System and method for measuring body joint range of motion

I claim: 1. A method for measuring body joint range of motion by a joint rotation measurement device that communicates with inertial measurement unit (IMU) sensors capable of measuring the IMUs' orientations relative to Earth, the method comprising: receiving, at the joint rotation measurement device, orientation data from a primary IMU sensor mounted on a proximal body segment and a secondary IMU sensor mounted on a distal body segment connected to the proximal body segment via a joint; measuring, at the joint rotation measurement device, a sensor orientation relationship between the primary IMU sensor and the secondary IMU sensor using the orientation data received from the primary and secondary IMU sensors; and converting, by a conversion application stored at a memory of the joint rotation measurement device, the sensor orientation relationship into at least one physiologically modeled constituent joint rotation relationship between the proximal body segment and the distal body segment, where a constituent joint rotation relationship is defined in no more than two dimensions of three-dimensional space, wherein converting the sensor orientation relationship into the physiologically modeled constituent joint rotation relationship includes defining a constituent axial axis rotation of the distal body segment measured with respect to the proximal body segment, where an axial intersects the joint connecting the distal body segment to the proximal body segment and is parallel to a major axis of a smallest rectangular cuboid enclosing a body segment, and where a major axis is a line passing through the center of two opposing sides of the cuboid that are farthest apart from each other. 2. The method of claim 1 , wherein measuring the sensor orientation relationship includes expressing the sensor orientation relationship as a quaternion. 3. A method for measuring body joint range of motion using by a joint rotation measurement device that communicates with inertial measurement unit (IMU) sensors capable of measuring the IMUs' orientations relative to Earth, the method comprising: receiving, at the joint rotation measurement device, orientation data from a primary IMU sensor mounted on a proximal body segment and a secondary IMU sensor mounted on a distal body segment connected to the proximal body segment via a joint; measuring, at the joint rotation measurement device, a sensor orientation relationship between the primary IMU sensor and the secondary IMU sensor using the orientation data received from the primary and secondary IMU sensors; and converting, by a conversion application stored at a memory of the joint rotation measurement device, the sensor orientation relationship into at least one physiologically modeled constituent joint rotation relationship between the proximal body segment and the distal body segment, where a constituent joint rotation relationship is defined in no more than two dimensions of three-dimensional space, wherein converting the sensor orientation relationship into the physiologically modeled constituent joint rotation relationship includes defining a constituent radial axis composite rotation of the distal body segment measured with respect to the proximal body segment, where the radial axis intersects the joint connecting the distal body segment to the proximal body segment, is orthogonal to an axial axis of the distal body segment, is orthogonal to an axial axis of the proximal body segment, where an axial axis intersects the joint connecting the distal body segment to the proximal body segment and is parallel to a major axis of a smallest rectangular cuboid enclosing a body segment, and where a major axis is a line passing through the center of two opposing sides of the cuboid that are farthest apart from each other. 4. The method of claim 3 , wherein defining the radial axis composite rotation comprises defining a constituent primary radial rotation and a constituent secondary radial rotation, where the primary radial rotation represents a first angle measured with respect to a first axis aligned with the radial axis of maximum possibly physiologically possible radial rotation, and the secondary rotation represents a second angle measured with respect to a second axis orthogonal to the first axis and the axial axis. 5. The method of claim 1 further comprising: displaying, on a user interface (UI) displayed on a display of the joint rotation measurement device, the physiologically modeled constituent joint rotation relationship between the proximal body segment and the distal body segment. 6. The method of claim 5 , wherein the displaying the physiologically modeled constituent joint rotation relationship includes displaying the constituent joint rotation relationship as a numerical value representing an extent of rotation. 7. The method of claim 5 , wherein displaying the physiologically modeled constituent joint rotation relationship includes mapping at least one constituent rotation relationship to a physiologically defined joint rotation. 8. The method of claim 1 further comprising: programmatically selecting a sensor alignment methodology for the primary and secondary orientation sensors based upon the body joint being measured.