Extremity imaging apparatus for cone beam computed tomography

The invention claimed is: 1. A method for cone beam computed tomography, the method comprising the steps of: moving a detector about an imaging axis along at least a portion of a circular detector path using a C-shaped gantry to support the detector; moving a source about the imaging axis along at least a portion of a circular source path, using the C-shaped gantry, simultaneously with the step of moving the detector, the source disposed to face the detector directly across the imaging axis during the movement of the source and the detector about the imaging axis; attaching a counterweight to the C-shaped gantry adjacent the detector so that the counterweight moves simultaneously with the movement of the source and the detector about the imaging axis attaching a C-shaped detector weight support arm to the detector and to the C-shaped gantry, the C-shaped detector weight support arm configured to support and to move the detector, and attaching a C-shaped counterweight support arm to the gantry and to the counterweight, the C-shaped counterweight support arm configured to support and to move the counterweight. 2. An imaging apparatus for cone beam computed tomography imaging, the apparatus comprising: at least one support column; and a scanner coupled to the at least one support column, the scanner comprising: a C-shaped gantry; a radiation source coupled to a proximal end of the C-shaped gantry; a radiation detector coupled to a distal end of the C-shaped gantry; a counterweight attached to the distal end of the C-shaped gantry adjacent to the radiation detector; and a C-shaped housing enclosing the C-shaped gantry, the radiation source, the radiation detector and the counterweight, wherein the C-shaped gantry is configured to revolve both the radiation detector and the radiation source simultaneously about an imaging axis during a scanning procedure to acquire radiographic image data in the radiation detector according to radiation received from the radiation source, an imaging surface of the radiation detector faces the radiation source along a line that intersects the imaging axis, and wherein the scanner is configured to move in at least three dimensions including a vertical movement along a track in the at least one support column, a rotational movement about a first axis perpendicular to the imaging axis, and a rotational movement about a second axis perpendicular to the imaging axis and the first axis, and wherein the scanner further comprises: a C-shaped detector weight support arm, a proximal end of the C-shaped detector weight support arm coupled to the proximal end of the C-shaped gantry, and a distal end of the C-shaped detector weight support arm coupled to the radiation detector; and a C-shaped counterweight support arm, a proximal end of the C-shaped counterweight support arm coupled to the proximal end of the C-shaped gantry, and a distal end of the C-shaped counterweight support arm coupled to the counterweight in a position adjacent to the radiation detector. 3. The imaging apparatus of claim 2 , wherein the C-shaped counterweight support arm is configured to provide independent movement of the counterweight relative to the detector. 4. The imaging apparatus of claim 2 , wherein the C-shaped counterweight support arm is configured to provide a prescribed size clearance gap between the detector and the counterweight. 5. The imaging apparatus of claim 2 , wherein relative motion of the counterweight during the scanning procedure is at least 5× greater than the motion of the detector during the scanning procedure. 6. The imaging apparatus of claim 2 , wherein the C-shaped detector weight support arm and the C-shaped counterweight support arm are parallel to one another, and wherein one of the C-shaped detector weight support arm and the C-shaped counterweight support arm is closer to the imaging axis. 7. The imaging apparatus of claim 2 , wherein the C-shaped detector weight support arm and the C-shaped counterweight support arm are made from different materials. 8. The imaging apparatus of claim 2 , wherein the counterweight is configured to reduce vibration of the imaging apparatus during the scanning procedure. 9. The imaging apparatus of claim 2 , wherein the C-shaped detector weight support arm is configured such that less than 10 mm of motion is created at the detector relative to the source during the scanning procedure. 10. The imaging apparatus of claim 2 , wherein the C-shaped detector weight support arm is configured to limit detector motion during the scanning procedure to less than 1/10 of the motion of the counterweight during the scanning procedure. 11. The imaging apparatus of claim 2 , wherein the C-shaped housing is configured to provide a gap in the detector path and the source path for radial access to the imaging axis, and wherein the scanner further comprises a door that moves into the gap from a first position that does not obstruct the gap to a second position that extends into the gap. 12. The imaging apparatus of claim 4 , wherein the detector on the C-shaped detector weight support arm and the counterweight on the C-shaped counterweight support arm are separately provided with a gap therebetween, and wherein the prescribed size clearance gap is responsive to a movement amount of the counterweight.