An electronic component housing package includes an insulating substrate including a first surface with a mounting region mounting an electronic component, a second surface located opposite to the first surface, a plurality of side surfaces located between the first surface and the second surface, and a corner portion located between two of the side surfaces; an external connection conductor located on the second surface; and a corner conductor connected to the external connection conductor. The corner conductor is located from the external connection conductor toward the corner portion in a manner to increase the distance from the second surface.

A copper base substrate of the present invention, in which a copper substrate, an insulating layer, and a circuit layer, are laminated in an order in the copper substrate, a ratio of a thickness (unit: .Math.m) to an elastic modulus (unit: GPa) at 100° C. is 50 or more in the insulating layer, and the circuit layer has an elastic modulus at 100° C. of 100 GPa or less.

An electronic device includes a first board, a second board, and support pillars. The support pillars hold the first board and the second board mutually separated. The first board has a first surface on which an electronic component is mounted. The first board has a second surface that includes depressed portions into which the support pillars extending from the second board are inserted.

To reduce, when a single encapsulated circuit module has electronic components that are mutually influenced by their electromagnetic waves, the mutual influence.

A encapsulated circuit module M has a substrate 100 on which a number of electronic components 200 are mounted. An electronic component 200A is a high frequency oscillator. A metal side wall 320 of a partition member is provided on the substrate 100. One surface of the substrate 100 is entirely covered with a first resin 400 together with the electronic components 200 and the side wall 320. The first resin 400 is covered with a metal shield layer 600 for shielding electromagnetic waves. The electronic component 200A is surrounded by the side wall 320 and the shield layer 600.

Close-contact layers that are capable of improving the degree of contact between electrodes and a ceramic insulating layer can be formed at low cost by firing a glass paste. When the electrodes, the ceramic insulating layer, and the close-contact layers are fired at the same time, the glass paste is sintered last, and thus, formation of voids, defects, and the like in portions of the ceramic insulating layer, on which the electrodes are disposed, as a result of shrinkage of the electrodes and the ceramic insulating layer at the time of firing being hindered by stress generated due to the difference in the degree of shrinkage can be suppressed. Therefore, the structure of the ceramic insulating layers in the above portions can be elaborated by the close-contact layers.

The present invention provides a micropackaged device comprising: a substrate for securing a device; a corrosion barrier affixed to said substrate; optionally at least one feedthrough disposed in said substrate to permit at least one input and or at least one output line into said micropackaged device; and an encapsulation material layer configured to encapsulate the micropackaged device.

An oven controlled crystal oscillator consisting of heater-embedded ceramic package includes a substrate, a crystal package, a crystal blank, a metal lid, a first IC chip, and a cover lid. The crystal package is mounted on the substrate, and a central bottom of the crystal package is provided with the first IC chip. The crystal blank is mounted in the crystal package and sealed by the metal lid. The crystal package has an embedded heater layer establishing a symmetric thermal field with respect to the first IC chip and the crystal blank. Alternatively, a heater-embedded ceramic carrier substrate is arranged between the first IC chip and the crystal blank to establish a symmetric thermal field with respect to the first IC chip and the crystal blank. The cover lid is combined with the substrate to cover the crystal package and the metal lid.

An electronic device and oscillator structure are provided. The electronic device includes a printed circuit board, an oscillator configured to oscillate at a frequency corresponding to an operation clock of the electronic device, and a connection member disposed between the oscillator and the printed circuit board such that the oscillator is spaced apart from a surface of the printed circuit board to electrically connect the oscillator to the printed circuit board. The connection member includes a first pad part electrically connected to a terminal of the oscillator, a second pad part electrically connected to a pad of the printed circuit board, and at least one conductive pattern electrically connecting the first pad part and the second pad part.

The present disclosure discloses a crystal oscillator circuit on a PCB. The crystal oscillator circuit includes a crystal oscillator including an input end, an output end, a first grounding end and a second grounding end; a first capacitor with one end connected to the input end; and a second capacitor with one end connected to the output end, wherein the first grounding end is connected to a first grounding hole, the second grounding end is connected to a second grounding hole, the other end of the first capacitor is connected to a third grounding hole, the other end of the second capacitor is connected to a fourth grounding hole. The present disclosure further discloses the PCB and a server.

A module comprises: a wiring board; a first component, a second component and a third component mounted on a first main surface; a shield structure mounted on the first main surface; a first sealing resin that seals the first component and the like; and a shield film that covers an upper surface of the first sealing resin and the like, the shield structure including a top side portion and at least one sidewall portion bent from the top side portion and thus extending therefrom, the top side portion including the top side portion's conductive layer and a magnetic layer therein, the sidewall portion including the sidewall portion's conductive layer therein, the top side portion's conductive layer and the sidewall portion's conductive layer being electrically connected to a ground conductor, the magnetic layer in the top side portion being located over the first component.