초록 ▼

A self-contained, integrated micro-cube-sized inertial measurement unit is provided wherein accuracy is achieved through the use of specifically oriented sensors, the orientation serving to substantially cancel noise and other first-order effects, and the use of a noise-reducing algorithm such as wa

A self-contained, integrated micro-cube-sized inertial measurement unit is provided wherein accuracy is achieved through the use of specifically oriented sensors, the orientation serving to substantially cancel noise and other first-order effects, and the use of a noise-reducing algorithm such as wavelet cascade denoising and an error correcting algorithm such as a Kalman filter embedded in a digital signal processor device. In a particular embodiment, a pair of three sets of angle rate sensors are orientable triaxially in opposite directions, wherein each set is mounted on a different sector of a base orientable normal to the other two and comprising N gyroscopes oriented at 360/N-degree increments, where N≧2. At least one accelerometer is included to provide triaxial data. Signals are output from the angle rate sensors and accelerometer for calculating a change in attitude, position, angular rate, acceleration, and/or velocity of the unit.

대표청구항 ▼

What is claimed is: 1. An inertial measurement unit comprising: a base comprising a plurality of physically distinct sectors; three sets of angle rate sensors orientable triaxially in a first direction, each set mounted on a different sector of the base orientable normal to the other two and compri

What is claimed is: 1. An inertial measurement unit comprising: a base comprising a plurality of physically distinct sectors; three sets of angle rate sensors orientable triaxially in a first direction, each set mounted on a different sector of the base orientable normal to the other two and comprising N gyroscopes oriented at 360/N-degree increments, where N≧2; three sets of angle rate sensors orientable triaxially in a second direction opposite the first direction, each set mounted on a different sector of the base orientable normal to the other two and comprising N gyroscopes oriented at 360/N-degree increments, where N≧2; at least one accelerometer positioned on the base adapted to provide six signals, three of the signals containing triaxial accelerometer data and three of the signals containing data for determining inclination; and means for outputting signals from the six sets of angle rate sensors and the accelerometer to a processor for calculating at least one of a change in attitude, a change in position, a change in angular rate, a change in velocity, and a change in acceleration of the unit over a plurality of finite time increments. 2. The unit recited in claim 1, further comprising a processor positioned on the base, the processor in signal communication with the outputting means and having resident thereon means for combining output from each set of angle rate sensors to form a composite angle rate signal for each set of angle rate sensors, for denoising the composite angle rate signals and signals from the accelerometer, and for calculating from the denoised composite angle rate signals and the three accelerometer signals the at least one of a change in attitude, a change in position, a change in angular rate, a change in velocity, and a change in acceleration of the unit. 3. The unit recited in claim 2, wherein the denoising means comprises a wavelet denoising algorithm adapted to produce a denoised signal. 4. The unit recited in claim 3, wherein the processor further has resident thereon a Kalman filter adapted to receive the denoised signal from the wavelet denoising algorithm, the Kalman filter for reducing sensor errors. 5. The unit recited in claim 1, wherein the processor further has resident thereon a Kalman filter adapted to receive input from the signals outputting means, the Kalman filter for reducing sensor errors. 6. The unit recited in claim 5, wherein the Kalman filter is selected from a group consisting of a simple, an unscented, an extended, and a sigma-point Kalman filter. 7. The unit recited in claim 1, wherein N=4. 8. The unit recited in claim 1, wherein the angle rate sensors comprise micro-electro-mechanical system (MEMS) gyros and the accelerometer comprises a MEMS accelerometer. 9. The unit recited in claim 1, wherein the angle rate sensors each further comprise a temperature sensor adapted to output a temperature signal to the processor via the outputting means, the temperature signal for use in correcting a calculation of the at least one of the change in attitude and the change in position of the unit. 10. The unit recited in claim 1, further comprising a magnetometer positioned on the base adapted to output a compass signal to the processor via the outputting means for use in calculating the at least one of a change in attitude, a change in position, a change in angular rate, a change in velocity, and a change in acceleration of the unit. 11. The unit recited in claim 1, further comprising a global positioning system (GPS) receiver positioned on the base adapted to output a GPS signal to the processor via the outputting means for use in calculating a position of the unit. 12. The unit recited in claim 1, further comprising means for performing a self-test on the angle rate sensors for performing a calibration in real time during unit operation. 