Abstract: Provided are an oven controlled crystal oscillator in which in a case where a metal lead is soldered to a substrate, even if cracks occur in the solder, its reliability is not reduced, and a production method. That is, an oven controlled crystal oscillator in which pre-tinning solders are formed around openings on a front surface and a rear surface of a substrate in which of a through hole for passing a metal lead therethrough is formed; and in a state where a metal lead including a solder layer (a pre-tinning solder) formed on its surface is inserted into the through hole of the substrate, the metal lead extending from the openings is soldered to the openings on the front surface and the rear surface of the substrate, so as to form a main solder, and a production method of the oven controlled crystal oscillator are provided.

Abstract: Devices having piezoelectric material structures integrated with substrates are described. Fabrication techniques for forming such devices are also described. The fabrication may include bonding a piezoelectric material wafer to a substrate of a differing material. A structure, such as a resonator, may then be formed from the piezoelectric material wafer.

Abstract: A metal base having plural protrusions at its bottom is engaged with and placed on standing metal pins in plural through holes provided in a base board, and a circuit board is fitted to an upper end of the metal pins. A crystal resonator is arranged on the circuit board via a heater element, and the metal base is covered with a metal cover, thereby obtaining a sealed structure of the crystal resonator. A two-stage counterbored portion including a first-stage and a second-stage counterbored portions is formed in the bottom of the base board, and a solder or conductive resin is filled in a gap between the first-stage counterbored portion formed around the metal pin inserted into the through hole, and the through hole and the metal pin to fix the metal pin in the though hole. Slits penetrating through the base board are formed around the metal pin.

Abstract: A method of manufacturing packages includes a welding step for welding a base substrate wafer to a rivet member by heating the base substrate wafer while pressing the same by a forming die from both sides in the thickness direction is provided, wherein a rivet member receiving portion which can receive a distal end of a core member is formed in a receiving die of the forming die, and an inner surface of the rivet member receiving portion is formed into a tapered shape widening from the bottom side toward the opening side.

Abstract: A surface mounted oven controlled crystal oscillator includes a crystal oscillator shell, a crystal oscillation circuit, several functional pins and a base plate. The crystal oscillation circuit is accommodated in a cavity that is formed by the crystal oscillator shell and the base plated and electrically connects with the functional pins. The functional pins drill through the base plate from the cavity. An insulating layer is formed between each functional pin and the base plate. The surface mounted oven controlled crystal oscillator further includes several pads formed at an outer surface of the base plate. The insulating layer is also formed between each pad and the base plate, and the functional pins are electrically connected with the corresponding pads respectively. Added pads, the oven controlled crystal oscillator has high stability, simple manufacturing process, and low manufacturing cost.

Abstract: The piezoelectric vibrator includes: a package in which a first substrate and a second substrate are superimposed so as to form a cavity therebetween; outer electrodes which are formed on an outer surface of the first substrate; inner electrodes which are formed on the first substrate so as to be accommodated in the cavity; penetration electrodes which are formed so as to penetrate through the first substrate so that the outer electrodes and the inner electrodes are electrically connected; and a piezoelectric vibrating reed which is sealed in the cavity and electrically connected to the inner electrodes at the inner side of the cavity. The first substrate and the second substrate are bonded by a bonding film that is formed of a low-melting-point glass, and the bonding film is heated to a predetermined bonding temperature when the first substrate and the second substrate are bonded together, and is formed by being heated to a temperature higher than the bonding temperature before the bonding is performed.

Abstract: A crystal oscillator includes a cover, a crystal blank and an Integrated Circuit (IC) chip. The cover has a surface, a cavity formed in the surface, a plurality of conductive contacts and a conductive sealing ring. The conductive contacts are disposed on the surface, and the conductive sealing ring is disposed on the surface and surrounds the conductive contacts. The IC chip is connected to the conductive contacts and the conductive sealing ring, and forms a hermetic chamber with the cover and the conductive sealing ring. The crystal blank is located in the hermetic chamber, and is electrically connected to the IC chip. Furthermore, a method for manufacturing a crystal oscillator is also provided.

