A method comprises receiving an integrated circuit (IC) chip design, and generating, by one or more processors and based on the IC chip design, dose information, a wafer image, and a wafer target. Further, the method comprises modifying, by the one or more processors, the dose information based on a comparison of the wafer image and the wafer target. Further, the method comprises outputting the modified dose information to a mask writing device.

A maskless exposure device including a light source configured to emit an exposure beam, a light modulation element configured to modulate the exposure beam according to an exposure pattern, a projection optical system configured to transfer a modulated exposure beam to a substrate as a beam spot array, a beam measurement part configured to measure a beam data of the beam spot array, and a compensating mask generator configured to generate a compensating mask by utilizing a measured data of the exposure beam for compensating cumulative illumination, wherein the compensating mask generator is configured to turn off left and right beams of a first selected spot beam selected by the beam data, and then to turn off a second selected spot beam.

A method of forming an optical structure in a semiconductor substrate includes applying a layer of photoresist on a surface of the semiconductor substrate, exposing the photoresist with exposure light, and subsequently developing the photoresist. After developing, a remaining layer of the photoresist has a photoresist relief profile. The method further includes etching the photoresist and the semiconductor substrate to transfer the photoresist relief profile into the semiconductor substrate to obtain the optical structure in one or more first sub-areas and a support structure in one or more second sub-areas. A thickness of the layer of the photoresist applied to the surface of the semiconductor substrate is greater than a product of a maximum height difference of a relief profile of the optical structure and a ratio between etch rates of the photoresist and of the semiconductor substrate.

A method of lithography in a lithographic apparatus configured to transfer a pattern from a patterning device onto a substrate, the method including: determining a dose sensitivity of at least part of the pattern at a plurality of values of a dose, wherein the dose sensitivity is not a monotonically increasing or monotonically decreasing function of the dose. A computer product including a processor, a memory and a storage device, wherein the storage device at least stores values of, or a function describing, a dose sensitivity of at least part of a lithographic pattern at a plurality of values of dose, wherein the dose sensitivity is not a monotonically increasing or monotonically decreasing function of the dose.

A structure in semiconductor fabrication includes at least a first periodic asymmetric feature and a periodic asymmetric second feature. The first feature contains a plurality of periodically distributed first elements. The first feature has a first asymmetric profile such that the first feature no longer has the same first asymmetric profile when it is rotated by 180 degrees. The second feature contains a plurality of periodically distributed second elements. The second feature has a second asymmetric profile such that the second feature no longer has the same second asymmetric profile when it is rotated by 180 degrees. The second asymmetric profile is different from the first asymmetric profile.

Maskless lithographic apparatus measuring accumulated amount of light is provided. The maskless lithographic apparatus includes a light source which emits light, a stage on which a substrate is disposed, an optical system which converts the light into a beam spot array including a plurality of columns and a plurality of rows and irradiates the beam spot array onto the stage, a slit to which the beam spot array is irradiated and which passes an nth (n is a natural number) row of the beam spot array, an optical sensor which senses the nth row of the beam spot array which has passed through the slit, and a measuring unit which measures an accumulated amount of light in the nth row of the beam spot array sensed by the optical sensor

According to one embodiment, wafer lithography equipment includes an exposure unit transferring a circuit pattern onto a wafer, a measurement unit measuring a dimension of the circuit pattern and a calculator. The calculator includes calculating a first difference. The first difference is the difference between a first dimension and a second dimension. The first dimension is obtained by substituting a first exposure amount and a first focus distance into an approximate response surface function. The second dimension is measured by the measurement unit. The calculator also includes calculating a second difference. The second difference is the sum total of the first difference for all of the circuit patterns. The calculator also includes calculating a second exposure amount and a second focus distance causing the difference between the approximate response surface function and the second difference to be a minimum. The calculator also includes calculating a correction exposure amount.

A method of controlling a feedback system with a data matching module of an extreme ultraviolet (EUV) radiation source is disclosed. The method includes obtaining a slit integrated energy (SLIE) sensor data and diffractive optical elements (DOE) data. The method performs a data match, by the data matching module, of a time difference of the SLIE sensor data and the DOE data to identify a mismatched set of the SLIE sensor data and the DOE data. The method also determines whether the time difference of the SLIE sensor data and the DOE data of the mismatched set is within an acceptable range. Based on the determination, the method automatically validates a configurable data of the mismatched set such that the SLIE sensor data of the mismatched set is valid for a reflectivity calculation.

A lithographic apparatus and associated method of controlling a lithographic process. The lithographic apparatus has a controller configured to define a control grid associated with positioning of a substrate within the lithographic apparatus. The control grid is based on a device layout, associated with a patterning device, defining a device pattern which is to be, and/or has been, applied to the substrate in a lithographic process.

A method for determining a contribution of a processing apparatus to a fingerprint of a parameter across a substrate, the method including: obtaining a delta image which relates to a difference between a first pupil image associated with inspection of a first feature on the substrate and a second pupil image associated with inspection of a second feature on the substrate, wherein the first and second features have different dose sensitivities; determining a rate of change of the difference in response to a variation of a dose used to form the first and second features; selecting a plurality of pixels within the delta image having a rate of change above a predetermined threshold; and determining the contribution using the determined rate of change and the delta image restricted to the plurality of pixels.