A crystal resonator includes a flat plate-shaped crystal element and excitation electrodes. The crystal element has principal surfaces parallel to an X′-axis and a Z′-axis. The X′-axis is an axis of rotating an X-axis in a range of 15 to 25 degrees around a Z-axis. The Z′-axis is an axis of rotating the Z-axis in a range of 33 to 35 degrees around the X′-axis. The excitation electrodes are formed on the respective principal. The excitation electrodes include a first region with a circular outer shape and a second region. The second region is formed at a peripheral area of the first region. The second region has a thickness thinner than the first region and has an elliptical outer shape. The elliptical shape has a long axis extending in a direction in a range of −5 to +15 degrees with respect to a direction that the X′-axis extends.

Provided are a chip packaging method and a chip packaging structure. A passivation layer is provided on a pad of a wafer, a first metal bonding layer is then formed on the passivation layer, a second metal bonding layer is formed on a substrate, the substrate and the wafer are bonded and packaged together through bonding of the first metal bonding layer and the second metal bonding layer, a first shielding layer is provided on the substrate, and the first shielding layer is connected to the second metal bonding layer; and after the wafer and the substrate are bonded, semi-cutting is performed on the wafer until the first metal bonding layer is exposed, and a second shielding layer is then formed, and the second shielding layer is electrically connected to the first metal bonding layer, such that an electromagnetic shielding structure jointly composed of the first shielding layer, the second metal bonding layer, the second shielding layer and the first metal bonding layer is obtained. The shielding structure is thus approximately closed, thereby improving the electromagnetic shielding effect.

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 resonator device includes: a resonator element that has a first surface on which a first mount electrode and a second mount electrode are disposed, and a second surface; a base that has a third surface which faces the first surface of the resonator element and on which a first base electrode and a second base electrode are disposed; a lid that has a fourth surface which faces the second surface of the resonator element; a first metal bump by which the first mount electrode and the first base electrode are bonded; a second metal bump by which the second mount electrode and the second base electrode are bonded; and a bonding member by which the second surface and the fourth surface are bonded. A loss tangent of the bonding member is larger than a loss tangent of the first metal bump and the second metal bump.

A resonator device includes: a resonator element that has a first surface on which a first mount electrode and a second mount electrode are disposed, and a second surface; a base that has a third surface which faces the first surface of the resonator element and on which a first base electrode and a second base electrode are disposed; a lid that has a fourth surface which faces the second surface of the resonator element; a first metal bump by which the first mount electrode and the first base electrode are bonded; a second metal bump by which the second mount electrode and the second base electrode are bonded; and a bonding member by which the second surface and the fourth surface are bonded. A loss tangent of the bonding member is larger than a loss tangent of the first metal bump and the second metal bump.

A resonator device includes: a base; a resonator element that includes a resonator substrate and an electrode; a conductive layer that is disposed on the base; a metal bump that is disposed between the conductive layer and the resonator element, and that electrically couples the conductive layer and the electrode while bonding the conductive layer and the resonator element; and at least one of a first low elastic modulus layer that is interposed between the base and the conductive layer, that overlaps the metal bump in a plan view of the base, and that has an elastic modulus smaller than that of the metal bump, and a second low elastic modulus layer that is interposed between the resonator substrate and the electrode, that overlaps the metal bump in the plan view of the base, and that has an elastic modulus smaller than that of the metal bump.

A resonator device includes: a base; a resonator element that includes a resonator substrate and an electrode; a conductive layer that is disposed on the base; a metal bump that is disposed between the conductive layer and the resonator element, and that electrically couples the conductive layer and the electrode while bonding the conductive layer and the resonator element; and at least one of a first low elastic modulus layer that is interposed between the base and the conductive layer, that overlaps the metal bump in a plan view of the base, and that has an elastic modulus smaller than that of the metal bump, and a second low elastic modulus layer that is interposed between the resonator substrate and the electrode, that overlaps the metal bump in the plan view of the base, and that has an elastic modulus smaller than that of the metal bump.

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 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 resonant member of a MEMS resonator oscillates in a mechanical resonance mode that produces non-uniform regional stresses such that a first level of mechanical stress in a first region of the resonant member is higher than a second level of mechanical stress in a second region of the resonant member. A plurality of openings within a surface of the resonant member are disposed more densely within the first region than the second region and at least partly filled with a compensating material that reduces temperature dependence of the resonant frequency corresponding to the mechanical resonance mode.