Patent Number: 
Section: claims

1. A charged particle beam apparatus comprising:a charged particle beam column configured to irradiate a charged particle beam to a first region and a second region of a sample, the second region included in the first region;a controller configured to control the charged particle beam column to irradiate the charged particle beam to the first region and the second region of the sample, the first region including a plurality of first pixels at a first pixel interval, each of the first pixels including a first predetermined number of first sub-pixels, the second region including a plurality of second pixels at a second pixel interval different from the first pixel interval, each of the second pixels including a second predetermined number of second sub-pixels, wherein the controller is configured to control the charged particle beam column to irradiate the charged particle beam to each of the first sub-pixels at the first pixel interval for the first region and to irradiate the charged particle beam to each of the second sub-pixels at the second pixel interval for the second region;a secondary electron detector configured to detect first secondary electrons for each of the first sub-pixels generated by irradiating the charged particle beam to each of the first sub-pixels at the first pixel interval for the first region, to generate a first signal of the first secondary electrons for each of the first sub-pixels, to detect second secondary electrons for each of the second sub-pixels generated by irradiating the charged particle beam to each of the second sub-pixels at the second pixel interval for the second region, and to generate a second signal of the second secondary electrons for each of the second sub-pixels; andan image forming unit configured to form first sub-pixel images by using the first signal, the number of the first sub-pixel images being the first predetermined number, to generate a first image by synthesizing the predetermined number of the first sub-pixel images, and to form second sub-pixel images by using the second signal, the number of the second sub-pixel images being the second predetermined number, to generate a second image by synthesizing the predetermined number of the second sub-pixel images. 2. The charged particle beam apparatus according to claim 1, wherein the second region is a correction mark detection region that includes a position at which a correction mark is provided. 3. The charged particle beam apparatus according to claim 1, wherein the controller controls the charged particle beam column to perform an irradiation process of irradiating the charged particle beam once for each pixel region designated in a bitmap for multiple times while displacing an irradiation position of the charged particle beam within each pixel region for each of the irradiation process for each pixel. 4. The charged particle beam apparatus according to claim 3,wherein the controller operates to:control the charged particle beam column to perform scanning of a drift correction region with a first pixel pitch that is smaller than a second pixel pitch of the bitmap;calculate a first amount of drift correction based on information obtained through the scanning; andperform drift correction by converting the first amount of drift correction into a second amount of drift correction for the second pixel pitch of the bitmap. 5. The charged particle beam apparatus according to claim 3, wherein when a field of view of the bitmap is set to FOV_A and a field of view having an amount, by which the irradiation position is displaced, the same with a pixel size is set to FOV_B, the controller controls the charged particle beam column to perform the irradiation process for at least (FOV_A/FOV_B) by (FOV_A/FOV_B) times in total within the first region. 6. A processing method of a sample including a first region and a second region, the second region included in the first region, the method comprising:controlling a charged particle beam column to irradiate a charged particle beam to the first region and the second region of the sample, the first region including a plurality of first pixels at a first pixel interval, each of the first pixels including a first predetermined number of first sub-pixels, the second region including a plurality of second pixels at a second pixel interval different from the first pixel interval, each of the second pixels including a second predetermined number of second sub-pixels;irradiating the charged particle beam to each of the first sub-pixels at the first pixel interval for the first region by controlling the charged particle beam column;irradiating the charged particle beam to each of the second sub-pixels at the second pixel interval by controlling the charged particle beam column;detecting first secondary electrons for each of the first sub-pixels generated by irradiating the charged particle beam to each of the first sub-pixels at the first pixel interval for the first region;generating a first signal of the first secondary electrons for each of the first sub-pixels by detecting first secondary electrons;detecting second secondary electrons for each of the second sub-pixels generated by irradiating the charged particle beam to each of the second sub-pixels at the second pixel interval for the second region;generating a second signal of the second secondary electrons for each of the second sub-pixels by detecting second secondary electrons;forming first sub-pixel images by using the first signal, the number of the first sub-pixel images being the first predetermined number;generating a first image by synthesizing the predetermined number of the first sub-pixel images;forming second sub-pixel images by using the second signal, the number of the second sub-pixel images being the second predetermined number; andgenerating a second image by synthesizing the predetermined number of the second sub-pixel images.