Abstract: An electronic device is provided which includes a base, a through-electrode that passes through the base and from which an insulating material on an end face thereof is removed by polishing, a circuit pattern that is formed on an end face of the through-electrode, an electronic component that is disposed via an internal wiring formed on the circuit pattern, an electrode pattern that is formed on the surface of the base opposite to the surface on which the electronic component is disposed and that is connected to the other end face of the through-electrode, an external electrode that is formed on the electrode pattern, and a cap that is bonded to the base so as to protect the electronic component on the base.

Abstract: There are provided a surface-mounted crystal oscillator and a manufacturing method thereof which can realize miniaturization, improve quality, reduce a manufacturing cost, and enhance productivity. According to the surface-mounted crystal oscillator and the manufacturing method thereof, through terminals and of AgPd are formed on wall surfaces of through holes formed at corner portions of a rectangular ceramic substrate, a metal electrode of a support electrode lower portion of AgPd which is connected to the through terminal and forms a lower layer of a support electrode is formed on a front side of the substrate, the support electrode which holds a crystal piece is formed on the support electrode lower layer portion by using Ag, and a cover is mounted on an insulating film formed on the inner side of the periphery of the substrate and effect airtight sealing.

Abstract: A resonator element includes: a base portion, a first resonating arm that is extended from the base portion along a first direction, and a second resonating arm that is extended from the base portion along a first direction opposite to the first resonating arm, wherein the first resonating arm and the second resonating arm are arranged such that a base end portion of one side resonating arm and a middle portion of the other side resonating arm are arranged in the second direction orthogonal to the first direction.

Abstract: There are disclosed a surface mount crystal oscillator which can enhance a product quality and improve productivity while realizing miniaturization and a manufacturing method of the crystal oscillator. On wall faces of through holes formed in corner portions of a rectangular ceramic base, through terminals are formed; on the front surface of the ceramic base, leading terminals of crystal holding terminals which hold a crystal piece are connected to the diagonal through terminals; on the back surface of the ceramic base, mount terminals connected to the through terminals are formed; and an insulating film projected especially in a corner portion direction is formed at such a position as to face the opening end face of a metal cover.

Abstract: The invention provides a multifunctional VC-TCXO that, as well as promoting miniaturization, selectively configures the functions as needed, and furthermore, is suitable for power savings. In a VC-TCXO provided with a chamber body that accommodates an IC chip and a crystal blank, the IC chip has; basic functions consisting of a first oscillator output function, and a temperature compensating function, and additional functions comprising of a second oscillator output function, an operation/non-operation function of the first oscillator output, and a temperature voltage output function, and basic IC terminals and additional IC terminals for these functions, and basic mounting terminals, and additional mounting terminals.

Abstract: There are disclosed a surface mount crystal oscillator which can enhance a product quality and improve productivity while realizing miniaturization and a manufacturing method of the crystal oscillator. On wall faces of through holes formed in corner portions of a rectangular ceramic base, through terminals are formed; on the front surface of the ceramic base, leading terminals of crystal holding terminals which hold a crystal piece are connected to the diagonal through terminals; on the back surface of the ceramic base, mount terminals connected to the through terminals are formed; and the opening end face of a metal cover joined onto the ceramic base via the molten resin comprises a flange having an inclined face in the surface mount crystal oscillator.

Abstract: There are disclosed a surface mount crystal oscillator which can enhance a product quality and improve productivity while realizing miniaturization and a manufacturing method of the crystal oscillator. On wall faces of through holes formed in corner portions of a rectangular ceramic base, through terminals are formed; on the front surface of the ceramic base, leading terminals of crystal holding terminals which hold a crystal piece are connected to the diagonal through terminals; and on the back surface of the ceramic base, mount terminals connected to the through terminals are formed in the surface mount crystal oscillator.

Abstract: A package of a quartz resonator includes a tabular base substrate, a base material of which is a single layer, a lid section that has a recess and covers the base substrate, and a bonding material provided over the entire periphery of one principal plane of the base substrate and including low-melting glass for bonding the base substrate and the lid section. Internal electrodes are provided on the one principal plane of the base substrate. External electrodes are provided on the other principal plane of the base substrate. A wire contains an Ag—Pd alloy having a glass component and crosses the bonding material on the one principal plane.

