Abstract: According to one embodiment, a sensor device includes a movable body capable of vibrating, and a catch-and-release mechanism capable of catching the vibrating movable body and capable of releasing the caught movable body. The catch-and-release mechanism includes a stopper portion capable of stopping vibration of the movable body when the movable body contacts the stopper portion, and an elastic member configured to reduce a force acting between the movable body and the stopper portion.

Abstract: According to one embodiment, a method of acquiring rotational information of a gyro sensor includes sensing a predetermined physical quantity which depends upon an amplitude of a vibration in a second direction, the vibration in the second direction being based on Coriolis force that is applied to a movable body which is vibrating in a first direction, calculating rotational information of the movable body based on the sensed predetermined physical quantity, and stopping a vibration in the first direction of the movable body after the predetermined physical quantity is sensed.

Abstract: According to one embodiment, a gyro sensor system including a gyro sensor unit is disclosed. The unit includes a movable body, a spring mechanism, a detector, an adjuster, and a rotation angle acquisition unit. The spring mechanism vibrates the movable body. A detector detects an amplitude of vibration of the movable body due to Coriolis force. The adjuster adjusts a first resonance frequency of vibration of the movable body in free vibration and a second resonance frequency of vibration of the movable body due to Coriolis force on the movable body so that the first and second resonance frequencies are to coincide with each other based on the amplitude of the vibration due to Coriolis force. The rotation angle acquisition unit acquires a rotation angle of the movable body, based on the amplitude of the vibration due to Coriolis force.

Abstract: According to one embodiment, a vibration device includes a first movable unit including first and second movable portions arranged in a direction parallel to a first axis and enabled to vibrate in the direction parallel to the first axis, a second movable unit enabled to vibrate in a direction parallel to a second axis perpendicular to the first axis, and a connection unit configured to connect the first and second movable units together, wherein the following relationship is satisfied fi>(1+1/(2Qa))fa where a resonant frequency of the first movable unit in an in-phase mode is denoted by fi, a resonant frequency of the first movable unit in an anti-phase mode is denoted by fa, and a Q factor of resonance of the first movable unit in the anti-phase mode is denoted by Qa.

Abstract: According to one embodiment, a sensor is disclosed. The sensor includes a substrate, a first fixed electrode arranged on the substrate, a movable electrode arranged above the first fixed electrode and being movable non-parallely, a second fixed electrode arranged above the movable electrode. The sensor further includes a detector to detect a difference between a first capacitance between the first fixed electrode and the movable electrode and a second capacitance between the movable electrode and the second fixed electrode.

Abstract: According to one embodiment, an electronic device includes a base region, an element portion located on the base region, the element portion including a movable portion, and a protective film overlying the element portion and forming a cavity on an inner side of the protective film. The protective film includes a first protective layer and a second protective layer located on the first protective layer. A hole extends in a direction parallel to a main surface of the base region, and the second protective layer covers the hole.

Abstract: According to one embodiment, an angular velocity acquisition device includes a movable body that vibrates in a first direction and in a second direction that is based on Coriolis force and includes a movable electrode portion extending in the second direction, a hold electrode that extends in the second direction and includes a fixed electrode portion opposite to the movable electrode portion across a gap, and a stopper that is provided between the fixed electrode portion and the movable electrode portion and includes an end portion closer to the movable electrode portion than a surface of the fixed electrode portion facing the movable electrode portion.

Abstract: A gas detection device includes a substrate having a main surface and a movable film structure located on, and including a portion thereof spaced from, the main surface of the substrate. The portion of the movable film structure located over and spaced from the substrate includes a first film formed of an insulating material, a patterned second film which deforms as a result of absorbing or adsorbing a predetermined gas, and a patterned third film comprising a resistive heater, at least a portion of the movable film structure spaced from the substrate being movable with respect to the substrate. From the perspective of a direction perpendicular to the main surface of the substrate, at least a portion of a pattern of the second film overlaps at least a portion of a pattern of the third film.

Abstract: According to one embodiment, an electronic device includes an underlying region, a variable capacitor including fixed electrodes and movable electrodes alternately arranged in a direction not perpendicular to a main surface of the underlying region, and a protective film which covers the variable capacitor and includes a conductive portion electrically connected to the fixed electrodes and having a hole.

Abstract: According to one embodiment, a method of manufacturing a device is provided. A amorphous metal layer is formed. A metal layer containing metal and having a crystal plane oriented to a predetermined plane is formed on the amorphous metal layer. A first layer containing semiconductor including silicon, and metal identical to the metal contained in the metal layer is formed on the metal layer. The first layer is changed to a second layer containing a compound of the semiconductor and the metal, the compound having a crystal plane oriented to the predetermined plane. A third layer containing polycrystalline silicon-germanium and having a crystal plane oriented to the predetermined plane is formed on the second layer.

