An overlay metrology tool providing site-by-site alignment includes a controller coupled to a telecentric imaging system. The controller may receive two or more alignment images of an overlay target on a sample captured at two or more focal positions by the imaging system, generate alignment data indicative of an alignment of the overlay target within the imaging system based on the alignment images, set the alignment images as measurement images when the alignment of the overlay target is within selected alignment tolerances, direct the imaging system to adjust the alignment of the overlay target in the imaging system and further receive one or more measurement images from the imaging system when the alignment of the overlay target is outside the selected alignment tolerances, and determine overlay between two or more layers of the sample based on at least one of the measurement images.

An optical path compensation apparatus includes a wedge assembly, a driving mechanism and a preload unit. The wedge assembly includes a movable wedge and a fixed wedge. The movable wedge and the fixed wedge having equal wedge angles and respective wedge surfaces inclined in opposite directions. The preload unit is configured to elastically press the movable wedge on the fixed wedge, and the driving mechanism is configured to cause relative movement between the wedge surface of the movable wedge and the wedge surface of the fixed wedge. This optical path compensation apparatus is capable of achieving effective position correction of a focal plane of a measurement system for focusing and leveling in a smooth, convenient and precise way while not causing any error in other directions.

A structure and method for employing the structure to reliably read indicia formed on a substrate such as a panel or wafer is disclosed. A gripping member pulls the substrate into at least partial compliance with a locating structure to facilitate the proper function of a code reader. Where the indicia are not read, the substrate is moved relative to the code reader, starting from a position that may be determined based on the material properties of the substrate.

To provide a safety device that, when a crosswind is present, allows an aircraft to more safely land on a runway in an airport. This safety device 10 for landing in a crosswind is designed for landing of an aircraft 1 on a runway 3 in a crosswind across the runway 3, and provided with a control unit 14 for controlling, when the nose cone 1T of the fuselage 8 of the aircraft 1 is directed windward, the orientation of the wheels of the aircraft 1 such that the wheels are oriented in the direction of travel of the aircraft 1.

A system comprises a topography measurement system configured to determine a respective height for each of a plurality of locations on a substrate; and a processor configured to: determine a height map for the substrate based on the determined heights for the plurality of locations; and determine at least one alignment parameter for the substrate by comparing the height map and a reference height map, wherein the reference height map comprises or represents heights for a plurality of locations on a reference substrate portion.

In order to improve the throughput performance and/or economy of a measurement apparatus, the present disclosure provides a metrology apparatus including: a first measuring apparatus; a second measuring apparatus; a first substrate stage configured to hold a first substrate and/or a second substrate; a second substrate stage configured to hold the first substrate and/or the second substrate; a first substrate handler configured to handle the first substrate and/or the second substrate; and a second substrate handler configured to handle the first substrate and/or the second substrate, wherein the first substrate is loaded from a first, second or third FOUP, wherein the second substrate is loaded from the first, second or third FOUP, wherein the first measuring apparatus is an alignment measuring apparatus, and wherein the second measuring apparatus is a level sensor, a film thickness measuring apparatus or a spectral reflectance measuring apparatus.

The present disclosure provides a method for manufacturing a semiconductor structure. The method includes forming a photo-sensitive layer on a first surface of a semiconductor substrate. The photo-sensitive layer has a top surface. The method also includes obtaining a first profile of the first surface of the semiconductor substrate, and obtaining a second profile of the top surface of the photo-sensitive layer. The method also includes calculating a vertical displacement profile of the semiconductor substrate according to the first profile and the second profile. An apparatus for manufacturing a semiconductor structure is also disclosed.

An exposure apparatus that exposes a substrate is provided. The apparatus includes a stage configured to hold and move the substrate, and a controller configured to control focus driving of the stage based on a measurement value and a correction value obtained for the focus driving of the stage for a shot region on the substrate. The controller is configured to determine the correction value in accordance with an angle of view at a time of exposure.

A projection exposure apparatus is disclosed, including a focal plane measuring system (8) and an alignment measuring system (9) both disposed between a reticle stage (3) and a substrate stage (4). The alignment measuring system (9) is capable of focusing. The focal plane measuring system (8) measures variation in the surface profile of a substrate (5), and the alignment measuring system (9) effectuates focusing based on data obtained from the measurement performed by the focal plane measuring system (8). After the completion of the focusing, coordinates of various points on the substrate (5) in the alignment measuring system (9) are those of the points that have experienced the profile variation of the substrate (5). A relative positional relationship between the reticle (2) and the substrate (5) that has undergone the profile variation can be computationally derived from the changes in the coordinates of the points, and compensation can be accomplished by moving the substrate stage (4). In this way, even when there are differences between measuring focal planes of the alignment measuring system (9) and the focal plane measuring system (8), the resulting errors can be compensated for through calculation and focusing. An exposure method for a projection apparatus is also disclosed.

A lithographic apparatus (LA) applies a pattern to a substrate (W). The lithographic apparatus includes a height sensor (LS), a substrate positioning subsystem, and a controller configured for causing the height sensor to measure the height (h) of the substrate surface at locations across the substrate. The measured heights are used to control the focusing of one or more patterns applied to the substrate. The height h is measured relative to a reference height (zref). The height sensor is operable to vary the reference height (zref), which allows a wider effective range of operation. Specifications for control of the substrate height during measurement can be relaxed. The reference height can be varied by moving one or more optical elements (566, 572, 576, 504 and/or 512) within the height sensor, or moving the height sensor. An embodiment without moving parts includes a multi-element photodetector (1212).