Treatment planning device, particle beam therapy system and method for determining scanning route of charged particle beam

The invention claimed is: 1. A treatment planning device by which a scanning route of a charged particle beam of a particle beam therapy system is determined, wherein the particle beam therapy system comprises an X-directional scanning electromagnet and a Y-directional scanning electromagnet for deflecting a charged particle beam in an X-direction and a Y-direction which are two perpendicular directions to a traveling direction of the charged particle beam so as for the charged particle beam to move and stay repeatedly and the charged particle beam is irradiated onto an affected part of a patient which is an irradiation objective, wherein the treatment planning device comprises a spot position storing unit which stores spot positions which are arranged in a grid shape in the X-direction and the Y-direction for each layer, which are points set in the affected part where the charged particle beam stays, a scanning candidate route extracting unit which extracts plural candidates of scanning routes in which each of the scanning routes connects all spot positions in one layer which are stored in the spot position storing unit, a scanning route evaluating unit which defines an evaluation function J J = ∑ k = 1 n - 1 ⁢ ( w k ⁢ T k ) using a necessary scanning time Tk and a weight coefficient wk for a kth partial route among partial routes which are routes between the spot positons which are adjacent on one of plural scanning routes which are extracted by the scanning candidate route extracting unit, and number n of spots in the layer, and calculates the evaluation function J regarding each of plural scanning candidate routes which are extracted by the scanning candidate route extracting unit by setting the weight coefficient wk with respect to a partial route which passes through affected tissue to be 1, the weight coefficient wk with respect to a normal tissue to be larger than 1 and the weight coefficient wk with respect to a partial route which passes through an important internal organ to be larger than the weight coefficient wk with respect to a partial route which passes through the normal tissue and a scanning route determining unit which determines a scanning route which is used for therapy based on a value of the evaluation function J which is calculated by the scanning route evaluating unit. 2. The treatment planning device according to claim 1 , wherein the scanning candidate route extracting unit sets a zigzag route as the scanning route by performing a route-setting repeatedly in which among arranging direction of spot positions which are arranged in a grid shape, among speed of the charged particle beam which is moved by the X-directional scanning electromagnet and speed of the charged particle beam which is moved by the Y-directional scanning electromagnet, a direction of faster speed is set to be a row direction, among rows of arrangement of the spot positons, a spot position of one end of one end row is set to be a starting point, a route is set from the starting point to a spot position of another end of the row, further, a route is set from a spot position of the other to a spot position of an end of an adjacent row, further, a route is set from a spot position of an end of adjacent row to another end of the row. 3. The treatment planning device according to claim 2 , wherein the scanning candidate route extracting unit sets a loop route or other zigzag route in a group of spot position where spot positions cannot be connected in a case where all of spot positions in the one layer cannot be connected by the zigzag route. 4. The treatment planning device according to claim 3 , wherein the scanning candidate route extracting unit sets a loop route which is set by a round-trip route in the spot position which is arranged in one dimension in a case where all of spot positions in the one layer cannot be connected by a zigzag route or a loop route and a group of spot position which is arranged in one dimension is left. 5. A particle beam therapy system comprising a treatment planning device claimed in claim 1 , an X-directional electromagnet and a Y-directional electromagnet, an irradiation controlling device comprising a scanning control unit which controls the X-directional electromagnet and the Y-directional electromagnet according to a scanning route which is determined by the scanning route determining unit. 6. A method for determining a scanning route of a charged particle beam of a particle beam therapy system in which scanning is performed by moving and staying the charged particle beam repeatedly by an X-directional scanning electromagnet and a Y-directional scanning electromagnet for deflecting a charged particle beam in an X-direction and a Y-direction which are two perpendicular directions to a traveling direction of the charged particle beam and the charted particle beam is irradiated onto an affected part of a patient which is an irradiation objective; comprising a spot positions storing step for storing spot positions which are arranged in a grid shape in the X-direction and the Y-direction for each layer, which are points set in the affected part where the charged particle beam stays, a scanning candidate route extracting step for extracting plural candidates of scanning routes in which each of the scanning routes connects all spot positions in one layer which are stored in the spot position storing step, a scanning route evaluating step for defining an evaluation function J J = ∑ k = 1 n - 1 ⁢ ( w k ⁢ T k ) using a necessary scanning time Tk and a weight coefficient wk for a kth partial route among partial routes which are routes between the spot positons which are adjacent on one of plural scanning routes which are extracted in the scanning candidate route extracting step, and number n of spots in the layer, and calculating the evaluation function J regarding each of plural scanning candidate routes which are extracted in the scanning candidate route extracting step by setting the weight coefficient wk with respect to a partial route which passes through affected tissue to be 1, the weight coefficient wk with respect to a normal tissue to be larger than 1 and the weight coefficient wk with respect to a partial route which passes through an important internal organ to be larger than th