In the present invention, at the time of measuring, using a CD-SEM, a length of a resist that shrinks when irradiated with an electron beam, in order to highly accurately estimate a shape and dimensions of the resist before shrink, a shrink database with respect to various patterns is previously prepared, said shrink database containing cross-sectional shape data obtained prior to electron beam irradiation, a cross-sectional shape data group and a CD-SEM image data group, which are obtained under various electron beam irradiation conditions, and models based on such data and data groups, and a CD-SEM image of a resist pattern to be measured is obtained (S102), then, the CD-SEM image and data in the shrink database are compared with each other (S103), and the shape and dimensions of the pattern before the shrink are estimated and outputted (S104).

A method of generating a layout pattern includes determining a first energy density indirectly exposed to a first feature of one or more features of a layout pattern on an energy-sensitive material when the one or more features of the layout pattern on the energy-sensitive material are directly exposed by a charged particle beam. The method also includes adjusting a second energy density exposed the first feature when the first feature is directly exposed by the charged particle beam. A total energy density of the first feature that comprises a sum of the first energy density from the indirect exposure and the second energy density from the direct exposure is maintained at about a threshold energy level to fully expose the first feature in the energy-sensitive material.

In one embodiment, a charged particle beam drawing apparatus performs drawing by deflecting a charged particle beam with a deflector. A method for evaluating the apparatus includes making a shot of a first pattern, controlling a deflection amount by the deflector to move an applied position of the beam from the first pattern along a first direction to make a shot of a second pattern, controlling the deflection amount to move the applied position from the second pattern along the first direction to make a shot of a third pattern, controlling the deflection amount to move the applied position from the third pattern along a second direction opposite to the first direction to make a shot of a fourth pattern between the second pattern and the third pattern, calculating an interval between the second pattern and the fourth pattern, and comparing the calculated interval to a reference interval.

In one embodiment, a charged particle beam drawing apparatus deflects a charged particle beam with a deflector to draw a pattern. The apparatus includes a storage unit that stores an approximate formula indicating a correspondence relationship between a settling time for a DAC amplifier that controls the deflector, and a position shift amount, from a design position, of a drawn position of each evaluation pattern drawn on a first substrate while the settling time and an amount of deflection by the deflector are changed, a shot position correction unit that creates a correction formula indicating a relationship between an amount of deflection and a shot position shift amount at the settling time, from the approximate formula and the settling time for the DAC amplifier based on an amount of deflection of a shot, obtains a position correction amount by using the amount of deflection of the shot and the correction formula, and corrects a shot position defined by the shot data based on the position correction amount, and a drawing unit that performs drawing by using the shot data with a corrected shot position.

A system includes a digital pattern generator (DPG) having a plurality of pixels that are dynamically and individually controllable; a switching device that is coupled to the DPG, the switching device configured to route a packet to the DPG so as to control at least one of the pixels, the switching device further comprising: a plurality of input buffers configured to receive and store the packet through a transmission line; a plurality of output buffers; a plurality of memory devices, wherein each of the plurality of memory devices is associated with one of the plurality of output buffers; and a scheduling engine that is coupled to the plurality of input buffers, the plurality of output buffers, and the plurality of memory devices and is configured to determine a routing path for the packet stored in one of the input buffers based on an availability of the output buffers and a vacancy level the memory devices.

According to one aspect of the present invention, a stage mechanism includes a movable stage disposed in a vacuum atmosphere and mounting a heat source, a first heat pipe connected to the heat source, a movable mechanism configured to move according to the movement of the first heat pipe caused by the movement of the stage, by using a portion of the first heat pipe, and a cooling mechanism configured to cool the first heat pipe through the movable mechanism.

A charged particle buncher includes a series of spaced apart electrodes arranged to generate a shaped electric-field. The series includes a first electrode, a last electrode and one or more intermediate electrodes. The charged particle buncher includes a waveform device attached to the electrodes and configured to apply a periodic potential waveform to each electrode independently in a manner so as to form a quasi-electrostatic time varying potential gradient between adjacent electrodes and to cause spatial distribution of charged particles that form a plurality of nodes and antinodes. The nodes have a charged particle density and the antinodes have substantially no charged particle density, and the nodes and the antinodes are formed from a charged particle beam with an energy greater than 500 keV.

A driving apparatus is disclosed which has a movable part, a measuring device measuring a position of the movable part, two actuators respectively generating two thrusts which have a common axis of action thereof with respect to the movable part, and a controller that controls the position by the two actuators based on output of the measuring device. The controller obtains information of at least one of a thrust constant of one of the two actuators, a thrust constant of the other of the actuators, and rigidity of a member which supports the movable part with respect to the axis of action, based on a relationship between disturbance force estimated from thrust commands for the two actuators and an output of the measuring device in a case where the one actuator generates a thrust and the other actuator controls the position, and a thrust command for the one actuator.

A multi charged particle beam writing method includes emitting each corresponding beam in an “on” state while starting and continuing tracking control, shifting a writing position by beam deflection of the multi beams, in addition to tracking control, while continuing tracking control, emitting each corresponding beam in the next “on” state to the next writing position having been shifted while continuing tracking control, and returning the tracking position by resetting tracking control, after emitting each next corresponding beam to the next writing position having been shifted at least once, wherein writing of a predetermined region is completed by repeating the number of preset times a group of performing emitting, shifting, emitting, and returning, wherein the tracking time from start to reset of tracking control in at least one of the repeated groups is longer than the others.

A method for altering surface charge on an insulating surface of a first sample includes generating first plasma inside a plasma source, causing the first plasma to diffuse into a first vacuum chamber to generate second downstream plasma, immersing the first sample in the second downstream plasma, and applying a first bias voltage to a conductive layer of the first sample, or applying a first bias voltage to a metal holder that holds the first sample.