Methods of attitude and misalignment estimation for constraint free portable navigation

The embodiments of the invention in which an exclusive property or privilege is claimed are defined as follows: 1. A method for enhancing a navigation solution of a device and a platform, wherein the method is operable when the mobility of the device is constrained within the platform and when mobility of the device is unconstrained within the platform, wherein the device is configured to receive readings related to navigational information from the platform via a wired or wireless connection, wherein the platform comprises at least one sensor and the readings related to navigational information comprise information from the at least one sensor, and wherein the sensor information is used to resolve at least one of attitude of the device and misalignment between the device and the platform, by: a) obtaining the information from the at least one sensor; b) choosing multiple possible candidates of the at least one of attitude and misalignment, c) determining candidate specific forces at the device for each of the chosen candidates of the at least one of attitude and misalignment, using the sensor information and the chosen candidates; d) comparing the determined candidate specific forces to specific forces measured by the device; e) estimating the at least one of attitude and misalignment value by assessing each chosen candidate of the at least one of attitude and misalignment based on the comparison of step d) of this claim; and f) providing the at least one of attitude and misalignment. 2. The method of claim 1 , wherein the platform is a vehicle, a vessel or a person. 3. The method of claim 1 , wherein the device comprises at least three accelerometers and wherein said accelerometers have quality specifications, further comprising: calculating roll and pitch of the device using specific forces measured at the device, and calculating a standard deviation of the roll and pitch of the device using the specific forces measured at the device and the quality specifications of the at least three accelerometers. 4. The method of claim 1 , further comprising: estimating an absolute heading of the platform and a standard deviation thereof by using a time rate of change of received signal strength (RSS) of wireless signals received by a wireless receiver of the device from a wireless communication system having at least one access point. 5. The method of claim 1 , wherein the device has motion sensors and wherein a source of absolute velocity is available, the method further comprising estimating heading misalignment between the device and the platform by: a) obtaining motion sensors readings; b) obtaining absolute velocity; c) choosing multiple possible candidates of heading misalignment to cover a range of angular value ambiguity for the heading misalignment between the device and the platform, wherein the heading misalignment between the device and the platform is a difference between a heading of the device and a heading of the platform and wherein the heading of the device is a heading of a frame of the motion sensors within the device; d) estimating motion sensor readings for each chosen candidate of heading misalignment based at least in part on the obtained absolute velocity; e) performing at least one of: i) transforming the estimated motion sensor readings from a frame of the absolute velocity to the motion sensor frame and comparing the transformed estimated motion sensor readings for each chosen candidate of heading misalignment to the obtained motion sensor readings in the motion sensor frame; and ii) transforming the obtained motion sensor readings from the motion sensor frame to a frame of the absolute velocity and comparing the estimated motion sensor readings for each chosen candidate of heading misalignment to the transformed obtained motion sensor readings in the frame of the absolute velocity; and f) assessing each chosen candidate of heading misalignment based on the comparison of step e) of this claim. 6. The method of claim 1 , wherein the device comprises at least three accelerometers, further comprising: estimating misalignment of heading between the device and the platform independent of the availability of absolute source of velocity or heading information. 7. The method of claim 1 , further comprising: calculating continued misalignment of heading between the device and the platform when a source of absolute velocity or heading information is available or interrupted. 8. The method of claim 1 , wherein the device further comprises a source of absolute position, which may be degraded or denied, and wherein the readings related to navigational information comprise a speed of the platform and one or both of the heading or turning rate of the platform, the method further comprising: (a) calculating the navigation solution of the platform, the navigation solution including heading of the platform; (b) calculating the heading of the device from the navigation solution of the device; and (c) Using the heading of the platform and the heading of the device to calculate the misalignment between the device and the platform. 9. The method of claim 8 , wherein the speed of the platform is obtained from an odometer or wheel speed sensors. 10. The method of claim 8 , wherein the turning rate of the platform is obtained from a gyroscope on the platform, individual wheel speeds of the platform, or a combination thereof. 11. The method of claim 8 , wherein the platform heading is obtained from a magnetometer on the platform, a steering rate sensor on the platform and the speed of the platform, or a combination thereof. 12. The method of claim 1 , wherein the platform comprises a positioning system capable of calculating position, velocity and orientation, or a subset thereof, of the platform, wherein the readings related to navigational information comprise the position, velocity and orientation, or a subset thereof, of the platform, wherein the navigation solution of the device is used to determine heading of the device, and wherein the method further comprises utilizing one of: (a) the platform heading provided from the received orientation of the platform, or (b) the platform heading derived from the received velocity of the platform, together with the heading of the device to calculate misalignment between the device and the platform. 13. The method of claim 1 , wherein the readings related to navigational information comprises a speed of the platform, wherein the misalignment between the device and the platform is not resolved, and wherein the speed information is used to resolve the misalignment, by using the speed information and assuming candidates of heading misalignment to determine candidate specific forces about the device and comparing the candidate specific forces to specific forces measured by the device. 14. The method of claim 1 , wherein the readings related to navigational information comprises a speed of the platform, wherein the misalignment between the device and the platform is resolved, and wherein the speed information is used to resolve pitch and roll of the device, by using the speed information and assuming candidates of pitch and roll to determine candidate specific forces at the device and comparing the candidate specific forces to specific forces measured by the device. 15. The method of claim 1 , wherein the readings related to navigational information comprises a speed of the platform, wherein the misalignment of the device and the platform is resolved, and wherein the speed of the platform and the misalignment are utilized to calculate and apply velocity up