Abstract: An angular velocity acquisition device includes a movable body, a drive electrode to which a drive voltage is applied to vibrate the movable body in a first direction, at least one stopper that stops the movable body at a predetermined position, a hold electrode which receives a hold voltage to hold the movable body at the predetermined position, a detection unit that detects a predetermined physical quantity depending on an amplitude of the vibration of the movable body in a second direction based on a Coriolis force acting on the movable body that vibrates in the first direction, and an angular velocity calculation unit that calculates an angular velocity of the movable body based on the predetermined physical quantity detected by the detection unit.

Abstract: According to one embodiment, an electronic device includes a base region, an element portion located on the base region, the element portion including a movable portion, and a protective film overlying the element portion and forming a cavity on an inner side of the protective film. The protective film includes a first protective layer and a second protective layer located on the first protective layer. A hole extends in a direction parallel to a main surface of the base region, and the second protective layer covers the hole.

Abstract: According to one embodiment, a sensor includes a substrate, a variable capacitor including a bottom electrode provided on the substrate and a top electrode provided above the bottom electrode so as to face the bottom electrode, a movable structure including a portion located above the top electrode and being movable in accordance with a specific physical quantity, a support structure including at least one support portion supporting the top electrode, and a connection structure connecting the movable structure and the top electrode to displace the top electrode based on displacement of the movable structure, wherein the top electrode is displaced about an axis penetrating the at least one support portion, which serves as a first rotation axis.

Abstract: According to an embodiment, a MEMS includes a substrate; a substrate; a membrane arranged above the substrate; a first conductor with a first plane, the first conductor being connected to the membrane; and a second conductor with a second plane facing the first plane, the second conductor being arranged with a gap between the first conductor and the second conductor, wherein relative positions of the first conductor and the second conductor change in a direction in which an area of the first plane facing the second plane changes.

Abstract: According to one embodiment, an electronic device includes at least one variable capacitor including a first electrode and a second electrode, and being brought into one of a first state and a second state according to a voltage applied between the first electrode and the second electrode, the first electrode and the second electrode being closer to each other in the second state compared with in the first state, and a charge pump circuit provided in a first integrated circuit chip and producing a voltage for establishing the second state. An external capacitor is connectable to the first integrated circuit chip and is receivable the voltage produced by the charge pump circuit.

Abstract: According to one embodiment, a method of acquiring angular velocity of a gyro sensor, includes sensing a predetermined physical quantity which depends upon an amplitude of a vibration in a second direction, the vibration in the second direction being based on Coriolis force that is applied to a movable body which is vibrating in a first direction, and calculating angular velocity of the movable body based on the sensed predetermined physical quantity, wherein the predetermined physical quantity is sensed when the vibration in the second direction based on the Coriolis force is in a non-stationary state.

Abstract: According to one embodiment, a method of manufacturing a device is provided. A amorphous metal layer is formed. A metal layer containing metal and having a crystal plane oriented to a predetermined plane is formed on the amorphous metal layer. A first layer containing semiconductor including silicon, and metal identical to the metal contained in the metal layer is formed on the metal layer. The first layer is changed to a second layer containing a compound of the semiconductor and the metal, the compound having a crystal plane oriented to the predetermined plane. A third layer containing polycrystalline silicon-germanium and having a crystal plane oriented to the predetermined plane is formed on the second layer.

Abstract: According to one embodiment, an electronic device includes an underlying region, a variable capacitor including fixed electrodes and movable electrodes alternately arranged in a direction not perpendicular to a main surface of the underlying region, and a protective film which covers the variable capacitor and includes a conductive portion electrically connected to the fixed electrodes and having a hole.

Abstract: According to one embodiment, a MEMS device is disclosed. The device includes a substrate, a first electrode fixed on the substrate. The first electrode includes a first one end portion and a first other end portion. A capacitor insulating film is provided on the first electrode. An insulating film is provided on the substrate and located around a periphery of the first electrode. A second electrode is provided above the first electrode and movable. The second electrode includes a second one end portion corresponding to the first one end portion, and a second other end portion corresponding to the first other end portion. The second one end portion extends outside the first one end portion and includes a first bent portion bent downward.

Abstract: According to one embodiment, a variable capacitance bank device, including a plurality of capacitor banks for generation of a variable capacitance, the plurality of capacitor banks being connected parallel with each other. each of the capacitor banks being constituted by serially connecting a fixed capacitor for generation of a fixed capacitance and a MEMS capacitor for generation of the variable capacitance. capacitances of the fixed capacitors in different capacitor banks being set at different values. capacitances of the MEMS capacitors in different capacitor banks being set at an equal value.