An acceleration-based mobile asset data recorder and transmitter equipped with a wireless processing unit, an event recorder, a digital video recorder, a fuel level sensor, and an inertial navigation sensor board. The inertial navigation sensor board includes a 3-axis gyroscope, a 3-axis acceleromet
An acceleration-based mobile asset data recorder and transmitter equipped with a wireless processing unit, an event recorder, a digital video recorder, a fuel level sensor, and an inertial navigation sensor board. The inertial navigation sensor board includes a 3-axis gyroscope, a 3-axis accelerometer, a 3-axis magnetometer, and a microcontroller. The data recorder and transmitter allows for automatic orientation, automatic compass calibration, fuel compensation with pitch and roll, emergency brake application with impact detection, rough operating condition detection, engine running detection, and inertial navigation of a mobile asset. Users can use the normal operation of their mobile assets to locate and alert, in real-time, areas where their assets are encountering rough operating environments, to provide for quicker emergency response, and to validate the effectiveness of repairs and rerouting.
대표청구항▼
1. A system for recording, processing, and transmitting data from a mobile asset, comprising: a wireless processing unit having at least one axis;at least one digital video recorder onboard the mobile asset, the at least one digital video recorder adapted to perform recording or transmitting a still
1. A system for recording, processing, and transmitting data from a mobile asset, comprising: a wireless processing unit having at least one axis;at least one digital video recorder onboard the mobile asset, the at least one digital video recorder adapted to perform recording or transmitting a still image file, a video file or an acoustic file in real-time;at least one inertial navigation sensor board onboard the mobile asset, the board comprising a microcontroller communicating with and processing data from a 3-axis accelerometer;at least one event data recorder onboard the mobile asset, the at least one event data recorder adapted to monitor real-time status of at least one input sensor and log event data relating to the mobile asset;firmware, running on the microcontroller, adapted to calculate pitch and roll based on an x-axis raw acceleration value, a y-axis raw acceleration value, or a z-axis raw acceleration value from the 3-axis accelerometer, to determine when at least one trigger event occurs, to send at least one trigger event message to the wireless processing unit when at least one trigger event occurs, or to send at least one periodic data message containing a predefined set of values to the wireless processing unit every second; anda software application running on the wireless processing unit, the software application adapted to: communicate with the inertial navigation sensor board;automatically calibrate a compass on the mobile asset;automatically orient the at least one axis of the wireless processing unit to at least one corresponding axis of the mobile asset;filter the x-axis raw acceleration value, y-axis raw acceleration value, and z-axis raw acceleration value into an x-axis filtered acceleration value, a y-axis filtered acceleration value, and a z-axis filtered acceleration value;translate the axes of the inertial navigation sensor board to the axes of the mobile asset and determine an x-axis translated raw acceleration value by translating the x-axis raw acceleration value to the axes of the mobile asset, determine a y-axis translated raw acceleration value by translating the y-axis raw acceleration value to the axes of the mobile asset, and determine a z-axis translated raw acceleration value by translating the z-axis raw acceleration value to the axes of the mobile asset;translate the axes of the inertial navigation sensor board to the axes of the mobile asset and determine an x-axis translated filtered acceleration value by translating the x-axis filtered acceleration value to the axes of the mobile asset, determine a y-axis translated filtered acceleration value by translating the y-axis filtered acceleration value to the axes of the mobile asset, and determine a z-axis translated filtered acceleration value by translating the z-axis filtered acceleration value to the axes of the mobile asset; andgather data from other software applications running on the wireless processing unit. 2. The system of claim 1, further adapted to: send initialization commands to the firmware to establish an x-axis acceleration duration, a y-axis acceleration duration, and a z-axis acceleration duration in each axis and to establish an x-axis acceleration threshold, a y-axis acceleration threshold, and a z-axis acceleration threshold in each axis;store the x-axis acceleration duration, y-axis acceleration duration, and z-axis acceleration duration;store the x-axis acceleration threshold, y-axis acceleration threshold, and z-axis acceleration threshold;determine an x-axis filtered threshold value by adding the x-axis translated filtered acceleration value to the x-axis acceleration threshold;determine a y-axis filtered threshold value by adding the y-axis translated filtered acceleration value to the y-axis acceleration threshold;determine a z-axis filtered threshold value by adding the z-axis translated filtered acceleration value to the z-axis acceleration threshold; andcontinually compare the x-axis filtered threshold value to the x-axis translated raw acceleration value, the y-axis filtered threshold value to the y-axis translated raw acceleration value, and the z-axis filtered threshold value to the z-axis translated raw acceleration value. 