Abstract: A method for manufacturing an electromechanical structure, including producing conductors on a flat film; estimating a strain a plurality of locations of the flat film will undergo during formation thereof into a three-dimensional film; attaching electronic elements on the flat film at selected locations of the plurality of locations of the flat film, wherein the estimated strain of the selected locations of the plurality of locations is less than the estimated strain in other locations of the plurality of locations; forming the flat film into the three-dimensional film; and injection molding material on the three-dimensional film.

Abstract: An electronic device includes a substrate film having a first side and a second side, and a number of light sources configured to emit light. A plastic lightguide layer is molded onto the first side of the substrate film. The plastic lightguide layer being of optically at least translucent material to transmit light. The device also includes a masking layer provided on the outer surface of the plastic lightguide layer. The masking layer defines a window for letting the light emitted by the embedded light sources to pass through the masking layer towards the environment.

Abstract: Multilayer assembly for an electronic device includes a substrate film configured to accommodate electronics, said film having the first side and a second side, at least one area light source and configured to emit light of predetermined frequency or frequency band, a molded lightguide layer, the lightguide layer being of optically at least translucent material, wherein the lightguide layer is configured to transmit light emitted by the embedded light source so that the transmitted light propagates within the lightguide layer and is outcoupled therefrom via an outer surface thereof substantially opposite to the embedded light source, and a masking layer provided on the outer surface of the plastic lightguide layer, containing substantially opaque material to block external view of at least some internals of the multilayer structure, wherein the masking layer defines a window for letting the light emitted by the embedded light source and propagated within the plastic lightguide layer to pass through the maskin

Abstract: A method for manufacturing an electromechanical structure, includes producing conductors and/or graphics on a substantially flat film, attaching electronic elements on the said film in relation to the desired three-dimensional shape of the film, forming the said film housing the electronic elements into a substantially three-dimensional shape, and using the substantially three-dimensional film as an insert in an injection molding process by molding substantially on said film, wherein a preferred layer of material is attached on the surface of the film. A corresponding arrangement for carrying out the method is also presented.

Abstract: A method for manufacturing a multilayer structure, includes obtaining a substrate film for accommodating electronics, providing, preferably at least in part by printed electronics technology, a number of conductive traces, and optionally electronic components, at least on a first side of the substrate film to establish a predetermined circuit design, providing a connector element to said substrate film to electrically connect to the circuit, wherein the substrate film is arranged with at least one hole, preferably through hole, substantially matching the location of the connector element so that a number of electrically conductive contact members of the connector element are accessible from a second, opposite side of the substrate film via said at least one hole, and molding thermoplastic material on said first side of the substrate film and said connector element to substantially cover the established circuit and the side of the connector element facing the material.

Abstract: A method for manufacturing a strain gauge device and a strain gauge device are presented. The method includes obtaining a first substrate, preferably a first formable substrate film for accommodating electronic components, printing by a printed electronics method, such as by screen printing or inkjet printing, a strain gauge on the first substrate, and molding, preferably by utilizing injection molding, a molded material layer embedding the strain gauge. The strain gauge device may comprise two, preferably formable, substrate films between which the strain gauge and the molded material layer may be arranged.

Abstract: An apparatus for carrying out a manufacturing method of an electromechanical structure apparatus includes an entity for producing conductors on a flat film, an entity for attaching electronic elements at locations on the flat film in relation to the desired three-dimensional shape of the flat film, the electronic elements including a number of SMT components, the locations of the electronic elements on the flat film selected such that the locations omit substantial deformation during subsequent 3D forming of the flat film, an entity for forming the flat film into a three-dimensional film and an entity for injection molding.

Abstract: An electronic arrangement for facilitating circuit layout design in connection with three-dimensional (3D) target designs, the arrangement including at least one communication interface for transferring data, at least one processor for processing instructions and other data, and a memory for storing the instructions and other data. The at least one processor being configured, in accordance with the stored instructions, to cause: obtaining and storing information in a data repository hosted by the memory, receiving design input characterizing 3D target design to be produced from a substrate, determining a mapping between locations of the 3D target design and the substrate, and establishing and providing digital output comprising human and/or machine readable instructions indicative of the mapping to a receiving entity, such as a manufacturing equipment, e.g. printing, electronics assembly and/or forming equipment.

Abstract: Multilayer structure, including a substrate film having a first and second opposite side, said substrate film including electrically insulating material, conductive traces on the first side of the substrate film for establishing a predetermined circuit design, a connector element laid upon the first side of, said substrate film, one side of the connector element facing the structure internals and the other, opposite side facing the environment on the second side of the substrate film including a number of electrically conductive contact members electrically connected to the circuit on the first side of the substrate film and configured to contact one or more electrical contact members of an external element responsive to mating the external element with the connector element, and a plastic layer molded onto the substrate film and the connector element so as to cover said one side of the connector element and the circuit.

Abstract: An electronic arrangement for facilitating circuit layout design in connection with three-dimensional (3D) target designs, the arrangement including at least one communication interface for transferring data, at least one processor for processing instructions and other data, and a memory for storing the instructions and other data. The at least one processor being configured, in accordance with the stored instructions, to cause: obtaining and storing information in a data repository hosted by the memory, receiving design input characterizing 3D target design to be produced from a substrate, determining a mapping between locations of the 3D target design and the substrate, and establishing and providing digital output comprising human and/or machine readable instructions indicative of the mapping to a receiving entity, such as a manufacturing equipment, e.g. printing, electronics assembly and/or forming equipment.

