Abstract: One or more embodiments of the disclosure may be an oven-controlled crystal oscillator that may include a core section hermetically encapsulated inside a thermal insulation package. The core section includes at least: an oscillation IC; a crystal resonator; and a heater IC. The core section is mounted on a core substrate that is mechanically connected to the package by a non-conductive adhesive. The core section and the package are electrically connected to each other by wire bonding. A space is provided between the core substrate and a bottom surface of the package.

Abstract: An oven-controlled crystal oscillator according to one or more embodiments may include including a core section hermetically encapsulated in a package for thermal insulation, wherein the core section is supported by the package via a core substrate, and the core section has a layered structure in which at least an oscillation IC, a crystal resonator and a heater IC are laminated in sequence.

Abstract: An oven-controlled crystal oscillator according to one or more embodiments may include a core section having a crystal resonator, an oscillator IC and a heating IC, wherein the core section is supported by a package via an interposer, and furthermore the core section is hermetically encapsulated in the package.

Abstract: An OCXO according to one or more embodiments may include a core section hermetically encapsulated in a heat insulation package. The core section includes: an oscillation IC; a crystal resonator; and a heater IC. The core section is supported by the package via a core substrate. The OCXO further includes a capacitor as an electronic component for adjustment, which is attached to the package by soldering. The core section is vacuum-sealed in a sealed space of the package, while the capacitor is disposed in a space other than the sealed space.

Abstract: An OCXO according to one or more embodiments may include a core section hermetically encapsulated inside a heat insulation package. The core section includes: an oscillation IC; a crystal resonator; and a heater IC, and furthermore is supported by the package via a core substrate. The core substrate is mechanically connected to the package by a non-conductive adhesive. The core section and the package are electrically connected to each other by wire bonding using wires.

Abstract: A piezoelectric resonator device according to one or more embodiments may be provided, in which a crystal resonator plate includes a cutout part between a vibrating part and an external frame part, and a metal film formed on a first main surface of a first sealing member is electrically connected to an external electrode terminal formed on a second main surface, which does not face an internal space, of a second sealing member via a first internal wiring formed on an inner wall surface of the external frame part.

Abstract: A through hole formed in an AT-cut crystal plate includes an inclined surface (72) that extends from a peripheral area toward a penetrating part (71) in a center part of the through hole. The inclined surface (72) includes: a first crystal surface S1 that extends from the penetrating part (71) toward the peripheral area of the through hole in a ?Z? and a +X directions; a second crystal surface S2 that extends from the penetrating part (71) toward the peripheral area of the through hole in the ?Z? and the +X directions and that contacts with the first crystal surface S1 in the +Z? and the +X directions of the first crystal surface S1; and a third crystal surface S3 that contacts with the second crystal surface S2 in the +X direction of the second crystal surface S2 and that contacts with the main surface of the AT-cut crystal plate.

Abstract: When a thick frequency adjustment metal film of a tuning fork-type vibration piece is irradiated with a beam on a wafer for frequency coarse adjustment, projections are possibly formed on a roughened end of the frequency adjustment metal film. Such projections are pressurized and pushed down not to chip off under any impact, so that the risk of frequency fluctuations is suppressed.

Abstract: A crystal oscillator (101) includes: a piezoelectric resonator plate (2) on which a first excitation electrode and a second excitation electrode are formed; a first sealing member (3) covering the first excitation electrode of the piezoelectric resonator plate (2); a second sealing member (4) covering the second excitation electrode of the piezoelectric resonator plate (2); and an internal space (13) formed by bonding the first sealing member (3) to the piezoelectric resonator plate (2) and by bonding the second sealing member (4) to the piezoelectric resonator plate (2), so as to hermetically seal a vibrating part including the first excitation electrode and the second excitation electrode of the piezoelectric resonator plate (2). An electrode pattern (371) including a mounting pad for wire bonding is formed on an outer surface (first main surface (311)) of the first sealing member (3).

Abstract: A tuning fork-type vibration piece is provided, in which a cushioning portion is formed on the base of a package and allowed to contact parts for contact of arm portions which are any parts but their edges, and the parts for contact of the arm portions that contact the cushioning portion are electrodeless regions, which prevents the risk of frequency fluctuations caused by any electrode being chipped off by contact with the cushioning portion.

Abstract: When a thick frequency adjustment metal film of a tuning fork-type vibration piece is irradiated with a beam on a wafer for frequency coarse adjustment, projections are possibly formed on a roughened end of the frequency adjustment metal film. Such projections are pressurized and pushed down not to chip off under any impact, so that the risk of frequency fluctuations is suppressed.

