An optical metrology system may include an overlay metrology tool for characterizing an overlay target on a sample, where the overlay target includes first-direction periodic features in a first set of layers of the sample, and second-direction periodic features in a second set of layers of the sample. The overlay metrology tool may simultaneously illuminate the overlay target with first illumination beams and second illumination beams and may further generate images of the overlay target based on diffraction of the first illumination beams and the second illumination beams by the overlay target, where diffraction orders of the first illumination beams contribute to resolved image formation of only the first-direction periodic features, and where diffraction orders of the second illumination beams contribute to resolved image formation of only the second-direction periodic features. The system may further generate overlay measurements along the first and second measurement directions based on the images.

A calibration method of a detection system including an illumination system configured to illuminate a detection target, and an imaging system configured to form an image of light from the detection target on a photoelectric conversion element, the method including obtaining, for each of at least two combinations of first apertures in the illumination system and second apertures in the imaging system, each of which is formed by selecting one first aperture and one second aperture from the plurality of first apertures and the plurality of second apertures, a defocus characteristic indicating a shift amount of the image on the photoelectric conversion element with respect to a defocus amount of the detection target in a state in which each of the first aperture and the second aperture is positioned in a first position shifted from a reference position.

An overlay measurement apparatus that can quickly measure an overlay error between layers with a large height difference is provided. The overlay measurement apparatus measures an error between a first overlay mark and a second overlay mark formed in a pair on different layers of a wafer. The overlay measurement apparatus includes an imaging system configured to acquire alignment images of a pair of first and second overlay marks at a plurality of focus positions, and a controller communicatively coupled to the imaging system. The overlay measurement apparatus can rapidly and accurately measure an overlay error between layers with a large height difference.

An illumination apparatus configured to provide illumination while changing a spectrum of light from a light source includes a wavelength variable unit configured to change a spectrum of irradiating light, and an optical system configured to irradiate the wavelength variable unit with the light from the light source. The wavelength variable unit is disposed so that an incident surface of the wavelength variable unit on which the light emitted from the optical system is incident is tilted with respect to a plane perpendicular to an optical axis of the optical system.

An inspection system, a lithographic apparatus, and a method are provided. The inspection system includes an illumination system, an optical system, a shutter system, an objective system and a detector. The illumination system is configured to generate an illumination beam. The optical system is configured to split the illumination beam into a first sub-beam and a second sub-beam. The shutter system is configured to independently control a transmittance of the first sub-beam and the second subbeam. The objective system is configured to receive the first sub-beam and the second beam from the optical system and direct the first sub-beam and the second sub-beam towards a substrate having a target structure. The detector is configured to receive an image or a diffracted image of the target structure.

A measurement system (11), the measurement system comprising: a sensor apparatus (22); an illumination system (IL1) arranged to illuminate the sensor apparatus with radiation, the sensor apparatus comprising a patterned region arranged to receive a radiation beam and to form a plurality of diffraction beams, the diffraction beams being separated in a shearing direction; the sensor apparatus comprising a radiation detector (24); wherein the patterned region is arranged such that at least some of the diffraction beams form interference patterns on the radiation detector; wherein the sensor apparatus comprises a plurality of patterned regions (19a-19c, 20a, 20b), and wherein pitches of the patterned regions are different in adjacent patterned regions.

Disclosed is a metrology apparatus for measurement of a target formed on a substrate by a lithographic process and associated method. The metrology apparatus comprises a radiation source operable to provide first radiation; a configured solid high harmonic generation medium being configured to receive and be excited by said first radiation to generate high harmonic second radiation from an output surface of the configured solid high harmonic generation medium; and a detection arrangement operable to detect said second radiation, at least a portion of which having been scattered by said target. The configured solid high harmonic generation medium is configured to shape the beam of said second radiation and/or separate said first and second radiation.

An alignment or overlay target that has an optically opaque layer disposed between the top and bottom target structure is measured using opto-acoustic metrology. A classifier library is generated for classifying whether an opto-acoustic metrology signal is on or off the bottom structure. A target may be measured by acquiring opto-acoustic measurement data for the bottom structure of the target and determining a location of the bottom structure using opto-acoustic metrology data acquired from the different locations over the bottom structure and the classifier library. Locations for acquisition of the data may be based on classification results of each measurement and a search pattern. The top structure of the target may be optically imaged. The relative position of the top structure with respect to the bottom structure is determined using the opto-acoustically determined location of the bottom structure and the image of the top structure.

A micromirror array comprises a substrate, a plurality of mirrors for reflecting incident light and, for each mirror of the plurality of mirrors, at least one multilayer piezoelectric actuator for displacing the mirror, wherein the at least one multilayer piezoelectric actuator is connected to the substrate, and wherein the at least one multilayer piezoelectric actuator comprises a plurality of piezoelectric layers of piezoelectric material interleaved with a plurality of electrode layers to form a stack of layers. Also disclosed is a method of forming such a micromirror array. The micromirror array may be used in a programmable illuminator. The programmable illuminator may be used in a lithographic apparatus and/or in an inspection and/or metrology apparatus.

A metrology or inspection system, a lithographic apparatus, and a method are provided. The system includes an illumination system, an optical system, a first optical device, a second optical device, a detector, and a processor. The optical system is configured to split an illumination beam into a first sub-beam and a second sub-beam. The first optical device is configured to receive the first sub beam and direct the first sub-beam towards a first spot on a substrate. The substrate includes one or more target structures. The second optical device is configured to receive the second sub-beam and direct the second sub-beam towards a second spot on the substrate. The first spot is a different location than the second spot. The detector is configured to receive diffracted beams and to generate a detection signal. The processor is configured to determine a property of the one or more target structures.