A computing unit generates a to-be-used-in-computation netlist on the basis of a to-be-used-in-calculation device model corresponding to a correction sample, estimates a first application result, on the basis of the to-be-used-in-computation netlist and an optical condition, when a charged particle beam is applied to the correction sample under the optical condition, compares the first application result and a second application result based on a detection signal when the charged particle beam is applied to the correction sample under the optical condition, and corrects the optical condition when the first application result and the second application result differ from each other.

A charged particle beam apparatus acquires an image that is not affected by movement of a stage at a high speed. The apparatus includes: a charged particle source for irradiating a sample with a charged particle beam; a stage on which the sample is placed; a measurement unit for measuring a movement amount of the stage; a deflector; a deflector offset control unit, which is a feedback control unit for adjusting a deflection amount of the deflector according to the movement amount of the stage; a plurality of detectors for detecting secondary charged particles emitted from the sample by irradiation of the charged particle beam; a composition ratio calculation unit that calculates composition ratios of signals output from the detectors based on the deflection amount adjusted by the feedback control unit; and an image generation unit for generating a composite image by compositing the signals using the composition ratio.

To provide, in observation of a sample that requires a movement between various devices, a charged particle beam device, a method for processing the sample, and an observation method which facilitate the movement between the devices. The charged particle beam device that processes an observation target on the sample using a charged particle beam includes: a sample stage on which the sample is placed; an observation unit configured to observe the observation target; and a writing unit configured to write information of the observation target in a writing position of the sample.

A charged particle beam device capable of generating an image having uniform image quality in a field of view is provided. The charged particle beam device includes: a beam source configured to irradiate a sample with a charged particle beam; a diaphragm including an opening used for angle discrimination of secondary charged particles emitted from the sample; a first detector provided closer to the sample than the diaphragm, and configured to detect a part of the secondary charged particles; a second detector provided closer to the beam source than the diaphragm, and configured to detect secondary charged particles passing through the opening; an image generation unit configured to generate an image based on a first signal output from the first detector or a second signal output from the second detector; and a composite ratio calculation unit configured to calculate a composite ratio for each position in a field of view based on the first signal or the second signal with respect to a calibration sample that is a sample having a flat surface. The image generation unit generates a composite image by synthesizing the first signal and the second signal with respect to an observation sample using the composite ratio.

The present invention provides an electron microscope and an observation method capable of observing secondary electrons in the atmosphere. In detail, a charged particle microscope of the invention includes: a partition wall that separates a non-vacuum space in which a sample is loaded from a vacuum space inside a charged particle optical lens barrel; an upper electrode; a lower electrode on which the sample is loaded; a power supply for applying a voltage to at least one of the upper electrode and the lower electrode; a sample gap adjusting mechanism for adjusting a gap between the sample and the partition wall; and an image forming unit for forming an image of the sample based on the current absorbed by the lower electrode. The secondary electrons are selectively measured by using an amplification effect due to ionization collision between electrons and gas molecules generated when a voltage is applied between the upper electrode and the lower electrode. As a detection method, a method is used which measures a current value flowing in a substrate.

Systems and methods to focus and align multiple electron beams are disclosed. A camera produces image data of light from electron beams that is projected at a fiber optics array with multiple targets. An image processing module determines an adjustment to a voltage applied to a relay lens, a field lens, or a multi-pole array based on the image data. The adjustment minimizes at least one of a displacement, a defocus, or an aberration of one of the electron beams. Using a control module, the voltage is applied to the relay lens, the field lens, or the multi-pole array.

The methods and systems disclosed here detect edges of top-down images of respective cross-sections of an array of high-aspect-ratio (HAR) features. The respective cross sections are at various depths of a HAR feature along a longitudinal direction. The detected edges are re-sampled in a spatial domain at a target angular resolution. The re-sampled edges are represented as a corresponding set of harmonics in a frequency domain, each set of harmonics preserving characteristic information about a respective cross-section of the HAR feature at a certain depth. A plurality of cross-sections at the various depths of the HAR feature are reconstructed by analyzing the corresponding sets of harmonics in the frequency domain. A 3D profile of the HAR feature is generated by stitching the plurality of re-constructed cross-sections at the various depths of the HAR feature.

A particle beam system is configured to perform a method which includes: preventing at least one of generation of induced particles and incidence of the induced particles onto a detection area of a detector configured to output a detection signal; generating a residual signal by processing the detection signal outputted during the preventing using a control value; adjusting, based on the residual signal, the control value so that the residual signal takes a value within a predetermined limited residual-signal target range; directing a primary particle beam onto an object while allowing generation of the induced particles due to the primary particle beam and incidence of the induced particles onto the detection area; generating a result signal by processing the detection signal outputted during the directing using the control value.

A calibration method for calibrating the position error in the point of interest induced from the stage of the defect inspection tool is achieved by controlling the deflectors directly. The position error in the point of interest is obtained from the design layout database.

To provide, in observation of a sample that requires a movement between various devices, a charged particle beam device, a method for processing the sample, and an observation method which facilitate the movement between the devices. The charged particle beam device that processes an observation target on the sample using a charged particle beam includes: a sample stage on which the sample is placed; an observation unit configured to observe the observation target; and a writing unit configured to write information of the observation target in a writing position of the sample.