Methods for constructing posture calibration matrices

What is claimed is: 1. A medical device deployable by being worn by, or implanted in, a subject, the device comprising: a multi-dimensional posture sensor configured to provide an electrical sensor output representative of alignment of respective first, second, and third axes of the device with the gravitational field of the earth while the device is deployed; and a processor communicatively coupled to the posture sensor and including: a posture calibration circuit configured to: measure a first sensor output for the first device axis and a second sensor output for one of the second or third device axes for a first specified posture of the subject; calculate first transformation components using the first and second sensor outputs; measure additional sensor outputs for the first, second, and third device axes for a second specified posture of the subject; calculate second transformation components using the first transformation components and the additional sensor outputs; and calculate elements of a calibration matrix using the first and second transformation components; and a posture circuit configured to determine a subsequent posture of the subject using outputs of the posture sensor and the calibration matrix. 2. The device of claim 1 wherein the calibration circuit is configured to: calculate, using the first sensor output, a first coordinate transformation associated with a first orientation angle; calculate, using the first sensor output and the second sensor output, a second coordinate transformation associated with a second orientation angle; measure third, fourth, and fifth sensor outputs for respective first, second, and third device axes while the subject is in the second specified posture; and transform the third, fourth, and fifth sensor outputs using the first and second coordinate transformations. 3. The device of claim 2 , wherein the calibration circuit is configured to: calculate elements of a first rotation matrix using the first sensor output; calculate elements of a second rotation matrix using the first sensor output and the second sensor output; and multiply the third, fourth, and fifth sensor outputs by the first and second rotation matrices to transform the sensor outputs. 4. The device of claim 1 , wherein the calibration circuit is configured to calculate a calibration transformation by calculating elements of a calibration matrix. 5. The device of claim 4 , wherein the calibration circuit is configured to: calculate, using the first sensor output, a first set of matrix components related to a first orientation angle; calculate, using the first sensor output and one of the second sensor output or the third sensor output, a second set of matrix components related to a second orientation angle; calculate, using the transformed sensor outputs, a third set of matrix components related to a third orientation angle; and calculate the elements of the calibration matrix using the first, second, and third sets of matrix components. 6. The device of claim 5 , wherein the first orientation angle is associated with a pitch angle, the second orientation angle is associated with a roll angle, and the third orientation angle is associated with a yaw angle. 7. The device of claim 5 , wherein the first orientation angle is associated with a pitch angle, the second orientation angle is associated with a yaw angle, and the third orientation angle is associated with a roll angle. 8. The device of claim 1 , wherein the posture circuit is configured to: receive a sensor output for each of the three non-parallel axes of the posture sensor; transform the sensor outputs using the calibration transformation; and compare the transformed sensor outputs to specified thresholds to determine posture of the subject. 9. The device of claim 1 , wherein the first posture is an upright posture, and the second posture is more supine than the first posture and less than fully supine. 10. The device of claim 1 , wherein the first posture is a supine posture, and the second posture is more upright than the first posture and less than fully upright. 11. A method of controlling operation of a medical device deployable by being worn by, or implanted in, a subject, the method comprising: determining a calibration transformation for a multi-dimensional posture sensor by a two posture process including: measuring a first sensor output for a first device axis and a second sensor output for one of a second device axis or a third device axis for a first specified posture of the subject; calculating first transformation components using the first and second sensor outputs; measuring additional sensor outputs for the first, second and third device axes for a second specified posture; calculating second transformation components using the first transformation components and the additional sensor outputs; and calculating elements of a calibration matrix using the first transformation components and the second transformation components; and determining subsequent subject posture using subsequent calibrated posture sensor output and the calibration matrix. 12. The method of claim 11 , wherein calculating the coordinate transformations includes: calculating, using the first sensor output, a first coordinate transformation associated with a first orientation angle; calculating, using the first sensor output and the second sensor output, a second coordinate transformation associated with a second orientation angle; and wherein measuring sensor outputs for the first, second and third device axes includes measuring third, fourth, and fifth sensor outputs for respective first, second and third device axes while the subject is in the second specified posture; and wherein transforming outputs includes transforming the third, fourth, and fifth sensor outputs using the first and second coordinate transformations. 13. The method of claim 12 , wherein calculating the first coordinate transformation includes calculating elements of a first rotation matrix using the first sensor output, wherein calculating the second coordinate transformation includes calculating elements of a second rotation matrix using the first sensor output and the second sensor output; and wherein transforming the third, fourth, and fifth sensor outputs includes multiplying the third, fourth, and fifth sensor outputs by the first and second rotation matrices to transform the sensor outputs. 14. The method of claim 11 , wherein calculating a calibration transformation includes calculating elements of a calibration matrix, and wherein using the calibration to determine subsequent subject posture includes using the calibration matrix to determine subsequent subject posture from subsequent sensor output. 15. The method of claim 14 , wherein calculating elements of a matrix to calibrate the posture sensor using the sensor outputs includes: calculating a first set of matrix components related to a first orientation angle using the first sensor output; calculating a second set of matrix components related to a second orientation angle using the first sensor output and the second sensor output; calculating a third set of matrix components related to a third orientation angle using the transformed sensor outputs; and calculating the elements of the calibration matrix using the first, second, and third sets of matrix components. 16. The method of claim 15 , wherein calculating a first set of matrix components related to a first orientation angle includes calculating a first set of matrix components associated with a