Abstract: In a structure where an electronic component is mounted on a glass base material, an external electrode is provided on an opposite side to the component mounted on the base, and a through electrode and the base are welded to each other at a temperature equal to or higher than a glass softening point, electrical conduction is ensured between the electronic component and the external electrode. An electronic device includes a base, a through electrode which pass through the base and has a metal film formed on both end surfaces after an insulating material on the surface is removed by polishing, an electronic component which is provided on one surface of the through electrode through a connection portion, an external electrode which is provided on an opposite side to a side of the base on which the electronic component is provided, and a cap which protects the electronic component on the base.

Abstract: A frequency setting circuit and method for an integrated circuit detect the voltage at a pin of the integrated circuit during a frequency setting period, and determine a frequency setting signal according to the detected voltage to set the frequency of a clock provided by an oscillator in the integrated circuit. After setting the frequency, the frequency setting circuit and method store the frequency setting signal and stop detecting the voltage at the pin. Thus the pin can be used for other functions.

Abstract: A vibrating device includes: a package having an internal space; and a vibrating reed housed in the internal space of the package, wherein the package has a porous portion formed of a communication hole communicating between the internal space and the outside and a porous body buried in the communication hole, and a metal film closing the internal space is arranged on the outside side of the porous portion.

Abstract: The invention relates to an oven controlled crystal oscillator for surface mounting with reduced height (low profile). The oven controlled crystal oscillator for surface mounting comprises: a flat first substrate made of ceramic and on which are installed a crystal device and a heat resistor; and a second substrate made of a glass epoxy resin which is quadrangular in plan view and which faces the first substrate and has a larger external shape in plan view than the first substrate. The second substrate has an opening into whose center the crystal device is inserted, and has terminal sections on four locations corresponding to the surface outer periphery of the first substrate and the peripheral surfaces of the opening in the second substrate, and the terminal sections of the first substrate and second substrate are connected by solder.

Abstract: A device includes: a base substrate having a bonding pad and a peripheral pad, the peripheral pad encompassing the bonding pad; an acoustic resonator on the base substrate; a cap substrate having a bonding pad seal and a peripheral pad seal, the bonding pad seal bonding around the perimeter of the bonding pad and the peripheral pad seal bonding with the peripheral pad to define a hermetically sealed volume between the cap substrate and the base substrate, the cap substrate having a through hole therein over the bonding pad providing access for a connection to the bonding pad; a low-resistivity material layer region disposed on a portion of a surface of the cap substrate disposed inside the hermetically sealed volume, the material layer region being isolated from the bonding pad seal; and electronic circuitry disposed in the material layer region and electrical connected with the acoustic resonator.

Abstract: Provided is a surface mount crystal oscillator and a substrate sheet to prevent a decrease in a frequency variable amount by reducing electrostatic capacitance of the crystal oscillator. The surface mount crystal oscillator and the substrate sheet are each configured such that one end of a crystal holding terminal is connected to a corner terminal, and another end of the crystal holding terminal is formed from a center of a short side to be shorter than the one end so as to form an area in which no pattern is formed, and a pattern of a GND terminal is formed on that portion of a rear surface of a substrate which is opposed to the area in which no pattern is formed, so that the pattern (a crystal-mounted pattern) of the crystal holding terminal and the pattern of the GND terminal are not opposed to each other across the substrate.

Abstract: A crystal oscillator with improved tolerance to radiation such as X-rays includes: a container body; a quartz crystal blank accommodated in a first recess formed on one main surface of the container body and hermetically encapsulated in the first recess by a metal cover; and an IC chip that integrates electronic circuits including at least an oscillator circuit using the crystal blank and is accommodated in the second recess formed on the other main surface of the container body. The IC chip is fixed to the bottom surface of the second recess by flip-chip bonding such that a circuit formation plane of the IC chip is opposed to the bottom surface of the second recess. A radiation protective film is formed on the main surface other than the circuit formation plane of the IC chip.

Abstract: A low-price, compact oscillating device having a good temperature characteristic of a frequency intermediate between a temperature compensated crystal oscillator (TCXO) and an oven-controlled crystal oscillator (OCXO) is provided. The oscillating device having a TCXO is provided with a base on which the TCXO is mounted, that is formed into a box shape having a recess, with a plane area substantially equal to that of the TCXO; and a semiconductor chip including a temperature control circuit, a temperature sensor, and a heating element, mounted in the recess. An opening of the recess is provided in a surface opposite a surface in which the temperature compensated crystal oscillator is mounted, and sealed by a cover. A temperature of the TCXO can be kept constant to provide a oscillating device having an excellent temperature characteristic of a frequency compared with the single TCXO.

