There is provided a computer structure comprising a first silicon substrate and a second silicon substrate. Computer circuitry configured to perform computing operations is formed in the first silicon substrate, which has a self-supporting depth and an inner facing surface. A plurality of distributed capacitance units are formed in the second silicon substrate, which has an inner facing surface located in overlap with the inner facing surface of the first substrate and is connected to the first substrate via a set of connectors arranged extending depthwise of the structure between the inner facing surfaces. The inner facing surfaces have matching planar surface dimensions. The second substrate has an outer facing surface on which are arranged a plurality of connector terminals for connecting the computer structure to a supply voltage. The second substrate has a smaller depth than the first substrate.

One manner of producing more desirable clothing with electronic capabilities is to manufacture electronics, such as the charging wires or devices themselves, directly onto the textile materials. Textile materials generally do not support the manufacturing of electronic devices, in part because the surface of the textile is too rough for electronic devices or the processes used to manufacture electronic devices. An intermediate layer may be placed on the textile material to reduce the roughness of the surface of the textile material and provide other beneficial characteristics for the placement of electronic devices directly on the textile material.

A fingerprint identification apparatus and an electrode device. The fingerprint identification apparatus could be configured to be disposed under a variety of different display screens, reducing a thickness of space for installation of the fingerprint identification apparatus under a screen. The fingerprint identification apparatus includes: a support plate; and at least one fingerprint sensor chip, the at least one fingerprint sensor chip being disposed at an upper surface of the support plate; where the support plate is configured to be mounted to an upper surface of a middle frame of the electronic device so that the at least one fingerprint sensor chip is located under the display screen of the electronic device; and the at least one fingerprint sensor chip is configured to receive a fingerprint detecting signal returned by reflection or scattering via a human finger on the display screen.

A circuit board includes a substrate including first and second sections with different thicknesses, a protective layer, and mounting electrodes. The substrate includes a step surface connecting a first principal surface of the first section and a first principal surface of the second section. The mounting electrodes are on the first principal surface corresponding to an element to be mounted. The protective layer is disposed over the first principal surface, the step surface, and the first principal surface. The separation distance between the mounting electrode and the step surface is greater than or equal to the terminal-to-terminal distance between the mounting electrode and the mounting electrode.

The invention provides a light generating device (1000) comprising s1 light sources (100) and a support (200) configured to support the s1 light sources (100), wherein the s1 light sources (100) are configured to generate light source light (101), wherein s1>1 and wherein: (a) the support (200) comprises n1 domains (210), wherein n1>3, wherein the support (200) comprises k1 fold lines (220), wherein k1>2, wherein at least three of the n1 domains (210) are separated by at least two of the k1 fold lines (220); wherein the domains (210) have a first domain side (211) and a second domain side (212); (b) the at least three of the n1 domains (210) and the at least two of the k1 fold lines (220) are configured parallel; and (c) the light generating device (1000) comprises m1 adhesive layers (400), wherein m1>2; and wherein at least two of the m1 adhesive layers (400) are functionally coupled to different domain sides (211,212) of one or more domains (210).

A method for manufacturing a semi-flex printed circuit board is provided, including: forming two convex metal dam structures and two concave laser cut grooves on a side surface of the core substrate; wherein inner sides of the two metal dam structures form a printing area at the side surface of the core substrate, and the positions of the two laser cut grooves correspond to the printing area; printing a strippable printing ink in the printing area on the core substrate; laminating a build-up board structure on the side surface of the core substrate; and forming two blind routing openings on another side surface of the core substrate, which correspond to the two laser cut grooves in position respectively; removing a cover-opening structure of the core substrate between the two blind routing openings, so as to form a cover-opening opening.

Electronic Devices Incorporating Flexible Component Layers with Interlocking Devices At least some aspects of the present disclosure directs to an electronic device 100 comprising a rigid member 100A, 100B, a flexible component layer 130, and an interlocking device 110A, HOB disposed between the flexible component layer and the rigid member. The flexible component layer has at least two sections when the flexible component layer is flexed. The interlocking device comprises a first interlocking component attached to or integrated with the flexible component layer, and a second interlocking component attached to or integrated with the rigid member configured to engage with the first interlocking component, such that the engagement prevents the separation of the flexible component layer from the rigid member along a direction generally perpendicular to a surface of the rigid member.

A flexible conductive track arrangement has a pre-flexing condition in which the arrangement is generally planar. Conductive tracks are formed from a metal layer and they are covered above and below by insulator layers. The elongate conductive tracks are generally planar but locally corrugated perpendicularly to the general plane. This enables improved binding performance, for example to form tight windings using the conductive tracks.

A fastener structure includes a body portion and a fastening body. The body portion has a solderable layer, and the solderable layer is soldered to a plate body. The fastening body combines movably with the body portion. The fastening body has a head and a fastening portion. The body portion or the fastening body, or both the body portion and the fastening body is provided on the plate body for soldering after it is picked up by a tool so that the body portion can combine with the plate body. Also, the body portion or the fastening body, or both the body portion and the fastening body combines with a assisting pickup unit, and the fastener structure is provided on the plate body for soldering after it is picked up by a tool through the assisting pickup unit so that the body portion can combine with the plate body.

An electronic apparatus includes: an electronic component; a substrate including a first layer at which the electronic component and a first ground pattern are disposed, and a second layer at which a second ground pattern is disposed; and a case which is in contact with the first ground pattern, covers the electronic component, reduces magnetic noise, and is fixed to the substrate, and plural conductors connecting the first ground pattern and the second ground pattern are disposed along a portion of the first ground pattern, the portion being in contact with the case.