Magnetron and method of adjusting resonance frequency of magnetron

The invention claimed is: 1. A magnetron comprising: an anode cylinder that extends in a cylindrical shape along a central axis; a plurality of tabular vanes each of which has at least one end fixed to the anode cylinder and that extend toward the central axis from an inner surface of the anode cylinder; and one or a plurality of pressure-equalizing rings that are disposed coaxially with respect to the central axis of the anode cylinder, wherein each of the tabular vanes includes: a protrusion that faces the pressure-equalizing ring in an axial direction of the anode cylinder, and a plurality of notches that are grooves formed in a base part of the protrusion at predetermined intervals, wherein the plurality of notches are base points for deforming the protrusion toward a side of the pressure-equalizing ring or an opposite side to the pressure-equalizing ring. 2. The magnetron according to claim 1 , wherein the protrusion is a columnar protrusion formed by providing a slit which is substantially parallel to the pressure-equalizing ring in the axial direction of the anode cylinder. 3. The magnetron according to claim 1 , wherein the tabular vanes include: a plurality of first tabular vanes that extend toward the central axis from the inner surface of the anode cylinder; and second tabular vanes that extend toward the central axis from the inner surface of the anode cylinder and are provided at positions interposed between the first tabular vanes, and wherein the tabular vanes which are adjacent to each other are respectively connected to different pressure-equalizing rings. 4. A magnetron comprising: an anode cylinder that extends in a cylindrical shape along a central axis; a plurality of tabular vanes each of which has at least one end fixed to the anode cylinder and that extend toward the central axis from an inner surface of the anode cylinder; and one or a plurality of pressure-equalizing rings that are disposed coaxially with respect to the central axis of the anode cylinder, wherein each of the tabular vanes include: first penetration holes that are formed to penetrate through the tabular vanes in a circumferential direction and not to be in contact with the pressure-equalizing rings; second penetration holes that are formed to penetrate through the tabular vanes in the circumferential direction and to be adjacent to the first penetration holes; and partitions that are formed between the first penetration holes and the second penetration holes and face the pressure-equalizing rings disposed in the first penetration holes, wherein the partitions are deformed toward a side of the pressure-equalizing rings disposed in the first penetration holes or opposite sides to the first penetration holes when applied with force. 5. The magnetron according to claim 4 , wherein the tabular vanes are separate from each other in an axial direction of the anode cylinder. 6. The magnetron according to claim 4 , wherein each of the partitions has a plurality of notches. 7. The magnetron according to claim 4 , wherein the tabular vanes include: a plurality of first tabular vanes that extend toward the central axis from the inner surface of the anode cylinder; and second tabular vanes that extend toward the central axis from the inner surface of the anode cylinder and are provided at positions interposed between the first tabular vanes, and wherein the tabular vanes which are adjacent to each other are respectively connected to different pressure-equalizing rings. 8. A method of adjusting a resonance frequency of a magnetron the method comprising: forming protrusions facing a pressure-equalizing ring in tabular vanes in an axial direction of an anode cylinder, wherein the anode cylinder extends in a cylindrical shape along a central axis and each of a plurality of tabular vanes has at least one end fixed to the anode cylinder and extends toward the central axis from an inner surface of the anode cylinder; forming a plurality of notches that are grooves formed in a base part of the protrusions at predetermined intervals, wherein the plurality of notches are base points for deforming the protrusions; and deforming, using the plurality of notches, the protrusions toward sides of the pressure-equalizing rings to adjust the resonance frequency of the magnetron. 9. The method of adjusting the resonance frequency of the magnetron according to claim 8 , wherein any one of the plurality of notches is deformed depending on an adjustment amount of the resonance frequency. 10. A method of adjusting a resonance frequency of a magnetron including an anode cylinder that extends in a cylindrical shape along a central axis, a plurality of tabular vanes each of which has at least one end fixed to the anode cylinder and that extend toward the central axis from an inner surface of the anode cylinder, and one or a plurality of pressure-equalizing rings that are disposed coaxially with respect to the central axis of the anode cylinder, the method comprising: a step of forming first penetration holes which penetrate through the tabular vanes in a circumferential direction and are not in contact with the pressure-equalizing rings; a step of forming second penetration holes which penetrate through the tabular vanes in the circumferential direction and are adjacent to the first penetration holes; and a step of forming partitions which face the pressure-equalizing rings disposed in the first penetration holes between the first penetration holes and the second penetration holes, wherein, in a case where the resonance frequency of the magnetron is adjusted, the partitions are deformed toward sides of the pressure-equalizing rings disposed in the first penetration holes or opposite sides to the first penetration holes.