Patent Number: 
Section: claims

1. A drawing apparatus configured to perform drawing on a substrate with a plurality of charged particle beams, the apparatus comprising:an irradiation system including a collimator lens on which a diverging charged particle beam is incident;an aperture array configured to split the charged particle beam from the collimator lens into the plurality of charged particle beams;a lens array configured to form a plurality of crossovers of the plurality of charged particle beams from the aperture array; anda projection system including an element having a single aperture and configured to converge the plurality of charged particle beams corresponding to the plurality of crossovers and to project the plurality of charged particle beams having passed through the single aperture onto the substrate,wherein the lens array includes a correction lens array and a magnifying less array, the correction lens array including a converging lens eccentric relative to corresponding one of a plurality of apertures of the aperture array such that the plurality of charged particle beams converged according to aberration of the projection system are converged to the single aperture, and the magnifying lens array configured, so as to form the plurality of crossovers, to magnify a plurality of crossovers formed by the correction lens array, converging lenses included in the correction lens array having such focal lengths that the eccentric converging lens refracts a charged particle beam corresponding thereto, without shielding of the charged particle beam, so that the plurality of charged particle beams are converged to the single aperture, magnifying lenses included in the magnifying lens array having such focal lengths that the magnifying lenses respectively converge a plurality of charged particle beams, respectively converged by the converging lenses and then diverged, with convergent angles smaller than convergent angles of the plurality of charged particle beams respectively converged by the converging lenses. 2. The drawing apparatus according to claim 1, wherein the magnifying lens array includes a magnifying lens eccentric relative to corresponding one of the plurality of apertures of the aperture array such that a principal ray of a charged particle beam having passed through the converging lens passes through a center of the magnifying lens. 3. The drawing apparatus according to claim 1, wherein a magnifying lens included in the magnifying lens array is configured to have infinite magnification. 4. The drawing apparatus according to claim 1, further comprising:an aligner deflector configured to deflect the plurality of charged particle beams between the plurality of crossovers formed by the lens array and the magnifying lens array, to adjust positions of the plurality of crossovers. 5. A drawing apparatus configured to perform drawing on a substrate with a plurality of charged particle beams, the apparatus comprising:an irradiation system including a collimator lens on which a diverging charged particle beam is incident;an aperture array configured to split the charged particle beam from the collimator lens into the plurality of charged particle beams;a lens array configured to form a plurality of crossovers of the plurality of charged particle beams from the aperture array; anda projection system including an element having a plurality of apertures corresponding to the plurality of crossovers, and a plurality of projection units corresponding to the plurality of apertures and configured to project the plurality of charged particle beams from the plurality of apertures onto the substrate,wherein the lens array includes a correction lens array and a magnifying lens array, the correction lens array including a converging lens eccentric relative to corresponding one of the plurality of apertures of the element so as to align each of the plurality of crossovers formed via the aperture array, on which the charged particle beam is incident at incident angles according to aberration of the irradiation system, and via the lens array, with corresponding one of the plurality of apertures of the element, and the magnifying lens array configured, so as to form the plurality of crossovers, to magnify a plurality of crossovers formed by the correction lens array, converging lenses included in the correction lens array having such focal lengths that the eccentric converging lens refracts a charged particle beam corresponding thereto, without shielding of the charged particle beam, so that each of the plurality of charged particle beams is aligned with corresponding one of the plurality of apertures of the element, magnifying lenses included in the magnifying lens array having such focal lengths that the magnifying lenses respectively converge a plurality of charged particle beams, respectively converged by the converging lenses and then diverged, with convergent angles smaller than convergent angles of the plurality of charged particle beams respectively converged by the converging lenses. 6. The drawing apparatus according to claim 5, wherein an arrangement of magnifying lenses of the magnifying lens array is aligned with an arrangement of the plurality of apertures of the element. 