A electronic component including a first protective layer covering the substrate and the conductive tract, a second protective layer covering at least a portion of the first protective layer, wherein the second protective layer includes Parylene, and a third protective layer covering at least a portion of the second protective layer.

A mouth guard senses impact forces and determines if the forces exceed an impact threshold. If so, the mouth guard notifies the user of the risk for injury by haptic feedback, vibratory feedback, and/or audible feedback. The mouth guard system may also remotely communicate the status of risk and the potential injury. The mouth guard uses a local memory device to store impact thresholds based on personal biometric information obtained from the user and compares the sensed forces relative to those threshold values. The mouth guard and its electrical components on the printed circuit board are custom manufactured for the user such that the mouth guard provides a comfortable and reliable fit, while ensuring exceptional performance.

A module includes: a substrate having a main surface and a side surface; an electronic component mounted on the main surface; a sealing resin that covers the main surface and the electronic component; and a shield film that covers a surface of the sealing resin and the side surface of the substrate. The sealing resin includes: a resin component containing an organic resin as a main component; and a granular filler containing an inorganic oxide as a main component. On a surface of the sealing resin, which is in contact with the shield film, parts of some grains of the filler are exposed from the resin component, a surface of the resin component includes a nitrogen functional group, and the shield film is formed of a metal that is a passivation metal and a transition metal or an alloy containing the metal.

An electronic component module includes a board, an electronic component, a sealing portion, a metal layer, and a magnetic layer. The board has a first main surface. The electronic component is provided on a first main surface of the board. The sealing portion seals the electronic component. The metal layer covers the sealing portion. The magnetic layer is provided between the sealing portion and the metal layer. The magnetic layer has a magnetic main body and a first cover sheet. The first cover sheet is provided between the magnetic main body and the metal layer. The first cover sheet has a first main surface and a second main surface. The first main surface faces the magnetic main body. The second main surface faces the metal layer. The second outer peripheral end of the second main surface is located inside the first outer peripheral end of the first main surface.

An electronic device module includes a first substrate, at least one electronic device mounted on a lower surface of the first substrate, a second substrate mounted on a lower surface of the first substrate to electrically connect the first substrate to an external source of power, a connecting conductor bonded to a lower surface of the second substrate, and a sealing portion sealing the electronic device, the second substrate, and the connecting conductor, wherein a mounting height of the second substrate is configured to be lower than a mounting height of the electronic device.

The method for manufacturing a number of electrical nodes, wherein the method includes providing a number of electronic circuits onto a first substrate, such as on a printed circuit board or other electronics substrate, optionally, a low-temperature co-fired ceramic substrate, wherein each one of the electronic circuits includes a circuit pattern and at least one electronics component in connection with the circuit pattern, wherein the electronic circuits are spaced from each other on the first substrate, thereby defining a blank area surrounding each one of the number of electronic circuits, respectively, and providing potting or casting material to embed each one of the number of electronic circuits in the potting or casting material, and, subsequently, hardening, optionally including curing, the potting or casting material to form a filler material layer of the number of electrical nodes.

Audio device, electronic circuit, and related methods, in particular a method of manufacturing an electronic circuit for an audio device is disclosed, the method comprising providing a circuit board; mounting one or more electronic components including a first electronic component on the circuit board; applying a first insulation layer outside the first electronic component; and applying a first shielding layer outside the first insulation layer.

A liquid metal-based flexible electron device and a preparation method are disclosed. In the method, 3D printing and the characteristic that ABS plastic can be dissolved by acetone are utilized, and a microchannel is quickly constructed in the flexible substrate of Ecoflex, and liquid metal is then injected into the microchannel to complete the manufacturing of a flexible electronic device. The gold film on the surface of ABS is transferred to the surface of the flexible Ecoflex substrate.

The method for manufacturing a number of electrical nodes, wherein the method includes providing a number of electronic circuits onto a first substrate, such as on a printed circuit board or other electronics substrate, optionally, a low-temperature co-fired ceramic substrate, wherein each one of the electronic circuits includes a circuit pattern and at least one electronics component in connection with the circuit pattern, wherein the electronic circuits are spaced from each other on the first substrate, thereby defining a blank area surrounding each one of the number of electronic circuits, respectively, and providing potting or casting material to embed each one of the number of electronic circuits in the potting or casting material, and, subsequently, hardening, optionally including curing, the potting or casting material to form a filler material layer of the number of electrical nodes.

The present invention relates to the field of electronic devices, in particular implantable electronic devices, e.g. for bio-medical applications, and more particularly, to hermetically packaged electronic devices for bio-medical in vivo applications and packaging methods for such electronic devices.