X-ray computed tomography apparatus, high voltage generation device, and radiological image diagnostic apparatus

The invention claimed is: 1. An X ray computed tomography apparatus, comprising: an X-ray tube device including a cathode configured to generate a thermoelectron, an anode configured to generate an X-ray upon receiving the thermoelectron generated by the cathode, and a support mechanism configured to support the anode to be rotatable about a rotation axis; an X-ray detector configured to detect the X-ray generated by the X-ray tube device; a rotating frame configured to support the X-ray tube device to be rotatable about a subject; a power generator configured to supply power to the support mechanism; voltage generators configured to switch, by high-speed X-ray ON/OFF control and high-speed X-ray modulation, an intensity of an X-ray to be generated by the anode; and a control circuit configured to control the voltage generators to switch the intensity of the X-ray to be generated by the anode, and control the power generator to rotate the anode, and when a value substantially equal to an integer multiple of a switching period of the intensity of the X-ray coincides with a rotation period of the anode, the control circuit is configured to control the power generator to shift at least some thermoelectron collision ranges of the anode in a first turn of the anode from thermoelectron collision ranges in a second turn of the anode. 2. The X-ray computed tomography apparatus according to claim 1 , wherein the control circuit changes the rotation period to shift a thermoelectron collision range of the anode in the first turn from a thermoelectron collision range in the second turn. 3. The X-ray computed tomography apparatus according to claim 2 , wherein the control circuit fixes the rotation period to a numerical value within a numerical value range not belonging to an integer multiple of the switching period. 4. The X-ray computed tomography apparatus according to claim 2 , wherein the control circuit fluctuates the rotation period. 5. The X-ray computed tomography apparatus according to claim 1 , further comprising a bias electrode placed between the cathode and the anode, wherein one of the voltage generators applies a bias voltage between the bias electrode and the cathode. 6. The X-ray computed tomography apparatus according to claim 5 , wherein the control circuit controls the voltage generators to alternately switch the intensity of the X-ray between a first intensity and a second intensity higher than the first intensity, and the first intensity is substantially zero. 7. The X-ray computed tomography apparatus according to claim 5 , wherein the control circuit controls the voltage generators to alternately switch the intensity of the X-ray between a first intensity and a second intensity higher than the first intensity, and the first intensity is higher than zero. 8. The X-ray computed tomography apparatus according to claim 7 , wherein one of the voltage generators applies a high voltage across the cathode and the anode. 9. The X-ray computed tomography apparatus according to claim 7 , wherein the first intensity is a first tube voltage and the second intensity is a second tube voltage higher than the first tube voltage, and the control circuit controls the voltage generators to switch a tube voltage of the X-ray between the first tube voltage and the second tube voltage for each view. 10. The X-ray computed tomography apparatus of claim 1 , wherein the control circuit is further configured to shift at least angular ranges of the thermoelectron collisions of the anode in the first turn of the anode from angular ranges of the thermoelectron collisions in the second turn of the anode, when the value substantially equal to the integer multiple of the switching period of the intensity of the X-ray coincides with the rotation period of the anode. 11. The X-ray computed tomography apparatus of claim 1 , wherein a switching period of the intensity of the X-ray generated by the anode is shorter than the rotation period of the anode. 12. A high voltage generation device connected to an X-ray tube device including a cathode configured to generate a thermoelectron, an anode configured to generate an X-ray upon receiving the thermoelectron generated by the cathode, and a support mechanism configured to support the anode to be rotatable about a rotation axis, comprising: a power generator configured to supply power to the support mechanism; voltage generators configured to switch, by high-speed X-ray ON/OFF control and high-speed X-ray modulation, an intensity of an X-ray to be generated by the anode; and a control circuit configured to control the voltage generators to switch the intensity of the X-ray to be generated by the anode, and control the power generator to rotate the anode, and when a value substantially equal to an integer multiple of a switching period of the intensity of the X-ray coincides with a rotation period of the anode, the control circuit is configured to control the power generator to shift at least some thermoelectron collision ranges of the anode in a first turn of the anode from thermoelectron collision ranges in a second turn of the anode. 13. A radiological image diagnostic apparatus, comprising: a cathode configured to generate a thermoelectron; an anode configured to generate an X-ray upon receiving the thermoelectron generated by the cathode; a support mechanism configured to support the anode to be rotatable about a rotation axis; a power generator configured to supply power to the support mechanism; voltage generators configured to switch, by high-speed X-ray ON/OFF control and high-speed X-ray modulation, an intensity of an X-ray to be generated by the anode; and a control circuit configured to control the voltage generators to switch the intensity of the X-ray to be generated by the anode, and control the power generator to rotate the anode, and when a value substantially equal to an integer multiple of a switching period of the intensity of the X-ray coincides with a rotation period of the anode, the control circuit is configured to control the power generator to shift at least some thermoelectron collision ranges of the anode in a first turn of the anode from thermoelectron collision ranges in a second turn of the anode.