Patent application number | Description | Published |
20090097147 | Plane waves to control critical dimension - The present invention describes an aperture including: an opaque plate; two sliver openings located in the opaque plate, the two sliver openings having rectangular shapes, the two sliver openings being parallel to each other. | 04-16-2009 |
20090104569 | Plane waves to control critical dimension - The present invention describes an aperture including: an opaque plate; two sliver openings located in the opaque plate, the two sliver openings having rectangular shapes, the two sliver openings being parallel to each other. | 04-23-2009 |
20090296055 | LENS HEATING COMPENSATION SYSTEMS AND METHODS - Methods for calibrating a photolithographic system are disclosed. A cold lens contour for a reticle design and at least one hot lens contour for the reticle design are generated from which a process window is defined. Aberrations induced by a lens manipulator are characterized in a manipulator model and the process window is optimized using the manipulator model. Aberrations are characterized by identifying variations in critical dimensions caused by lens manipulation for a plurality of manipulator settings and by modeling behavior of the manipulator as a relationship between manipulator settings and aberrations. The process window may be optimized by minimizing a cost function for a set of critical locations. | 12-03-2009 |
20100162199 | THREE-DIMENSIONAL MASK MODEL FOR PHOTOLITHOGRAPHY SIMULATION - A three-dimensional mask model of the invention provides a more realistic approximation of the three-dimensional effects of a photolithography mask with sub-wavelength features than a thin-mask model. In one embodiment, the three-dimensional mask model includes a set of filtering kernels in the spatial domain that are configured to be convolved with thin-mask transmission functions to produce a near-field image. In another embodiment, the three-dimensional mask model includes a set of correction factors in the frequency domain that are configured to be multiplied by the Fourier transform of thin-mask transmission functions to produce a near-field image. | 06-24-2010 |
20130042211 | Lithography Model for 3D Topographic Wafers - Described herein is a method for simulating an image formed within a resist layer on a substrate resulting from an incident radiation, the method comprising: calculating a forward propagating electric field or forward propagating magnetic field resultant from the incident radiation at a depth in the resist layer; calculating a backward propagating electric field or backward propagating magnetic field resultant from the incident radiation at the depth in the resist layer; calculating a radiation field at the depth in the resist layer from the forward propagating electric field or forward propagating magnetic field and from the backward propagating electric field or backward propagating magnetic field while ignoring an interference between the forward propagating electric field or forward propagating magnetic field and the backward propagating electric field or backward propagating magnetic field. | 02-14-2013 |
20130139118 | THREE-DIMENSIONAL MASK MODEL FOR PHOTOLITHOGRAPHYSIMULATION - A three-dimensional mask model of the invention provides a more realistic approximation of the three-dimensional effects of a photolithography mask with sub-wavelength features than a thin-mask model. In one embodiment, the three-dimensional mask model includes a set of filtering kernels in the spatial domain that are configured to be convolved with thin-mask transmission functions to produce a near-field image. In another embodiment, the three-dimensional mask model includes a set of correction factors in the frequency domain that are configured to be multiplied by the Fourier transform of thin-mask transmission functions to produce a near-field image. | 05-30-2013 |
20130204594 | Lithography Model For 3D Resist Profile Simulations - Described herein is a method for simulating a three-dimensional spatial intensity distribution of radiation formed within a resist layer on a substrate resulting from an incident radiation, the method comprising: calculating an incoherent sum of forward propagating radiation in the resist layer and backward propagating radiation in the resist layer; calculating an interference of the forward propagating radiation in the resist layer and the backward propagating radiation in the resist layer; and calculating the three-dimensional spatial intensity distribution of radiation from the incoherent sum and the interference. | 08-08-2013 |
20130212543 | LENS HEATING AWARE SOURCE MASK OPTIMIZATION FOR ADVANCED LITHOGRAPHY - A computer-implemented method for improving a lithographic process for imaging a portion of a design layout onto a substrate using a lithographic projection apparatus comprising an illumination source and projection optics, the method including computing a multi-variable cost function of a plurality of design variables that are characteristics of the lithographic process, at least some of the design variables being characteristics of the illumination source and the design layout, the computing of the multi-variable cost function accounting for lens heating effects; and reconfiguring the characteristics of the lithographic process by adjusting the design variables until a predefined termination condition is satisfied. | 08-15-2013 |
20140047397 | LENS HEATING COMPENSATION SYSTEMS AND METHODS - Methods for calibrating a photolithographic system are disclosed. A cold lens contour for a reticle design and at least one hot lens contour for the reticle design are generated from which a process window is defined. Aberrations induced by a lens manipulator are characterized in a manipulator model and the process window is optimized using the manipulator model. Aberrations are characterized by identifying variations in critical dimensions caused by lens manipulation for a plurality of manipulator settings and by modeling behavior of the manipulator as a relationship between manipulator settings and aberrations. The process window may be optimized by minimizing a cost function for a set of critical locations. | 02-13-2014 |
20140195993 | THREE-DIMENSIONAL MASK MODEL FOR PHOTOLITHOGRAPHY SIMULATION - A three-dimensional mask model of the invention provides a more realistic approximation of the three-dimensional effects of a photolithography mask with sub-wavelength features than a thin-mask model. In one embodiment, the three-dimensional mask model includes a set of filtering kernels in the spatial domain that are configured to be convolved with thin-mask transmission functions to produce a near-field image. In another embodiment, the three-dimensional mask model includes a set of correction factors in the frequency domain that are configured to be multiplied by the Fourier transform of thin-mask transmission functions to produce a near-field image. | 07-10-2014 |