Charged particle accelerators, radiation sources, systems, and methods

We claim: 1. A man-portable radiation generation system, comprising: a first module comprising a first case and at least one battery within the first case; a second module comprising a second case separate from the first case and a modulator within the second case, wherein the first and second modules are configured to be selectively electrically coupled to each other; and a third module comprising a third case separate from the first and second cases and a charged particle accelerator within the third case, wherein the second and third modules are configured to be selectively electrically coupled to each other; wherein: the at least one battery provides power to the second module when the first, second, and third modules are electrically coupled; and each of the modules is portable by hand by one or two people. 2. The man-portable radiation generation system of claim 1 , wherein each module is portable by hand by one person. 3. The man-portable radiation generation system of claim 1 , wherein the system weighs less than 300 pounds (136 kg). 4. The man-portable radiation generation system of claim 1 , wherein the first module further comprises: a controller to control operation of the source; and a control device removably mounted to the first module, for remote control of the controller. 5. The man-portable radiation generation system of claim 4 , wherein the first module further comprises: a cable electrically coupling the control device to the controller, and a spool, around which the cable is selectively wound. 6. The man-portable radiation generation system of claim 1 , wherein the third module further comprises: an electron gun mounted to the accelerator, to inject electrons into the accelerator, wherein the electron gun is powered by the modulator; a target coupled to the accelerator to generate X-ray radiation upon impact by accelerated electrons; and a magnetron coupled to the accelerator to provide radiofrequency power to the accelerator, wherein the magnetron is powered by the modulator, and the modulator is powered by the at least one battery. 7. The man-portable radiation generation system of claim 1 , wherein the third module further comprises a rigid support coupled to at least one inner wall of the third module; and the accelerator is coupled to the support. 8. The man-portable radiation generation system of claim 7 , wherein the support comprises: a rigid plate connected to the at least one inner wall; and at least one elastomeric member coupling the accelerator to the rigid plate. 9. The man-portable radiation generation system of claim 1 , configured to generate radiation having a peak energy of from about 500 KeV to about 1 MeV. 10. The man-portable radiation generation system of claim 1 , wherein at least one of the modules comprises a case having handles. 11. The man-portable radiation generation system of claim 1 , wherein the accelerator further comprises: a plurality of fins coupled to an exterior surface of the accelerator. 12. The man-portable radiation generation system of claim 1 , wherein the first module further comprises: an electrical plug for connection to an external power source. 13. The man-portable radiation generation system of claim 1 , further comprising: a detector. 14. The man-portable radiation generation system of claim 1 , wherein the first, second, and third modules each weigh less than 100 pounds (34 kg). 15. A radiation generation source, comprising: a case having at least one wall defining an air inlet therethrough; a charged particle accelerator within the case; a source of charged particles coupled to the accelerator to inject charged particles into the accelerator; a target coupled to an output of the accelerator, wherein impact of the accelerated charged particles on the target causes generation of radiation; and a plurality of fins coupled to an exterior surface of the accelerator, to air cool the accelerator; a fan proximate the case opening to move air through the case; and a guide to direct air into the first opening. 16. The radiation generation source of claim 15 , further comprising: a cover covering at least some of the plurality of fins, wherein the cover, the fins covered by the cover, and the exterior surface of the accelerator proximate the covered fins define a cooling manifold having a first opening for air to enter the cooling manifold and a second opening for air to exit the cooling manifold. 17. The radiation generation source of claim 16 , further comprising: a duct to convey air from the fan to the guide. 18. The radiation generation source of claim 17 , wherein: the guide is coupled to the manifold; and the at least one wall further defines at least one air exhaust vent. 19. The radiation generation source of claim 15 , wherein: the charged particle accelerator is a linear charged particle accelerator; and at least some of the plurality of fins are transverse to a long axis of the linear charged particle accelerator. 20. A battery operated radiation generation source, comprising: at least one battery; a charged particle accelerator; a source of charged particles coupled to the accelerator to inject charged particles into the accelerator; a target coupled to an output of the accelerator, wherein impact of the accelerated charged particles on the target causes generation of radiation; and a radiofrequency power supply to provide radiofrequency power to the accelerator; wherein the at least one battery provides power to the source of charged particles and the radiofrequency power supply. 21. The source of claim 20 , further comprising: a modulator coupled to the at least one battery, to convert direct current voltage from the battery to voltage pulses to be provided to the source of charged particles and to the radiofrequency power supply. 22. A charged particle acceleration system comprising: a case having at least one exterior wall, the exterior wall having an inner surface defining an interior space of the case; a charged particle accelerator within the interior space; a rigid support connected to the at least one exterior wall of the case, the rigid support being at least partially within the interior space of the case; and at least one elastomeric member connected to a portion of the rigid support within the interior space of the case; wherein the at least one elastomeric member couples the charged particle accelerator to the rigid support, the charged particle accelerator is suspended from the at least one elastomeric member at positions such that respective spaces are provided between the charged particle accelerator and the inner surface of the case, allowing for movement of the charged particle accelerator within the interior space of the case, and the charged particle accelerator system is portable by hand by one or two people. 23. The charged particle acceleration system of claim 22 , further comprising: a second rigid support coupled to the first rigid support by the at least one elastomeric member; wherein the accelerator is suspended from the at least one elastomeric member via the second rigid support. 24. The charged particle acceleration system of claim 22 , further comprising: a magnetron coupled to the charged particle accelerator within the case to provide radiofrequency power to the charged particle accelerator. 25. The charged particle acce