7. The drawing apparatus according to claim 5, wherein the aperture array includes an aperture eccentric relative to the corresponding one of the plurality of apertures of the element with the converging lens. 8. The drawing apparatus according to claim 7, wherein the aperture array is disposed on a front focal plane of the correction lens array, and includes an aperture eccentric relative to the corresponding one of the plurality of apertures of the element by the same amount as that of the converging lens. 9. The drawing apparatus according to claim 5, wherein the collimator lens receives the charged particle beam from a crossover, deviating from a front focal plane of the collimator lens, of a charged particle beam. 10. The drawing apparatus according to claim 5, comprising:a plurality of groups arranged in parallel, each group including the irradiation system, the aperture array, the lens array, and the projection system. 11. The drawing apparatus according to claim 5, wherein the element includes a blanking deflector array. 12. The drawing apparatus according to claim 5, wherein the element includes a blanking stop aperture array. 13. A method of manufacturing an article, the method comprising:performing drawing on a substrate using a drawing apparatus;developing the substrate on which the drawing has been performed; andprocessing the developed substrate to manufacture the article,wherein the drawing apparatus is configured to perform drawing on the substrate with a plurality of charged particle beams, the apparatus comprises:an irradiation system including a collimator lens on which a diverging charged particle beam is incident;an aperture array configured to split the charged particle beam from the collimator lens into the plurality of charged particle beams;a lens array configured to form a plurality of crossovers of the plurality of charged particle beams from the aperture array; anda projection system including an element having a single aperture and configured to converge the plurality of charged particle beams corresponding to the plurality of crossovers and to project the plurality of charged particle beams having passed through the single aperture onto the substrate,wherein the lens array includes a correction lens array and a magnifying less array, the correction lens array including a converging lens eccentric relative to corresponding one of a plurality of apertures of the aperture array such that the plurality of charged particle beams converged according to aberration of the projection system are converged to the single aperture, and the magnifying lens array configured, so as to form the plurality of crossovers, to magnify a plurality of crossovers formed by the correction lens array, converging lenses included in the correction lens array having such focal lengths that the eccentric converging lens refracts a charged particle beam corresponding thereto, without shielding of the charged particle beam, so that the plurality of charged particle beams are converged to the single aperture, magnifying lenses included in the magnifying lens array having such focal lengths that the magnifying lenses respectively converge a plurality of charged particle beams, respectively converged by the converging lenses and then diverged, with convergent angles smaller than convergent angles of the plurality of charged particle beams respectively converged by the converging lenses. 14. A method of manufacturing an article, the method comprising:performing drawing on a substrate using a drawing apparatus;developing the substrate on which the drawing has been performed; andprocessing the developed substrate to manufacture the article,wherein the drawing apparatus is configured to perform drawing on the substrate with a plurality of charged particle beams, the apparatus comprises:an irradiation system including a collimator lens on which a diverging charged particle beam is incident;an aperture array configured to split the charged particle beam from the collimator lens into the plurality of charged particle beams;a lens array configured to form a plurality of crossovers of the plurality of charged particle beams from the aperture array; anda projection system including an element having a plurality of apertures corresponding to the plurality of crossovers, and a plurality of projection units corresponding to the plurality of apertures and configured to project the plurality of charged particle beams from the plurality of apertures onto the substrate,wherein the lens array includes a correction lens array and a magnifying lens array, the correction lens array including a converging lens eccentric relative to corresponding one of the plurality of apertures of the element so as to align each of the plurality of crossovers formed via the aperture array, on which the charged particle beam is incident at incident angles according to aberration of the irradiation system, and via the lens array, with corresponding one of the plurality of apertures of the element, and the magnifying lens array configured, so as to form the plurality of crossovers, to magnify a plurality of crossovers formed by the correction lens array, converging lenses included in the correction lens array having such focal lengths that the eccentric converging lens refracts a charged particle beam corresponding thereto, without shielding of the charged particle beam, so that each of the plurality of charged particle beams is aligned with corresponding one of the plurality of apertures of the element, magnifying lenses included in the magnifying lens array having such focal lengths that the magnifying lenses respectively converge a plurality of charged particle beams, respectively converged by the converging lenses and then diverged, with convergent angles smaller than convergent angles of the plurality of charged particle beams respectively converged by the converging lenses.