Strategy for controlling cathode width voltage

The invention claimed is: 1 . A method for an interventional imaging system, the method comprising: applying a voltage to a gridding electrode of a cathode of the interventional imaging system via a multi-stage switching unit including a first control circuit and a second control circuit different from the first control circuit; during a first transition of the voltage from a first, gridding voltage of the interventional imaging system generated by the first control circuit to a second, bias voltage of the interventional imaging system generated by the second control circuit, selectively bypassing a plurality of stages of the first control circuit sequentially in a first non-consecutive order to decrease the voltage from the first, gridding voltage to a common voltage of the interventional imaging system; and during a second transition of the voltage from the second, bias voltage generated by the second control circuit to the first, gridding voltage generated by the first control circuit, selectively engaging the plurality of stages of the first control circuit sequentially in a second non-consecutive order to increase the voltage from the common voltage to the first, gridding voltage. 2 . The method of claim 1 , wherein the cathode is a unipolar cathode, and both of the first, gridding voltage and the second, bias voltage are negative voltages. 3 . The method of claim 2 , wherein the voltage is applied to the gridding electrode of the cathode of the interventional imaging system from voltage control modules that are connected to the gridding electrode through a cable with a length greater than 40 meters. 4 . The method of claim 1 , wherein: each stage of the plurality of stages of the first control circuit includes a −1 kV voltage source, a capacitor, and at least two switches to bypass or negatively connect the −1 kV voltage source to the cathode; and the second control circuit includes a high precision voltage source capable of generating up to 1.2 kV with a precision of +/−50V, a capacitor, and at least two switches to bypass or negatively connect the high precision voltage source to the cathode. 5 . The method of claim 4 , wherein: the first, gridding voltage is −8 kV with respect to the common voltage, and the second, bias voltage is between 0 and −1.2 kV with respect to the common voltage. 6 . The method of claim 1 , wherein the second non-consecutive order is a reverse of the first non-consecutive order. 7 . The method of claim 1 , wherein: selectively bypassing the plurality of stages of the first control circuit sequentially in the first non-consecutive order to decrease the voltage from the first, gridding voltage to the common voltage of the interventional imaging system comprises performing a first sequence of steps, where during each step of the first sequence of steps at least one stage of the plurality of stages is bypassed, and during at least one step of the first sequence of steps, a previously bypassed stage is engaged; and selectively engaging the plurality of stages of the first control circuit sequentially in the second non-consecutive order to increase the voltage from the common voltage to the first, gridding voltage comprises performing a second sequence of steps, where during each step of the second sequence of steps at least one stage of the plurality of stages is engaged, and during at least one step of the second sequence of steps, a previously engaged stage is bypassed. 8 . The method of claim 1 , further comprising: selectively bypassing the plurality of stages of the first control circuit sequentially in the first non-consecutive order to decrease the voltage from the first, gridding voltage to the common voltage of the interventional imaging system based on a first protocol generated based on a first stage engagement matrix stored in a memory of the interventional imaging system; and selectively engaging the plurality of stages of the first control circuit sequentially in the second non-consecutive order to increase the voltage from the common voltage to the first, gridding voltage based on a second protocol generated based on a second stage engagement matrix stored in the memory; wherein the first stage engagement matrix and the second stage engagement matrix indicate when each stage of the plurality of stages is to be engaged, and when each stage of the plurality of stages is to be bypassed. 9 . The method of claim 8 , wherein the first stage engagement matrix and the second stage engagement matrix indicate when each stage of the plurality of stages is to be engaged and when each stage of the plurality of stages is to be bypassed via a binary coding, where a one indicates that a stage is to be engaged and a zero indicates that a stage is to be bypassed. 10 . The method of claim 8 , wherein the first protocol and the second protocol are optimized to reduce a voltage imbalance between stages of the plurality of stages. 11 . An interventional imaging system, comprising: an X-ray source including a unipolar cathode and a gridding electrode; a multi-stage switching unit including a first control circuit having a plurality of stages configured to generate a first, gridding voltage at the gridding electrode of the unipolar cathode via the plurality of stages of the multi-stage switching unit, and a second control circuit configured to generate a second, bias voltage at the gridding electrode; and a controller operably connected to the X-ray source and configured to: when transitioning from the first, gridding voltage to the second, bias voltage, selectively bypass the plurality of stages of the first control circuit sequentially in a first non-consecutive order to decrease a voltage applied to the gridding electrode; and when transitioning from the bias voltage to the gridding voltage, selectively engage the plurality of stages of the first control circuit sequentially in a second non-consecutive order to increase the voltage applied to the gridding electrode, the second non-consecutive order being a reverse of the first non-consecutive order. 12 . The interventional imaging system of claim 11 , wherein the first, gridding voltage and the second, bias voltage are generated at the gridding electrode via a cable with a length greater than 40 meters, and wherein both of the first, gridding voltage and the second, bias voltage are negative voltages with respect to a common voltage of the interventional imaging system. 13 . The interventional imaging system of claim 11 , wherein: each of the plurality of stages of the first control circuit includes a −1 kV voltage source, a capacitor, and at least two switches to bypass or negatively connect the −1 kV voltage source to the unipolar cathode; and the second control circuit includes a high precision voltage source capable of generating up to 1.2 kV with a precision of +/−50V, a capacitor, and at least two switches to bypass or negatively connect the high precision voltage source to the unipolar cathode. 14 . The interventional imaging system of claim 13 , wherein the controller is further configured to: selectively bypass the plurality of stages of the first control circuit sequentially in the first non-consecutive order to decrease the voltage applied to the gridding electrode by bypassing at least one stage of the plurality of stages at each step of a first sequence of steps, and engaging a previously bypassed stage during at least one step of the first sequence of steps; and selectively engage the plurality of stages of the first control circuit sequentially in the second non-consecutive order to increase the voltage app