Patent Number: 
Section: claims

1. A compact device that generates radiation, comprising:a generator vacuum tube comprising:a source generating charged particles, anda target onto which the charged particles are directed;a high voltage supply comprising a high voltage multiplier ladder located at least partly side-by-side and substantially adjacent to the generator vacuum tube, the high voltage supply being configured to apply a high voltage between the source and the target to accelerate the charged particles to a predetermined energy level; andan electrical coupling between the high voltage supply and the target of the generator vacuum tube, wherein the electrical coupling comprises a high voltage turn-around comprising a split and flip that accommodates an electrical field stress caused by the high voltage multiplier ladder being located side-by-side adjacent to the generator vacuum tube,wherein the split and flip reduces electrical field stress by a split in the high voltage multiplier ladder such that the high voltage multiplier ladder comprises a first portion and a second portion and the first portion of the high voltage multiplier ladder is turned directionally back toward the target. 2. The compact device according to claim 1, the generated radiation comprising neutron radiation. 3. The compact device according to claim 1, the generated radiation comprising x-rays. 4. The compact device according to claim 1, the generated radiation comprising gamma-rays. 5. The compact device according to claim 1, wherein the compact device measures an overall length of less than about twenty (20) inches in length. 6. The compact device according to claim 1, further comprising a corona shield covering the high voltage turn-around to reduce the electrical field stress. 7. The compact device according to claim 1, further comprising a corona shield about the split. 8. The compact device according to claim 1, further comprising an electrically insulating mechanical support that is located proximately to the target and provides mechanical support to an end of the generator vacuum tube, the electrically insulating mechanical support comprising a conductor positioned perpendicular to the axis of the electrically insulating mechanical support. 9. The compact device according to claim 8, further comprising a corona shield that reduces electrical field stress at the high-voltage turn-around. 10. The compact device according to claim 9, wherein the conductor is operatively coupled to the corona shield. 11. The compact device according to claim 8, wherein the electrically insulating mechanical support comprises Aluminum Nitride. 12. The compact device according to claim 1, wherein the generator vacuum tube comprises at least one intermediate electrode located between the source and the target and operatively coupled to an intermediate-voltage point located between multiplier stages at an intermediate potential between an input voltage and an output voltage of the high voltage multiplier ladder. 13. The compact device according to claim 12, further comprising a protective surge resistor coupled between the intermediate electrode and the intermediate-voltage point between the multiplier stages. 14. The compact device according to claim 12, further comprising a diode coupled between the intermediate electrode and the intermediate-voltage point-between the multiplier stages. 15. The compact device according to claim 8, the electrically insulating mechanical support further comprising an internal flow path configured for circulation of an insulating cooling fluid. 16. A radiation logging tool, comprising:a tool housing;a compact generator that produces radiation through a reaction of energetic charged particles accelerated in a DC electrostatic field with a target on which the charged particles impinge;a power supply operatively coupled to the compact generator;control circuitry operatively coupled to the compact generator;wherein the compact generator comprises:a generator vacuum tube comprising:a source generating charged particles, and a target onto which the charged particles are directed; a high voltage supply comprising a high voltage multiplier ladder located at least partly side-by-side and substantially adjacent to the generator vacuum tube, the high voltage supply being configured to apply a high voltage between the source and the target to accelerate the charged particles to a predetermined energy level; andan electrical coupling between the high voltage supply and the target of the generator vacuum tube, wherein the electrical coupling comprises a high voltage turn-around comprising a split and flip that accommodates an electrical field stress caused by the high voltage multiplier ladder being located side-by-side adjacent to the generator vacuum tube by reducing the electrical field stress at the high voltage turn-around,wherein the split and flip and reduces electrical field stress by a split in the high voltage multiplier ladder, wherein the high voltage multiplier ladder comprises a first portion and a second portion and the first portion of the high voltage multiplier ladder is turned directionally back toward the target, wherein the voltage level at an end of the first portion and a beginning of the second portion is lower than an output voltage of the high voltage multiplier ladder.