An irradiation apparatus for irradiating by scanning a target volume according to a predetermined dose profile with a scanning beam of charged particles forming an irradiation spot on said target volume, said apparatus comprising: a beam generating device, a reference generator for computing, fro
An irradiation apparatus for irradiating by scanning a target volume according to a predetermined dose profile with a scanning beam of charged particles forming an irradiation spot on said target volume, said apparatus comprising: a beam generating device, a reference generator for computing, from said predetermined dose profile, through a dynamic inverse control strategy, the time evolution of commanded variables, these variables being the beam current I(t), the spot position settings x(t),y(t) and the scanning speed settings vx(t), vy(t), a monitor device having means for detecting at each time (t), the actual spot position as a measured position defined by the values xm(t),ym(t) on the target volume, characterised in that said irradiation apparatus further comprises means for determining the differences ex(t), ey(t) between the measured values xm(t), ym(t) and the spot position settings x(t) and y(t), and means for applying a correction to the scanning speed settings vx(t) and vy(t) depending on said differences ex(t), ey(t). The present invention is also related to a monitor for determining beam position in real-time.
대표청구항▼
The invention claimed is: 1. An irradiation apparatus for irradiating by scanning a target volume according to a predetermined dose profile with a scanning beam of charged particles forming an irradiation spot on said target volume, said apparatus comprising: a beam generating device, a reference g
The invention claimed is: 1. An irradiation apparatus for irradiating by scanning a target volume according to a predetermined dose profile with a scanning beam of charged particles forming an irradiation spot on said target volume, said apparatus comprising: a beam generating device, a reference generator for computing, from said predetermined dose profile, through a dynamic inverse control strategy, the time evolution of commanded variables, these variables being the beam current I(t), the spot position settings x(t),y(t) and the scanning speed settings vx(t), vy(t), a monitor device having means for detecting at each time (t), the actual spot position as a measured position defined by the values xm(t),ym(t) on the target volume, wherein said irradiation apparatus further comprises means for determining the differences ex(t), ey(t) between the measured values xm(t), ym(t) and the spot position settings x(t) and y(t), and means for applying a correction to the scanning speed settings vx(t) and vy(t) depending on said differences ex(t), ey(t). 2. The irradiation apparatus according to claim 1, wherein the monitor device further comprises means for measuring the total instantaneous dose deposited by the beam in the target volume, and means for correcting this dose deposition or for pausing the beam and informing an external operator when said instantaneous dose is outside of an expected range. 3. The irradiation apparatus according to claim 1, arranged so as to generate a beam in one direction and so as to irradiate with said beam the target volume in layers perpendicular to said direction, said layers being irradiated in one or more irradiation frames, wherein the monitor device comprises in addition means for determining the dose distribution in a plane perpendicular to the beam direction, for each successive irradiation frame, and means for pausing the beam and informing an external operator when said dose distribution is outside of an expected range. 4. A process implementing the apparatus as claimed in claim 1, said process comprising the steps of: determining a dose distribution profile referenced as a map D(x,y,z); determining, from said dose map, trajectories comprising spot position settings x(t), y(t), scanning speed settings vx(t), vy(t) and a beam current setting I(t) for a set of irradiation depths z; feeding said scanning speed signals vx(t) and vy(t) to a scanning magnet system; feeding said beam current signal I(t) to a beam generating device; detecting and measuring the actual spot values xm(t), ym(t), determining the differences ex(t), ey(t) between said measured spot values xm(t), ym(t) and the spot position settings x(t) and y(t); and applying a correction to the scanning speed settings vx(t) and vy(t) depending on said differences ex(t), ey(t). 5. Use of the apparatus according to claim 1 or a process implementing the apparatus as claimed in claim 1, said process comprising the steps of: determining a dose distribution profile referenced as a map D(x,y,z); determining, from said dose map, trajectories comprising spot position settings x(t), y(t), determining, from said dose map, trajectories comprising spot position settings x(t), v(t), scanning speed settings vx(t), vyt and a beam current setting I(t) for a set of irradiation depths z; feeding said scanning speed signals vx(t) and vy(t) to a scanning magnet system; feeding said beam current signal I(t) to a beam generating device; detecting and measuring the actual spot values xm(t), ym(t), determining the differences ex(t), ey(t) between said measured spot values xm(t), ym(t) and the spot position settings x(t) and v(t); and applying a correction to the scanning speed settings vx(t) and vy(t) depending on said differences ex(t), ey(t) for irradiating a target.
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