Abstract: An object of the invention is to provide a surface mount oscillator that can suppress a change with the lapse of time in frequency characteristics. A surface mount type crystal unit 1 includes: a framed crystal plate 2 in which an oscillating part 6 having a first excitation electrode 5a and a second excitation electrode 5b on opposite principal surfaces thereof is surrounded by a frame 7, and the oscillating part 6 and the frame 7 are connected by connecting parts 8a and 8b; a base 3; and a cover 4. The surface mount type crystal unit 1 has such a configuration that a first metal film 17 is formed in one area of two areas formed by dividing the principal surface of the frame 7 facing the base 3 at two positions around a circumferential direction of the frame 7, and a second metal film 18 is formed in the other area. The first metal film 17 is electrically connected to the first excitation electrode 5a, and the second metal film 18 is electrically connected to the second excitation electrode 5b.

Abstract: A crystal oscillator having a plurality of quartz crystals that are manufactured so that the directional orientation of the acceleration sensitivity vector is essentially the same for each crystal. This enables convenient mounting of the crystals to a circuit assembly with consistent alignment of the acceleration vectors. The crystals are aligned with the acceleration vectors in an essentially anti-parallel relationship and can be coupled to the oscillator circuit in either a series or parallel arrangement. Mounting the crystals in this manner substantially cancels the acceleration sensitivity of the composite resonator and oscillator, rendering it less sensitive to vibrational forces and shock events.

Abstract: An oscillator that includes a movable element formed of silicon, the movable element vibrating by electrostatic force, a stationary element supporting the movable element, a temperature detector located in contact with the stationary element, the temperature detector detecting the temperature of the stationary element, a supporting element joined to a joint surface between the movable element and the stationary element, the supporting element supporting the movable element, the stationary element, and the temperature detector on a surface opposite to the joint surface, a surrounding element contacted with the supporting element, the surrounding element and the supporting element surround the movable element, and electrodes provided on a surface of the surrounding element opposite to a surface of surrounding element contacted with the supporting element.

Abstract: A constant-temperature type crystal oscillator includes: a crystal unit including a case main body, in which two crystal terminals and two dummy terminals are provided on an outer bottom face thereof, and a crystal element housed in the case main body; an oscillator output circuit including an oscillating stage and a buffering stage; a temperature control circuit for keeping an operational temperature of the crystal unit; and a circuit substrate, on which circuit elements of the crystal unit, the oscillator output circuit and the temperature control circuit are installed. The temperature control circuit includes: heating chip resistors; a power transistor; and a temperature sensing element. Each of the dummy terminals is connected to a respective one of circuit terminals on the circuit substrate. At least one of the circuit terminals is connected to an electrically-conducting path, to which one terminal of the heating chip resistors is electrically connected, on the circuit substrate.

Abstract: An object of the invention is to provide an oscillator with a pedestal that facilitates soldering operations and offers a high level of productivity. A surface mount crystal oscillator with a pedestal comprises a crystal oscillator with lead wires led out from a bottom surface of a metallic base thereof; and a pedestal having a substantially rectangular outer shape in plan view, has insertion holes through which the lead wires pass, and is attached to a bottom surface of the crystal oscillator, and has mount terminals to be electrically connected to the lead wires formed on a bottom surface thereof. The configuration is such that the insertion holes are provided in four corner sections of the pedestal, in the four corner sections of the bottom surface of the pedestal where the insertion holes are formed there is provided a recess with an open outer periphery, and the lead wire is connected to a terminal electrode formed inside the recess, using solder.

Abstract: There is provided a surface mount oscillator of a junction type in which the size of an IC chip is increased while maintaining high performance thereof, and the outer dimension of the oscillator in plan view are small.

Abstract: An integrated circuit module with temperature compensation crystal oscillator (TCXO) applying to an electronic device comprises: one substrate having one top surface; one temperature compensation crystal oscillator (TCXO) disposed on the top surface; at least one chip disposed on the top surface; one encapsulating piece formed on the top surface for covering the TCXO and the chip. As above-described structure, TCXO is prevented from exchanging heat due to the temperature difference so that the stability of the TCXO is improved.