Abstract: An oven-controlled crystal oscillator according to one or more embodiments includes a core section having at least an oscillation IC, a crystal resonator, and a heater IC. The core section is hermetically encapsulated in a heat-insulating package. The core section is supported by the package via a core substrate. The core substrate is connected to the package outside a region where the core section is provided in plan view.

Abstract: A thin-film heater according to one or more embodiments may include an insulated substrate and metal wiring patterned thereon to extend between both terminals of the metal wiring. The metal wiring has a resistance of 10? or less between the terminals. The metal wiring includes a heat-generating layer made of a material that recrystallizes at a temperature of 200° C. or lower.

Abstract: An oven-controlled crystal oscillator according to one or more embodiments may include a core section having a crystal resonator, an oscillator IC and a heating IC, wherein the core section is supported by a package via an interposer, and furthermore the core section is hermetically encapsulated in the package.

Abstract: A third through hole is formed in a crystal resonator plate of a crystal resonator to penetrate between a first main surface and a second main surface. A through electrode of the third through hole is conducted to a first excitation electrode. A seventh through hole is formed in a first sealing member of the crystal resonator to penetrate between a first main surface and a second main surface. The through electrode of the third through hole is conducted to the through electrode of the seventh through hole. The third through hole is not superimposed to the seventh through hole in plan view.

Abstract: A crystal resonator plate according to one or more embodiments may include: a vibrating part; an external frame part surrounding the outer periphery of the vibrating part; and a support part connecting the vibrating part to the external frame part. A first excitation electrode is formed on a first main surface of the vibrating part. A second excitation electrode is formed on a second main surface of the vibrating part. The second excitation electrode includes a pair of parallel sides parallel to each other. The first excitation electrode includes protruding parts that protrude outward from a part between the parallel sides the second excitation electrode in plan view. The protruding parts each have an outer edge shape that is not along the parallel sides in plan view.

Abstract: In a crystal oscillator accordance to an embodiment, a crystal resonator plate is bonded to, via laminated bonding patterns, a first sealing member covering a first excitation electrode of the crystal resonator plate; and a second sealing member covering a second excitation electrode of the crystal resonator plate. An internal space is formed, which hermetically seals a vibrating part including the first and second excitation electrodes of the crystal resonator plate. The laminated bonding patterns include a laminated sealing pattern annularly formed to surround the vibrating part in plan view so as to hermetically seal the internal space, and a laminated conductive pattern establishing conduction between wiring and electrodes. The laminated conductive pattern is disposed within a closed space surrounded by the laminated sealing pattern. To the laminated sealing pattern, GND potential is applied when the crystal oscillator operates.

Abstract: In a crystal resonator plate (2), a support part (24) extends from only one corner part positioned in the +X direction and in the ?Z? direction of a vibrating part (22) to an external frame part (23) in the ?Z? direction. The vibrating part (22) and at least part of the support part (24) form an etching region (Eg) having a thickness thinner than a thickness of the external frame part (23). A stepped part is formed at a boundary of the etching region (Eg), and a first lead-out wiring (223) is formed over the support part (24) to the external frame part (23) so as to overlap with the stepped part. At least part of the stepped part that is superimposed on the first lead-out wiring (223) is formed so as not to be parallel to the X axis in plan view.

Abstract: In a piezoelectric resonator device according to an embodiment, an internal space is formed by bonding a first sealing member to a crystal resonator plate and bonding a second sealing member to the crystal resonator plate. The internal space hermetically seals a vibrating part including a first excitation electrode and a second excitation electrode of the crystal resonator plate. Seal paths that hermetically seal the vibrating part of the crystal resonator plate are formed to have an annular shape in plan view. A plurality of external electrode terminals is formed on a second main surface of the second sealing member to be electrically connected to an external circuit board. The external electrode terminals are respectively disposed on and along an external frame part surrounding the internal space in plan view.

Abstract: Hermeticity of an annular sealing bonding material to seal a vibrating part is improved. In the crystal resonator 10, a resonator-plate-side first bonding pattern 251 annularly formed on a crystal resonator plate 2 is bonded to a sealing-member-side first bonding pattern 321 annularly formed on a first sealing member 3, and a resonator-plate-side second bonding pattern 252 annularly formed on the crystal resonator plate 2 is bonded to a sealing-member-side second bonding pattern 421 annularly formed on a second sealing member 4. Thus, annular bonding materials 11a and 11b, which hermetically seal a vibrating part 22 causing piezoelectric resonance, are formed. Inner peripheral edge parts 111a and 111b and outer peripheral edge parts 112a and 112b of the bonding materials 11a and 11b are formed denser than intermediate parts 113a and 113b between the inner and outer peripheral edge parts 111a and 112a, and between the inner and outer peripheral edge parts 111b and 112b.