An actuator device includes a support portion, a movable portion, a connection portion which connects the movable portion to the support portion on a second axis, a first wiring which is provided on the connection portion, a second wiring which is provided on the support portion, and an insulation layer which includes a first opening exposing a surface opposite to the support portion in a first connection part located on the support portion in one of the first wiring and the second wiring and covers a corner of the first connection part. The rigidity of a first metal material forming the first wiring is higher than the rigidity of a second metal material forming the second wiring. The other wiring of the first wiring and the second wiring is connected to the surface of the first connection part in the first opening.

An inertial sensor includes a movable element including a first movable section and a second movable section, a first detection electrode, and a first dummy electrode. The first movable section has a first section, a second section that is farther from the swing axis than the first section, and a third section disposed between the first section and second section. A separation distance between the third section and the first dummy electrode is greater than a separation distance between the first section and the first detection electrode.

Described examples include an apparatus having a substrate with a substrate surface. The apparatus also includes an element with a planar surface facing the substrate surface and with a nonplanar surface opposite the planar surface facing away from the substrate surface.

A thermal metamaterial device comprises at least one MEMS thermal switch, comprising a substrate layer including a first material having a first thermal conductivity, and a thermal bus over a first portion of the substrate layer. The thermal bus includes a second material having a second thermal conductivity higher than the first thermal conductivity. An insulator layer is over a second portion of the substrate layer and includes a third material that is different from the first and second materials. A thermal pad is supported by a first portion of the insulator layer, the thermal pad including the second material and having an overhang portion located over a portion of the thermal bus. When a voltage is applied to the thermal pad, an electrostatic interaction occurs to cause a deflection of the overhang portion toward the thermal bus, thereby providing thermal conductivity between the thermal pad and the thermal bus.

The inertial sensor includes a substrate, stationary electrodes provided to the substrate, an element section including a movable body which is displaceable with respect to the stationary electrodes, and which has electrodes in a first portion and a second portion opposed to the stationary electrodes, a protrusion which limits a displacement of the movable body, and which has a detection electrode in a portion opposed to the first portion of the movable body, a drive circuit for outputting a drive signal to the element section, a contact detection circuit for outputting a detection signal due to a contact between the electrode in the first portion of the movable body and the detection electrode of the protrusion, a self-diagnostic circuit for outputting a test signal to the element section when receiving the detection signal from the contact detection circuit, and a determination circuit for determining whether or not a level of a signal output by the element section in response to the test signal is out of a threshold value.

An inertial sensor includes a support substrate, a sensor main body supported by the support substrate, and a bonding member that is located between the support substrate and the sensor main body and bonds the sensor main body to the support substrate. The sensor main body includes a substrate bonded to the support substrate via the bonding member and a capacitance-type sensor device provided at a side of the substrate opposite to the support substrate. The substrate has a side surface, a first principal surface facing the support substrate, and a recessed step section that is located between the side surface and the first principal surface and connects the side surface to the first principal surface. The bonding member extends along the first principal surface and the step section.

A microelectromechanical systems (MEMS) device comprising: a substrate; a signal conductor supported on the substrate; ground conductors supported on the substrate on either side of the signal conductor; and a MEMS bridge at least one end of which is mechanically connected to the substrate by way of at least one anchor, the MEMS bridge comprising an electrically conductive switching portion, the electrically conductive switching portion comprising a switching signal conductor region and a switching ground conductor region, the switching signal conductor region being provided over the signal conductor and the switching ground conductor region being provided over a said ground conductor, the electrically conductive switching region being movable relative to the said signal and ground conductors respectively to thereby change the inductances between the switching signal conductor region and the signal conductor and between the switching ground conductor region and the respective ground conductor, wherein there is no continuous electrically conductive path extending from the switching conductor region to the at least one anchor. Capacative and ohmic switches, a varactor, a phase shifter, a tuneable power splitter/combiner, tuneable attenuator, SPDT switch and antenna apparatus comprising said devices.

A MEMS accelerometric sensor includes a bearing structure and a suspended region that is made of semiconductor material, mobile with respect to the bearing structure. At least one modulation electrode is fixed to the bearing structure and is biased with an electrical modulation signal including at least one periodic component having a first frequency. At least one variable capacitor is formed by the suspended region and by the modulation electrode in such a way that the suspended region is subjected to an electrostatic force that depends upon the electrical modulation signal. A sensing assembly generates, when the accelerometric sensor is subjected to an acceleration, an electrical sensing signal indicating the position of the suspended region with respect to the bearing structure and includes a frequency-modulated component that is a function of the acceleration and of the first frequency.

The physical quantity sensor includes a movable body oscillating around an oscillation axis, and a detection electrode disposed so as to be opposed to the movable body. The substrate has a first area through an m-th area, and the detection electrode is disposed so as to straddle the first area through an n-th area. When setting a first imaginary straight line which is the smallest in an angle formed with an X-axis direction out of imaginary straight lines connecting two of end parts on respective areas of the first area through the n-th area of the detection electrode, and a second imaginary straight line extending along a principal surface located at the substrate side of the movable body in a state in which the movable body makes a maximum displacement around the oscillation axis, the first imaginary straight line and the second imaginary straight line fail to cross each other in an area between a first normal line which passes the end part of the first area, and which extends in the Z-axis direction, and a second normal line which passes the end part in the n-th area, and which extends in the Z-axis direction.

The inertial sensor includes a substrate, stationary electrodes provided to the substrate, an element section including a movable body which is displaceable with respect to the stationary electrodes, and which has electrodes in a first portion and a second portion opposed to the stationary electrodes, a protrusion which limits a displacement of the movable body, and which has a detection electrode in a portion opposed to the first portion of the movable body, a drive circuit for outputting a drive signal to the element section, a contact detection circuit for outputting a detection signal due to a contact between the electrode in the first portion of the movable body and the detection electrode of the protrusion, a self-diagnostic circuit for outputting a test signal to the element section when receiving the detection signal from the contact detection circuit, and a determination circuit for determining whether or not a level of a signal output by the element section in response to the test signal is out of a threshold value.