Abstract: A wideband frequency generator has two or more oscillators for different frequency bands, disposed on the same die within a flip chip package. Coupling between inductors of the two oscillators is reduced by placing one inductor on the die and the other inductor on the package, separating the inductors by a solder bump diameter. The loosely coupled inductors allow manipulation of the LC tank circuit of one of the oscillators to increase the bandwidth of the other oscillator, and vice versa. Preventing undesirable mode of oscillation in one of the oscillators may be achieved by loading the LC tank circuit of the other oscillator with a large capacitance, such as the entire capacitance of the coarse tuning bank of the other oscillator. Preventing the undesirable mode may also be achieved by decreasing the quality factor of the other oscillator's LC tank and thereby increasing the losses in the tank circuit.

Abstract: A method of manufacturing a surface mounted (crystal) device comprising: the steps of providing an aggregated sheet material having a plurality of container main bodies lengthwise and crosswise, accommodating at least a crystal piece inside the concavities of the plurality of container main bodies formed in the aggregated sheet material, and then parting the aggregated sheet material into individual container main bodies. The method further includes: the steps of providing annular grooves on outer perimeters between the container main bodies of the aggregated sheet material; positioning an outer peripheral edge of an electrode roller having an inclined face of a seam welder inside the annular groove; abutting the inclined face against a metal cover tacked to the container main body; bonding the metal cover to an aperture end face of the container main body, by seam welding; and then parting the aggregated sheet material into individual container main bodies.

Abstract: A surface-mount type crystal oscillator includes: a container body with a first recess and a second recess; a crystal blank including excitation electrodes on respective principal surfaces thereof and hermetically encapsulated in the first recess; and an IC chip which is accommodated in the second recess and into which at least an oscillation circuit using the crystal blank is integrated. The container body includes a bottom wall and a frame wall provided on the bottom wall. Two openings which make up the first and second recesses, respectively, are formed in juxtaposition in the frame wall. A pair of inspection terminals are provided in an area of a top surface of the frame wall which surrounds the second recess. The inspection terminals are electrically connected to the excitation electrodes of the crystal blank.

Abstract: The invention provides a multifunctional VC-TCXO that, as well as promoting miniaturization, selectively configures the functions as needed, and furthermore, is suitable for power savings. In a VC-TCXO provided with a chamber body that accommodates an IC chip and a crystal blank, the IC chip has; basic functions consisting of a first oscillator output function, and a temperature compensating function, and additional functions comprising of a second oscillator output function, an operation/non-operation function of the first oscillator output, and a temperature voltage output function, and basic IC terminals and additional IC terminals for these functions, and basic mounting terminals, and additional mounting terminals.

Abstract: An oscillator assembly including an oscillator seated on a pad of thermally conductive material formed on the surface of a printed circuit board and covered by a lid defining an oven for the oscillator. In one embodiment, a plurality of heaters are located on different sides of the oscillator and at least partially seated on the pad for evenly transferring heat to the pad and the oscillator. In one embodiment, the oscillator is a temperature compensated crystal oscillator and an integrated amplifier controller circuit on the printed circuit board integrates at least one operational amplifier for controlling the heater(s) and one or more transistors for providing heat to the oven. A canopy seated on the pad and covering the oscillator can be used for transferring heat more evenly to the oscillator. A cavity in the bottom of the printed circuit board defines an insulative air pocket.

Abstract: There are disclosed a surface mount crystal oscillator which can enhance a product quality and improve productivity while realizing miniaturization and a manufacturing method of the crystal oscillator. On wall faces of through holes formed in corner portions of a rectangular ceramic base, through terminals are formed; on the front surface of the ceramic base, leading terminals of crystal holding terminals which hold a crystal piece are connected to the diagonal through terminals; on the back surface of the ceramic base, mount terminals connected to the through terminals are formed; and an insulating film projected especially in a corner portion direction is formed at such a position as to face the opening end face of a metal cover.

