i.e., to oven temperature) by the one or more heating elements while the latter is provided with (e.g., disposed adjacent) one or more heat dissipation paths to discharge heat generated by transistor circuitry (i.e., expel heat from the integrated circuit package).

A thermally conductive sheet including a sheet body that is a cured product of a thermally conductive resin composition including a binder resin and carbon fibers covered with insulating coating films, wherein the carbon fibers exposed on a surface of the sheet body are not covered with the insulating coating films and are covered with a component of the binder resin.

A microelectromechanical system (MEMS) actuator device includes a substrate; a shape memory alloy over the substrate; and a reflective coating on the shape memory alloy. The shape memory alloy and the reflective coating form a bi-layer cantilever beam having a first end anchored to the substrate, and a second end released from the substrate. The second end of the cantilever beam articulates between a deflection configuration away from the substrate and a non-deflection configuration towards the substrate based on a thermal phase change in the shape memory alloy.

A sensor element for thermal anemometry includes a semiconductor substrate and a thin-film diaphragm attached to the semiconductor substrate and having a front side and a rear side. A resistive heating element and a temperature-dependent resistor are attached to the front side of the thin-film diaphragm. In the area of the rear side of the thin-film diaphragm, the semiconductor substrate has a first recess. A silicon layer including a recess which merges with the first recess of the semiconductor substrate is located between the thin-film diaphragm and the semiconductor substrate.

A configuration for a capacitive pressure sensor uses a silicon on insulator wafer to create an electrically isolated sensing node across a gap from a pressure sensing wafer. The electrical isolation, small area of the gap, and silicon material throughout the capacitive pressure sensor allow for minimal parasitic capacitance and avoid problems associated with thermal mismatch.

Provided is an internal temperature measurement device capable of measuring an internal temperature of a measuring object for which the thermal resistance value of a non-heating body present on the surface side of the object is unknown, more accurately with better responsiveness than hitherto. The internal temperature measurement device 10 includes a MEMS chip 12 including: two cells 20a, 20b for measuring two heat fluxes for calculating an internal temperature of a measuring object for which the thermal resistance value of a non-heating body is unknown; and a cell 20c for increasing a difference between the heat fluxes.

The present invention relates to microelectromechanical systems (MEMS), and more specifically to an anchor structure for anchoring MEMS components within a MEMS device. The anchor points for rotor and stator components of the device are arranged such that the anchor points are arranged along and overlap a common axis.

A method for manufacturing a resonator that effectively addresses variations in resistivity for each wafer. The method for manufacturing a resonator includes forming a Si oxide film on a surface of a degenerated Si wafer, where the Si oxide film has a thickness set that is based on the doping amount of impurity in the degenerated Si wafer.

A semiconductor package with design features, including an isolation structure for internal components and a flexible electrical connection, that minimizes errors due to environmental temperature, shock, and vibration effects. The semiconductor package may include a base having a first portion surrounded by a second portion. A connector assembly may be attached to the first portion. The connector assembly may extend through an opening in the base. A lid attached may be attached to, at least, the second portion. The attached lid may form a hermetically-sealed cavity defined by an upper surface of the first portion, the connector assembly, and an inner surface of the lid. An elastomer pad may be on the first portion and a sub-assembly may be on the elastomer pad. A flexible electrical connection may be formed between the connector assembly and the sub-assembly.

One or more heating elements are provided to heat a MEMS component (such as a resonator) to a temperature higher than an ambient temperature range in which the MEMS component is intended to operate—in effect, heating the MEMS component and optionally related circuitry to a steady-state “oven” temperature above that which would occur naturally during component operation and thereby avoiding temperature-dependent performance variance/instability (frequency, voltage, propagation delay, etc.). In a number of embodiments, an IC package is implemented with distinct temperature-isolated and temperature-interfaced regions, the former bearing or housing the MEMS component and subject to heating (i.e., to oven temperature) by the one or more heating elements while the latter is provided with (e.g., disposed adjacent) one or more heat dissipation paths to discharge heat generated by transistor circuitry (i.e., expel heat from the integrated circuit package).