Charged particle beam exposure apparatus and method of manufacturing semiconductor device

What is claimed is: 1. A charged particle beam exposure apparatus configured to expose cut patterns or via patterns on a substrate having a plurality of line patterns arranged on an upper surface of the substrate at a constant pitch, the cut patterns provided to cut the line patterns, the via patterns provided to form via holes on the line patterns, the charged particle beam exposure apparatus comprising: a charged particle source configured to emit charged particles; an aperture plate having a plurality of openings arranged in one row and in a one-dimensional direction orthogonal to the line patterns, the aperture plate configured to form a one-dimensional array beam in which charged particle beams formed of the charged particles having passed through the openings are arranged in array in the one-dimensional direction; a blanker plate including a blanker array configured to independently deflect in a blanking manner the charged particle beams included in the one-dimensional array beam; a final aperture plate configured to block the charged particle beams deflected by the blanker array; a deflector configured to adjust an irradiation position of the entire one-dimensional array beam; a stage including a drive mechanism configured to hold and move the substrate; and a control part configured to control operations of the blanker plate, the deflector, and the stage, wherein the control part causes the stage to continuously move in a direction parallel to the line patterns and, at the same time, performs irradiation of the charged particle beams over a frame in one linear movement while stopping the one-dimensional array beam at a pixel position on the substrate, where the pixel position is set at regular intervals on the line pattern, for a certain period, in accordance with the movement of the stage; and wherein, while performing exposure across one frame, irradiation position of the one-dimensional array beam, on the substrate, is fixed in a direction perpendicular to that of the movement of the stage and is moved in a stepwise manner in the direction parallel to that of the movement of the stage; and wherein exposure of one of the pattern of a plurality of patterns arranged in the line pattern is performed by irradiation at one or two pixel positions. 2. The charged particle beam exposure apparatus according to claim 1 , wherein the intervals of the pixel positions are set such that blurring portions of each of the charged particle beams overlap each other. 3. The charged particle beam exposure apparatus according to claim 2 , wherein the control part draws each of the cut patterns or the via patterns at an arbitrary position between adjacent two of the pixel positions, by using overlapping of portions of irradiation amount distribution of a corresponding one of the charged particle beams at the adjacent two pixel positions. 4. The charged particle beam exposure apparatus according to claim 2 , wherein the control part draws each of the cut patterns or the via patterns at an arbitrary position between adjacent two of the pixel positions, by adjusting a proportion between irradiation times of a corresponding one of the charged particle beams respectively at the adjacent two pixel positions with the blanker plate. 5. The charged particle beam exposure apparatus according to claim 4 , wherein the control part obtains a proportion between irradiation amounts of the corresponding charged particle beam respectively at the adjacent two pixel positions from a polynomial of an internal ratio of a pattern position for the adjacent two pixel positions. 6. The charged particle beam exposure apparatus according to claim 5 , wherein, provided that a p and a p+1 represent a pixel position and a pixel position adjacent thereto, respectively, and that a position of a pattern to be drawn is expressed as a p ×r+a p ×(1−r) by using an internal ratio r, the control part obtains an exposure amount D p at the pixel position a p and an exposure amount D p+1 at the pixels position a p+1 from relationship formulae of D p =D 0 ×( r− 4× R 0 ×r (1− r )) D p+1 =D 0 ×(( r− 1)−4× R 0 ×r (1− r )) (where D 0 is a constant determined from a resist material and a development condition and R 0 is a constant determined within a range of 0<R 0 ≦0.1). 7. The charged particle beam exposure apparatus according to claim 2 , further comprising a focus lens configured to adjust focal positions of the charged particle beams, wherein the control part adjusts sizes of the blurring (blur) portions of the charged particle beams by displacing a focal position of the focus lens. 8. The charged particle beam exposure apparatus according to claim 1 , wherein the control unit: obtains the number P of pixel positions included in a deflection width L by dividing the deflection width L by a distance between the pixel positions, the deflection width L being a width by which the deflector is capable of deflecting the one-dimensional array beam in the line pattern direction; obtains a stop time T at each of the pixel positions by adding a beam deflection stabilization waiting time to a beam irradiation time obtained by dividing an exposure amount required for exposure of the cut pattern or the via pattern by a current density of the charged particle beam: and sets a movement speed of the stage to L/(T×P). 9. A method of manufacturing a semiconductor device, comprising a step of exposing cut patterns or via patterns on a substrate having a plurality of line patterns arranged on an upper surface of the substrate at a constant pitch, the cut patterns provided to cut the line patterns, the via patterns provided to form via holes on the line patterns, the exposure performed by using a charged particle beam exposure apparatus including: a charged particle source configured to emit charged particles; an aperture plate having a plurality of openings arranged in one row and in a one-dimensional direction orthogonal to the line patterns, the aperture plate configured to form a one-dimensional array beam in which charged particle beams formed of the charged particles having passed through the openings are arranged in array in the one-dimensional direction; a blanker plate including a blanker array configured to independently deflect in a blanking manner the charged particle beams included in the one-dimensional array beam; a final aperture plate configured to block the charged particle beams deflected by the blanker array; a deflector configured to adjust an irradiation position of the entire one-dimensional array beam; a stage including a drive mechanism configured to hold and move the substrate; and a control part configured to control operations of the blanker plate, the deflector, and the stage, wherein the stage is continuously moved in a direction parallel to the line patterns and, at the same time, irradiation of the charged particle beams over a frame in one linear movement is performed with the one-dimensional array beam at a pixel position being stopped on the substrate, where the pixel position is set at regular intervals on the line pattern, for a certain period, in accordance with the movement of the stage; and wherein, while performing exposure across one frame, irradiation position of the one-dimensional array beam, on the substrate, is fixed in a direction perpendicular to that of the movement of the stage and is moved in a stepwise manner in the direction parallel to that of the movement of the stage; and wherein exposure of one of the pattern of a plurality of patterns arranged in the line pattern is performed by irradiation at one or two pixel positions. 10. The method of manufacturing a semiconductor device according