Abstract: A surface mount crystal oscillator comprises a crystal blank, an IC chip having an oscillation circuit integrated thereon, and a hermetic package for accommodating the crystal blank and IC chip therein. The hermetic package comprises a substantially rectangular ceramic substrate formed with a metal film which makes a round on one main surface thereof, and a concave metal cover having an open end face bonded to the metal film. The IC chip is secured to the one main surface of the ceramic substrate through ultrasonic thermo-compression bonding using bumps, the crystal blank is disposed above the IC chip, and the ceramic substrate has the one main surface formed as a flat surface.

Abstract: The invention relates to an oven controlled crystal oscillator for surface mounting with reduced height (low profile). The oven controlled crystal oscillator for surface mounting comprises: a flat first substrate made of ceramic and on which are installed a crystal device and a heat resistor; and a second substrate made of a glass epoxy resin which is quadrangular in plan view and which faces the first substrate and has a larger external shape in plan view than the first substrate. The second substrate has an opening into whose center the crystal device is inserted, and has terminal sections on four locations corresponding to the surface outer periphery of the first substrate and the peripheral surfaces of the opening in the second substrate, and the terminal sections of the first substrate and second substrate are connected by solder.

Abstract: A package manufacturing method capable of preventing recess portions from being formed in penetration electrodes. The package manufacturing method includes an electrode member forming step of inserting core portions made of a metallic material into cylindrical members made of a first glass material and heating the cylindrical members so as to weld the cylindrical members to the core portions, thus forming electrode members; a hole forming step of forming holes, in which the electrode members 8 are disposed, on a penetration electrode forming board wafer made of a second glass material; an electrode member disposing step of disposing the electrode members in the holes formed on the wafer; a welding step of heating the wafer and the electrode members so as to be welded to each other; and a cooling step of cooling the wafer and the electrode members.

Abstract: A crystal oscillator is provided to secure a space for housing the IC and electronic components, even if the vibrator is small in size. In this crystal oscillator, there is not a hindrance to the wire connections between the IC and the electronic components, and the limitation on the vibrator and oscillator design is reduced. Also, the influence of the heat from the IC and the electronic components is made smaller. Thus, desired characteristics can be readily achieved with this crystal oscillator. In this crystal oscillator, the IC and the electronic components are housed in a concave portion formed in the ceramic package. A pedestal formed with a crystal plate made of the same material as the vibrator is provided to cover almost the entire opening of the concave portion, and the vibrator is placed on the pedestal.

Abstract: An object of the invention is to provide a surface mount type crystal oscillator in which a probe can be easily brought into contact with a crystal inspection terminal. The surface mount type crystal oscillator is such that a crystal piece and an IC chip are housed within a container main body having a bottom wall and frame wall formed with laminated ceramics, and a communication terminal is provided on an outer side surface of the container main body. The communication terminal is provided so as to span from the outer side surface of the bottom wall to the outer bottom surface of the outer wall, the communication terminal is made the crystal inspection terminal, and the crystal piece and the IC chip are arranged in parallel on the inner bottom surface within the container main body.

Abstract: There are disclosed a surface mount crystal oscillator which can enhance a product quality and improve productivity while realizing miniaturization and a manufacturing method of the crystal oscillator. On wall faces of through holes formed in corner portions of a rectangular ceramic base, through terminals are formed; on the front surface of the ceramic base, leading terminals of crystal holding terminals which hold a crystal piece are connected to the diagonal through terminals; on the back surface of the ceramic base, mount terminals connected to the through terminals are formed; and the opening end face of a metal cover joined onto the ceramic base via the molten resin comprises a flange having an inclined face in the surface mount crystal oscillator.

Abstract: A crystal device has an area defined inside a ceramic case thereof, and this area is made larger to increase the design freedom for mounting of a crystal unit (crystal element) in the crystal device. The crystal device is configured such that at least one crystal element is housed in a ceramic case in a rectangular form as seen in plan view. The crystal device includes the ceramic case having a bottom wall and a frame wall, and whose cross section is formed to be concave, and a metal cover jointed to a metal ring provided at an end face of the opening of the ceramic case by seam welding, to hermetically encapsulate the crystal element therein. The crystal device is configures such that one of the widths of the long side and the short side of the metal ring is shorter than the other one.

