A method is provided for fabricating and inspecting a photovoltaic assembly including a base, at least one photovoltaic module, and at least one adhesion layer based on a crosslinkable polymer material. The method includes depositing the at least one adhesion layer on the base; an assembly step; a partial crosslinking step; an electrical connection step; inspecting for mechanical and electrical functioning; in the event of correct functioning being detected, a crosslinking finalization step; in the event of incorrect functioning being detected removing at least one defective photovoltaic module.

Metrology targets and methods are provided, which comprise at least two overlapping structures configured to be measurable in a mutually exclusive manner at least at two different corresponding optical conditions. The targets may be single cell targets which are measured at different optical conditions which enable independent measurements of the different layers of the target. Accordingly, the targets may be designed to be very small, and be located in-die for providing accurate metrology measured of complex devices.

Systems, method and related apparatuses for adjusting support elements of a support apparatus to approximate a surface profile of a wafer. The support apparatus may include a group of mutually lateral adjacent support elements, each mutually lateral adjacent support element is configured to independently move at least vertically and comprising an upper surface. The support apparatus may further include a thermal energy transfer device operably coupled to each of the mutually lateral support elements, and an actuator system operably coupled to each of the support elements to selectively move one or more of the mutually lateral support elements vertically.

Some embodiments include apparatuses and methods of fabricating the apparatuses. One of the apparatuses includes a substrate of a semiconductor die; a memory cell portion located over a first portion of the substrate; a conductive pad portion located over a second portion of the substrate and outside the memory cell portion; and a sensor circuit including a portion located over the second portion of the substrate and under the conductive pad portion. The conductive pad portion includes conductive pads. Each of the conductive pads is part of a respective electrical path coupled to a conductive contact of a base outside the substrate.

Disclosed is a method for producing a wafer map. More specifically, the present invention relates to: a method for producing a wafer map used for manufacturing chips in the semiconductor field, wherein a geographic information system (GIS) technique is used to produce the wafer map; and a method and system for providing wafer test results using same. According to an embodiment of the present invention, a semiconductor wafer is formed as a map by using the GIS technique, a coordinate system used in the GIS is utilized to create a map of the same size as an actual semiconductor wafer, and each of various constituent elements constituting the wafer can be stratified to reflect the actual size of the element to create a wafer map in which each of the elements is geocoded.

Methods and systems are described for generating assessment maps. A method includes receiving a first vector map comprising a first set of vectors each indicating a distortion of a particular location on a substrate and generating a second vector map indicating a change in direction of a magnitude of the distortion of the particular location on the substrate. The method further includes generating a third vector map comprising vectors reflecting reduced noise in distortions across the plurality of locations on the substrate and generating a fourth vector map projecting a direction component of each vector component in the third set of vectors to a radial direction. The method further includes generating a fifth vector map by grouping the vectors of the fourth set of vectors and determining a magnitude associated with each group of vectors.

A method for manufacturing an epitaxial substrate includes the steps of: epitaxially growing a group III nitride semiconductor layer on a substrate; removing the substrate from a growth furnace; irradiating a surface of the group III nitride semiconductor layer with ultraviolet light while exposing the surface to an atmosphere containing oxygen; and measuring a sheet resistance value of the group III nitride semiconductor layer.

The present disclosure is a substrate processing apparatus including: a chamber configured to accommodate a substrate; a heat source configured to heat-treat the substrate; a heat ray sensor provided outside the chamber and configured to receive infrared rays radiated from the substrate; and an infrared ray transmission window provided in the chamber and configured to transmit an infrared ray having a wavelength greater than or equal to 8 μm to the heat ray sensor.

An electronic part includes: a chip part having a first main surface and a second main surface opposite to the first main surface, a wiring portion being derived from the chip part; and a substrate having a pad forming surface, pads to which the wiring portion can be connected being formed on the pad forming surface, in which a gap is formed between the second main surface and the pad forming surface while the wiring portion is connected to a predetermined pad of the pads.

The present invention is an IC chip mounting apparatus for mounting an IC chip at a reference position of an inlay antenna while conveying the antenna, the IC chip mounting apparatus including: a nozzle configured to suck an IC chip when located at a first position and to place the IC chip at the reference position of the antenna when located at a second position; a nozzle attachment to which the nozzle is attached; an image acquisition unit configured to acquire an image of the IC chip sucked by the nozzle; and a correction amount determination unit configured to determine correction amounts for the IC chip sucked by the nozzle, based on the image acquired by the image acquisition unit. The correction amounts includes a first correction amount for correcting an angle of the nozzle around the axis, a second correction amount for correcting a position of the antenna in a conveying direction of the antenna, and a third correction amount for correcting the position of the antenna in a width direction.