3. The system of claim 2, further adapted to: activate a timer when the x-axis translated raw acceleration value exceeds the x-axis filtered threshold value, the y-axis translated raw acceleration value exceeds the y-axis filtered threshold value, or the z-axis translated raw acceleration value exceeds the z-axis filtered threshold value;determine a timer duration of the timer when the x-axis translated raw acceleration value does not exceed the x-axis filtered threshold value, the y-axis translated raw acceleration value does not exceed the y-axis filtered threshold value, or the z-axis translated raw acceleration value does not exceed the z-axis filtered threshold value, the timer duration comprising the duration that the x-axis translated raw acceleration value exceeded the x-axis filtered threshold value, the y-axis translated raw acceleration value exceeded the y-axis filtered threshold value, or the z-axis translated raw acceleration value exceeded the z-axis filtered threshold value;store a trigger event when the timer duration exceeds the x-axis acceleration duration, the y-axis acceleration duration, or the z-axis acceleration duration;monitor the event data recorder for at least one periodic data message;receive the at least one periodic data message from the event data recorder;detect when the at least one periodic data message indicates an emergency brake application discrete signal occurred; andstore a trigger event time when the trigger event occurred or a brake time and an emergency brake event when the emergency brake application discrete signal occurred. 4. The system of claim 3, further adapted to: trigger an emergency brake application with an impact alert when the trigger event time and the brake time are in close temporal proximity;request a download of the still image file, the acoustic file, or the video file from the onboard digital video recorder, the still image file, the acoustic file, or the video file recorded a predetermined time period prior to, during, and after the trigger event time or the brake time;receive the still image file, the acoustic file, or the video file; andsend the still image file, the acoustic file, or the video file to the back office in real time. 5. The system of claim 4, further adapted to send at least one alert indicating a GPS location, digital video, data from the event data recorder, actual force when a collision occurred, a rollover alert when a rollover occurred as a result of the collision, or a derailment alert when a derailment occurred as a result of the collision. 6. The system of claim 3, wherein the trigger event comprises specifics on the axes, the timer duration, and the trigger event time. 7. The system of claim 3, wherein the at least one periodic data message comprises at least one real-time status of the at least one input sensor. 8. The system of claim 1, further adapted to: measure an amount of fuel inside a fuel tank of the mobile asset upon receiving a signal from at least one fuel level sensor;calculate the mobile asset's pitch, wherein the mobile asset's pitch is determined by applying the equation: arctan(x-axistranslatedfilteredaccelerationvaluez-axistranslatedfilteredaccelerationvalue);calculate the mobile asset's roll, wherein the mobile asset's roll is determined by applying the equation: arctan(y-axistranslatedfilteredaccelerationvaluez-axistranslatedfilteredaccelerationvalue);determine a first distance the fuel sensor is mounted forward of the center of the fuel tank;determine a second distance the fuel sensor is mounted left of the center of the fuel tank;calculate a first fuel distance adjustment by combining the first distance with the tangent of the mobile asset's pitch;calculate a second fuel distance adjustment by combining the second distance with the tangent of the mobile asset's roll;calculate a third fuel distance adjustment by combining the first fuel distance adjustment with the second fuel distance adjustment;determine a raw distance from the top of the tank to the fuel level present in the fuel tank;calculate an adjusted distance by combining the raw distance with the third fuel distance adjustment; andcalculate a fuel volume by combining the adjusted distance with a fuel tank geometric profile. 