Abstract: Method for manufacturing an electromechanical structure, comprising: producing conductors and/or graphics on a substantially flat film 106, attaching electronic elements on the said film 108 in relation to the desired three-dimensional shape of the film, forming the said film housing the electronic elements into a substantially three-dimensional shape 110, using the substantially three-dimensional film as an insert in an injection molding process by molding substantially on said film 112, wherein a preferred layer of material is attached on the surface of the film, creating an electromechanical structure. A corresponding arrangement for carrying out said method is also presented.

Abstract: A composite laminate assembly for an electronic device provides integrated backlighting for one or more indicator shapes defined by the assembly. The assembly includes a substantially opaque cover member to obscure at least parts of the electronic device. Translucent indicator structures in the cover member define respective indicator shapes to allow backlighting to pass through the cover member. An optical matrix layer of an optically conductive material is attached to an inner face of the cover member, with a plurality of lighting devices embedded in the optical matrix layer and laterally offset from associated indicator structures. The plurality of lighting devices may be connected to an electric circuit carried on the inner face of the cover member.

Abstract: A composite laminate assembly for an electronic device provides integrated backlighting for one or more indicator shapes defined by the assembly. The assembly includes a substantially opaque cover member to obscure at least parts of the electronic device. Translucent indicator structures in the cover member define respective indicator shapes to allow backlighting to pass through the cover member. An optical matrix layer of an optically conductive material is attached to an inner face of the cover member, with a plurality of lighting devices embedded in the optical matrix layer and laterally offset from associated indicator structures. The plurality of lighting devices may be connected to an electric circuit carried on the inner face of the cover member.

Abstract: Method for manufacturing an electromechanical structure, com-prising: producing conductors and/or graphics on a substantially flat film 106, attaching electronic elements on the said film 108 in relation to the de-sired three-dimensional shape of the film, forming the said film housing the electronic elements into a substantially three-dimensional shape 110, using the substantially three-dimensional film as an insert in an injection molding process by molding substantially on said film 112, wherein a preferred layer of material is attached on the surface of the film, creating an electromechanical structure. A corresponding arrangement for carrying out said method is also presented.

Abstract: A composite laminate assembly for an electronic device provides integrated backlighting for one or more indicator shapes defined by the assembly. The assembly includes a substantially opaque cover member to obscure at least parts of the electronic device. Translucent indicator structures in the cover member define respective indicator shapes to allow backlighting to pass through the cover member. An optical matrix layer of an optically conductive material is attached to an inner face of the cover member, with a plurality of lighting devices embedded in the optical matrix layer and laterally offset from associated indicator structures. The plurality of lighting devices may be connected to an electric circuit carried on the inner face of the cover member.

Abstract: A composite laminate assembly for an electronic device provides integrated backlighting for one or more indicator shapes defined by the assembly. The assembly includes a substantially opaque cover member to obscure at least parts of the electronic device. Translucent indicator structures in the cover member define respective indicator shapes to allow backlighting to pass through the cover member. An optical matrix layer of an optically conductive material is attached to an inner face of the cover member, with a plurality of lighting devices embedded in the optical matrix layer and laterally offset from associated indicator structures. The plurality of lighting devices may be connected to an electric circuit carried on the inner face of the cover member.

Abstract: A composite laminate assembly for an electronic device provides integrated backlighting for one or more indicator shapes defined by the assembly. The assembly includes a substantially opaque cover member to obscure at least parts of the electronic device. Translucent indicator structures in the cover member define respective indicator shapes to allow backlighting to pass through the cover member. An optical matrix layer of an optically conductive material is attached to an inner face of the cover member, with a plurality of lighting devices embedded in the optical matrix layer and laterally offset from associated indicator structures. The plurality of lighting devices may be connected to an electric circuit carried on the inner face of the cover member.

Abstract: Arrangement (202) for a user input device, such as a touchscreen or a touchpad, comprising a substrate (206), such as an optically substantially transparent flex film or a multilayer film, said substrate comprising support electronics (212) for providing power, control and/or communications connection to further electronic components (210), a number of emitters and detectors (210) arranged to said substrate into contact with the support electronics, for emitting and detecting light, respectively, and a lightguide (208) provided, such as laminated, onto the substrate such that said emitters and detectors are optically coupled to the lightguide material, the properties of the lightguide including the refractive index of the lightguide material being selected and the emitters and detectors being configured so as to enable, when in use, total internal reflection (TIR) -type propagation of light within the lightguide between the emitters and detectors, and recognition of a touch on the basis of a drop in the TIR p

Abstract: Arrangement (202) for a user input device, such as a touchscreen or a touchpad, comprising a substrate (206), such as an optically substantially transparent flex film or a multilayer film, said substrate comprising support electronics (212) for providing power, control and/or communications connection to further electronic components (210), a number of emitters and detectors (210) arranged to said substrate into contact with the support electronics, for emitting and detecting light, respectively, and a lightguide (208) provided, such as laminated, onto the substrate such that said emitters and detectors are optically coupled to the lightguide material, the properties of the lightguide including the refractive index of the lightguide material being selected and the emitters and detectors being configured so as to enable, when in use, total internal reflection (TIR) -type propagation of light within the lightguide between the emitters and detectors, and recognition of a touch on the basis of a drop in the TIR p