13. The unit recited in claim 12, wherein the self-test performing means comprises means for determining a malfunctioning of an angle rate sensor and for preventing a signal from the malfunctioning angle rate sensor from being employed in the calculating of the at least one of a change in attitude, a change in position, a change in angular rate, a change in velocity, and a change in acceleration of the unit. 14. The unit recited in claim 1, wherein the base comprises a unitary, substantially planar base having a plurality of sectors foldable relative to each other to form a three-dimensional structure having at least three faces, each face comprising at least one sector. 15. The unit recited in claim 14, wherein the base comprises a semirigid flex board comprising a plurality of PCB panels linked together with flexible connectors, the panels foldable relative to each other. 16. The unit recited in claim 15, wherein each set of angle rate sensors orientable in the first and the second direction is positioned on a unitary panel, each set of angle rate sensors orientable in the first direction having a respective set of angle rate sensors orientable in the second direction, the respective sets of angle rate sensors positioned on panels positionable in opposed relation to each other. 17. A method of making an inertial measurement unit comprising the steps of: providing a base comprising a plurality of physically distinct sectors, the sectors foldable relative to each other; orienting a first angle rate sensor in a first direction on a first sector of the base and a second angle rate sensor in a second direction opposite the first direction on the first base sector; orienting a third angle rate sensor in the first direction on a second sector of the base and a fourth angle rate sensor in the second direction on the second base sector; orienting a fifth angle rate sensor in the first direction on a third sector of the base and a sixth angle rate sensor in the second direction on the third base sector; wherein each angle rate sensor comprises N gyroscopes oriented at 360/N-degree increments, where N≧2; folding the first, the second, and the third base sectors relative to each other so as to be relatively normal to each other; positioning at least one accelerometer on the base, the accelerometer adapted to provide six signals, three of the signals containing triaxial accelerometer data and three of the signals containing data for determining inclination; and outputting signals from the angle rate sensors and the accelerometer; and calculating from the output signals at least one of a change in attitude, a change in position, a change in angular rate, a change in velocity, and a change in acceleration of the unit over a plurality of finite time increments. 18. The method recited in claim 17, further comprising the steps of combining output from each set of angle rate sensors to form a composite angle rate signal for each set of angle rate sensors, denoising the composite angle rate signals and signals from the accelerometer, and calculating from the denoised composite angle rate signals and the three accelerometer signals the at least one of a change in attitude, a change in position, a change in angular rate, a change in velocity, and a change in acceleration of the unit. 19. The method recited in claim 18, wherein the denoising step comprises applying a wavelet denoising algorithm to produce a denoised signal. 20. The method recited in claim 19, further comprising the step of applying a Kalman filter to the denoised signal for reducing sensor errors. 21. The method recited in claim 17, wherein the angle rate sensors each further comprise a temperature sensor, and the outputting step further comprises outputting a temperature signal for use in correcting a calculation of the at least one of a change in attitude, a change in position, a change in angular rate, a change in velocity, and a change in acceleration of the unit. 22. The method recited in claim 17, further comprising the steps of positioning a magnetometer on the base, outputting a compass signal from the magnetometer, and using the compass signal in calculating the at least one of a change in attitude, a change in position, a change in angular rate, a change in velocity, and a change in acceleration of the unit. 23. The method recited in claim 17, further comprising the steps of positioning a global positioning system (GPS) receiver on the base, outputting a GPS signal from the GPS receiver, and using the GPS signal in calculating a position of the unit. 24. The method recited in claim 17, further comprising the step of performing a self-test on the angle rate sensors for calibrating the angle rate sensors in real time.