초록 ▼

A highly miniaturized electronic data acquisition system includes MEMS sensors that can be embedded onto moving device without affecting the static/dynamic motion characteristics of the device. The basic inertial magnetic motion capture (IMMCAP) module consists of a 3D printed circuit board having M

A highly miniaturized electronic data acquisition system includes MEMS sensors that can be embedded onto moving device without affecting the static/dynamic motion characteristics of the device. The basic inertial magnetic motion capture (IMMCAP) module consists of a 3D printed circuit board having MEMS sensors configured to provide a tri-axial accelerometer; a tri-axial gyroscope, and a tri-axial magnetometer all in communication with analog to digital converters to convert the analog motion data to digital data for determining classic inertial measurement and change in spatial orientation (rho, theta, phi) and linear translation (x, y, z) relative to a fixed external coordinate system as well as the initial spatial orientation relative to the know relationship of the earth magnetic and gravitational fields. The data stream from the IMMCAP modules will allow the reconstruction of the time series of the 6 degrees of freedom for each rigid axis associated with each independent IMMCAP module.

대표청구항 ▼

What is claimed is: 1. A motion sensing system, comprising: one or more motion sensors, each motion sensor operable to measure data on motion and orientation of the motion sensor and comprising (1) a microprocessor to process and transform measured data into digital sensor data and (2) a sensor com

