Abstract: A method and system for alignment of a tool to a workpiece in a continuous or discontinuous material flow are disclosed. The workpiece may be a portion of a web of material. An imaging system captures first and second images of the workpiece at first and second occasions respectively. Microscopic native features of the workpiece are selected, detected, tracked and/or compared in the first and second images. Based on the correspondence between, tracking or relative displacement of features as captured in the first and second images, an alignment to the workpiece is controlled. In embodiments, the workpiece and a tool, a projected image or a pattern to be imparted to the workpiece by a lithography or photolithography apparatus are aligned based upon positioning information determined from an analysis of correlated features or texture in the images. Positioning information may include a positioning error or a distortion indication.

Abstract: An alignment system for optical lithography uses cameras fixed to a movable stage and to a lithography unit to view unique microscopic non-uniformities that are inherent to the surface of a work piece, e.g., metal or ceramic microcrystalline grains, for position referencing. Stage cameras image two sites on the work piece through windows in the stage to establish original position templates. After the work piece has been repositioned, e.g., reversed topside-down, the same two sites are again viewed and template matching establishes the transformed coordinates of the work piece, e.g. by a lithography unit camera under which the stage moves to approximate site locations. Two corner cameras can serve as a coarse positioning mechanism. The alignment system is particular useful for backside alignment in printed circuit board lithography.

Abstract: A method and system for alignment of a tool to a workpiece in a continuous or discontinuous material flow are disclosed. The workpiece may be a portion of a web of material. An imaging system captures first and second images of the workpiece at first and second occasions respectively. Microscopic native features of the workpiece are selected, detected, tracked and/or compared in the first and second images. Based on the correspondence between, tracking or relative displacement of features as captured in the first and second images, an alignment to the workpiece is controlled. In embodiments, the workpiece and a tool, a projected image or a pattern to be imparted to the workpiece by a lithography or photolithography apparatus are aligned based upon positioning information determined from an analysis of correlated features or texture in the images. Positioning information may include a positioning error or a distortion indication.

Abstract: An alignment system for optical lithography uses cameras fixed to a movable stage and to a lithography unit to view unique microscopic non-uniformities that are inherent to the surface of a work piece, e.g., metal or ceramic microcrystalline grains, for position referencing. Stage cameras image two sites on the work piece through windows in the stage to establish original position templates. After the work piece has been repositioned, e.g., reversed topside-down, the same two sites are again viewed and template matching establishes the transformed coordinates of the work piece, e.g. by a lithography unit camera under which the stage moves to approximate site locations. Two corner cameras can serve as a coarse positioning mechanism. The alignment system is particular useful for backside alignment in printed circuit board lithography.

Abstract: An alignment system for optical lithography uses cameras fixed to a movable stage and to a lithography unit to view unique microscopic non-uniformities that are inherent to the surface of a work piece, e.g., metal or ceramic microcrystalline grains, for position referencing. Stage cameras image two sites on the work piece through windows in the stage to establish original position templates. After the work piece has been repositioned, e.g., reversed topside-down, the same two sites are again viewed and template matching establishes the transformed coordinates of the work piece, e.g. by a lithography unit camera under which the stage moves to approximate site locations. Two corner cameras can serve as a coarse positioning mechanism. The alignment system is particular useful for backside alignment in printed circuit board lithography.

Abstract: An alignment system for optical lithography uses cameras fixed to a movable stage and to a lithography unit to view unique microscopic non-uniformities that are inherent to the surface of a work piece, e.g., metal or ceramic microcrystalline grains, for position referencing. Stage cameras image two sites on the work piece through windows in the stage to establish original position templates. After the work piece has been repositioned, e.g., reversed topside-down, the same two sites are again viewed and template matching establishes the transformed coordinates of the work piece, e.g. by a lithography unit camera under which the stage moves to approximate site locations. Two corner cameras can serve as a coarse positioning mechanism. The alignment system is particular useful for backside alignment in printed circuit board lithography.

Abstract: There is disclosed numerous embodiments of a method and apparatus for a particle scanning system and an automatic inspection system. In each of these a particle beam is directed at the surface of a substrate for scanning that substrate. Also included are a selection of detectors to detect at least one of the secondary particles, back-scattered particles and transmitted particles from the substrate. The substrate is mounted on an x-y stage to provide it with at least one degree of freedom while the substrate is being scanned by the/particle beam. The substrate is also subjected to an electric field on it's surface to accelerate the secondary particles. The system also has the capability to accurately measure the position of the substrate with respect to the charged particle beam. Additionally, there is an optical alignment means for initially aligning the substrate beneath the,particle beam means.