Patent Number: 044255063
Section: claims

1. A charged particle accelerator irradiation machine for irradiating an object comprising: (a) charged particle accelerator means for accelerating a beam of charged particles along a given axis,  (b) a bending magnet system or bending said beam away from said axis through a deflection angle .chi. with respect to said given axis, said bending magnet system comprising,  polepiece means comprising first and second pole caps disposed about a median plane for establishing at least contiguous first and second magnetic field regions, each said magnetic field region comprising a substantially homogeneous field. 2. The irradiation machine of claim 1 wherein said first field boundary comprises a straight line. 3. The irradiation machine of claim 2 wherein said first field boundary is parallel to said second field boundary. 4. The irradiation machine of claim 3 comprising target means for production of penetrating radiation from the collision of said beam therewith. 5. The irradiation machine of claim 4 further comprising gantry means for rotating said machine along arcs through angles in each of two orthogonal planes passing through said object. 6. A first order achromatic deflection system for deflecting charged particles through a deflection angle .chi. comprising: 7. The deflection system of claim 6 wherein said polepiece means comprising at least one step in the thickness of each said pole cap for establishing a field boundary between said magnetic field regions, the locus of said field boundary forming a straight line in the plane of each said pole cap. 8. The deflection system of claim 7 wherein said charged particles are incident upon said first magnetic field region through first field boundary at an entrance position, the direction of incidence substantially at an angle .vertline..beta..vertline. with said field boundary, whereby a desired focal condition is obtained and whereby said charged particle momentum is rotated through an angle .alpha..sub.1 in transiting said first magnetic field region. 9. The deflection system of claim 8 wherein said charged particles exiting said first region are concurrently incident upon said second region through second field boundary between first and second region at an angle .beta..sub.2 at a first position on said boundary whereby another desired focal condition is attained and said charged particle momenta are rotated through an additional angle .alpha..sub.2, said angle .beta..sub.2 =90.degree.-.alpha..sub.2. 10. The deflection system of claim 9 wherein said charged particles are rotated through an additional angular increment .alpha..sub.2 to again intercept said second boundary at an angle having the magnitude .vertline..beta..sub.2 .vertline. and re-enter said first region at a position spaced apart from said first position along said second boundary whereby a third focal condition is achieved. 11. The deflection system of claim 10 wherein said charged particles are again rotated through yet an additional angular increment of magnitude .alpha..sub.1 whereby the total angular deflection .chi.=2(.alpha..sub.1 +.alpha..sub.2) is achieved and said charged particle momentum exits said first field region at an exit position along said first field boundary, said exit position spaced apart from said entrance position and at an angle .beta. with respect to said first field boundary. 12. The deflection system of claim 11 wherein said first and second field boundaries are parallel.