What is claimed is: 1. A motion sensing system, comprising: one or more motion sensors, each motion sensor operable to measure data on motion and orientation of the motion sensor and comprising (1) a microprocessor to process and transform measured data into digital sensor data and (2) a sensor communication interface to output the digital sensor data; and a controller, separate from and external to the one or more motion sensors and the microprocessor in each of the one or more motion sensors, comprising (1) a controller communication interface in communication with the one or more motion sensors via the sensor communication interface and (2) a controller memory to receive the digital sensor data from the one or more motion sensors, wherein the controller processes, in real time as the digital sensor data is being received, the received digital sensor data to produce a measured motion profile of the one or more motion sensors and to compare the measured motion profile to a reference motion profile for the one or more motion sensors that is stored in the controller microprocessor, and wherein the controller produces an indicator signal to indicate a deviation of the measured motion profile from the reference motion profile. 2. The system as in claim 1, wherein: the sensor communication interface in each motion sensor is an RF interface that transmits a wireless RF signal carrying the digital sensor data, and the controller communication interface is an RF interface that wirelessly transmits and receives data. 3. The system as in claim 1, wherein: each motion sensor comprises a tri-axial magnetometer to measure a local magnetic field vector at each motion sensor, and wherein the system comprises a mechanism to process measured data on the local magnetic field to measure a differential rate of rotation of each motion sensor relative to a local earth magnetic field vector. 4. The system as in claim 1, comprises: an alert mechanism that responds to the indicator signal to produce an alert signal to alert a person of the deviation of the measured motion profile from the reference motion profile when the deviation exceeds a tolerance range. 5. The system as in claim 1, wherein the controller comprises a communication link to send out the digital sensor data for further analysis and processing. 6. The system as in claim 1, comprising: a body suit structured to be complaint and to hold a plurality of groups of the motion sensors and the controller, wherein the groups of the motion sensors are located on selected portions of the body suit corresponding to selected rigid body segments, respectively, and each group of the motion sensors acquires motion data of a respective selected rigid body segment and communicates the acquired motion data to the controller which assemblies the acquired motion data from the groups of the motion sensors to provide motion data for analysis of body motion. 7. The system as in claim 1, comprising: a shaft mounted appliance module structured to engage to a golf club and to hold a motion sensor which measures the motion of the golf club caused by a person to produce the measured motion profile of the golf club, wherein the reference motion profile includes one or more reference golf club swings for golf training, wherein the sensor communication interface in each motion sensor is an RF interface that transmits a wireless RF signal carrying the digital sensor data, and the controller communication interface is an RF interface that wirelessly transmits and receives data. 8. The system as in claim 3, wherein: each motion sensor comprises a tri-axial gyroscope to measure a rate of rotation of each motion sensor in addition to the measured differential rate of rotation from the tri-axial magnetometer, and wherein the system comprises a mechanism to use the measured differential rate of rotation from the tri-axial magnetometer to indicate a rotation rate of the motion sensor when the external earth magnetic field is not aligned with any one of three orthogonal axes of the tri-axial magnetometer and to select the measured rate of rotation from the tri-axial gyroscope when data when the external earth magnetic field is aligned with one of three orthogonal axes of the tri-axial magnetometer. 9. The system as in claim 3, wherein: each motion sensor does not include a tri-axial gyroscope to measure a rate of rotation of each motion sensor, and wherein the system comprises a mechanism to: use data samples of the measured differential rate of rotation from the tri-axial magnetometer to estimate a rate of rotation of the motion sensor during a period when the external earth magnetic field is not aligned with any one of three orthogonal axes of the tri-axial magnetometer. 10. The system as in claim 4, wherein the alert signal is an acoustic, optical or tactical feedback signal. 11. The system as in claim 6, wherein: each motion sensor comprises a tri-axial magnetometer to measure a local magnetic field vector at each motion sensor, and wherein the system comprises a mechanism to process measured data on the local magnetic field to measure a differential rate of rotation of each motion sensor relative to a local earth magnetic field vector. 12. The system as in claim 7, wherein the motion sensor is an integrated sensor module that comprises a battery power supply to supply power for operating the motion sensor. 13. The system as in claim 7, wherein the motion sensor is a microelectromechanical system (MEMS) motion sensor. 14. The system as in claim 7, comprising: an alert mechanism that responds to the indicator signal to produce an alert signal to alert a person of the deviation of the measured motion profile from the reference motion profile when the deviation exceeds a tolerance range. 15. The system as in claim 9, comprising: a shaft mounted appliance module structured to engage to a golf club and to hold a motion sensor which measures the motion of the golf club caused by a person to produce the measured motion profile of the golf club, wherein the sensor communication interface in each motion sensor is an RF interface that transmits a wireless RF signal carrying the digital sensor data, and the controller communication interface is an RF interface that wirelessly transmits and receives data. 16. The system as in claim 11, comprising: a mechanism that uses data samples of the measured differential rate of rotation from the tri-axial magnetometer to estimate a rate of rotation of the motion sensor during a period when the external earth magnetic field is not aligned with any one of three orthogonal axes of the tri-axial magnetometer. 17. The system as in claim 11, wherein: each motion sensor comprises a tri-axial gyroscope to measure a rate of rotation of each motion sensor in addition to the measured differential rate of rotation from the tri-axial magnetometer, and wherein the system comprises a mechanism that uses the measured differential rate of rotation from the tri-axial magnetometer to indicate a rotation rate of the motion sensor when the external earth magnetic field is not aligned with any one of three orthogonal axes of the tri-axial magnetometer and to select the measured rate of rotation from the tri-axial gyroscope when data when the external earth magnetic field is aligned with one of three orthogonal axes of the tri-axial magnetometer. 18. The system as in claim 15, wherein the motion sensor is a microelectromechanical system (MEMS) motion sensor. 19. A motion sensing system, comprising: one or more motion sensors, each motion sensor operable to measure data on motion and orientation of the motion sensor and comprising (1) a microprocessor to process and transform measured data into digital sensor data and (2) a sensor communication interface to output the digital sensor data; and a controller comprising (1) a controller communication interface in communication with each of the one or more motion sensors via the sensor communication interface and (2) a controller memory to receive the digital sensor data from the one or more motion sensors, wherein the controller processes, in real time as the digital sensor data is being received, the received digital sensor data to produce a measured motion profile of the one or more motion sensors and to compare the measured motion profile to a reference motion profile for the one or more motion sensors that is stored in the controller microprocessor, and wherein the controller produces an indicator signal to indicate a deviation of the measured motion profile from the reference motion profile; and a body suit structured to be complaint and to hold a plurality of groups of the motion sensors and the controller, wherein the groups of the motion sensors are located on selected portions of the body suit corresponding to selected rigid body segments, respectively, and each group of the motion sensors acquires motion data of a respective selected rigid body segment and communicates the acquired motion data to the controller which assemblies the acquired motion data from the groups of the motion sensors to provide motion data for analysis of body motion, and wherein: each motion sensor is a microelectromechanical system (MEMS) motion sensor. 20. The system as in claim 19, wherein: each MEMS motion sensor includes a tri-axial MEMS accelerometer; a tri-axial MEMS gyroscope and a tri-axial MEMS magnetometer. 21. The system as in claim 19, wherein: the sensor communication interface in each motion sensor is an RF interface that transmits a wireless RF signal carrying the digital sensor data, and the controller communication interface is an RF interface that wirelessly transmits and receives data. 22. The system as in claim 19, wherein the controller communication interface is connected to each of the motion sensors to communicate with each motion sensor via the sensor communication interface.