In one embodiment, a data generation method includes generating a plurality of parametric elements by dividing, at positions of an extremum and an inflection point, a parametric curve that expresses a shape of a writing pattern and is defined by a plurality of control points arranged in order in a predetermined direction, generating a polygon by extracting, for each of the parametric elements, one or some of the plurality of control points and connecting the extracted control points in order in the predetermined direction, calculating a coverage by the polygon in each of a plurality of rectangular segmented regions obtained by dividing a target to be irradiated with a charged particle beam into a predetermined size, and calculating a coverage of each segmented region in a peripheral part of the writing pattern by finding intersections of each of the plurality of parametric elements and four sides of each of the plurality of segmented regions.

In one embodiment, a data generation method includes generating a plurality of parametric elements by dividing, at positions of an extremum and an inflection point, a parametric curve that expresses a shape of a writing pattern and is defined by a plurality of control points arranged in order in a predetermined direction, generating a polygon by extracting, for each of the parametric elements, one or some of the plurality of control points and connecting the extracted control points in order in the predetermined direction, calculating a coverage by the polygon in each of a plurality of rectangular segmented regions obtained by dividing a target to be irradiated with a charged particle beam into a predetermined size, and calculating a coverage of each segmented region in a peripheral part of the writing pattern by finding intersections of each of the plurality of parametric elements and four sides of each of the plurality of segmented regions.

A method for irradiating a target with a beam of energetic electrically charged particles, wherein the target comprises an exposure region where an exposure by said beam is to be performed, and the exposure of a desired pattern is done employing a multitude of exposure positions on the target. Each exposure position represents the location of one of a multitude of exposure spots of uniform size and shape, with each exposure spot covering at least one pattern pixel of the desired pattern. The exposure positions are located within a number of mutually separate cluster areas which are defined at respective fixed locations on the target. In each cluster area the exposure position are within a given neighboring distance to a next neighboring exposure position, while the cluster areas are separated from each other by spaces free of exposure positions, which space has a width, which is at least the double of the neighboring distance.

Analyzing a buried layer on a sample includes milling a spot on the sample using a charged particle beam of a focused ion beam (FIB) column to expose the buried layer along a sidewall of the spot. From a first perspective a first distance is measured between a first point on the sidewall corresponding to an upper surface of the buried layer and a second point on the sidewall corresponding to a lower surface of the buried layer. From a second perspective a second distance is measured between the first point on the sidewall corresponding to the upper surface of the buried layer and the second point on the sidewall corresponding to the lower surface of the buried layer. A thickness of the buried layer is determined using the first distance and the second distance.

A charged particle beam drawing device includes: a storage unit that stores a pattern generation program for generating pattern data, the pattern generation program being a program in which an instruction for specifying a type of a figure and an instruction for specifying a regular arrangement of the figure are described; an execution unit that executes the pattern generation program stored in the storage unit; and a control unit that performs drawing control based on the pattern data generated by the executed pattern generation program.

A method of milling a sample that includes a first layer formed over a second layer, where the first and second layers are different materials, the method comprising: milling the region of the sample by scanning a focused ion beam over the region a plurality of iterations in which, for each iteration, the focused ion beam removes material from the sample generating byproducts from the milled region; detecting, during the milling, the partial pressures of one or more byproducts with a residual gas analyzer positioned to have a direct line of sight to the milled region; generating, in real-time, an output detection signal from the residual gas analyzer indicative of an amount of the one or more byproducts detected; and stopping the milling based on the output signal.

The invention provides a charged particle beam device that can accurately move a convergence point of a charged particle beam to a surface of a sample and facilitates a user to grasp a positional relation between the surface of the sample and the convergence point of the charged particle beam. The charged particle beam device according to the invention includes: an electron optics system configured to irradiate a sample table with a charged particle beam; a movable stage on which the sample table is to be placed; a sample chamber that accommodates the movable stage; a detector configured to detect a signal from a sample placed on the sample table; a camera configured to capture an image of the sample table and the sample; an extraction means configured to extract outer shape information relating to outer shapes of the sample table and the sample from the image captured by the camera; a control unit configured to control the movable stage based on the outer shape information; and a display unit configured to display an image relating to the outer shape information together with the image captured by the camera.

The invention provides a charged particle beam device that can accurately move a convergence point of a charged particle beam to a surface of a sample and facilitates a user to grasp a positional relation between the surface of the sample and the convergence point of the charged particle beam. The charged particle beam device according to the invention includes: an electron optics system configured to irradiate a sample table with a charged particle beam; a movable stage on which the sample table is to be placed; a sample chamber that accommodates the movable stage; a detector configured to detect a signal from a sample placed on the sample table; a camera configured to capture an image of the sample table and the sample; an extraction means configured to extract outer shape information relating to outer shapes of the sample table and the sample from the image captured by the camera; a control unit configured to control the movable stage based on the outer shape information; and a display unit configured to display an image relating to the outer shape information together with the image captured by the camera.

A multi-charged particle beam writing apparatus according to one aspect of the present invention includes a region setting unit configured to set, as an irradiation region for a beam array to be used, the region of the central portion of an irradiation region for all of multiple beams of charged particle beams implemented to be emittable by a multiple beam irradiation mechanism, and a writing mechanism, including the multiple beam irradiation mechanism, configured to write a pattern on a target object with the beam array in the region of the central portion having been set in the multiple beams implemented.

A specimen machining device for machining a specimen by irradiating the specimen with an ion beam includes an ion source for irradiating the specimen with the ion beam, a shielding member disposed on the specimen to block the ion beam, a specimen stage for holding the specimen, a camera for photographing the specimen, a coaxial illumination device for irradiating the specimen with illumination light along an optical axis of the camera, and a processing unit for determining whether to terminate the machining based on an image photographed by the camera. The processing unit performs processing for acquiring information indicating a target machined width, processing for acquiring the image, processing for measuring a machined width on the acquired image, and processing for terminating the machining when the measured machined width equals or exceeds the target machined width.