CT imaging apparatus and methods

What is claimed is: 1. A method of imaging a patient in an apparatus comprising: a patient support on which the patient may be positioned, and a rotatable gantry supporting: a source of imaging radiation for generating a radiation beam towards the patient, and a detector for detecting the radiation beam after interaction with the patient, the detector operating in a cyclical pattern of an exposure phase followed by a readout phase, the method comprising: for a first detector cycle, in which the gantry has a first angle of rotation, controlling the source of imaging radiation to emit a first radiation beam pulse during the exposure phase, and reading out respective first imaging data during the readout phase; for a second, subsequent detector cycle, determining if the gantry has rotated through at least a threshold angular displacement relative to said first angle of rotation, if so, controlling the source of imaging radiation to emit a second radiation beam pulse during the exposure phase, and reading out respective second imaging data during the readout phase. 2. The method according to claim 1 , wherein the first radiation beam pulse is emitted at a first point in time, and the method further comprises: for said second detector cycle, determining if a threshold period of time has elapsed since said first point in time and, if so, controlling the source of imaging radiation to emit said second radiation beam pulse during the exposure phase. 3. The method according to claim 1 , wherein the rotatable gantry further supports a source of therapeutic radiation, and the source of therapeutic radiation and the rotatable gantry are controlled according to a treatment plan which is delivered at a varying rate of rotation. 4. The method according to claim 1 , wherein said second detector cycle follows said first detector cycle successively. 5. The method according to claim 1 , further comprising: reconstructing a volume image of said patient using a dataset comprising at least the imaging data from said first and second detector cycles. 6. An apparatus for imaging a patient, comprising: a patient support configured to position the patient; a rotatable gantry supporting a source of imaging radiation configured to generate a radiation beam towards the patient; and a detector configured to detect the radiation beam after interaction with the patient, the detector operating in a cyclical pattern of an exposure phase followed by a readout phase; and control and imaging circuitry configured to: for a first detector cycle, in which the gantry has a first angle of rotation: control the source of imaging radiation to emit a first radiation beam pulse during the exposure phase, and read out respective first imaging data during the readout phase; for a second, subsequent detector cycle: determine if the gantry has rotated through at least a threshold angular displacement relative to said first angle of rotation, and if so, control the source of imaging radiation to emit a second radiation beam pulse during the exposure phase, and read out respective second imaging data during the readout phase. 7. The apparatus according to claim 6 , wherein the first radiation beam pulse is emitted at a first point in time, and the control and imaging circuitry is further configured to: for said second detector cycle, determine if a threshold period of time has elapsed since said first point in time and, if so, control the source of imaging radiation to emit said second radiation beam pulse during the exposure phase. 8. The apparatus according to claim 6 , wherein the rotatable gantry further supports a source of therapeutic radiation, and the source of the therapeutic radiation and the rotatable gantry are controlled according to a treatment plan which is delivered at a varying rate of rotation. 9. The apparatus according to claim 6 , wherein said second detector cycle follows said first detector cycle successively. 10. The apparatus according to claim 6 , wherein the control and imaging circuitry is further arranged to reconstruct a volume image of said patient using a dataset comprising at least the imaging data from said first and second detector cycles.