Disclosed are methods, systems, and articles of manufacture for implementing schematic driven extracted views for an electronic design. These techniques identify a schematic circuit component design represented by a schematic symbol from a schematic design and identifying layout device information from a layout of the electronic design. An extracted view is generated anew or updated from an existing extracted view at least by placing and interconnecting a symbol in the schematic design based at least in part upon the layout device information. The electronic design may be further updated based in part or in whole upon results of performing one or more analyses on the extracted view.

The present invention relates to a method for manufacturing an electronic or electrical system, the method comprising the layer-free production of at least one physical structure (101, 102) which is designed to guide electromagnetic waves, using at least one additively operating apparatus, wherein the layer-free production of the spatial, layer-free structure comprises the simultaneous or sequential application and/or removal of one or more materials in the spatial arrangement, as a result of which the electronic or electrical system is partially or completely formed. The invention further relates to a system which is manufactured in accordance with the method.

The disclosure relates to methods and compositions for direct printing of rigid flexible electronic objects. Specifically, the disclosure relates to methods, systems and compositions for the direct, optionally simultaneous inkjet printing of rigid-flexible electronics, for example, rigid-flexible PCBs, FPCs, TFTs, antennae solar cells, RFIDs and the like, using a combination of print heads with flexible and rigid conductive and dielectric ink compositions.

A thermally expandable material includes microcapsules and a binder having a conducting property, each microcapsule including a shell having an insulating property, and a thermally expandable component contained in the shell and having a property of expanding by heating, the shell deforming due to expansion of the thermally expandable component to come in contact with another capsule and have an insulating state with the other capsule.

There is provided a computer readable storage medium storing a program executable by a computer, and the program causes the computer to execute functions including: forming a first image in accordance with an electronic circuit diagram, in which a resistance value of a wiring portion is defined, to form the wiring portion by printing with a conductive ink; and correcting the first image in accordance with a second image, which is formed with a photothermal conversion material, when the first image is formed at least partially overlapping the second image, wherein the second image is an image for expanding a thermally expandable layer that thermally expands with heat and, when the image is irradiated with light, expanding the thermally expandable layer by converting the light into heat with the photothermal conversion material.

A microcapsule includes a shell including a conducting component; and a thermally expandable component contained in the shell and having a property of expanding by heating, the shell deforming due to expansion of the thermally expandable component to come in contact with another capsule and have a conducting state with the other capsule.

A method for manufacturing an induction coil assembly is disclosed. The method includes preparing a Computer Aided Design (CAD) model of an induction coil. The method further includes communicating the CAD model of the induction coil with a Three Dimensional (3D) printing machine The method further includes operating the 3D printing machine to deposit a plurality of layers of copper material one above other to manufacture the induction coil corresponding to the CAD model. The method further includes forming at least one hole in an annular member of the induction coil to receive a coolant and at least one hole in a first leg and a second leg to discharge the coolant.

Methods are provided for manufacturing shape-retaining non-flat devices comprising components integrated on a device surface, the non-flat devices being made by deformation of a flat device. Based on the layout of a non-flat device, a layout of a flat device is designed. A method for designing the layout of such a flat device is provided, wherein the method includes inserting mechanical interconnections between pairs of elements to define the position of the elements on a surface of the non-flat device, thus leaving zero or less degrees of freedom for the location of the components. Based on the layout of a flat device thus obtained, the flat device is manufactured and next transformed into the shape-retaining non-flat device by means of a thermoforming process, thereby accurately and reproducibly positioning the elements at a predetermined location on a surface of the non-flat device.

An apparatus for detecting printed circuit board (PCB) design violations includes an analysis module that analyzes a position of a trace on a PCB design to determine conductivity of a design material over which the trace is being added and/or an electrical property of the trace at the position. The apparatus further includes an identification module that identifies, in real time, a void violation on the PCB design in response to the design material including a non-conductive material and/or a reference voltage violation on the PCB design in response to the position including a voltage and a notification module that notifies a user of the void violation and/or the reference voltage violation. At least a portion of said modules include hardware circuits, a programmable hardware device, and/or executable code stored on one or more non-transitory computer-readable storage media.

An electronic breadboard system may include a computing device including a display screen. The display screen has a first portion to display an electronic circuit model and a second portion directly adjacent to the first portion. The electronic breadboard system also includes a translucent breadboard on the second portion of the display screen. The translucent breadboard includes a translucent face plate having a rectangular grid of openings exposing a plurality of contacts. The plurality of contacts are arranged lengthwise along each row of the rectangular grid of openings and orthogonal to a transparent back plate coupling the plurality of contacts to the translucent face plate. The electronic breadboard system includes a graphics controller. The graphics controller may illuminate a row opening and/or a column opening of the translucent breadboard to direct placement of electrical components of a computer model in response to user interaction with the electronic circuit model.