An antenna device includes a resin multilayer board in which a plurality of resin sheets are stacked, and a coil conductor provided in the resin multilayer board. A plurality of line portions of the coil conductor are provided on a lower surface of the resin sheet. When a magnetic material core is preliminarily pressure-bonded to the resin sheet, the magnetic material core is fractured along the line portions and cracks occur. Thus, the resin sheet with the magnetic material core in which the cracks have been formed is fully pressure-bonded together with the other resin sheets.

A stretchable circuit board includes plural stretchable bases, and plural stretchable wiring portions, at least one of which is provided on each of main surfaces, facing each other, of the plural stretchable bases, in which the stretchable wiring portions provided on the main surfaces are electrically continuous with each other through a connecting portion.

A method for forming thin film conductors is disclosed. A thin film precursor material is initially deposited onto a porous substrate. The thin film precursor material is then irradiated with a light pulse in order to transform the thin film precursor material to a thin film such that the thin film is more electrically conductive than the thin film precursor material. Finally, compressive stress is applied to the thin film and the porous substrate to further increase the thin film's electrical conductivity.

A conductive tape formed by laying a conductive pathway on a tape layer is disclosed. Various apparatus and methods for laying conductive pathways to form conductive tape are disclosed. The conductive pathways may be laid by varying the lateral position of the conductive pathway on the tape substrate. Such patterns all stretchable conductive tape to be realized. Multiple conductive pathways may be laid in the tape and the lateral separation of the pathways in the tape may vary. In some embodiments the pathways are formed from conductive yarn or by printing or laying conductive ink.

Provided are circuit board excellent in interlayer adhesion and solder heat resistance, and production method thereof. The circuit board is produced by a method including: preparing a plurality of at least one kind of thermoplastic liquid crystal polymer (TLCP) films, forming a conductor layer on one side or both sides of a film in at least one of the films to obtain a unit circuit board, laminating the films containing the unit circuit board to obtain a stacked material, conducting thermo-compression-bonding of the stacked material under pressurization to a first temperature giving an interlayer adhesion to integrate the stacked material, carrying out structure-controlling thermal treatment by heating the integrated stacked material at a second temperature which is lower than the first temperature and is lower than a melting point of a TLCP having a lowest melting point out of the plurality of TLCP films.

Process for producing an electronic subassembly by low-temperature pressure sintering, comprising the following steps: arranging an electronic component on a circuit carrier having a conductor track, connecting the electronic component to the circuit carrier by the low-temperature pressure sintering of a joining material which connects the electronic component to the circuit carrier, characterized in that, to avoid the oxidation of the electronic component or of the conductor track, the low-temperature pressure sintering is carried out in a low-oxygen atmosphere having a relative oxygen content of 0.005 to 0.3%.

A driver mounting apparatus 40 includes a driver mount-side heat supply support member 42, a substrate support member 41, a driver-side heat supply support member 43, a first moving portion 44, and a second moving portion 45. The driver mount-side heat supply support member 42 supports a driver mount portion GSd and supplies heat to the driver mount portion GSd. The substrate support member supports a substrate main portion GSm. The driver-side heat supply support member 43 supports and sandwich a driver 21 with the driver mount-side heat supply support member 42 and supplies heat to the driver 21. The first moving portion 44 relatively moves the driver mount portion GSd and the driver mount-side heat supply support member 42 in an overlapping direction in which the glass substrate GS and the driver 21 are overlapped. The second moving portion 45 relatively moves the driver 21 and the driver-side heat supply support member 43 in the overlapping direction.

A method for producing an electronic module includes providing a first substrate including at least one first electrical contacting surface, an electronic component including at least one second electrical contacting surface, and a first material layer made of a thermoplastic material including at least one recess extending through the material layer. The first substrate, the electronic component and the first material layer are arranged with the first material layer disposed between the first substrate and the electronic component, and the at least one first electrical contacting surface, the at least one second electrical contacting surface and the at least one recess aligned relative to one another. The first substrate, the electronic component and the material layer are thermocompression bonded. A joint formed between the at least one first electrical contacting surface and the at least one second electrical contacting surface is surrounded or enclosed by the first material layer.

A step of scattering electrically conductive particles on a wiring board having wiring that is formed in accordance with an array pattern of the electrically conductive particles and prevented from being charged, and charging the electrically conductive particles; a step of aligning the charged electrically conductive particles in a predetermined array pattern corresponding to the wiring pattern by moving a squeegee on the wiring board; and a step of bonding a transfer film having an adhesive material layer formed thereon to the wiring board and transferring the electrically conductive particles aligned in a predetermined array pattern to the adhesive layer.

Soldering is performed with a high yield ratio even when extremely-thin wires are joined at an extremely-narrow pitch. Moreover, a bridge between conductive joint portions is reduced. A core wire 41 is placed on a preliminarily-soldered conductive joint portion 2. Then, the conductive joint portions 2 and the core wires 41 are covered with an optically-transparent sheet 30. Thus, the state in which the core wire 41 is placed on the conductive joint portion 2 is held. In this state, the optically-transparent sheet 30 is irradiated with light. A preliminary solder 3 is heated and melted to join the core wire 41 and the conductive joint portion 2 together.