Provided is a method of measuring eccentricity of a blind via hole formed in a printed circuit board including an inner-layer board and an outer-layer board that are bonded by thermocompression bonding. The method includes acquiring, by a microscope camera, an image by photographing a marker which is formed on a surface of the outer-layer board and a blind via hole which is exposed upward through a marker hole formed in a center of the marker with a microscope camera, and measuring, by computing equipment connected to the microscope camera, eccentricity indicating a separation distance and a separation direction from central coordinates of the marker hole to central coordinates of the blind via hole using a distance between an end point of the marker hole and an end point of the blind via hole which are included in the image.

A system for controlled motion of circuit components to create reconfigurable circuits comprising: a support; a substrate operatively associated with the support; actuators operatively associated with the support configured to physically move circuit components and to move the circuit components into physical and electrical contact with the substrate; the substrate comprising at least one conductive segment arranged to electrically connect circuit components when electrical contacts of circuit components are placed in contact with at least one conductive segment; and control circuitry configured to control the first and second actuators to thereby position the circuit components relative to the substrate; whereby circuit function is determined by the selection of circuit components and the location and orientation of circuit components relative to the substrate and conductive segments to create a reconfigurable circuit.

The present disclosure relates to a machining station for machining platelike workpieces (1) by means of at least one tool, in particular a drilling station for machining at least one circuit board, as well as to a method for controlling or identifying a platelike workpiece (1). The machining station has at least one X-ray radiation source (3), at least one detector (4) and a table (2) that can be positioned between the X-ray radiation source (3) and the detector (4), on which the workpiece (1) to be machined can be fastened. The table (2) has a receiving plate (6) made out of a material permeable to X-rays (5), in particular a plastic. The receiving plate (6) has at least one suction port (11) for extracting air and a distribution grid, which is connected in terms of flow with the at least one suction port (11) and consists of several channels (10) unilaterally open in a support surface (9) with beveled and/or rounded edges (13) and/or of inclinedly running through openings (14).

An apparatus for manufacturing printing circuit boards is provided. The apparatus includes a microcontroller, power supply, two-dimensional stage, laser, and one or more chemical treatment tanks. The apparatus may include a mutlifunctional print module, or multiple independent tool modules capable of being exchanged, to perform various different processes on a substrate on the same build plate, and may include mechanical means for transporting the substrate during different stages between the build plate, chemical processing chamber(s), and a pressing chamber. A rapid, auto-calibrating loading system may be provided for the independent tool modules, and a camera provided for an optical registration operation.

Provided is a cover for pressing a printed circuit board on a heat sink, the cover comprising a metal sheet and one or more domes arranged in the metal sheet, wherein each dome is associated with one or more slits in the shape of ring segments in the metal sheet, the ring segment-shaped slits being provided in the metal sheet side by side and spaced apart from each other, the ring segment-shaped slits surrounding the dome they are associated with. At least at one end of each ring segment-shaped slit a slit extension may be provided in the metal sheet, the slit extension at least in part pointing away from the dome the ring segment-shaped slit is associated with. Further provided is an electronic appliance that includes such a cover, a heat sink and an electronic circuit board sandwiched there between.

A stencil printer for printing an assembly material on an electronic substrate includes a frame, a stencil coupled to the frame, the stencil having apertures formed therein, a support assembly coupled to the frame, the support assembly being configured to support the electronic substrate, a print head gantry coupled to the frame, and a print head assembly supported by the print head gantry in such a manner that the print head assembly is configured to traverse the stencil during print strokes. The stencil printer further comprises a verification system to determine whether an item placed within the stencil printer is properly installed within the stencil printer.

System and methods to enable integration of electronic components to form LED assembly with a high accuracy (0.1 mm or better) and high process capability (Cpk of 1.67 or higher) for realizing precision electro-mechanical device. The system and methods use through holes that connect a printed circuit board to a housing as fiducial marks and LED emitter center as a reference point for alignment in order to improve the efficacy and accuracy of assembling of the LED assembly. The through holes are drilled by using laser drilling or milling machine, Use of adhesive to anchor the LED component down prior to reflow process i.e. to avoid self alignment characteristic of component on solder paste during reflow process.

A press-in machine for pressing electrical, electronic, mechanical and/or electromechanical components into a substrate, in particular into a printed circuit board or carrier plate, and method therefor, including a moving unit, which comprises a receptacle for a substrate and with which the substrate can be moved in a plane, which is spanned by an x-axis and a y-axis and can be placed in a press-in position in which one or more components are pressed into the substrate, a lower tool, which comes to rest against the underside of the substrate before or during the press-in, an upper tool, which can be moved against the component for pressing the component along the z axis toward the substrate, a control unit for controlling the moving unit, and a sensor for detecting at least one reference mark present on the substrate, wherein the control unit is configured and designed such that it controls the moving unit depending on the detected reference mark in such a way that the substrate is placed between the lower tool and the upper tool in the press-in position.

A method for assembling a camera suitable for use for a vision system of a vehicle includes providing a circuit board having first and second sides separated by a thickness dimension of the circuit board. An imager is disposed at the first side of the circuit board and solder pads are disposed at the second side of the circuit board. The solder pads are in electrical connection with circuitry of the circuit board. A coaxial connector is aligned at the solder pads at the second side of the circuit board. The coaxial connector is soldered at the second side of the circuit board via melting the solder paste at the solder pads.

The apparatus according to various embodiments includes one or more processors, and one or more memories operatively connected to the one or more processors. The one or more memories may store instructions that, when executed, cause the one or more processors to acquire a plurality of first position offsets of a plurality of first components respectively mounted on a plurality of first substrates with respect to a plurality of pads of the plurality of first substrates corresponding to the plurality of first components from the optical measurement device, set a range of a normal state for a component position offset based on the plurality of first position offsets, generate a control signal for adjusting at least one control parameter of the component mounting device associated with a component mounting position based on the range of the normal state, and transmit the control signal to the component mounting device.