The present disclosure relates to a smart textile product and a method for manufacturing a smart textile product. The smart textile product is provided with a flexible and/or stretchable textile fabric (10) comprising a plurality of electrically conductive threads (11, 12) and at least one rigid electronic or optoelectronic component (20) comprising at least one electrically conductive pad (21, 22), which is in electrical contact with at least one of the plurality of electrically conductive threads. The smart textile product (10) comprises an elastomeric encapsulation layer (31) in which the electrical connection (1, 2) is embedded, so as to provide a gradual transition in deformability between the flexible and/or stretchable textile fabric (10) and the at least one rigid component (20) at the location of the at least one electrical connection (1, 2).

Multilayer structure (200) for electronic devices, including a flexible substrate film (102) for accommodating electronics, a number of electrical elements (204, 206) provided to the flexible substrate film, preferably by element of printed electronics and/or surface mounting, a protective layer (104) laminated onto at least first surface of the substrate film, the protective layer being configured to mask perceivable physical deviation of the substrate, such as uneven surface profile or coloring, substantially at the location of the number of elements, from outside perception, optionally visual perception and/or tactile inspection taking place via the protective layer, and plastic layer (106) molded over at least second surface of the substrate film opposite to the first surface. A corresponding method of manufacture is presented.

A compliant electronic device is presented. The device may be, for example a wearable display for sports applications. The compliant electronic device comprises a thin sheet with a regular pattern of openings optimized to provide maximum compliance. The device may be partially or completely embedded in foam or other highly stretchable and compressible material that, while preserving compliance, protects the device from untoward environmental influences.

Disclosed is an elastic electrical contact terminal capable of implementing a reliable electrical connection between objects. The electrical contact terminal comprises: an elastic core; a silicone rubber adhesive applied to the outer surface of the elastic core; and an electrically conductive fiber wrapped around and bonded to the elastic core by means of being interposed with the silicone rubber adhesive, wherein a sheet has a polymer coating layer formed on the inner surface thereof facing the silicone rubber adhesive, and has a metal layer formed on the outer surface thereof.

Disclosed is a method for producing a semiconductor device including a circuit board having a flexible resin layer that encapsulates a circuit component. The method may include a step of immersing a flexible substrate in an encapsulant, drying the encapsulant, and thereby encapsulating the circuit component with the encapsulant; and a step of curing the encapsulant, and thereby forming a flexible resin layer.

A power semiconductor substrate comprising an insulating planar base, at least one conductor track and at least one contact area as part of the conductor track, wherein a layer of a metallic material is disposed on the contact area by means of pressure sintering. The associated method comprises the steps of: producing a power semiconductor substrate that includes a planar insulating base, conductor tracks and contact areas; arranging a pasty layer, composed of a metallic material and a solvent, on at least one contact area of the power semiconductor substrate; and applying pressure to the pasty layer.

According to at least one aspect, a lighting device is provided. The lighting device comprises a circuit board, an LED mounted to the circuit board that is configured to emit light with an angular CCT deviation, a lens assembly mounted to the circuit board over the LED and configured to receive the light emitted from the LED and reduce the angular CCT deviation of the light received from the LED to make a color temperature of the light received from the LED more uniform, and an elastomer encapsulating at least part of the circuit board that is separate and distinct from the lens assembly.

A flexible and/or stretchable structural system for transmitting electrical signal between first and second rigid portions comprises a body structure and said first and second portions arranged to said body structure. The modulus of elasticity of said first portion is lower than the corresponding modulus of elasticity of said second portion. In addition the modulus of elasticity of said body structure is lower than the corresponding modulus of elasticity of said second portion. The system comprises also an interface portion, such as e.g. an electrically conducting fabric, textile or knit, which is arranged to said body structure and between said first and second portions. The interface portion electrically connects said first and second portions. The modulus of elasticity of said interface portion is lower than the corresponding modulus of elasticity of said second portion.

A wiring board includes a first substrate having stretchability, wiring disposed adjacent to a first surface of the first substrate and extending in a first direction, and a stopper disposed adjacent to the first surface or second surface of the first substrate. While stretch length of the wiring board is being increased in the first direction, electrical resistance of the wiring exhibits a first turning point at a first stretch length and tension applied to the wiring board exhibits a second turning point at a second stretch length smaller than the first stretch length. The first turning point is a point at which an increase in electrical resistance per unit stretch length changes. The second turning point is a point at which an increase in tension per unit stretch length changes.

Various embodiments include an electrical assembly with: an electronic switching element electrically contacted on an underside and arranged on a flexible first wiring support; wherein the electronic switching element is electrically contacted on an upper side lying opposite the lower side; and a second wiring support arranged lying opposite the first wiring support on the upper side electrical contacting area of the electronic switching element. The first wiring support and the second wiring support each comprise a permanently elastic, electrically insulating, thermally conductive material.