Reduction of image lag in an X-ray detector panel

We claim: 1. A method of acquiring an X-ray image of a target volume, the method comprising: transferring accumulated charge from each pixel in a first array of pixels of an X-ray detector panel to a readout device during a first readout interval, wherein residual charge remains in each pixel in the first array of pixels after the transferring; after the first readout interval, transferring accumulated charge from each pixel in a second array of pixels of the X-ray detector panel to the readout device during a second readout interval, wherein residual charge remains in each pixel in the second array of pixels after the transferring of accumulated charge from each pixel in the second array of pixels; and during a reset interval that follows the second readout interval, concurrently transferring at least a portion of the residual charge from each pixel in the first array of pixels and at least a portion of the residual charge from each pixel in the second array of pixels, wherein transferring residual charge from each pixel in the first array of pixels comprises electrically coupling each pixel in the first array of pixels to a reference voltage associated with the readout device and transferring residual charge from each pixel in the second array of pixels comprises electrically coupling each pixel in the second array of pixels to the reference voltage associated with the readout device. 2. The method of claim 1 , further comprising, during the reset interval, concurrently transferring at least a portion of the residual charge from each pixel in each array of pixels of the X-ray detector panel to the reference voltage associated with the readout device. 3. The method of claim 1 , wherein electrically coupling each pixel in the first array of pixels to the reference voltage associated with the readout device comprises electrically coupling each pixel in the first array of pixels to the readout device. 4. The method of claim 1 , wherein the first array of pixels comprises a first row of pixels and the second array of pixels comprises a second row of pixels. 5. The method of claim 1 , wherein a start time of the reset interval is selected to occur prior to a treatment beam pulse and an end time of the reset interval is selected to occur after the treatment beam pulse. 6. The method of claim 5 , wherein a megavolt treatment beam is directed to the target volume during the treatment beam pulse. 7. The method of claim 1 , wherein concurrently transferring at least the portion of the residual charge from each pixel in the first array of pixels and at least the portion of the residual charge from each pixel in the second array of pixels comprises: communicatively coupling the first array of pixels to the reference voltage so that the residual charge from each pixel in the first array of pixels begins to be transferred to the reference voltage; and while the residual charge from each pixel in the first array of pixels is being transferred to the reference voltage, communicatively coupling the second array of pixels to the reference voltage so that the residual charge from each pixel in the second array of pixels begins to be transferred to the reference voltage. 8. The method of claim 1 , wherein concurrently transferring at least the portion of the residual charge from each pixel in the first array of pixels and at least the portion of the residual charge from each pixel in the second array of pixels comprises: communicatively coupling a first group of arrays of pixels that includes the first array of pixels to the reference voltage so that the residual charge from each pixel in the first group of arrays of pixels begins to be transferred to the reference voltage; and while the residual charge from each pixel in the first group of arrays of pixels is being transferred to the reference voltage, communicatively coupling a second group of arrays of pixels that includes the second array of pixels to the reference voltage so that the residual charge from each pixel in the second group of arrays of pixels begins to be transferred to the reference voltage. 9. The method of claim 1 , further comprising: prior to the first readout interval, preparing each pixel in the first array of pixels and each pixel in the second array of pixels to accumulate charge in response to incident X-rays; and causing imaging X-rays to be directed to the X-ray detector panel. 10. An apparatus comprising: an imaging X-ray source configured to direct imaging X-rays through a target volume and toward an X-ray detector panel; and a controller configured to: cause accumulated charge from each pixel in a first array of pixels of the X-ray detector panel to be transferred to a readout device during a first readout interval, wherein residual charge remains in each pixel in the first array of pixels after the transferring; after the first readout interval, causing accumulated charge from each pixel in a second array of pixels of the X-ray detector panel to be transferred to the readout device during a second readout interval, wherein residual charge remains in each pixel in the second array of pixels after the transferring of accumulated charge from each pixel in the second array of pixels; and during a reset interval that follows the second readout interval, causing at least a portion of the residual charge to be transferred from each pixel in the first array of pixels and concurrently causing at least a portion of the residual charge to be transferred from each pixel in the second array of pixels, wherein transferring residual charge from each pixel in the first array of pixels comprises electrically coupling each pixel in the first array of pixels to a reference voltage associated with the readout device and transferring residual charge from each pixel in the second array of pixels comprises electrically coupling each pixel in the second array of pixels to the reference voltage associated with the readout device. 11. The apparatus of claim 10 , wherein the controller is further configured to, during the reset interval, concurrently transfer at least a portion of the residual charge from each pixel in each array of pixels of the X-ray detector panel to the reference voltage associated with the readout device. 12. The apparatus of claim 10 , wherein electrically coupling each pixel in the first array of pixels to the reference voltage associated with the readout device comprises electrically coupling each pixel in the first array of pixels to the readout device. 13. The apparatus of claim 10 , wherein the first array of pixels comprises a first row of pixels and the second array of pixels comprises a second row of pixels. 14. The apparatus of claim 10 , wherein a start time of the reset interval is selected to occur prior to a treatment beam pulse and an end time of the reset interval is selected to occur after the treatment beam pulse. 15. The apparatus of claim 10 , wherein concurrently transferring at least the portion of the residual charge from each pixel in the first array of pixels and at least the portion of the residual charge from each pixel in the second array of pixels comprises: communicatively coupling the first array of pixels to the reference voltage so that the residual charge from each pixel in the first array of pixels begins to be transferred to the reference voltage; and while the residual charge from each pixel in the first array of pixels is being transferred to the reference voltage, communicatively coupling the second array of pixels to the reference voltage so that the residual charge from each pixel in the second array of pixel