A mirror array device, and related exposure apparatus and manufacturing method, for driving a spatial light modulator that includes: setting, in an array of mirror elements, mirror elements in a first state for turning incident light into reflected light with the same phase as that of the incident light or with a phase different by a first phase from that of the incident light and mirror elements in a second state for turning incident light into reflected light with a phase different approximately 180 from the first phase to an arrangement with a first phase distribution; and setting, in the array of mirror elements, the first mirror elements and the second mirror elements to an arrangement with a second phase distribution which is an inversion of the first phase distribution.

A method for making a circuit board uses a dielectric core, and at least one thin foil bottom surface with a foil backing of sufficient thickness to absorb heat from a laser drilling operation to prevent the penetration of the thin foil bottom surface during laser drilling. A sequence of steps including a laser drilling step, removing the foil backing step, electroless plating step, patterned resist step, electroplating step, resist strip step, tin plate step, and copper etch step are performed, which provide dot vias of fine linewidth and resolution.

Embodiments described herein provide a system, a software application, and methods of a lithography process that provide at least one of the ability to decrease the stabilization time and write an exposure pattern into a photoresist on a substrate compensating for the change in the total pitch over a stabilization time. One embodiment of the system includes a slab, a stage disposed over the slab, a pair of supports disposed on the slab, a processing apparatus, and a chiller system. The pair of supports support a pair of tracks and the stage is configured to move along the pair of tracks. The processing apparatus has an apparatus support coupled to the slab and a processing unit supported by the apparatus support. The processing unit has a plurality of image projection systems. The chiller system has at least one fluid channel disposed in each track of the pair of tracks.

A method for correcting misalignments is provided. An alignment for each device of a group of devices mounted on a substrate is determined. An alignment error for the group of devices mounted on the substrate is determined based on the respective alignment for each device. One or more correction factors are calculated based on the alignment error. The alignment error is corrected based on the one or more correction factors.

A method for exposing a structure on a substrate includes positioning of an invariable reticle and a programmable reticle in a light path between a light source and a layer on a substrate to be exposed to light and exposing the layer on the substrate by light from the light source passing the invariable reticle and the programmable reticle.

Provided is a process including: obtaining a layout specifying, at least in part, a pattern to be transferred to a substrate via a patterning process and an etch process; and modifying, with one or more processors, the layout to include an etch-assist feature that is larger than a resolution limit of the patterning process and smaller than a resolution limit of the etch process, the etch-assist feature being configured to reduce a bias of the patterning process or the etch process, to reduce an etch induced shift of a feature in the layout due to the etch process, or to expand a process window of another patterning process.

A method for inspecting a spatial light modulator includes: performing such control that in an inspection target area in an array of mirror elements, the mirror elements in a first state in which incident light is given a phase change amount of 0 and the mirror elements in a second state in which incident light is given a phase change amount of 180 () become arrayed in a checkered pattern; guiding light having passed the inspection target area to a projection optical system with a resolution limit coarser than a width of an image of one mirror element, to form a spatial image; and inspecting a characteristic of the spatial light modulator from the spatial image. This method allows us to readily perform the inspection of the characteristic of the spatial light modulator having the array of optical elements.

Detection device detects relative position between overlapping first and second marks. The device includes illumination system configured to illuminate the first and second marks with unpolarized illumination light, detection system having image sensor and configured to form image on imaging surface of the image sensor from diffracted lights from the first and second marks. The first and second marks are configured to form, on the imaging surface, optical information representing the relative position in first or second direction. Light blocking body arranged on pupil surface of the detection system includes first light blocking portion crossing the optical axis of the detection system in direction conjugate to the first direction and second light blocking portion crossing the optical axis of the detection system in fourth direction conjugate to the second direction.

A method of fabricating an integrated circuit (IC) uses a first lithography technique having a first resolution and a second lithography technique having a second resolution lower than the first resolution. The method includes deriving a graph from an IC layout, the graph having vertices and edges that connect some of the vertices, the vertices representing IC patterns in the IC layout, the edges representing spacing between the IC patterns that are smaller than the second resolution. The method further includes classifying the edges into at least two types, a first type of edges representing spacing that is smaller than the first resolution, a second type of edges representing spacing that is equal to or greater than the first resolution but smaller than the second resolution.

A method of manufacturing a semiconductor device includes forming a first photoresist film over a substrate, exposing a first pattern including an alignment pattern in a first region, forming, on the substrate, an alignment mark corresponding to the exposed alignment pattern, forming a second photoresist film over the substrate on which the alignment mark is formed, dividing a second pattern into a plurality of regions and exposing the divided regions separately in a second region while performing positioning with respect to the alignment mark, and developing the second photoresist film and forming the second photoresist film having the second pattern, wherein at least a part of the second region is located outside an effective exposure region of an exposure apparatus in exposure of the first pattern.