9. The system of claim 2, further adapted to: receive global positioning system (GPS) signals from at least one GPS sensor onboard the mobile asset;activate a timer at a start time when the x-axis translated raw acceleration value exceeds the x-axis filtered threshold value, the y-axis translated raw acceleration value exceeds the y-axis filtered threshold value, or the z-axis translated raw acceleration value exceeds the z-axis filtered threshold value;determine a timer duration of the timer when the x-axis translated raw acceleration value does not exceed the x-axis filtered threshold value, the y-axis translated raw acceleration value does not exceed the y-axis filtered threshold value, or the z-axis translated raw acceleration value does not exceed the z-axis filtered threshold value, the timer duration comprising a duration that the x-axis translated raw acceleration value exceeded the x-axis filtered threshold value, the y-axis translated raw acceleration value exceeded the y-axis filtered threshold value, or the z-axis translated raw acceleration value exceeded the z-axis filtered threshold value;stores a trigger event at a time when the timer duration exceeds the x-axis acceleration duration, the y-axis acceleration duration, or the z-axis acceleration duration;determine a speed of the mobile asset based on at least one periodic data message from the at least one of the event data recorder or the GPS sensor; andmonitor the speed of the mobile asset, wherein the speed is determined by applying the equation: ∫ asset's accelerationx-axis translated filtered acceleration value. 10. The system of claim 9, further adapted to: determine an axis in which the trigger event was triggered when the asset's speed exceeds a specified value at the time the trigger event was stored;log a potential track issue alert when the axis is the z-axis; andlog an operator mishandling alert when the axis is the x-axis or the y-axis. 11. The system of claim 10, further adapted to: send alerts indicating rough operating environments, bad tracks and switches, rough seas, poor roads, repaired routes, GPS location, video, or access to event data recorder information. 12. The system of claim 9, wherein the trigger event comprises specifics on the data from the axes, duration of the event, and the time when the trigger event occurred. 13. The system of claim 9, wherein the at least one periodic data message comprises the real-time status of the at least one input sensor on the mobile asset. 14. The system of claim 1, further adapted to: establish an x-axis activity duration, a y-axis activity duration, and a z-axis activity duration;store the x-axis activity duration, the y-axis activity duration, and the z-axis activity duration;establish an x-axis activity threshold, a y-axis activity threshold, and a z-axis activity threshold;store the x-axis activity threshold, y-axis activity threshold, and z-axis activity threshold;determine an x-axis filtered threshold value by adding the x-axis translated filtered acceleration value to the x-axis activity threshold;determine a y-axis filtered threshold value by adding the y-axis translated filtered acceleration value to the y-axis activity threshold;determine a z-axis filtered threshold value by adding the z-axis translated filtered acceleration value to the z-axis activity threshold; andcontinually compare the x-axis filtered threshold value to the x-axis translated raw acceleration value, the y-axis filtered threshold value to the y-axis translated raw acceleration value, and the z-axis filtered threshold value to the z-axis translated raw acceleration value. 15. The system of claim 14, further adapted to: activate a timer when the x-axis translated raw acceleration value exceeds the x-axis filtered threshold value, the y-axis translated raw acceleration value exceeds the y-axis filtered threshold value, or the z-axis translated raw acceleration value exceeds the z-axis filtered threshold value;determine a timer duration of the timer when the x-axis translated raw acceleration value does not exceed the x-axis filtered threshold value, the y-axis translated raw acceleration value does not exceed the y-axis filtered threshold value, or the z-axis translated raw acceleration value does not exceed the z-axis filtered threshold value, the timer duration comprising a duration that the x-axis translated raw acceleration value exceeded the x-axis filtered threshold value, the y-axis translated raw acceleration value exceeded the y-axis filtered threshold value, or the z-axis translated raw acceleration value exceeded the z-axis filtered threshold value;store a trigger activity event or a trigger inactivity event at a time when the timer duration exceeds the x-axis activity duration, the y-axis activity duration, or the z-axis activity duration; andupdate an engine running status. 16. The system of claim 15, wherein the trigger activity event or the trigger inactivity event comprises specifics on the axes, the timer duration, and the time of the trigger activity event or the trigger inactivity event. 