Abstract: A metrology system may include an optical metrology sub-system to generate optical metrology measurements of optical metrology based on features of the optical metrology targets associated with at least one optical pitch and an additional metrology sub-system to generate additional metrology measurements of the optical metrology targets, where the additional metrology measurements have a higher resolution than the optical metrology measurements, and where the additional metrology sub-system further measures deviations of the optical metrology targets from a reference design. The system may further include a controller to generate accuracy measurements for the optical metrology targets based on the measurements, identify variations of a lithography process based on the deviations, correlate the accuracy measurements to the variations, and adjust at least one of the optical metrology sub-system, a lithography tool, or the reference design based on the correlations.

Abstract: In a method for controlling the positioning of patterns on a substrate in a manufacturing process at least one registration measurement is conducted with a registration tool on at least one pattern formed in at least one layer on the substrate by a previous process step of the manufacturing process. From the registration measurement a position of the at least one pattern in a coordinate system is determined. The determined position of the at least one pattern is fed into an automatic process control of a manufacturing system for controlling a setup of the manufacturing system for a subsequent process step of the manufacturing process. The manufacturing process may be a wafer manufacturing process with a silicon substrate. Complementary information may be collected in addition to performing the registration measurement and fed to the automatic process control. The process steps may for example include lithography steps, etching steps, layer deposition.

Abstract: In a method for controlling the positioning of patterns on a substrate in a manufacturing process at least one registration measurement is conducted with a registration tool on at least one pattern formed in at least one layer on the substrate by a previous process step of the manufacturing process. From the registration measurement a position of the at least one pattern in a coordinate system is determined. The determined position of the at least one pattern is fed into an automatic process control of a manufacturing system for controlling a setup of the manufacturing system for a subsequent process step of the manufacturing process. The manufacturing process may be a wafer manufacturing process with a silicon substrate. Complementary information may be collected in addition to performing the registration measurement and fed to the automatic process control. The process steps may for example include lithography steps, etching steps, layer deposition.

Abstract: The invention discloses a method for measuring positions of structures on a mask and thereby determining mask manufacturing errors. It is shown, that from a plurality measurement sites an influence of an optical proximity effect on a position measurement of structures on the mask, is determined with a metrology tool. A rendered image of the data representation of the structures is obtained. Additionally, at least one optical image of the pattern within the area on the mask is captured with the imaging system of the metrology tool. The field of view of the metrology tool is approximately identical to the size of the selected area of the mask design data. Finally, a residual is determined, which shows the manufacturing based proximity effect.

Abstract: A method for determining the lateral correction as a function of the substrate topology and/or the geometry of the substrate holder is disclosed. The substrate is placed on a measuring stage traversable in the X coordinate direction and Y coordinate direction, which carries the substrate to be measured. The substrate is supported on at least three support points which define a plane. An apparatus is provided for determining the position of a plurality of positions on the surface of the substrate in the in the X, Y and Z coordinate directions. The substrate is tiltable about an axis parallel to the X/Y plane, to enable the substrate to be measured in a tilted position.

Abstract: A coordinate measuring machine is disclosed having an orientor automatically orienting a substrate associated therewith. A control and computing unit is further associated with the coordinate measuring machine, so that self-calibration may be performed on the basis of at least two different and automatically set orientations of the substrate.

Abstract: A metrology system (1) and a method for determining low order errors are disclosed. At least one measurement objective (9) for the determination of the position of structures (3) on a substrate (2) is provided. The substrate (2) to be measured rests in a support on three points of support (52). The support exhibits an opening (53) for measuring the substrate (2). At least two marks (54) are provided on the support for the mask (2) in such a way that the marks (54) are capturable with the measurement objective (9) by moving the measurement table (20). Furthermore the substrate (2) in the support does not screen the marks (54) on the support.

Abstract: A method for correcting the measured values of positions of structures (3) on a substrate (2) resulting from bending of a substrate (2) is disclosed. A plurality of geometric parameters of the substrate (2) are determined. A plurality of physical parameters of the substrate (2) are determined. A degree of bending is calculated individually for each substrate (2) on the basis of the obtained geometric parameters, the physical parameters and the position of the support points (40). The measured position data of the structures (3) on the substrate (2) is corrected with the aid of each individually calculated degree of bending.

Abstract: The invention relates to a coordinate measuring machine (1) and a method for adapting the temperature of substrates. The coordinate measuring machine (1) includes at least one measurement table (20) movable in the X-coordinate direction and in the Y-coordinate direction, a measurement objective (9) and a camera (10) for determining the positions of the structures (3) on the substrate (2). There is further provided an interferometer (24) for determining the positions of the measurement objective (9) and the measurement table (20). The entire system is enclosed by a housing (50) forming a climatic chamber, in which there are further provided a magazine (32) for substrates (2), a loading station (35) for substrates (2) and a transport means (38) transporting the substrates (2) between the loading station (35), the magazine (32) and/or the measurement table (20).

Abstract: A method for determining the lateral correction as a function of the substrate topology and/or the geometry of the substrate holder is disclosed. The substrate is placed on a measuring stage traversable in the X coordinate direction and Y coordinate direction, which carries the substrate to be measured. The substrate is supported on at least three support points which define a plane. An apparatus is provided for determining the position of a plurality of positions on the surface of the substrate in the in the X, Y and Z coordinate directions. The substrate is tiltable about an axis parallel to the X/Y plane, to enable the substrate to be measured in a tilted position.

Abstract: A method for correcting the measured values of positions of structures (3) on a substrate (2) resulting from bending of a substrate (2) is disclosed. A plurality of geometric parameters of the substrate (2) are determined. A plurality of physical parameters of the substrate (2) are determined. A degree of bending is calculated individually for each substrate (2) on the basis of the obtained geometric parameters, the physical parameters and the position of the support points (40). The measured position data of the structures (3) on the substrate (2) is corrected with the aid of each individually calculated degree of bending.

Abstract: A coordinate measuring machine is disclosed having an orientor automatically orienting a substrate associated therewith. A control and computing unit is further associated with the coordinate measuring machine, so that self-calibration may be performed on the basis of at least two different and automatically set orientations of the substrate.