Abstract: There are disclosed a surface mount crystal oscillator which can enhance a product quality and improve productivity while realizing miniaturization and a manufacturing method of the crystal oscillator. On wall faces of through holes formed in corner portions of a rectangular ceramic base, through terminals are formed; on the front surface of the ceramic base, leading terminals of crystal holding terminals which hold a crystal piece are connected to the diagonal through terminals; and on the back surface of the ceramic base, mount terminals connected to the through terminals are formed in the surface mount crystal oscillator.

Abstract: A surface mount crystal oscillator comprises a crystal blank, an IC chip having an oscillation circuit integrated thereon, and a hermetic package for accommodating the crystal blank and IC chip therein. The hermetic package comprises a substantially rectangular ceramic substrate formed with a metal film which makes a round on one main surface thereof, and a concave metal cover having an open end face bonded to the metal film. The IC chip is secured to the one main surface of the ceramic substrate through ultrasonic thermo-compression bonding using bumps, the crystal blank is disposed above the IC chip, and the ceramic substrate has the one main surface formed as a flat surface.

Abstract: A surface-mounted device includes a ceramic case, which has a concave portion formed by a bottom wall layer, a frame wall intermediate layer and a frame wall upper layer, and which houses at least a crystal element inside the concave portion. The ceramic case includes: arc-formed notched parts at outer circumference four corners thereof; and mounting terminals, which are extended to notched parts in the bottom wall layer among the notched parts, on an outer bottom face thereof. A radius of curvature of the notched parts in the frame wall intermediate layer is made identical to or greater than a radius of curvature of the notched parts in the bottom wall layer, and a radius of curvature of the notched parts in the frame wall upper layer is less than the radii of curvature of the notched parts in the bottom wall layer and the frame wall intermediate layer.

Abstract: This invention relates to an oscillator having reduced sensitivity to acceleration. The oscillator includes a plurality of asymmetrically mounted resonator portions each having an active resonance region. The asymmetric mounting of the resonator portions means that each resonator portion has an axis passing through its active resonance region along which the acceleration sensitivity vector is dominant, i.e. the sensitivity to acceleration along the direction defined by one axis is much greater than the sensitivity to acceleration in other directions. The resonators are mounted in an oscillator such that their dominant axes are directed in different directions, e.g. an anti-parallel arrangement, which means that the dominant acceleration sensitivity vectors can cancel each other out.

Abstract: A piezoelectric oscillator includes: a piezoelectric resonator including a container, the container containing a piezoelectric resonator element: and a semiconductor device including an oscillation circuit for vibrating the piezoelectric resonator. The semiconductor device is bonded to a surface of the container. The container has an external coupling terminal and a cut-off part, the external coupling terminal being coupled to the semiconductor device, the cut-off part being disposed on a side surface of the container. The external coupling terminal is disposed in an area of the container, the area being opposed to the semiconductor device, and in the cut-off part. The semiconductor device has a coupling terminal on a surface thereof, the surface being opposed to the container. The coupling terminal of the semiconductor device and the external coupling terminal of the container are coupled with a conductive material.

Abstract: A surface-mount crystal oscillator includes: a crystal blank; an IC chip in which at least an oscillation circuit using the crystal blank is integrated, a plurality of IC terminals are provided on one principal surface, and a plurality of mounting terminals for surface mounting are provided on the other principal surface; and a housing member joined to the one principal surface of the IC chip and formed into a recessed shape. The crystal blank is fixed to crystal connection terminals out of the IC terminals, and is hermetically encapsulated in a space formed by the IC chip and the housing member. At least a power supply terminal, an output terminal and a ground terminal out of the IC terminals are electrically connected to the mounting terminals by a through-electrode provided to penetrate through the IC chip.

Abstract: An inventive temperature-compensated crystal oscillator has a construction such that a crystal oscillator element (5) is accommodated in a container (1) and an IC element (7) for controlling an oscillation output on the basis of the oscillation of the crystal oscillator element (5) is mounted on a lower surface of the container (1). A plurality of electrode pads (10) at least including plural crystal electrode pads connected to the crystal oscillator element (5), plural writing control electrode pads, and an oscillation output electrode pad, a ground electrode pad, a power source voltage electrode pad and an oscillation control electrode pad connected to surface mounting external terminals are arranged in a matrix configuration of m rows×n columns (wherein m and n are natural numbers not smaller than 2) in an IC element mounting area. The IC element (7) is electrically connected to the electrode pads (10).