A resonator that includes a piezoelectric vibrating portion; a retainer provided in at least part of an area surrounding the piezoelectric vibrating portion; a first node generating portion disposed between the piezoelectric vibrating portion and the retainer; a first connecting arm that connects the first node generating portion to a region in the piezoelectric vibrating portion that faces the first node generating portion; and a first retaining arm that connects the first node generating portion to a region in the retainer that faces the first node generating portion. The first node generating portion is substantially symmetrical with respect to each of two lines passing through a center of the first node generating portion along a first direction and a second direction orthogonal to the first direction, with the first direction being a direction that the first connecting arm connects the first node generating portion to the piezoelectric vibrating portion.

A resonator is provided that includes a base, and three or more vibrating arms each including a first and second electrodes and a piezoelectric film disposed therebetween and having a top surface facing the first electrode. The piezoelectric film vibrates in a predetermined vibration mode when a voltage is applied between the first and second electrodes. Moreover, the three or more vibrating arms include two first arms each located on an outermost side in a direction in which the three or more vibrating arms are arranged and that vibrate in a same phase, and one or more second arms disposed between the two first arms. Each first arm is greater in mass than each second arm.

A resonance device is provided that includes a first substrate with a resonator having an upper electrode, a second substrate that is disposed such that a first surface faces the first substrate with the resonator therebetween, a first terminal that is disposed on a second surface of the second substrate and that is electrically connected to the upper electrode, a second terminal that is disposed on the second surface and that applies a reference electric potential to the resonator, and an extended wiring line that is connected to the first terminal electrically and that extends on the second surface to an outer edge.

A moveable micromachined member of a microelectromechanical system (MEMS) device includes an insulating layer disposed between first and second electrically conductive layers. First and second mechanical structures secure the moveable micromachined member to a substrate of the MEMS device and include respective first and second electrical interconnect layers coupled in series, with the first electrically conductive layer of the moveable micromachined member and each other, between first and second electrical terminals to enable conduction of a first joule-heating current from the first electrical terminal to the second electrical terminal through the first electrically conductive layer of the moveable micromachined member.

A package structure that includes a pair of substrates arranged to oppose each other so as to form an internal space; a bonding portion sealing the pair of substrates; an element is sealed in the internal space and surrounded by the pair of substrates; an adsorption layer within the internal space and opposing at least one substrate of the pair of substrates, the adsorption layer constructed to adsorbs at least hydrogen; and a diffusion-inhibiting layer between the at least one substrate and the adsorption layer, and in which hydrogen is more difficult to diffuse compared with in the at least one substrate.

A resonator device includes a base made of silicon and provided with a first surface and a second surface in a front-back relationship with each other, a resonator element arranged on the first surface, a lid which is made of silicon, which has a third surface arranged at the first surface side to be faced to the first surface, and a recessed part having a bottom surface and opening on the third surface, and the third surface of which is bonded to the first surface, and a getter layer which is arranged on the bottom surface of the recessed part, and which is provided with a gas adsorptive property, wherein the bottom surface of the recessed part is higher in surface roughness Ra than the third surface.

A resonator device includes an element substrate including a frame part having a first surface and a second surface in a front-back relationship with each other, and a resonator element which is coupled to the frame part, and is arranged inside the frame part, a first substrate which is arranged at the first surface side, and has a third surface faced to the first surface, a first bonding layer which is arranged between the element substrate and the first substrate, and which is configured to bond the first surface and the third surface to each other, a second substrate which is arranged at the second surface side, and has a fourth surface faced to the second surface, a second bonding layer which is arranged between the element substrate and the second substrate, and which is configured to bond the second surface and the fourth surface to each other, a housing part which is surrounded by the frame part, the first substrate, and the second substrate, and which houses the resonator element, and a getter layer which is arranged on the fourth surface, exposed to the housing part, and has a gas adsorptive property.

In examples, a device comprises a semiconductor die, a thin-film layer, and an air cavity positioned between the semiconductor die and the thin-film layer. The air cavity comprises a resonator positioned on the semiconductor die. A rib couples to a surface of the thin-film layer opposite the air cavity.

Multiple degenerately-doped silicon layers are implemented within resonant structures to control multiple orders of temperature coefficients of frequency.

A single frequency control device incorporating a high frequency resonator, a low frequency resonator and a temperature sensing element, the latter thermally coupled closely to the said resonators to facilitate temperature sensing with higher resolution and accuracy. Additional benefits offered by the structure include smaller size and lower cost.