17. The system of claim 1, further adapted to: receive a magnetometer data signal from at least one 3-axis magnetometer communicating with the microcontroller of the inertial navigation sensor board, the microcontroller processing the magnetometer data signal from the 3-axis magnetometer;calculate the mobile asset's pitch, wherein the mobile asset's pitch is determined by applying the equation: arctan(x-axistranslatedfilteredaccelerationvaluez-axistranslatedfilteredaccelerationvalue);calculate the mobile asset's roll, wherein the mobile asset's roll is determined by applying the equation: arctan(y-axistranslatedfilteredaccelerationvaluez-axistranslatedfilteredaccelerationvalue);calculate the mobile asset's speed, wherein the mobile asset's speed is determined by applying the equation: ∫ asset's accelerationx-axis translated filtered acceleration value;determine an x-axis gauss value, a y-axis gauss value, and a z-axis gauss value based on the magnetometer data signal; andcalculate a tilt compensation heading based on the x-axis gauss value, the y-axis gauss value, the z-axis gauss value, the mobile asset's pitch, and the mobile asset's roll. 18. The system of claim 17, further adapted to: receive a global positioning system (GPS) signal from at least one GPS sensor onboard the mobile asset;receive a gyroscope data signal from at least one 3-axis gyroscope communicating with the microcontroller of the inertial navigation sensor board, the microcontroller processing the gyroscope data signal from the 3-axis gyroscope;determine GPS data when the GPS signal is available from the GPS sensor;parse the GPS data into a speed, a heading, a latitude, and a longitude;store the latitude and longitude;determine gyroscope data based on the gyroscope data signal from the at least one 3-axis gyroscope;calculate a new position using the latitude, longitude, mobile asset speed, a wheel speed or the event data from the event data recorder, tilt compensation heading, and the gyroscope data, the new position comprising a new latitude and a new longitude; andstore the new latitude and new longitude. 19. The system of claim 17, further adapted to: receive a gyroscope data signal from at least one 3-axis gyroscope communicating with the microcontroller of the inertial navigation sensor board, the microcontroller processing the gyroscope data signal from the 3-axis gyroscope;receive a global positioning system (GPS) signal from at least one GPS sensor onboard the mobile asset;determine the mobile asset's last known latitude and last known longitude from the GPS sensor;store the mobile asset's last known latitude and last known longitude;read gyroscope data from the at least one 3-axis gyroscope;calculate a new position based on the last known latitude, last known longitude, mobile asset speed, a wheel speed or the event data from the event data recorder data, tilt compensation heading, and gyroscope data, the new position comprising a new latitude and a new longitude; andstore the new latitude and new longitude. 20. The system of claim 19, further adapted to: log a new position time of the new latitude and new longitude; andsend an asset departure alert or an asset arrival alert. 21. The system of claim 20, further adapted to: define at least one departure virtual trip wire or at least one arrival virtual trip wire, the departure virtual trip wire comprising a departure virtual trip wire location and the arrival virtual trip wire comprising an arrival virtual trip wire location;log a trip wire time when the new position of the mobile asset is the same as the departure virtual trip wire location or the arrival virtual trip wire location; andsend an alert when the new position of the mobile asset is the same as the departure virtual trip wire location or the arrival virtual trip wire location. 22. The system of claim 1, further comprising at least one fuel level sensor adapted to measure an amount of fuel inside a fuel tank of the mobile asset. 23. The system of claim 4, further adapted to: request a data log file covering the trigger event time or the brake time from the event data recorder;receive the data log file; andsend the data log file to the back office in real-time. 24. The system of claim 10, further adapted to: request a digital video download covering the time of the trigger event from the digital video recorder;receive the digital video download; andsend the digital video download to a back office. 25. The system of claim 18, further adapted to: log a new position time of the new latitude and new longitude; andsend an asset departure alert or an asset arrival alert. 26. The system of claim 25, further adapted to: define at least one departure virtual trip wire or at least one arrival virtual trip wire, the departure virtual trip wire comprising a departure virtual trip wire location and the arrival virtual trip wire comprising an arrival virtual trip wire location;log a trip wire time when the new position of the mobile asset is the same as the departure virtual trip wire location or the arrival virtual trip wire location; andsend an alert when the new position of the mobile asset is the same as the departure virtual trip wire location or the arrival virtual trip wire location.
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