Controller module for strut adjustment

The invention claimed is: 1. An external fixation system comprising: a first fixation ring configured to couple to a first bone portion of a patient; a second fixation ring configured to couple to a second bone portion of the patient; a plurality of adjustable length struts, each adjustable length strut having a first joint proximate a first end of the strut, a second joint proximate a second end of the strut opposite the first end, a rod, a tube that receives the rod, and an actuator configured to drive the rod axially relative to the tube to change an effective length of the strut; and a plurality of controller modules, each controller module configured to couple to a corresponding strut; wherein in an assembled condition of the external fixation system, the plurality of struts couple the first fixation ring to the second fixation ring; the external fixation system has a manual mode of operation in which there is no coupling between any of the plurality of controller modules and any of the plurality of struts, and manual actuation of one of the actuators is configured to change the effective length of the corresponding strut in discrete length increments; and the external fixation system has an automated mode of operation in which each of the controller modules is coupled to the corresponding strut, and automated actuation of one of the actuators is configured to change the effective length of the corresponding strut in infinitesimally small length increments, wherein the actuator of each strut includes a strut knob and a strut gear, the strut knob being translatable relative to the strut gear between a first axial position relative to the strut gear and a second axial position relative to the strut gear, wherein when the strut knob is in the first axial position relative to the strut gear, the strut knob is constrained from rotation relative to the strut, and when the strut knob is in the second axial position relative to the strut gear, the strut knob is rotatable relative to the strut. 2. The external fixation system of claim 1 , wherein in the manual mode of operation, a biasing member biases the strut knob to the first axial position. 3. The external fixation system of claim 2 , wherein in the manual mode of operation, each discrete length increment corresponds to a discrete increment of rotation of the strut knob relative to the strut. 4. The external fixation system of claim 3 , wherein in the manual mode of operation, when the strut knob is in the second axial position relative to the strut gear, the biasing member is prevented from transitioning the strut knob to the first axial position between each discrete increment of rotation. 5. The external fixation system of claim 1 , wherein in the automated mode of operation, the controller module maintains the strut knob in the second axial position relative to the strut gear. 6. The external fixation system of claim 5 , wherein in the automated mode of operation, a controller gear of the controller module interfaces with the strut gear. 7. The external fixation system of claim 6 , wherein each controller module includes a motor configured to rotate the controller gear. 8. The external fixation system of claim 7 , wherein each controller module includes a collar with at least one prong, and when the controller module is coupled to the corresponding strut, the at least one prong is positioned between the strut gear and the strut knob. 9. The external fixation system of claim 8 , wherein the at least one prong includes a tip portion with a ramped surface, the ramped surface configured to drive the strut knob to the second axial position as the controller module is coupled to the corresponding strut. 10. The external fixation system of claim 8 , wherein the collar includes a first extension and a second extension defining a distance therebetween, the distance being about equal to a width of a securement area of the strut, the first and second extensions configured to abut the securement area of the strut when the controller module is coupled to the strut to secure the controller module to the strut. 11. The external fixation system of claim 10 , wherein the first extension is flexible and includes a transverse projection extending toward the second extension, a reduced distance between the transverse projection and the second extension being smaller than the width of the securement area of the strut. 12. The external fixation system of claim 11 , wherein, as the controller module is coupled to the strut, contact between the transverse projection and the securement area of the strut is configured to cause the first extension to flex away from the strut until the transverse projection clears an end of the securement area and the first extension snaps back toward the securement area so that the transverse projection impedes the controller module from uncoupling from the strut. 13. The external fixation system of claim 7 , wherein when the external fixation system is in the automated mode of operation, each controller module has a dynamization mode configured to cycle between increasing and decreasing the effective length of the strut to axially dynamize the strut with effective length adjustments that are smaller than the discrete length increments in the manual mode of operation. 14. The external fixation system of claim 13 , wherein in the assembled condition of the external fixation system, the external fixation system has a stable construction, and while each controller module is operating in the dynamization mode cycling between increasing and decreasing the effective length of the corresponding strut, the external fixation system remains in the stable construction. 15. A method of implementing a correction plan to correct a deformity in a bone of a patient, the method comprising: coupling a first fixation ring to a first portion of the bone of the patient; coupling a second fixation ring to a second bone portion of the bone of the patient; coupling the first fixation ring to the second fixation ring with a plurality of adjustable length struts, each strut having a first joint proximate a first end of the strut, a second joint proximate a second end of the strut opposite the first end, a rod, a tube that receives the rod, and an actuator configured to drive the rod axially relative to the tube to change an effective length of the strut; and providing a plurality of controller modules, each controller module configured to couple to a corresponding strut; wherein the correction plan may be implemented using either (i) a manual mode of operation or (ii) an automated mode of operation; wherein in the manual mode of operation, there is no coupling between any of the plurality of controller modules and any of the plurality of struts, and manual actuation of one of the actuators changes the effective length of the corresponding strut in discrete length increments; and wherein in the automated mode of operation, each of the controller modules is coupled to the corresponding strut, and automated actuation of one of the actuators is capable of changing the effective length of the corresponding strut in infinitesimally small length increments, coupling the plurality of controller modules to the corresponding struts, and implementing the correction plan using the automated mode of operation, and operating one of the controller modules in a dynamization mode to cycle between increasing and decreasing the effective length of the corresponding strut to axially dynamize the strut with effective length adjustments that are smaller than the discrete length increments availabl