Coupling assembly and radiofrequency amplification system having the same

What is claimed is: 1. A radiofrequency (RF) amplification system comprising: a power cavity defined by a grounding deck, an inner conductor, and an outer conductor of the RF amplification system; and a coupling loop operably positioned within the power cavity between the inner conductor and the outer conductor, the coupling loop including a secured segment that is coupled to the grounding deck and a movable segment that is coupled to the secured segment, the secured segment extending between the grounding deck and the movable segment; wherein the coupling loop defines a loop region, the movable segment being movable relative to the secured segment while the secured segment is stationary to change a size of the loop region and thereby change an amount of inductive coupling between the coupling loop and a magnetic field within the power cavity. 2. The RF amplification system of claim 1 , wherein the loop region includes a fixed section and an adjustable section, the secured segment defining a boundary of the fixed section, wherein at least a portion of the fixed section of the loop region exists between the adjustable section of the loop region and the secured segment, the fixed section of the loop region determining a baseline portion of the amount of inductive coupling, the adjustable section of the loop region increasing the amount of inductive coupling from the baseline portion. 3. The RF amplification system of claim 2 , wherein the amount of inductive coupling increases in a substantially gradual manner as the amount of inductive coupling increases from the baseline portion to a maximum of the amount of inductive coupling. 4. The RF amplification system of claim 2 , wherein the baseline portion is at least 30% of a maximum of the amount of inductive coupling. 5. The RF amplification system of claim 1 , wherein the coupling loop is connected to the grounding deck at a first conductor interface and the secured segment and the movable segment are connected to each other at a second conductor interface, wherein the first and second conductor interfaces have fixed positions with respect to each other when the movable segment is moved, the secured segment extending between the first and second conductor interfaces and having a non-linear shape. 6. The RF amplification system of claim 1 , wherein the secured segment is a first secured segment and the coupling loop further comprises a second secured segment that is electrically coupled to an output conductor of the RF amplification system, the movable segment extending between and electrically joining the first and second secured segments, the movable segment being movable relative to the first and second secured segments. 7. The RF amplification system of claim 1 , further comprising a capacitor positioned in series with the secured segment and the movable segment. 8. The RF amplification system of claim 1 , wherein the movable segment is rotatable about an axis of rotation that extends generally parallel to the grounding deck, the coupling loop having a three-dimensional structure at one or more positions of the movable segment. 9. The RF amplification system of claim 1 , further comprising a coupling-control instrument that is attached to the coupling loop, the coupling-control instrument indicating how to move the movable segment to increase or decrease the amount of inductive coupling. 10. The RF amplification system of claim 9 , wherein the coupling-control instrument includes non-conductive material and has an indicator and at least one reference marker, wherein a position of the indicator with respect to the at least one reference marker approximates the amount of inductive coupling, wherein the indicator or the at least one reference marker is attached to the movable segment and moves with the movable segment while the other has a stationary position. 11. A coupling assembly configured to transfer power to a load, the coupling assembly comprising: a first secured segment configured to mechanically and electrically couple to a ground; a second secured segment configured to mechanically and electrically couple to an output conductor; and a movable segment configured to extend between and join the first and second secured segments thereby forming a coupling loop, the movable segment being movable relative to each of the first and second secured segments while connected to the first and second secured segments; wherein the coupling loop is configured to define a loop region, the movable segment being movable relative to the first and second secured segments to change a size of the loop region and thereby change an amount of inductive coupling between the coupling loop and a magnetic field. 12. The coupling assembly of claim 11 , wherein the loop region includes a fixed section and an adjustable section, the first secured segment defining a boundary of the fixed section, the movable segment being movable relative to the first and second secured segments to change a size of the adjustable section of the loop region and thereby change the amount of inductive coupling, wherein at least a portion of the fixed section of the loop region exists between the adjustable section of the loop region and the first secured segment, the fixed section of the loop region determining a baseline portion of the amount of inductive coupling, the adjustable section of the loop region increasing the amount of inductive coupling from the baseline portion. 13. The coupling assembly of claim 11 , further comprising a capacitor positioned in series with the movable segment and the first and second secured segments. 14. The coupling assembly of claim 11 , wherein the first secured segment is designed to be positioned in a region with a stronger magnetic field than a region where the second secured segment is positioned. 15. The coupling assembly of claim 11 , further comprising a coupling-control instrument that is attached to the coupling loop, the coupling-control instrument indicating how to move the movable segment to increase or decrease the amount of inductive coupling. 16. The coupling assembly of claim 15 , wherein the coupling-control instrument includes non-conductive material and has an indicator and at least one reference marker, wherein a position of the indicator with respect to the at least one reference marker approximates the amount of inductive coupling, wherein the indicator or the at least one reference marker is attached to the movable segment and moves with the movable segment while the other has a stationary position. 17. A method of tuning a radio-frequency (RF) amplification system, the method comprising: providing a resonator that includes an inner conductor and an outer conductor that define a power cavity therebetween, wherein a coupling loop is positioned within the power cavity between the inner conductor and the outer conductor, the coupling loop including a secured segment that is electrically coupled to a grounding deck and a movable segment that is mechanically and electrically coupled to the secured segment, the secured segment extending between the grounding deck and the movable segment; and moving the movable segment of the coupling loop relative to the secured segment while the secured segment is stationary to change a size of a loop region of the coupling loop. 18. The method of claim 17 , wherein the secured segment is a first secured segment and the coupling loop further comprises a second secured segment that is electrically coupled to an output, the movable segment extending between and electrically